wolfssl/src/ssl.c

/* ssl.c
 *
 * Copyright (C) 2006-2023 wolfSSL Inc.
 *
 * This file is part of wolfSSL.
 *
 * wolfSSL is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; either version 2 of the License, or
 * (at your option) any later version.
 *
 * wolfSSL is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1335, USA
 */


#ifdef HAVE_CONFIG_H
    #include <config.h>
#endif

#include <wolfssl/wolfcrypt/settings.h>
#if defined(OPENSSL_EXTRA) && !defined(_WIN32)
    /* turn on GNU extensions for XISASCII */
    #undef  _GNU_SOURCE
    #define _GNU_SOURCE
#endif

#if !defined(WOLFCRYPT_ONLY) || defined(OPENSSL_EXTRA) || \
    defined(OPENSSL_EXTRA_X509_SMALL)

#include <wolfssl/internal.h>
#include <wolfssl/error-ssl.h>
#include <wolfssl/wolfcrypt/coding.h>
#include <wolfssl/wolfcrypt/kdf.h>
#ifdef NO_INLINE
    #include <wolfssl/wolfcrypt/misc.h>
#else
    #define WOLFSSL_MISC_INCLUDED
    #include <wolfcrypt/src/misc.c>
#endif

#ifdef HAVE_ERRNO_H
    #include <errno.h>
#endif


#if !defined(WOLFSSL_ALLOW_NO_SUITES) && !defined(WOLFCRYPT_ONLY)
    #if defined(NO_DH) && !defined(HAVE_ECC) && !defined(WOLFSSL_STATIC_RSA) \
                && !defined(WOLFSSL_STATIC_DH) && !defined(WOLFSSL_STATIC_PSK) \
                && !defined(HAVE_CURVE25519) && !defined(HAVE_CURVE448)
        #error "No cipher suites defined because DH disabled, ECC disabled, and no static suites defined. Please see top of README"
    #endif
    #ifdef WOLFSSL_CERT_GEN
        /* need access to Cert struct for creating certificate */
        #include <wolfssl/wolfcrypt/asn_public.h>
    #endif
#endif

#if !defined(WOLFCRYPT_ONLY) && (defined(OPENSSL_EXTRA)     \
    || defined(OPENSSL_EXTRA_X509_SMALL)                    \
    || defined(HAVE_WEBSERVER) || defined(WOLFSSL_KEY_GEN))
    #include <wolfssl/openssl/evp.h>
    /* openssl headers end, wolfssl internal headers next */
#endif

#include <wolfssl/wolfcrypt/wc_encrypt.h>

#ifndef NO_RSA
    #include <wolfssl/wolfcrypt/rsa.h>
#endif

#ifdef OPENSSL_EXTRA
    /* openssl headers begin */
    #include <wolfssl/openssl/ssl.h>
    #include <wolfssl/openssl/aes.h>
#ifndef WOLFCRYPT_ONLY
    #include <wolfssl/openssl/hmac.h>
    #include <wolfssl/openssl/cmac.h>
#endif
    #include <wolfssl/openssl/crypto.h>
    #include <wolfssl/openssl/des.h>
    #include <wolfssl/openssl/bn.h>
    #include <wolfssl/openssl/buffer.h>
    #include <wolfssl/openssl/dh.h>
    #include <wolfssl/openssl/rsa.h>
    #include <wolfssl/openssl/fips_rand.h>
#ifndef WOLFCRYPT_ONLY
    #include <wolfssl/openssl/pem.h>
#endif
    #include <wolfssl/openssl/ec.h>
    #include <wolfssl/openssl/ec25519.h>
    #include <wolfssl/openssl/ed25519.h>
    #include <wolfssl/openssl/ec448.h>
    #include <wolfssl/openssl/ed448.h>
    #include <wolfssl/openssl/ecdsa.h>
    #include <wolfssl/openssl/ecdh.h>
    #include <wolfssl/openssl/err.h>
    #include <wolfssl/openssl/modes.h>
    #include <wolfssl/openssl/opensslv.h>
    #include <wolfssl/openssl/rc4.h>
    #include <wolfssl/openssl/stack.h>
    #include <wolfssl/openssl/x509_vfy.h>
    /* openssl headers end, wolfssl internal headers next */
    #include <wolfssl/wolfcrypt/hmac.h>
    #include <wolfssl/wolfcrypt/random.h>
    #include <wolfssl/wolfcrypt/des3.h>
    #include <wolfssl/wolfcrypt/ecc.h>
    #include <wolfssl/wolfcrypt/md4.h>
    #include <wolfssl/wolfcrypt/md5.h>
    #include <wolfssl/wolfcrypt/arc4.h>
    #include <wolfssl/wolfcrypt/curve25519.h>
    #include <wolfssl/wolfcrypt/ed25519.h>
    #include <wolfssl/wolfcrypt/curve448.h>
    #if defined(HAVE_PQC)
    #if defined(HAVE_FALCON)
        #include <wolfssl/wolfcrypt/falcon.h>
    #endif /* HAVE_FALCON */
    #if defined(HAVE_DILITHIUM)
        #include <wolfssl/wolfcrypt/dilithium.h>
    #endif /* HAVE_DILITHIUM */
    #endif /* HAVE_PQC */
    #if defined(OPENSSL_ALL) || defined(HAVE_STUNNEL)
        #ifdef HAVE_OCSP
            #include <wolfssl/openssl/ocsp.h>
        #endif
        #include <wolfssl/openssl/lhash.h>
        #include <wolfssl/openssl/txt_db.h>
    #endif /* WITH_STUNNEL */
    #if defined(WOLFSSL_SHA512) || defined(WOLFSSL_SHA384)
        #include <wolfssl/wolfcrypt/sha512.h>
    #endif
    #if defined(WOLFCRYPT_HAVE_SRP) && !defined(NO_SHA256) \
        && !defined(WC_NO_RNG)
        #include <wolfssl/wolfcrypt/srp.h>
    #endif
    #if defined(HAVE_FIPS) || defined(HAVE_SELFTEST)
        #include <wolfssl/wolfcrypt/pkcs7.h>
    #endif
    #if defined(OPENSSL_ALL) && defined(HAVE_PKCS7)
        #include <wolfssl/openssl/pkcs7.h>
    #endif /* OPENSSL_ALL && HAVE_PKCS7 */
#endif

#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
    #include <wolfssl/openssl/x509v3.h>
    int SetIndividualInternal(WOLFSSL_BIGNUM* bn, mp_int* mpi);
    int SetIndividualExternal(WOLFSSL_BIGNUM** bn, mp_int* mpi);
#endif

#if defined(WOLFSSL_QT)
    #include <wolfssl/wolfcrypt/sha.h>
#endif

#ifdef NO_ASN
    #include <wolfssl/wolfcrypt/dh.h>
#endif
#endif /* !WOLFCRYPT_ONLY || OPENSSL_EXTRA */

#ifdef WOLFSSL_SYS_CA_CERTS

#ifdef _WIN32
    #include <windows.h>
    #include <Wincrypt.h>

    /* mingw gcc does not support pragma comment, and the
     * linking with crypt32 is handled in configure.ac */
    #if !defined(__MINGW32__) && !defined(__MINGW64__)
        #pragma comment(lib, "crypt32")
    #endif
#endif

#if defined(__APPLE__) && defined(HAVE_SECURITY_SECTRUSTSETTINGS_H)
#include <Security/SecTrustSettings.h>
#endif

#endif /* WOLFSSL_SYS_CA_CERTS */

/*
 * OPENSSL_COMPATIBLE_DEFAULTS:
 *     Enable default behaviour that is compatible with OpenSSL. For example
 *     SSL_CTX by default doesn't verify the loaded certs. Enabling this
 *     should make porting to new projects easier.
 * WOLFSSL_CHECK_ALERT_ON_ERR:
 *     Check for alerts during the handshake in the event of an error.
 * NO_SESSION_CACHE_REF:
 *     wolfSSL_get_session on a client will return a reference to the internal
 *     ClientCache by default for backwards compatibility. This define will
 *     make wolfSSL_get_session return a reference to ssl->session. The returned
 *     pointer will be freed with the related WOLFSSL object.
 * WOLFSSL_SYS_CA_CERTS
 *     Enables ability to load system CA certs from the OS via
 *     wolfSSL_CTX_load_system_CA_certs.
 */

#define WOLFSSL_SSL_MISC_INCLUDED
#include "src/ssl_misc.c"

#define WOLFSSL_EVP_INCLUDED
#include "wolfcrypt/src/evp.c"

#ifndef WOLFCRYPT_ONLY

#define WOLFSSL_PK_INCLUDED
#include "src/pk.c"

#ifdef OPENSSL_EXTRA
    /* Global pointer to constant BN on */
    static WOLFSSL_BIGNUM* bn_one = NULL;

    /* WOLFSSL_NO_OPENSSL_RAND_CB: Allows way to reduce code size for
     *                OPENSSL_EXTRA where RAND callbacks are not used */
    #ifndef WOLFSSL_NO_OPENSSL_RAND_CB
        static const WOLFSSL_RAND_METHOD* gRandMethods = NULL;
        static int gRandMethodsInit = 0;
        static wolfSSL_Mutex gRandMethodMutex;
    #endif /* !WOLFSSL_NO_OPENSSL_RAND_CB */
#endif /* OPENSSL_EXTRA */

#include <wolfssl/wolfcrypt/hpke.h>

#if defined(OPENSSL_EXTRA) && defined(HAVE_ECC)
const WOLF_EC_NIST_NAME kNistCurves[] = {
    {XSTR_SIZEOF("P-192"),   "P-192",   NID_X9_62_prime192v1},
    {XSTR_SIZEOF("P-256"),   "P-256",   NID_X9_62_prime256v1},
    {XSTR_SIZEOF("P-112"),   "P-112",   NID_secp112r1},
    {XSTR_SIZEOF("P-112-2"), "P-112-2", NID_secp112r2},
    {XSTR_SIZEOF("P-128"),   "P-128",   NID_secp128r1},
    {XSTR_SIZEOF("P-128-2"), "P-128-2", NID_secp128r2},
    {XSTR_SIZEOF("P-160"),   "P-160",   NID_secp160r1},
    {XSTR_SIZEOF("P-160-2"), "P-160-2", NID_secp160r2},
    {XSTR_SIZEOF("P-224"),   "P-224",   NID_secp224r1},
    {XSTR_SIZEOF("P-384"),   "P-384",   NID_secp384r1},
    {XSTR_SIZEOF("P-521"),   "P-521",   NID_secp521r1},
    {XSTR_SIZEOF("K-160"),   "K-160",   NID_secp160k1},
    {XSTR_SIZEOF("K-192"),   "K-192",   NID_secp192k1},
    {XSTR_SIZEOF("K-224"),   "K-224",   NID_secp224k1},
    {XSTR_SIZEOF("K-256"),   "K-256",   NID_secp256k1},
    {XSTR_SIZEOF("B-160"),   "B-160",   NID_brainpoolP160r1},
    {XSTR_SIZEOF("B-192"),   "B-192",   NID_brainpoolP192r1},
    {XSTR_SIZEOF("B-224"),   "B-224",   NID_brainpoolP224r1},
    {XSTR_SIZEOF("B-256"),   "B-256",   NID_brainpoolP256r1},
    {XSTR_SIZEOF("B-320"),   "B-320",   NID_brainpoolP320r1},
    {XSTR_SIZEOF("B-384"),   "B-384",   NID_brainpoolP384r1},
    {XSTR_SIZEOF("B-512"),   "B-512",   NID_brainpoolP512r1},
#ifdef HAVE_PQC
    {XSTR_SIZEOF("KYBER_LEVEL1"), "KYBER_LEVEL1", WOLFSSL_KYBER_LEVEL1},
    {XSTR_SIZEOF("KYBER_LEVEL3"), "KYBER_LEVEL3", WOLFSSL_KYBER_LEVEL3},
    {XSTR_SIZEOF("KYBER_LEVEL5"), "KYBER_LEVEL5", WOLFSSL_KYBER_LEVEL5},
#ifdef HAVE_LIBOQS
    {XSTR_SIZEOF("P256_KYBER_LEVEL1"), "P256_KYBER_LEVEL1", WOLFSSL_P256_KYBER_LEVEL1},
    {XSTR_SIZEOF("P384_KYBER_LEVEL3"), "P384_KYBER_LEVEL3", WOLFSSL_P384_KYBER_LEVEL3},
    {XSTR_SIZEOF("P521_KYBER_LEVEL5"), "P521_KYBER_LEVEL5", WOLFSSL_P521_KYBER_LEVEL5},
#endif
#endif
    {0, NULL, 0},
};
#endif

#if defined(HAVE_ECH)
/* create the hpke key and ech config to send to clients */
int wolfSSL_CTX_GenerateEchConfig(WOLFSSL_CTX* ctx, const char* publicName,
    word16 kemId, word16 kdfId, word16 aeadId)
{
    int ret = 0;
    word16 encLen = DHKEM_X25519_ENC_LEN;
#ifdef WOLFSSL_SMALL_STACK
    Hpke* hpke = NULL;
    WC_RNG* rng;
#else
    Hpke hpke[1];
    WC_RNG rng[1];
#endif

    if (ctx == NULL || publicName == NULL)
        return BAD_FUNC_ARG;

#ifdef WOLFSSL_SMALL_STACK
    rng = (WC_RNG*)XMALLOC(sizeof(WC_RNG), ctx->heap, DYNAMIC_TYPE_RNG);
    if (rng == NULL)
        return MEMORY_E;
#endif
    ret = wc_InitRng(rng);
    if (ret != 0) {
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(rng, ctx->heap, DYNAMIC_TYPE_RNG);
    #endif
        return ret;
    }

    ctx->echConfigs = (WOLFSSL_EchConfig*)XMALLOC(sizeof(WOLFSSL_EchConfig),
        ctx->heap, DYNAMIC_TYPE_TMP_BUFFER);
    if (ctx->echConfigs == NULL)
        ret = MEMORY_E;
    else
        XMEMSET(ctx->echConfigs, 0, sizeof(WOLFSSL_EchConfig));

    /* set random config id */
    if (ret == 0)
        ret = wc_RNG_GenerateByte(rng, &ctx->echConfigs->configId);

    /* if 0 is selected for algorithms use default, may change with draft */
    if (kemId == 0)
        kemId = DHKEM_X25519_HKDF_SHA256;

    if (kdfId == 0)
        kdfId = HKDF_SHA256;

    if (aeadId == 0)
        aeadId = HPKE_AES_128_GCM;

    if (ret == 0) {
        /* set the kem id */
        ctx->echConfigs->kemId = kemId;

        /* set the cipher suite, only 1 for now */
        ctx->echConfigs->numCipherSuites = 1;
        ctx->echConfigs->cipherSuites = (EchCipherSuite*)XMALLOC(
            sizeof(EchCipherSuite), ctx->heap, DYNAMIC_TYPE_TMP_BUFFER);

        if (ctx->echConfigs->cipherSuites == NULL) {
            ret = MEMORY_E;
        }
        else {
            ctx->echConfigs->cipherSuites[0].kdfId = kdfId;
            ctx->echConfigs->cipherSuites[0].aeadId = aeadId;
        }
    }

#ifdef WOLFSSL_SMALL_STACK
    if (ret == 0) {
        hpke = (Hpke*)XMALLOC(sizeof(Hpke), ctx->heap, DYNAMIC_TYPE_TMP_BUFFER);
        if (hpke == NULL)
            ret = MEMORY_E;
    }
#endif

    if (ret == 0)
        ret = wc_HpkeInit(hpke, kemId, kdfId, aeadId, ctx->heap);

    /* generate the receiver private key */
    if (ret == 0)
        ret = wc_HpkeGenerateKeyPair(hpke, &ctx->echConfigs->receiverPrivkey,
            rng);

    /* done with RNG */
    wc_FreeRng(rng);

    /* serialize the receiver key */
    if (ret == 0)
        ret = wc_HpkeSerializePublicKey(hpke, ctx->echConfigs->receiverPrivkey,
            ctx->echConfigs->receiverPubkey, &encLen);

    if (ret == 0) {
        ctx->echConfigs->publicName = (char*)XMALLOC(XSTRLEN(publicName) + 1,
            ctx->heap, DYNAMIC_TYPE_TMP_BUFFER);
        if (ctx->echConfigs->publicName == NULL) {
            ret = MEMORY_E;
        }
        else {
            XMEMCPY(ctx->echConfigs->publicName, publicName,
                XSTRLEN(publicName) + 1);
        }
    }

    if (ret != 0) {
        if (ctx->echConfigs) {
            XFREE(ctx->echConfigs->cipherSuites, ctx->heap,
                DYNAMIC_TYPE_TMP_BUFFER);
            XFREE(ctx->echConfigs->publicName, ctx->heap,
                DYNAMIC_TYPE_TMP_BUFFER);
            XFREE(ctx->echConfigs, ctx->heap, DYNAMIC_TYPE_TMP_BUFFER);
            /* set to null to avoid double free in cleanup */
            ctx->echConfigs = NULL;
        }
    }

    if (ret == 0)
        ret = WOLFSSL_SUCCESS;

#ifdef WOLFSSL_SMALL_STACK
    XFREE(hpke, ctx->heap, DYNAMIC_TYPE_TMP_BUFFER);
    XFREE(rng, ctx->heap, DYNAMIC_TYPE_RNG);
#endif

    return ret;
}

/* get the ech configs that the server context is using */
int wolfSSL_CTX_GetEchConfigs(WOLFSSL_CTX* ctx, byte* output,
    word32* outputLen) {
    if (ctx == NULL || outputLen == NULL)
        return BAD_FUNC_ARG;

    /* if we don't have ech configs */
    if (ctx->echConfigs == NULL) {
        return WOLFSSL_FATAL_ERROR;
    }

    return GetEchConfigsEx(ctx->echConfigs, output, outputLen);
}

/* set the ech config from base64 for our client ssl object, base64 is the
 * format ech configs are sent using dns records */
int wolfSSL_SetEchConfigsBase64(WOLFSSL* ssl, char* echConfigs64,
    word32 echConfigs64Len)
{
    int ret = 0;
    word32 decodedLen = echConfigs64Len * 3 / 4 + 1;
    byte* decodedConfigs;

    if (ssl == NULL || echConfigs64 == NULL || echConfigs64Len == 0)
        return BAD_FUNC_ARG;

    /* already have ech configs */
    if (ssl->options.useEch == 1) {
        return WOLFSSL_FATAL_ERROR;
    }

    decodedConfigs = (byte*)XMALLOC(decodedLen, ssl->heap,
        DYNAMIC_TYPE_TMP_BUFFER);

    if (decodedConfigs == NULL)
        return MEMORY_E;

    decodedConfigs[decodedLen - 1] = 0;

    /* decode the echConfigs */
    ret = Base64_Decode((byte*)echConfigs64, echConfigs64Len,
      decodedConfigs, &decodedLen);

    if (ret != 0) {
        XFREE(decodedConfigs, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
        return ret;
    }

    ret = wolfSSL_SetEchConfigs(ssl, decodedConfigs, decodedLen);

    XFREE(decodedConfigs, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);

    return ret;
}

/* set the ech config from a raw buffer, this is the format ech configs are
 * sent using retry_configs from the ech server */
int wolfSSL_SetEchConfigs(WOLFSSL* ssl, const byte* echConfigs,
  word32 echConfigsLen)
{
    int ret = 0;
    int i;
    int j;
    word16 totalLength;
    word16 version;
    word16 length;
    word16 hpkePubkeyLen;
    word16 cipherSuitesLen;
    word16 publicNameLen;
    WOLFSSL_EchConfig* configList = NULL;
    WOLFSSL_EchConfig* workingConfig = NULL;
    WOLFSSL_EchConfig* lastConfig = NULL;
    byte* echConfig = NULL;

    if (ssl == NULL || echConfigs == NULL || echConfigsLen == 0)
        return BAD_FUNC_ARG;

    /* already have ech configs */
    if (ssl->options.useEch == 1) {
        return WOLFSSL_FATAL_ERROR;
    }

    /* check that the total length is well formed */
    ato16(echConfigs, &totalLength);

    if (totalLength != echConfigsLen - 2) {
        return WOLFSSL_FATAL_ERROR;
    }

    /* skip the total length uint16_t */
    i = 2;

    do {
        echConfig = (byte*)echConfigs + i;
        ato16(echConfig, &version);
        ato16(echConfig + 2, &length);

        /* if the version does not match */
        if (version != TLSX_ECH) {
            /* we hit the end of the configs */
            if ( (word32)i + 2 >= echConfigsLen ) {
                break;
            }

            /* skip this config, +4 for version and length */
            i += length + 4;
            continue;
        }

        /* check if the length will overrun the buffer */
        if ((word32)i + length + 4 > echConfigsLen) {
            break;
        }

        if (workingConfig == NULL) {
            workingConfig =
                (WOLFSSL_EchConfig*)XMALLOC(sizeof(WOLFSSL_EchConfig),
                ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
            configList = workingConfig;
            workingConfig->next = NULL;
        }
        else {
            lastConfig = workingConfig;
            workingConfig->next =
                (WOLFSSL_EchConfig*)XMALLOC(sizeof(WOLFSSL_EchConfig),
                ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
            workingConfig = workingConfig->next;
        }

        if (workingConfig == NULL) {
            ret = MEMORY_E;
            break;
        }

        XMEMSET(workingConfig, 0, sizeof(WOLFSSL_EchConfig));

        /* rawLen */
        workingConfig->rawLen = length + 4;

        /* raw body */
        workingConfig->raw = (byte*)XMALLOC(workingConfig->rawLen,
            ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
        if (workingConfig->raw == NULL) {
            ret = MEMORY_E;
            break;
        }

        XMEMCPY(workingConfig->raw, echConfig, workingConfig->rawLen);

        /* skip over version and length */
        echConfig += 4;

        /* configId, 1 byte */
        workingConfig->configId = *(echConfig);
        echConfig++;
        /* kemId, 2 bytes */
        ato16(echConfig, &workingConfig->kemId);
        echConfig += 2;
        /* hpke public_key length, 2 bytes */
        ato16(echConfig, &hpkePubkeyLen);
        echConfig += 2;
        /* hpke public_key */
        XMEMCPY(workingConfig->receiverPubkey, echConfig, hpkePubkeyLen);
        echConfig += hpkePubkeyLen;
        /* cipherSuitesLen */
        ato16(echConfig, &cipherSuitesLen);

        workingConfig->cipherSuites = (EchCipherSuite*)XMALLOC(cipherSuitesLen,
            ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
        if (workingConfig->cipherSuites == NULL) {
            ret = MEMORY_E;
            break;
        }

        echConfig += 2;
        workingConfig->numCipherSuites = cipherSuitesLen / 4;
        /* cipherSuites */
        for (j = 0; j < workingConfig->numCipherSuites; j++) {
            ato16(echConfig + j * 4, &workingConfig->cipherSuites[j].kdfId);
            ato16(echConfig + j * 4 + 2,
                &workingConfig->cipherSuites[j].aeadId);
        }
        echConfig += cipherSuitesLen;
        /* publicNameLen */
        ato16(echConfig, &publicNameLen);
        workingConfig->publicName = (char*)XMALLOC(publicNameLen + 1,
            ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
        if (workingConfig->publicName == NULL) {
            ret = MEMORY_E;
            break;
        }

        echConfig += 2;
        /* publicName */
        XMEMCPY(workingConfig->publicName, echConfig, publicNameLen);
        /* null terminated */
        workingConfig->publicName[publicNameLen] = 0;

        /* add length to go to next config, +4 for version and length */
        i += length + 4;

        /* check that we support this config */
        for (j = 0; j < HPKE_SUPPORTED_KEM_LEN; j++) {
            if (hpkeSupportedKem[j] == workingConfig->kemId)
                break;
        }

        /* if we don't support the kem or at least one cipher suite */
        if (j >= HPKE_SUPPORTED_KEM_LEN ||
            EchConfigGetSupportedCipherSuite(workingConfig) < 0)
        {
            XFREE(workingConfig->cipherSuites, ssl->heap,
                DYNAMIC_TYPE_TMP_BUFFER);
            XFREE(workingConfig->publicName, ssl->heap,
                DYNAMIC_TYPE_TMP_BUFFER);
            XFREE(workingConfig->raw, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
            workingConfig = lastConfig;
        }
    } while ((word32)i < echConfigsLen);

    /* if we found valid configs */
    if (ret == 0 && configList != NULL) {
        ssl->options.useEch = 1;
        ssl->echConfigs = configList;

        return WOLFSSL_SUCCESS;
    }

    workingConfig = configList;

    while (workingConfig != NULL) {
        lastConfig = workingConfig;
        workingConfig = workingConfig->next;

        XFREE(lastConfig->cipherSuites, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
        XFREE(lastConfig->publicName, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
        XFREE(lastConfig->raw, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);

        XFREE(lastConfig, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
    }

    if (ret == 0)
        return WOLFSSL_FATAL_ERROR;

    return ret;
}

/* get the raw ech config from our struct */
int GetEchConfig(WOLFSSL_EchConfig* config, byte* output, word32* outputLen)
{
    int i;
    word16 totalLen = 0;

    if (config == NULL || (output == NULL && outputLen == NULL))
        return BAD_FUNC_ARG;

    /* 2 for version */
    totalLen += 2;
    /* 2 for length */
    totalLen += 2;
    /* 1 for configId */
    totalLen += 1;
    /* 2 for kemId */
    totalLen += 2;
    /* 2 for hpke_len */
    totalLen += 2;

    /* hpke_pub_key */
    switch (config->kemId) {
        case DHKEM_P256_HKDF_SHA256:
            totalLen += DHKEM_P256_ENC_LEN;
            break;
        case DHKEM_P384_HKDF_SHA384:
            totalLen += DHKEM_P384_ENC_LEN;
            break;
        case DHKEM_P521_HKDF_SHA512:
            totalLen += DHKEM_P521_ENC_LEN;
            break;
        case DHKEM_X25519_HKDF_SHA256:
            totalLen += DHKEM_X25519_ENC_LEN;
            break;
        case DHKEM_X448_HKDF_SHA512:
            totalLen += DHKEM_X448_ENC_LEN;
            break;
    }

    /* cipherSuitesLen */
    totalLen += 2;
    /* cipherSuites */
    totalLen += config->numCipherSuites * 4;
    /* public name len */
    totalLen += 2;

    /* public name */
    totalLen += XSTRLEN(config->publicName);
    /* trailing zeros */
    totalLen += 2;

    if (output == NULL) {
        *outputLen = totalLen;
        return LENGTH_ONLY_E;
    }

    if (totalLen > *outputLen) {
        *outputLen = totalLen;
        return INPUT_SIZE_E;
    }

    /* version */
    c16toa(TLSX_ECH, output);
    output += 2;

    /* length - 4 for version and length itself */
    c16toa(totalLen - 4, output);
    output += 2;

    /* configId */
    *output = config->configId;
    output++;
    /* kemId */
    c16toa(config->kemId, output);
    output += 2;

    /* length and key itself */
    switch (config->kemId) {
        case DHKEM_P256_HKDF_SHA256:
            c16toa(DHKEM_P256_ENC_LEN, output);
            output += 2;
            XMEMCPY(output, config->receiverPubkey, DHKEM_P256_ENC_LEN);
            output += DHKEM_P256_ENC_LEN;
            break;
        case DHKEM_P384_HKDF_SHA384:
            c16toa(DHKEM_P384_ENC_LEN, output);
            output += 2;
            XMEMCPY(output, config->receiverPubkey, DHKEM_P384_ENC_LEN);
            output += DHKEM_P384_ENC_LEN;
            break;
        case DHKEM_P521_HKDF_SHA512:
            c16toa(DHKEM_P521_ENC_LEN, output);
            output += 2;
            XMEMCPY(output, config->receiverPubkey, DHKEM_P521_ENC_LEN);
            output += DHKEM_P521_ENC_LEN;
            break;
        case DHKEM_X25519_HKDF_SHA256:
            c16toa(DHKEM_X25519_ENC_LEN, output);
            output += 2;
            XMEMCPY(output, config->receiverPubkey, DHKEM_X25519_ENC_LEN);
            output += DHKEM_X25519_ENC_LEN;
            break;
        case DHKEM_X448_HKDF_SHA512:
            c16toa(DHKEM_X448_ENC_LEN, output);
            output += 2;
            XMEMCPY(output, config->receiverPubkey, DHKEM_X448_ENC_LEN);
            output += DHKEM_X448_ENC_LEN;
            break;
    }

    /* cipherSuites len */
    c16toa(config->numCipherSuites * 4, output);
    output += 2;

    /* cipherSuites */
    for (i = 0; i < config->numCipherSuites; i++) {
        c16toa(config->cipherSuites[i].kdfId, output);
        output += 2;
        c16toa(config->cipherSuites[i].aeadId, output);
        output += 2;
    }

    /* publicName len */
    c16toa(XSTRLEN(config->publicName), output);
    output += 2;

    /* publicName */
    XMEMCPY(output, config->publicName,
        XSTRLEN(config->publicName));
    output += XSTRLEN(config->publicName);

    /* terminating zeros */
    c16toa(0, output);
    /* output += 2; */

    *outputLen = totalLen;

    return 0;
}

/* wrapper function to get ech configs from application code */
int wolfSSL_GetEchConfigs(WOLFSSL* ssl, byte* output, word32* outputLen)
{
    if (ssl == NULL || outputLen == NULL)
        return BAD_FUNC_ARG;

    /* if we don't have ech configs */
    if (ssl->options.useEch != 1) {
        return WOLFSSL_FATAL_ERROR;
    }

    return GetEchConfigsEx(ssl->echConfigs, output, outputLen);
}

/* get the raw ech configs from our linked list of ech config structs */
int GetEchConfigsEx(WOLFSSL_EchConfig* configs, byte* output, word32* outputLen)
{
    int ret = 0;
    WOLFSSL_EchConfig* workingConfig = NULL;
    byte* outputStart = output;
    word32 totalLen = 2;
    word32 workingOutputLen;

    if (configs == NULL || outputLen == NULL)
        return BAD_FUNC_ARG;

    workingOutputLen = *outputLen - totalLen;

    /* skip over total length which we fill in later */
    if (output != NULL)
        output += 2;

    workingConfig = configs;

    while (workingConfig != NULL) {
        /* get this config */
        ret = GetEchConfig(workingConfig, output, &workingOutputLen);

        if (output != NULL)
            output += workingOutputLen;

        /* add this config's length to the total length */
        totalLen += workingOutputLen;

        if (totalLen > *outputLen)
            workingOutputLen = 0;
        else
            workingOutputLen = *outputLen - totalLen;

        /* only error we break on, other 2 we need to keep finding length */
        if (ret == BAD_FUNC_ARG)
            return BAD_FUNC_ARG;

        workingConfig = workingConfig->next;
    }

    if (output == NULL) {
        *outputLen = totalLen;
        return LENGTH_ONLY_E;
    }

    if (totalLen > *outputLen) {
        *outputLen = totalLen;
        return INPUT_SIZE_E;
    }

    /* total size -2 for size itself */
    c16toa(totalLen - 2, outputStart);

    *outputLen = totalLen;

    return WOLFSSL_SUCCESS;
}
#endif /* HAVE_ECH */


#if defined(WOLFSSL_RENESAS_TSIP_TLS) || defined(WOLFSSL_RENESAS_SCEPROTECT)
#include <wolfssl/wolfcrypt/port/Renesas/renesas_cmn.h>
#endif

#ifdef WOLFSSL_SESSION_EXPORT
/* Used to import a serialized TLS session.
 * WARNING: buf contains sensitive information about the state and is best to be
 *          encrypted before storing if stored.
 *
 * @param ssl WOLFSSL structure to import the session into
 * @param buf serialized session
 * @param sz  size of buffer 'buf'
 * @return the number of bytes read from buffer 'buf'
 */
int wolfSSL_tls_import(WOLFSSL* ssl, const unsigned char* buf, unsigned int sz)
{
    if (ssl == NULL || buf == NULL) {
        return BAD_FUNC_ARG;
    }
    return wolfSSL_session_import_internal(ssl, buf, sz, WOLFSSL_EXPORT_TLS);
}


/* Used to export a serialized TLS session.
 * WARNING: buf contains sensitive information about the state and is best to be
 *          encrypted before storing if stored.
 *
 * @param ssl WOLFSSL structure to export the session from
 * @param buf output of serialized session
 * @param sz  size in bytes set in 'buf'
 * @return the number of bytes written into buffer 'buf'
 */
int wolfSSL_tls_export(WOLFSSL* ssl, unsigned char* buf, unsigned int* sz)
{
    if (ssl == NULL || sz == NULL) {
        return BAD_FUNC_ARG;
    }
    return wolfSSL_session_export_internal(ssl, buf, sz, WOLFSSL_EXPORT_TLS);
}

#ifdef WOLFSSL_DTLS
int wolfSSL_dtls_import(WOLFSSL* ssl, const unsigned char* buf, unsigned int sz)
{
    WOLFSSL_ENTER("wolfSSL_session_import");

    if (ssl == NULL || buf == NULL) {
        return BAD_FUNC_ARG;
    }

    /* sanity checks on buffer and protocol are done in internal function */
    return wolfSSL_session_import_internal(ssl, buf, sz, WOLFSSL_EXPORT_DTLS);
}


/* Sets the function to call for serializing the session. This function is
 * called right after the handshake is completed. */
int wolfSSL_CTX_dtls_set_export(WOLFSSL_CTX* ctx, wc_dtls_export func)
{

    WOLFSSL_ENTER("wolfSSL_CTX_dtls_set_export");

    /* purposefully allow func to be NULL */
    if (ctx == NULL) {
        return BAD_FUNC_ARG;
    }

    ctx->dtls_export = func;

    return WOLFSSL_SUCCESS;
}


/* Sets the function in WOLFSSL struct to call for serializing the session. This
 * function is called right after the handshake is completed. */
int wolfSSL_dtls_set_export(WOLFSSL* ssl, wc_dtls_export func)
{

    WOLFSSL_ENTER("wolfSSL_dtls_set_export");

    /* purposefully allow func to be NULL */
    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }

    ssl->dtls_export = func;

    return WOLFSSL_SUCCESS;
}


/* This function allows for directly serializing a session rather than using
 * callbacks. It has less overhead by removing a temporary buffer and gives
 * control over when the session gets serialized. When using callbacks the
 * session is always serialized immediately after the handshake is finished.
 *
 * buf is the argument to contain the serialized session
 * sz  is the size of the buffer passed in
 * ssl is the WOLFSSL struct to serialize
 * returns the size of serialized session on success, 0 on no action, and
 *         negative value on error */
int wolfSSL_dtls_export(WOLFSSL* ssl, unsigned char* buf, unsigned int* sz)
{
    WOLFSSL_ENTER("wolfSSL_dtls_export");

    if (ssl == NULL || sz == NULL) {
        return BAD_FUNC_ARG;
    }

    if (buf == NULL) {
        *sz = MAX_EXPORT_BUFFER;
        return 0;
    }

    /* if not DTLS do nothing */
    if (!ssl->options.dtls) {
        WOLFSSL_MSG("Currently only DTLS export is supported");
        return 0;
    }

    /* copy over keys, options, and dtls state struct */
    return wolfSSL_session_export_internal(ssl, buf, sz, WOLFSSL_EXPORT_DTLS);
}


/* This function is similar to wolfSSL_dtls_export but only exports the portion
 * of the WOLFSSL structure related to the state of the connection, i.e. peer
 * sequence number, epoch, AEAD state etc.
 *
 * buf is the argument to contain the serialized state, if null then set "sz" to
 *     buffer size required
 * sz  is the size of the buffer passed in
 * ssl is the WOLFSSL struct to serialize
 * returns the size of serialized session on success, 0 on no action, and
 *         negative value on error */
int wolfSSL_dtls_export_state_only(WOLFSSL* ssl, unsigned char* buf,
        unsigned int* sz)
{
    WOLFSSL_ENTER("wolfSSL_dtls_export_state_only");

    if (ssl == NULL || sz == NULL) {
        return BAD_FUNC_ARG;
    }

    if (buf == NULL) {
        *sz = MAX_EXPORT_STATE_BUFFER;
        return 0;
    }

    /* if not DTLS do nothing */
    if (!ssl->options.dtls) {
        WOLFSSL_MSG("Currently only DTLS export state is supported");
        return 0;
    }

    /* copy over keys, options, and dtls state struct */
    return wolfSSL_dtls_export_state_internal(ssl, buf, *sz);
}


/* returns 0 on success */
int wolfSSL_send_session(WOLFSSL* ssl)
{
    int ret;
    byte* buf;
    word32 bufSz = MAX_EXPORT_BUFFER;

    WOLFSSL_ENTER("wolfSSL_send_session");

    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }

    buf = (byte*)XMALLOC(bufSz, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
    if (buf == NULL) {
        return MEMORY_E;
    }

    /* if not DTLS do nothing */
    if (!ssl->options.dtls) {
        XFREE(buf, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
        WOLFSSL_MSG("Currently only DTLS export is supported");
        return 0;
    }

    /* copy over keys, options, and dtls state struct */
    ret = wolfSSL_session_export_internal(ssl, buf, &bufSz, WOLFSSL_EXPORT_DTLS);
    if (ret < 0) {
        XFREE(buf, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
        return ret;
    }

    /* if no error ret has size of buffer */
    ret = ssl->dtls_export(ssl, buf, ret, NULL);
    if (ret != WOLFSSL_SUCCESS) {
        XFREE(buf, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
        return ret;
    }

    XFREE(buf, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
    return 0;
}
#endif /* WOLFSSL_DTLS */
#endif /* WOLFSSL_SESSION_EXPORT */

/* prevent multiple mutex initializations */
static volatile WOLFSSL_GLOBAL int initRefCount = 0;
static WOLFSSL_GLOBAL wolfSSL_Mutex count_mutex;   /* init ref count mutex */
static WOLFSSL_GLOBAL int count_mutex_valid = 0;

/* Create a new WOLFSSL_CTX struct and return the pointer to created struct.
   WOLFSSL_METHOD pointer passed in is given to ctx to manage.
   This function frees the passed in WOLFSSL_METHOD struct on failure and on
   success is freed when ctx is freed.
 */
WOLFSSL_CTX* wolfSSL_CTX_new_ex(WOLFSSL_METHOD* method, void* heap)
{
    WOLFSSL_CTX* ctx = NULL;

    WOLFSSL_ENTER("wolfSSL_CTX_new_ex");

    if (initRefCount == 0) {
        /* user no longer forced to call Init themselves */
        int ret = wolfSSL_Init();
        if (ret != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("wolfSSL_Init failed");
            WOLFSSL_LEAVE("WOLFSSL_CTX_new", 0);
            if (method != NULL) {
                XFREE(method, heap, DYNAMIC_TYPE_METHOD);
            }
            return NULL;
        }
    }

    if (method == NULL)
        return ctx;

    ctx = (WOLFSSL_CTX*)XMALLOC(sizeof(WOLFSSL_CTX), heap, DYNAMIC_TYPE_CTX);
    if (ctx) {
        int ret;

        ret = InitSSL_Ctx(ctx, method, heap);
    #ifdef WOLFSSL_STATIC_MEMORY
        if (heap != NULL) {
            ctx->onHeapHint = 1; /* free the memory back to heap when done */
        }
    #endif
        if (ret < 0) {
            WOLFSSL_MSG("Init CTX failed");
            wolfSSL_CTX_free(ctx);
            ctx = NULL;
        }
#if defined(OPENSSL_EXTRA) && defined(WOLFCRYPT_HAVE_SRP) \
                           && !defined(NO_SHA256) && !defined(WC_NO_RNG)
        else {
            ctx->srp = (Srp*)XMALLOC(sizeof(Srp), heap, DYNAMIC_TYPE_SRP);
            if (ctx->srp == NULL){
                WOLFSSL_MSG("Init CTX failed");
                wolfSSL_CTX_free(ctx);
                return NULL;
            }
            XMEMSET(ctx->srp, 0, sizeof(Srp));
        }
#endif
    }
    else {
        WOLFSSL_MSG("Alloc CTX failed, method freed");
        XFREE(method, heap, DYNAMIC_TYPE_METHOD);
    }

#ifdef OPENSSL_COMPATIBLE_DEFAULTS
    if (ctx) {
        wolfSSL_CTX_set_verify(ctx, SSL_VERIFY_NONE, NULL);
        wolfSSL_CTX_set_mode(ctx, SSL_MODE_AUTO_RETRY);
        if (wolfSSL_CTX_set_min_proto_version(ctx,
                                              (method->version.major == DTLS_MAJOR) ?
                                               DTLS1_VERSION : SSL3_VERSION) != WOLFSSL_SUCCESS ||
#ifdef HAVE_ANON
                wolfSSL_CTX_allow_anon_cipher(ctx) != WOLFSSL_SUCCESS ||
#endif
                wolfSSL_CTX_set_group_messages(ctx) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("Setting OpenSSL CTX defaults failed");
            wolfSSL_CTX_free(ctx);
            ctx = NULL;
        }
    }
#endif

    WOLFSSL_LEAVE("WOLFSSL_CTX_new", 0);
    return ctx;
}


WOLFSSL_ABI
WOLFSSL_CTX* wolfSSL_CTX_new(WOLFSSL_METHOD* method)
{
#ifdef WOLFSSL_HEAP_TEST
    /* if testing the heap hint then set top level CTX to have test value */
    return wolfSSL_CTX_new_ex(method, (void*)WOLFSSL_HEAP_TEST);
#else
    return wolfSSL_CTX_new_ex(method, NULL);
#endif
}

/* increases CTX reference count to track proper time to "free" */
int wolfSSL_CTX_up_ref(WOLFSSL_CTX* ctx)
{
    int refCount = SSL_CTX_RefCount(ctx, 1);
    return ((refCount > 1) ? WOLFSSL_SUCCESS : WOLFSSL_FAILURE);
}

WOLFSSL_ABI
void wolfSSL_CTX_free(WOLFSSL_CTX* ctx)
{
    WOLFSSL_ENTER("SSL_CTX_free");
    if (ctx) {
#if defined(OPENSSL_EXTRA) && defined(WOLFCRYPT_HAVE_SRP) \
&& !defined(NO_SHA256) && !defined(WC_NO_RNG)
        if (ctx->srp != NULL) {
            if (ctx->srp_password != NULL){
                XFREE(ctx->srp_password, ctx->heap, DYNAMIC_TYPE_SRP);
                ctx->srp_password = NULL;
            }
            wc_SrpTerm(ctx->srp);
            XFREE(ctx->srp, ctx->heap, DYNAMIC_TYPE_SRP);
            ctx->srp = NULL;
        }
#endif
        FreeSSL_Ctx(ctx);
    }

    WOLFSSL_LEAVE("SSL_CTX_free", 0);
}


#ifdef HAVE_ENCRYPT_THEN_MAC
/**
 * Sets whether Encrypt-Then-MAC extension can be negotiated against context.
 * The default value: enabled.
 *
 * ctx  SSL/TLS context.
 * set  Whether to allow or not: 1 is allow and 0 is disallow.
 * returns WOLFSSL_SUCCESS
 */
int wolfSSL_CTX_AllowEncryptThenMac(WOLFSSL_CTX *ctx, int set)
{
    ctx->disallowEncThenMac = !set;
    return WOLFSSL_SUCCESS;
}

/**
 * Sets whether Encrypt-Then-MAC extension can be negotiated against context.
 * The default value comes from context.
 *
 * ctx  SSL/TLS context.
 * set  Whether to allow or not: 1 is allow and 0 is disallow.
 * returns WOLFSSL_SUCCESS
 */
int wolfSSL_AllowEncryptThenMac(WOLFSSL *ssl, int set)
{
    ssl->options.disallowEncThenMac = !set;
    return WOLFSSL_SUCCESS;
}
#endif

#ifdef SINGLE_THREADED
/* no locking in single threaded mode, allow a CTX level rng to be shared with
 * WOLFSSL objects, WOLFSSL_SUCCESS on ok */
int wolfSSL_CTX_new_rng(WOLFSSL_CTX* ctx)
{
    WC_RNG* rng;
    int     ret;

    if (ctx == NULL) {
        return BAD_FUNC_ARG;
    }

    rng = (WC_RNG*)XMALLOC(sizeof(WC_RNG), ctx->heap, DYNAMIC_TYPE_RNG);
    if (rng == NULL) {
        return MEMORY_E;
    }

#ifndef HAVE_FIPS
    ret = wc_InitRng_ex(rng, ctx->heap, ctx->devId);
#else
    ret = wc_InitRng(rng);
#endif
    if (ret != 0) {
        XFREE(rng, ctx->heap, DYNAMIC_TYPE_RNG);
        return ret;
    }

    ctx->rng = rng;
    return WOLFSSL_SUCCESS;
}
#endif


WOLFSSL_ABI
WOLFSSL* wolfSSL_new(WOLFSSL_CTX* ctx)
{
    WOLFSSL* ssl = NULL;
    int ret = 0;

    WOLFSSL_ENTER("SSL_new");

    if (ctx == NULL)
        return ssl;

    ssl = (WOLFSSL*) XMALLOC(sizeof(WOLFSSL), ctx->heap, DYNAMIC_TYPE_SSL);
    if (ssl)
        if ( (ret = InitSSL(ssl, ctx, 0)) < 0) {
            FreeSSL(ssl, ctx->heap);
            ssl = 0;
        }

    WOLFSSL_LEAVE("SSL_new", ret);
    (void)ret;

    return ssl;
}


WOLFSSL_ABI
void wolfSSL_free(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("SSL_free");
    if (ssl)
        FreeSSL(ssl, ssl->ctx->heap);
    WOLFSSL_LEAVE("SSL_free", 0);
}


int wolfSSL_is_server(WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;
    return ssl->options.side == WOLFSSL_SERVER_END;
}

#ifdef HAVE_WRITE_DUP

/*
 * Release resources around WriteDup object
 *
 * ssl WOLFSSL object
 *
 * no return, destruction so make best attempt
*/
void FreeWriteDup(WOLFSSL* ssl)
{
    int doFree = 0;

    WOLFSSL_ENTER("FreeWriteDup");

    if (ssl->dupWrite) {
        if (wc_LockMutex(&ssl->dupWrite->dupMutex) == 0) {
            ssl->dupWrite->dupCount--;
            if (ssl->dupWrite->dupCount == 0) {
                doFree = 1;
            } else {
                WOLFSSL_MSG("WriteDup count not zero, no full free");
            }
            wc_UnLockMutex(&ssl->dupWrite->dupMutex);
        }
    }

    if (doFree) {
        WOLFSSL_MSG("Doing WriteDup full free, count to zero");
        wc_FreeMutex(&ssl->dupWrite->dupMutex);
        XFREE(ssl->dupWrite, ssl->heap, DYNAMIC_TYPE_WRITEDUP);
    }
}


/*
 * duplicate existing ssl members into dup needed for writing
 *
 * dup write only WOLFSSL
 * ssl existing WOLFSSL
 *
 * 0 on success
*/
static int DupSSL(WOLFSSL* dup, WOLFSSL* ssl)
{
    /* shared dupWrite setup */
    ssl->dupWrite = (WriteDup*)XMALLOC(sizeof(WriteDup), ssl->heap,
                                       DYNAMIC_TYPE_WRITEDUP);
    if (ssl->dupWrite == NULL) {
        return MEMORY_E;
    }
    XMEMSET(ssl->dupWrite, 0, sizeof(WriteDup));

    if (wc_InitMutex(&ssl->dupWrite->dupMutex) != 0) {
        XFREE(ssl->dupWrite, ssl->heap, DYNAMIC_TYPE_WRITEDUP);
        ssl->dupWrite = NULL;
        return BAD_MUTEX_E;
    }
    ssl->dupWrite->dupCount = 2;    /* both sides have a count to start */
    dup->dupWrite = ssl->dupWrite; /* each side uses */

    /* copy write parts over to dup writer */
    XMEMCPY(&dup->specs,   &ssl->specs,   sizeof(CipherSpecs));
    XMEMCPY(&dup->options, &ssl->options, sizeof(Options));
    XMEMCPY(&dup->keys,    &ssl->keys,    sizeof(Keys));
    XMEMCPY(&dup->encrypt, &ssl->encrypt, sizeof(Ciphers));
    XMEMCPY(&dup->version, &ssl->version, sizeof(ProtocolVersion));
    XMEMCPY(&dup->chVersion, &ssl->chVersion, sizeof(ProtocolVersion));

    /* dup side now owns encrypt/write ciphers */
    XMEMSET(&ssl->encrypt, 0, sizeof(Ciphers));

    dup->IOCB_WriteCtx = ssl->IOCB_WriteCtx;
    dup->CBIOSend = ssl->CBIOSend;
#ifdef OPENSSL_EXTRA
    dup->cbioFlag = ssl->cbioFlag;
#endif
    dup->wfd    = ssl->wfd;
    dup->wflags = ssl->wflags;
#ifndef WOLFSSL_AEAD_ONLY
    dup->hmac   = ssl->hmac;
#endif
#ifdef HAVE_TRUNCATED_HMAC
    dup->truncated_hmac = ssl->truncated_hmac;
#endif

    /* unique side dup setup */
    dup->dupSide = WRITE_DUP_SIDE;
    ssl->dupSide = READ_DUP_SIDE;

    return 0;
}


/*
 * duplicate a WOLFSSL object post handshake for writing only
 * turn existing object into read only.  Allows concurrent access from two
 * different threads.
 *
 * ssl existing WOLFSSL object
 *
 * return dup'd WOLFSSL object on success
*/
WOLFSSL* wolfSSL_write_dup(WOLFSSL* ssl)
{
    WOLFSSL* dup = NULL;
    int ret = 0;

    (void)ret;
    WOLFSSL_ENTER("wolfSSL_write_dup");

    if (ssl == NULL) {
        return ssl;
    }

    if (ssl->options.handShakeDone == 0) {
        WOLFSSL_MSG("wolfSSL_write_dup called before handshake complete");
        return NULL;
    }

    if (ssl->dupWrite) {
        WOLFSSL_MSG("wolfSSL_write_dup already called once");
        return NULL;
    }

    dup = (WOLFSSL*) XMALLOC(sizeof(WOLFSSL), ssl->ctx->heap, DYNAMIC_TYPE_SSL);
    if (dup) {
        if ( (ret = InitSSL(dup, ssl->ctx, 1)) < 0) {
            FreeSSL(dup, ssl->ctx->heap);
            dup = NULL;
        } else if ( (ret = DupSSL(dup, ssl)) < 0) {
            FreeSSL(dup, ssl->ctx->heap);
            dup = NULL;
        }
    }

    WOLFSSL_LEAVE("wolfSSL_write_dup", ret);

    return dup;
}


/*
 * Notify write dup side of fatal error or close notify
 *
 * ssl WOLFSSL object
 * err Notify err
 *
 * 0 on success
*/
int NotifyWriteSide(WOLFSSL* ssl, int err)
{
    int ret;

    WOLFSSL_ENTER("NotifyWriteSide");

    ret = wc_LockMutex(&ssl->dupWrite->dupMutex);
    if (ret == 0) {
        ssl->dupWrite->dupErr = err;
        ret = wc_UnLockMutex(&ssl->dupWrite->dupMutex);
    }

    return ret;
}


#endif /* HAVE_WRITE_DUP */


#ifdef HAVE_POLY1305
/* set if to use old poly 1 for yes 0 to use new poly */
int wolfSSL_use_old_poly(WOLFSSL* ssl, int value)
{
    (void)ssl;
    (void)value;

#ifndef WOLFSSL_NO_TLS12
    WOLFSSL_ENTER("SSL_use_old_poly");
    WOLFSSL_MSG("Warning SSL connection auto detects old/new and this function"
            "is depreciated");
    ssl->options.oldPoly = (word16)value;
    WOLFSSL_LEAVE("SSL_use_old_poly", 0);
#endif
    return 0;
}
#endif


WOLFSSL_ABI
int wolfSSL_set_fd(WOLFSSL* ssl, int fd)
{
    int ret;

    WOLFSSL_ENTER("SSL_set_fd");

    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }

    ret = wolfSSL_set_read_fd(ssl, fd);
    if (ret == WOLFSSL_SUCCESS) {
        ret = wolfSSL_set_write_fd(ssl, fd);
    }

    return ret;
}

#ifdef WOLFSSL_DTLS
int wolfSSL_set_dtls_fd_connected(WOLFSSL* ssl, int fd)
{
    int ret;

    WOLFSSL_ENTER("SSL_set_dtls_fd_connected");

    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }

    ret = wolfSSL_set_fd(ssl, fd);
    if (ret == WOLFSSL_SUCCESS)
        ssl->buffers.dtlsCtx.connected = 1;

    return ret;
}
#endif


int wolfSSL_set_read_fd(WOLFSSL* ssl, int fd)
{
    WOLFSSL_ENTER("SSL_set_read_fd");

    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }

    ssl->rfd = fd;      /* not used directly to allow IO callbacks */
    ssl->IOCB_ReadCtx  = &ssl->rfd;

    #ifdef WOLFSSL_DTLS
        ssl->buffers.dtlsCtx.connected = 0;
        if (ssl->options.dtls) {
            ssl->IOCB_ReadCtx = &ssl->buffers.dtlsCtx;
            ssl->buffers.dtlsCtx.rfd = fd;
        }
    #endif

    WOLFSSL_LEAVE("SSL_set_read_fd", WOLFSSL_SUCCESS);
    return WOLFSSL_SUCCESS;
}


int wolfSSL_set_write_fd(WOLFSSL* ssl, int fd)
{
    WOLFSSL_ENTER("SSL_set_write_fd");

    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }

    ssl->wfd = fd;      /* not used directly to allow IO callbacks */
    ssl->IOCB_WriteCtx  = &ssl->wfd;

    #ifdef WOLFSSL_DTLS
        ssl->buffers.dtlsCtx.connected = 0;
        if (ssl->options.dtls) {
            ssl->IOCB_WriteCtx = &ssl->buffers.dtlsCtx;
            ssl->buffers.dtlsCtx.wfd = fd;
        }
    #endif

    WOLFSSL_LEAVE("SSL_set_write_fd", WOLFSSL_SUCCESS);
    return WOLFSSL_SUCCESS;
}


/**
  * Get the name of cipher at priority level passed in.
  */
char* wolfSSL_get_cipher_list(int priority)
{
    const CipherSuiteInfo* ciphers = GetCipherNames();

    if (priority >= GetCipherNamesSize() || priority < 0) {
        return 0;
    }

    return (char*)ciphers[priority].name;
}


/**
  * Get the name of cipher at priority level passed in.
  */
char* wolfSSL_get_cipher_list_ex(WOLFSSL* ssl, int priority)
{

    if (ssl == NULL) {
        return NULL;
    }
    else {
        const char* cipher;

        if ((cipher = wolfSSL_get_cipher_name_internal(ssl)) != NULL) {
            if (priority == 0) {
                return (char*)cipher;
            }
            else {
                return NULL;
            }
        }
        else {
            return wolfSSL_get_cipher_list(priority);
        }
    }
}


int wolfSSL_get_ciphers(char* buf, int len)
{
    const CipherSuiteInfo* ciphers = GetCipherNames();
    int ciphersSz = GetCipherNamesSize();
    int i;
    int cipherNameSz;

    if (buf == NULL || len <= 0)
        return BAD_FUNC_ARG;

    /* Add each member to the buffer delimited by a : */
    for (i = 0; i < ciphersSz; i++) {
        cipherNameSz = (int)XSTRLEN(ciphers[i].name);
        if (cipherNameSz + 1 < len) {
            XSTRNCPY(buf, ciphers[i].name, len);
            buf += cipherNameSz;

            if (i < ciphersSz - 1)
                *buf++ = ':';
            *buf = 0;

            len -= cipherNameSz + 1;
        }
        else
            return BUFFER_E;
    }
    return WOLFSSL_SUCCESS;
}


#ifndef NO_ERROR_STRINGS
/* places a list of all supported cipher suites in TLS_* format into "buf"
 * return WOLFSSL_SUCCESS on success */
int wolfSSL_get_ciphers_iana(char* buf, int len)
{
    const CipherSuiteInfo* ciphers = GetCipherNames();
    int ciphersSz = GetCipherNamesSize();
    int i;
    int cipherNameSz;

    if (buf == NULL || len <= 0)
        return BAD_FUNC_ARG;

    /* Add each member to the buffer delimited by a : */
    for (i = 0; i < ciphersSz; i++) {
#ifndef NO_CIPHER_SUITE_ALIASES
        if (ciphers[i].flags & WOLFSSL_CIPHER_SUITE_FLAG_NAMEALIAS)
            continue;
#endif
        cipherNameSz = (int)XSTRLEN(ciphers[i].name_iana);
        if (cipherNameSz + 1 < len) {
            XSTRNCPY(buf, ciphers[i].name_iana, len);
            buf += cipherNameSz;

            if (i < ciphersSz - 1)
                *buf++ = ':';
            *buf = 0;

            len -= cipherNameSz + 1;
        }
        else
            return BUFFER_E;
    }
    return WOLFSSL_SUCCESS;
}
#endif /* NO_ERROR_STRINGS */


const char* wolfSSL_get_shared_ciphers(WOLFSSL* ssl, char* buf, int len)
{
    const char* cipher;

    if (ssl == NULL)
        return NULL;

    cipher = wolfSSL_get_cipher_name_iana(ssl);
    len = min(len, (int)(XSTRLEN(cipher) + 1));
    XMEMCPY(buf, cipher, len);
    return buf;
}

int wolfSSL_get_fd(const WOLFSSL* ssl)
{
    int fd = -1;
    WOLFSSL_ENTER("SSL_get_fd");
    if (ssl) {
        fd = ssl->rfd;
    }
    WOLFSSL_LEAVE("SSL_get_fd", fd);
    return fd;
}


int wolfSSL_dtls(WOLFSSL* ssl)
{
    int dtlsOpt = 0;
    if (ssl)
        dtlsOpt = ssl->options.dtls;
    return dtlsOpt;
}

#if !defined(NO_CERTS)
/* Set whether mutual authentication is required for connections.
 * Server side only.
 *
 * ctx  The SSL/TLS CTX object.
 * req  1 to indicate required and 0 when not.
 * returns BAD_FUNC_ARG when ctx is NULL, SIDE_ERROR when not a server and
 * 0 on success.
 */
int wolfSSL_CTX_mutual_auth(WOLFSSL_CTX* ctx, int req)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;
    if (ctx->method->side == WOLFSSL_CLIENT_END)
        return SIDE_ERROR;

    ctx->mutualAuth = (byte)req;

    return 0;
}

/* Set whether mutual authentication is required for the connection.
 * Server side only.
 *
 * ssl  The SSL/TLS object.
 * req  1 to indicate required and 0 when not.
 * returns BAD_FUNC_ARG when ssl is NULL, or not using TLS v1.3,
 * SIDE_ERROR when not a client and 0 on success.
 */
int wolfSSL_mutual_auth(WOLFSSL* ssl, int req)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;
    if (ssl->options.side == WOLFSSL_SERVER_END)
        return SIDE_ERROR;

    ssl->options.mutualAuth = (word16)req;

    return 0;
}
#endif /* NO_CERTS */

#ifdef WOLFSSL_WOLFSENTRY_HOOKS

int wolfSSL_CTX_set_AcceptFilter(
    WOLFSSL_CTX *ctx,
    NetworkFilterCallback_t AcceptFilter,
    void *AcceptFilter_arg)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;
    ctx->AcceptFilter = AcceptFilter;
    ctx->AcceptFilter_arg = AcceptFilter_arg;
    return 0;
}

int wolfSSL_set_AcceptFilter(
    WOLFSSL *ssl,
    NetworkFilterCallback_t AcceptFilter,
    void *AcceptFilter_arg)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;
    ssl->AcceptFilter = AcceptFilter;
    ssl->AcceptFilter_arg = AcceptFilter_arg;
    return 0;
}

int wolfSSL_CTX_set_ConnectFilter(
    WOLFSSL_CTX *ctx,
    NetworkFilterCallback_t ConnectFilter,
    void *ConnectFilter_arg)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;
    ctx->ConnectFilter = ConnectFilter;
    ctx->ConnectFilter_arg = ConnectFilter_arg;
    return 0;
}

int wolfSSL_set_ConnectFilter(
    WOLFSSL *ssl,
    NetworkFilterCallback_t ConnectFilter,
    void *ConnectFilter_arg)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;
    ssl->ConnectFilter = ConnectFilter;
    ssl->ConnectFilter_arg = ConnectFilter_arg;
    return 0;
}

#endif /* WOLFSSL_WOLFSENTRY_HOOKS */

#ifndef WOLFSSL_LEANPSK
#if defined(WOLFSSL_DTLS) && defined(XINET_PTON) && \
    !defined(WOLFSSL_NO_SOCK) && defined(HAVE_SOCKADDR)
void* wolfSSL_dtls_create_peer(int port, char* ip)
{
    SOCKADDR_IN *addr;
    addr = (SOCKADDR_IN*)XMALLOC(sizeof(*addr), NULL,
            DYNAMIC_TYPE_SOCKADDR);
    if (addr == NULL) {
        return NULL;
    }

    addr->sin_family = AF_INET;
    addr->sin_port = XHTONS((word16)port);
    if (XINET_PTON(AF_INET, ip, &addr->sin_addr) < 1) {
        XFREE(addr, NULL, DYNAMIC_TYPE_SOCKADDR);
        return NULL;
    }

    return addr;
}

int wolfSSL_dtls_free_peer(void* addr)
{
    XFREE(addr, NULL, DYNAMIC_TYPE_SOCKADDR);
    return WOLFSSL_SUCCESS;
}
#endif

int wolfSSL_dtls_set_peer(WOLFSSL* ssl, void* peer, unsigned int peerSz)
{
#ifdef WOLFSSL_DTLS
    void* sa;

    if (ssl == NULL)
        return WOLFSSL_FAILURE;

    if (peer == NULL || peerSz == 0) {
        if (ssl->buffers.dtlsCtx.peer.sa != NULL)
            XFREE(ssl->buffers.dtlsCtx.peer.sa,ssl->heap,DYNAMIC_TYPE_SOCKADDR);
        ssl->buffers.dtlsCtx.peer.sa = NULL;
        ssl->buffers.dtlsCtx.peer.sz = 0;
        ssl->buffers.dtlsCtx.peer.bufSz = 0;
        ssl->buffers.dtlsCtx.userSet = 0;
        return WOLFSSL_SUCCESS;
    }

    sa = (void*)XMALLOC(peerSz, ssl->heap, DYNAMIC_TYPE_SOCKADDR);
    if (sa != NULL) {
        if (ssl->buffers.dtlsCtx.peer.sa != NULL) {
            XFREE(ssl->buffers.dtlsCtx.peer.sa,ssl->heap,DYNAMIC_TYPE_SOCKADDR);
            ssl->buffers.dtlsCtx.peer.sa = NULL;
        }
        XMEMCPY(sa, peer, peerSz);
        ssl->buffers.dtlsCtx.peer.sa = sa;
        ssl->buffers.dtlsCtx.peer.sz = peerSz;
        ssl->buffers.dtlsCtx.peer.bufSz = peerSz;
        ssl->buffers.dtlsCtx.userSet = 1;
        return WOLFSSL_SUCCESS;
    }
    return WOLFSSL_FAILURE;
#else
    (void)ssl;
    (void)peer;
    (void)peerSz;
    return WOLFSSL_NOT_IMPLEMENTED;
#endif
}

int wolfSSL_dtls_get_peer(WOLFSSL* ssl, void* peer, unsigned int* peerSz)
{
#ifdef WOLFSSL_DTLS
    if (ssl == NULL) {
        return WOLFSSL_FAILURE;
    }

    if (peer != NULL && peerSz != NULL
            && *peerSz >= ssl->buffers.dtlsCtx.peer.sz
            && ssl->buffers.dtlsCtx.peer.sa != NULL) {
        *peerSz = ssl->buffers.dtlsCtx.peer.sz;
        XMEMCPY(peer, ssl->buffers.dtlsCtx.peer.sa, *peerSz);
        return WOLFSSL_SUCCESS;
    }
    return WOLFSSL_FAILURE;
#else
    (void)ssl;
    (void)peer;
    (void)peerSz;
    return WOLFSSL_NOT_IMPLEMENTED;
#endif
}


#if defined(WOLFSSL_SCTP) && defined(WOLFSSL_DTLS)

int wolfSSL_CTX_dtls_set_sctp(WOLFSSL_CTX* ctx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_dtls_set_sctp()");

    if (ctx == NULL)
        return BAD_FUNC_ARG;

    ctx->dtlsSctp = 1;
    return WOLFSSL_SUCCESS;
}


int wolfSSL_dtls_set_sctp(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_dtls_set_sctp()");

    if (ssl == NULL)
        return BAD_FUNC_ARG;

    ssl->options.dtlsSctp = 1;
    return WOLFSSL_SUCCESS;
}

#endif /* WOLFSSL_DTLS && WOLFSSL_SCTP */

#if (defined(WOLFSSL_SCTP) || defined(WOLFSSL_DTLS_MTU)) && \
                                                           defined(WOLFSSL_DTLS)

int wolfSSL_CTX_dtls_set_mtu(WOLFSSL_CTX* ctx, word16 newMtu)
{
    if (ctx == NULL || newMtu > MAX_RECORD_SIZE)
        return BAD_FUNC_ARG;

    ctx->dtlsMtuSz = newMtu;
    return WOLFSSL_SUCCESS;
}


int wolfSSL_dtls_set_mtu(WOLFSSL* ssl, word16 newMtu)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    if (newMtu > MAX_RECORD_SIZE) {
        ssl->error = BAD_FUNC_ARG;
        return WOLFSSL_FAILURE;
    }

    ssl->dtlsMtuSz = newMtu;
    return WOLFSSL_SUCCESS;
}

#endif /* WOLFSSL_DTLS && (WOLFSSL_SCTP || WOLFSSL_DTLS_MTU) */

#ifdef WOLFSSL_SRTP

static const WOLFSSL_SRTP_PROTECTION_PROFILE gSrtpProfiles[] = {
    /* AES CCM 128, Salt:112-bits, Auth HMAC-SHA1 Tag: 80-bits
     * (master_key:128bits + master_salt:112bits) * 2 = 480 bits (60) */
    {"SRTP_AES128_CM_SHA1_80", SRTP_AES128_CM_SHA1_80, (((128 + 112) * 2) / 8) },
    /* AES CCM 128, Salt:112-bits, Auth HMAC-SHA1 Tag: 32-bits
     * (master_key:128bits + master_salt:112bits) * 2 = 480 bits (60) */
    {"SRTP_AES128_CM_SHA1_32", SRTP_AES128_CM_SHA1_32, (((128 + 112) * 2) / 8) },
    /* NULL Cipher, Salt:112-bits, Auth HMAC-SHA1 Tag 80-bits */
    {"SRTP_NULL_SHA1_80", SRTP_NULL_SHA1_80, ((112 * 2) / 8)},
    /* NULL Cipher, Salt:112-bits, Auth HMAC-SHA1 Tag 32-bits */
    {"SRTP_NULL_SHA1_32", SRTP_NULL_SHA1_32, ((112 * 2) / 8)},
    /* AES GCM 128, Salt: 96-bits, Auth GCM Tag 128-bits
     * (master_key:128bits + master_salt:96bits) * 2 = 448 bits (56) */
    {"SRTP_AEAD_AES_128_GCM", SRTP_AEAD_AES_128_GCM, (((128 + 96) * 2) / 8) },
    /* AES GCM 256, Salt: 96-bits, Auth GCM Tag 128-bits
     * (master_key:256bits + master_salt:96bits) * 2 = 704 bits (88) */
    {"SRTP_AEAD_AES_256_GCM", SRTP_AEAD_AES_256_GCM, (((256 + 96) * 2) / 8) },
};

static const WOLFSSL_SRTP_PROTECTION_PROFILE* DtlsSrtpFindProfile(
    const char* profile_str, word32 profile_str_len, unsigned long id)
{
    int i;
    const WOLFSSL_SRTP_PROTECTION_PROFILE* profile = NULL;
    for (i=0;
         i<(int)(sizeof(gSrtpProfiles)/sizeof(WOLFSSL_SRTP_PROTECTION_PROFILE));
         i++) {
        if (profile_str != NULL) {
            word32 srtp_profile_len = (word32)XSTRLEN(gSrtpProfiles[i].name);
            if (srtp_profile_len == profile_str_len &&
                XMEMCMP(gSrtpProfiles[i].name, profile_str, profile_str_len)
                                                                         == 0) {
                profile = &gSrtpProfiles[i];
                break;
            }
        }
        else if (id != 0 && gSrtpProfiles[i].id == id) {
            profile = &gSrtpProfiles[i];
            break;
        }
    }
    return profile;
}

/* profile_str: accepts ":" colon separated list of SRTP profiles */
static int DtlsSrtpSelProfiles(word16* id, const char* profile_str)
{
    const WOLFSSL_SRTP_PROTECTION_PROFILE* profile;
    const char *current, *next = NULL;
    word32 length = 0, current_length;

    *id = 0; /* reset destination ID's */

    if (profile_str == NULL) {
        return WOLFSSL_FAILURE;
    }

    /* loop on end of line or colon ":" */
    next = profile_str;
    length = (word32)XSTRLEN(profile_str);
    do {
        current = next;
        next = XSTRSTR(current, ":");
        current_length = (!next) ? (word32)XSTRLEN(current)
                                 : (word32)(next - current);
        if (current_length < length)
            length = current_length;
        profile = DtlsSrtpFindProfile(current, current_length, 0);
        if (profile != NULL) {
            *id |= (1 << profile->id); /* selected bit based on ID */
        }
    } while (next != NULL && next++); /* ++ needed to skip ':' */
    return WOLFSSL_SUCCESS;
}

int wolfSSL_CTX_set_tlsext_use_srtp(WOLFSSL_CTX* ctx, const char* profile_str)
{
    int ret = WOLFSSL_FAILURE;
    if (ctx != NULL) {
        ret = DtlsSrtpSelProfiles(&ctx->dtlsSrtpProfiles, profile_str);
    }
    return ret;
}
int wolfSSL_set_tlsext_use_srtp(WOLFSSL* ssl, const char* profile_str)
{
    int ret = WOLFSSL_FAILURE;
    if (ssl != NULL) {
        ret = DtlsSrtpSelProfiles(&ssl->dtlsSrtpProfiles, profile_str);
    }
    return ret;
}

const WOLFSSL_SRTP_PROTECTION_PROFILE* wolfSSL_get_selected_srtp_profile(
    WOLFSSL* ssl)
{
    const WOLFSSL_SRTP_PROTECTION_PROFILE* profile = NULL;
    if (ssl) {
        profile = DtlsSrtpFindProfile(NULL, 0, ssl->dtlsSrtpId);
    }
    return profile;
}
#ifndef NO_WOLFSSL_STUB
WOLF_STACK_OF(WOLFSSL_SRTP_PROTECTION_PROFILE)* wolfSSL_get_srtp_profiles(
    WOLFSSL* ssl)
{
    /* Not yet implemented - should return list of available SRTP profiles
     * ssl->dtlsSrtpProfiles */
    (void)ssl;
    return NULL;
}
#endif

#define DTLS_SRTP_KEYING_MATERIAL_LABEL "EXTRACTOR-dtls_srtp"

int wolfSSL_export_dtls_srtp_keying_material(WOLFSSL* ssl,
    unsigned char* out, size_t* olen)
{
    const WOLFSSL_SRTP_PROTECTION_PROFILE* profile = NULL;

    if (ssl == NULL || olen == NULL) {
        return BAD_FUNC_ARG;
    }

    profile = DtlsSrtpFindProfile(NULL, 0, ssl->dtlsSrtpId);
    if (profile == NULL) {
        WOLFSSL_MSG("Not using DTLS SRTP");
        return EXT_MISSING;
    }
    if (out == NULL) {
        *olen = profile->kdfBits;
        return LENGTH_ONLY_E;
    }

    if (*olen < (size_t)profile->kdfBits) {
        return BUFFER_E;
    }

    return wolfSSL_export_keying_material(ssl, out, profile->kdfBits,
            DTLS_SRTP_KEYING_MATERIAL_LABEL,
            XSTR_SIZEOF(DTLS_SRTP_KEYING_MATERIAL_LABEL), NULL, 0, 0);
}

#endif /* WOLFSSL_SRTP */


#ifdef WOLFSSL_DTLS_DROP_STATS

int wolfSSL_dtls_get_drop_stats(WOLFSSL* ssl,
                                word32* macDropCount, word32* replayDropCount)
{
    int ret;

    WOLFSSL_ENTER("wolfSSL_dtls_get_drop_stats()");

    if (ssl == NULL)
        ret = BAD_FUNC_ARG;
    else {
        ret = WOLFSSL_SUCCESS;
        if (macDropCount != NULL)
            *macDropCount = ssl->macDropCount;
        if (replayDropCount != NULL)
            *replayDropCount = ssl->replayDropCount;
    }

    WOLFSSL_LEAVE("wolfSSL_dtls_get_drop_stats()", ret);
    return ret;
}

#endif /* WOLFSSL_DTLS_DROP_STATS */


#if defined(WOLFSSL_MULTICAST)

int wolfSSL_CTX_mcast_set_member_id(WOLFSSL_CTX* ctx, word16 id)
{
    int ret = 0;

    WOLFSSL_ENTER("wolfSSL_CTX_mcast_set_member_id()");

    if (ctx == NULL || id > 255)
        ret = BAD_FUNC_ARG;

    if (ret == 0) {
        ctx->haveEMS = 0;
        ctx->haveMcast = 1;
        ctx->mcastID = (byte)id;
#ifndef WOLFSSL_USER_IO
        ctx->CBIORecv = EmbedReceiveFromMcast;
#endif /* WOLFSSL_USER_IO */

        ret = WOLFSSL_SUCCESS;
    }
    WOLFSSL_LEAVE("wolfSSL_CTX_mcast_set_member_id()", ret);
    return ret;
}

int wolfSSL_mcast_get_max_peers(void)
{
    return WOLFSSL_MULTICAST_PEERS;
}

#ifdef WOLFSSL_DTLS
static WC_INLINE word32 UpdateHighwaterMark(word32 cur, word32 first,
                                         word32 second, word32 high)
{
    word32 newCur = 0;

    if (cur < first)
        newCur = first;
    else if (cur < second)
        newCur = second;
    else if (cur < high)
        newCur = high;

    return newCur;
}
#endif /* WOLFSSL_DTLS */


int wolfSSL_set_secret(WOLFSSL* ssl, word16 epoch,
                       const byte* preMasterSecret, word32 preMasterSz,
                       const byte* clientRandom, const byte* serverRandom,
                       const byte* suite)
{
    int ret = 0;

    WOLFSSL_ENTER("wolfSSL_set_secret()");

    if (ssl == NULL || preMasterSecret == NULL ||
        preMasterSz == 0 || preMasterSz > ENCRYPT_LEN ||
        clientRandom == NULL || serverRandom == NULL || suite == NULL) {

        ret = BAD_FUNC_ARG;
    }

    if (ret == 0 && ssl->arrays->preMasterSecret == NULL) {
        ssl->arrays->preMasterSz = ENCRYPT_LEN;
        ssl->arrays->preMasterSecret = (byte*)XMALLOC(ENCRYPT_LEN, ssl->heap,
            DYNAMIC_TYPE_SECRET);
        if (ssl->arrays->preMasterSecret == NULL) {
            ret = MEMORY_E;
        }
    }

    if (ret == 0) {
        XMEMCPY(ssl->arrays->preMasterSecret, preMasterSecret, preMasterSz);
        XMEMSET(ssl->arrays->preMasterSecret + preMasterSz, 0, ENCRYPT_LEN - preMasterSz);
        ssl->arrays->preMasterSz = preMasterSz;
        XMEMCPY(ssl->arrays->clientRandom, clientRandom, RAN_LEN);
        XMEMCPY(ssl->arrays->serverRandom, serverRandom, RAN_LEN);
        ssl->options.cipherSuite0 = suite[0];
        ssl->options.cipherSuite = suite[1];

        ret = SetCipherSpecs(ssl);
    }

    if (ret == 0)
        ret = MakeTlsMasterSecret(ssl);

    if (ret == 0) {
        ssl->keys.encryptionOn = 1;
        ret = SetKeysSide(ssl, ENCRYPT_AND_DECRYPT_SIDE);
    }

    if (ret == 0) {
        if (ssl->options.dtls) {
        #ifdef WOLFSSL_DTLS
            WOLFSSL_DTLS_PEERSEQ* peerSeq;
            int i;

            ssl->keys.dtls_epoch = epoch;
            for (i = 0, peerSeq = ssl->keys.peerSeq;
                 i < WOLFSSL_DTLS_PEERSEQ_SZ;
                 i++, peerSeq++) {

                peerSeq->nextEpoch = epoch;
                peerSeq->prevSeq_lo = peerSeq->nextSeq_lo;
                peerSeq->prevSeq_hi = peerSeq->nextSeq_hi;
                peerSeq->nextSeq_lo = 0;
                peerSeq->nextSeq_hi = 0;
                XMEMCPY(peerSeq->prevWindow, peerSeq->window, DTLS_SEQ_SZ);
                XMEMSET(peerSeq->window, 0, DTLS_SEQ_SZ);
                peerSeq->highwaterMark = UpdateHighwaterMark(0,
                        ssl->ctx->mcastFirstSeq,
                        ssl->ctx->mcastSecondSeq,
                        ssl->ctx->mcastMaxSeq);
            }
        #else
            (void)epoch;
        #endif
        }
        FreeHandshakeResources(ssl);
        ret = WOLFSSL_SUCCESS;
    }
    else {
        if (ssl)
            ssl->error = ret;
        ret = WOLFSSL_FATAL_ERROR;
    }
    WOLFSSL_LEAVE("wolfSSL_set_secret()", ret);
    return ret;
}


#ifdef WOLFSSL_DTLS

int wolfSSL_mcast_peer_add(WOLFSSL* ssl, word16 peerId, int sub)
{
    WOLFSSL_DTLS_PEERSEQ* p = NULL;
    int ret = WOLFSSL_SUCCESS;
    int i;

    WOLFSSL_ENTER("wolfSSL_mcast_peer_add()");
    if (ssl == NULL || peerId > 255)
        return BAD_FUNC_ARG;

    if (!sub) {
        /* Make sure it isn't already present, while keeping the first
         * open spot. */
        for (i = 0; i < WOLFSSL_DTLS_PEERSEQ_SZ; i++) {
            if (ssl->keys.peerSeq[i].peerId == INVALID_PEER_ID)
                p = &ssl->keys.peerSeq[i];
            if (ssl->keys.peerSeq[i].peerId == peerId) {
                WOLFSSL_MSG("Peer ID already in multicast peer list.");
                p = NULL;
            }
        }

        if (p != NULL) {
            XMEMSET(p, 0, sizeof(WOLFSSL_DTLS_PEERSEQ));
            p->peerId = peerId;
            p->highwaterMark = UpdateHighwaterMark(0,
                ssl->ctx->mcastFirstSeq,
                ssl->ctx->mcastSecondSeq,
                ssl->ctx->mcastMaxSeq);
        }
        else {
            WOLFSSL_MSG("No room in peer list.");
            ret = -1;
        }
    }
    else {
        for (i = 0; i < WOLFSSL_DTLS_PEERSEQ_SZ; i++) {
            if (ssl->keys.peerSeq[i].peerId == peerId)
                p = &ssl->keys.peerSeq[i];
        }

        if (p != NULL) {
            p->peerId = INVALID_PEER_ID;
        }
        else {
            WOLFSSL_MSG("Peer not found in list.");
        }
    }

    WOLFSSL_LEAVE("wolfSSL_mcast_peer_add()", ret);
    return ret;
}


/* If peerId is in the list of peers and its last sequence number is non-zero,
 * return 1, otherwise return 0. */
int wolfSSL_mcast_peer_known(WOLFSSL* ssl, unsigned short peerId)
{
    int known = 0;
    int i;

    WOLFSSL_ENTER("wolfSSL_mcast_peer_known()");

    if (ssl == NULL || peerId > 255) {
        return BAD_FUNC_ARG;
    }

    for (i = 0; i < WOLFSSL_DTLS_PEERSEQ_SZ; i++) {
        if (ssl->keys.peerSeq[i].peerId == peerId) {
            if (ssl->keys.peerSeq[i].nextSeq_hi ||
                ssl->keys.peerSeq[i].nextSeq_lo) {

                known = 1;
            }
            break;
        }
    }

    WOLFSSL_LEAVE("wolfSSL_mcast_peer_known()", known);
    return known;
}


int wolfSSL_CTX_mcast_set_highwater_cb(WOLFSSL_CTX* ctx, word32 maxSeq,
                                       word32 first, word32 second,
                                       CallbackMcastHighwater cb)
{
    if (ctx == NULL || (second && first > second) ||
        first > maxSeq || second > maxSeq || cb == NULL) {

        return BAD_FUNC_ARG;
    }

    ctx->mcastHwCb = cb;
    ctx->mcastFirstSeq = first;
    ctx->mcastSecondSeq = second;
    ctx->mcastMaxSeq = maxSeq;

    return WOLFSSL_SUCCESS;
}


int wolfSSL_mcast_set_highwater_ctx(WOLFSSL* ssl, void* ctx)
{
    if (ssl == NULL || ctx == NULL)
        return BAD_FUNC_ARG;

    ssl->mcastHwCbCtx = ctx;

    return WOLFSSL_SUCCESS;
}

#endif /* WOLFSSL_DTLS */

#endif /* WOLFSSL_MULTICAST */


#endif /* WOLFSSL_LEANPSK */


/* return underlying connect or accept, WOLFSSL_SUCCESS on ok */
int wolfSSL_negotiate(WOLFSSL* ssl)
{
    int err = WOLFSSL_FATAL_ERROR;

    WOLFSSL_ENTER("wolfSSL_negotiate");

    if (ssl == NULL)
        return WOLFSSL_FATAL_ERROR;

#ifndef NO_WOLFSSL_SERVER
    if (ssl->options.side == WOLFSSL_SERVER_END) {
#ifdef WOLFSSL_TLS13
        if (IsAtLeastTLSv1_3(ssl->version))
            err = wolfSSL_accept_TLSv13(ssl);
        else
#endif
            err = wolfSSL_accept(ssl);
    }
#endif

#ifndef NO_WOLFSSL_CLIENT
    if (ssl->options.side == WOLFSSL_CLIENT_END) {
#ifdef WOLFSSL_TLS13
        if (IsAtLeastTLSv1_3(ssl->version))
            err = wolfSSL_connect_TLSv13(ssl);
        else
#endif
            err = wolfSSL_connect(ssl);
    }
#endif

    (void)ssl;

    WOLFSSL_LEAVE("wolfSSL_negotiate", err);

    return err;
}


WOLFSSL_ABI
WC_RNG* wolfSSL_GetRNG(WOLFSSL* ssl)
{
    if (ssl) {
        return ssl->rng;
    }

    return NULL;
}


#ifndef WOLFSSL_LEANPSK
/* object size based on build */
int wolfSSL_GetObjectSize(void)
{
#ifdef SHOW_SIZES
    printf("sizeof suites           = %lu\n", (unsigned long)sizeof(Suites));
    printf("sizeof ciphers(2)       = %lu\n", (unsigned long)sizeof(Ciphers));
#ifndef NO_RC4
    printf("\tsizeof arc4         = %lu\n", (unsigned long)sizeof(Arc4));
#endif
    printf("\tsizeof aes          = %lu\n", (unsigned long)sizeof(Aes));
#ifndef NO_DES3
    printf("\tsizeof des3         = %lu\n", (unsigned long)sizeof(Des3));
#endif
#ifdef HAVE_CHACHA
    printf("\tsizeof chacha       = %lu\n", (unsigned long)sizeof(ChaCha));
#endif
    printf("sizeof cipher specs     = %lu\n", (unsigned long)sizeof(CipherSpecs));
    printf("sizeof keys             = %lu\n", (unsigned long)sizeof(Keys));
    printf("sizeof Hashes(2)        = %lu\n", (unsigned long)sizeof(Hashes));
#ifndef NO_MD5
    printf("\tsizeof MD5          = %lu\n", (unsigned long)sizeof(wc_Md5));
#endif
#ifndef NO_SHA
    printf("\tsizeof SHA          = %lu\n", (unsigned long)sizeof(wc_Sha));
#endif
#ifdef WOLFSSL_SHA224
    printf("\tsizeof SHA224       = %lu\n", (unsigned long)sizeof(wc_Sha224));
#endif
#ifndef NO_SHA256
    printf("\tsizeof SHA256       = %lu\n", (unsigned long)sizeof(wc_Sha256));
#endif
#ifdef WOLFSSL_SHA384
    printf("\tsizeof SHA384       = %lu\n", (unsigned long)sizeof(wc_Sha384));
#endif
#ifdef WOLFSSL_SHA384
    printf("\tsizeof SHA512       = %lu\n", (unsigned long)sizeof(wc_Sha512));
#endif
    printf("sizeof Buffers          = %lu\n", (unsigned long)sizeof(Buffers));
    printf("sizeof Options          = %lu\n", (unsigned long)sizeof(Options));
    printf("sizeof Arrays           = %lu\n", (unsigned long)sizeof(Arrays));
#ifndef NO_RSA
    printf("sizeof RsaKey           = %lu\n", (unsigned long)sizeof(RsaKey));
#endif
#ifdef HAVE_ECC
    printf("sizeof ecc_key          = %lu\n", (unsigned long)sizeof(ecc_key));
#endif
    printf("sizeof WOLFSSL_CIPHER    = %lu\n", (unsigned long)sizeof(WOLFSSL_CIPHER));
    printf("sizeof WOLFSSL_SESSION   = %lu\n", (unsigned long)sizeof(WOLFSSL_SESSION));
    printf("sizeof WOLFSSL           = %lu\n", (unsigned long)sizeof(WOLFSSL));
    printf("sizeof WOLFSSL_CTX       = %lu\n", (unsigned long)sizeof(WOLFSSL_CTX));
#endif

    return sizeof(WOLFSSL);
}

int wolfSSL_CTX_GetObjectSize(void)
{
    return sizeof(WOLFSSL_CTX);
}

int wolfSSL_METHOD_GetObjectSize(void)
{
    return sizeof(WOLFSSL_METHOD);
}
#endif


#ifdef WOLFSSL_STATIC_MEMORY

int wolfSSL_CTX_load_static_memory(WOLFSSL_CTX** ctx, wolfSSL_method_func method,
                                   unsigned char* buf, unsigned int sz,
                                   int flag, int maxSz)
{
    WOLFSSL_HEAP*      heap;
    WOLFSSL_HEAP_HINT* hint;
    word32 idx = 0;

    if (ctx == NULL || buf == NULL) {
        return BAD_FUNC_ARG;
    }

    if (*ctx == NULL && method == NULL) {
        return BAD_FUNC_ARG;
    }

    if (*ctx == NULL || (*ctx)->heap == NULL) {
        if (sizeof(WOLFSSL_HEAP) + sizeof(WOLFSSL_HEAP_HINT) > sz - idx) {
            return BUFFER_E; /* not enough memory for structures */
        }
        heap = (WOLFSSL_HEAP*)buf;
        idx += sizeof(WOLFSSL_HEAP);
        if (wolfSSL_init_memory_heap(heap) != 0) {
            return WOLFSSL_FAILURE;
        }
        hint = (WOLFSSL_HEAP_HINT*)(buf + idx);
        idx += sizeof(WOLFSSL_HEAP_HINT);
        XMEMSET(hint, 0, sizeof(WOLFSSL_HEAP_HINT));
        hint->memory = heap;

        if (*ctx && (*ctx)->heap == NULL) {
            (*ctx)->heap = (void*)hint;
        }
    }
    else {
#ifdef WOLFSSL_HEAP_TEST
        /* do not load in memory if test has been set */
        if ((*ctx)->heap == (void*)WOLFSSL_HEAP_TEST) {
            return WOLFSSL_SUCCESS;
        }
#endif
        hint = (WOLFSSL_HEAP_HINT*)((*ctx)->heap);
        heap = hint->memory;
    }

    if (wolfSSL_load_static_memory(buf + idx, sz - idx, flag, heap) != 1) {
        WOLFSSL_MSG("Error partitioning memory");
        return WOLFSSL_FAILURE;
    }

    /* create ctx if needed */
    if (*ctx == NULL) {
        *ctx = wolfSSL_CTX_new_ex(method(hint), hint);
        if (*ctx == NULL) {
            WOLFSSL_MSG("Error creating ctx");
            return WOLFSSL_FAILURE;
        }
    }

    /* determine what max applies too */
    if (flag & WOLFMEM_IO_POOL || flag & WOLFMEM_IO_POOL_FIXED) {
        heap->maxIO = maxSz;
    }
    else { /* general memory used in handshakes */
        heap->maxHa = maxSz;
    }

    heap->flag |= flag;

    (void)maxSz;
    (void)method;

    return WOLFSSL_SUCCESS;
}


int wolfSSL_is_static_memory(WOLFSSL* ssl, WOLFSSL_MEM_CONN_STATS* mem_stats)
{
    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }
    WOLFSSL_ENTER("wolfSSL_is_static_memory");

    /* fill out statistics if wanted and WOLFMEM_TRACK_STATS flag */
    if (mem_stats != NULL && ssl->heap != NULL) {
        WOLFSSL_HEAP_HINT* hint = ((WOLFSSL_HEAP_HINT*)(ssl->heap));
        WOLFSSL_HEAP* heap      = hint->memory;
        if (heap->flag & WOLFMEM_TRACK_STATS && hint->stats != NULL) {
            XMEMCPY(mem_stats, hint->stats, sizeof(WOLFSSL_MEM_CONN_STATS));
        }
    }

    return (ssl->heap) ? 1 : 0;
}


int wolfSSL_CTX_is_static_memory(WOLFSSL_CTX* ctx, WOLFSSL_MEM_STATS* mem_stats)
{
    if (ctx == NULL) {
        return BAD_FUNC_ARG;
    }
    WOLFSSL_ENTER("wolfSSL_CTX_is_static_memory");

    /* fill out statistics if wanted */
    if (mem_stats != NULL && ctx->heap != NULL) {
        WOLFSSL_HEAP* heap = ((WOLFSSL_HEAP_HINT*)(ctx->heap))->memory;
        if (wolfSSL_GetMemStats(heap, mem_stats) != 1) {
            return MEMORY_E;
        }
    }

    return (ctx->heap) ? 1 : 0;
}

#endif /* WOLFSSL_STATIC_MEMORY */


/* return max record layer size plaintext input size */
int wolfSSL_GetMaxOutputSize(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_GetMaxOutputSize");

    if (ssl == NULL)
        return BAD_FUNC_ARG;

    if (ssl->options.handShakeState != HANDSHAKE_DONE) {
        WOLFSSL_MSG("Handshake not complete yet");
        return BAD_FUNC_ARG;
    }

    return wolfSSL_GetMaxFragSize(ssl, OUTPUT_RECORD_SIZE);
}


/* return record layer size of plaintext input size */
int wolfSSL_GetOutputSize(WOLFSSL* ssl, int inSz)
{
    int maxSize;

    WOLFSSL_ENTER("wolfSSL_GetOutputSize");

    if (inSz < 0)
        return BAD_FUNC_ARG;

    maxSize = wolfSSL_GetMaxOutputSize(ssl);
    if (maxSize < 0)
        return maxSize;   /* error */
    if (inSz > maxSize)
        return INPUT_SIZE_E;

    return BuildMessage(ssl, NULL, 0, NULL, inSz, application_data, 0, 1, 0, CUR_ORDER);
}


#ifdef HAVE_ECC
int wolfSSL_CTX_SetMinEccKey_Sz(WOLFSSL_CTX* ctx, short keySz)
{
    if (ctx == NULL || keySz < 0 || keySz % 8 != 0) {
        WOLFSSL_MSG("Key size must be divisible by 8 or ctx was null");
        return BAD_FUNC_ARG;
    }

    ctx->minEccKeySz     = keySz / 8;
#ifndef NO_CERTS
    ctx->cm->minEccKeySz = keySz / 8;
#endif
    return WOLFSSL_SUCCESS;
}


int wolfSSL_SetMinEccKey_Sz(WOLFSSL* ssl, short keySz)
{
    if (ssl == NULL || keySz < 0 || keySz % 8 != 0) {
        WOLFSSL_MSG("Key size must be divisible by 8 or ssl was null");
        return BAD_FUNC_ARG;
    }

    ssl->options.minEccKeySz = keySz / 8;
    return WOLFSSL_SUCCESS;
}

#endif /* HAVE_ECC */

#ifndef NO_RSA
int wolfSSL_CTX_SetMinRsaKey_Sz(WOLFSSL_CTX* ctx, short keySz)
{
    if (ctx == NULL || keySz < 0 || keySz % 8 != 0) {
        WOLFSSL_MSG("Key size must be divisible by 8 or ctx was null");
        return BAD_FUNC_ARG;
    }

    ctx->minRsaKeySz     = keySz / 8;
    ctx->cm->minRsaKeySz = keySz / 8;
    return WOLFSSL_SUCCESS;
}


int wolfSSL_SetMinRsaKey_Sz(WOLFSSL* ssl, short keySz)
{
    if (ssl == NULL || keySz < 0 || keySz % 8 != 0) {
        WOLFSSL_MSG("Key size must be divisible by 8 or ssl was null");
        return BAD_FUNC_ARG;
    }

    ssl->options.minRsaKeySz = keySz / 8;
    return WOLFSSL_SUCCESS;
}
#endif /* !NO_RSA */

#ifndef NO_DH

#ifdef OPENSSL_EXTRA
long wolfSSL_set_tmp_dh(WOLFSSL *ssl, WOLFSSL_DH *dh)
{
    int pSz, gSz;
    byte *p, *g;
    int ret = 0;

    WOLFSSL_ENTER("wolfSSL_set_tmp_dh");

    if (!ssl || !dh)
        return BAD_FUNC_ARG;

    /* Get needed size for p and g */
    pSz = wolfSSL_BN_bn2bin(dh->p, NULL);
    gSz = wolfSSL_BN_bn2bin(dh->g, NULL);

    if (pSz <= 0 || gSz <= 0)
        return -1;

    p = (byte*)XMALLOC(pSz, ssl->heap, DYNAMIC_TYPE_PUBLIC_KEY);
    if (!p)
        return MEMORY_E;

    g = (byte*)XMALLOC(gSz, ssl->heap, DYNAMIC_TYPE_PUBLIC_KEY);
    if (!g) {
        XFREE(p, ssl->heap, DYNAMIC_TYPE_PUBLIC_KEY);
        return MEMORY_E;
    }

    pSz = wolfSSL_BN_bn2bin(dh->p, p);
    gSz = wolfSSL_BN_bn2bin(dh->g, g);

    if (pSz >= 0 && gSz >= 0) /* Conversion successful */
        ret = wolfSSL_SetTmpDH(ssl, p, pSz, g, gSz);

    XFREE(p, ssl->heap, DYNAMIC_TYPE_PUBLIC_KEY);
    XFREE(g, ssl->heap, DYNAMIC_TYPE_PUBLIC_KEY);

    return pSz > 0 && gSz > 0 ? ret : -1;
}
#endif /* OPENSSL_EXTRA */

/* server Diffie-Hellman parameters, WOLFSSL_SUCCESS on ok */
int wolfSSL_SetTmpDH(WOLFSSL* ssl, const unsigned char* p, int pSz,
                    const unsigned char* g, int gSz)
{
    WOLFSSL_ENTER("wolfSSL_SetTmpDH");

    if (ssl == NULL || p == NULL || g == NULL)
        return BAD_FUNC_ARG;

    if ((word16)pSz < ssl->options.minDhKeySz)
        return DH_KEY_SIZE_E;
    if ((word16)pSz > ssl->options.maxDhKeySz)
        return DH_KEY_SIZE_E;

    /* this function is for server only */
    if (ssl->options.side == WOLFSSL_CLIENT_END)
        return SIDE_ERROR;

    #if !defined(WOLFSSL_OLD_PRIME_CHECK) && !defined(HAVE_FIPS) && \
        !defined(HAVE_SELFTEST)
        ssl->options.dhKeyTested = 0;
        ssl->options.dhDoKeyTest = 1;
    #endif

    if (ssl->buffers.serverDH_P.buffer && ssl->buffers.weOwnDH) {
        XFREE(ssl->buffers.serverDH_P.buffer, ssl->heap, DYNAMIC_TYPE_PUBLIC_KEY);
        ssl->buffers.serverDH_P.buffer = NULL;
    }
    if (ssl->buffers.serverDH_G.buffer && ssl->buffers.weOwnDH) {
        XFREE(ssl->buffers.serverDH_G.buffer, ssl->heap, DYNAMIC_TYPE_PUBLIC_KEY);
        ssl->buffers.serverDH_G.buffer = NULL;
    }

    ssl->buffers.weOwnDH = 1;  /* SSL owns now */
    ssl->buffers.serverDH_P.buffer = (byte*)XMALLOC(pSz, ssl->heap,
                                                    DYNAMIC_TYPE_PUBLIC_KEY);
    if (ssl->buffers.serverDH_P.buffer == NULL)
            return MEMORY_E;

    ssl->buffers.serverDH_G.buffer = (byte*)XMALLOC(gSz, ssl->heap,
                                                    DYNAMIC_TYPE_PUBLIC_KEY);
    if (ssl->buffers.serverDH_G.buffer == NULL) {
        XFREE(ssl->buffers.serverDH_P.buffer, ssl->heap, DYNAMIC_TYPE_PUBLIC_KEY);
        ssl->buffers.serverDH_P.buffer = NULL;
        return MEMORY_E;
    }

    ssl->buffers.serverDH_P.length = pSz;
    ssl->buffers.serverDH_G.length = gSz;

    XMEMCPY(ssl->buffers.serverDH_P.buffer, p, pSz);
    XMEMCPY(ssl->buffers.serverDH_G.buffer, g, gSz);

    ssl->options.haveDH = 1;

    if (ssl->options.side != WOLFSSL_NEITHER_END) {
        word16 havePSK;
        word16 haveRSA;
        int    keySz   = 0;

    #ifndef NO_PSK
        havePSK = ssl->options.havePSK;
    #else
        havePSK = 0;
    #endif
    #ifdef NO_RSA
        haveRSA = 0;
    #else
        haveRSA = 1;
    #endif
    #ifndef NO_CERTS
        keySz = ssl->buffers.keySz;
    #endif
        InitSuites(ssl->suites, ssl->version, keySz, haveRSA, havePSK,
                   ssl->options.haveDH, ssl->options.haveECDSAsig,
                   ssl->options.haveECC, TRUE, ssl->options.haveStaticECC,
                   ssl->options.haveFalconSig, ssl->options.haveDilithiumSig,
                   ssl->options.haveAnon, TRUE, ssl->options.side);
    }

    WOLFSSL_LEAVE("wolfSSL_SetTmpDH", 0);

    return WOLFSSL_SUCCESS;
}


#if !defined(WOLFSSL_OLD_PRIME_CHECK) && !defined(HAVE_FIPS) && \
    !defined(HAVE_SELFTEST)
/* Enables or disables the session's DH key prime test. */
int wolfSSL_SetEnableDhKeyTest(WOLFSSL* ssl, int enable)
{
    WOLFSSL_ENTER("wolfSSL_SetEnableDhKeyTest");

    if (ssl == NULL)
        return BAD_FUNC_ARG;

    if (!enable)
        ssl->options.dhDoKeyTest = 0;
    else
        ssl->options.dhDoKeyTest = 1;

    WOLFSSL_LEAVE("wolfSSL_SetEnableDhKeyTest", WOLFSSL_SUCCESS);
    return WOLFSSL_SUCCESS;
}
#endif


/* server ctx Diffie-Hellman parameters, WOLFSSL_SUCCESS on ok */
int wolfSSL_CTX_SetTmpDH(WOLFSSL_CTX* ctx, const unsigned char* p, int pSz,
                         const unsigned char* g, int gSz)
{
    WOLFSSL_ENTER("wolfSSL_CTX_SetTmpDH");
    if (ctx == NULL || p == NULL || g == NULL) return BAD_FUNC_ARG;

    if ((word16)pSz < ctx->minDhKeySz)
        return DH_KEY_SIZE_E;
    if ((word16)pSz > ctx->maxDhKeySz)
        return DH_KEY_SIZE_E;

    #if !defined(WOLFSSL_OLD_PRIME_CHECK) && !defined(HAVE_FIPS) && \
        !defined(HAVE_SELFTEST)
    {
        WC_RNG rng;
        int error, freeKey = 0;
    #ifdef WOLFSSL_SMALL_STACK
        DhKey *checkKey = (DhKey*)XMALLOC(sizeof(DhKey), NULL, DYNAMIC_TYPE_DH);
        if (checkKey == NULL)
            return MEMORY_E;
    #else
        DhKey checkKey[1];
    #endif

        error = wc_InitRng(&rng);
        if (!error)
            error = wc_InitDhKey(checkKey);
        if (!error) {
            freeKey = 1;
            error = wc_DhSetCheckKey(checkKey,
                                 p, pSz, g, gSz, NULL, 0, 0, &rng);
        }
        if (freeKey)
            wc_FreeDhKey(checkKey);
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(checkKey, NULL, DYNAMIC_TYPE_DH);
    #endif
        wc_FreeRng(&rng);
        if (error)
            return error;

        ctx->dhKeyTested = 1;
    }
    #endif

    XFREE(ctx->serverDH_P.buffer, ctx->heap, DYNAMIC_TYPE_PUBLIC_KEY);
    ctx->serverDH_P.buffer = NULL;
    XFREE(ctx->serverDH_G.buffer, ctx->heap, DYNAMIC_TYPE_PUBLIC_KEY);
    ctx->serverDH_G.buffer = NULL;

    ctx->serverDH_P.buffer = (byte*)XMALLOC(pSz, ctx->heap, DYNAMIC_TYPE_PUBLIC_KEY);
    if (ctx->serverDH_P.buffer == NULL)
       return MEMORY_E;

    ctx->serverDH_G.buffer = (byte*)XMALLOC(gSz, ctx->heap, DYNAMIC_TYPE_PUBLIC_KEY);
    if (ctx->serverDH_G.buffer == NULL) {
        XFREE(ctx->serverDH_P.buffer, ctx->heap, DYNAMIC_TYPE_PUBLIC_KEY);
        ctx->serverDH_P.buffer = NULL;
        return MEMORY_E;
    }

    ctx->serverDH_P.length = pSz;
    ctx->serverDH_G.length = gSz;

    XMEMCPY(ctx->serverDH_P.buffer, p, pSz);
    XMEMCPY(ctx->serverDH_G.buffer, g, gSz);

    ctx->haveDH = 1;

    WOLFSSL_LEAVE("wolfSSL_CTX_SetTmpDH", 0);
    return WOLFSSL_SUCCESS;
}


int wolfSSL_CTX_SetMinDhKey_Sz(WOLFSSL_CTX* ctx, word16 keySz_bits)
{
    if (ctx == NULL || keySz_bits > 16000 || keySz_bits % 8 != 0)
        return BAD_FUNC_ARG;

    ctx->minDhKeySz = keySz_bits / 8;
    return WOLFSSL_SUCCESS;
}


int wolfSSL_SetMinDhKey_Sz(WOLFSSL* ssl, word16 keySz_bits)
{
    if (ssl == NULL || keySz_bits > 16000 || keySz_bits % 8 != 0)
        return BAD_FUNC_ARG;

    ssl->options.minDhKeySz = keySz_bits / 8;
    return WOLFSSL_SUCCESS;
}


int wolfSSL_CTX_SetMaxDhKey_Sz(WOLFSSL_CTX* ctx, word16 keySz_bits)
{
    if (ctx == NULL || keySz_bits > 16000 || keySz_bits % 8 != 0)
        return BAD_FUNC_ARG;

    ctx->maxDhKeySz = keySz_bits / 8;
    return WOLFSSL_SUCCESS;
}


int wolfSSL_SetMaxDhKey_Sz(WOLFSSL* ssl, word16 keySz_bits)
{
    if (ssl == NULL || keySz_bits > 16000 || keySz_bits % 8 != 0)
        return BAD_FUNC_ARG;

    ssl->options.maxDhKeySz = keySz_bits / 8;
    return WOLFSSL_SUCCESS;
}


int wolfSSL_GetDhKey_Sz(WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    return (ssl->options.dhKeySz * 8);
}

#endif /* !NO_DH */


WOLFSSL_ABI
int wolfSSL_write(WOLFSSL* ssl, const void* data, int sz)
{
    int ret;

    WOLFSSL_ENTER("SSL_write()");

    if (ssl == NULL || data == NULL || sz < 0)
        return BAD_FUNC_ARG;

#ifdef WOLFSSL_QUIC
    if (WOLFSSL_IS_QUIC(ssl)) {
        WOLFSSL_MSG("SSL_write() on QUIC not allowed");
        return BAD_FUNC_ARG;
    }
#endif
#ifdef WOLFSSL_EARLY_DATA
    if (ssl->earlyData != no_early_data && (ret = wolfSSL_negotiate(ssl)) < 0) {
        ssl->error = ret;
        return WOLFSSL_FATAL_ERROR;
    }
    ssl->earlyData = no_early_data;
#endif

#ifdef HAVE_WRITE_DUP
    { /* local variable scope */
        int dupErr = 0;   /* local copy */

        ret = 0;

        if (ssl->dupWrite && ssl->dupSide == READ_DUP_SIDE) {
            WOLFSSL_MSG("Read dup side cannot write");
            return WRITE_DUP_WRITE_E;
        }
        if (ssl->dupWrite) {
            if (wc_LockMutex(&ssl->dupWrite->dupMutex) != 0) {
                return BAD_MUTEX_E;
            }
            dupErr = ssl->dupWrite->dupErr;
            ret = wc_UnLockMutex(&ssl->dupWrite->dupMutex);
        }

        if (ret != 0) {
            ssl->error = ret;  /* high priority fatal error */
            return WOLFSSL_FATAL_ERROR;
        }
        if (dupErr != 0) {
            WOLFSSL_MSG("Write dup error from other side");
            ssl->error = dupErr;
            return WOLFSSL_FATAL_ERROR;
        }
    }
#endif

#ifdef HAVE_ERRNO_H
    errno = 0;
#endif

    #ifdef OPENSSL_EXTRA
    if (ssl->CBIS != NULL) {
        ssl->CBIS(ssl, SSL_CB_WRITE, WOLFSSL_SUCCESS);
        ssl->cbmode = SSL_CB_WRITE;
    }
    #endif
    ret = SendData(ssl, data, sz);

    WOLFSSL_LEAVE("SSL_write()", ret);

    if (ret < 0)
        return WOLFSSL_FATAL_ERROR;
    else
        return ret;
}

static int wolfSSL_read_internal(WOLFSSL* ssl, void* data, int sz, int peek)
{
    int ret;

    WOLFSSL_ENTER("wolfSSL_read_internal()");

    if (ssl == NULL || data == NULL || sz < 0)
        return BAD_FUNC_ARG;

#ifdef WOLFSSL_QUIC
    if (WOLFSSL_IS_QUIC(ssl)) {
        WOLFSSL_MSG("SSL_read() on QUIC not allowed");
        return BAD_FUNC_ARG;
    }
#endif
#if defined(WOLFSSL_ERROR_CODE_OPENSSL) && defined(OPENSSL_EXTRA)
    /* This additional logic is meant to simulate following openSSL behavior:
     * After bidirectional SSL_shutdown complete, SSL_read returns 0 and
     * SSL_get_error_code returns SSL_ERROR_ZERO_RETURN.
     * This behavior is used to know the disconnect of the underlying
     * transport layer.
     *
     * In this logic, CBIORecv is called with a read size of 0 to check the
     * transport layer status. It also returns WOLFSSL_FAILURE so that
     * SSL_read does not return a positive number on failure.
     */

    /* make sure bidirectional TLS shutdown completes */
    if (ssl->error == WOLFSSL_ERROR_SYSCALL) {
        /* ask the underlying transport the connection is closed */
        if (ssl->CBIORecv(ssl, (char*)data, 0, ssl->IOCB_ReadCtx) ==
                                            WOLFSSL_CBIO_ERR_CONN_CLOSE) {
            ssl->options.isClosed = 1;
            ssl->error = WOLFSSL_ERROR_ZERO_RETURN;
        }
        return WOLFSSL_FAILURE;
    }
#endif

#ifdef HAVE_WRITE_DUP
    if (ssl->dupWrite && ssl->dupSide == WRITE_DUP_SIDE) {
        WOLFSSL_MSG("Write dup side cannot read");
        return WRITE_DUP_READ_E;
    }
#endif

#ifdef HAVE_ERRNO_H
        errno = 0;
#endif

#ifdef WOLFSSL_DTLS
    if (ssl->options.dtls) {
        ssl->dtls_expected_rx = max(sz + DTLS_MTU_ADDITIONAL_READ_BUFFER,
                MAX_MTU);
#ifdef WOLFSSL_SCTP
        if (ssl->options.dtlsSctp)
#endif
#if defined(WOLFSSL_SCTP) || defined(WOLFSSL_DTLS_MTU)
            /* Add some bytes so that we can operate with slight difference
             * in set MTU size on each peer */
            ssl->dtls_expected_rx = max(ssl->dtls_expected_rx,
                    ssl->dtlsMtuSz + (word32)DTLS_MTU_ADDITIONAL_READ_BUFFER);
#endif
    }
#endif

    ret = ReceiveData(ssl, (byte*)data, sz, peek);

#ifdef HAVE_WRITE_DUP
    if (ssl->dupWrite) {
        if (ssl->error != 0 && ssl->error != WANT_READ
        #ifdef WOLFSSL_ASYNC_CRYPT
            && ssl->error != WC_PENDING_E
        #endif
        ) {
            int notifyErr;

            WOLFSSL_MSG("Notifying write side of fatal read error");
            notifyErr  = NotifyWriteSide(ssl, ssl->error);
            if (notifyErr < 0) {
                ret = ssl->error = notifyErr;
            }
        }
    }
#endif

    WOLFSSL_LEAVE("wolfSSL_read_internal()", ret);

    if (ret < 0)
        return WOLFSSL_FATAL_ERROR;
    else
        return ret;
}


int wolfSSL_peek(WOLFSSL* ssl, void* data, int sz)
{
    WOLFSSL_ENTER("wolfSSL_peek()");

    return wolfSSL_read_internal(ssl, data, sz, TRUE);
}


WOLFSSL_ABI
int wolfSSL_read(WOLFSSL* ssl, void* data, int sz)
{
    WOLFSSL_ENTER("wolfSSL_read()");

    #ifdef OPENSSL_EXTRA
    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }
    if (ssl->CBIS != NULL) {
        ssl->CBIS(ssl, SSL_CB_READ, WOLFSSL_SUCCESS);
        ssl->cbmode = SSL_CB_READ;
    }
    #endif
    return wolfSSL_read_internal(ssl, data, sz, FALSE);
}


#ifdef WOLFSSL_MULTICAST

int wolfSSL_mcast_read(WOLFSSL* ssl, word16* id, void* data, int sz)
{
    int ret = 0;

    WOLFSSL_ENTER("wolfSSL_mcast_read()");

    if (ssl == NULL)
        return BAD_FUNC_ARG;

    ret = wolfSSL_read_internal(ssl, data, sz, FALSE);
    if (ssl->options.dtls && ssl->options.haveMcast && id != NULL)
        *id = ssl->keys.curPeerId;
    return ret;
}

#endif /* WOLFSSL_MULTICAST */


/* helpers to set the device id, WOLFSSL_SUCCESS on ok */
WOLFSSL_ABI
int wolfSSL_SetDevId(WOLFSSL* ssl, int devId)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    ssl->devId = devId;

    return WOLFSSL_SUCCESS;
}

WOLFSSL_ABI
int wolfSSL_CTX_SetDevId(WOLFSSL_CTX* ctx, int devId)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;

    ctx->devId = devId;

    return WOLFSSL_SUCCESS;
}

/* helpers to get device id and heap */
WOLFSSL_ABI
int wolfSSL_CTX_GetDevId(WOLFSSL_CTX* ctx, WOLFSSL* ssl)
{
    int devId = INVALID_DEVID;
    if (ssl != NULL)
        devId = ssl->devId;
    if (ctx != NULL && devId == INVALID_DEVID)
        devId = ctx->devId;
    return devId;
}
void* wolfSSL_CTX_GetHeap(WOLFSSL_CTX* ctx, WOLFSSL* ssl)
{
    void* heap = NULL;
    if (ctx != NULL)
        heap = ctx->heap;
    else if (ssl != NULL)
        heap = ssl->heap;
    return heap;
}


#ifdef HAVE_SNI

WOLFSSL_ABI
int wolfSSL_UseSNI(WOLFSSL* ssl, byte type, const void* data, word16 size)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    return TLSX_UseSNI(&ssl->extensions, type, data, size, ssl->heap);
}


WOLFSSL_ABI
int wolfSSL_CTX_UseSNI(WOLFSSL_CTX* ctx, byte type, const void* data,
                                                                    word16 size)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;

    return TLSX_UseSNI(&ctx->extensions, type, data, size, ctx->heap);
}

#ifndef NO_WOLFSSL_SERVER

void wolfSSL_SNI_SetOptions(WOLFSSL* ssl, byte type, byte options)
{
    if (ssl && ssl->extensions)
        TLSX_SNI_SetOptions(ssl->extensions, type, options);
}


void wolfSSL_CTX_SNI_SetOptions(WOLFSSL_CTX* ctx, byte type, byte options)
{
    if (ctx && ctx->extensions)
        TLSX_SNI_SetOptions(ctx->extensions, type, options);
}


byte wolfSSL_SNI_Status(WOLFSSL* ssl, byte type)
{
    return TLSX_SNI_Status(ssl ? ssl->extensions : NULL, type);
}


word16 wolfSSL_SNI_GetRequest(WOLFSSL* ssl, byte type, void** data)
{
    if (data)
        *data = NULL;

    if (ssl && ssl->extensions)
        return TLSX_SNI_GetRequest(ssl->extensions, type, data);

    return 0;
}


int wolfSSL_SNI_GetFromBuffer(const byte* clientHello, word32 helloSz,
                              byte type, byte* sni, word32* inOutSz)
{
    if (clientHello && helloSz > 0 && sni && inOutSz && *inOutSz > 0)
        return TLSX_SNI_GetFromBuffer(clientHello, helloSz, type, sni, inOutSz);

    return BAD_FUNC_ARG;
}

#endif /* NO_WOLFSSL_SERVER */

#endif /* HAVE_SNI */


#ifdef HAVE_TRUSTED_CA

int wolfSSL_UseTrustedCA(WOLFSSL* ssl, byte type,
    const byte* certId, word32 certIdSz)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    if (type == WOLFSSL_TRUSTED_CA_PRE_AGREED) {
        if (certId != NULL || certIdSz != 0)
            return BAD_FUNC_ARG;
    }
    else if (type == WOLFSSL_TRUSTED_CA_X509_NAME) {
        if (certId == NULL || certIdSz == 0)
            return BAD_FUNC_ARG;
    }
    #ifndef NO_SHA
    else if (type == WOLFSSL_TRUSTED_CA_KEY_SHA1 ||
            type == WOLFSSL_TRUSTED_CA_CERT_SHA1) {
        if (certId == NULL || certIdSz != WC_SHA_DIGEST_SIZE)
            return BAD_FUNC_ARG;
    }
    #endif
    else
        return BAD_FUNC_ARG;

    return TLSX_UseTrustedCA(&ssl->extensions,
            type, certId, certIdSz, ssl->heap);
}

#endif /* HAVE_TRUSTED_CA */


#ifdef HAVE_MAX_FRAGMENT
#ifndef NO_WOLFSSL_CLIENT

int wolfSSL_UseMaxFragment(WOLFSSL* ssl, byte mfl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

#ifdef WOLFSSL_ALLOW_MAX_FRAGMENT_ADJUST
    /* The following is a non-standard way to reconfigure the max packet size
        post-handshake for wolfSSL_write/wolfSSL_read */
    if (ssl->options.handShakeState == HANDSHAKE_DONE) {
        switch (mfl) {
            case WOLFSSL_MFL_2_8 : ssl->max_fragment =  256; break;
            case WOLFSSL_MFL_2_9 : ssl->max_fragment =  512; break;
            case WOLFSSL_MFL_2_10: ssl->max_fragment = 1024; break;
            case WOLFSSL_MFL_2_11: ssl->max_fragment = 2048; break;
            case WOLFSSL_MFL_2_12: ssl->max_fragment = 4096; break;
            case WOLFSSL_MFL_2_13: ssl->max_fragment = 8192; break;
            default: ssl->max_fragment = MAX_RECORD_SIZE; break;
        }
        return WOLFSSL_SUCCESS;
    }
#endif /* WOLFSSL_MAX_FRAGMENT_ADJUST */

    /* This call sets the max fragment TLS extension, which gets sent to server.
        The server_hello response is what sets the `ssl->max_fragment` in
        TLSX_MFL_Parse */
    return TLSX_UseMaxFragment(&ssl->extensions, mfl, ssl->heap);
}


int wolfSSL_CTX_UseMaxFragment(WOLFSSL_CTX* ctx, byte mfl)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;

    return TLSX_UseMaxFragment(&ctx->extensions, mfl, ctx->heap);
}

#endif /* NO_WOLFSSL_CLIENT */
#endif /* HAVE_MAX_FRAGMENT */

#ifdef HAVE_TRUNCATED_HMAC
#ifndef NO_WOLFSSL_CLIENT

int wolfSSL_UseTruncatedHMAC(WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    return TLSX_UseTruncatedHMAC(&ssl->extensions, ssl->heap);
}


int wolfSSL_CTX_UseTruncatedHMAC(WOLFSSL_CTX* ctx)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;

    return TLSX_UseTruncatedHMAC(&ctx->extensions, ctx->heap);
}

#endif /* NO_WOLFSSL_CLIENT */
#endif /* HAVE_TRUNCATED_HMAC */

#ifdef HAVE_CERTIFICATE_STATUS_REQUEST

int wolfSSL_UseOCSPStapling(WOLFSSL* ssl, byte status_type, byte options)
{
    WOLFSSL_ENTER("wolfSSL_UseOCSPStapling");

    if (ssl == NULL || ssl->options.side != WOLFSSL_CLIENT_END)
        return BAD_FUNC_ARG;

    return TLSX_UseCertificateStatusRequest(&ssl->extensions, status_type,
                                          options, NULL, ssl->heap, ssl->devId);
}


int wolfSSL_CTX_UseOCSPStapling(WOLFSSL_CTX* ctx, byte status_type,
                                                                   byte options)
{
    WOLFSSL_ENTER("wolfSSL_CTX_UseOCSPStapling");

    if (ctx == NULL || ctx->method->side != WOLFSSL_CLIENT_END)
        return BAD_FUNC_ARG;

    return TLSX_UseCertificateStatusRequest(&ctx->extensions, status_type,
                                          options, NULL, ctx->heap, ctx->devId);
}

#endif /* HAVE_CERTIFICATE_STATUS_REQUEST */

#ifdef HAVE_CERTIFICATE_STATUS_REQUEST_V2

int wolfSSL_UseOCSPStaplingV2(WOLFSSL* ssl, byte status_type, byte options)
{
    if (ssl == NULL || ssl->options.side != WOLFSSL_CLIENT_END)
        return BAD_FUNC_ARG;

    return TLSX_UseCertificateStatusRequestV2(&ssl->extensions, status_type,
                                                options, ssl->heap, ssl->devId);
}


int wolfSSL_CTX_UseOCSPStaplingV2(WOLFSSL_CTX* ctx, byte status_type,
                                                                   byte options)
{
    if (ctx == NULL || ctx->method->side != WOLFSSL_CLIENT_END)
        return BAD_FUNC_ARG;

    return TLSX_UseCertificateStatusRequestV2(&ctx->extensions, status_type,
                                                options, ctx->heap, ctx->devId);
}

#endif /* HAVE_CERTIFICATE_STATUS_REQUEST_V2 */

/* Elliptic Curves */
#if defined(HAVE_SUPPORTED_CURVES)

static int isValidCurveGroup(word16 name)
{
    switch (name) {
        case WOLFSSL_ECC_SECP160K1:
        case WOLFSSL_ECC_SECP160R1:
        case WOLFSSL_ECC_SECP160R2:
        case WOLFSSL_ECC_SECP192K1:
        case WOLFSSL_ECC_SECP192R1:
        case WOLFSSL_ECC_SECP224K1:
        case WOLFSSL_ECC_SECP224R1:
        case WOLFSSL_ECC_SECP256K1:
        case WOLFSSL_ECC_SECP256R1:
        case WOLFSSL_ECC_SECP384R1:
        case WOLFSSL_ECC_SECP521R1:
        case WOLFSSL_ECC_BRAINPOOLP256R1:
        case WOLFSSL_ECC_BRAINPOOLP384R1:
        case WOLFSSL_ECC_BRAINPOOLP512R1:
        case WOLFSSL_ECC_X25519:
        case WOLFSSL_ECC_X448:

        case WOLFSSL_FFDHE_2048:
        case WOLFSSL_FFDHE_3072:
        case WOLFSSL_FFDHE_4096:
        case WOLFSSL_FFDHE_6144:
        case WOLFSSL_FFDHE_8192:

#ifdef HAVE_PQC
        case WOLFSSL_KYBER_LEVEL1:
        case WOLFSSL_KYBER_LEVEL3:
        case WOLFSSL_KYBER_LEVEL5:
    #ifdef HAVE_LIBOQS
        case WOLFSSL_P256_KYBER_LEVEL1:
        case WOLFSSL_P384_KYBER_LEVEL3:
        case WOLFSSL_P521_KYBER_LEVEL5:
    #endif
#endif
            return 1;

        default:
            return 0;
    }
}

int wolfSSL_UseSupportedCurve(WOLFSSL* ssl, word16 name)
{
    if (ssl == NULL || !isValidCurveGroup(name))
        return BAD_FUNC_ARG;

    ssl->options.userCurves = 1;
#if defined(NO_TLS)
    return WOLFSSL_FAILURE;
#else
    return TLSX_UseSupportedCurve(&ssl->extensions, name, ssl->heap);
#endif /* NO_TLS */
}


int wolfSSL_CTX_UseSupportedCurve(WOLFSSL_CTX* ctx, word16 name)
{
    if (ctx == NULL || !isValidCurveGroup(name))
        return BAD_FUNC_ARG;

    ctx->userCurves = 1;
#if defined(NO_TLS)
    return WOLFSSL_FAILURE;
#else
    return TLSX_UseSupportedCurve(&ctx->extensions, name, ctx->heap);
#endif /* NO_TLS */
}

#if defined(OPENSSL_EXTRA) && defined(WOLFSSL_TLS13)
int  wolfSSL_CTX_set1_groups(WOLFSSL_CTX* ctx, int* groups,
                                        int count)
{
    int i;
    int _groups[WOLFSSL_MAX_GROUP_COUNT];
    WOLFSSL_ENTER("wolfSSL_CTX_set1_groups");
    if (count == 0) {
        WOLFSSL_MSG("Group count is zero");
        return WOLFSSL_FAILURE;
    }
    for (i = 0; i < count; i++) {
        if (isValidCurveGroup((word16)groups[i])) {
            _groups[i] = groups[i];
        }
#ifdef HAVE_ECC
        else {
            /* groups may be populated with curve NIDs */
            int oid = nid2oid(groups[i], oidCurveType);
            int name = (int)GetCurveByOID(oid);
            if (name == 0) {
                WOLFSSL_MSG("Invalid group name");
                return WOLFSSL_FAILURE;
            }
            _groups[i] = name;
        }
#else
        else {
            WOLFSSL_MSG("Invalid group name");
            return WOLFSSL_FAILURE;
        }
#endif
    }
    return wolfSSL_CTX_set_groups(ctx, _groups, count) == WOLFSSL_SUCCESS ?
            WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
}

int  wolfSSL_set1_groups(WOLFSSL* ssl, int* groups, int count)
{
    int i;
    int _groups[WOLFSSL_MAX_GROUP_COUNT];
    WOLFSSL_ENTER("wolfSSL_CTX_set1_groups");
    if (count == 0) {
        WOLFSSL_MSG("Group count is zero");
        return WOLFSSL_FAILURE;
    }
    for (i = 0; i < count; i++) {
        if (isValidCurveGroup((word16)groups[i])) {
            _groups[i] = groups[i];
        }
#ifdef HAVE_ECC
        else {
            /* groups may be populated with curve NIDs */
            int oid = nid2oid(groups[i], oidCurveType);
            int name = (int)GetCurveByOID(oid);
            if (name == 0) {
                WOLFSSL_MSG("Invalid group name");
                return WOLFSSL_FAILURE;
            }
            _groups[i] = name;
        }
#else
        else {
            WOLFSSL_MSG("Invalid group name");
            return WOLFSSL_FAILURE;
        }
#endif
    }
    return wolfSSL_set_groups(ssl, _groups, count) == WOLFSSL_SUCCESS ?
            WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
}
#endif /* OPENSSL_EXTRA && WOLFSSL_TLS13 */
#endif /* HAVE_SUPPORTED_CURVES */

/* Application-Layer Protocol Negotiation */
#ifdef HAVE_ALPN

WOLFSSL_ABI
int wolfSSL_UseALPN(WOLFSSL* ssl, char *protocol_name_list,
                    word32 protocol_name_listSz, byte options)
{
    char    *list, *ptr, **token;
    word16  len;
    int     idx = 0;
    int     ret = WOLFSSL_FAILURE;

    WOLFSSL_ENTER("wolfSSL_UseALPN");

    if (ssl == NULL || protocol_name_list == NULL)
        return BAD_FUNC_ARG;

    if (protocol_name_listSz > (WOLFSSL_MAX_ALPN_NUMBER *
                                WOLFSSL_MAX_ALPN_PROTO_NAME_LEN +
                                WOLFSSL_MAX_ALPN_NUMBER)) {
        WOLFSSL_MSG("Invalid arguments, protocol name list too long");
        return BAD_FUNC_ARG;
    }

    if (!(options & WOLFSSL_ALPN_CONTINUE_ON_MISMATCH) &&
        !(options & WOLFSSL_ALPN_FAILED_ON_MISMATCH)) {
            WOLFSSL_MSG("Invalid arguments, options not supported");
            return BAD_FUNC_ARG;
        }


    list = (char *)XMALLOC(protocol_name_listSz+1, ssl->heap,
                           DYNAMIC_TYPE_ALPN);
    if (list == NULL) {
        WOLFSSL_MSG("Memory failure");
        return MEMORY_ERROR;
    }

    token = (char **)XMALLOC(sizeof(char *) * (WOLFSSL_MAX_ALPN_NUMBER+1), ssl->heap, DYNAMIC_TYPE_ALPN);
    if (token == NULL) {
        XFREE(list, ssl->heap, DYNAMIC_TYPE_ALPN);
        WOLFSSL_MSG("Memory failure");
        return MEMORY_ERROR;
    }
    XMEMSET(token, 0, sizeof(char *) * (WOLFSSL_MAX_ALPN_NUMBER+1));

    XSTRNCPY(list, protocol_name_list, protocol_name_listSz);
    list[protocol_name_listSz] = '\0';

    /* read all protocol name from the list */
    token[idx] = XSTRTOK(list, ",", &ptr);
    while (idx < WOLFSSL_MAX_ALPN_NUMBER && token[idx] != NULL)
        token[++idx] = XSTRTOK(NULL, ",", &ptr);

    /* add protocol name list in the TLS extension in reverse order */
    while ((idx--) > 0) {
        len = (word16)XSTRLEN(token[idx]);

        ret = TLSX_UseALPN(&ssl->extensions, token[idx], len, options,
                                                                     ssl->heap);
        if (ret != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("TLSX_UseALPN failure");
            break;
        }
    }

    XFREE(token, ssl->heap, DYNAMIC_TYPE_ALPN);
    XFREE(list, ssl->heap, DYNAMIC_TYPE_ALPN);

    return ret;
}

int wolfSSL_ALPN_GetProtocol(WOLFSSL* ssl, char **protocol_name, word16 *size)
{
    return TLSX_ALPN_GetRequest(ssl ? ssl->extensions : NULL,
                               (void **)protocol_name, size);
}

int wolfSSL_ALPN_GetPeerProtocol(WOLFSSL* ssl, char **list, word16 *listSz)
{
    int i, len;
    char *p;
    byte *s;

    if (ssl == NULL || list == NULL || listSz == NULL)
        return BAD_FUNC_ARG;

    if (ssl->alpn_peer_requested == NULL
        || ssl->alpn_peer_requested_length == 0)
        return BUFFER_ERROR;

    /* ssl->alpn_peer_requested are the original bytes sent in a ClientHello,
     * formatted as (len-byte chars+)+. To turn n protocols into a
     * comma-separated C string, one needs (n-1) commas and a final 0 byte
     * which has the same length as the original.
     * The returned length is the strlen() of the C string, so -1 of that. */
    *listSz = ssl->alpn_peer_requested_length-1;
    *list = p = (char *)XMALLOC(ssl->alpn_peer_requested_length, ssl->heap,
                                DYNAMIC_TYPE_TLSX);
    if (p == NULL)
        return MEMORY_ERROR;

    for (i = 0, s = ssl->alpn_peer_requested;
         i < ssl->alpn_peer_requested_length;
         p += len, i += len)
    {
        if (i)
            *p++ = ',';
        len = s[i++];
        /* guard against bad length bytes. */
        if (i + len > ssl->alpn_peer_requested_length) {
            XFREE(*list, ssl->heap, DYNAMIC_TYPE_TLSX);
            *list = NULL;
            return WOLFSSL_FAILURE;
        }
        XMEMCPY(p, s + i, len);
    }
    *p = 0;

    return WOLFSSL_SUCCESS;
}


/* used to free memory allocated by wolfSSL_ALPN_GetPeerProtocol */
int wolfSSL_ALPN_FreePeerProtocol(WOLFSSL* ssl, char **list)
{
    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }

    XFREE(*list, ssl->heap, DYNAMIC_TYPE_TLSX);
    *list = NULL;

    return WOLFSSL_SUCCESS;
}

#endif /* HAVE_ALPN */

/* Secure Renegotiation */
#ifdef HAVE_SERVER_RENEGOTIATION_INFO

/* user is forcing ability to use secure renegotiation, we discourage it */
int wolfSSL_UseSecureRenegotiation(WOLFSSL* ssl)
{
    int ret = BAD_FUNC_ARG;
#if defined(NO_TLS)
    (void)ssl;
#else
    if (ssl)
        ret = TLSX_UseSecureRenegotiation(&ssl->extensions, ssl->heap);

    if (ret == WOLFSSL_SUCCESS) {
        TLSX* extension = TLSX_Find(ssl->extensions, TLSX_RENEGOTIATION_INFO);

        if (extension)
            ssl->secure_renegotiation = (SecureRenegotiation*)extension->data;
    }
#endif /* !NO_TLS */
    return ret;
}

int wolfSSL_CTX_UseSecureRenegotiation(WOLFSSL_CTX* ctx)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;

    ctx->useSecureReneg = 1;
    return WOLFSSL_SUCCESS;
}


/* do a secure renegotiation handshake, user forced, we discourage */
static int _Rehandshake(WOLFSSL* ssl)
{
    int ret;

    if (ssl == NULL)
        return BAD_FUNC_ARG;

    if (IsAtLeastTLSv1_3(ssl->version)) {
        WOLFSSL_MSG("Secure Renegotiation not supported in TLS 1.3");
        return SECURE_RENEGOTIATION_E;
    }

    if (ssl->secure_renegotiation == NULL) {
        WOLFSSL_MSG("Secure Renegotiation not forced on by user");
        return SECURE_RENEGOTIATION_E;
    }

    if (ssl->secure_renegotiation->enabled == 0) {
        WOLFSSL_MSG("Secure Renegotiation not enabled at extension level");
        return SECURE_RENEGOTIATION_E;
    }

#ifdef WOLFSSL_DTLS
    if (ssl->options.dtls && ssl->keys.dtls_epoch == 0xFFFF) {
        WOLFSSL_MSG("Secure Renegotiation not allowed. Epoch would wrap");
        return SECURE_RENEGOTIATION_E;
    }
#endif

    /* If the client started the renegotiation, the server will already
     * have processed the client's hello. */
    if (ssl->options.side != WOLFSSL_SERVER_END ||
        ssl->options.acceptState != ACCEPT_FIRST_REPLY_DONE) {

        if (ssl->options.handShakeState != HANDSHAKE_DONE) {
            if (!ssl->options.handShakeDone) {
                WOLFSSL_MSG("Can't renegotiate until initial "
                            "handshake complete");
                return SECURE_RENEGOTIATION_E;
            }
            else {
                WOLFSSL_MSG("Renegotiation already started. "
                            "Moving it forward.");
                ret = wolfSSL_negotiate(ssl);
                if (ret == WOLFSSL_SUCCESS)
                    ssl->secure_rene_count++;
                return ret;
            }
        }

#ifndef NO_FORCE_SCR_SAME_SUITE
        /* force same suite */
        if (ssl->suites) {
            ssl->suites->suiteSz = SUITE_LEN;
            ssl->suites->suites[0] = ssl->options.cipherSuite0;
            ssl->suites->suites[1] = ssl->options.cipherSuite;
        }
#endif

        /* reset handshake states */
        ssl->options.sendVerify = 0;
        ssl->options.serverState = NULL_STATE;
        ssl->options.clientState = NULL_STATE;
        ssl->options.connectState  = CONNECT_BEGIN;
        ssl->options.acceptState   = ACCEPT_BEGIN_RENEG;
        ssl->options.handShakeState = NULL_STATE;
        ssl->options.processReply  = 0;  /* TODO, move states in internal.h */

        XMEMSET(&ssl->msgsReceived, 0, sizeof(ssl->msgsReceived));

        ssl->secure_renegotiation->cache_status = SCR_CACHE_NEEDED;

#if !defined(NO_WOLFSSL_SERVER) && defined(HAVE_SECURE_RENEGOTIATION)
        if (ssl->options.side == WOLFSSL_SERVER_END) {
            ret = SendHelloRequest(ssl);
            if (ret != 0) {
                ssl->error = ret;
                return WOLFSSL_FATAL_ERROR;
            }
        }
#endif /* !NO_WOLFSSL_SERVER && HAVE_SECURE_RENEGOTIATION */

        ret = InitHandshakeHashes(ssl);
        if (ret != 0) {
            ssl->error = ret;
            return WOLFSSL_FATAL_ERROR;
        }
    }
    ret = wolfSSL_negotiate(ssl);
    if (ret == WOLFSSL_SUCCESS)
        ssl->secure_rene_count++;
    return ret;
}


/* do a secure renegotiation handshake, user forced, we discourage */
int wolfSSL_Rehandshake(WOLFSSL* ssl)
{
    int ret;
    WOLFSSL_ENTER("wolfSSL_Rehandshake");

    if (ssl == NULL)
        return WOLFSSL_FAILURE;

#ifdef HAVE_SESSION_TICKET
    ret = WOLFSSL_SUCCESS;
#endif

    if (ssl->options.side == WOLFSSL_SERVER_END) {
        /* Reset option to send certificate verify. */
        ssl->options.sendVerify = 0;
    }
    else {
        /* Reset resuming flag to do full secure handshake. */
        ssl->options.resuming = 0;
        #ifdef HAVE_SESSION_TICKET
            /* Clearing the ticket. */
            ret = wolfSSL_UseSessionTicket(ssl);
        #endif
    }
    /* CLIENT/SERVER: Reset peer authentication for full secure handshake. */
    ssl->options.peerAuthGood = 0;

#ifdef HAVE_SESSION_TICKET
    if (ret == WOLFSSL_SUCCESS)
#endif
        ret = _Rehandshake(ssl);

    return ret;
}


#ifndef NO_WOLFSSL_CLIENT

/* do a secure resumption handshake, user forced, we discourage */
int wolfSSL_SecureResume(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_SecureResume");

    if (ssl == NULL)
        return BAD_FUNC_ARG;

    if (ssl->options.side == WOLFSSL_SERVER_END) {
        ssl->error = SIDE_ERROR;
        return WOLFSSL_FATAL_ERROR;
    }

    return _Rehandshake(ssl);
}

#endif /* NO_WOLFSSL_CLIENT */

long wolfSSL_SSL_get_secure_renegotiation_support(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_SSL_get_secure_renegotiation_support");

    if (!ssl || !ssl->secure_renegotiation)
        return WOLFSSL_FAILURE;
    return ssl->secure_renegotiation->enabled;
}

#endif /* HAVE_SECURE_RENEGOTIATION_INFO */

#if defined(HAVE_SESSION_TICKET)
/* Session Ticket */

#if !defined(NO_WOLFSSL_SERVER)
int wolfSSL_CTX_NoTicketTLSv12(WOLFSSL_CTX* ctx)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;

    ctx->noTicketTls12 = 1;

    return WOLFSSL_SUCCESS;
}

int wolfSSL_NoTicketTLSv12(WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    ssl->options.noTicketTls12 = 1;

    return WOLFSSL_SUCCESS;
}

/* WOLFSSL_SUCCESS on ok */
int wolfSSL_CTX_set_TicketEncCb(WOLFSSL_CTX* ctx, SessionTicketEncCb cb)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;

    ctx->ticketEncCb = cb;

    return WOLFSSL_SUCCESS;
}

/* set hint interval, WOLFSSL_SUCCESS on ok */
int wolfSSL_CTX_set_TicketHint(WOLFSSL_CTX* ctx, int hint)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;

    ctx->ticketHint = hint;

    return WOLFSSL_SUCCESS;
}

/* set user context, WOLFSSL_SUCCESS on ok */
int wolfSSL_CTX_set_TicketEncCtx(WOLFSSL_CTX* ctx, void* userCtx)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;

    ctx->ticketEncCtx = userCtx;

    return WOLFSSL_SUCCESS;
}

/* get user context - returns userCtx on success, NULL on failure */
void* wolfSSL_CTX_get_TicketEncCtx(WOLFSSL_CTX* ctx)
{
    if (ctx == NULL)
        return NULL;

    return ctx->ticketEncCtx;
}

#ifdef WOLFSSL_TLS13
/* set the maximum number of tickets to send
 * return WOLFSSL_SUCCESS on success and WOLFSSL_FAILURE on fail
 */
int wolfSSL_CTX_set_num_tickets(WOLFSSL_CTX* ctx, size_t mxTickets)
{
    if (ctx == NULL)
        return WOLFSSL_FAILURE;

    ctx->maxTicketTls13 = (unsigned int)mxTickets;
    return WOLFSSL_SUCCESS;
}

/* get the maximum number of tickets to send
 * return number of tickets set to be sent
 */
size_t wolfSSL_CTX_get_num_tickets(WOLFSSL_CTX* ctx)
{
    if (ctx == NULL)
        return 0;

    return (size_t)ctx->maxTicketTls13;
}
#endif /* WOLFSSL_TLS13 */
#endif /* !NO_WOLFSSL_SERVER */

#if !defined(NO_WOLFSSL_CLIENT)
int wolfSSL_UseSessionTicket(WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    return TLSX_UseSessionTicket(&ssl->extensions, NULL, ssl->heap);
}

int wolfSSL_CTX_UseSessionTicket(WOLFSSL_CTX* ctx)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;

    return TLSX_UseSessionTicket(&ctx->extensions, NULL, ctx->heap);
}

int wolfSSL_get_SessionTicket(WOLFSSL* ssl, byte* buf, word32* bufSz)
{
    if (ssl == NULL || buf == NULL || bufSz == NULL || *bufSz == 0)
        return BAD_FUNC_ARG;

    if (ssl->session->ticketLen <= *bufSz) {
        XMEMCPY(buf, ssl->session->ticket, ssl->session->ticketLen);
        *bufSz = ssl->session->ticketLen;
    }
    else
        *bufSz = 0;

    return WOLFSSL_SUCCESS;
}

int wolfSSL_set_SessionTicket(WOLFSSL* ssl, const byte* buf,
                                          word32 bufSz)
{
    if (ssl == NULL || (buf == NULL && bufSz > 0))
        return BAD_FUNC_ARG;

    if (bufSz > 0) {
        /* Ticket will fit into static ticket */
        if (bufSz <= SESSION_TICKET_LEN) {
            if (ssl->session->ticketLenAlloc > 0) {
                XFREE(ssl->session->ticket, ssl->session->heap,
                      DYNAMIC_TYPE_SESSION_TICK);
                ssl->session->ticketLenAlloc = 0;
                ssl->session->ticket = ssl->session->staticTicket;
            }
        }
        else { /* Ticket requires dynamic ticket storage */
            if (ssl->session->ticketLen < bufSz) { /* is dyn buffer big enough */
                if (ssl->session->ticketLenAlloc > 0) {
                    XFREE(ssl->session->ticket, ssl->session->heap,
                          DYNAMIC_TYPE_SESSION_TICK);
                }
                ssl->session->ticket = (byte*)XMALLOC(bufSz, ssl->session->heap,
                        DYNAMIC_TYPE_SESSION_TICK);
                if(ssl->session->ticket == NULL) {
                    ssl->session->ticket = ssl->session->staticTicket;
                    ssl->session->ticketLenAlloc = 0;
                    return MEMORY_ERROR;
                }
                ssl->session->ticketLenAlloc = (word16)bufSz;
            }
        }
        XMEMCPY(ssl->session->ticket, buf, bufSz);
    }
    ssl->session->ticketLen = (word16)bufSz;

    return WOLFSSL_SUCCESS;
}


int wolfSSL_set_SessionTicket_cb(WOLFSSL* ssl,
                                 CallbackSessionTicket cb, void* ctx)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    ssl->session_ticket_cb = cb;
    ssl->session_ticket_ctx = ctx;

    return WOLFSSL_SUCCESS;
}
#endif /* !NO_WOLFSSL_CLIENT */

#endif /* HAVE_SESSION_TICKET */


#ifdef HAVE_EXTENDED_MASTER
#ifndef NO_WOLFSSL_CLIENT

int wolfSSL_CTX_DisableExtendedMasterSecret(WOLFSSL_CTX* ctx)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;

    ctx->haveEMS = 0;

    return WOLFSSL_SUCCESS;
}


int wolfSSL_DisableExtendedMasterSecret(WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    ssl->options.haveEMS = 0;

    return WOLFSSL_SUCCESS;
}

#endif
#endif


#ifndef WOLFSSL_LEANPSK

int wolfSSL_send(WOLFSSL* ssl, const void* data, int sz, int flags)
{
    int ret;
    int oldFlags;

    WOLFSSL_ENTER("wolfSSL_send()");

    if (ssl == NULL || data == NULL || sz < 0)
        return BAD_FUNC_ARG;

    oldFlags = ssl->wflags;

    ssl->wflags = flags;
    ret = wolfSSL_write(ssl, data, sz);
    ssl->wflags = oldFlags;

    WOLFSSL_LEAVE("wolfSSL_send()", ret);

    return ret;
}


int wolfSSL_recv(WOLFSSL* ssl, void* data, int sz, int flags)
{
    int ret;
    int oldFlags;

    WOLFSSL_ENTER("wolfSSL_recv()");

    if (ssl == NULL || data == NULL || sz < 0)
        return BAD_FUNC_ARG;

    oldFlags = ssl->rflags;

    ssl->rflags = flags;
    ret = wolfSSL_read(ssl, data, sz);
    ssl->rflags = oldFlags;

    WOLFSSL_LEAVE("wolfSSL_recv()", ret);

    return ret;
}
#endif


/* WOLFSSL_SUCCESS on ok */
WOLFSSL_ABI
int wolfSSL_shutdown(WOLFSSL* ssl)
{
    int  ret = WOLFSSL_FATAL_ERROR;
    WOLFSSL_ENTER("SSL_shutdown()");

    if (ssl == NULL)
        return WOLFSSL_FATAL_ERROR;

    if (ssl->options.quietShutdown) {
        WOLFSSL_MSG("quiet shutdown, no close notify sent");
        ret = WOLFSSL_SUCCESS;
    }
    else {
        /* try to send close notify, not an error if can't */
        if (!ssl->options.isClosed && !ssl->options.connReset &&
                                      !ssl->options.sentNotify) {
            ssl->error = SendAlert(ssl, alert_warning, close_notify);
            if (ssl->error < 0) {
                WOLFSSL_ERROR(ssl->error);
                return WOLFSSL_FATAL_ERROR;
            }
            ssl->options.sentNotify = 1;  /* don't send close_notify twice */
            if (ssl->options.closeNotify)
                ret = WOLFSSL_SUCCESS;
            else {
                ret = WOLFSSL_SHUTDOWN_NOT_DONE;
                WOLFSSL_LEAVE("SSL_shutdown()", ret);
                return ret;
            }
        }

#ifdef WOLFSSL_SHUTDOWNONCE
        if (ssl->options.isClosed || ssl->options.connReset) {
            /* Shutdown has already occurred.
             * Caller is free to ignore this error. */
            return SSL_SHUTDOWN_ALREADY_DONE_E;
        }
#endif

        /* call wolfSSL_shutdown again for bidirectional shutdown */
        if (ssl->options.sentNotify && !ssl->options.closeNotify) {
            ret = ProcessReply(ssl);
            if (ret == ZERO_RETURN) {
                /* simulate OpenSSL behavior */
                ssl->error = WOLFSSL_ERROR_SYSCALL;
                ret = WOLFSSL_SUCCESS;
            } else if (ssl->error == WOLFSSL_ERROR_NONE) {
                ret = WOLFSSL_SHUTDOWN_NOT_DONE;
            } else {
                WOLFSSL_ERROR(ssl->error);
                ret = WOLFSSL_FATAL_ERROR;
            }
        }
    }

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
    /* reset WOLFSSL structure state for possible re-use */
    if (ret == WOLFSSL_SUCCESS) {
        if (wolfSSL_clear(ssl) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("could not clear WOLFSSL");
            ret = WOLFSSL_FATAL_ERROR;
        }
    }
#endif

    WOLFSSL_LEAVE("SSL_shutdown()", ret);

    return ret;
}


/* get current error state value */
int wolfSSL_state(WOLFSSL* ssl)
{
    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }

    return ssl->error;
}


WOLFSSL_ABI
int wolfSSL_get_error(WOLFSSL* ssl, int ret)
{
    WOLFSSL_ENTER("SSL_get_error");

    if (ret > 0)
        return WOLFSSL_ERROR_NONE;
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    WOLFSSL_LEAVE("SSL_get_error", ssl->error);

    /* make sure converted types are handled in SetErrorString() too */
    if (ssl->error == WANT_READ)
        return WOLFSSL_ERROR_WANT_READ;         /* convert to OpenSSL type */
    else if (ssl->error == WANT_WRITE)
        return WOLFSSL_ERROR_WANT_WRITE;        /* convert to OpenSSL type */
    else if (ssl->error == ZERO_RETURN)
        return WOLFSSL_ERROR_ZERO_RETURN;       /* convert to OpenSSL type */
    return ssl->error;
}


/* retrieve alert history, WOLFSSL_SUCCESS on ok */
int wolfSSL_get_alert_history(WOLFSSL* ssl, WOLFSSL_ALERT_HISTORY *h)
{
    if (ssl && h) {
        *h = ssl->alert_history;
    }
    return WOLFSSL_SUCCESS;
}

#ifdef OPENSSL_EXTRA
/* returns SSL_WRITING, SSL_READING or SSL_NOTHING */
int wolfSSL_want(WOLFSSL* ssl)
{
    int rw_state = SSL_NOTHING;
    if (ssl) {
        if (ssl->error == WANT_READ)
            rw_state = SSL_READING;
        else if (ssl->error == WANT_WRITE)
            rw_state = SSL_WRITING;
    }
    return rw_state;
}
#endif

/* return TRUE if current error is want read */
int wolfSSL_want_read(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("SSL_want_read");
    if (ssl->error == WANT_READ)
        return 1;

    return 0;
}


/* return TRUE if current error is want write */
int wolfSSL_want_write(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("SSL_want_write");
    if (ssl->error == WANT_WRITE)
        return 1;

    return 0;
}


char* wolfSSL_ERR_error_string(unsigned long errNumber, char* data)
{
    static char tmp[WOLFSSL_MAX_ERROR_SZ] = {0};

    WOLFSSL_ENTER("ERR_error_string");
    if (data) {
        SetErrorString((int)errNumber, data);
        return data;
    }
    else {
        SetErrorString((int)errNumber, tmp);
        return tmp;
    }
}


void wolfSSL_ERR_error_string_n(unsigned long e, char* buf, unsigned long len)
{
    WOLFSSL_ENTER("wolfSSL_ERR_error_string_n");
    if (len >= WOLFSSL_MAX_ERROR_SZ)
        wolfSSL_ERR_error_string(e, buf);
    else {
        char tmp[WOLFSSL_MAX_ERROR_SZ];

        WOLFSSL_MSG("Error buffer too short, truncating");
        if (len) {
            wolfSSL_ERR_error_string(e, tmp);
            XMEMCPY(buf, tmp, len-1);
            buf[len-1] = '\0';
        }
    }
}


/* don't free temporary arrays at end of handshake */
void wolfSSL_KeepArrays(WOLFSSL* ssl)
{
    if (ssl)
        ssl->options.saveArrays = 1;
}


/* user doesn't need temporary arrays anymore, Free */
void wolfSSL_FreeArrays(WOLFSSL* ssl)
{
    if (ssl && ssl->options.handShakeState == HANDSHAKE_DONE) {
        ssl->options.saveArrays = 0;
        FreeArrays(ssl, 1);
    }
}

/* Set option to indicate that the resources are not to be freed after
 * handshake.
 *
 * ssl  The SSL/TLS object.
 * returns BAD_FUNC_ARG when ssl is NULL and 0 on success.
 */
int wolfSSL_KeepHandshakeResources(WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    ssl->options.keepResources = 1;

    return 0;
}

/* Free the handshake resources after handshake.
 *
 * ssl  The SSL/TLS object.
 * returns BAD_FUNC_ARG when ssl is NULL and 0 on success.
 */
int wolfSSL_FreeHandshakeResources(WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    FreeHandshakeResources(ssl);

    return 0;
}

/* Use the client's order of preference when matching cipher suites.
 *
 * ssl  The SSL/TLS context object.
 * returns BAD_FUNC_ARG when ssl is NULL and 0 on success.
 */
int wolfSSL_CTX_UseClientSuites(WOLFSSL_CTX* ctx)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;

    ctx->useClientOrder = 1;

    return 0;
}

/* Use the client's order of preference when matching cipher suites.
 *
 * ssl  The SSL/TLS object.
 * returns BAD_FUNC_ARG when ssl is NULL and 0 on success.
 */
int wolfSSL_UseClientSuites(WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    ssl->options.useClientOrder = 1;

    return 0;
}

#ifdef WOLFSSL_DTLS
const byte* wolfSSL_GetDtlsMacSecret(WOLFSSL* ssl, int verify, int epochOrder)
{
#ifndef WOLFSSL_AEAD_ONLY
    Keys* keys = NULL;

    (void)epochOrder;

    if (ssl == NULL)
        return NULL;

#ifdef HAVE_SECURE_RENEGOTIATION
    switch (epochOrder) {
    case PEER_ORDER:
        if (IsDtlsMsgSCRKeys(ssl))
            keys = &ssl->secure_renegotiation->tmp_keys;
        else
            keys = &ssl->keys;
        break;
    case PREV_ORDER:
        keys = &ssl->keys;
        break;
    case CUR_ORDER:
        if (DtlsUseSCRKeys(ssl))
            keys = &ssl->secure_renegotiation->tmp_keys;
        else
            keys = &ssl->keys;
        break;
    default:
        WOLFSSL_MSG("Unknown epoch order");
        return NULL;
    }
#else
    keys = &ssl->keys;
#endif

    if ( (ssl->options.side == WOLFSSL_CLIENT_END && !verify) ||
         (ssl->options.side == WOLFSSL_SERVER_END &&  verify) )
        return keys->client_write_MAC_secret;
    else
        return keys->server_write_MAC_secret;
#else
    (void)ssl;
    (void)verify;
    (void)epochOrder;

    return NULL;
#endif
}
#endif /* WOLFSSL_DTLS */

const byte* wolfSSL_GetMacSecret(WOLFSSL* ssl, int verify)
{
#ifndef WOLFSSL_AEAD_ONLY
    if (ssl == NULL)
        return NULL;

    if ( (ssl->options.side == WOLFSSL_CLIENT_END && !verify) ||
         (ssl->options.side == WOLFSSL_SERVER_END &&  verify) )
        return ssl->keys.client_write_MAC_secret;
    else
        return ssl->keys.server_write_MAC_secret;
#else
    (void)ssl;
    (void)verify;

    return NULL;
#endif
}

int wolfSSL_GetSide(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->options.side;

    return BAD_FUNC_ARG;
}

#ifdef ATOMIC_USER

void  wolfSSL_CTX_SetMacEncryptCb(WOLFSSL_CTX* ctx, CallbackMacEncrypt cb)
{
    if (ctx)
        ctx->MacEncryptCb = cb;
}


void  wolfSSL_SetMacEncryptCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->MacEncryptCtx = ctx;
}


void* wolfSSL_GetMacEncryptCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->MacEncryptCtx;

    return NULL;
}


void  wolfSSL_CTX_SetDecryptVerifyCb(WOLFSSL_CTX* ctx, CallbackDecryptVerify cb)
{
    if (ctx)
        ctx->DecryptVerifyCb = cb;
}


void  wolfSSL_SetDecryptVerifyCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->DecryptVerifyCtx = ctx;
}


void* wolfSSL_GetDecryptVerifyCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->DecryptVerifyCtx;

    return NULL;
}

#if defined(HAVE_ENCRYPT_THEN_MAC) && !defined(WOLFSSL_AEAD_ONLY)
/**
 * Set the callback, against the context, that encrypts then MACs.
 *
 * ctx  SSL/TLS context.
 * cb   Callback function to use with Encrypt-Then-MAC.
 */
void  wolfSSL_CTX_SetEncryptMacCb(WOLFSSL_CTX* ctx, CallbackEncryptMac cb)
{
    if (ctx)
        ctx->EncryptMacCb = cb;
}

/**
 * Set the context to use with callback that encrypts then MACs.
 *
 * ssl  SSL/TLS object.
 * ctx  Callback function's context.
 */
void  wolfSSL_SetEncryptMacCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->EncryptMacCtx = ctx;
}

/**
 * Get the context being used with callback that encrypts then MACs.
 *
 * ssl  SSL/TLS object.
 * returns callback function's context or NULL if SSL/TLS object is NULL.
 */
void* wolfSSL_GetEncryptMacCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->EncryptMacCtx;

    return NULL;
}


/**
 * Set the callback, against the context, that MAC verifies then decrypts.
 *
 * ctx  SSL/TLS context.
 * cb   Callback function to use with Encrypt-Then-MAC.
 */
void  wolfSSL_CTX_SetVerifyDecryptCb(WOLFSSL_CTX* ctx, CallbackVerifyDecrypt cb)
{
    if (ctx)
        ctx->VerifyDecryptCb = cb;
}

/**
 * Set the context to use with callback that MAC verifies then decrypts.
 *
 * ssl  SSL/TLS object.
 * ctx  Callback function's context.
 */
void  wolfSSL_SetVerifyDecryptCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->VerifyDecryptCtx = ctx;
}

/**
 * Get the context being used with callback that MAC verifies then decrypts.
 *
 * ssl  SSL/TLS object.
 * returns callback function's context or NULL if SSL/TLS object is NULL.
 */
void* wolfSSL_GetVerifyDecryptCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->VerifyDecryptCtx;

    return NULL;
}
#endif /* HAVE_ENCRYPT_THEN_MAC !WOLFSSL_AEAD_ONLY */



const byte* wolfSSL_GetClientWriteKey(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->keys.client_write_key;

    return NULL;
}


const byte* wolfSSL_GetClientWriteIV(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->keys.client_write_IV;

    return NULL;
}


const byte* wolfSSL_GetServerWriteKey(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->keys.server_write_key;

    return NULL;
}


const byte* wolfSSL_GetServerWriteIV(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->keys.server_write_IV;

    return NULL;
}

int wolfSSL_GetKeySize(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->specs.key_size;

    return BAD_FUNC_ARG;
}


int wolfSSL_GetIVSize(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->specs.iv_size;

    return BAD_FUNC_ARG;
}


int wolfSSL_GetBulkCipher(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->specs.bulk_cipher_algorithm;

    return BAD_FUNC_ARG;
}


int wolfSSL_GetCipherType(WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

#ifndef WOLFSSL_AEAD_ONLY
    if (ssl->specs.cipher_type == block)
        return WOLFSSL_BLOCK_TYPE;
    if (ssl->specs.cipher_type == stream)
        return WOLFSSL_STREAM_TYPE;
#endif
    if (ssl->specs.cipher_type == aead)
        return WOLFSSL_AEAD_TYPE;

    return -1;
}


int wolfSSL_GetCipherBlockSize(WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    return ssl->specs.block_size;
}


int wolfSSL_GetAeadMacSize(WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    return ssl->specs.aead_mac_size;
}


int wolfSSL_IsTLSv1_1(WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    if (ssl->options.tls1_1)
        return 1;

    return 0;
}



int wolfSSL_GetHmacSize(WOLFSSL* ssl)
{
    /* AEAD ciphers don't have HMAC keys */
    if (ssl)
        return (ssl->specs.cipher_type != aead) ? ssl->specs.hash_size : 0;

    return BAD_FUNC_ARG;
}

#ifdef WORD64_AVAILABLE
int wolfSSL_GetPeerSequenceNumber(WOLFSSL* ssl, word64 *seq)
{
    if ((ssl == NULL) || (seq == NULL))
        return BAD_FUNC_ARG;

    *seq = ((word64)ssl->keys.peer_sequence_number_hi << 32) |
                    ssl->keys.peer_sequence_number_lo;
    return !(*seq);
}

int wolfSSL_GetSequenceNumber(WOLFSSL* ssl, word64 *seq)
{
    if ((ssl == NULL) || (seq == NULL))
        return BAD_FUNC_ARG;

    *seq = ((word64)ssl->keys.sequence_number_hi << 32) |
                    ssl->keys.sequence_number_lo;
    return !(*seq);
}
#endif

#endif /* ATOMIC_USER */

#ifndef NO_CERTS

WOLFSSL_CERT_MANAGER* wolfSSL_CTX_GetCertManager(WOLFSSL_CTX* ctx)
{
    WOLFSSL_CERT_MANAGER* cm = NULL;
    if (ctx)
        cm = ctx->cm;
    return cm;
}

WOLFSSL_CERT_MANAGER* wolfSSL_CertManagerNew_ex(void* heap)
{
    WOLFSSL_CERT_MANAGER* cm;

    WOLFSSL_ENTER("wolfSSL_CertManagerNew");

    cm = (WOLFSSL_CERT_MANAGER*) XMALLOC(sizeof(WOLFSSL_CERT_MANAGER), heap,
                                         DYNAMIC_TYPE_CERT_MANAGER);
    if (cm) {
        XMEMSET(cm, 0, sizeof(WOLFSSL_CERT_MANAGER));
        cm->refCount = 1;

        if (wc_InitMutex(&cm->caLock) != 0) {
            WOLFSSL_MSG("Bad mutex init");
            wolfSSL_CertManagerFree(cm);
            return NULL;
        }
        #ifndef SINGLE_THREADED
        if (wc_InitMutex(&cm->refMutex) != 0) {
            WOLFSSL_MSG("Bad mutex init");
            wolfSSL_CertManagerFree(cm);
            return NULL;
        }
        #endif

        #ifdef WOLFSSL_TRUST_PEER_CERT
        if (wc_InitMutex(&cm->tpLock) != 0) {
            WOLFSSL_MSG("Bad mutex init");
            wolfSSL_CertManagerFree(cm);
            return NULL;
        }
        #endif

        /* set default minimum key size allowed */
        #ifndef NO_RSA
            cm->minRsaKeySz = MIN_RSAKEY_SZ;
        #endif
        #ifdef HAVE_ECC
            cm->minEccKeySz = MIN_ECCKEY_SZ;
        #endif
        #ifdef HAVE_PQC
        #ifdef HAVE_FALCON
            cm->minFalconKeySz = MIN_FALCONKEY_SZ;
        #endif /* HAVE_FALCON */
        #ifdef HAVE_DILITHIUM
            cm->minDilithiumKeySz = MIN_DILITHIUMKEY_SZ;
        #endif /* HAVE_DILITHIUM */
        #endif /* HAVE_PQC */

            cm->heap = heap;
    }

    return cm;
}


WOLFSSL_CERT_MANAGER* wolfSSL_CertManagerNew(void)
{
    return wolfSSL_CertManagerNew_ex(NULL);
}


void wolfSSL_CertManagerFree(WOLFSSL_CERT_MANAGER* cm)
{
    int doFree = 0;
    WOLFSSL_ENTER("wolfSSL_CertManagerFree");

    if (cm) {
        #ifndef SINGLE_THREADED
        if (wc_LockMutex(&cm->refMutex) != 0) {
            WOLFSSL_MSG("Couldn't lock cm mutex");
        }
        #endif
        cm->refCount--;
        if (cm->refCount == 0)
            doFree = 1;
        #ifndef SINGLE_THREADED
        wc_UnLockMutex(&cm->refMutex);
        #endif
        if (doFree) {
            #ifdef HAVE_CRL
                if (cm->crl)
                    FreeCRL(cm->crl, 1);
            #endif
            #ifdef HAVE_OCSP
                if (cm->ocsp)
                    FreeOCSP(cm->ocsp, 1);
                XFREE(cm->ocspOverrideURL, cm->heap, DYNAMIC_TYPE_URL);
            #if !defined(NO_WOLFSSL_SERVER) && \
                (defined(HAVE_CERTIFICATE_STATUS_REQUEST) || \
                 defined(HAVE_CERTIFICATE_STATUS_REQUEST_V2))
                if (cm->ocsp_stapling)
                    FreeOCSP(cm->ocsp_stapling, 1);
            #endif
            #endif
            FreeSignerTable(cm->caTable, CA_TABLE_SIZE, cm->heap);
            wc_FreeMutex(&cm->caLock);

            #ifdef WOLFSSL_TRUST_PEER_CERT
            FreeTrustedPeerTable(cm->tpTable, TP_TABLE_SIZE, cm->heap);
            wc_FreeMutex(&cm->tpLock);
            #endif
            #ifndef SINGLE_THREADED
            if (wc_FreeMutex(&cm->refMutex) != 0) {
                WOLFSSL_MSG("Couldn't free refMutex mutex");
            }
            #endif
            XFREE(cm, cm->heap, DYNAMIC_TYPE_CERT_MANAGER);
        }
    }

}

int wolfSSL_CertManager_up_ref(WOLFSSL_CERT_MANAGER* cm)
{
    if (cm) {
#ifndef SINGLE_THREADED
        if (wc_LockMutex(&cm->refMutex) != 0) {
            WOLFSSL_MSG("Failed to lock cm mutex");
            return WOLFSSL_FAILURE;
        }
#endif
        cm->refCount++;
#ifndef SINGLE_THREADED
        wc_UnLockMutex(&cm->refMutex);
#endif

        return WOLFSSL_SUCCESS;
    }

    return WOLFSSL_FAILURE;
}

#if defined(OPENSSL_EXTRA) && !defined(NO_FILESYSTEM)
#if defined(WOLFSSL_SIGNER_DER_CERT)
/******************************************************************************
* wolfSSL_CertManagerGetCerts - retrieve stack of X509 certificates in a
* certificate manager (CM).
*
* RETURNS:
* returns stack of X509 certs on success, otherwise returns a NULL.
*/
WOLFSSL_STACK* wolfSSL_CertManagerGetCerts(WOLFSSL_CERT_MANAGER* cm)
{
    WOLFSSL_STACK* sk = NULL;
    int numCerts = 0;
    DerBuffer** certBuffers = NULL;
    const byte* derBuffer = NULL;
    Signer* signers = NULL;
    word32  row = 0;
    WOLFSSL_X509* x509 = NULL;
    int i = 0;
    int ret = 0;

    if (cm == NULL)
        return NULL;

    sk = wolfSSL_sk_X509_new_null();
    if (sk == NULL)
        goto error;

    if (wc_LockMutex(&cm->caLock) != 0)
        goto error;

    /* Iterate once to get the number of certs, for memory allocation
       purposes. */
    for (row = 0; row < CA_TABLE_SIZE; row++) {
        signers = cm->caTable[row];
        while (signers && signers->derCert && signers->derCert->buffer) {
            ++numCerts;
            signers = signers->next;
        }
    }

    if (numCerts == 0) {
        wc_UnLockMutex(&cm->caLock);
        goto error;
    }

    certBuffers = (DerBuffer**)XMALLOC(sizeof(DerBuffer*) * numCerts, cm->heap,
                                       DYNAMIC_TYPE_TMP_BUFFER);
    if (certBuffers == NULL) {
        wc_UnLockMutex(&cm->caLock);
        goto error;
    }
    XMEMSET(certBuffers, 0, sizeof(DerBuffer*) * numCerts);

    /* Copy the certs locally so that we can release the caLock. If the lock is
       held when wolfSSL_d2i_X509 is called, GetCA will also try to get the
       lock, leading to deadlock. */
    for (row = 0; row < CA_TABLE_SIZE; row++) {
        signers = cm->caTable[row];
        while (signers && signers->derCert && signers->derCert->buffer) {
            ret = AllocDer(&certBuffers[i], signers->derCert->length, CA_TYPE,
                           cm->heap);
            if (ret < 0) {
                wc_UnLockMutex(&cm->caLock);
                goto error;
            }

            XMEMCPY(certBuffers[i]->buffer, signers->derCert->buffer,
                    signers->derCert->length);
            certBuffers[i]->length = signers->derCert->length;

            ++i;
            signers = signers->next;
        }
    }

    wc_UnLockMutex(&cm->caLock);

    for (i = 0; i < numCerts; ++i) {
        derBuffer = certBuffers[i]->buffer;
        wolfSSL_d2i_X509(&x509, &derBuffer, certBuffers[i]->length);
        if (x509 == NULL)
            goto error;

        if (wolfSSL_sk_X509_push(sk, x509) != WOLFSSL_SUCCESS)
            goto error;
    }

    for (i = 0; i < numCerts && certBuffers[i] != NULL; ++i) {
        FreeDer(&certBuffers[i]);
    }

    XFREE(certBuffers, cm->heap, DYNAMIC_TYPE_TMP_BUFFER);

    return sk;

error:
    if (sk)
        wolfSSL_sk_X509_pop_free(sk, NULL);

    if (certBuffers != NULL) {
        for (i = 0; i < numCerts && certBuffers[i] != NULL; ++i) {
            FreeDer(&certBuffers[i]);
        }
    }

    if (certBuffers)
        XFREE(certBuffers, cm->heap, DYNAMIC_TYPE_TMP_BUFFER);

    return NULL;
}

#endif /* WOLFSSL_SIGNER_DER_CERT */
#endif /* OPENSSL_EXTRA && !NO_FILESYSTEM */

/* Unload the CA signer list */
int wolfSSL_CertManagerUnloadCAs(WOLFSSL_CERT_MANAGER* cm)
{
    WOLFSSL_ENTER("wolfSSL_CertManagerUnloadCAs");

    if (cm == NULL)
        return BAD_FUNC_ARG;

    if (wc_LockMutex(&cm->caLock) != 0)
        return BAD_MUTEX_E;

    FreeSignerTable(cm->caTable, CA_TABLE_SIZE, cm->heap);

    wc_UnLockMutex(&cm->caLock);


    return WOLFSSL_SUCCESS;
}


#ifdef WOLFSSL_TRUST_PEER_CERT
int wolfSSL_CertManagerUnload_trust_peers(WOLFSSL_CERT_MANAGER* cm)
{
    WOLFSSL_ENTER("wolfSSL_CertManagerUnload_trust_peers");

    if (cm == NULL)
        return BAD_FUNC_ARG;

    if (wc_LockMutex(&cm->tpLock) != 0)
        return BAD_MUTEX_E;

    FreeTrustedPeerTable(cm->tpTable, TP_TABLE_SIZE, cm->heap);

    wc_UnLockMutex(&cm->tpLock);


    return WOLFSSL_SUCCESS;
}
#endif /* WOLFSSL_TRUST_PEER_CERT */

#endif /* NO_CERTS */

#if !defined(NO_FILESYSTEM) && !defined(NO_STDIO_FILESYSTEM) \
    && defined(XFPRINTF)

void wolfSSL_ERR_print_errors_fp(XFILE fp, int err)
{
    char data[WOLFSSL_MAX_ERROR_SZ + 1];

    WOLFSSL_ENTER("wolfSSL_ERR_print_errors_fp");
    SetErrorString(err, data);
    if (XFPRINTF(fp, "%s", data) < 0)
        WOLFSSL_MSG("fprintf failed in wolfSSL_ERR_print_errors_fp");
}

#if defined(OPENSSL_EXTRA) || defined(DEBUG_WOLFSSL_VERBOSE)
void wolfSSL_ERR_dump_errors_fp(XFILE fp)
{
    wc_ERR_print_errors_fp(fp);
}

void wolfSSL_ERR_print_errors_cb (int (*cb)(const char *str, size_t len,
                                            void *u), void *u)
{
    wc_ERR_print_errors_cb(cb, u);
}
#endif
#endif /* !NO_FILESYSTEM && !NO_STDIO_FILESYSTEM && XFPRINTF */

/*
 * TODO This ssl parameter needs to be changed to const once our ABI checker
 *      stops flagging qualifier additions as ABI breaking.
 */
WOLFSSL_ABI
int wolfSSL_pending(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("SSL_pending");
    if (ssl == NULL)
        return WOLFSSL_FAILURE;

    return ssl->buffers.clearOutputBuffer.length;
}

int wolfSSL_has_pending(const WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_has_pending");
    if (ssl == NULL)
        return WOLFSSL_FAILURE;

    return ssl->buffers.clearOutputBuffer.length > 0;
}

#ifndef WOLFSSL_LEANPSK
/* turn on handshake group messages for context */
int wolfSSL_CTX_set_group_messages(WOLFSSL_CTX* ctx)
{
    if (ctx == NULL)
       return BAD_FUNC_ARG;

    ctx->groupMessages = 1;

    return WOLFSSL_SUCCESS;
}
#endif


#ifndef NO_WOLFSSL_CLIENT
/* connect enough to get peer cert chain */
int wolfSSL_connect_cert(WOLFSSL* ssl)
{
    int  ret;

    if (ssl == NULL)
        return WOLFSSL_FAILURE;

    ssl->options.certOnly = 1;
    ret = wolfSSL_connect(ssl);
    ssl->options.certOnly   = 0;

    return ret;
}
#endif


#ifndef WOLFSSL_LEANPSK
/* turn on handshake group messages for ssl object */
int wolfSSL_set_group_messages(WOLFSSL* ssl)
{
    if (ssl == NULL)
       return BAD_FUNC_ARG;

    ssl->options.groupMessages = 1;

    return WOLFSSL_SUCCESS;
}


/* make minVersion the internal equivalent SSL version */
static int SetMinVersionHelper(byte* minVersion, int version)
{
#ifdef NO_TLS
    (void)minVersion;
#endif

    switch (version) {
#if defined(WOLFSSL_ALLOW_SSLV3) && !defined(NO_OLD_TLS)
        case WOLFSSL_SSLV3:
            *minVersion = SSLv3_MINOR;
            break;
#endif

#ifndef NO_TLS
    #ifndef NO_OLD_TLS
        #ifdef WOLFSSL_ALLOW_TLSV10
        case WOLFSSL_TLSV1:
            *minVersion = TLSv1_MINOR;
            break;
        #endif

        case WOLFSSL_TLSV1_1:
            *minVersion = TLSv1_1_MINOR;
            break;
    #endif
    #ifndef WOLFSSL_NO_TLS12
        case WOLFSSL_TLSV1_2:
            *minVersion = TLSv1_2_MINOR;
            break;
    #endif
#endif
    #ifdef WOLFSSL_TLS13
        case WOLFSSL_TLSV1_3:
            *minVersion = TLSv1_3_MINOR;
            break;
    #endif

#ifdef WOLFSSL_DTLS
        case WOLFSSL_DTLSV1:
            *minVersion = DTLS_MINOR;
            break;
        case WOLFSSL_DTLSV1_2:
            *minVersion = DTLSv1_2_MINOR;
            break;
#ifdef WOLFSSL_DTLS13
        case WOLFSSL_DTLSV1_3:
            *minVersion = DTLSv1_3_MINOR;
            break;
#endif /* WOLFSSL_DTLS13 */
#endif /* WOLFSSL_DTLS */

        default:
            WOLFSSL_MSG("Bad function argument");
            return BAD_FUNC_ARG;
    }

    return WOLFSSL_SUCCESS;
}


/* Set minimum downgrade version allowed, WOLFSSL_SUCCESS on ok */
WOLFSSL_ABI
int wolfSSL_CTX_SetMinVersion(WOLFSSL_CTX* ctx, int version)
{
    WOLFSSL_ENTER("wolfSSL_CTX_SetMinVersion");

    if (ctx == NULL) {
        WOLFSSL_MSG("Bad function argument");
        return BAD_FUNC_ARG;
    }

    return SetMinVersionHelper(&ctx->minDowngrade, version);
}


/* Set minimum downgrade version allowed, WOLFSSL_SUCCESS on ok */
int wolfSSL_SetMinVersion(WOLFSSL* ssl, int version)
{
    WOLFSSL_ENTER("wolfSSL_SetMinVersion");

    if (ssl == NULL) {
        WOLFSSL_MSG("Bad function argument");
        return BAD_FUNC_ARG;
    }

    return SetMinVersionHelper(&ssl->options.minDowngrade, version);
}


/* Function to get version as WOLFSSL_ enum value for wolfSSL_SetVersion */
int wolfSSL_GetVersion(const WOLFSSL* ssl)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    if (ssl->version.major == SSLv3_MAJOR) {
        switch (ssl->version.minor) {
            case SSLv3_MINOR :
                return WOLFSSL_SSLV3;
            case TLSv1_MINOR :
                return WOLFSSL_TLSV1;
            case TLSv1_1_MINOR :
                return WOLFSSL_TLSV1_1;
            case TLSv1_2_MINOR :
                return WOLFSSL_TLSV1_2;
            case TLSv1_3_MINOR :
                return WOLFSSL_TLSV1_3;
            default:
                break;
        }
    }

    return VERSION_ERROR;
}

int wolfSSL_SetVersion(WOLFSSL* ssl, int version)
{
    word16 haveRSA = 1;
    word16 havePSK = 0;
    int    keySz   = 0;

    WOLFSSL_ENTER("wolfSSL_SetVersion");

    if (ssl == NULL) {
        WOLFSSL_MSG("Bad function argument");
        return BAD_FUNC_ARG;
    }

    switch (version) {
#if defined(WOLFSSL_ALLOW_SSLV3) && !defined(NO_OLD_TLS)
        case WOLFSSL_SSLV3:
            ssl->version = MakeSSLv3();
            break;
#endif

#ifndef NO_TLS
    #ifndef NO_OLD_TLS
        #ifdef WOLFSSL_ALLOW_TLSV10
        case WOLFSSL_TLSV1:
            ssl->version = MakeTLSv1();
            break;
        #endif

        case WOLFSSL_TLSV1_1:
            ssl->version = MakeTLSv1_1();
            break;
    #endif
    #ifndef WOLFSSL_NO_TLS12
        case WOLFSSL_TLSV1_2:
            ssl->version = MakeTLSv1_2();
            break;
    #endif

    #ifdef WOLFSSL_TLS13
        case WOLFSSL_TLSV1_3:
            ssl->version = MakeTLSv1_3();
            break;
    #endif /* WOLFSSL_TLS13 */
#endif

        default:
            WOLFSSL_MSG("Bad function argument");
            return BAD_FUNC_ARG;
    }

    #ifdef NO_RSA
        haveRSA = 0;
    #endif
    #ifndef NO_PSK
        havePSK = ssl->options.havePSK;
    #endif
    #ifndef NO_CERTS
        keySz = ssl->buffers.keySz;
    #endif

    InitSuites(ssl->suites, ssl->version, keySz, haveRSA, havePSK,
               ssl->options.haveDH, ssl->options.haveECDSAsig,
               ssl->options.haveECC, TRUE, ssl->options.haveStaticECC,
               ssl->options.haveFalconSig, ssl->options.haveDilithiumSig,
               ssl->options.haveAnon, TRUE, ssl->options.side);
    return WOLFSSL_SUCCESS;
}
#endif /* !leanpsk */

#ifndef NO_CERTS

/* hash is the SHA digest of name, just use first 32 bits as hash */
static WC_INLINE word32 HashSigner(const byte* hash)
{
    return MakeWordFromHash(hash) % CA_TABLE_SIZE;
}


/* does CA already exist on signer list */
int AlreadySigner(WOLFSSL_CERT_MANAGER* cm, byte* hash)
{
    Signer* signers;
    int     ret = 0;
    word32  row;

    if (cm == NULL || hash == NULL) {
        return ret;
    }

    row = HashSigner(hash);

    if (wc_LockMutex(&cm->caLock) != 0) {
        return ret;
    }
    signers = cm->caTable[row];
    while (signers) {
        byte* subjectHash;

    #ifndef NO_SKID
        subjectHash = signers->subjectKeyIdHash;
    #else
        subjectHash = signers->subjectNameHash;
    #endif

        if (XMEMCMP(hash, subjectHash, SIGNER_DIGEST_SIZE) == 0) {
            ret = 1; /* success */
            break;
        }
        signers = signers->next;
    }
    wc_UnLockMutex(&cm->caLock);

    return ret;
}


#ifdef WOLFSSL_TRUST_PEER_CERT
/* hash is the SHA digest of name, just use first 32 bits as hash */
static WC_INLINE word32 TrustedPeerHashSigner(const byte* hash)
{
    return MakeWordFromHash(hash) % TP_TABLE_SIZE;
}

/* does trusted peer already exist on signer list */
int AlreadyTrustedPeer(WOLFSSL_CERT_MANAGER* cm, DecodedCert* cert)
{
    TrustedPeerCert* tp;
    int     ret = 0;
    word32  row = TrustedPeerHashSigner(cert->subjectHash);

    if (wc_LockMutex(&cm->tpLock) != 0)
        return  ret;
    tp = cm->tpTable[row];
    while (tp) {
        if (XMEMCMP(cert->subjectHash, tp->subjectNameHash,
                SIGNER_DIGEST_SIZE) == 0)
            ret = 1;
    #ifndef NO_SKID
        if (cert->extSubjKeyIdSet) {
            /* Compare SKID as well if available */
            if (ret == 1 && XMEMCMP(cert->extSubjKeyId, tp->subjectKeyIdHash,
                    SIGNER_DIGEST_SIZE) != 0)
                ret = 0;
        }
    #endif
        if (ret == 1)
            break;
        tp = tp->next;
    }
    wc_UnLockMutex(&cm->tpLock);

    return ret;
}


/* return Trusted Peer if found, otherwise NULL
    type is what to match on
 */
TrustedPeerCert* GetTrustedPeer(void* vp, DecodedCert* cert)
{
    WOLFSSL_CERT_MANAGER* cm = (WOLFSSL_CERT_MANAGER*)vp;
    TrustedPeerCert* ret = NULL;
    TrustedPeerCert* tp  = NULL;
    word32  row;

    if (cm == NULL || cert == NULL)
        return NULL;

    row = TrustedPeerHashSigner(cert->subjectHash);

    if (wc_LockMutex(&cm->tpLock) != 0)
        return ret;

    tp = cm->tpTable[row];
    while (tp) {
        if (XMEMCMP(cert->subjectHash, tp->subjectNameHash,
                SIGNER_DIGEST_SIZE) == 0)
            ret = tp;
    #ifndef NO_SKID
        if (cert->extSubjKeyIdSet) {
            /* Compare SKID as well if available */
            if (ret != NULL && XMEMCMP(cert->extSubjKeyId, tp->subjectKeyIdHash,
                    SIGNER_DIGEST_SIZE) != 0)
                ret = NULL;
        }
    #endif
        if (ret != NULL)
            break;
        tp = tp->next;
    }
    wc_UnLockMutex(&cm->tpLock);

    return ret;
}


int MatchTrustedPeer(TrustedPeerCert* tp, DecodedCert* cert)
{
    if (tp == NULL || cert == NULL)
        return BAD_FUNC_ARG;

    /* subject key id or subject hash has been compared when searching
       tpTable for the cert from function GetTrustedPeer */

    /* compare signatures */
    if (tp->sigLen == cert->sigLength) {
        if (XMEMCMP(tp->sig, cert->signature, cert->sigLength)) {
            return WOLFSSL_FAILURE;
        }
    }
    else {
        return WOLFSSL_FAILURE;
    }

    return WOLFSSL_SUCCESS;
}
#endif /* WOLFSSL_TRUST_PEER_CERT */


/* return CA if found, otherwise NULL */
Signer* GetCA(void* vp, byte* hash)
{
    WOLFSSL_CERT_MANAGER* cm = (WOLFSSL_CERT_MANAGER*)vp;
    Signer* ret = NULL;
    Signer* signers;
    word32  row = 0;

    if (cm == NULL || hash == NULL)
        return NULL;

    row = HashSigner(hash);

    if (wc_LockMutex(&cm->caLock) != 0)
        return ret;

    signers = cm->caTable[row];
    while (signers) {
        byte* subjectHash;
        #ifndef NO_SKID
            subjectHash = signers->subjectKeyIdHash;
        #else
            subjectHash = signers->subjectNameHash;
        #endif
        if (XMEMCMP(hash, subjectHash, SIGNER_DIGEST_SIZE) == 0) {
            ret = signers;
            break;
        }
        signers = signers->next;
    }
    wc_UnLockMutex(&cm->caLock);

    return ret;
}


#ifndef NO_SKID
/* return CA if found, otherwise NULL. Walk through hash table. */
Signer* GetCAByName(void* vp, byte* hash)
{
    WOLFSSL_CERT_MANAGER* cm = (WOLFSSL_CERT_MANAGER*)vp;
    Signer* ret = NULL;
    Signer* signers;
    word32  row;

    if (cm == NULL)
        return NULL;

    if (wc_LockMutex(&cm->caLock) != 0)
        return ret;

    for (row = 0; row < CA_TABLE_SIZE && ret == NULL; row++) {
        signers = cm->caTable[row];
        while (signers && ret == NULL) {
            if (XMEMCMP(hash, signers->subjectNameHash,
                        SIGNER_DIGEST_SIZE) == 0) {
                ret = signers;
            }
            signers = signers->next;
        }
    }
    wc_UnLockMutex(&cm->caLock);

    return ret;
}
#endif


#ifdef WOLFSSL_TRUST_PEER_CERT
/* add a trusted peer cert to linked list */
int AddTrustedPeer(WOLFSSL_CERT_MANAGER* cm, DerBuffer** pDer, int verify)
{
    int ret, row;
    TrustedPeerCert* peerCert;
    DecodedCert* cert;
    DerBuffer*   der = *pDer;

    WOLFSSL_MSG("Adding a Trusted Peer Cert");

    cert = (DecodedCert*)XMALLOC(sizeof(DecodedCert), cm->heap,
                                 DYNAMIC_TYPE_DCERT);
    if (cert == NULL) {
        FreeDer(&der);
        return MEMORY_E;
    }

    InitDecodedCert(cert, der->buffer, der->length, cm->heap);
    if ((ret = ParseCert(cert, TRUSTED_PEER_TYPE, verify, cm)) != 0) {
        FreeDecodedCert(cert);
        XFREE(cert, NULL, DYNAMIC_TYPE_DCERT);
        FreeDer(&der);
        return ret;
    }
    WOLFSSL_MSG("\tParsed new trusted peer cert");

    peerCert = (TrustedPeerCert*)XMALLOC(sizeof(TrustedPeerCert), cm->heap,
                                                             DYNAMIC_TYPE_CERT);
    if (peerCert == NULL) {
        FreeDecodedCert(cert);
        XFREE(cert, cm->heap, DYNAMIC_TYPE_DCERT);
        FreeDer(&der);
        return MEMORY_E;
    }
    XMEMSET(peerCert, 0, sizeof(TrustedPeerCert));

    #ifndef IGNORE_NAME_CONSTRAINTS
        if (peerCert->permittedNames)
            FreeNameSubtrees(peerCert->permittedNames, cm->heap);
        if (peerCert->excludedNames)
            FreeNameSubtrees(peerCert->excludedNames, cm->heap);
    #endif

    if (AlreadyTrustedPeer(cm, cert)) {
        WOLFSSL_MSG("\tAlready have this CA, not adding again");
        FreeTrustedPeer(peerCert, cm->heap);
        (void)ret;
    }
    else {
        /* add trusted peer signature */
        peerCert->sigLen = cert->sigLength;
        peerCert->sig = (byte *)XMALLOC(cert->sigLength, cm->heap,
                                                        DYNAMIC_TYPE_SIGNATURE);
        if (peerCert->sig == NULL) {
            FreeDecodedCert(cert);
            XFREE(cert, cm->heap, DYNAMIC_TYPE_DCERT);
            FreeTrustedPeer(peerCert, cm->heap);
            FreeDer(&der);
            return MEMORY_E;
        }
        XMEMCPY(peerCert->sig, cert->signature, cert->sigLength);

        /* add trusted peer name */
        peerCert->nameLen = cert->subjectCNLen;
        peerCert->name    = cert->subjectCN;
        #ifndef IGNORE_NAME_CONSTRAINTS
            peerCert->permittedNames = cert->permittedNames;
            peerCert->excludedNames  = cert->excludedNames;
        #endif

        /* add SKID when available and hash of name */
        #ifndef NO_SKID
            XMEMCPY(peerCert->subjectKeyIdHash, cert->extSubjKeyId,
                    SIGNER_DIGEST_SIZE);
        #endif
            XMEMCPY(peerCert->subjectNameHash, cert->subjectHash,
                    SIGNER_DIGEST_SIZE);
            peerCert->next    = NULL; /* If Key Usage not set, all uses valid. */
            cert->subjectCN = 0;
        #ifndef IGNORE_NAME_CONSTRAINTS
            cert->permittedNames = NULL;
            cert->excludedNames = NULL;
        #endif

            row = TrustedPeerHashSigner(peerCert->subjectNameHash);

            if (wc_LockMutex(&cm->tpLock) == 0) {
                peerCert->next = cm->tpTable[row];
                cm->tpTable[row] = peerCert;   /* takes ownership */
                wc_UnLockMutex(&cm->tpLock);
            }
            else {
                WOLFSSL_MSG("\tTrusted Peer Cert Mutex Lock failed");
                FreeDecodedCert(cert);
                XFREE(cert, cm->heap, DYNAMIC_TYPE_DCERT);
                FreeTrustedPeer(peerCert, cm->heap);
                FreeDer(&der);
                return BAD_MUTEX_E;
            }
        }

    WOLFSSL_MSG("\tFreeing parsed trusted peer cert");
    FreeDecodedCert(cert);
    XFREE(cert, cm->heap, DYNAMIC_TYPE_DCERT);
    WOLFSSL_MSG("\tFreeing der trusted peer cert");
    FreeDer(&der);
    WOLFSSL_MSG("\t\tOK Freeing der trusted peer cert");
    WOLFSSL_LEAVE("AddTrustedPeer", ret);

    return WOLFSSL_SUCCESS;
}
#endif /* WOLFSSL_TRUST_PEER_CERT */


/* owns der, internal now uses too */
/* type flag ids from user or from chain received during verify
   don't allow chain ones to be added w/o isCA extension */
int AddCA(WOLFSSL_CERT_MANAGER* cm, DerBuffer** pDer, int type, int verify)
{
    int         ret;
    Signer*     signer = NULL;
    word32      row;
    byte*       subjectHash;
#ifdef WOLFSSL_SMALL_STACK
    DecodedCert* cert = NULL;
#else
    DecodedCert  cert[1];
#endif
    DerBuffer*   der = *pDer;

    WOLFSSL_MSG("Adding a CA");

    if (cm == NULL) {
        FreeDer(pDer);
        return BAD_FUNC_ARG;
    }

#ifdef WOLFSSL_SMALL_STACK
    cert = (DecodedCert*)XMALLOC(sizeof(DecodedCert), NULL,
                                 DYNAMIC_TYPE_DCERT);
    if (cert == NULL) {
        FreeDer(pDer);
        return MEMORY_E;
    }
#endif

    InitDecodedCert(cert, der->buffer, der->length, cm->heap);
    ret = ParseCert(cert, CA_TYPE, verify, cm);
    WOLFSSL_MSG("\tParsed new CA");

#ifndef NO_SKID
    subjectHash = cert->extSubjKeyId;
#else
    subjectHash = cert->subjectHash;
#endif

    /* check CA key size */
    if (verify) {
        switch (cert->keyOID) {
        #ifndef NO_RSA
            #ifdef WC_RSA_PSS
            case RSAPSSk:
            #endif
            case RSAk:
                if (cm->minRsaKeySz < 0 ||
                                   cert->pubKeySize < (word16)cm->minRsaKeySz) {
                    ret = RSA_KEY_SIZE_E;
                    WOLFSSL_MSG("\tCA RSA key size error");
                }
                break;
        #endif /* !NO_RSA */
            #ifdef HAVE_ECC
            case ECDSAk:
                if (cm->minEccKeySz < 0 ||
                                   cert->pubKeySize < (word16)cm->minEccKeySz) {
                    ret = ECC_KEY_SIZE_E;
                    WOLFSSL_MSG("\tCA ECC key size error");
                }
                break;
            #endif /* HAVE_ECC */
            #ifdef HAVE_ED25519
            case ED25519k:
                if (cm->minEccKeySz < 0 ||
                                   ED25519_KEY_SIZE < (word16)cm->minEccKeySz) {
                    ret = ECC_KEY_SIZE_E;
                    WOLFSSL_MSG("\tCA ECC key size error");
                }
                break;
            #endif /* HAVE_ED25519 */
            #ifdef HAVE_ED448
            case ED448k:
                if (cm->minEccKeySz < 0 ||
                                     ED448_KEY_SIZE < (word16)cm->minEccKeySz) {
                    ret = ECC_KEY_SIZE_E;
                    WOLFSSL_MSG("\tCA ECC key size error");
                }
                break;
            #endif /* HAVE_ED448 */
            #if defined(HAVE_PQC)
            #if defined(HAVE_FALCON)
            case FALCON_LEVEL1k:
                if (cm->minFalconKeySz < 0 ||
                          FALCON_LEVEL1_KEY_SIZE < (word16)cm->minFalconKeySz) {
                    ret = FALCON_KEY_SIZE_E;
                    WOLFSSL_MSG("\tCA Falcon level 1 key size error");
                }
                break;
            case FALCON_LEVEL5k:
                if (cm->minFalconKeySz < 0 ||
                          FALCON_LEVEL5_KEY_SIZE < (word16)cm->minFalconKeySz) {
                    ret = FALCON_KEY_SIZE_E;
                    WOLFSSL_MSG("\tCA Falcon level 5 key size error");
                }
                break;
            #endif /* HAVE_FALCON */
            #if defined(HAVE_DILITHIUM)
            case DILITHIUM_LEVEL2k:
                if (cm->minDilithiumKeySz < 0 ||
                    DILITHIUM_LEVEL2_KEY_SIZE < (word16)cm->minDilithiumKeySz) {
                    ret = DILITHIUM_KEY_SIZE_E;
                    WOLFSSL_MSG("\tCA Dilithium level 2 key size error");
                }
                break;
            case DILITHIUM_LEVEL3k:
                if (cm->minDilithiumKeySz < 0 ||
                    DILITHIUM_LEVEL3_KEY_SIZE < (word16)cm->minDilithiumKeySz) {
                    ret = DILITHIUM_KEY_SIZE_E;
                    WOLFSSL_MSG("\tCA Dilithium level 3 key size error");
                }
                break;
            case DILITHIUM_LEVEL5k:
                if (cm->minDilithiumKeySz < 0 ||
                    DILITHIUM_LEVEL5_KEY_SIZE < (word16)cm->minDilithiumKeySz) {
                    ret = DILITHIUM_KEY_SIZE_E;
                    WOLFSSL_MSG("\tCA Dilithium level 5 key size error");
                }
                break;
            #endif /* HAVE_DILITHIUM */
            #endif /* HAVE_PQC */

            default:
                WOLFSSL_MSG("\tNo key size check done on CA");
                break; /* no size check if key type is not in switch */
        }
    }

    if (ret == 0 && cert->isCA == 0 && type != WOLFSSL_USER_CA) {
        WOLFSSL_MSG("\tCan't add as CA if not actually one");
        ret = NOT_CA_ERROR;
    }
#ifndef ALLOW_INVALID_CERTSIGN
    else if (ret == 0 && cert->isCA == 1 && type != WOLFSSL_USER_CA &&
        !cert->selfSigned && (cert->extKeyUsage & KEYUSE_KEY_CERT_SIGN) == 0) {
        /* Intermediate CA certs are required to have the keyCertSign
        * extension set. User loaded root certs are not. */
        WOLFSSL_MSG("\tDoesn't have key usage certificate signing");
        ret = NOT_CA_ERROR;
    }
#endif
    else if (ret == 0 && AlreadySigner(cm, subjectHash)) {
        WOLFSSL_MSG("\tAlready have this CA, not adding again");
        (void)ret;
    }
    else if (ret == 0) {
        /* take over signer parts */
        signer = MakeSigner(cm->heap);
        if (!signer)
            ret = MEMORY_ERROR;
    }
    if (ret == 0 && signer != NULL) {
    #ifdef WOLFSSL_SIGNER_DER_CERT
        ret = AllocDer(&signer->derCert, der->length, der->type, NULL);
    }
    if (ret == 0 && signer != NULL) {
        XMEMCPY(signer->derCert->buffer, der->buffer, der->length);
    #endif
        signer->keyOID         = cert->keyOID;
        if (cert->pubKeyStored) {
            signer->publicKey      = cert->publicKey;
            signer->pubKeySize     = cert->pubKeySize;
        }
        if (cert->subjectCNStored) {
            signer->nameLen        = cert->subjectCNLen;
            signer->name           = cert->subjectCN;
        }
        signer->pathLength     = cert->pathLength;
        signer->maxPathLen     = cert->maxPathLen;
        signer->pathLengthSet  = cert->pathLengthSet;
        signer->selfSigned     = cert->selfSigned;
    #ifndef IGNORE_NAME_CONSTRAINTS
        signer->permittedNames = cert->permittedNames;
        signer->excludedNames  = cert->excludedNames;
    #endif
    #ifndef NO_SKID
        XMEMCPY(signer->subjectKeyIdHash, cert->extSubjKeyId,
                SIGNER_DIGEST_SIZE);
    #endif
        XMEMCPY(signer->subjectNameHash, cert->subjectHash,
                SIGNER_DIGEST_SIZE);
    #ifdef HAVE_OCSP
        XMEMCPY(signer->subjectKeyHash, cert->subjectKeyHash,
                KEYID_SIZE);
    #endif
        signer->keyUsage = cert->extKeyUsageSet ? cert->extKeyUsage
                                                : 0xFFFF;
        signer->next    = NULL; /* If Key Usage not set, all uses valid. */
        cert->publicKey = 0;    /* in case lock fails don't free here.   */
        cert->subjectCN = 0;
    #ifndef IGNORE_NAME_CONSTRAINTS
        cert->permittedNames = NULL;
        cert->excludedNames = NULL;
    #endif

    #ifndef NO_SKID
        row = HashSigner(signer->subjectKeyIdHash);
    #else
        row = HashSigner(signer->subjectNameHash);
    #endif

        if (wc_LockMutex(&cm->caLock) == 0) {
            signer->next = cm->caTable[row];
            cm->caTable[row] = signer;   /* takes ownership */
            wc_UnLockMutex(&cm->caLock);
            if (cm->caCacheCallback)
                cm->caCacheCallback(der->buffer, (int)der->length, type);
        }
        else {
            WOLFSSL_MSG("\tCA Mutex Lock failed");
            ret = BAD_MUTEX_E;
        }
    }
#if defined(WOLFSSL_RENESAS_TSIP_TLS) || defined(WOLFSSL_RENESAS_SCEPROTECT)
    /* Verify CA by TSIP so that generated tsip key is going to be able to */
    /* be used for peer's cert verification                                */
    /* TSIP is only able to handle USER CA, and only one CA.               */
    /* Therefore, it doesn't need to call TSIP again if there is already   */
    /* verified CA.                                                        */
    if ( ret == 0 && signer != NULL ) {
        signer->cm_idx = row;
        if (type == WOLFSSL_USER_CA) {
            if ((ret = wc_Renesas_cmn_RootCertVerify(cert->source, cert->maxIdx,
                 cert->sigCtx.CertAtt.pubkey_n_start,
                 cert->sigCtx.CertAtt.pubkey_n_len - 1,
                 cert->sigCtx.CertAtt.pubkey_e_start,
                cert->sigCtx.CertAtt.pubkey_e_len - 1,
                 row/* cm index */))
                < 0)
                WOLFSSL_MSG("Renesas_RootCertVerify() failed");
            else
                WOLFSSL_MSG("Renesas_RootCertVerify() succeed or skipped");
        }
    }
#endif /* TSIP or SCE */

    WOLFSSL_MSG("\tFreeing Parsed CA");
    FreeDecodedCert(cert);
    if (ret != 0 && signer != NULL)
        FreeSigner(signer, cm->heap);
#ifdef WOLFSSL_SMALL_STACK
    XFREE(cert, NULL, DYNAMIC_TYPE_DCERT);
#endif
    WOLFSSL_MSG("\tFreeing der CA");
    FreeDer(pDer);
    WOLFSSL_MSG("\t\tOK Freeing der CA");

    WOLFSSL_LEAVE("AddCA", ret);

    return ret == 0 ? WOLFSSL_SUCCESS : ret;
}

#endif /* !NO_CERTS */


#ifndef NO_SESSION_CACHE

    /* basic config gives a cache with 33 sessions, adequate for clients and
       embedded servers

       TITAN_SESSION_CACHE allows just over 2 million sessions, for servers
       with titanic amounts of memory with long session ID timeouts and high
       levels of traffic.

       ENABLE_SESSION_CACHE_ROW_LOCK: Allows row level locking for increased
       performance with large session caches

       HUGE_SESSION_CACHE yields 65,791 sessions, for servers under heavy load,
       allows over 13,000 new sessions per minute or over 200 new sessions per
       second

       BIG_SESSION_CACHE yields 20,027 sessions

       MEDIUM_SESSION_CACHE allows 1055 sessions, adequate for servers that
       aren't under heavy load, basically allows 200 new sessions per minute

       SMALL_SESSION_CACHE only stores 6 sessions, good for embedded clients
       or systems where the default of nearly 3kB is too much RAM, this define
       uses less than 500 bytes RAM

       default SESSION_CACHE stores 33 sessions (no XXX_SESSION_CACHE defined)
    */
    #if defined(TITAN_SESSION_CACHE)
        #define SESSIONS_PER_ROW 31
        #define SESSION_ROWS 64937
        #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
        #define ENABLE_SESSION_CACHE_ROW_LOCK
        #endif
    #elif defined(HUGE_SESSION_CACHE)
        #define SESSIONS_PER_ROW 11
        #define SESSION_ROWS 5981
    #elif defined(BIG_SESSION_CACHE)
        #define SESSIONS_PER_ROW 7
        #define SESSION_ROWS 2861
    #elif defined(MEDIUM_SESSION_CACHE)
        #define SESSIONS_PER_ROW 5
        #define SESSION_ROWS 211
    #elif defined(SMALL_SESSION_CACHE)
        #define SESSIONS_PER_ROW 2
        #define SESSION_ROWS 3
    #else
        #define SESSIONS_PER_ROW 3
        #define SESSION_ROWS 11
    #endif
    #define INVALID_SESSION_ROW (-1)

    #ifdef NO_SESSION_CACHE_ROW_LOCK
        #undef ENABLE_SESSION_CACHE_ROW_LOCK
    #endif

    typedef struct SessionRow {
        int nextIdx;                           /* where to place next one   */
        int totalCount;                        /* sessions ever on this row */
        WOLFSSL_SESSION Sessions[SESSIONS_PER_ROW];

    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
        /* not included in import/export */
        wolfSSL_Mutex row_mutex;
        int mutex_valid;
    #endif
    } SessionRow;
    #define SIZEOF_SESSION_ROW (sizeof(WOLFSSL_SESSION) + (sizeof(int) * 2))

    static WOLFSSL_GLOBAL SessionRow SessionCache[SESSION_ROWS];

    #if defined(WOLFSSL_SESSION_STATS) && defined(WOLFSSL_PEAK_SESSIONS)
        static WOLFSSL_GLOBAL word32 PeakSessions;
    #endif

    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
    #define SESSION_ROW_LOCK(row)   wc_LockMutex(&(row)->row_mutex)
    #define SESSION_ROW_UNLOCK(row) wc_UnLockMutex(&(row)->row_mutex);
    #else
    static WOLFSSL_GLOBAL wolfSSL_Mutex session_mutex; /* SessionCache mutex */
    static WOLFSSL_GLOBAL int session_mutex_valid = 0;
    #define SESSION_ROW_LOCK(row)   wc_LockMutex(&session_mutex)
    #define SESSION_ROW_UNLOCK(row) wc_UnLockMutex(&session_mutex);
    #endif

    #if !defined(NO_SESSION_CACHE_REF) && defined(NO_CLIENT_CACHE)
    #error ClientCache is required when not using NO_SESSION_CACHE_REF
    #endif

    #ifndef NO_CLIENT_CACHE

        #ifndef CLIENT_SESSIONS_MULTIPLIER
            #ifdef NO_SESSION_CACHE_REF
                #define CLIENT_SESSIONS_MULTIPLIER 1
            #else
                /* ClientSession objects are lightweight (compared to
                 * WOLFSSL_SESSION) so to decrease chance that user will reuse
                 * thse wrong session, increase the ClientCache size. This will
                 * make the entire ClientCache about the size of one
                 * WOLFSSL_SESSION object. */
                #define CLIENT_SESSIONS_MULTIPLIER 8
            #endif
        #endif
        #define CLIENT_SESSIONS_PER_ROW \
                                (SESSIONS_PER_ROW * CLIENT_SESSIONS_MULTIPLIER)
        #define CLIENT_SESSION_ROWS (SESSION_ROWS * CLIENT_SESSIONS_MULTIPLIER)

        #if CLIENT_SESSIONS_PER_ROW > 65535
        #error CLIENT_SESSIONS_PER_ROW too big
        #endif
        #if CLIENT_SESSION_ROWS > 65535
        #error CLIENT_SESSION_ROWS too big
        #endif

        struct ClientSession {
            word16 serverRow;            /* SessionCache Row id */
            word16 serverIdx;            /* SessionCache Idx (column) */
            word32 sessionIDHash;
        };
    #ifndef WOLFSSL_CLIENT_SESSION_DEFINED
        typedef struct ClientSession ClientSession;
        #define WOLFSSL_CLIENT_SESSION_DEFINED
    #endif

        typedef struct ClientRow {
            int nextIdx;                /* where to place next one   */
            int totalCount;             /* sessions ever on this row */
            ClientSession Clients[CLIENT_SESSIONS_PER_ROW];
        } ClientRow;

        static WOLFSSL_GLOBAL ClientRow ClientCache[CLIENT_SESSION_ROWS];
                                                     /* Client Cache */
                                                     /* uses session mutex */

        static WOLFSSL_GLOBAL wolfSSL_Mutex clisession_mutex; /* ClientCache mutex */
        static WOLFSSL_GLOBAL int clisession_mutex_valid = 0;
    #endif /* !NO_CLIENT_CACHE */

#endif /* !NO_SESSION_CACHE */

#if !defined(WC_NO_RNG) && (defined(OPENSSL_EXTRA) || \
    (defined(OPENSSL_EXTRA_X509_SMALL) && !defined(NO_RSA)) || \
    (defined(OPENSSL_ALL) && !defined(NO_DH)))

    #define HAVE_GLOBAL_RNG /* consolidate flags for using globalRNG */
    static WC_RNG globalRNG;
    static int initGlobalRNG = 0;
    static wolfSSL_Mutex globalRNGMutex;
    static int globalRNGMutex_valid = 0;

    #if defined(OPENSSL_EXTRA) && defined(HAVE_HASHDRBG)
    static WOLFSSL_DRBG_CTX* gDrbgDefCtx = NULL;
    #endif

    WC_RNG* wolfssl_get_global_rng(void)
    {
        WC_RNG* ret = NULL;

        if (initGlobalRNG == 0)
            WOLFSSL_MSG("Global RNG no Init");
        else
            ret = &globalRNG;

        return ret;
    }
#endif

#if defined(OPENSSL_EXTRA) && !defined(WOLFSSL_NO_OPENSSL_RAND_CB)
static int wolfSSL_RAND_InitMutex(void);
#endif

#if defined(OPENSSL_EXTRA) && defined(HAVE_ATEXIT)
static void AtExitCleanup(void)
{
    if (initRefCount > 0) {
        initRefCount = 1;
        (void)wolfSSL_Cleanup();
    }
}
#endif

WOLFSSL_ABI
int wolfSSL_Init(void)
{
    int ret = WOLFSSL_SUCCESS;
#if !defined(NO_SESSION_CACHE) && defined(ENABLE_SESSION_CACHE_ROW_LOCK)
    int i;
#endif

    WOLFSSL_ENTER("wolfSSL_Init");

    #if FIPS_VERSION_GE(5,1)
        ret = wolfCrypt_SetPrivateKeyReadEnable_fips(1, WC_KEYTYPE_ALL);
        if (ret != 0)
            return ret;
        else
            ret = WOLFSSL_SUCCESS;
    #endif

    if (initRefCount == 0) {
        /* Initialize crypto for use with TLS connection */
        if (wolfCrypt_Init() != 0) {
            WOLFSSL_MSG("Bad wolfCrypt Init");
            ret = WC_INIT_E;
        }

#ifdef HAVE_GLOBAL_RNG
        if (ret == WOLFSSL_SUCCESS) {
            if (wc_InitMutex(&globalRNGMutex) != 0) {
                WOLFSSL_MSG("Bad Init Mutex rng");
                ret = BAD_MUTEX_E;
            }
            else {
                globalRNGMutex_valid = 1;
            }
        }
#endif

    #ifdef WC_RNG_SEED_CB
        wc_SetSeed_Cb(wc_GenerateSeed);
    #endif

#ifdef OPENSSL_EXTRA
    #ifndef WOLFSSL_NO_OPENSSL_RAND_CB
        if ((ret == WOLFSSL_SUCCESS) && (wolfSSL_RAND_InitMutex() != 0)) {
            ret = BAD_MUTEX_E;
        }
    #endif
        if ((ret == WOLFSSL_SUCCESS) &&
            (wolfSSL_RAND_seed(NULL, 0) != WOLFSSL_SUCCESS)) {
            WOLFSSL_MSG("wolfSSL_RAND_Seed failed");
            ret = WC_INIT_E;
        }
#endif

#ifndef NO_SESSION_CACHE
    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
        for (i = 0; i < SESSION_ROWS; ++i) {
            SessionCache[i].mutex_valid = 0;
        }
        for (i = 0; (ret == WOLFSSL_SUCCESS) && (i < SESSION_ROWS); ++i) {
            if (wc_InitMutex(&SessionCache[i].row_mutex) != 0) {
                WOLFSSL_MSG("Bad Init Mutex session");
                ret = BAD_MUTEX_E;
            }
            else {
                SessionCache[i].mutex_valid = 1;
            }
        }
    #else
        if (ret == WOLFSSL_SUCCESS) {
            if (wc_InitMutex(&session_mutex) != 0) {
                WOLFSSL_MSG("Bad Init Mutex session");
                ret = BAD_MUTEX_E;
            }
            else {
                session_mutex_valid = 1;
            }
        }
    #endif
    #ifndef NO_CLIENT_CACHE
        if (ret == WOLFSSL_SUCCESS) {
            if (wc_InitMutex(&clisession_mutex) != 0) {
                WOLFSSL_MSG("Bad Init Mutex session");
                ret = BAD_MUTEX_E;
            }
            else {
                clisession_mutex_valid = 1;
            }
        }
    #endif
#endif
        if (ret == WOLFSSL_SUCCESS) {
            if (wc_InitMutex(&count_mutex) != 0) {
                WOLFSSL_MSG("Bad Init Mutex count");
                ret = BAD_MUTEX_E;
            }
            else {
                count_mutex_valid = 1;
            }
        }
#if defined(OPENSSL_EXTRA) && defined(HAVE_ATEXIT)
        /* OpenSSL registers cleanup using atexit */
        if ((ret == WOLFSSL_SUCCESS) && (atexit(AtExitCleanup) != 0)) {
            WOLFSSL_MSG("Bad atexit registration");
            ret = WC_INIT_E;
        }
#endif
    }

    if (ret == WOLFSSL_SUCCESS) {
        if (wc_LockMutex(&count_mutex) != 0) {
            WOLFSSL_MSG("Bad Lock Mutex count");
            ret = BAD_MUTEX_E;
        }
        else {
            initRefCount++;
            wc_UnLockMutex(&count_mutex);
        }
    }

    if (ret != WOLFSSL_SUCCESS) {
        initRefCount = 1; /* Force cleanup */
        (void)wolfSSL_Cleanup(); /* Ignore any error from cleanup */
    }

    return ret;
}


#ifndef NO_CERTS

/* process user cert chain to pass during the handshake */
static int ProcessUserChain(WOLFSSL_CTX* ctx, const unsigned char* buff,
                         long sz, int format, int type, WOLFSSL* ssl,
                         long* used, EncryptedInfo* info, int verify)
{
    int ret = 0;
    void* heap = wolfSSL_CTX_GetHeap(ctx, ssl);
#ifdef WOLFSSL_TLS13
    int cnt = 0;
#endif

    if ((type == CA_TYPE) && (ctx == NULL)) {
        WOLFSSL_MSG("Need context for CA load");
        return BAD_FUNC_ARG;
    }

    /* we may have a user cert chain, try to consume */
    if ((type == CERT_TYPE || type == CA_TYPE) && (info->consumed < sz)) {
    #ifdef WOLFSSL_SMALL_STACK
        byte   staticBuffer[1];                 /* force heap usage */
    #else
        byte   staticBuffer[FILE_BUFFER_SIZE];  /* tmp chain buffer */
    #endif
        byte*  chainBuffer = staticBuffer;
        int    dynamicBuffer = 0;
        word32 bufferSz;
        long   consumed = info->consumed;
        word32 idx = 0;
        int    gotOne = 0;

        /* Calculate max possible size, including max headers */
        bufferSz = (word32)(sz - consumed) + (CERT_HEADER_SZ * MAX_CHAIN_DEPTH);
        if (bufferSz > sizeof(staticBuffer)) {
            WOLFSSL_MSG("Growing Tmp Chain Buffer");
            /* will shrink to actual size */
            chainBuffer = (byte*)XMALLOC(bufferSz, heap, DYNAMIC_TYPE_FILE);
            if (chainBuffer == NULL) {
                return MEMORY_E;
            }
            dynamicBuffer = 1;
        }

        WOLFSSL_MSG("Processing Cert Chain");
        while (consumed < sz) {
            DerBuffer* part = NULL;
            word32 remain = (word32)(sz - consumed);
            info->consumed = 0;

            if (format == WOLFSSL_FILETYPE_PEM) {
            #ifdef WOLFSSL_PEM_TO_DER
                ret = PemToDer(buff + consumed, remain, type, &part,
                               heap, info, NULL);
            #else
                ret = NOT_COMPILED_IN;
            #endif
            }
            else {
                int length = remain;
                if (format == WOLFSSL_FILETYPE_ASN1) {
                    /* get length of der (read sequence) */
                    word32 inOutIdx = 0;
                    if (GetSequence(buff + consumed, &inOutIdx, &length,
                            remain) < 0) {
                        ret = ASN_NO_PEM_HEADER;
                    }
                    length += inOutIdx; /* include leading sequence */
                }
                info->consumed = length;
                if (ret == 0) {
                    ret = AllocDer(&part, length, type, heap);
                    if (ret == 0) {
                        XMEMCPY(part->buffer, buff + consumed, length);
                    }
                }
            }
            if (ret == 0) {
                gotOne = 1;
#ifdef WOLFSSL_TLS13
                cnt++;
#endif
                if ((idx + part->length + CERT_HEADER_SZ) > bufferSz) {
                    WOLFSSL_MSG("   Cert Chain bigger than buffer. "
                                "Consider increasing MAX_CHAIN_DEPTH");
                    ret = BUFFER_E;
                }
                else {
                    c32to24(part->length, &chainBuffer[idx]);
                    idx += CERT_HEADER_SZ;
                    XMEMCPY(&chainBuffer[idx], part->buffer, part->length);
                    idx += part->length;
                    consumed  += info->consumed;
                    if (used)
                        *used += info->consumed;
                }

                /* add CA's to certificate manager */
                if (ret == 0 && type == CA_TYPE) {
                    /* verify CA unless user set to no verify */
                    ret = AddCA(ctx->cm, &part, WOLFSSL_USER_CA, verify);
                    if (ret == WOLFSSL_SUCCESS) {
                        ret = 0; /* converted success case */
                    }
                    gotOne = 0; /* don't exit loop for CA type */
                }
            }

            FreeDer(&part);

            if (ret == ASN_NO_PEM_HEADER && gotOne) {
                WOLFSSL_MSG("We got one good cert, so stuff at end ok");
                break;
            }

            if (ret < 0) {
                WOLFSSL_MSG("   Error in Cert in Chain");
                if (dynamicBuffer)
                    XFREE(chainBuffer, heap, DYNAMIC_TYPE_FILE);
                return ret;
            }
            WOLFSSL_MSG("   Consumed another Cert in Chain");
        }
        WOLFSSL_MSG("Finished Processing Cert Chain");

        /* only retain actual size used */
        ret = 0;
        if (idx > 0) {
            if (ssl) {
                if (ssl->buffers.weOwnCertChain) {
                    FreeDer(&ssl->buffers.certChain);
                }
                ret = AllocDer(&ssl->buffers.certChain, idx, type, heap);
                if (ret == 0) {
                    XMEMCPY(ssl->buffers.certChain->buffer, chainBuffer,
                            idx);
                    ssl->buffers.weOwnCertChain = 1;
                }
            #ifdef WOLFSSL_TLS13
                ssl->buffers.certChainCnt = cnt;
            #endif
            } else if (ctx) {
                FreeDer(&ctx->certChain);
                ret = AllocDer(&ctx->certChain, idx, type, heap);
                if (ret == 0) {
                    XMEMCPY(ctx->certChain->buffer, chainBuffer, idx);
                }
            #ifdef WOLFSSL_TLS13
                ctx->certChainCnt = cnt;
            #endif
            }
        }

        if (dynamicBuffer)
            XFREE(chainBuffer, heap, DYNAMIC_TYPE_FILE);
    }

    return ret;
}

static int ProcessBufferTryDecode(WOLFSSL_CTX* ctx, WOLFSSL* ssl, DerBuffer* der,
    int* keySz, word32* idx, int* resetSuites, int* keyFormat, void* heap, int devId)
{
    int ret = 0;

    (void)heap;
    (void)devId;

    if (ctx == NULL && ssl == NULL)
        return BAD_FUNC_ARG;
    if (!der || !keySz || !idx || !resetSuites || !keyFormat)
        return BAD_FUNC_ARG;

#ifndef NO_RSA
    if ((*keyFormat == 0 || *keyFormat == RSAk)) {
        /* make sure RSA key can be used */
    #ifdef WOLFSSL_SMALL_STACK
        RsaKey* key;
    #else
        RsaKey  key[1];
    #endif

    #ifdef WOLFSSL_SMALL_STACK
        key = (RsaKey*)XMALLOC(sizeof(RsaKey), heap, DYNAMIC_TYPE_RSA);
        if (key == NULL)
            return MEMORY_E;
    #endif

        ret = wc_InitRsaKey_ex(key, heap, devId);
        if (ret == 0) {
            *idx = 0;
            ret = wc_RsaPrivateKeyDecode(der->buffer, idx, key, der->length);
        #ifdef WOLF_PRIVATE_KEY_ID
            if (ret != 0 && (devId != INVALID_DEVID
            #ifdef HAVE_PK_CALLBACKS
                || wolfSSL_CTX_IsPrivatePkSet(ctx)
            #endif
            )) {
                /* if using crypto or PK callbacks, try public key decode */
                *idx = 0;
                ret = wc_RsaPublicKeyDecode(der->buffer, idx, key, der->length);
            }
        #endif
            if (ret != 0) {
            #if !defined(HAVE_ECC) && !defined(HAVE_ED25519) && \
                !defined(HAVE_ED448) && !defined(HAVE_PQC)
                WOLFSSL_MSG("RSA decode failed and other algorithms "
                            "not enabled to try");
                ret = WOLFSSL_BAD_FILE;
            #else
                ret = 0; /* continue trying other algorithms */
            #endif
            }
            else {
                /* check that the size of the RSA key is enough */
                int minRsaSz = ssl ? ssl->options.minRsaKeySz :
                    ctx->minRsaKeySz;
                *keySz = wc_RsaEncryptSize((RsaKey*)key);
                if (*keySz < minRsaSz) {
                    ret = RSA_KEY_SIZE_E;
                    WOLFSSL_MSG("Private Key size too small");
                }

                if (ssl) {
                    ssl->buffers.keyType = rsa_sa_algo;
                    ssl->buffers.keySz = *keySz;
                }
                else {
                    ctx->privateKeyType = rsa_sa_algo;
                    ctx->privateKeySz = *keySz;
                }

                *keyFormat = RSAk;

                if (ssl && ssl->options.side == WOLFSSL_SERVER_END) {
                    ssl->options.haveStaticECC = 0;
                    *resetSuites = 1;
                }
            }

            wc_FreeRsaKey(key);
        }

    #ifdef WOLFSSL_SMALL_STACK
        XFREE(key, heap, DYNAMIC_TYPE_RSA);
    #endif
        if (ret != 0)
            return ret;
    }
#endif
#ifdef HAVE_ECC
    if ((*keyFormat == 0 || *keyFormat == ECDSAk)) {
        /* make sure ECC key can be used */
    #ifdef WOLFSSL_SMALL_STACK
        ecc_key* key;
    #else
        ecc_key  key[1];
    #endif

    #ifdef WOLFSSL_SMALL_STACK
        key = (ecc_key*)XMALLOC(sizeof(ecc_key), heap, DYNAMIC_TYPE_ECC);
        if (key == NULL)
            return MEMORY_E;
    #endif

        if (wc_ecc_init_ex(key, heap, devId) == 0) {
            *idx = 0;
            ret = wc_EccPrivateKeyDecode(der->buffer, idx, key, der->length);
        #ifdef WOLF_PRIVATE_KEY_ID
            if (ret != 0 && (devId != INVALID_DEVID
            #ifdef HAVE_PK_CALLBACKS
                || wolfSSL_CTX_IsPrivatePkSet(ctx)
            #endif
            )) {
                /* if using crypto or PK callbacks, try public key decode */
                *idx = 0;
                ret = wc_EccPublicKeyDecode(der->buffer, idx, key, der->length);
            }
        #endif
            if (ret == 0) {
                /* check for minimum ECC key size and then free */
                int minKeySz = ssl ? ssl->options.minEccKeySz :
                                                        ctx->minEccKeySz;
                *keySz = wc_ecc_size(key);
                if (*keySz < minKeySz) {
                    WOLFSSL_MSG("ECC private key too small");
                    ret = ECC_KEY_SIZE_E;
                }

                *keyFormat = ECDSAk;
                if (ssl) {
                    ssl->options.haveStaticECC = 1;
                    ssl->buffers.keyType = ecc_dsa_sa_algo;
                    ssl->buffers.keySz = *keySz;
                }
                else {
                    ctx->haveStaticECC = 1;
                    ctx->privateKeyType = ecc_dsa_sa_algo;
                    ctx->privateKeySz = *keySz;
                }

                if (ssl && ssl->options.side == WOLFSSL_SERVER_END) {
                    *resetSuites = 1;
                }
            }
            else {
                ret = 0; /* continue trying other algorithms */
            }

            wc_ecc_free(key);
        }

    #ifdef WOLFSSL_SMALL_STACK
        XFREE(key, heap, DYNAMIC_TYPE_ECC);
    #endif
        if (ret != 0)
            return ret;
    }
#endif /* HAVE_ECC */
#if defined(HAVE_ED25519) && defined(HAVE_ED25519_KEY_IMPORT)
    if ((*keyFormat == 0 || *keyFormat == ED25519k)) {
        /* make sure Ed25519 key can be used */
    #ifdef WOLFSSL_SMALL_STACK
        ed25519_key* key;
    #else
        ed25519_key  key[1];
    #endif

    #ifdef WOLFSSL_SMALL_STACK
        key = (ed25519_key*)XMALLOC(sizeof(ed25519_key), heap,
                                                      DYNAMIC_TYPE_ED25519);
        if (key == NULL)
            return MEMORY_E;
    #endif

        ret = wc_ed25519_init_ex(key, heap, devId);
        if (ret == 0) {
            *idx = 0;
            ret = wc_Ed25519PrivateKeyDecode(der->buffer, idx, key, der->length);
        #ifdef WOLF_PRIVATE_KEY_ID
            if (ret != 0 && (devId != INVALID_DEVID
            #ifdef HAVE_PK_CALLBACKS
                || wolfSSL_CTX_IsPrivatePkSet(ctx)
            #endif
            )) {
                /* if using crypto or PK callbacks, try public key decode */
                *idx = 0;
                ret = wc_Ed25519PublicKeyDecode(der->buffer, idx, key,
                                                der->length);
            }
        #endif
            if (ret == 0) {
                /* check for minimum key size and then free */
                int minKeySz = ssl ? ssl->options.minEccKeySz :
                                                           ctx->minEccKeySz;
                *keySz = ED25519_KEY_SIZE;
                if (*keySz < minKeySz) {
                    WOLFSSL_MSG("ED25519 private key too small");
                    ret = ECC_KEY_SIZE_E;
                }
                if (ret == 0) {
                    if (ssl) {
                        ssl->buffers.keyType = ed25519_sa_algo;
                        ssl->buffers.keySz = *keySz;
                    }
                    else if (ctx) {
                        ctx->privateKeyType = ed25519_sa_algo;
                        ctx->privateKeySz = *keySz;
                    }

                    *keyFormat = ED25519k;
                    if (ssl != NULL) {
                        /* ED25519 requires caching enabled for tracking message
                         * hash used in EdDSA_Update for signing */
                        ssl->options.cacheMessages = 1;
                        if (ssl->options.side == WOLFSSL_SERVER_END) {
                            *resetSuites = 1;
                        }
                    }
                }
            }
            else {
                ret = 0; /* continue trying other algorithms */
            }

            wc_ed25519_free(key);
        }

    #ifdef WOLFSSL_SMALL_STACK
        XFREE(key, heap, DYNAMIC_TYPE_ED25519);
    #endif
        if (ret != 0)
            return ret;
    }
#endif /* HAVE_ED25519 && HAVE_ED25519_KEY_IMPORT */
#if defined(HAVE_ED448) && defined(HAVE_ED448_KEY_IMPORT)
    if ((*keyFormat == 0 || *keyFormat == ED448k)) {
        /* make sure Ed448 key can be used */
    #ifdef WOLFSSL_SMALL_STACK
        ed448_key* key = NULL;
    #else
        ed448_key  key[1];
    #endif

    #ifdef WOLFSSL_SMALL_STACK
        key = (ed448_key*)XMALLOC(sizeof(ed448_key), heap, DYNAMIC_TYPE_ED448);
        if (key == NULL)
            return MEMORY_E;
    #endif

        ret = wc_ed448_init(key);
        if (ret == 0) {
            *idx = 0;
            ret = wc_Ed448PrivateKeyDecode(der->buffer, idx, key, der->length);
        #ifdef WOLF_PRIVATE_KEY_ID
            if (ret != 0 && (devId != INVALID_DEVID
            #ifdef HAVE_PK_CALLBACKS
                || wolfSSL_CTX_IsPrivatePkSet(ctx)
            #endif
            )) {
                /* if using crypto or PK callbacks, try public key decode */
                *idx = 0;
                ret = wc_Ed448PublicKeyDecode(der->buffer, idx, key,
                                              der->length);
            }
        #endif
            if (ret == 0) {
                /* check for minimum key size and then free */
                int minKeySz = ssl ? ssl->options.minEccKeySz :
                                                               ctx->minEccKeySz;
                *keySz = ED448_KEY_SIZE;
                if (*keySz < minKeySz) {
                    WOLFSSL_MSG("ED448 private key too small");
                    ret = ECC_KEY_SIZE_E;
                }
            }
            if (ret == 0) {
                if (ssl) {
                    ssl->buffers.keyType = ed448_sa_algo;
                    ssl->buffers.keySz = *keySz;
                }
                else if (ctx) {
                    ctx->privateKeyType = ed448_sa_algo;
                    ctx->privateKeySz = *keySz;
                }

                *keyFormat = ED448k;
                if (ssl != NULL) {
                    /* ED448 requires caching enabled for tracking message
                     * hash used in EdDSA_Update for signing */
                    ssl->options.cacheMessages = 1;
                    if (ssl->options.side == WOLFSSL_SERVER_END) {
                        *resetSuites = 1;
                    }
                }
            }

            wc_ed448_free(key);
        }

    #ifdef WOLFSSL_SMALL_STACK
        XFREE(key, heap, DYNAMIC_TYPE_ED448);
    #endif
        if (ret != 0)
            return ret;
    }
#endif /* HAVE_ED448 && HAVE_ED448_KEY_IMPORT */
#if defined(HAVE_PQC)
#if defined(HAVE_FALCON)
    if (((*keyFormat == 0) || (*keyFormat == FALCON_LEVEL1k) ||
         (*keyFormat == FALCON_LEVEL5k))) {
        /* make sure Falcon key can be used */
        falcon_key* key = (falcon_key*)XMALLOC(sizeof(falcon_key), heap,
                                               DYNAMIC_TYPE_FALCON);
        if (key == NULL) {
            return MEMORY_E;
        }
        ret = wc_falcon_init(key);
        if (ret == 0) {
            if (*keyFormat == FALCON_LEVEL1k) {
                ret = wc_falcon_set_level(key, 1);
            }
            else if (*keyFormat == FALCON_LEVEL5k) {
                ret = wc_falcon_set_level(key, 5);
            }
            else {
                /* What if *keyformat is 0? We might want to do something more
                 * graceful here. */
                wc_falcon_free(key);
                ret = ALGO_ID_E;
            }
        }

        if (ret == 0) {
            *idx = 0;
            ret = wc_falcon_import_private_only(der->buffer, der->length, key);
            if (ret == 0) {
                /* check for minimum key size and then free */
                int minKeySz = ssl ? ssl->options.minFalconKeySz :
                                     ctx->minFalconKeySz;
                *keySz = FALCON_MAX_KEY_SIZE;
                if (*keySz < minKeySz) {
                    WOLFSSL_MSG("Falcon private key too small");
                    ret = FALCON_KEY_SIZE_E;
                }
                if (ssl) {
                    if (*keyFormat == FALCON_LEVEL1k) {
                        ssl->buffers.keyType = falcon_level1_sa_algo;
                    }
                    else {
                        ssl->buffers.keyType = falcon_level5_sa_algo;
                    }
                    ssl->buffers.keySz = *keySz;
                }
                else {
                    if (*keyFormat == FALCON_LEVEL1k) {
                        ctx->privateKeyType = falcon_level1_sa_algo;
                    }
                    else {
                        ctx->privateKeyType = falcon_level5_sa_algo;
                    }
                    ctx->privateKeySz = *keySz;
                }

                if (ssl && ssl->options.side == WOLFSSL_SERVER_END) {
                    *resetSuites = 1;
                }
            }
            wc_falcon_free(key);
        }
        XFREE(key, heap, DYNAMIC_TYPE_FALCON);
        if (ret != 0)
            return ret;
    }
#endif /* HAVE_FALCON */
#if defined(HAVE_DILITHIUM)
    if ((*keyFormat == 0) ||
        (*keyFormat == DILITHIUM_LEVEL2k) ||
        (*keyFormat == DILITHIUM_LEVEL3k) ||
        (*keyFormat == DILITHIUM_LEVEL5k)) {
        /* make sure Dilithium key can be used */
        dilithium_key* key = (dilithium_key*)XMALLOC(sizeof(dilithium_key),
                                                     heap,
                                                     DYNAMIC_TYPE_DILITHIUM);
        if (key == NULL) {
            return MEMORY_E;
        }
        ret = wc_dilithium_init(key);
        if (ret == 0) {
            if (*keyFormat == DILITHIUM_LEVEL2k) {
                ret = wc_dilithium_set_level(key, 2);
            }
            else if (*keyFormat == DILITHIUM_LEVEL3k) {
                ret = wc_dilithium_set_level(key, 3);
            }
            else if (*keyFormat == DILITHIUM_LEVEL5k) {
                ret = wc_dilithium_set_level(key, 5);
            }
            else {
                /* What if *keyformat is 0? We might want to do something more
                 * graceful here. */
                wc_dilithium_free(key);
                ret = ALGO_ID_E;
            }
        }

        if (ret == 0) {
            *idx = 0;
            ret = wc_dilithium_import_private_only(der->buffer, der->length,
                                                   key);
            if (ret == 0) {
                /* check for minimum key size and then free */
                int minKeySz = ssl ? ssl->options.minDilithiumKeySz :
                                     ctx->minDilithiumKeySz;
                *keySz = DILITHIUM_MAX_KEY_SIZE;
                if (*keySz < minKeySz) {
                    WOLFSSL_MSG("Dilithium private key too small");
                    ret = DILITHIUM_KEY_SIZE_E;
                }
                if (ssl) {
                    if (*keyFormat == DILITHIUM_LEVEL2k) {
                        ssl->buffers.keyType = dilithium_level2_sa_algo;
                    }
                    else if (*keyFormat == DILITHIUM_LEVEL3k) {
                        ssl->buffers.keyType = dilithium_level3_sa_algo;
                    }
                    else if (*keyFormat == DILITHIUM_LEVEL5k) {
                        ssl->buffers.keyType = dilithium_level5_sa_algo;
                    }
                    ssl->buffers.keySz = *keySz;
                }
                else {
                    if (*keyFormat == DILITHIUM_LEVEL2k) {
                        ctx->privateKeyType = dilithium_level2_sa_algo;
                    }
                    else if (*keyFormat == DILITHIUM_LEVEL3k) {
                        ctx->privateKeyType = dilithium_level3_sa_algo;
                    }
                    else if (*keyFormat == DILITHIUM_LEVEL5k) {
                        ctx->privateKeyType = dilithium_level5_sa_algo;
                    }
                    ctx->privateKeySz = *keySz;
                }

                if (ssl && ssl->options.side == WOLFSSL_SERVER_END) {
                    *resetSuites = 1;
                }
            }
            wc_dilithium_free(key);
        }
        XFREE(key, heap, DYNAMIC_TYPE_DILITHIUM);
        if (ret != 0) {
            return ret;
        }
    }
#endif /* HAVE_DILITHIUM */
#endif /* HAVE_PQC */
    return ret;
}

/* process the buffer buff, length sz, into ctx of format and type
   used tracks bytes consumed, userChain specifies a user cert chain
   to pass during the handshake */
int ProcessBuffer(WOLFSSL_CTX* ctx, const unsigned char* buff,
                         long sz, int format, int type, WOLFSSL* ssl,
                         long* used, int userChain, int verify)
{
    DerBuffer*    der = NULL;
    int           ret = 0;
    int           done = 0;
    int           keyFormat = 0;
    int           resetSuites = 0;
    void*         heap = wolfSSL_CTX_GetHeap(ctx, ssl);
    int           devId = wolfSSL_CTX_GetDevId(ctx, ssl);
    word32        idx = 0;
    int           keySz = 0;
#if (defined(WOLFSSL_ENCRYPTED_KEYS) && !defined(NO_PWDBASED)) || \
     defined(HAVE_PKCS8)
    word32        algId = 0;
#endif
#ifdef WOLFSSL_SMALL_STACK
    EncryptedInfo* info = NULL;
#else
    EncryptedInfo  info[1];
#endif

    (void)devId;
    (void)idx;
    (void)keySz;

    if (used)
        *used = sz;     /* used bytes default to sz, PEM chain may shorten*/

    /* check args */
    if (format != WOLFSSL_FILETYPE_ASN1 && format != WOLFSSL_FILETYPE_PEM)
        return WOLFSSL_BAD_FILETYPE;

    if (ctx == NULL && ssl == NULL)
        return BAD_FUNC_ARG;

#ifdef WOLFSSL_SMALL_STACK
    info = (EncryptedInfo*)XMALLOC(sizeof(EncryptedInfo), heap,
                                   DYNAMIC_TYPE_ENCRYPTEDINFO);
    if (info == NULL)
        return MEMORY_E;
#endif

    XMEMSET(info, 0, sizeof(EncryptedInfo));
#if defined(WOLFSSL_ENCRYPTED_KEYS) && !defined(NO_PWDBASED)
    if (ctx) {
        info->passwd_cb       = ctx->passwd_cb;
        info->passwd_userdata = ctx->passwd_userdata;
    }
#endif

    if (format == WOLFSSL_FILETYPE_PEM) {
    #ifdef WOLFSSL_PEM_TO_DER
        ret = PemToDer(buff, sz, type, &der, heap, info, &keyFormat);
    #else
        ret = NOT_COMPILED_IN;
    #endif
    }
    else {
        /* ASN1 (DER) */
        int length = (int)sz;
        if (format == WOLFSSL_FILETYPE_ASN1) {
            /* get length of der (read sequence or octet string) */
            word32 inOutIdx = 0;
            if (GetSequence(buff, &inOutIdx, &length, (word32)sz) >= 0) {
                length += inOutIdx; /* include leading sequence */
            }
            /* get length using octect string (allowed for private key types) */
            else if (type == PRIVATEKEY_TYPE &&
                    GetOctetString(buff, &inOutIdx, &length, (word32)sz) >= 0) {
                length += inOutIdx; /* include leading oct string */
            }
            else {
                ret = ASN_PARSE_E;
            }
        }

        info->consumed = length;

        if (ret == 0) {
            ret = AllocDer(&der, (word32)length, type, heap);
            if (ret == 0) {
                XMEMCPY(der->buffer, buff, length);
            }

        #ifdef HAVE_PKCS8
            /* if private key try and remove PKCS8 header */
            if (type == PRIVATEKEY_TYPE) {
                if ((ret = ToTraditional_ex(der->buffer, der->length,
                                                                 &algId)) > 0) {
                    /* Found PKCS8 header */
                    /* ToTraditional_ex moves buff and returns adjusted length */
                    der->length = ret;
                    keyFormat = algId;
                }
                ret = 0; /* failures should be ignored */
            }
        #endif
        }
    }

    if (used) {
        *used = info->consumed;
    }

    /* process user chain */
    if (ret >= 0) {
        /* Chain should have server cert first, then intermediates, then root.
         * First certificate in chain is processed below after ProcessUserChain
         *   and is loaded into ssl->buffers.certificate.
         * Remainder are processed using ProcessUserChain and are loaded into
         *   ssl->buffers.certChain. */
        if (userChain) {
            ret = ProcessUserChain(ctx, buff, sz, format, type, ssl, used, info,
                                   verify);
            if (ret == ASN_NO_PEM_HEADER) { /* Additional chain is optional */
                unsigned long pemErr;
                CLEAR_ASN_NO_PEM_HEADER_ERROR(pemErr);
                ret = 0;
            }
        }
    }

    /* info is only used for private key with DER or PEM, so free now */
    if (ret < 0 || type != PRIVATEKEY_TYPE) {
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(info, heap, DYNAMIC_TYPE_ENCRYPTEDINFO);
    #endif
    }

    /* check for error */
    if (ret < 0) {
        FreeDer(&der);
        done = 1;
    }

    if (done == 1) {
        /* No operation, just skip the next section */
    }
    /* Handle DER owner */
    else if (type == CA_TYPE) {
        if (ctx == NULL) {
            WOLFSSL_MSG("Need context for CA load");
            FreeDer(&der);
            return BAD_FUNC_ARG;
        }
        /* verify CA unless user set to no verify */
        ret = AddCA(ctx->cm, &der, WOLFSSL_USER_CA, verify);
        done = 1;
    }
#ifdef WOLFSSL_TRUST_PEER_CERT
    else if (type == TRUSTED_PEER_TYPE) {
        /* add trusted peer cert. der is freed within */
        if (ctx != NULL)
            ret = AddTrustedPeer(ctx->cm, &der, !ctx->verifyNone);
        else
            ret = AddTrustedPeer(SSL_CM(ssl), &der, !ssl->options.verifyNone);
        if (ret != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("Error adding trusted peer");
        }
        done = 1;
    }
#endif /* WOLFSSL_TRUST_PEER_CERT */
    else if (type == CERT_TYPE) {
        if (ssl != NULL) {
             /* Make sure previous is free'd */
            if (ssl->buffers.weOwnCert) {
                FreeDer(&ssl->buffers.certificate);
            #ifdef KEEP_OUR_CERT
                wolfSSL_X509_free(ssl->ourCert);
                ssl->ourCert = NULL;
            #endif
            }
            ssl->buffers.certificate = der;
        #ifdef KEEP_OUR_CERT
            ssl->keepCert = 1; /* hold cert for ssl lifetime */
        #endif
            ssl->buffers.weOwnCert = 1;
        }
        else if (ctx != NULL) {
            FreeDer(&ctx->certificate); /* Make sure previous is free'd */
        #ifdef KEEP_OUR_CERT
            if (ctx->ourCert) {
                if (ctx->ownOurCert)
                    wolfSSL_X509_free(ctx->ourCert);
                ctx->ourCert = NULL;
            }
        #endif
            ctx->certificate = der;
        }
    }
    else if (type == PRIVATEKEY_TYPE) {
        if (ssl != NULL) {
             /* Make sure previous is free'd */
            if (ssl->buffers.weOwnKey) {
                ForceZero(ssl->buffers.key->buffer, ssl->buffers.key->length);
                FreeDer(&ssl->buffers.key);
            }
            ssl->buffers.key = der;
#ifdef WOLFSSL_CHECK_MEM_ZERO
            wc_MemZero_Add("SSL Buffers key", der->buffer, der->length);
#endif
            ssl->buffers.weOwnKey = 1;
        }
        else if (ctx != NULL) {
            if (ctx->privateKey != NULL && ctx->privateKey->buffer != NULL) {
                ForceZero(ctx->privateKey->buffer, ctx->privateKey->length);
            }
            FreeDer(&ctx->privateKey);
            ctx->privateKey = der;
#ifdef WOLFSSL_CHECK_MEM_ZERO
            wc_MemZero_Add("CTX private key", der->buffer, der->length);
#endif
        }
    }
    else {
        FreeDer(&der);
        return WOLFSSL_BAD_CERTTYPE;
    }

    if (done == 1) {
        /* No operation, just skip the next section */
    }
    else if (type == PRIVATEKEY_TYPE) {
        ret = ProcessBufferTryDecode(ctx, ssl, der, &keySz, &idx, &resetSuites,
                &keyFormat, heap, devId);

    #if defined(WOLFSSL_ENCRYPTED_KEYS) && !defined(NO_PWDBASED)
        /* for WOLFSSL_FILETYPE_PEM, PemToDer manages the decryption */
        /* If private key type PKCS8 header wasn't already removed (algoId == 0) */
        if ((ret != 0 || keyFormat == 0)
            && format != WOLFSSL_FILETYPE_PEM && info->passwd_cb && algId == 0)
        {
            int   passwordSz = NAME_SZ;
        #ifndef WOLFSSL_SMALL_STACK
            char  password[NAME_SZ];
        #else
            char* password = (char*)XMALLOC(passwordSz, heap, DYNAMIC_TYPE_STRING);
            if (password == NULL) {
                XFREE(info, heap, DYNAMIC_TYPE_ENCRYPTEDINFO);
                FreeDer(&der);
                return MEMORY_E;
            }
        #endif
            /* get password */
            ret = info->passwd_cb(password, passwordSz, PEM_PASS_READ,
                info->passwd_userdata);
            if (ret >= 0) {
                passwordSz = ret;
            #ifdef WOLFSSL_CHECK_MEM_ZERO
                wc_MemZero_Add("ProcessBuffer password", password, passwordSz);
            #endif

                /* PKCS8 decrypt */
                ret = ToTraditionalEnc(der->buffer, der->length,
                                       password, passwordSz, &algId);
                if (ret >= 0) {
                    ForceZero(der->buffer + ret, der->length - ret);
                    der->length = ret;
                }
                /* ignore failures and try parsing as unencrypted */

                ForceZero(password, passwordSz);
            }

        #ifdef WOLFSSL_SMALL_STACK
            XFREE(password, heap, DYNAMIC_TYPE_STRING);
        #elif defined(WOLFSSL_CHECK_MEM_ZERO)
            wc_MemZero_Check(password, NAME_SZ);
        #endif
            ret = ProcessBufferTryDecode(ctx, ssl, der, &keySz, &idx,
                &resetSuites, &keyFormat, heap, devId);
        }
    #endif /* WOLFSSL_ENCRYPTED_KEYS && !NO_PWDBASED */

    #ifdef WOLFSSL_SMALL_STACK
        XFREE(info, heap, DYNAMIC_TYPE_ENCRYPTEDINFO);
    #endif

        if (ret != 0)
            return ret;
        if (keyFormat == 0) {
#ifdef OPENSSL_EXTRA
            /* Reaching this point probably means that the
             * decryption password is wrong */
            if (info->passwd_cb)
                EVPerr(0, EVP_R_BAD_DECRYPT);
#endif
            WOLFSSL_ERROR(WOLFSSL_BAD_FILE);
            return WOLFSSL_BAD_FILE;
        }

        (void)devId;
    }
    else if (type == CERT_TYPE) {
    #ifdef WOLFSSL_SMALL_STACK
        DecodedCert* cert;
    #else
        DecodedCert  cert[1];
    #endif
    #ifdef WOLF_PRIVATE_KEY_ID
        int keyType = 0;
    #endif

    #ifdef WOLFSSL_SMALL_STACK
        cert = (DecodedCert*)XMALLOC(sizeof(DecodedCert), heap,
                                     DYNAMIC_TYPE_DCERT);
        if (cert == NULL)
            return MEMORY_E;
    #endif

        WOLFSSL_MSG("Checking cert signature type");
        InitDecodedCert(cert, der->buffer, der->length, heap);

        if (DecodeToKey(cert, 0) < 0) {
            WOLFSSL_MSG("Decode to key failed");
            FreeDecodedCert(cert);
        #ifdef WOLFSSL_SMALL_STACK
            XFREE(cert, heap, DYNAMIC_TYPE_DCERT);
        #endif
            return WOLFSSL_BAD_FILE;
        }

        if (ssl && ssl->options.side == WOLFSSL_SERVER_END) {
            resetSuites = 1;
        }
        if (ssl && ssl->ctx->haveECDSAsig) {
            WOLFSSL_MSG("SSL layer setting cert, CTX had ECDSA, turning off");
            ssl->options.haveECDSAsig = 0;   /* may turn back on next */
        }

        switch (cert->signatureOID) {
            case CTC_SHAwECDSA:
            case CTC_SHA256wECDSA:
            case CTC_SHA384wECDSA:
            case CTC_SHA512wECDSA:
            case CTC_ED25519:
            case CTC_ED448:
                WOLFSSL_MSG("ECDSA/ED25519/ED448 cert signature");
                if (ssl)
                    ssl->options.haveECDSAsig = 1;
                else if (ctx)
                    ctx->haveECDSAsig = 1;
                break;
            case CTC_FALCON_LEVEL1:
            case CTC_FALCON_LEVEL5:
                WOLFSSL_MSG("Falcon cert signature");
                if (ssl)
                    ssl->options.haveFalconSig = 1;
                else if (ctx)
                    ctx->haveFalconSig = 1;
                break;
            case CTC_DILITHIUM_LEVEL2:
            case CTC_DILITHIUM_LEVEL3:
            case CTC_DILITHIUM_LEVEL5:
                WOLFSSL_MSG("Dilithium cert signature");
                if (ssl)
                    ssl->options.haveDilithiumSig = 1;
                else if (ctx)
                    ctx->haveDilithiumSig = 1;
                break;
            default:
                WOLFSSL_MSG("Not ECDSA cert signature");
                break;
        }

    #if defined(HAVE_ECC) || defined(HAVE_ED25519) || defined(HAVE_ED448) || \
        (defined(HAVE_PQC) && defined(HAVE_LIBOQS)) || !defined(NO_RSA)
        if (ssl) {
        #if defined(HAVE_ECC) || defined(HAVE_ED25519) || \
            (defined(HAVE_CURVE448) && defined(HAVE_ED448))
            ssl->pkCurveOID = cert->pkCurveOID;
        #endif
        #ifndef WC_STRICT_SIG
            if (cert->keyOID == ECDSAk) {
                ssl->options.haveECC = 1;
            }
            #ifndef NO_RSA
            else if (cert->keyOID == RSAk) {
                ssl->options.haveRSA = 1;
            }
            #ifdef WC_RSA_PSS
            else if (cert->keyOID == RSAPSSk) {
                ssl->options.haveRSA = 1;
            }
            #endif
            #endif
            #ifdef HAVE_ED25519
                else if (cert->keyOID == ED25519k) {
                    ssl->options.haveECC = 1;
                }
            #endif
            #ifdef HAVE_ED448
                else if (cert->keyOID == ED448k) {
                    ssl->options.haveECC = 1;
                }
            #endif
            #ifdef HAVE_PQC
            #ifdef HAVE_FALCON
                else if (cert->keyOID == FALCON_LEVEL1k ||
                         cert->keyOID == FALCON_LEVEL5k) {
                    ssl->options.haveFalconSig = 1;
                }
            #endif /* HAVE_FALCON */
            #ifdef HAVE_DILITHIUM
                else if (cert->keyOID == DILITHIUM_LEVEL2k ||
                         cert->keyOID == DILITHIUM_LEVEL3k ||
                         cert->keyOID == DILITHIUM_LEVEL5k) {
                    ssl->options.haveDilithiumSig = 1;
                }
            #endif /* HAVE_DILITHIUM */
            #endif /* HAVE_PQC */
        #else
            ssl->options.haveECC = ssl->options.haveECDSAsig;
        #endif
        }
        else if (ctx) {
        #if defined(HAVE_ECC) || defined(HAVE_ED25519) || defined(HAVE_ED448)
            ctx->pkCurveOID = cert->pkCurveOID;
        #endif
        #ifndef WC_STRICT_SIG
            if (cert->keyOID == ECDSAk) {
                ctx->haveECC = 1;
            }
            #ifndef NO_RSA
            else if (cert->keyOID == RSAk) {
                ctx->haveRSA = 1;
            }
            #ifdef WC_RSA_PSS
            else if (cert->keyOID == RSAPSSk) {
                ctx->haveRSA = 1;
            }
            #endif
            #endif
            #ifdef HAVE_ED25519
                else if (cert->keyOID == ED25519k) {
                    ctx->haveECC = 1;
                }
            #endif
            #ifdef HAVE_ED448
                else if (cert->keyOID == ED448k) {
                    ctx->haveECC = 1;
                }
            #endif
            #ifdef HAVE_PQC
            #ifdef HAVE_FALCON
                else if (cert->keyOID == FALCON_LEVEL1k ||
                         cert->keyOID == FALCON_LEVEL5k) {
                    ctx->haveFalconSig = 1;
                }
            #endif /* HAVE_FALCON */
            #ifdef HAVE_DILITHIUM
                else if (cert->keyOID == DILITHIUM_LEVEL2k ||
                         cert->keyOID == DILITHIUM_LEVEL3k ||
                         cert->keyOID == DILITHIUM_LEVEL5k) {
                    ctx->haveDilithiumSig = 1;
                }
            #endif /* HAVE_DILITHIUM */
            #endif /* HAVE_PQC */
        #else
            ctx->haveECC = ctx->haveECDSAsig;
        #endif
        }
    #endif

        /* check key size of cert unless specified not to */
        switch (cert->keyOID) {
        #ifndef NO_RSA
            #ifdef WC_RSA_PSS
            case RSAPSSk:
            #endif
            case RSAk:
            #ifdef WOLF_PRIVATE_KEY_ID
                keyType = rsa_sa_algo;
            #endif
                /* Determine RSA key size by parsing public key */
                idx = 0;
                ret = wc_RsaPublicKeyDecode_ex(cert->publicKey, &idx,
                    cert->pubKeySize, NULL, (word32*)&keySz, NULL, NULL);
                if (ret < 0)
                    break;

                if (ssl && !ssl->options.verifyNone) {
                    if (ssl->options.minRsaKeySz < 0 ||
                          keySz < (int)ssl->options.minRsaKeySz ||
                          keySz > (RSA_MAX_SIZE / 8)) {
                        ret = RSA_KEY_SIZE_E;
                        WOLFSSL_MSG("Certificate RSA key size too small");
                    }
                }
                else if (ctx && !ctx->verifyNone) {
                    if (ctx->minRsaKeySz < 0 ||
                            keySz < (int)ctx->minRsaKeySz ||
                            keySz > (RSA_MAX_SIZE / 8)) {
                        ret = RSA_KEY_SIZE_E;
                        WOLFSSL_MSG("Certificate RSA key size too small");
                    }
                }
                break;
        #endif /* !NO_RSA */
        #ifdef HAVE_ECC
            case ECDSAk:
            #ifdef WOLF_PRIVATE_KEY_ID
                keyType = ecc_dsa_sa_algo;
            #endif
                /* Determine ECC key size based on curve */
                keySz = wc_ecc_get_curve_size_from_id(
                    wc_ecc_get_oid(cert->pkCurveOID, NULL, NULL));

                if (ssl && !ssl->options.verifyNone) {
                    if (ssl->options.minEccKeySz < 0 ||
                          keySz < (int)ssl->options.minEccKeySz) {
                        ret = ECC_KEY_SIZE_E;
                        WOLFSSL_MSG("Certificate ECC key size error");
                    }
                }
                else if (ctx && !ctx->verifyNone) {
                    if (ctx->minEccKeySz < 0 ||
                                  keySz < (int)ctx->minEccKeySz) {
                        ret = ECC_KEY_SIZE_E;
                        WOLFSSL_MSG("Certificate ECC key size error");
                    }
                }
                break;
        #endif /* HAVE_ECC */
        #ifdef HAVE_ED25519
            case ED25519k:
            #ifdef WOLF_PRIVATE_KEY_ID
                keyType = ed25519_sa_algo;
            #endif
                /* ED25519 is fixed key size */
                keySz = ED25519_KEY_SIZE;
                if (ssl && !ssl->options.verifyNone) {
                    if (ssl->options.minEccKeySz < 0 ||
                          keySz < (int)ssl->options.minEccKeySz) {
                        ret = ECC_KEY_SIZE_E;
                        WOLFSSL_MSG("Certificate Ed key size error");
                    }
                }
                else if (ctx && !ctx->verifyNone) {
                    if (ctx->minEccKeySz < 0 ||
                                  keySz < (int)ctx->minEccKeySz) {
                        ret = ECC_KEY_SIZE_E;
                        WOLFSSL_MSG("Certificate ECC key size error");
                    }
                }
                break;
        #endif /* HAVE_ED25519 */
        #ifdef HAVE_ED448
            case ED448k:
            #ifdef WOLF_PRIVATE_KEY_ID
                keyType = ed448_sa_algo;
            #endif
                /* ED448 is fixed key size */
                keySz = ED448_KEY_SIZE;
                if (ssl && !ssl->options.verifyNone) {
                    if (ssl->options.minEccKeySz < 0 ||
                          keySz < (int)ssl->options.minEccKeySz) {
                        ret = ECC_KEY_SIZE_E;
                        WOLFSSL_MSG("Certificate Ed key size error");
                    }
                }
                else if (ctx && !ctx->verifyNone) {
                    if (ctx->minEccKeySz < 0 ||
                                  keySz < (int)ctx->minEccKeySz) {
                        ret = ECC_KEY_SIZE_E;
                        WOLFSSL_MSG("Certificate ECC key size error");
                    }
                }
                break;
        #endif /* HAVE_ED448 */
        #if defined(HAVE_PQC)
        #if defined(HAVE_FALCON)
            case FALCON_LEVEL1k:
            case FALCON_LEVEL5k:
                /* Falcon is fixed key size */
                keySz = FALCON_MAX_KEY_SIZE;
                if (ssl && !ssl->options.verifyNone) {
                    if (ssl->options.minFalconKeySz < 0 ||
                          keySz < (int)ssl->options.minFalconKeySz) {
                        ret = FALCON_KEY_SIZE_E;
                        WOLFSSL_MSG("Certificate Falcon key size error");
                    }
                }
                else if (ctx && !ctx->verifyNone) {
                    if (ctx->minFalconKeySz < 0 ||
                                  keySz < (int)ctx->minFalconKeySz) {
                        ret = FALCON_KEY_SIZE_E;
                        WOLFSSL_MSG("Certificate Falcon key size error");
                    }
                }
                break;
        #endif /* HAVE_FALCON */
        #if defined(HAVE_DILITHIUM)
            case DILITHIUM_LEVEL2k:
            case DILITHIUM_LEVEL3k:
            case DILITHIUM_LEVEL5k:
                /* Dilithium is fixed key size */
                keySz = DILITHIUM_MAX_KEY_SIZE;
                if (ssl && !ssl->options.verifyNone) {
                    if (ssl->options.minDilithiumKeySz < 0 ||
                          keySz < (int)ssl->options.minDilithiumKeySz) {
                        ret = DILITHIUM_KEY_SIZE_E;
                        WOLFSSL_MSG("Certificate Dilithium key size error");
                    }
                }
                else if (ctx && !ctx->verifyNone) {
                    if (ctx->minDilithiumKeySz < 0 ||
                                  keySz < (int)ctx->minDilithiumKeySz) {
                        ret = DILITHIUM_KEY_SIZE_E;
                        WOLFSSL_MSG("Certificate Dilithium key size error");
                    }
                }
                break;
        #endif /* HAVE_DILITHIUM */
        #endif /* HAVE_PQC */

            default:
                WOLFSSL_MSG("No key size check done on certificate");
                break; /* do no check if not a case for the key */
        }

    #ifdef WOLF_PRIVATE_KEY_ID
        if (ssl != NULL && ssl->buffers.keyType == 0) {
            ssl->buffers.keyType = keyType;
            ssl->buffers.keySz = keySz;
        }
        else if (ctx != NULL && ctx->privateKeyType == 0) {
            ctx->privateKeyType = keyType;
            ctx->privateKeySz = keySz;
        }
    #endif

        FreeDecodedCert(cert);
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(cert, heap, DYNAMIC_TYPE_DCERT);
    #endif

        if (ret != 0) {
            done = 1;
        }
    }

    if (done == 1) {
    #if !defined(NO_WOLFSSL_CM_VERIFY) && (!defined(NO_WOLFSSL_CLIENT) || \
                                           !defined(WOLFSSL_NO_CLIENT_AUTH))
        if ((type == CA_TYPE) || (type == CERT_TYPE)) {
            /* Call to over-ride status */
            if ((ctx != NULL) && (ctx->cm != NULL) &&
                (ctx->cm->verifyCallback != NULL)) {
                ret = CM_VerifyBuffer_ex(ctx->cm, buff,
                        sz, format, (ret == WOLFSSL_SUCCESS ? 0 : ret));
            }
        }
    #endif /* NO_WOLFSSL_CM_VERIFY */

        return ret;
    }


    if (ssl && resetSuites) {
        word16 havePSK = 0;
        word16 haveRSA = 0;

        #ifndef NO_PSK
        if (ssl->options.havePSK) {
            havePSK = 1;
        }
        #endif
        #ifndef NO_RSA
            haveRSA = 1;
        #endif
            keySz = ssl->buffers.keySz;

        /* let's reset suites */
        InitSuites(ssl->suites, ssl->version, keySz, haveRSA,
                   havePSK, ssl->options.haveDH, ssl->options.haveECDSAsig,
                   ssl->options.haveECC, TRUE, ssl->options.haveStaticECC,
                   ssl->options.haveFalconSig, ssl->options.haveDilithiumSig,
                   ssl->options.haveAnon, TRUE, ssl->options.side);
    }

    return WOLFSSL_SUCCESS;
}


/* CA PEM file for verification, may have multiple/chain certs to process */
static int ProcessChainBuffer(WOLFSSL_CTX* ctx, const unsigned char* buff,
                        long sz, int format, int type, WOLFSSL* ssl, int verify)
{
    long used   = 0;
    int  ret    = 0;
    int  gotOne = 0;

    WOLFSSL_MSG("Processing CA PEM file");
    while (used < sz) {
        long consumed = 0;

        ret = ProcessBuffer(ctx, buff + used, sz - used, format, type, ssl,
                            &consumed, 0, verify);

        if (ret < 0) {
#if defined(WOLFSSL_WPAS) && defined(HAVE_CRL)
            DerBuffer*    der = NULL;
            EncryptedInfo info;

            WOLFSSL_MSG("Trying a CRL");
            if (PemToDer(buff + used, sz - used, CRL_TYPE, &der, NULL, &info,
                                                                   NULL) == 0) {
                WOLFSSL_MSG("   Processed a CRL");
                wolfSSL_CertManagerLoadCRLBuffer(ctx->cm, der->buffer,
                                            der->length, WOLFSSL_FILETYPE_ASN1);
                FreeDer(&der);
                used += info.consumed;
                continue;
            }
#endif

            if (consumed > 0) { /* Made progress in file */
                WOLFSSL_ERROR(ret);
                WOLFSSL_MSG("CA Parse failed, with progress in file.");
                WOLFSSL_MSG("Search for other certs in file");
            }
            else {
                WOLFSSL_MSG("CA Parse failed, no progress in file.");
                WOLFSSL_MSG("Do not continue search for other certs in file");
                break;
            }
        }
        else {
            WOLFSSL_MSG("   Processed a CA");
            gotOne = 1;
        }
        used += consumed;
    }

    if (gotOne) {
        WOLFSSL_MSG("Processed at least one valid CA. Other stuff OK");
        return WOLFSSL_SUCCESS;
    }
    return ret;
}


static WC_INLINE WOLFSSL_METHOD* cm_pick_method(void)
{
    #ifndef NO_WOLFSSL_CLIENT
        #if !defined(NO_OLD_TLS) && defined(WOLFSSL_ALLOW_SSLV3)
            return wolfSSLv3_client_method();
        #elif !defined(NO_OLD_TLS) && defined(WOLFSSL_ALLOW_TLSV10)
            return wolfTLSv1_client_method();
        #elif !defined(NO_OLD_TLS)
            return wolfTLSv1_1_client_method();
        #elif !defined(WOLFSSL_NO_TLS12)
            return wolfTLSv1_2_client_method();
        #elif defined(WOLFSSL_TLS13)
            return wolfTLSv1_3_client_method();
        #else
            return NULL;
        #endif
    #elif !defined(NO_WOLFSSL_SERVER)
        #if !defined(NO_OLD_TLS) && defined(WOLFSSL_ALLOW_SSLV3)
            return wolfSSLv3_server_method();
        #elif !defined(NO_OLD_TLS) && defined(WOLFSSL_ALLOW_TLSV10)
            return wolfTLSv1_server_method();
        #elif !defined(NO_OLD_TLS)
            return wolfTLSv1_1_server_method();
        #elif !defined(WOLFSSL_NO_TLS12)
            return wolfTLSv1_2_server_method();
        #elif defined(WOLFSSL_TLS13)
            return wolfTLSv1_3_server_method();
        #else
            return NULL;
        #endif
    #else
        return NULL;
    #endif
}


int wolfSSL_CertManagerLoadCABuffer_ex(WOLFSSL_CERT_MANAGER* cm,
                                       const unsigned char* in, long sz,
                                       int format, int userChain, word32 flags)
{
    int ret = WOLFSSL_FATAL_ERROR;
    WOLFSSL_CTX* tmp;

    WOLFSSL_ENTER("wolfSSL_CertManagerLoadCABuffer_ex");

    if (cm == NULL) {
        WOLFSSL_MSG("No CertManager error");
        return ret;
    }
    tmp = wolfSSL_CTX_new(cm_pick_method());

    if (tmp == NULL) {
        WOLFSSL_MSG("CTX new failed");
        return ret;
    }

    /* for tmp use */
    wolfSSL_CertManagerFree(tmp->cm);
    tmp->cm = cm;

    ret = wolfSSL_CTX_load_verify_buffer_ex(tmp, in, sz, format,
                                            userChain, flags);

    /* don't loose our good one */
    tmp->cm = NULL;
    wolfSSL_CTX_free(tmp);

    return ret;
}

/* like load verify locations, 1 for success, < 0 for error */
int wolfSSL_CertManagerLoadCABuffer(WOLFSSL_CERT_MANAGER* cm,
                                    const unsigned char* in, long sz,
                                    int format)
{
    return wolfSSL_CertManagerLoadCABuffer_ex(cm, in, sz, format, 0,
                                             WOLFSSL_LOAD_VERIFY_DEFAULT_FLAGS);
}

#ifdef HAVE_CRL

int wolfSSL_CertManagerLoadCRLBuffer(WOLFSSL_CERT_MANAGER* cm,
                                   const unsigned char* buff, long sz, int type)
{
    WOLFSSL_ENTER("wolfSSL_CertManagerLoadCRLBuffer");
    if (cm == NULL)
        return BAD_FUNC_ARG;

    if (cm->crl == NULL) {
        if (wolfSSL_CertManagerEnableCRL(cm, 0) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("Enable CRL failed");
            return WOLFSSL_FATAL_ERROR;
        }
    }

    return BufferLoadCRL(cm->crl, buff, sz, type, VERIFY);
}

int wolfSSL_CertManagerFreeCRL(WOLFSSL_CERT_MANAGER* cm)
{
    WOLFSSL_ENTER("wolfSSL_CertManagerFreeCRL");
    if (cm == NULL)
        return BAD_FUNC_ARG;
    if (cm->crl != NULL){
        FreeCRL(cm->crl, 1);
        cm->crl = NULL;
    }
    return WOLFSSL_SUCCESS;
}

int wolfSSL_CTX_LoadCRLBuffer(WOLFSSL_CTX* ctx, const unsigned char* buff,
                              long sz, int type)
{
    WOLFSSL_ENTER("wolfSSL_CTX_LoadCRLBuffer");

    if (ctx == NULL)
        return BAD_FUNC_ARG;

    return wolfSSL_CertManagerLoadCRLBuffer(ctx->cm, buff, sz, type);
}


int wolfSSL_LoadCRLBuffer(WOLFSSL* ssl, const unsigned char* buff,
                          long sz, int type)
{
    WOLFSSL_ENTER("wolfSSL_LoadCRLBuffer");

    if (ssl == NULL || ssl->ctx == NULL)
        return BAD_FUNC_ARG;

    return wolfSSL_CertManagerLoadCRLBuffer(SSL_CM(ssl), buff, sz, type);
}


#endif /* HAVE_CRL */

/* turn on CRL if off and compiled in, set options */
int wolfSSL_CertManagerEnableCRL(WOLFSSL_CERT_MANAGER* cm, int options)
{
    int ret = WOLFSSL_SUCCESS;

    (void)options;

    WOLFSSL_ENTER("wolfSSL_CertManagerEnableCRL");
    if (cm == NULL)
        return BAD_FUNC_ARG;

    #ifdef HAVE_CRL
        if (cm->crl == NULL) {
            cm->crl = (WOLFSSL_CRL*)XMALLOC(sizeof(WOLFSSL_CRL), cm->heap,
                                            DYNAMIC_TYPE_CRL);
            if (cm->crl == NULL)
                return MEMORY_E;

            if (InitCRL(cm->crl, cm) != 0) {
                WOLFSSL_MSG("Init CRL failed");
                FreeCRL(cm->crl, 1);
                cm->crl = NULL;
                return WOLFSSL_FAILURE;
            }

        #if defined(HAVE_CRL_IO) && defined(USE_WOLFSSL_IO)
            cm->crl->crlIOCb = EmbedCrlLookup;
        #endif
        }

        cm->crlEnabled = 1;
        if (options & WOLFSSL_CRL_CHECKALL)
            cm->crlCheckAll = 1;
    #else
        ret = NOT_COMPILED_IN;
    #endif

    return ret;
}


int wolfSSL_CertManagerDisableCRL(WOLFSSL_CERT_MANAGER* cm)
{
    WOLFSSL_ENTER("wolfSSL_CertManagerDisableCRL");
    if (cm == NULL)
        return BAD_FUNC_ARG;

    cm->crlEnabled = 0;

    return WOLFSSL_SUCCESS;
}

#ifndef NO_WOLFSSL_CM_VERIFY
void wolfSSL_CertManagerSetVerify(WOLFSSL_CERT_MANAGER* cm, VerifyCallback vc)
{
    WOLFSSL_ENTER("wolfSSL_CertManagerSetVerify");
    if (cm == NULL)
        return;

    cm->verifyCallback = vc;
}
#endif /* NO_WOLFSSL_CM_VERIFY */

#if !defined(NO_WOLFSSL_CLIENT) || !defined(WOLFSSL_NO_CLIENT_AUTH)
/* Verify the certificate, WOLFSSL_SUCCESS for ok, < 0 for error */
int CM_VerifyBuffer_ex(WOLFSSL_CERT_MANAGER* cm, const byte* buff,
                                    long sz, int format, int err_val)
{
    int ret = 0;
    DerBuffer* der = NULL;
#ifdef WOLFSSL_SMALL_STACK
    DecodedCert* cert;
#else
    DecodedCert  cert[1];
#endif

    WOLFSSL_ENTER("wolfSSL_CertManagerVerifyBuffer");

#ifdef WOLFSSL_SMALL_STACK
    cert = (DecodedCert*)XMALLOC(sizeof(DecodedCert), cm->heap,
                                 DYNAMIC_TYPE_DCERT);
    if (cert == NULL)
        return MEMORY_E;
#endif

    if (format == WOLFSSL_FILETYPE_PEM) {
#ifdef WOLFSSL_PEM_TO_DER
        ret = PemToDer(buff, sz, CERT_TYPE, &der, cm->heap, NULL, NULL);
        if (ret != 0) {
            FreeDer(&der);
        #ifdef WOLFSSL_SMALL_STACK
            XFREE(cert, cm->heap, DYNAMIC_TYPE_DCERT);
        #endif
            return ret;
        }
        InitDecodedCert(cert, der->buffer, der->length, cm->heap);
#else
        ret = NOT_COMPILED_IN;
#endif
    }
    else {
        InitDecodedCert(cert, buff, (word32)sz, cm->heap);
    }

    if (ret == 0)
        ret = ParseCertRelative(cert, CERT_TYPE, 1, cm);

#ifdef HAVE_CRL
    if (ret == 0 && cm->crlEnabled)
        ret = CheckCertCRL(cm->crl, cert);
#endif

#ifndef NO_WOLFSSL_CM_VERIFY
    /* if verify callback has been set */
    if (cm->verifyCallback) {
        buffer certBuf;
    #ifdef WOLFSSL_SMALL_STACK
        ProcPeerCertArgs* args;
        args = (ProcPeerCertArgs*)XMALLOC(
            sizeof(ProcPeerCertArgs), cm->heap, DYNAMIC_TYPE_TMP_BUFFER);
        if (args == NULL) {
            XFREE(cert, cm->heap, DYNAMIC_TYPE_DCERT);
            return MEMORY_E;
        }
    #else
        ProcPeerCertArgs  args[1];
    #endif

        certBuf.buffer = (byte*)buff;
        certBuf.length = (unsigned int)sz;
        XMEMSET(args, 0, sizeof(ProcPeerCertArgs));

        args->totalCerts = 1;
        args->certs = &certBuf;
        args->dCert = cert;
        args->dCertInit = 1;

        if (err_val != 0) {
            ret = err_val;
        }
        ret = DoVerifyCallback(cm, NULL, ret, args);
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(args, cm->heap, DYNAMIC_TYPE_TMP_BUFFER);
    #endif
    }
#else
    (void)err_val;
#endif

    FreeDecodedCert(cert);
    FreeDer(&der);
#ifdef WOLFSSL_SMALL_STACK
    XFREE(cert, cm->heap, DYNAMIC_TYPE_DCERT);
#endif

    return ret == 0 ? WOLFSSL_SUCCESS : ret;
}

/* Verify the certificate, WOLFSSL_SUCCESS for ok, < 0 for error */
int wolfSSL_CertManagerVerifyBuffer(WOLFSSL_CERT_MANAGER* cm, const byte* buff,
                                    long sz, int format)
{
    return CM_VerifyBuffer_ex(cm, buff, sz, format, 0);
}
#endif /* !NO_WOLFSSL_CLIENT || !WOLFSSL_NO_CLIENT_AUTH */

/* turn on OCSP if off and compiled in, set options */
int wolfSSL_CertManagerEnableOCSP(WOLFSSL_CERT_MANAGER* cm, int options)
{
    int ret = WOLFSSL_SUCCESS;

    (void)options;

    WOLFSSL_ENTER("wolfSSL_CertManagerEnableOCSP");
    if (cm == NULL)
        return BAD_FUNC_ARG;

    #ifdef HAVE_OCSP
        if (cm->ocsp == NULL) {
            cm->ocsp = (WOLFSSL_OCSP*)XMALLOC(sizeof(WOLFSSL_OCSP), cm->heap,
                                              DYNAMIC_TYPE_OCSP);
            if (cm->ocsp == NULL)
                return MEMORY_E;

            if (InitOCSP(cm->ocsp, cm) != 0) {
                WOLFSSL_MSG("Init OCSP failed");
                FreeOCSP(cm->ocsp, 1);
                cm->ocsp = NULL;
                return WOLFSSL_FAILURE;
            }
        }
        cm->ocspEnabled = 1;
        if (options & WOLFSSL_OCSP_URL_OVERRIDE)
            cm->ocspUseOverrideURL = 1;
        if (options & WOLFSSL_OCSP_NO_NONCE)
            cm->ocspSendNonce = 0;
        else
            cm->ocspSendNonce = 1;
        if (options & WOLFSSL_OCSP_CHECKALL)
            cm->ocspCheckAll = 1;
        #ifndef WOLFSSL_USER_IO
            cm->ocspIOCb = EmbedOcspLookup;
            cm->ocspRespFreeCb = EmbedOcspRespFree;
            cm->ocspIOCtx = cm->heap;
        #endif /* WOLFSSL_USER_IO */
    #else
        ret = NOT_COMPILED_IN;
    #endif

    return ret;
}


int wolfSSL_CertManagerDisableOCSP(WOLFSSL_CERT_MANAGER* cm)
{
    WOLFSSL_ENTER("wolfSSL_CertManagerDisableOCSP");
    if (cm == NULL)
        return BAD_FUNC_ARG;

    cm->ocspEnabled = 0;

    return WOLFSSL_SUCCESS;
}

/* turn on OCSP Stapling if off and compiled in, set options */
int wolfSSL_CertManagerEnableOCSPStapling(WOLFSSL_CERT_MANAGER* cm)
{
    int ret = WOLFSSL_SUCCESS;

    WOLFSSL_ENTER("wolfSSL_CertManagerEnableOCSPStapling");

    if (cm == NULL)
        return BAD_FUNC_ARG;

#if defined(HAVE_CERTIFICATE_STATUS_REQUEST) \
 || defined(HAVE_CERTIFICATE_STATUS_REQUEST_V2)
    #ifndef NO_WOLFSSL_SERVER
    if (cm->ocsp_stapling == NULL) {
        cm->ocsp_stapling = (WOLFSSL_OCSP*)XMALLOC(sizeof(WOLFSSL_OCSP),
                                               cm->heap, DYNAMIC_TYPE_OCSP);
        if (cm->ocsp_stapling == NULL)
            return MEMORY_E;

        if (InitOCSP(cm->ocsp_stapling, cm) != 0) {
            WOLFSSL_MSG("Init OCSP failed");
            FreeOCSP(cm->ocsp_stapling, 1);
            cm->ocsp_stapling = NULL;
            return WOLFSSL_FAILURE;
        }
    }

    #ifndef WOLFSSL_USER_IO
        cm->ocspIOCb = EmbedOcspLookup;
        cm->ocspRespFreeCb = EmbedOcspRespFree;
        cm->ocspIOCtx = cm->heap;
    #endif /* WOLFSSL_USER_IO */
    #endif /* NO_WOLFSSL_SERVER */
    cm->ocspStaplingEnabled = 1;
#else
    ret = NOT_COMPILED_IN;
#endif

    return ret;
}

int wolfSSL_CertManagerDisableOCSPStapling(WOLFSSL_CERT_MANAGER* cm)
{
    int ret = WOLFSSL_SUCCESS;

    WOLFSSL_ENTER("wolfSSL_CertManagerDisableOCSPStapling");

    if (cm == NULL)
        return BAD_FUNC_ARG;

#if defined(HAVE_CERTIFICATE_STATUS_REQUEST) \
 || defined(HAVE_CERTIFICATE_STATUS_REQUEST_V2)
    cm->ocspStaplingEnabled = 0;
#else
    ret = NOT_COMPILED_IN;
#endif
    return ret;
}

/* require OCSP stapling response */
int wolfSSL_CertManagerEnableOCSPMustStaple(WOLFSSL_CERT_MANAGER* cm)
{
    int ret;

    WOLFSSL_ENTER("wolfSSL_CertManagerEnableOCSPMustStaple");

    if (cm == NULL)
        return BAD_FUNC_ARG;

#if defined(HAVE_CERTIFICATE_STATUS_REQUEST) \
 || defined(HAVE_CERTIFICATE_STATUS_REQUEST_V2)
    #ifndef NO_WOLFSSL_CLIENT
        cm->ocspMustStaple = 1;
    #endif
    ret = WOLFSSL_SUCCESS;
#else
    ret = NOT_COMPILED_IN;
#endif

    return ret;
}

int wolfSSL_CertManagerDisableOCSPMustStaple(WOLFSSL_CERT_MANAGER* cm)
{
    int ret;

    WOLFSSL_ENTER("wolfSSL_CertManagerDisableOCSPMustStaple");

    if (cm == NULL)
        return BAD_FUNC_ARG;

#if defined(HAVE_CERTIFICATE_STATUS_REQUEST) \
 || defined(HAVE_CERTIFICATE_STATUS_REQUEST_V2)
    #ifndef NO_WOLFSSL_CLIENT
        cm->ocspMustStaple = 0;
    #endif
    ret = WOLFSSL_SUCCESS;
#else
    ret = NOT_COMPILED_IN;
#endif
    return ret;
}

#ifdef HAVE_OCSP
/* check CRL if enabled, WOLFSSL_SUCCESS  */
int wolfSSL_CertManagerCheckOCSP(WOLFSSL_CERT_MANAGER* cm, byte* der, int sz)
{
    int ret;
#ifdef WOLFSSL_SMALL_STACK
    DecodedCert* cert = NULL;
#else
    DecodedCert  cert[1];
#endif

    WOLFSSL_ENTER("wolfSSL_CertManagerCheckOCSP");

    if (cm == NULL)
        return BAD_FUNC_ARG;

    if (cm->ocspEnabled == 0)
        return WOLFSSL_SUCCESS;

#ifdef WOLFSSL_SMALL_STACK
    cert = (DecodedCert*)XMALLOC(sizeof(DecodedCert), cm->heap, DYNAMIC_TYPE_DCERT);
    if (cert == NULL)
        return MEMORY_E;
#endif

    InitDecodedCert(cert, der, sz, NULL);

    if ((ret = ParseCertRelative(cert, CERT_TYPE, VERIFY_OCSP, cm)) != 0) {
        WOLFSSL_MSG("ParseCert failed");
    }
    else if ((ret = CheckCertOCSP(cm->ocsp, cert, NULL)) != 0) {
        WOLFSSL_MSG("CheckCertOCSP failed");
    }

    FreeDecodedCert(cert);
#ifdef WOLFSSL_SMALL_STACK
    XFREE(cert, cm->heap, DYNAMIC_TYPE_DCERT);
#endif

    return ret == 0 ? WOLFSSL_SUCCESS : ret;
}

int wolfSSL_CertManagerCheckOCSPResponse(WOLFSSL_CERT_MANAGER *cm,
    byte *response, int responseSz, buffer *responseBuffer,
    CertStatus *status, OcspEntry *entry, OcspRequest *ocspRequest)
{
    int ret;

    WOLFSSL_ENTER("wolfSSL_CertManagerCheckOCSPResponse");
    if (cm == NULL || response == NULL)
        return BAD_FUNC_ARG;
    if (cm->ocspEnabled == 0)
        return WOLFSSL_SUCCESS;

    ret = CheckOcspResponse(cm->ocsp, response, responseSz, responseBuffer, status,
                        entry, ocspRequest);

    return ret == 0 ? WOLFSSL_SUCCESS : ret;
}

int wolfSSL_CertManagerSetOCSPOverrideURL(WOLFSSL_CERT_MANAGER* cm,
                                          const char* url)
{
    WOLFSSL_ENTER("wolfSSL_CertManagerSetOCSPOverrideURL");
    if (cm == NULL)
        return BAD_FUNC_ARG;

    XFREE(cm->ocspOverrideURL, cm->heap, DYNAMIC_TYPE_URL);
    if (url != NULL) {
        int urlSz = (int)XSTRLEN(url) + 1;
        cm->ocspOverrideURL = (char*)XMALLOC(urlSz, cm->heap, DYNAMIC_TYPE_URL);
        if (cm->ocspOverrideURL != NULL) {
            XMEMCPY(cm->ocspOverrideURL, url, urlSz);
        }
        else
            return MEMORY_E;
    }
    else
        cm->ocspOverrideURL = NULL;

    return WOLFSSL_SUCCESS;
}


int wolfSSL_CertManagerSetOCSP_Cb(WOLFSSL_CERT_MANAGER* cm,
                        CbOCSPIO ioCb, CbOCSPRespFree respFreeCb, void* ioCbCtx)
{
    WOLFSSL_ENTER("wolfSSL_CertManagerSetOCSP_Cb");
    if (cm == NULL)
        return BAD_FUNC_ARG;

    cm->ocspIOCb = ioCb;
    cm->ocspRespFreeCb = respFreeCb;
    cm->ocspIOCtx = ioCbCtx;

    return WOLFSSL_SUCCESS;
}


int wolfSSL_EnableOCSP(WOLFSSL* ssl, int options)
{
    WOLFSSL_ENTER("wolfSSL_EnableOCSP");
    if (ssl)
        return wolfSSL_CertManagerEnableOCSP(SSL_CM(ssl), options);
    else
        return BAD_FUNC_ARG;
}

int wolfSSL_DisableOCSP(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_DisableOCSP");
    if (ssl)
        return wolfSSL_CertManagerDisableOCSP(SSL_CM(ssl));
    else
        return BAD_FUNC_ARG;
}


int wolfSSL_EnableOCSPStapling(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_EnableOCSPStapling");
    if (ssl)
        return wolfSSL_CertManagerEnableOCSPStapling(SSL_CM(ssl));
    else
        return BAD_FUNC_ARG;
}

int wolfSSL_DisableOCSPStapling(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_DisableOCSPStapling");
    if (ssl)
        return wolfSSL_CertManagerDisableOCSPStapling(SSL_CM(ssl));
    else
        return BAD_FUNC_ARG;
}

int wolfSSL_SetOCSP_OverrideURL(WOLFSSL* ssl, const char* url)
{
    WOLFSSL_ENTER("wolfSSL_SetOCSP_OverrideURL");
    if (ssl)
        return wolfSSL_CertManagerSetOCSPOverrideURL(SSL_CM(ssl), url);
    else
        return BAD_FUNC_ARG;
}


int wolfSSL_SetOCSP_Cb(WOLFSSL* ssl,
                        CbOCSPIO ioCb, CbOCSPRespFree respFreeCb, void* ioCbCtx)
{
    WOLFSSL_ENTER("wolfSSL_SetOCSP_Cb");
    if (ssl) {
        ssl->ocspIOCtx = ioCbCtx; /* use SSL specific ioCbCtx */
        return wolfSSL_CertManagerSetOCSP_Cb(SSL_CM(ssl),
                                             ioCb, respFreeCb, NULL);
    }
    else
        return BAD_FUNC_ARG;
}


int wolfSSL_CTX_EnableOCSP(WOLFSSL_CTX* ctx, int options)
{
    WOLFSSL_ENTER("wolfSSL_CTX_EnableOCSP");
    if (ctx)
        return wolfSSL_CertManagerEnableOCSP(ctx->cm, options);
    else
        return BAD_FUNC_ARG;
}


int wolfSSL_CTX_DisableOCSP(WOLFSSL_CTX* ctx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_DisableOCSP");
    if (ctx)
        return wolfSSL_CertManagerDisableOCSP(ctx->cm);
    else
        return BAD_FUNC_ARG;
}


int wolfSSL_CTX_SetOCSP_OverrideURL(WOLFSSL_CTX* ctx, const char* url)
{
    WOLFSSL_ENTER("wolfSSL_SetOCSP_OverrideURL");
    if (ctx)
        return wolfSSL_CertManagerSetOCSPOverrideURL(ctx->cm, url);
    else
        return BAD_FUNC_ARG;
}


int wolfSSL_CTX_SetOCSP_Cb(WOLFSSL_CTX* ctx, CbOCSPIO ioCb,
                           CbOCSPRespFree respFreeCb, void* ioCbCtx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_SetOCSP_Cb");
    if (ctx)
        return wolfSSL_CertManagerSetOCSP_Cb(ctx->cm, ioCb,
                                             respFreeCb, ioCbCtx);
    else
        return BAD_FUNC_ARG;
}

#if defined(HAVE_CERTIFICATE_STATUS_REQUEST) \
 || defined(HAVE_CERTIFICATE_STATUS_REQUEST_V2)
int wolfSSL_CTX_EnableOCSPStapling(WOLFSSL_CTX* ctx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_EnableOCSPStapling");
    if (ctx)
        return wolfSSL_CertManagerEnableOCSPStapling(ctx->cm);
    else
        return BAD_FUNC_ARG;
}

int wolfSSL_CTX_DisableOCSPStapling(WOLFSSL_CTX* ctx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_DisableOCSPStapling");
    if (ctx)
        return wolfSSL_CertManagerDisableOCSPStapling(ctx->cm);
    else
        return BAD_FUNC_ARG;
}

int wolfSSL_CTX_EnableOCSPMustStaple(WOLFSSL_CTX* ctx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_EnableOCSPMustStaple");
    if (ctx)
        return wolfSSL_CertManagerEnableOCSPMustStaple(ctx->cm);
    else
        return BAD_FUNC_ARG;
}

int wolfSSL_CTX_DisableOCSPMustStaple(WOLFSSL_CTX* ctx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_DisableOCSPMustStaple");
    if (ctx)
        return wolfSSL_CertManagerDisableOCSPMustStaple(ctx->cm);
    else
        return BAD_FUNC_ARG;
}
#endif /* HAVE_CERTIFICATE_STATUS_REQUEST || HAVE_CERTIFICATE_STATUS_REQUEST_V2 */

#endif /* HAVE_OCSP */

/* macro to get verify settings for AddCA */
#define GET_VERIFY_SETTING_CTX(ctx) \
    ((ctx) && (ctx)->verifyNone ? NO_VERIFY : VERIFY)
#define GET_VERIFY_SETTING_SSL(ssl) \
    ((ssl)->options.verifyNone ? NO_VERIFY : VERIFY)

#ifndef NO_FILESYSTEM

/* process a file with name fname into ctx of format and type
   userChain specifies a user certificate chain to pass during handshake */
int ProcessFile(WOLFSSL_CTX* ctx, const char* fname, int format, int type,
                WOLFSSL* ssl, int userChain, WOLFSSL_CRL* crl, int verify)
{
#ifdef WOLFSSL_SMALL_STACK
    byte   staticBuffer[1]; /* force heap usage */
#else
    byte   staticBuffer[FILE_BUFFER_SIZE];
#endif
    byte*  myBuffer = staticBuffer;
    int    dynamic = 0;
    int    ret;
    long   sz = 0;
    XFILE  file;
    void*  heapHint = wolfSSL_CTX_GetHeap(ctx, ssl);
#ifndef NO_CODING
    const char* header = NULL;
    const char* footer = NULL;
#endif

    (void)crl;
    (void)heapHint;

    if (fname == NULL) return WOLFSSL_BAD_FILE;

    file = XFOPEN(fname, "rb");
    if (file == XBADFILE) return WOLFSSL_BAD_FILE;
    if (XFSEEK(file, 0, XSEEK_END) != 0) {
        XFCLOSE(file);
        return WOLFSSL_BAD_FILE;
    }
    sz = XFTELL(file);
    XREWIND(file);

    if (sz > MAX_WOLFSSL_FILE_SIZE || sz <= 0) {
        WOLFSSL_MSG("ProcessFile file size error");
        XFCLOSE(file);
        return WOLFSSL_BAD_FILE;
    }

    if (sz > (long)sizeof(staticBuffer)) {
        WOLFSSL_MSG("Getting dynamic buffer");
        myBuffer = (byte*)XMALLOC(sz, heapHint, DYNAMIC_TYPE_FILE);
        if (myBuffer == NULL) {
            XFCLOSE(file);
            return WOLFSSL_BAD_FILE;
        }
        dynamic = 1;
    }

    if ((size_t)XFREAD(myBuffer, 1, sz, file) != (size_t)sz)
        ret = WOLFSSL_BAD_FILE;
    else {
        /* Try to detect type by parsing cert header and footer */
        if (type == DETECT_CERT_TYPE) {
#ifndef NO_CODING
            if (wc_PemGetHeaderFooter(CA_TYPE, &header, &footer) == 0 &&
               (XSTRNSTR((char*)myBuffer, header, (int)sz) != NULL)) {
                type = CA_TYPE;
            }
#ifdef HAVE_CRL
            else if (wc_PemGetHeaderFooter(CRL_TYPE, &header, &footer) == 0 &&
                    (XSTRNSTR((char*)myBuffer, header, (int)sz) != NULL)) {
                type = CRL_TYPE;
            }
#endif
            else if (wc_PemGetHeaderFooter(CERT_TYPE, &header, &footer) == 0 &&
                    (XSTRNSTR((char*)myBuffer, header, (int)sz) != NULL)) {
                type = CERT_TYPE;
            }
            else
#endif
            {
                WOLFSSL_MSG("Failed to detect certificate type");
                if (dynamic)
                    XFREE(myBuffer, heapHint, DYNAMIC_TYPE_FILE);
                XFCLOSE(file);
                return WOLFSSL_BAD_CERTTYPE;
            }
        }
        if ((type == CA_TYPE || type == TRUSTED_PEER_TYPE)
                                          && format == WOLFSSL_FILETYPE_PEM) {
            ret = ProcessChainBuffer(ctx, myBuffer, sz, format, type, ssl,
                                     verify);
        }
#ifdef HAVE_CRL
        else if (type == CRL_TYPE)
            ret = BufferLoadCRL(crl, myBuffer, sz, format, verify);
#endif
        else
            ret = ProcessBuffer(ctx, myBuffer, sz, format, type, ssl, NULL,
                                userChain, verify);
    }

    XFCLOSE(file);
    if (dynamic)
        XFREE(myBuffer, heapHint, DYNAMIC_TYPE_FILE);

    return ret;
}

/* loads file then loads each file in path, no c_rehash */
int wolfSSL_CTX_load_verify_locations_ex(WOLFSSL_CTX* ctx, const char* file,
                                     const char* path, word32 flags)
{
    int ret = WOLFSSL_SUCCESS;
#ifndef NO_WOLFSSL_DIR
    int fileRet;
    int successCount = 0;
    int failCount = 0;
#endif
    int verify;

    WOLFSSL_MSG("wolfSSL_CTX_load_verify_locations_ex");

    if (ctx == NULL || (file == NULL && path == NULL)) {
        return WOLFSSL_FAILURE;
    }

    verify = GET_VERIFY_SETTING_CTX(ctx);
    if (flags & WOLFSSL_LOAD_FLAG_DATE_ERR_OKAY)
        verify = VERIFY_SKIP_DATE;

    if (file) {
        ret = ProcessFile(ctx, file, WOLFSSL_FILETYPE_PEM, CA_TYPE, NULL, 0,
                          NULL, verify);
#ifndef NO_WOLFSSL_DIR
        if (ret == WOLFSSL_SUCCESS)
            successCount++;
#endif
#if defined(WOLFSSL_TRUST_PEER_CERT) && defined(OPENSSL_COMPATIBLE_DEFAULTS)
        ret = wolfSSL_CTX_trust_peer_cert(ctx, file, WOLFSSL_FILETYPE_PEM);
        if (ret != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("wolfSSL_CTX_trust_peer_cert error");
        }
#endif
    }

    if (ret == WOLFSSL_SUCCESS && path) {
#ifndef NO_WOLFSSL_DIR
        char* name = NULL;
    #ifdef WOLFSSL_SMALL_STACK
        ReadDirCtx* readCtx;
        readCtx = (ReadDirCtx*)XMALLOC(sizeof(ReadDirCtx), ctx->heap,
                                                       DYNAMIC_TYPE_DIRCTX);
        if (readCtx == NULL)
            return MEMORY_E;
    #else
        ReadDirCtx readCtx[1];
    #endif

        /* try to load each regular file in path */
        fileRet = wc_ReadDirFirst(readCtx, path, &name);
        while (fileRet == 0 && name) {
            WOLFSSL_MSG(name); /* log file name */
            ret = ProcessFile(ctx, name, WOLFSSL_FILETYPE_PEM, CA_TYPE,
                              NULL, 0, NULL, verify);
            if (ret != WOLFSSL_SUCCESS) {
                /* handle flags for ignoring errors, skipping expired certs or
                   by PEM certificate header error */
                if ( (flags & WOLFSSL_LOAD_FLAG_IGNORE_ERR) ||
                    ((flags & WOLFSSL_LOAD_FLAG_PEM_CA_ONLY) &&
                       (ret == ASN_NO_PEM_HEADER))) {
                    /* Do not fail here if a certificate fails to load,
                       continue to next file */
                    unsigned long err;
                    CLEAR_ASN_NO_PEM_HEADER_ERROR(err);
    #if defined(WOLFSSL_QT)
                    ret = WOLFSSL_SUCCESS;
    #endif
                }
                else {
                    WOLFSSL_ERROR(ret);
                    WOLFSSL_MSG("Load CA file failed, continuing");
                    failCount++;
                }
            }
            else {
    #if defined(WOLFSSL_TRUST_PEER_CERT) && defined(OPENSSL_COMPATIBLE_DEFAULTS)
                ret = wolfSSL_CTX_trust_peer_cert(ctx, file, WOLFSSL_FILETYPE_PEM);
                if (ret != WOLFSSL_SUCCESS) {
                    WOLFSSL_MSG("wolfSSL_CTX_trust_peer_cert error. Ignoring"
                            "this error.");
                }
    #endif
                successCount++;
            }
            fileRet = wc_ReadDirNext(readCtx, path, &name);
        }
        wc_ReadDirClose(readCtx);

        /* pass directory read failure to response code */
        if (fileRet != WC_READDIR_NOFILE) {
            ret = fileRet;
    #if defined(WOLFSSL_QT)
            if (ret == BAD_PATH_ERROR &&
                flags & WOLFSSL_LOAD_FLAG_IGNORE_BAD_PATH_ERR) {
               /* QSslSocket always loads certs in system folder
                * when it is initialized.
                * Compliant with OpenSSL when flag sets.
                */
                ret = WOLFSSL_SUCCESS;
            }
            else {
                /* qssl socket wants to know errors. */
                WOLFSSL_ERROR(ret);
            }
    #endif
        }
        /* report failure if no files were loaded or there were failures */
        else if (successCount == 0 || failCount > 0) {
            /* use existing error code if exists */
    #if defined(WOLFSSL_QT)
            /* compliant with OpenSSL when flag sets*/
            if (!(flags & WOLFSSL_LOAD_FLAG_IGNORE_ZEROFILE))
    #endif
            {
                ret = WOLFSSL_FAILURE;
            }
        }
        else {
            ret = WOLFSSL_SUCCESS;
        }

    #ifdef WOLFSSL_SMALL_STACK
        XFREE(readCtx, ctx->heap, DYNAMIC_TYPE_DIRCTX);
    #endif
#else
        ret = NOT_COMPILED_IN;
        (void)flags;
#endif
    }

    return ret;
}

WOLFSSL_ABI
int wolfSSL_CTX_load_verify_locations(WOLFSSL_CTX* ctx, const char* file,
                                     const char* path)
{
    int ret = wolfSSL_CTX_load_verify_locations_ex(ctx, file, path,
        WOLFSSL_LOAD_VERIFY_DEFAULT_FLAGS);

    return WS_RETURN_CODE(ret,WOLFSSL_FAILURE);
}

#ifdef WOLFSSL_SYS_CA_CERTS

#ifdef USE_WINDOWS_API

static int LoadSystemCaCertsWindows(WOLFSSL_CTX* ctx, byte* loaded)
{
    int ret = WOLFSSL_SUCCESS;
    word32 i;
    HANDLE handle = NULL;
    PCCERT_CONTEXT certCtx = NULL;
    LPCSTR storeNames[2] = {"ROOT", "CA"};
    HCRYPTPROV_LEGACY hProv = (HCRYPTPROV_LEGACY)NULL;

    if (ctx == NULL || loaded == NULL) {
        ret = WOLFSSL_FAILURE;
    }

    for (i = 0; ret == WOLFSSL_SUCCESS &&
         i < sizeof(storeNames)/sizeof(*storeNames); ++i) {
        handle = CertOpenSystemStoreA(hProv, storeNames[i]);
        if (handle != NULL) {
            while ((certCtx = CertEnumCertificatesInStore(handle, certCtx))
                   != NULL) {
                if (certCtx->dwCertEncodingType == X509_ASN_ENCODING) {
                    if (ProcessBuffer(ctx, certCtx->pbCertEncoded,
                          certCtx->cbCertEncoded, WOLFSSL_FILETYPE_ASN1,
                          CA_TYPE, NULL, NULL, 0,
                          GET_VERIFY_SETTING_CTX(ctx)) == WOLFSSL_SUCCESS) {
                        /*
                         * Set "loaded" as long as we've loaded one CA
                         * cert.
                         */
                        *loaded = 1;
                    }
                }
            }
        }
        else {
            WOLFSSL_MSG_EX("Failed to open cert store %s.", storeNames[i]);
        }

        if (handle != NULL && !CertCloseStore(handle, 0)) {
            WOLFSSL_MSG_EX("Failed to close cert store %s.", storeNames[i]);
            ret = WOLFSSL_FAILURE;
        }
    }

    return ret;
}

#elif defined(__APPLE__)

static int LoadSystemCaCertsMac(WOLFSSL_CTX* ctx, byte* loaded)
{
    int ret = WOLFSSL_SUCCESS;
    word32 i;
    const unsigned int trustDomains[] = {
        kSecTrustSettingsDomainUser,
        kSecTrustSettingsDomainAdmin,
        kSecTrustSettingsDomainSystem
    };
    CFArrayRef certs;
    OSStatus stat;
    CFIndex numCerts;
    CFDataRef der;
    CFIndex j;

    if (ctx == NULL || loaded == NULL) {
        ret = WOLFSSL_FAILURE;
    }

    for (i = 0; ret == WOLFSSL_SUCCESS &&
         i < sizeof(trustDomains)/sizeof(*trustDomains); ++i) {
        stat = SecTrustSettingsCopyCertificates(trustDomains[i], &certs);

        if (stat == errSecSuccess) {
            numCerts = CFArrayGetCount(certs);
            for (j = 0; j < numCerts; ++j) {
                der = SecCertificateCopyData((SecCertificateRef)
                          CFArrayGetValueAtIndex(certs, j));
                if (der != NULL) {
                    if (ProcessBuffer(ctx, CFDataGetBytePtr(der),
                          CFDataGetLength(der), WOLFSSL_FILETYPE_ASN1,
                          CA_TYPE, NULL, NULL, 0,
                          GET_VERIFY_SETTING_CTX(ctx)) == WOLFSSL_SUCCESS) {
                        /*
                         * Set "loaded" as long as we've loaded one CA
                         * cert.
                         */
                        *loaded = 1;
                    }

                    CFRelease(der);
                }
            }

            CFRelease(certs);
        }
        else if (stat == errSecNoTrustSettings) {
            WOLFSSL_MSG_EX("No trust settings for domain %d, moving to next "
                "domain.", trustDomains[i]);
        }
        else {
            WOLFSSL_MSG_EX("SecTrustSettingsCopyCertificates failed with"
                " status %d.", stat);
            ret = WOLFSSL_FAILURE;
            break;
        }
    }

    return ret;
}

#else

/* Potential system CA certs directories on Linux/Unix distros. */
static const char* systemCaDirs[] = {
#if defined(__ANDROID__) || defined(ANDROID)
    "/system/etc/security/cacerts"      /* Android */
#else
    "/etc/ssl/certs",                   /* Debian, Ubuntu, Gentoo, others */
    "/etc/pki/ca-trust/source/anchors", /* Fedora, RHEL */
    "/etc/pki/tls/certs"                /* Older RHEL */
#endif
};

const char** wolfSSL_get_system_CA_dirs(word32* num)
{
    const char** ret;

    if (num == NULL) {
        ret = NULL;
    }
    else {
        ret = systemCaDirs;
        *num = sizeof(systemCaDirs)/sizeof(*systemCaDirs);
    }

    return ret;
}

static int LoadSystemCaCertsNix(WOLFSSL_CTX* ctx, byte* loaded) {
    int ret = WOLFSSL_SUCCESS;
    word32 i;

    if (ctx == NULL || loaded == NULL) {
        ret = WOLFSSL_FAILURE;
    }

    for (i = 0; ret == WOLFSSL_SUCCESS &&
         i < sizeof(systemCaDirs)/sizeof(*systemCaDirs); ++i) {
        WOLFSSL_MSG_EX("Attempting to load system CA certs from %s.",
            systemCaDirs[i]);
        /*
         * We want to keep trying to load more CAs even if one cert in
         * the directory is bad and can't be used (e.g. if one is expired),
         * so we use WOLFSSL_LOAD_FLAG_IGNORE_ERR.
         */
        if (wolfSSL_CTX_load_verify_locations_ex(ctx, NULL, systemCaDirs[i],
                WOLFSSL_LOAD_FLAG_IGNORE_ERR) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG_EX("Failed to load CA certs from %s, trying "
                "next possible location.", systemCaDirs[i]);
        }
        else {
            WOLFSSL_MSG_EX("Loaded CA certs from %s.",
                systemCaDirs[i]);
            *loaded = 1;
            /* Stop searching after we've loaded one directory. */
            break;
        }
    }

    return ret;
}

#endif

int wolfSSL_CTX_load_system_CA_certs(WOLFSSL_CTX* ctx)
{
    int ret;
    byte loaded = 0;

    WOLFSSL_ENTER("wolfSSL_CTX_load_system_CA_certs");

#ifdef USE_WINDOWS_API
    ret = LoadSystemCaCertsWindows(ctx, &loaded);
#elif defined(__APPLE__)
    ret = LoadSystemCaCertsMac(ctx, &loaded);
#else
    ret = LoadSystemCaCertsNix(ctx, &loaded);
#endif

    if (ret == WOLFSSL_SUCCESS && !loaded) {
        ret = WOLFSSL_BAD_PATH;
    }

    WOLFSSL_LEAVE("wolfSSL_CTX_load_system_CA_certs", ret);

    return ret;
}

#endif /* WOLFSSL_SYS_CA_CERTS */

#ifdef WOLFSSL_TRUST_PEER_CERT
/* Used to specify a peer cert to match when connecting
    ctx : the ctx structure to load in peer cert
    file: the string name of cert file
    type: type of format such as PEM/DER
 */
int wolfSSL_CTX_trust_peer_cert(WOLFSSL_CTX* ctx, const char* file, int type)
{
    WOLFSSL_ENTER("wolfSSL_CTX_trust_peer_cert");

    if (ctx == NULL || file == NULL) {
        return WOLFSSL_FAILURE;
    }

    return ProcessFile(ctx, file, type, TRUSTED_PEER_TYPE, NULL, 0, NULL,
                       GET_VERIFY_SETTING_CTX(ctx));
}

int wolfSSL_trust_peer_cert(WOLFSSL* ssl, const char* file, int type)
{
    WOLFSSL_ENTER("wolfSSL_trust_peer_cert");

    if (ssl == NULL || file == NULL) {
        return WOLFSSL_FAILURE;
    }

    return ProcessFile(NULL, file, type, TRUSTED_PEER_TYPE, ssl, 0, NULL,
                       GET_VERIFY_SETTING_SSL(ssl));
}
#endif /* WOLFSSL_TRUST_PEER_CERT */


#if !defined(NO_WOLFSSL_CLIENT) || !defined(WOLFSSL_NO_CLIENT_AUTH)
/* Verify the certificate, WOLFSSL_SUCCESS for ok, < 0 for error */
int wolfSSL_CertManagerVerify(WOLFSSL_CERT_MANAGER* cm, const char* fname,
                             int format)
{
    int    ret = WOLFSSL_FATAL_ERROR;
#ifdef WOLFSSL_SMALL_STACK
    byte   staticBuffer[1]; /* force heap usage */
#else
    byte   staticBuffer[FILE_BUFFER_SIZE];
#endif
    byte*  myBuffer = staticBuffer;
    int    dynamic = 0;
    long   sz = 0;
    XFILE  file = XFOPEN(fname, "rb");

    WOLFSSL_ENTER("wolfSSL_CertManagerVerify");

    if (file == XBADFILE) return WOLFSSL_BAD_FILE;
    if(XFSEEK(file, 0, XSEEK_END) != 0) {
        XFCLOSE(file);
        return WOLFSSL_BAD_FILE;
    }
    sz = XFTELL(file);
    XREWIND(file);

    if (sz > MAX_WOLFSSL_FILE_SIZE || sz <= 0) {
        WOLFSSL_MSG("CertManagerVerify file size error");
        XFCLOSE(file);
        return WOLFSSL_BAD_FILE;
    }

    if (sz > (long)sizeof(staticBuffer)) {
        WOLFSSL_MSG("Getting dynamic buffer");
        myBuffer = (byte*) XMALLOC(sz, cm->heap, DYNAMIC_TYPE_FILE);
        if (myBuffer == NULL) {
            XFCLOSE(file);
            return WOLFSSL_BAD_FILE;
        }
        dynamic = 1;
    }

    if ((size_t)XFREAD(myBuffer, 1, sz, file) != (size_t)sz)
        ret = WOLFSSL_BAD_FILE;
    else
        ret = wolfSSL_CertManagerVerifyBuffer(cm, myBuffer, sz, format);

    XFCLOSE(file);
    if (dynamic)
        XFREE(myBuffer, cm->heap, DYNAMIC_TYPE_FILE);

    return ret;
}
#endif

/* like load verify locations, 1 for success, < 0 for error */
int wolfSSL_CertManagerLoadCA(WOLFSSL_CERT_MANAGER* cm, const char* file,
                             const char* path)
{
    int ret = WOLFSSL_FATAL_ERROR;
    WOLFSSL_CTX* tmp;

    WOLFSSL_ENTER("wolfSSL_CertManagerLoadCA");

    if (cm == NULL) {
        WOLFSSL_MSG("No CertManager error");
        return ret;
    }
    tmp = wolfSSL_CTX_new(cm_pick_method());

    if (tmp == NULL) {
        WOLFSSL_MSG("CTX new failed");
        return ret;
    }

    /* for tmp use */
    wolfSSL_CertManagerFree(tmp->cm);
    tmp->cm = cm;

    ret = wolfSSL_CTX_load_verify_locations(tmp, file, path);

    /* don't lose our good one */
    tmp->cm = NULL;
    wolfSSL_CTX_free(tmp);

    return ret;
}


#endif /* NO_FILESYSTEM */

#ifdef HAVE_CRL

/* check CRL if enabled, WOLFSSL_SUCCESS  */
int wolfSSL_CertManagerCheckCRL(WOLFSSL_CERT_MANAGER* cm, byte* der, int sz)
{
    int ret = 0;
#ifdef WOLFSSL_SMALL_STACK
    DecodedCert* cert = NULL;
#else
    DecodedCert  cert[1];
#endif

    WOLFSSL_ENTER("wolfSSL_CertManagerCheckCRL");

    if (cm == NULL)
        return BAD_FUNC_ARG;

    if (cm->crlEnabled == 0)
        return WOLFSSL_SUCCESS;

#ifdef WOLFSSL_SMALL_STACK
    cert = (DecodedCert*)XMALLOC(sizeof(DecodedCert), NULL, DYNAMIC_TYPE_DCERT);
    if (cert == NULL)
        return MEMORY_E;
#endif

    InitDecodedCert(cert, der, sz, NULL);

    if ((ret = ParseCertRelative(cert, CERT_TYPE, VERIFY_CRL, cm)) != 0) {
        WOLFSSL_MSG("ParseCert failed");
    }
    else if ((ret = CheckCertCRL(cm->crl, cert)) != 0) {
        WOLFSSL_MSG("CheckCertCRL failed");
    }

    FreeDecodedCert(cert);
#ifdef WOLFSSL_SMALL_STACK
    XFREE(cert, NULL, DYNAMIC_TYPE_DCERT);
#endif

    return ret == 0 ? WOLFSSL_SUCCESS : ret;
}


int wolfSSL_CertManagerSetCRL_Cb(WOLFSSL_CERT_MANAGER* cm, CbMissingCRL cb)
{
    WOLFSSL_ENTER("wolfSSL_CertManagerSetCRL_Cb");
    if (cm == NULL)
        return BAD_FUNC_ARG;

    cm->cbMissingCRL = cb;

    return WOLFSSL_SUCCESS;
}

#ifdef HAVE_CRL_IO
int wolfSSL_CertManagerSetCRL_IOCb(WOLFSSL_CERT_MANAGER* cm, CbCrlIO cb)
{
    if (cm == NULL)
        return BAD_FUNC_ARG;

    cm->crl->crlIOCb = cb;

    return WOLFSSL_SUCCESS;
}
#endif

#ifndef NO_FILESYSTEM
int wolfSSL_CertManagerLoadCRL(WOLFSSL_CERT_MANAGER* cm, const char* path,
                              int type, int monitor)
{
    WOLFSSL_ENTER("wolfSSL_CertManagerLoadCRL");
    if (cm == NULL)
        return BAD_FUNC_ARG;

    if (cm->crl == NULL) {
        if (wolfSSL_CertManagerEnableCRL(cm, 0) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("Enable CRL failed");
            return WOLFSSL_FATAL_ERROR;
        }
    }

    return LoadCRL(cm->crl, path, type, monitor);
}

int wolfSSL_CertManagerLoadCRLFile(WOLFSSL_CERT_MANAGER* cm, const char* file,
                              int type)
{
    WOLFSSL_ENTER("wolfSSL_CertManagerLoadCRLFile");
    if (cm == NULL || file == NULL)
        return BAD_FUNC_ARG;

    if (cm->crl == NULL) {
        if (wolfSSL_CertManagerEnableCRL(cm, 0) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("Enable CRL failed");
            return WOLFSSL_FATAL_ERROR;
        }
    }

    return ProcessFile(NULL, file, type, CRL_TYPE, NULL, 0, cm->crl,
            VERIFY);
}
#endif

int wolfSSL_EnableCRL(WOLFSSL* ssl, int options)
{
    WOLFSSL_ENTER("wolfSSL_EnableCRL");
    if (ssl)
        return wolfSSL_CertManagerEnableCRL(SSL_CM(ssl), options);
    else
        return BAD_FUNC_ARG;
}


int wolfSSL_DisableCRL(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_DisableCRL");
    if (ssl)
        return wolfSSL_CertManagerDisableCRL(SSL_CM(ssl));
    else
        return BAD_FUNC_ARG;
}

#ifndef NO_FILESYSTEM
int wolfSSL_LoadCRL(WOLFSSL* ssl, const char* path, int type, int monitor)
{
    WOLFSSL_ENTER("wolfSSL_LoadCRL");
    if (ssl)
        return wolfSSL_CertManagerLoadCRL(SSL_CM(ssl), path, type, monitor);
    else
        return BAD_FUNC_ARG;
}

int wolfSSL_LoadCRLFile(WOLFSSL* ssl, const char* file, int type)
{
    WOLFSSL_ENTER("wolfSSL_LoadCRL");
    if (ssl)
        return wolfSSL_CertManagerLoadCRLFile(SSL_CM(ssl), file, type);
    else
        return BAD_FUNC_ARG;
}
#endif


int wolfSSL_SetCRL_Cb(WOLFSSL* ssl, CbMissingCRL cb)
{
    WOLFSSL_ENTER("wolfSSL_SetCRL_Cb");
    if (ssl)
        return wolfSSL_CertManagerSetCRL_Cb(SSL_CM(ssl), cb);
    else
        return BAD_FUNC_ARG;
}

#ifdef HAVE_CRL_IO
int wolfSSL_SetCRL_IOCb(WOLFSSL* ssl, CbCrlIO cb)
{
    WOLFSSL_ENTER("wolfSSL_SetCRL_Cb");
    if (ssl)
        return wolfSSL_CertManagerSetCRL_IOCb(SSL_CM(ssl), cb);
    else
        return BAD_FUNC_ARG;
}
#endif

int wolfSSL_CTX_EnableCRL(WOLFSSL_CTX* ctx, int options)
{
    WOLFSSL_ENTER("wolfSSL_CTX_EnableCRL");
    if (ctx)
        return wolfSSL_CertManagerEnableCRL(ctx->cm, options);
    else
        return BAD_FUNC_ARG;
}


int wolfSSL_CTX_DisableCRL(WOLFSSL_CTX* ctx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_DisableCRL");
    if (ctx)
        return wolfSSL_CertManagerDisableCRL(ctx->cm);
    else
        return BAD_FUNC_ARG;
}


#ifndef NO_FILESYSTEM
int wolfSSL_CTX_LoadCRL(WOLFSSL_CTX* ctx, const char* path,
                        int type, int monitor)
{
    WOLFSSL_ENTER("wolfSSL_CTX_LoadCRL");
    if (ctx)
        return wolfSSL_CertManagerLoadCRL(ctx->cm, path, type, monitor);
    else
        return BAD_FUNC_ARG;
}

int wolfSSL_CTX_LoadCRLFile(WOLFSSL_CTX* ctx, const char* file,
                        int type)
{
    WOLFSSL_ENTER("wolfSSL_CTX_LoadCRL");
    if (ctx)
        return wolfSSL_CertManagerLoadCRLFile(ctx->cm, file, type);
    else
        return BAD_FUNC_ARG;
}
#endif


int wolfSSL_CTX_SetCRL_Cb(WOLFSSL_CTX* ctx, CbMissingCRL cb)
{
    WOLFSSL_ENTER("wolfSSL_CTX_SetCRL_Cb");
    if (ctx)
        return wolfSSL_CertManagerSetCRL_Cb(ctx->cm, cb);
    else
        return BAD_FUNC_ARG;
}

#ifdef HAVE_CRL_IO
int wolfSSL_CTX_SetCRL_IOCb(WOLFSSL_CTX* ctx, CbCrlIO cb)
{
    WOLFSSL_ENTER("wolfSSL_CTX_SetCRL_IOCb");
    if (ctx)
        return wolfSSL_CertManagerSetCRL_IOCb(ctx->cm, cb);
    else
        return BAD_FUNC_ARG;
}
#endif


#endif /* HAVE_CRL */


#ifndef NO_FILESYSTEM


#ifdef WOLFSSL_DER_LOAD

/* Add format parameter to allow DER load of CA files */
int wolfSSL_CTX_der_load_verify_locations(WOLFSSL_CTX* ctx, const char* file,
                                          int format)
{
    WOLFSSL_ENTER("wolfSSL_CTX_der_load_verify_locations");
    if (ctx == NULL || file == NULL)
        return WOLFSSL_FAILURE;

    if (ProcessFile(ctx, file, format, CA_TYPE, NULL, 0, NULL,
                    GET_VERIFY_SETTING_CTX(ctx)) == WOLFSSL_SUCCESS) {
        return WOLFSSL_SUCCESS;
    }

    return WOLFSSL_FAILURE;
}

#endif /* WOLFSSL_DER_LOAD */



WOLFSSL_ABI
int wolfSSL_CTX_use_certificate_file(WOLFSSL_CTX* ctx, const char* file,
                                     int format)
{
    WOLFSSL_ENTER("wolfSSL_CTX_use_certificate_file");

    if (ProcessFile(ctx, file, format, CERT_TYPE, NULL, 0, NULL,
                    GET_VERIFY_SETTING_CTX(ctx)) == WOLFSSL_SUCCESS) {
        return WOLFSSL_SUCCESS;
    }

    return WOLFSSL_FAILURE;
}


WOLFSSL_ABI
int wolfSSL_CTX_use_PrivateKey_file(WOLFSSL_CTX* ctx, const char* file,
                                    int format)
{
    WOLFSSL_ENTER("wolfSSL_CTX_use_PrivateKey_file");

    if (ProcessFile(ctx, file, format, PRIVATEKEY_TYPE, NULL, 0, NULL,
                    GET_VERIFY_SETTING_CTX(ctx)) == WOLFSSL_SUCCESS) {
        return WOLFSSL_SUCCESS;
    }

    return WOLFSSL_FAILURE;
}


#endif /* NO_FILESYSTEM */


/* Sets the max chain depth when verifying a certificate chain. Default depth
 * is set to MAX_CHAIN_DEPTH.
 *
 * ctx   WOLFSSL_CTX structure to set depth in
 * depth max depth
 */
void wolfSSL_CTX_set_verify_depth(WOLFSSL_CTX *ctx, int depth) {
    WOLFSSL_ENTER("wolfSSL_CTX_set_verify_depth");

    if (ctx == NULL || depth < 0 || depth > MAX_CHAIN_DEPTH) {
        WOLFSSL_MSG("Bad depth argument, too large or less than 0");
        return;
    }

    ctx->verifyDepth = (byte)depth;
}


/* get cert chaining depth using ssl struct */
long wolfSSL_get_verify_depth(WOLFSSL* ssl)
{
    if(ssl == NULL) {
        return BAD_FUNC_ARG;
    }
#ifndef OPENSSL_EXTRA
    return MAX_CHAIN_DEPTH;
#else
    return ssl->options.verifyDepth;
#endif
}


/* get cert chaining depth using ctx struct */
long wolfSSL_CTX_get_verify_depth(WOLFSSL_CTX* ctx)
{
    if (ctx == NULL) {
        return BAD_FUNC_ARG;
    }
#ifndef OPENSSL_EXTRA
    return MAX_CHAIN_DEPTH;
#else
    return ctx->verifyDepth;
#endif
}


#ifndef NO_FILESYSTEM


WOLFSSL_ABI
int wolfSSL_CTX_use_certificate_chain_file(WOLFSSL_CTX* ctx, const char* file)
{
    /* process up to MAX_CHAIN_DEPTH plus subject cert */
    WOLFSSL_ENTER("wolfSSL_CTX_use_certificate_chain_file");

    if (ProcessFile(ctx, file, WOLFSSL_FILETYPE_PEM, CERT_TYPE, NULL, 1, NULL,
                    GET_VERIFY_SETTING_CTX(ctx)) == WOLFSSL_SUCCESS) {
        return WOLFSSL_SUCCESS;
    }

   return WOLFSSL_FAILURE;
}


int wolfSSL_CTX_use_certificate_chain_file_format(WOLFSSL_CTX* ctx,
                                                  const char* file, int format)
{
    /* process up to MAX_CHAIN_DEPTH plus subject cert */
    WOLFSSL_ENTER("wolfSSL_CTX_use_certificate_chain_file_format");

    if (ProcessFile(ctx, file, format, CERT_TYPE, NULL, 1, NULL,
                    GET_VERIFY_SETTING_CTX(ctx)) == WOLFSSL_SUCCESS) {
        return WOLFSSL_SUCCESS;
    }

   return WOLFSSL_FAILURE;
}


#ifndef NO_DH

/* server Diffie-Hellman parameters */
static int wolfSSL_SetTmpDH_file_wrapper(WOLFSSL_CTX* ctx, WOLFSSL* ssl,
                                        const char* fname, int format)
{
#ifdef WOLFSSL_SMALL_STACK
    byte   staticBuffer[1]; /* force heap usage */
#else
    byte   staticBuffer[FILE_BUFFER_SIZE];
#endif
    byte*  myBuffer = staticBuffer;
    int    dynamic = 0;
    int    ret;
    long   sz = 0;
    XFILE  file;

    if (ctx == NULL || fname == NULL)
        return BAD_FUNC_ARG;

    file = XFOPEN(fname, "rb");
    if (file == XBADFILE) return WOLFSSL_BAD_FILE;
    if(XFSEEK(file, 0, XSEEK_END) != 0) {
        XFCLOSE(file);
        return WOLFSSL_BAD_FILE;
    }
    sz = XFTELL(file);
    XREWIND(file);

    if (sz > MAX_WOLFSSL_FILE_SIZE || sz <= 0) {
        WOLFSSL_MSG("SetTmpDH file size error");
        XFCLOSE(file);
        return WOLFSSL_BAD_FILE;
    }

    if (sz > (long)sizeof(staticBuffer)) {
        WOLFSSL_MSG("Getting dynamic buffer");
        myBuffer = (byte*) XMALLOC(sz, ctx->heap, DYNAMIC_TYPE_FILE);
        if (myBuffer == NULL) {
            XFCLOSE(file);
            return WOLFSSL_BAD_FILE;
        }
        dynamic = 1;
    }

    if ((size_t)XFREAD(myBuffer, 1, sz, file) != (size_t)sz)
        ret = WOLFSSL_BAD_FILE;
    else {
        if (ssl)
            ret = wolfSSL_SetTmpDH_buffer(ssl, myBuffer, sz, format);
        else
            ret = wolfSSL_CTX_SetTmpDH_buffer(ctx, myBuffer, sz, format);
    }

    XFCLOSE(file);
    if (dynamic)
        XFREE(myBuffer, ctx->heap, DYNAMIC_TYPE_FILE);

    return ret;
}

/* server Diffie-Hellman parameters */
int wolfSSL_SetTmpDH_file(WOLFSSL* ssl, const char* fname, int format)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    return wolfSSL_SetTmpDH_file_wrapper(ssl->ctx, ssl, fname, format);
}


/* server Diffie-Hellman parameters */
int wolfSSL_CTX_SetTmpDH_file(WOLFSSL_CTX* ctx, const char* fname, int format)
{
    return wolfSSL_SetTmpDH_file_wrapper(ctx, NULL, fname, format);
}

#endif /* NO_DH */

#endif /* NO_FILESYSTEM */

#ifndef NO_CHECK_PRIVATE_KEY
/* Check private against public in certificate for match
 *
 * Returns WOLFSSL_SUCCESS on good private key
 *         WOLFSSL_FAILURE if mismatched */
static int check_cert_key(DerBuffer* cert, DerBuffer* key, void* heap,
    int devId, int isKeyLabel, int isKeyId)
{
#ifdef WOLFSSL_SMALL_STACK
    DecodedCert* der = NULL;
#else
    DecodedCert  der[1];
#endif
    word32 size;
    byte*  buff;
    int    ret = WOLFSSL_FAILURE;

    WOLFSSL_ENTER("check_cert_key");

    if (cert == NULL || key == NULL) {
        return WOLFSSL_FAILURE;
    }

#ifdef WOLFSSL_SMALL_STACK
    der = (DecodedCert*)XMALLOC(sizeof(DecodedCert), NULL, DYNAMIC_TYPE_DCERT);
    if (der == NULL)
        return MEMORY_E;
#endif

    size = cert->length;
    buff = cert->buffer;
    InitDecodedCert(der, buff, size, heap);
    if (ParseCertRelative(der, CERT_TYPE, NO_VERIFY, NULL) != 0) {
        FreeDecodedCert(der);
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(der, NULL, DYNAMIC_TYPE_DCERT);
    #endif
        return WOLFSSL_FAILURE;
    }

    size = key->length;
    buff = key->buffer;
#ifdef WOLF_PRIVATE_KEY_ID
    if (devId != INVALID_DEVID) {
        int type = 0;
        void *pkey = NULL;

    #ifndef NO_RSA
        if (der->keyOID == RSAk) {
            type = DYNAMIC_TYPE_RSA;
        }
    #ifdef WC_RSA_PSS
        if (der->keyOID == RSAPSSk) {
            type = DYNAMIC_TYPE_RSA;
        }
    #endif
    #endif
    #ifdef HAVE_ECC
        if (der->keyOID == ECDSAk) {
            type = DYNAMIC_TYPE_ECC;
        }
    #endif

        ret = CreateDevPrivateKey(&pkey, buff, size, type,
                                  isKeyLabel, isKeyId, heap, devId);
        #ifdef WOLF_CRYPTO_CB
        if (ret == 0) {
            #ifndef NO_RSA
            if (der->keyOID == RSAk
            #ifdef WC_RSA_PSS
                || der->keyOID == RSAPSSk
            #endif
                ) {
                ret = wc_CryptoCb_RsaCheckPrivKey((RsaKey*)pkey,
                                               der->publicKey, der->pubKeySize);
            }
            #endif
            #ifdef HAVE_ECC
            if (der->keyOID == ECDSAk) {
                ret = wc_CryptoCb_EccCheckPrivKey((ecc_key*)pkey,
                                               der->publicKey, der->pubKeySize);
            }
            #endif
        }
        #else
            /* devId was set, don't check, for now */
            /* TODO: Add callback for private key check? */
        #endif
        if (pkey != NULL) {
        #ifndef NO_RSA
            if (der->keyOID == RSAk
            #ifdef WC_RSA_PSS
                || der->keyOID == RSAPSSk
            #endif
                ) {
                wc_FreeRsaKey((RsaKey*)pkey);
            }
        #endif
        #ifdef HAVE_ECC
            if (der->keyOID == ECDSAk) {
                wc_ecc_free((ecc_key*)pkey);
            }
        #endif
            XFREE(pkey, heap, type);
        }
        if (ret != CRYPTOCB_UNAVAILABLE) {
            ret = (ret == 0) ? WOLFSSL_SUCCESS: WOLFSSL_FAILURE;
        }
    }
    else {
        /* fall through if unavailable */
        ret = CRYPTOCB_UNAVAILABLE;
    }

    if (ret == CRYPTOCB_UNAVAILABLE)
#endif /* WOLF_PRIVATE_KEY_ID */
    {
        ret = wc_CheckPrivateKeyCert(buff, size, der);
        ret = (ret == 1) ? WOLFSSL_SUCCESS: WOLFSSL_FAILURE;
    }
    FreeDecodedCert(der);
#ifdef WOLFSSL_SMALL_STACK
    XFREE(der, NULL, DYNAMIC_TYPE_DCERT);
#endif

    (void)devId;
    (void)isKeyLabel;
    (void)isKeyId;

    return ret;
}

/* Check private against public in certificate for match
 *
 * ctx  WOLFSSL_CTX structure to check private key in
 *
 * Returns WOLFSSL_SUCCESS on good private key
 *         WOLFSSL_FAILURE if mismatched. */
int wolfSSL_CTX_check_private_key(const WOLFSSL_CTX* ctx)
{
    if (ctx == NULL) {
        return WOLFSSL_FAILURE;
    }
    return check_cert_key(ctx->certificate, ctx->privateKey, ctx->heap,
        ctx->privateKeyDevId, ctx->privateKeyLabel, ctx->privateKeyId);
}
#endif /* !NO_CHECK_PRIVATE_KEY */

#ifdef OPENSSL_ALL
/**
 * Return the private key of the WOLFSSL_CTX struct
 * @return WOLFSSL_EVP_PKEY* The caller doesn *NOT*` free the returned object.
 */
WOLFSSL_EVP_PKEY* wolfSSL_CTX_get0_privatekey(const WOLFSSL_CTX* ctx)
{
    const unsigned char *key;
    int type;

    WOLFSSL_ENTER("wolfSSL_CTX_get0_privatekey");

    if (ctx == NULL || ctx->privateKey == NULL ||
            ctx->privateKey->buffer == NULL) {
        WOLFSSL_MSG("Bad parameter or key not set");
        return NULL;
    }

    switch (ctx->privateKeyType) {
#ifndef NO_RSA
        case rsa_sa_algo:
            type = EVP_PKEY_RSA;
            break;
#endif
#ifdef HAVE_ECC
        case ecc_dsa_sa_algo:
            type = EVP_PKEY_EC;
            break;
#endif
        default:
            /* Other key types not supported either as ssl private keys
             * or in the EVP layer */
            WOLFSSL_MSG("Unsupported key type");
            return NULL;
    }

    key = ctx->privateKey->buffer;

    if (ctx->privateKeyPKey != NULL)
        return ctx->privateKeyPKey;
    else
        return wolfSSL_d2i_PrivateKey(type,
                (WOLFSSL_EVP_PKEY**)&ctx->privateKeyPKey, &key,
                (long)ctx->privateKey->length);
}
#endif

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)

static WOLFSSL_EVP_PKEY* d2iGenericKey(WOLFSSL_EVP_PKEY** out,
    const unsigned char** in, long inSz, int priv)
{

    WOLFSSL_EVP_PKEY* pkey = NULL;
    const unsigned char* mem;
    long memSz = inSz;

    WOLFSSL_ENTER("d2iGenericKey");

    if (in == NULL || *in == NULL || inSz < 0) {
        WOLFSSL_MSG("Bad argument");
        return NULL;
    }
    mem = *in;

    #if !defined(NO_RSA)
    {
        word32 keyIdx = 0;
        int isRsaKey;
    #ifdef WOLFSSL_SMALL_STACK
        RsaKey *rsa = (RsaKey*)XMALLOC(sizeof(RsaKey), NULL, DYNAMIC_TYPE_RSA);
        if (rsa == NULL)
            return NULL;
    #else
        RsaKey rsa[1];
    #endif
        XMEMSET(rsa, 0, sizeof(RsaKey));

        /* test if RSA key */
        if (priv)
            isRsaKey = wc_InitRsaKey(rsa, NULL) == 0 &&
                wc_RsaPrivateKeyDecode(mem, &keyIdx, rsa, (word32)memSz) == 0;
        else
            isRsaKey = wc_InitRsaKey(rsa, NULL) == 0 &&
                wc_RsaPublicKeyDecode(mem, &keyIdx, rsa, (word32)memSz) == 0;
        wc_FreeRsaKey(rsa);
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(rsa, NULL, DYNAMIC_TYPE_RSA);
    #endif

        if (isRsaKey) {
            pkey = wolfSSL_EVP_PKEY_new();
            if (pkey != NULL) {
                pkey->pkey_sz = keyIdx;
                pkey->pkey.ptr = (char*)XMALLOC(memSz, NULL,
                        priv ? DYNAMIC_TYPE_PRIVATE_KEY :
                               DYNAMIC_TYPE_PUBLIC_KEY);
                if (pkey->pkey.ptr == NULL) {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }
                XMEMCPY(pkey->pkey.ptr, mem, keyIdx);
                pkey->type = EVP_PKEY_RSA;
                if (out != NULL) {
                    *out = pkey;
                }

                pkey->ownRsa = 1;
                pkey->rsa = wolfssl_rsa_d2i(NULL, mem, inSz,
                    priv ? WOLFSSL_RSA_LOAD_PRIVATE : WOLFSSL_RSA_LOAD_PUBLIC);
                if (pkey->rsa == NULL) {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }

                return pkey;
            }
            else {
                WOLFSSL_MSG("RSA wolfSSL_EVP_PKEY_new error");
            }
        }
    }
    #endif /* NO_RSA */

    #if defined(HAVE_ECC) && defined(OPENSSL_EXTRA)
    {
        word32  keyIdx = 0;
        int     isEccKey;
    #ifdef WOLFSSL_SMALL_STACK
        ecc_key *ecc = (ecc_key*)XMALLOC(sizeof(ecc_key), NULL, DYNAMIC_TYPE_ECC);
        if (ecc == NULL)
            return NULL;
    #else
        ecc_key ecc[1];
    #endif
        XMEMSET(ecc, 0, sizeof(ecc_key));

        if (priv)
            isEccKey = wc_ecc_init(ecc) == 0 &&
                wc_EccPrivateKeyDecode(mem, &keyIdx, ecc, (word32)memSz) == 0;
        else
            isEccKey = wc_ecc_init(ecc) == 0 &&
                wc_EccPublicKeyDecode(mem, &keyIdx, ecc, (word32)memSz) == 0;
        wc_ecc_free(ecc);
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(ecc, NULL, DYNAMIC_TYPE_ECC);
    #endif

        if (isEccKey) {
            pkey = wolfSSL_EVP_PKEY_new();
            if (pkey != NULL) {
                pkey->pkey_sz = keyIdx;
                pkey->pkey.ptr = (char*)XMALLOC(keyIdx, NULL,
                        priv ? DYNAMIC_TYPE_PRIVATE_KEY :
                               DYNAMIC_TYPE_PUBLIC_KEY);
                if (pkey->pkey.ptr == NULL) {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }
                XMEMCPY(pkey->pkey.ptr, mem, keyIdx);
                pkey->type = EVP_PKEY_EC;
                if (out != NULL) {
                    *out = pkey;
                }

                pkey->ownEcc = 1;
                pkey->ecc = wolfSSL_EC_KEY_new();
                if (pkey->ecc == NULL) {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }

                if (wolfSSL_EC_KEY_LoadDer_ex(pkey->ecc,
                        (const unsigned char*)pkey->pkey.ptr,
                        pkey->pkey_sz, priv ? WOLFSSL_RSA_LOAD_PRIVATE
                                            : WOLFSSL_RSA_LOAD_PUBLIC) != 1) {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }

                return pkey;
            }
            else {
                WOLFSSL_MSG("ECC wolfSSL_EVP_PKEY_new error");
            }
        }
    }
    #endif /* HAVE_ECC && OPENSSL_EXTRA */

    #if !defined(NO_DSA)
    {
        word32 keyIdx = 0;
        int     isDsaKey;
    #ifdef WOLFSSL_SMALL_STACK
        DsaKey *dsa = (DsaKey*)XMALLOC(sizeof(DsaKey), NULL, DYNAMIC_TYPE_DSA);
        if (dsa == NULL)
            return NULL;
    #else
        DsaKey dsa[1];
    #endif
        XMEMSET(dsa, 0, sizeof(DsaKey));

        if (priv)
            isDsaKey = wc_InitDsaKey(dsa) == 0 &&
                wc_DsaPrivateKeyDecode(mem, &keyIdx, dsa, (word32)memSz) == 0;
        else
            isDsaKey = wc_InitDsaKey(dsa) == 0 &&
                wc_DsaPublicKeyDecode(mem, &keyIdx, dsa, (word32)memSz) == 0;
        wc_FreeDsaKey(dsa);
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(dsa, NULL, DYNAMIC_TYPE_DSA);
    #endif

        /* test if DSA key */
        if (isDsaKey) {
            pkey = wolfSSL_EVP_PKEY_new();

            if (pkey != NULL) {
                pkey->pkey_sz = keyIdx;
                pkey->pkey.ptr = (char*)XMALLOC(memSz, NULL,
                        priv ? DYNAMIC_TYPE_PRIVATE_KEY :
                               DYNAMIC_TYPE_PUBLIC_KEY);
                if (pkey->pkey.ptr == NULL) {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }
                XMEMCPY(pkey->pkey.ptr, mem, keyIdx);
                pkey->type = EVP_PKEY_DSA;
                if (out != NULL) {
                    *out = pkey;
                }

                pkey->ownDsa = 1;
                pkey->dsa = wolfSSL_DSA_new();
                if (pkey->dsa == NULL) {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }

                if (wolfSSL_DSA_LoadDer_ex(pkey->dsa,
                        (const unsigned char*)pkey->pkey.ptr,
                        pkey->pkey_sz, priv ? WOLFSSL_RSA_LOAD_PRIVATE
                                            : WOLFSSL_RSA_LOAD_PUBLIC) != 1) {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }

                return pkey;
            }
            else {
                WOLFSSL_MSG("DSA wolfSSL_EVP_PKEY_new error");
            }
        }
    }
    #endif /* NO_DSA */

    #if !defined(NO_DH) && (defined(WOLFSSL_QT) || defined(OPENSSL_ALL))
    #if !defined(HAVE_FIPS) || (defined(HAVE_FIPS_VERSION) && \
        (HAVE_FIPS_VERSION > 2))
    {
        int isDhKey;
        word32 keyIdx = 0;
    #ifdef WOLFSSL_SMALL_STACK
        DhKey *dh = (DhKey*)XMALLOC(sizeof(DhKey), NULL, DYNAMIC_TYPE_DH);
        if (dh == NULL)
            return NULL;
    #else
        DhKey dh[1];
    #endif
        XMEMSET(dh, 0, sizeof(DhKey));

        isDhKey = wc_InitDhKey(dh) == 0 &&
                  wc_DhKeyDecode(mem, &keyIdx, dh, (word32)memSz) == 0;
        wc_FreeDhKey(dh);
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(dh, NULL, DYNAMIC_TYPE_DH);
    #endif

        /* test if DH key */
        if (isDhKey) {
            pkey = wolfSSL_EVP_PKEY_new();

            if (pkey != NULL) {
                pkey->pkey_sz = (int)memSz;
                pkey->pkey.ptr = (char*)XMALLOC(memSz, NULL,
                        priv ? DYNAMIC_TYPE_PRIVATE_KEY :
                               DYNAMIC_TYPE_PUBLIC_KEY);
                if (pkey->pkey.ptr == NULL) {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }
                XMEMCPY(pkey->pkey.ptr, mem, memSz);
                pkey->type = EVP_PKEY_DH;
                if (out != NULL) {
                    *out = pkey;
                }

                pkey->ownDh = 1;
                pkey->dh = wolfSSL_DH_new();
                if (pkey->dh == NULL) {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }

                if (wolfSSL_DH_LoadDer(pkey->dh,
                            (const unsigned char*)pkey->pkey.ptr,
                            pkey->pkey_sz) != WOLFSSL_SUCCESS) {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }

                return pkey;
            }
            else {
                WOLFSSL_MSG("DH wolfSSL_EVP_PKEY_new error");
            }
        }
    }
    #endif /* !HAVE_FIPS || HAVE_FIPS_VERSION > 2 */
    #endif /* !NO_DH && (WOLFSSL_QT || OPENSSL_ALL) */

    #if !defined(NO_DH) && defined(OPENSSL_EXTRA) && defined(WOLFSSL_DH_EXTRA)
    #if !defined(HAVE_FIPS) || (defined(HAVE_FIPS_VERSION) && \
            (HAVE_FIPS_VERSION > 2))
    {
        word32  keyIdx = 0;
        DhKey*  key = NULL;
        int ret;
        int elements;
    #ifdef WOLFSSL_SMALL_STACK
        DhKey* dh = (DhKey*)XMALLOC(sizeof(DhKey), NULL, DYNAMIC_TYPE_DH);
        if (dh == NULL)
            return NULL;
    #else
        DhKey  dh[1];
    #endif
        XMEMSET(dh, 0, sizeof(DhKey));

        /* test if DH-public key */
        if (wc_InitDhKey(dh) != 0)
            return NULL;

        ret = wc_DhKeyDecode(mem, &keyIdx, dh, (word32)memSz);
        wc_FreeDhKey(dh);
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(dh, NULL, DYNAMIC_TYPE_DH);
    #endif

        if (ret == 0) {
            pkey = wolfSSL_EVP_PKEY_new();
            if (pkey != NULL) {
                pkey->type     = EVP_PKEY_DH;
                pkey->pkey_sz  = (int)memSz;
                pkey->pkey.ptr = (char*)XMALLOC(memSz, NULL,
                        priv ? DYNAMIC_TYPE_PRIVATE_KEY :
                               DYNAMIC_TYPE_PUBLIC_KEY);
                if (pkey->pkey.ptr == NULL) {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }
                XMEMCPY(pkey->pkey.ptr, mem, memSz);
                if (out != NULL) {
                    *out = pkey;
                }
                pkey->ownDh = 1;
                pkey->dh = wolfSSL_DH_new();
                if (pkey->dh == NULL) {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }

                key = (DhKey*)pkey->dh->internal;

                keyIdx = 0;
                if (wc_DhKeyDecode(mem, &keyIdx, key, (word32)memSz) == 0)
                {
                    elements = ELEMENT_P | ELEMENT_G | ELEMENT_Q | ELEMENT_PUB;
                    if (priv)
                        elements |= ELEMENT_PRV;
                    if(SetDhExternal_ex(pkey->dh, elements)
                            == WOLFSSL_SUCCESS ) {
                        return pkey;
                    }
                }
                else {
                    wolfSSL_EVP_PKEY_free(pkey);
                    return NULL;
                }
            }
        }
    }
    #endif /* !HAVE_FIPS || HAVE_FIPS_VERSION > 2 */
    #endif /* !NO_DH &&  OPENSSL_EXTRA && WOLFSSL_DH_EXTRA */

    #ifdef HAVE_PQC
    #ifdef HAVE_FALCON
    {
        int isFalcon = 0;
    #ifdef WOLFSSL_SMALL_STACK
        falcon_key *falcon = (falcon_key *)XMALLOC(sizeof(falcon_key), NULL,
                                                  DYNAMIC_TYPE_FALCON);
        if (falcon == NULL) {
            return NULL;
        }
    #else
        falcon_key falcon[1];
    #endif

        if (wc_falcon_init(falcon) == 0) {
            /* test if Falcon key */
            if (priv) {
                /* Try level 1 */
                isFalcon = wc_falcon_set_level(falcon, 1) == 0 &&
                           wc_falcon_import_private_only(mem, (word32)memSz,
                                                         falcon) == 0;
                if (!isFalcon) {
                    /* Try level 5 */
                    isFalcon = wc_falcon_set_level(falcon, 5) == 0 &&
                               wc_falcon_import_private_only(mem, (word32)memSz,
                                                             falcon) == 0;
                }
            } else {
                /* Try level 1 */
                isFalcon = wc_falcon_set_level(falcon, 1) == 0 &&
                           wc_falcon_import_public(mem, (word32)memSz, falcon)
                           == 0;

                if (!isFalcon) {
                    /* Try level 5 */
                    isFalcon = wc_falcon_set_level(falcon, 5) == 0 &&
                               wc_falcon_import_public(mem, (word32)memSz,
                                                       falcon) == 0;
                }
            }
            wc_falcon_free(falcon);
        }

    #ifdef WOLFSSL_SMALL_STACK
        XFREE(falcon, NULL, DYNAMIC_TYPE_FALCON);
    #endif
        if (isFalcon) {
            /* Create a fake Falcon EVP_PKEY. In the future, we might integrate
             * Falcon into the compatibility layer. */
            pkey = wolfSSL_EVP_PKEY_new();
            if (pkey == NULL) {
                WOLFSSL_MSG("Falcon wolfSSL_EVP_PKEY_new error");
                return NULL;
            }
            pkey->type = EVP_PKEY_FALCON;
            pkey->pkey.ptr = NULL;
            pkey->pkey_sz = 0;
            return pkey;
        }

    }
    #endif /* HAVE_FALCON */
    #ifdef HAVE_DILITHIUM
    {
        int isDilithium = 0;
    #ifdef WOLFSSL_SMALL_STACK
        dilithium_key *dilithium = (dilithium_key *)
            XMALLOC(sizeof(dilithium_key), NULL, DYNAMIC_TYPE_DILITHIUM);
        if (dilithium == NULL) {
            return NULL;
        }
    #else
        dilithium_key dilithium[1];
    #endif

        if (wc_dilithium_init(dilithium) == 0) {
            /* Test if Dilithium key. Try all levels. */
            if (priv) {
                isDilithium = wc_dilithium_set_level(dilithium, 2) == 0 &&
                              wc_dilithium_import_private_only(mem,
                                  (word32)memSz, dilithium) == 0;
                if (!isDilithium) {
                    isDilithium = wc_dilithium_set_level(dilithium, 3) == 0 &&
                                  wc_dilithium_import_private_only(mem,
                                      (word32)memSz, dilithium) == 0;
                }
                if (!isDilithium) {
                    isDilithium = wc_dilithium_set_level(dilithium, 5) == 0 &&
                                  wc_dilithium_import_private_only(mem,
                                      (word32)memSz, dilithium) == 0;
                }
            } else {
                isDilithium = wc_dilithium_set_level(dilithium, 2) == 0 &&
                              wc_dilithium_import_public(mem, (word32)memSz,
                                  dilithium) == 0;
                if (!isDilithium) {
                    isDilithium = wc_dilithium_set_level(dilithium, 3) == 0 &&
                                  wc_dilithium_import_public(mem, (word32)memSz,
                                      dilithium) == 0;
                }
                if (!isDilithium) {
                    isDilithium = wc_dilithium_set_level(dilithium, 5) == 0 &&
                                  wc_dilithium_import_public(mem, (word32)memSz,
                                      dilithium) == 0;
                }
            }
            wc_dilithium_free(dilithium);
        }

    #ifdef WOLFSSL_SMALL_STACK
        XFREE(dilithium, NULL, DYNAMIC_TYPE_DILITHIUM);
    #endif
        if (isDilithium) {
            /* Create a fake Dilithium EVP_PKEY. In the future, we might
             * integrate Dilithium into the compatibility layer. */
            pkey = wolfSSL_EVP_PKEY_new();
            if (pkey == NULL) {
                WOLFSSL_MSG("Dilithium wolfSSL_EVP_PKEY_new error");
                return NULL;
            }
            pkey->type = EVP_PKEY_DILITHIUM;
            pkey->pkey.ptr = NULL;
            pkey->pkey_sz = 0;
            return pkey;
        }

    }
    #endif /* HAVE_DILITHIUM */
    #endif /* HAVE_PQC */

    if (pkey == NULL) {
        WOLFSSL_MSG("wolfSSL_d2i_PUBKEY couldn't determine key type");
    }

    return pkey;

}
#endif /* OPENSSL_EXTRA || WPA_SMALL */

#ifdef OPENSSL_EXTRA

WOLFSSL_PKCS8_PRIV_KEY_INFO* wolfSSL_d2i_PKCS8_PKEY(
    WOLFSSL_PKCS8_PRIV_KEY_INFO** pkey, const unsigned char** keyBuf, long keyLen)
{
    WOLFSSL_PKCS8_PRIV_KEY_INFO* pkcs8 = NULL;
#ifdef WOLFSSL_PEM_TO_DER
    int ret;
    DerBuffer* der = NULL;

    if (keyBuf == NULL || *keyBuf == NULL || keyLen <= 0) {
        WOLFSSL_MSG("Bad key PEM/DER args");
        return NULL;
    }

    ret = PemToDer(*keyBuf, keyLen, PRIVATEKEY_TYPE, &der, NULL, NULL, NULL);
    if (ret < 0) {
        WOLFSSL_MSG("Not PEM format");
        ret = AllocDer(&der, (word32)keyLen, PRIVATEKEY_TYPE, NULL);
        if (ret == 0) {
            XMEMCPY(der->buffer, *keyBuf, keyLen);
        }
    }

    if (ret == 0) {
        /* Verify this is PKCS8 Key */
        word32 inOutIdx = 0;
        word32 algId;
        ret = ToTraditionalInline_ex(der->buffer, &inOutIdx, der->length, &algId);
        if (ret >= 0) {
            ret = 0; /* good DER */
        }
    }

    if (ret == 0) {
        pkcs8 = wolfSSL_EVP_PKEY_new();
        if (pkcs8 == NULL)
            ret = MEMORY_E;
    }
    if (ret == 0) {
        pkcs8->pkey.ptr = (char*)XMALLOC(der->length, NULL,
            DYNAMIC_TYPE_PUBLIC_KEY);
        if (pkcs8->pkey.ptr == NULL)
            ret = MEMORY_E;
    }
    if (ret == 0) {
        XMEMCPY(pkcs8->pkey.ptr, der->buffer, der->length);
        pkcs8->pkey_sz = der->length;
    }

    FreeDer(&der);
    if (ret != 0) {
        wolfSSL_EVP_PKEY_free(pkcs8);
        pkcs8 = NULL;
    }
    if (pkey != NULL) {
        *pkey = pkcs8;
    }

#else
    (void)bio;
    (void)pkey;
#endif /* WOLFSSL_PEM_TO_DER */

    return pkcs8;
}


#ifndef NO_BIO
/* put SSL type in extra for now, not very common */

/* Converts a DER format key read from "bio" to a PKCS8 structure.
 *
 * bio  input bio to read DER from
 * pkey If not NULL then this pointer will be overwritten with a new PKCS8
 *      structure.
 *
 * returns a WOLFSSL_PKCS8_PRIV_KEY_INFO pointer on success and NULL in fail
 *         case.
 */
WOLFSSL_PKCS8_PRIV_KEY_INFO* wolfSSL_d2i_PKCS8_PKEY_bio(WOLFSSL_BIO* bio,
        WOLFSSL_PKCS8_PRIV_KEY_INFO** pkey)
{
    WOLFSSL_PKCS8_PRIV_KEY_INFO* pkcs8 = NULL;
#ifdef WOLFSSL_PEM_TO_DER
    unsigned char* mem = NULL;
    int memSz;

    WOLFSSL_ENTER("wolfSSL_d2i_PKCS8_PKEY_bio");

    if (bio == NULL) {
        return NULL;
    }

    if ((memSz = wolfSSL_BIO_get_mem_data(bio, &mem)) < 0) {
        return NULL;
    }

    pkcs8 = wolfSSL_d2i_PKCS8_PKEY(pkey, (const unsigned char**)&mem, memSz);
#else
    (void)bio;
    (void)pkey;
#endif /* WOLFSSL_PEM_TO_DER */

    return pkcs8;
}


/* expecting DER format public key
 *
 * bio  input bio to read DER from
 * out  If not NULL then this pointer will be overwritten with a new
 * WOLFSSL_EVP_PKEY pointer
 *
 * returns a WOLFSSL_EVP_PKEY pointer on success and NULL in fail case.
 */
WOLFSSL_EVP_PKEY* wolfSSL_d2i_PUBKEY_bio(WOLFSSL_BIO* bio,
                                         WOLFSSL_EVP_PKEY** out)
{
    unsigned char* mem;
    long memSz;
    WOLFSSL_EVP_PKEY* pkey = NULL;

    WOLFSSL_ENTER("wolfSSL_d2i_PUBKEY_bio()");

    if (bio == NULL) {
        return NULL;
    }
    (void)out;

    memSz = wolfSSL_BIO_get_len(bio);
    if (memSz <= 0) {
        return NULL;
    }

    mem = (unsigned char*)XMALLOC(memSz, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
    if (mem == NULL) {
        return NULL;
    }

    if (wolfSSL_BIO_read(bio, mem, (int)memSz) == memSz) {
        pkey = wolfSSL_d2i_PUBKEY(NULL, (const unsigned char**)&mem, memSz);
        if (out != NULL && pkey != NULL) {
            *out = pkey;
        }
    }

    XFREE(mem, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
    return pkey;
}

#endif /* !NO_BIO */


/* Converts a DER encoded public key to a WOLFSSL_EVP_PKEY structure.
 *
 * out  pointer to new WOLFSSL_EVP_PKEY structure. Can be NULL
 * in   DER buffer to convert
 * inSz size of in buffer
 *
 * returns a pointer to a new WOLFSSL_EVP_PKEY structure on success and NULL
 *         on fail
 */
WOLFSSL_EVP_PKEY* wolfSSL_d2i_PUBKEY(WOLFSSL_EVP_PKEY** out,
                                     const unsigned char** in, long inSz)
{
    WOLFSSL_ENTER("wolfSSL_d2i_PUBKEY");
    return d2iGenericKey(out, in, inSz, 0);
}

/* helper function to get raw pointer to DER buffer from WOLFSSL_EVP_PKEY */
static int wolfSSL_EVP_PKEY_get_der(const WOLFSSL_EVP_PKEY* key, unsigned char** der)
{
    unsigned char* pt;
    int sz;
    word16 pkcs8HeaderSz;

    if (!key || !key->pkey_sz)
        return WOLFSSL_FATAL_ERROR;

    /* return the key without PKCS8 for compatibility */
    /* if pkcs8HeaderSz is invalid, use 0 and return all of pkey */
    pkcs8HeaderSz = 0;
    if (key->pkey_sz > key->pkcs8HeaderSz)
        pkcs8HeaderSz = key->pkcs8HeaderSz;
    sz = key->pkey_sz - pkcs8HeaderSz;
    if (der) {
        pt = (unsigned char*)key->pkey.ptr;
        if (*der) {
            /* since this function signature has no size value passed in it is
             * assumed that the user has allocated a large enough buffer */
            XMEMCPY(*der, pt + pkcs8HeaderSz, sz);
            *der += sz;
        }
        else {
            *der = (unsigned char*)XMALLOC(sz, NULL, DYNAMIC_TYPE_OPENSSL);
            if (*der == NULL) {
                return WOLFSSL_FATAL_ERROR;
            }
            XMEMCPY(*der, pt + pkcs8HeaderSz, sz);
        }
    }
    return sz;
}

int wolfSSL_i2d_PUBKEY(const WOLFSSL_EVP_PKEY *key, unsigned char **der)
{
    return wolfSSL_EVP_PKEY_get_der(key, der);
}

static WOLFSSL_EVP_PKEY* _d2i_PublicKey(int type, WOLFSSL_EVP_PKEY** out,
    const unsigned char **in, long inSz, int priv)
{
    int ret = 0;
    word32 idx = 0, algId;
    word16 pkcs8HeaderSz = 0;
    WOLFSSL_EVP_PKEY* local;
    int opt;

    (void)opt;

    if (in == NULL || inSz < 0) {
        WOLFSSL_MSG("Bad argument");
        return NULL;
    }

    if (priv == 1) {
        /* Check if input buffer has PKCS8 header. In the case that it does not
         * have a PKCS8 header then do not error out. */
        if ((ret = ToTraditionalInline_ex((const byte*)(*in), &idx,
                                          (word32)inSz, &algId)) > 0) {
            WOLFSSL_MSG("Found PKCS8 header");
            pkcs8HeaderSz = (word16)idx;

            if ((type == EVP_PKEY_RSA && algId != RSAk
            #ifdef WC_RSA_PSS
                 && algId != RSAPSSk
            #endif
                 ) ||
                (type == EVP_PKEY_EC && algId != ECDSAk) ||
                (type == EVP_PKEY_DSA && algId != DSAk) ||
                (type == EVP_PKEY_DH && algId != DHk)) {
                WOLFSSL_MSG("PKCS8 does not match EVP key type");
                return NULL;
            }

            (void)idx; /* not used */
        }
        else {
            if (ret != ASN_PARSE_E) {
                WOLFSSL_MSG("Unexpected error with trying to remove PKCS8 "
                    "header");
                return NULL;
            }
        }
    }

    if (out != NULL && *out != NULL) {
        wolfSSL_EVP_PKEY_free(*out);
        *out = NULL;
    }
    local = wolfSSL_EVP_PKEY_new();
    if (local == NULL) {
        return NULL;
    }

    local->type     = type;
    local->pkey_sz  = (int)inSz;
    local->pkcs8HeaderSz = pkcs8HeaderSz;
    local->pkey.ptr = (char*)XMALLOC(inSz, NULL, DYNAMIC_TYPE_PUBLIC_KEY);
    if (local->pkey.ptr == NULL) {
        wolfSSL_EVP_PKEY_free(local);
        local = NULL;
        return NULL;
    }
    else {
        XMEMCPY(local->pkey.ptr, *in, inSz);
    }

    switch (type) {
#ifndef NO_RSA
        case EVP_PKEY_RSA:
            opt = priv ? WOLFSSL_RSA_LOAD_PRIVATE : WOLFSSL_RSA_LOAD_PUBLIC;
            local->ownRsa = 1;
            local->rsa = wolfssl_rsa_d2i(NULL,
                (const unsigned char*)local->pkey.ptr, local->pkey_sz, opt);
            if (local->rsa == NULL) {
                wolfSSL_EVP_PKEY_free(local);
                return NULL;
            }
            break;
#endif /* NO_RSA */
#ifdef HAVE_ECC
        case EVP_PKEY_EC:
            local->ownEcc = 1;
            local->ecc = wolfSSL_EC_KEY_new();
            if (local->ecc == NULL) {
                wolfSSL_EVP_PKEY_free(local);
                return NULL;
            }
            opt = priv ? WOLFSSL_EC_KEY_LOAD_PRIVATE :
                         WOLFSSL_EC_KEY_LOAD_PUBLIC;
            if (wolfSSL_EC_KEY_LoadDer_ex(local->ecc,
                      (const unsigned char*)local->pkey.ptr, local->pkey_sz,
                      opt)
                      != WOLFSSL_SUCCESS) {
                wolfSSL_EVP_PKEY_free(local);
                return NULL;
            }
            break;
#endif /* HAVE_ECC */
#if defined(WOLFSSL_QT) || defined(OPENSSL_ALL) || defined(WOLFSSL_OPENSSH)
#ifndef NO_DSA
        case EVP_PKEY_DSA:
            local->ownDsa = 1;
            local->dsa = wolfSSL_DSA_new();
            if (local->dsa == NULL) {
                wolfSSL_EVP_PKEY_free(local);
                return NULL;
            }
            opt = priv ? WOLFSSL_DSA_LOAD_PRIVATE : WOLFSSL_DSA_LOAD_PUBLIC;
            if (wolfSSL_DSA_LoadDer_ex(local->dsa,
                    (const unsigned char*)local->pkey.ptr, local->pkey_sz,
                    opt)
                    != WOLFSSL_SUCCESS) {
                wolfSSL_EVP_PKEY_free(local);
                return NULL;
            }
            break;
#endif /* NO_DSA */
#ifndef NO_DH
#if !defined(HAVE_FIPS) || (defined(HAVE_FIPS_VERSION) && (HAVE_FIPS_VERSION>2))
        case EVP_PKEY_DH:
            local->ownDh = 1;
            local->dh = wolfSSL_DH_new();
            if (local->dh == NULL) {
                wolfSSL_EVP_PKEY_free(local);
                return NULL;
            }
            if (wolfSSL_DH_LoadDer(local->dh,
                      (const unsigned char*)local->pkey.ptr, local->pkey_sz)
                      != WOLFSSL_SUCCESS) {
                wolfSSL_EVP_PKEY_free(local);
                return NULL;
            }
            break;
#endif /* !HAVE_FIPS || HAVE_FIPS_VERSION > 2 */
#endif /* HAVE_DH */
#endif /* WOLFSSL_QT || OPENSSL_ALL || WOLFSSL_OPENSSH */
        default:
            WOLFSSL_MSG("Unsupported key type");
            wolfSSL_EVP_PKEY_free(local);
            return NULL;
    }

    /* advance pointer with success */
    if (local != NULL) {
        if (local->pkey_sz <= (int)inSz) {
            *in += local->pkey_sz;
        }

        if (out != NULL) {
            *out = local;
        }
    }

    return local;
}

WOLFSSL_EVP_PKEY* wolfSSL_d2i_PublicKey(int type, WOLFSSL_EVP_PKEY** out,
        const unsigned char **in, long inSz)
{
    WOLFSSL_ENTER("wolfSSL_d2i_PublicKey");

    return _d2i_PublicKey(type, out, in, inSz, 0);
}
/* Reads in a DER format key. If PKCS8 headers are found they are stripped off.
 *
 * type  type of key
 * out   newly created WOLFSSL_EVP_PKEY structure
 * in    pointer to input key DER
 * inSz  size of in buffer
 *
 * On success a non null pointer is returned and the pointer in is advanced the
 * same number of bytes read.
 */
WOLFSSL_EVP_PKEY* wolfSSL_d2i_PrivateKey(int type, WOLFSSL_EVP_PKEY** out,
        const unsigned char **in, long inSz)
{
    WOLFSSL_ENTER("wolfSSL_d2i_PrivateKey");

    return _d2i_PublicKey(type, out, in, inSz, 1);
}

#ifdef WOLF_PRIVATE_KEY_ID
/* Create an EVP structure for use with crypto callbacks */
WOLFSSL_EVP_PKEY* wolfSSL_d2i_PrivateKey_id(int type, WOLFSSL_EVP_PKEY** out,
    void* heap, int devId)
{
    WOLFSSL_EVP_PKEY* local;

    if (out != NULL && *out != NULL) {
        wolfSSL_EVP_PKEY_free(*out);
        *out = NULL;
    }

    local = wolfSSL_EVP_PKEY_new_ex(heap);
    if (local == NULL) {
        return NULL;
    }

    local->type     = type;
    local->pkey_sz  = 0;
    local->pkcs8HeaderSz = 0;

    switch (type) {
#ifndef NO_RSA
        case EVP_PKEY_RSA:
        {
            RsaKey* key;
            local->ownRsa = 1;
            local->rsa = wolfSSL_RSA_new_ex(heap, devId);
            if (local->rsa == NULL) {
                wolfSSL_EVP_PKEY_free(local);
                return NULL;
            }
            key = (RsaKey*)local->rsa->internal;
        #ifdef WOLF_CRYPTO_CB
            key->devId = devId;
        #endif
            (void)key;
            local->rsa->inSet = 1;
            break;
        }
#endif /* !NO_RSA */
#ifdef HAVE_ECC
        case EVP_PKEY_EC:
        {
            ecc_key* key;
            local->ownEcc = 1;
            local->ecc = wolfSSL_EC_KEY_new_ex(heap, devId);
            if (local->ecc == NULL) {
                wolfSSL_EVP_PKEY_free(local);
                return NULL;
            }
            key = (ecc_key*)local->ecc->internal;
        #ifdef WOLF_CRYPTO_CB
            key->devId = devId;
        #endif
            key->type = ECC_PRIVATEKEY;
            /* key is required to have a key size / curve set, although
             * actual one used is determined by devId callback function */
            wc_ecc_set_curve(key, ECDHE_SIZE, ECC_CURVE_DEF);

            local->ecc->inSet = 1;
            break;
        }
#endif /* HAVE_ECC */
        default:
            WOLFSSL_MSG("Unsupported private key id type");
            wolfSSL_EVP_PKEY_free(local);
            return NULL;
    }

    if (local != NULL && out != NULL) {
        *out = local;
    }

    return local;
}
#endif /* WOLF_PRIVATE_KEY_ID */

#ifndef NO_CERTS // NOLINT(readability-redundant-preprocessor)

#ifndef NO_CHECK_PRIVATE_KEY
/* Check private against public in certificate for match
 *
 * ssl  WOLFSSL structure to check private key in
 *
 * Returns WOLFSSL_SUCCESS on good private key
 *         WOLFSSL_FAILURE if mismatched. */
int wolfSSL_check_private_key(const WOLFSSL* ssl)
{
    if (ssl == NULL) {
        return WOLFSSL_FAILURE;
    }
    return check_cert_key(ssl->buffers.certificate, ssl->buffers.key, ssl->heap,
        ssl->buffers.keyDevId, ssl->buffers.keyLabel, ssl->buffers.keyId);
}
#endif /* !NO_CHECK_PRIVATE_KEY */

#if defined(OPENSSL_ALL)

int wolfSSL_ASN1_BIT_STRING_set_bit(WOLFSSL_ASN1_BIT_STRING* str, int pos,
    int val)
{
    int bytes_cnt, bit;
    byte* temp;

    if (!str || (val != 0 && val != 1) || pos < 0) {
        return WOLFSSL_FAILURE;
    }

    bytes_cnt = pos/8;
    bit = 1<<(7-(pos%8));

    if (bytes_cnt+1 > str->length) {
        if (!(temp = (byte*)XREALLOC(str->data, bytes_cnt+1, NULL,
                DYNAMIC_TYPE_OPENSSL))) {
            return WOLFSSL_FAILURE;
        }
        XMEMSET(temp+str->length, 0, bytes_cnt+1 - str->length);
        str->data = temp;
        str->length = bytes_cnt+1;
    }

    str->data[bytes_cnt] &= ~bit;
    str->data[bytes_cnt] |= val ? bit : 0;

    return WOLFSSL_SUCCESS;
}

#endif /* OPENSSL_ALL */

#endif /* !NO_CERTS */
#endif /* OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
WOLFSSL_ASN1_BIT_STRING* wolfSSL_ASN1_BIT_STRING_new(void)
{
    WOLFSSL_ASN1_BIT_STRING* str;

    str = (WOLFSSL_ASN1_BIT_STRING*)XMALLOC(sizeof(WOLFSSL_ASN1_BIT_STRING),
                                                  NULL, DYNAMIC_TYPE_OPENSSL);
    if (str) {
        XMEMSET(str, 0, sizeof(WOLFSSL_ASN1_BIT_STRING));
    }
    return str;
}

void wolfSSL_ASN1_BIT_STRING_free(WOLFSSL_ASN1_BIT_STRING* str)
{
    if (str) {
        if (str->data) {
            XFREE(str->data, NULL, DYNAMIC_TYPE_OPENSSL);
            str->data = NULL;
        }
        XFREE(str, NULL, DYNAMIC_TYPE_OPENSSL);
    }
}

int wolfSSL_ASN1_BIT_STRING_get_bit(const WOLFSSL_ASN1_BIT_STRING* str, int i)
{
    if (!str || !str->data || str->length <= (i/8) || i < 0) {
        return WOLFSSL_FAILURE;
    }

    return (str->data[i/8] & (1<<(7-(i%8)))) ? 1 : 0;
}
#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL */

#ifdef OPENSSL_EXTRA

int wolfSSL_use_PrivateKey(WOLFSSL* ssl, WOLFSSL_EVP_PKEY* pkey)
{
    WOLFSSL_ENTER("wolfSSL_use_PrivateKey");
    if (ssl == NULL || pkey == NULL ) {
        return WOLFSSL_FAILURE;
    }

    return wolfSSL_use_PrivateKey_buffer(ssl, (unsigned char*)pkey->pkey.ptr,
                                         pkey->pkey_sz, WOLFSSL_FILETYPE_ASN1);
}


int wolfSSL_use_PrivateKey_ASN1(int pri, WOLFSSL* ssl, const unsigned char* der,
                                long derSz)
{
    WOLFSSL_ENTER("wolfSSL_use_PrivateKey_ASN1");
    if (ssl == NULL || der == NULL ) {
        return WOLFSSL_FAILURE;
    }

    (void)pri; /* type of private key */
    return wolfSSL_use_PrivateKey_buffer(ssl, der, derSz, WOLFSSL_FILETYPE_ASN1);
}
/******************************************************************************
* wolfSSL_CTX_use_PrivateKey_ASN1 - loads a private key buffer into the SSL ctx
*
* RETURNS:
* returns WOLFSSL_SUCCESS on success, otherwise returns WOLFSSL_FAILURE
*/

int wolfSSL_CTX_use_PrivateKey_ASN1(int pri, WOLFSSL_CTX* ctx,
                                            unsigned char* der, long derSz)
{
    WOLFSSL_ENTER("wolfSSL_CTX_use_PrivateKey_ASN1");
    if (ctx == NULL || der == NULL ) {
        return WOLFSSL_FAILURE;
    }

    (void)pri; /* type of private key */
    return wolfSSL_CTX_use_PrivateKey_buffer(ctx, der, derSz, WOLFSSL_FILETYPE_ASN1);
}


#ifndef NO_RSA
int wolfSSL_use_RSAPrivateKey_ASN1(WOLFSSL* ssl, unsigned char* der, long derSz)
{
    WOLFSSL_ENTER("wolfSSL_use_RSAPrivateKey_ASN1");
    if (ssl == NULL || der == NULL ) {
        return WOLFSSL_FAILURE;
    }

    return wolfSSL_use_PrivateKey_buffer(ssl, der, derSz, WOLFSSL_FILETYPE_ASN1);
}
#endif

int wolfSSL_use_certificate(WOLFSSL* ssl, WOLFSSL_X509* x509)
{
    long idx;

    WOLFSSL_ENTER("wolfSSL_use_certificate");
    if (x509 != NULL && ssl != NULL && x509->derCert != NULL) {
        if (ProcessBuffer(NULL, x509->derCert->buffer, x509->derCert->length,
                          WOLFSSL_FILETYPE_ASN1, CERT_TYPE, ssl, &idx, 0,
                          GET_VERIFY_SETTING_SSL(ssl)) == WOLFSSL_SUCCESS) {
            return WOLFSSL_SUCCESS;
        }
    }

    (void)idx;
    return WOLFSSL_FAILURE;
}

#endif /* OPENSSL_EXTRA */

int wolfSSL_use_certificate_ASN1(WOLFSSL* ssl, const unsigned char* der,
                                 int derSz)
{
    long idx;

    WOLFSSL_ENTER("wolfSSL_use_certificate_ASN1");
    if (der != NULL && ssl != NULL) {
        if (ProcessBuffer(NULL, der, derSz, WOLFSSL_FILETYPE_ASN1, CERT_TYPE,
                ssl, &idx, 0, GET_VERIFY_SETTING_SSL(ssl)) == WOLFSSL_SUCCESS) {
            return WOLFSSL_SUCCESS;
        }
    }

    (void)idx;
    return WOLFSSL_FAILURE;
}

#ifndef NO_FILESYSTEM

WOLFSSL_ABI
int wolfSSL_use_certificate_file(WOLFSSL* ssl, const char* file, int format)
{
    WOLFSSL_ENTER("wolfSSL_use_certificate_file");

    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }

    if (ProcessFile(ssl->ctx, file, format, CERT_TYPE,
                ssl, 0, NULL, GET_VERIFY_SETTING_SSL(ssl)) == WOLFSSL_SUCCESS) {
        return WOLFSSL_SUCCESS;
    }

    return WOLFSSL_FAILURE;
}


WOLFSSL_ABI
int wolfSSL_use_PrivateKey_file(WOLFSSL* ssl, const char* file, int format)
{
    WOLFSSL_ENTER("wolfSSL_use_PrivateKey_file");

    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }

    if (ProcessFile(ssl->ctx, file, format, PRIVATEKEY_TYPE,
                ssl, 0, NULL, GET_VERIFY_SETTING_SSL(ssl)) == WOLFSSL_SUCCESS) {
        return WOLFSSL_SUCCESS;
    }

    return WOLFSSL_FAILURE;
}


WOLFSSL_ABI
int wolfSSL_use_certificate_chain_file(WOLFSSL* ssl, const char* file)
{
    /* process up to MAX_CHAIN_DEPTH plus subject cert */
    WOLFSSL_ENTER("wolfSSL_use_certificate_chain_file");

    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }

    if (ProcessFile(ssl->ctx, file, WOLFSSL_FILETYPE_PEM, CERT_TYPE,
               ssl, 1, NULL, GET_VERIFY_SETTING_SSL(ssl)) == WOLFSSL_SUCCESS) {
        return WOLFSSL_SUCCESS;
    }

   return WOLFSSL_FAILURE;
}

int wolfSSL_use_certificate_chain_file_format(WOLFSSL* ssl, const char* file,
                                              int format)
{
    /* process up to MAX_CHAIN_DEPTH plus subject cert */
    WOLFSSL_ENTER("wolfSSL_use_certificate_chain_file_format");

    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }

    if (ProcessFile(ssl->ctx, file, format, CERT_TYPE, ssl, 1,
                    NULL, GET_VERIFY_SETTING_SSL(ssl)) == WOLFSSL_SUCCESS) {
        return WOLFSSL_SUCCESS;
    }
    return WOLFSSL_FAILURE;
}

#endif /* !NO_FILESYSTEM */

#ifdef HAVE_ECC

/* Set Temp CTX EC-DHE size in octets, can be 14 - 66 (112 - 521 bit) */
int wolfSSL_CTX_SetTmpEC_DHE_Sz(WOLFSSL_CTX* ctx, word16 sz)
{
    if (ctx == NULL)
        return BAD_FUNC_ARG;

    /* if 0 then get from loaded private key */
    if (sz == 0) {
        /* applies only to ECDSA */
        if (ctx->privateKeyType != ecc_dsa_sa_algo)
            return WOLFSSL_SUCCESS;

        if (ctx->privateKeySz == 0) {
            WOLFSSL_MSG("Must set private key/cert first");
            return BAD_FUNC_ARG;
        }

        sz = (word16)ctx->privateKeySz;
    }

    /* check size */
    if (sz < ECC_MINSIZE || sz > ECC_MAXSIZE)
        return BAD_FUNC_ARG;

    ctx->eccTempKeySz = sz;

    return WOLFSSL_SUCCESS;
}


/* Set Temp SSL EC-DHE size in octets, can be 14 - 66 (112 - 521 bit) */
int wolfSSL_SetTmpEC_DHE_Sz(WOLFSSL* ssl, word16 sz)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    /* check size */
    if (sz < ECC_MINSIZE || sz > ECC_MAXSIZE)
        return BAD_FUNC_ARG;

    ssl->eccTempKeySz = sz;

    return WOLFSSL_SUCCESS;
}

#endif /* HAVE_ECC */


#ifdef OPENSSL_EXTRA

#ifndef NO_FILESYSTEM
int wolfSSL_CTX_use_RSAPrivateKey_file(WOLFSSL_CTX* ctx,const char* file,
                                   int format)
{
    WOLFSSL_ENTER("SSL_CTX_use_RSAPrivateKey_file");

    return wolfSSL_CTX_use_PrivateKey_file(ctx, file, format);
}


int wolfSSL_use_RSAPrivateKey_file(WOLFSSL* ssl, const char* file, int format)
{
    WOLFSSL_ENTER("wolfSSL_use_RSAPrivateKey_file");

    return wolfSSL_use_PrivateKey_file(ssl, file, format);
}
#endif /* NO_FILESYSTEM */


/* Copies the master secret over to out buffer. If outSz is 0 returns the size
 * of master secret.
 *
 * ses : a session from completed TLS/SSL handshake
 * out : buffer to hold copy of master secret
 * outSz : size of out buffer
 * returns : number of bytes copied into out buffer on success
 *           less then or equal to 0 is considered a failure case
 */
int wolfSSL_SESSION_get_master_key(const WOLFSSL_SESSION* ses,
        unsigned char* out, int outSz)
{
    int size;

    ses = ClientSessionToSession(ses);

    if (outSz == 0) {
        return SECRET_LEN;
    }

    if (ses == NULL || out == NULL || outSz < 0) {
        return 0;
    }

    if (outSz > SECRET_LEN) {
        size = SECRET_LEN;
    }
    else {
        size = outSz;
    }

    XMEMCPY(out, ses->masterSecret, size);
    return size;
}


int wolfSSL_SESSION_get_master_key_length(const WOLFSSL_SESSION* ses)
{
    (void)ses;
    return SECRET_LEN;
}

#ifdef WOLFSSL_EARLY_DATA
unsigned int wolfSSL_SESSION_get_max_early_data(const WOLFSSL_SESSION *session)
{
    return session->maxEarlyDataSz;
}
#endif /* WOLFSSL_EARLY_DATA */

#endif /* OPENSSL_EXTRA */

typedef struct {
    byte verifyPeer:1;
    byte verifyNone:1;
    byte failNoCert:1;
    byte failNoCertxPSK:1;
    byte verifyPostHandshake:1;
} SetVerifyOptions;

static SetVerifyOptions ModeToVerifyOptions(int mode)
{
    SetVerifyOptions opts;
    XMEMSET(&opts, 0, sizeof(SetVerifyOptions));

    if (mode != WOLFSSL_VERIFY_DEFAULT) {
        opts.verifyNone = (mode == WOLFSSL_VERIFY_NONE);
        if (!opts.verifyNone) {
            opts.verifyPeer =
                    (mode & WOLFSSL_VERIFY_PEER) != 0;
            opts.failNoCertxPSK =
                    (mode & WOLFSSL_VERIFY_FAIL_EXCEPT_PSK) != 0;
            opts.failNoCert =
                    (mode & WOLFSSL_VERIFY_FAIL_IF_NO_PEER_CERT) != 0;
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_POST_HANDSHAKE_AUTH)
            opts.verifyPostHandshake =
                    (mode & WOLFSSL_VERIFY_POST_HANDSHAKE) != 0;
#endif
        }
    }

    return opts;
}

WOLFSSL_ABI
void wolfSSL_CTX_set_verify(WOLFSSL_CTX* ctx, int mode, VerifyCallback vc)
{
    SetVerifyOptions opts;

    WOLFSSL_ENTER("wolfSSL_CTX_set_verify");
    if (ctx == NULL)
        return;

    opts = ModeToVerifyOptions(mode);

    ctx->verifyNone     = opts.verifyNone;
    ctx->verifyPeer     = opts.verifyPeer;
    ctx->failNoCert     = opts.failNoCert;
    ctx->failNoCertxPSK = opts.failNoCertxPSK;
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_POST_HANDSHAKE_AUTH)
    ctx->verifyPostHandshake = opts.verifyPostHandshake;
#endif

    ctx->verifyCallback = vc;
}

#ifdef OPENSSL_ALL
void wolfSSL_CTX_set_cert_verify_callback(WOLFSSL_CTX* ctx,
    CertVerifyCallback cb, void* arg)
{
    WOLFSSL_ENTER("SSL_CTX_set_cert_verify_callback");
    if (ctx == NULL)
        return;

    ctx->verifyCertCb = cb;
    ctx->verifyCertCbArg = arg;
}
#endif


void wolfSSL_set_verify(WOLFSSL* ssl, int mode, VerifyCallback vc)
{
    SetVerifyOptions opts;

    WOLFSSL_ENTER("wolfSSL_set_verify");
    if (ssl == NULL)
        return;

    opts = ModeToVerifyOptions(mode);

    ssl->options.verifyNone = opts.verifyNone;
    ssl->options.verifyPeer = opts.verifyPeer;
    ssl->options.failNoCert = opts.failNoCert;
    ssl->options.failNoCertxPSK = opts.failNoCertxPSK;
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_POST_HANDSHAKE_AUTH)
    ssl->options.verifyPostHandshake = opts.verifyPostHandshake;
#endif

    ssl->verifyCallback = vc;
}

void wolfSSL_set_verify_result(WOLFSSL *ssl, long v)
{
    WOLFSSL_ENTER("wolfSSL_set_verify_result");

    if (ssl == NULL)
        return;

#ifdef OPENSSL_ALL
    ssl->verifyCallbackResult = v;
#else
    (void)v;
    WOLFSSL_STUB("wolfSSL_set_verify_result");
#endif
}

#if defined(OPENSSL_EXTRA) && !defined(NO_CERTS) && \
    defined(WOLFSSL_TLS13) && defined(WOLFSSL_POST_HANDSHAKE_AUTH)
/* For TLS v1.3 send handshake messages after handshake completes. */
/* Returns 1=WOLFSSL_SUCCESS or 0=WOLFSSL_FAILURE */
int wolfSSL_verify_client_post_handshake(WOLFSSL* ssl)
{
    int ret = wolfSSL_request_certificate(ssl);
    if (ret != WOLFSSL_SUCCESS) {
        if (!IsAtLeastTLSv1_3(ssl->version)) {
            /* specific error of wrong version expected */
            WOLFSSL_ERROR(UNSUPPORTED_PROTO_VERSION);

        }
        else {
            WOLFSSL_ERROR(ret); /* log the error in the error queue */
        }
    }
    return (ret == WOLFSSL_SUCCESS) ? WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
}

int wolfSSL_CTX_set_post_handshake_auth(WOLFSSL_CTX* ctx, int val)
{
    int ret = wolfSSL_CTX_allow_post_handshake_auth(ctx);
    if (ret == 0) {
        ctx->postHandshakeAuth = (val != 0);
    }
    return (ret == 0) ? WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
}
int wolfSSL_set_post_handshake_auth(WOLFSSL* ssl, int val)
{
    int ret = wolfSSL_allow_post_handshake_auth(ssl);
    if (ret == 0) {
        ssl->options.postHandshakeAuth = (val != 0);
    }
    return (ret == 0) ? WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
}
#endif /* OPENSSL_EXTRA && !NO_CERTS && WOLFSSL_TLS13 && WOLFSSL_POST_HANDSHAKE_AUTH */

/* store user ctx for verify callback */
void wolfSSL_SetCertCbCtx(WOLFSSL* ssl, void* ctx)
{
    WOLFSSL_ENTER("wolfSSL_SetCertCbCtx");
    if (ssl)
        ssl->verifyCbCtx = ctx;
}


/* store user ctx for verify callback */
void wolfSSL_CTX_SetCertCbCtx(WOLFSSL_CTX* ctx, void* userCtx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_SetCertCbCtx");
    if (ctx)
        ctx->verifyCbCtx = userCtx;
}


/* store context CA Cache addition callback */
void wolfSSL_CTX_SetCACb(WOLFSSL_CTX* ctx, CallbackCACache cb)
{
    if (ctx && ctx->cm)
        ctx->cm->caCacheCallback = cb;
}


#if defined(PERSIST_CERT_CACHE)

#if !defined(NO_FILESYSTEM)

/* Persist cert cache to file */
int wolfSSL_CTX_save_cert_cache(WOLFSSL_CTX* ctx, const char* fname)
{
    WOLFSSL_ENTER("wolfSSL_CTX_save_cert_cache");

    if (ctx == NULL || fname == NULL)
        return BAD_FUNC_ARG;

    return CM_SaveCertCache(ctx->cm, fname);
}


/* Persist cert cache from file */
int wolfSSL_CTX_restore_cert_cache(WOLFSSL_CTX* ctx, const char* fname)
{
    WOLFSSL_ENTER("wolfSSL_CTX_restore_cert_cache");

    if (ctx == NULL || fname == NULL)
        return BAD_FUNC_ARG;

    return CM_RestoreCertCache(ctx->cm, fname);
}

#endif /* NO_FILESYSTEM */

/* Persist cert cache to memory */
int wolfSSL_CTX_memsave_cert_cache(WOLFSSL_CTX* ctx, void* mem,
                                   int sz, int* used)
{
    WOLFSSL_ENTER("wolfSSL_CTX_memsave_cert_cache");

    if (ctx == NULL || mem == NULL || used == NULL || sz <= 0)
        return BAD_FUNC_ARG;

    return CM_MemSaveCertCache(ctx->cm, mem, sz, used);
}


/* Restore cert cache from memory */
int wolfSSL_CTX_memrestore_cert_cache(WOLFSSL_CTX* ctx, const void* mem, int sz)
{
    WOLFSSL_ENTER("wolfSSL_CTX_memrestore_cert_cache");

    if (ctx == NULL || mem == NULL || sz <= 0)
        return BAD_FUNC_ARG;

    return CM_MemRestoreCertCache(ctx->cm, mem, sz);
}


/* get how big the the cert cache save buffer needs to be */
int wolfSSL_CTX_get_cert_cache_memsize(WOLFSSL_CTX* ctx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_get_cert_cache_memsize");

    if (ctx == NULL)
        return BAD_FUNC_ARG;

    return CM_GetCertCacheMemSize(ctx->cm);
}

#endif /* PERSIST_CERT_CACHE */
#endif /* !NO_CERTS */


#ifndef NO_SESSION_CACHE

WOLFSSL_ABI
WOLFSSL_SESSION* wolfSSL_get_session(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("SSL_get_session");
    if (ssl) {
#ifdef NO_SESSION_CACHE_REF
        return ssl->session;
#else
        if (ssl->options.side == WOLFSSL_CLIENT_END) {
            /* On the client side we want to return a persistant reference for
             * backwards compatibility. */
#ifndef NO_CLIENT_CACHE
            if (ssl->clientSession) {
                return (WOLFSSL_SESSION*)ssl->clientSession;
            }
            else {
                /* Try to add a ClientCache entry to associate with the current
                 * session. Ignore any session cache options. */
                int err;
                const byte* id = ssl->session->sessionID;
                byte idSz = ssl->session->sessionIDSz;
                if (ssl->session->haveAltSessionID) {
                    id = ssl->session->altSessionID;
                    idSz = ID_LEN;
                }
                err = AddSessionToCache(ssl->ctx, ssl->session, id, idSz,
                        NULL, ssl->session->side,
                #ifdef HAVE_SESSION_TICKET
                        ssl->session->ticketLen > 0,
                #else
                        0,
                #endif
                        &ssl->clientSession);
                if (err == 0) {
                    return (WOLFSSL_SESSION*)ssl->clientSession;
                }
            }
#endif
        }
        else {
            return ssl->session;
        }
#endif
    }

    return NULL;
}

/* The get1 version requires caller to call SSL_SESSION_free */
WOLFSSL_SESSION* wolfSSL_get1_session(WOLFSSL* ssl)
{
    WOLFSSL_SESSION* sess = NULL;
    WOLFSSL_ENTER("SSL_get1_session");
    if (ssl != NULL) {
        sess = ssl->session;
        if (sess != NULL) {
            /* increase reference count if allocated session */
            if (sess->type == WOLFSSL_SESSION_TYPE_HEAP) {
                if (wolfSSL_SESSION_up_ref(sess) != WOLFSSL_SUCCESS)
                    sess = NULL;
            }
        }
    }
    return sess;
}


/*
 * Sets the session object to use when establishing a TLS/SSL session using
 * the ssl object. Therefore, this function must be called before
 * wolfSSL_connect. The session object to use can be obtained in a previous
 * TLS/SSL connection using wolfSSL_get_session.
 *
 * This function rejects the session if it has been expired when this function
 * is called. Note that this expiration check is wolfSSL specific and differs
 * from OpenSSL return code behavior.
 *
 * By default, wolfSSL_set_session returns WOLFSSL_SUCCESS on successfully
 * setting the session, WOLFSSL_FAILURE on failure due to the session cache
 * being disabled, or the session has expired.
 *
 * To match OpenSSL return code behavior when session is expired, define
 * OPENSSL_EXTRA and WOLFSSL_ERROR_CODE_OPENSSL. This behavior will return
 * WOLFSSL_SUCCESS even when the session is expired and rejected.
 */
WOLFSSL_ABI
int wolfSSL_set_session(WOLFSSL* ssl, WOLFSSL_SESSION* session)
{
    WOLFSSL_ENTER("SSL_set_session");
    if (session)
        return wolfSSL_SetSession(ssl, session);

    return WOLFSSL_FAILURE;
}


#ifndef NO_CLIENT_CACHE

/* Associate client session with serverID, find existing or store for saving
   if newSession flag on, don't reuse existing session
   WOLFSSL_SUCCESS on ok */
int wolfSSL_SetServerID(WOLFSSL* ssl, const byte* id, int len, int newSession)
{
    WOLFSSL_SESSION* session = NULL;

    WOLFSSL_ENTER("wolfSSL_SetServerID");

    if (ssl == NULL || id == NULL || len <= 0)
        return BAD_FUNC_ARG;

    if (newSession == 0) {
        session = wolfSSL_GetSessionClient(ssl, id, len);
        if (session) {
            if (wolfSSL_SetSession(ssl, session) != WOLFSSL_SUCCESS) {
            #ifdef HAVE_EXT_CACHE
                wolfSSL_FreeSession(ssl->ctx, session);
            #endif
                WOLFSSL_MSG("wolfSSL_SetSession failed");
                session = NULL;
            }
        }
    }

    if (session == NULL) {
        WOLFSSL_MSG("Valid ServerID not cached already");

        ssl->session->idLen = (word16)min(SERVER_ID_LEN, (word32)len);
        XMEMCPY(ssl->session->serverID, id, ssl->session->idLen);
    }
#ifdef HAVE_EXT_CACHE
    else {
        wolfSSL_FreeSession(ssl->ctx, session);
    }
#endif

    return WOLFSSL_SUCCESS;
}

#endif /* !NO_CLIENT_CACHE */

#if defined(PERSIST_SESSION_CACHE)

/* for persistence, if changes to layout need to increment and modify
   save_session_cache() and restore_session_cache and memory versions too */
#define WOLFSSL_CACHE_VERSION 2

/* Session Cache Header information */
typedef struct {
    int version;     /* cache layout version id */
    int rows;        /* session rows */
    int columns;     /* session columns */
    int sessionSz;   /* sizeof WOLFSSL_SESSION */
} cache_header_t;

/* current persistence layout is:

   1) cache_header_t
   2) SessionCache
   3) ClientCache

   update WOLFSSL_CACHE_VERSION if change layout for the following
   PERSISTENT_SESSION_CACHE functions
*/


/* get how big the the session cache save buffer needs to be */
int wolfSSL_get_session_cache_memsize(void)
{
    int sz  = (int)(sizeof(SessionCache) + sizeof(cache_header_t));
#ifndef NO_CLIENT_CACHE
    sz += (int)(sizeof(ClientCache));
#endif
    return sz;
}


/* Persist session cache to memory */
int wolfSSL_memsave_session_cache(void* mem, int sz)
{
    int i;
    cache_header_t cache_header;
    SessionRow*    row  = (SessionRow*)((byte*)mem + sizeof(cache_header));

    WOLFSSL_ENTER("wolfSSL_memsave_session_cache");

    if (sz < wolfSSL_get_session_cache_memsize()) {
        WOLFSSL_MSG("Memory buffer too small");
        return BUFFER_E;
    }

    cache_header.version   = WOLFSSL_CACHE_VERSION;
    cache_header.rows      = SESSION_ROWS;
    cache_header.columns   = SESSIONS_PER_ROW;
    cache_header.sessionSz = (int)sizeof(WOLFSSL_SESSION);
    XMEMCPY(mem, &cache_header, sizeof(cache_header));

#ifndef ENABLE_SESSION_CACHE_ROW_LOCK
    if (wc_LockMutex(&session_mutex) != 0) {
        WOLFSSL_MSG("Session cache mutex lock failed");
        return BAD_MUTEX_E;
    }
#endif
    for (i = 0; i < cache_header.rows; ++i) {
    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
        if (SESSION_ROW_LOCK(&SessionCache[i]) != 0) {
            WOLFSSL_MSG("Session row cache mutex lock failed");
            return BAD_MUTEX_E;
        }
    #endif

        XMEMCPY(row++, &SessionCache[i], SIZEOF_SESSION_ROW);
    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
        SESSION_ROW_UNLOCK(&SessionCache[i]);
    #endif
    }
#ifndef ENABLE_SESSION_CACHE_ROW_LOCK
    wc_UnLockMutex(&session_mutex);
#endif

#ifndef NO_CLIENT_CACHE
    if (wc_LockMutex(&clisession_mutex) != 0) {
        WOLFSSL_MSG("Client cache mutex lock failed");
        return BAD_MUTEX_E;
    }
    XMEMCPY(row, ClientCache, sizeof(ClientCache));
    wc_UnLockMutex(&clisession_mutex);
#endif

    WOLFSSL_LEAVE("wolfSSL_memsave_session_cache", WOLFSSL_SUCCESS);

    return WOLFSSL_SUCCESS;
}


/* Restore the persistent session cache from memory */
int wolfSSL_memrestore_session_cache(const void* mem, int sz)
{
    int    i;
    cache_header_t cache_header;
    SessionRow*    row  = (SessionRow*)((byte*)mem + sizeof(cache_header));

    WOLFSSL_ENTER("wolfSSL_memrestore_session_cache");

    if (sz < wolfSSL_get_session_cache_memsize()) {
        WOLFSSL_MSG("Memory buffer too small");
        return BUFFER_E;
    }

    XMEMCPY(&cache_header, mem, sizeof(cache_header));
    if (cache_header.version   != WOLFSSL_CACHE_VERSION ||
        cache_header.rows      != SESSION_ROWS ||
        cache_header.columns   != SESSIONS_PER_ROW ||
        cache_header.sessionSz != (int)sizeof(WOLFSSL_SESSION)) {

        WOLFSSL_MSG("Session cache header match failed");
        return CACHE_MATCH_ERROR;
    }

#ifndef ENABLE_SESSION_CACHE_ROW_LOCK
    if (wc_LockMutex(&session_mutex) != 0) {
        WOLFSSL_MSG("Session cache mutex lock failed");
        return BAD_MUTEX_E;
    }
#endif
    for (i = 0; i < cache_header.rows; ++i) {
    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
        if (SESSION_ROW_LOCK(&SessionCache[i]) != 0) {
            WOLFSSL_MSG("Session row cache mutex lock failed");
            return BAD_MUTEX_E;
        }
    #endif

        XMEMCPY(&SessionCache[i], row++, SIZEOF_SESSION_ROW);
    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
        SESSION_ROW_UNLOCK(&SessionCache[i]);
    #endif
    }
#ifndef ENABLE_SESSION_CACHE_ROW_LOCK
    wc_UnLockMutex(&session_mutex);
#endif

#ifndef NO_CLIENT_CACHE
    if (wc_LockMutex(&clisession_mutex) != 0) {
        WOLFSSL_MSG("Client cache mutex lock failed");
        return BAD_MUTEX_E;
    }
    XMEMCPY(ClientCache, row, sizeof(ClientCache));
    wc_UnLockMutex(&clisession_mutex);
#endif

    WOLFSSL_LEAVE("wolfSSL_memrestore_session_cache", WOLFSSL_SUCCESS);

    return WOLFSSL_SUCCESS;
}

#if !defined(NO_FILESYSTEM)

/* Persist session cache to file */
/* doesn't use memsave because of additional memory use */
int wolfSSL_save_session_cache(const char *fname)
{
    XFILE  file;
    int    ret;
    int    rc = WOLFSSL_SUCCESS;
    int    i;
    cache_header_t cache_header;

    WOLFSSL_ENTER("wolfSSL_save_session_cache");

    file = XFOPEN(fname, "w+b");
    if (file == XBADFILE) {
        WOLFSSL_MSG("Couldn't open session cache save file");
        return WOLFSSL_BAD_FILE;
    }
    cache_header.version   = WOLFSSL_CACHE_VERSION;
    cache_header.rows      = SESSION_ROWS;
    cache_header.columns   = SESSIONS_PER_ROW;
    cache_header.sessionSz = (int)sizeof(WOLFSSL_SESSION);

    /* cache header */
    ret = (int)XFWRITE(&cache_header, sizeof cache_header, 1, file);
    if (ret != 1) {
        WOLFSSL_MSG("Session cache header file write failed");
        XFCLOSE(file);
        return FWRITE_ERROR;
    }

#ifndef ENABLE_SESSION_CACHE_ROW_LOCK
    if (wc_LockMutex(&session_mutex) != 0) {
        WOLFSSL_MSG("Session cache mutex lock failed");
        XFCLOSE(file);
        return BAD_MUTEX_E;
    }
#endif
    /* session cache */
    for (i = 0; i < cache_header.rows; ++i) {
    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
        if (SESSION_ROW_LOCK(&SessionCache[i]) != 0) {
            WOLFSSL_MSG("Session row cache mutex lock failed");
            XFCLOSE(file);
            return BAD_MUTEX_E;
        }
    #endif

        ret = (int)XFWRITE(&SessionCache[i], SIZEOF_SESSION_ROW, 1, file);
    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
        SESSION_ROW_UNLOCK(&SessionCache[i]);
    #endif
        if (ret != 1) {
            WOLFSSL_MSG("Session cache member file write failed");
            rc = FWRITE_ERROR;
            break;
        }
    }
#ifndef ENABLE_SESSION_CACHE_ROW_LOCK
    wc_UnLockMutex(&session_mutex);
#endif

#ifndef NO_CLIENT_CACHE
    /* client cache */
    if (wc_LockMutex(&clisession_mutex) != 0) {
        WOLFSSL_MSG("Client cache mutex lock failed");
        XFCLOSE(file);
        return BAD_MUTEX_E;
    }
    ret = (int)XFWRITE(ClientCache, sizeof(ClientCache), 1, file);
    if (ret != 1) {
        WOLFSSL_MSG("Client cache member file write failed");
        rc = FWRITE_ERROR;
    }
    wc_UnLockMutex(&clisession_mutex);
#endif /* !NO_CLIENT_CACHE */

    XFCLOSE(file);
    WOLFSSL_LEAVE("wolfSSL_save_session_cache", rc);

    return rc;
}


/* Restore the persistent session cache from file */
/* doesn't use memstore because of additional memory use */
int wolfSSL_restore_session_cache(const char *fname)
{
    XFILE  file;
    int    rc = WOLFSSL_SUCCESS;
    int    ret;
    int    i;
    cache_header_t cache_header;

    WOLFSSL_ENTER("wolfSSL_restore_session_cache");

    file = XFOPEN(fname, "rb");
    if (file == XBADFILE) {
        WOLFSSL_MSG("Couldn't open session cache save file");
        return WOLFSSL_BAD_FILE;
    }
    /* cache header */
    ret = (int)XFREAD(&cache_header, sizeof(cache_header), 1, file);
    if (ret != 1) {
        WOLFSSL_MSG("Session cache header file read failed");
        XFCLOSE(file);
        return FREAD_ERROR;
    }
    if (cache_header.version   != WOLFSSL_CACHE_VERSION ||
        cache_header.rows      != SESSION_ROWS ||
        cache_header.columns   != SESSIONS_PER_ROW ||
        cache_header.sessionSz != (int)sizeof(WOLFSSL_SESSION)) {

        WOLFSSL_MSG("Session cache header match failed");
        XFCLOSE(file);
        return CACHE_MATCH_ERROR;
    }

#ifndef ENABLE_SESSION_CACHE_ROW_LOCK
    if (wc_LockMutex(&session_mutex) != 0) {
        WOLFSSL_MSG("Session cache mutex lock failed");
        XFCLOSE(file);
        return BAD_MUTEX_E;
    }
#endif
    /* session cache */
    for (i = 0; i < cache_header.rows; ++i) {
    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
        if (SESSION_ROW_LOCK(&SessionCache[i]) != 0) {
            WOLFSSL_MSG("Session row cache mutex lock failed");
            XFCLOSE(file);
            return BAD_MUTEX_E;
        }
    #endif

        ret = (int)XFREAD(&SessionCache[i], SIZEOF_SESSION_ROW, 1, file);
    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
        SESSION_ROW_UNLOCK(&SessionCache[i]);
    #endif
        if (ret != 1) {
            WOLFSSL_MSG("Session cache member file read failed");
            XMEMSET(SessionCache, 0, sizeof SessionCache);
            rc = FREAD_ERROR;
            break;
        }
    }
#ifndef ENABLE_SESSION_CACHE_ROW_LOCK
    wc_UnLockMutex(&session_mutex);
#endif

#ifndef NO_CLIENT_CACHE
    /* client cache */
    if (wc_LockMutex(&clisession_mutex) != 0) {
        WOLFSSL_MSG("Client cache mutex lock failed");
        XFCLOSE(file);
        return BAD_MUTEX_E;
    }
    ret = (int)XFREAD(ClientCache, sizeof(ClientCache), 1, file);
    if (ret != 1) {
        WOLFSSL_MSG("Client cache member file read failed");
        XMEMSET(ClientCache, 0, sizeof ClientCache);
        rc = FREAD_ERROR;
    }
    wc_UnLockMutex(&clisession_mutex);
#endif /* !NO_CLIENT_CACHE */

    XFCLOSE(file);
    WOLFSSL_LEAVE("wolfSSL_restore_session_cache", rc);

    return rc;
}

#endif /* !NO_FILESYSTEM */
#endif /* PERSIST_SESSION_CACHE */
#endif /* NO_SESSION_CACHE */


void wolfSSL_load_error_strings(void)
{
    /* compatibility only */
}


int wolfSSL_library_init(void)
{
    WOLFSSL_ENTER("SSL_library_init");
    if (wolfSSL_Init() == WOLFSSL_SUCCESS)
        return WOLFSSL_SUCCESS;
    else
        return WOLFSSL_FATAL_ERROR;
}


#ifdef HAVE_SECRET_CALLBACK

int wolfSSL_set_session_secret_cb(WOLFSSL* ssl, SessionSecretCb cb, void* ctx)
{
    WOLFSSL_ENTER("wolfSSL_set_session_secret_cb");
    if (ssl == NULL)
        return WOLFSSL_FATAL_ERROR;

    ssl->sessionSecretCb = cb;
    ssl->sessionSecretCtx = ctx;
    if (cb != NULL) {
        /* If using a pre-set key, assume session resumption. */
        ssl->session->sessionIDSz = 0;
        ssl->options.resuming = 1;
    }

    return WOLFSSL_SUCCESS;
}

#endif


#ifndef NO_SESSION_CACHE

/* on by default if built in but allow user to turn off */
WOLFSSL_ABI
long wolfSSL_CTX_set_session_cache_mode(WOLFSSL_CTX* ctx, long mode)
{
    WOLFSSL_ENTER("SSL_CTX_set_session_cache_mode");

    if (ctx == NULL)
        return WOLFSSL_FAILURE;

    if (mode == WOLFSSL_SESS_CACHE_OFF)
        ctx->sessionCacheOff = 1;

    if ((mode & WOLFSSL_SESS_CACHE_NO_AUTO_CLEAR) != 0)
        ctx->sessionCacheFlushOff = 1;

#ifdef HAVE_EXT_CACHE
    if ((mode & WOLFSSL_SESS_CACHE_NO_INTERNAL_STORE) != 0)
        ctx->internalCacheOff = 1;
    if ((mode & WOLFSSL_SESS_CACHE_NO_INTERNAL_LOOKUP) != 0)
        ctx->internalCacheLookupOff = 1;
#endif

    return WOLFSSL_SUCCESS;
}

#ifdef OPENSSL_EXTRA
/* Get the session cache mode for CTX
 *
 * ctx  WOLFSSL_CTX struct to get cache mode from
 *
 * Returns a bit mask that has the session cache mode */
long wolfSSL_CTX_get_session_cache_mode(WOLFSSL_CTX* ctx)
{
    long m = 0;

    WOLFSSL_ENTER("SSL_CTX_set_session_cache_mode");

    if (ctx == NULL) {
        return m;
    }

    if (ctx->sessionCacheOff != 1) {
        m |= WOLFSSL_SESS_CACHE_SERVER;
    }

    if (ctx->sessionCacheFlushOff == 1) {
        m |= WOLFSSL_SESS_CACHE_NO_AUTO_CLEAR;
    }

#ifdef HAVE_EXT_CACHE
    if (ctx->internalCacheOff == 1) {
        m |= WOLFSSL_SESS_CACHE_NO_INTERNAL_STORE;
    }
    if (ctx->internalCacheLookupOff == 1) {
        m |= WOLFSSL_SESS_CACHE_NO_INTERNAL_LOOKUP;
    }
#endif

    return m;
}
#endif /* OPENSSL_EXTRA */

#endif /* NO_SESSION_CACHE */


#if !defined(NO_CERTS)
#if defined(PERSIST_CERT_CACHE)


#define WOLFSSL_CACHE_CERT_VERSION 1

typedef struct {
    int version;                 /* cache cert layout version id */
    int rows;                    /* hash table rows, CA_TABLE_SIZE */
    int columns[CA_TABLE_SIZE];  /* columns per row on list */
    int signerSz;                /* sizeof Signer object */
} CertCacheHeader;

/* current cert persistence layout is:

   1) CertCacheHeader
   2) caTable

   update WOLFSSL_CERT_CACHE_VERSION if change layout for the following
   PERSIST_CERT_CACHE functions
*/


/* Return memory needed to persist this signer, have lock */
static WC_INLINE int GetSignerMemory(Signer* signer)
{
    int sz = sizeof(signer->pubKeySize) + sizeof(signer->keyOID)
           + sizeof(signer->nameLen)    + sizeof(signer->subjectNameHash);

#if !defined(NO_SKID)
        sz += (int)sizeof(signer->subjectKeyIdHash);
#endif

    /* add dynamic bytes needed */
    sz += signer->pubKeySize;
    sz += signer->nameLen;

    return sz;
}


/* Return memory needed to persist this row, have lock */
static WC_INLINE int GetCertCacheRowMemory(Signer* row)
{
    int sz = 0;

    while (row) {
        sz += GetSignerMemory(row);
        row = row->next;
    }

    return sz;
}


/* get the size of persist cert cache, have lock */
static WC_INLINE int GetCertCacheMemSize(WOLFSSL_CERT_MANAGER* cm)
{
    int sz;
    int i;

    sz = sizeof(CertCacheHeader);

    for (i = 0; i < CA_TABLE_SIZE; i++)
        sz += GetCertCacheRowMemory(cm->caTable[i]);

    return sz;
}


/* Store cert cache header columns with number of items per list, have lock */
static WC_INLINE void SetCertHeaderColumns(WOLFSSL_CERT_MANAGER* cm, int* columns)
{
    int     i;
    Signer* row;

    for (i = 0; i < CA_TABLE_SIZE; i++) {
        int count = 0;
        row = cm->caTable[i];

        while (row) {
            ++count;
            row = row->next;
        }
        columns[i] = count;
    }
}


/* Restore whole cert row from memory, have lock, return bytes consumed,
   < 0 on error, have lock */
static WC_INLINE int RestoreCertRow(WOLFSSL_CERT_MANAGER* cm, byte* current,
                                 int row, int listSz, const byte* end)
{
    int idx = 0;

    if (listSz < 0) {
        WOLFSSL_MSG("Row header corrupted, negative value");
        return PARSE_ERROR;
    }

    while (listSz) {
        Signer* signer;
        byte*   publicKey;
        byte*   start = current + idx;  /* for end checks on this signer */
        int     minSz = sizeof(signer->pubKeySize) + sizeof(signer->keyOID) +
                      sizeof(signer->nameLen) + sizeof(signer->subjectNameHash);
        #ifndef NO_SKID
                minSz += (int)sizeof(signer->subjectKeyIdHash);
        #endif

        if (start + minSz > end) {
            WOLFSSL_MSG("Would overread restore buffer");
            return BUFFER_E;
        }
        signer = MakeSigner(cm->heap);
        if (signer == NULL)
            return MEMORY_E;

        /* pubKeySize */
        XMEMCPY(&signer->pubKeySize, current + idx, sizeof(signer->pubKeySize));
        idx += (int)sizeof(signer->pubKeySize);

        /* keyOID */
        XMEMCPY(&signer->keyOID, current + idx, sizeof(signer->keyOID));
        idx += (int)sizeof(signer->keyOID);

        /* publicKey */
        if (start + minSz + signer->pubKeySize > end) {
            WOLFSSL_MSG("Would overread restore buffer");
            FreeSigner(signer, cm->heap);
            return BUFFER_E;
        }
        publicKey = (byte*)XMALLOC(signer->pubKeySize, cm->heap,
                                   DYNAMIC_TYPE_KEY);
        if (publicKey == NULL) {
            FreeSigner(signer, cm->heap);
            return MEMORY_E;
        }

        XMEMCPY(publicKey, current + idx, signer->pubKeySize);
        signer->publicKey = publicKey;
        idx += signer->pubKeySize;

        /* nameLen */
        XMEMCPY(&signer->nameLen, current + idx, sizeof(signer->nameLen));
        idx += (int)sizeof(signer->nameLen);

        /* name */
        if (start + minSz + signer->pubKeySize + signer->nameLen > end) {
            WOLFSSL_MSG("Would overread restore buffer");
            FreeSigner(signer, cm->heap);
            return BUFFER_E;
        }
        signer->name = (char*)XMALLOC(signer->nameLen, cm->heap,
                                      DYNAMIC_TYPE_SUBJECT_CN);
        if (signer->name == NULL) {
            FreeSigner(signer, cm->heap);
            return MEMORY_E;
        }

        XMEMCPY(signer->name, current + idx, signer->nameLen);
        idx += signer->nameLen;

        /* subjectNameHash */
        XMEMCPY(signer->subjectNameHash, current + idx, SIGNER_DIGEST_SIZE);
        idx += SIGNER_DIGEST_SIZE;

        #ifndef NO_SKID
            /* subjectKeyIdHash */
            XMEMCPY(signer->subjectKeyIdHash, current + idx,SIGNER_DIGEST_SIZE);
            idx += SIGNER_DIGEST_SIZE;
        #endif

        signer->next = cm->caTable[row];
        cm->caTable[row] = signer;

        --listSz;
    }

    return idx;
}


/* Store whole cert row into memory, have lock, return bytes added */
static WC_INLINE int StoreCertRow(WOLFSSL_CERT_MANAGER* cm, byte* current, int row)
{
    int     added  = 0;
    Signer* list   = cm->caTable[row];

    while (list) {
        XMEMCPY(current + added, &list->pubKeySize, sizeof(list->pubKeySize));
        added += (int)sizeof(list->pubKeySize);

        XMEMCPY(current + added, &list->keyOID,     sizeof(list->keyOID));
        added += (int)sizeof(list->keyOID);

        XMEMCPY(current + added, list->publicKey, list->pubKeySize);
        added += list->pubKeySize;

        XMEMCPY(current + added, &list->nameLen, sizeof(list->nameLen));
        added += (int)sizeof(list->nameLen);

        XMEMCPY(current + added, list->name, list->nameLen);
        added += list->nameLen;

        XMEMCPY(current + added, list->subjectNameHash, SIGNER_DIGEST_SIZE);
        added += SIGNER_DIGEST_SIZE;

        #ifndef NO_SKID
            XMEMCPY(current + added, list->subjectKeyIdHash,SIGNER_DIGEST_SIZE);
            added += SIGNER_DIGEST_SIZE;
        #endif

        list = list->next;
    }

    return added;
}


/* Persist cert cache to memory, have lock */
static WC_INLINE int DoMemSaveCertCache(WOLFSSL_CERT_MANAGER* cm,
                                     void* mem, int sz)
{
    int realSz;
    int ret = WOLFSSL_SUCCESS;
    int i;

    WOLFSSL_ENTER("DoMemSaveCertCache");

    realSz = GetCertCacheMemSize(cm);
    if (realSz > sz) {
        WOLFSSL_MSG("Mem output buffer too small");
        ret = BUFFER_E;
    }
    else {
        byte*           current;
        CertCacheHeader hdr;

        hdr.version  = WOLFSSL_CACHE_CERT_VERSION;
        hdr.rows     = CA_TABLE_SIZE;
        SetCertHeaderColumns(cm, hdr.columns);
        hdr.signerSz = (int)sizeof(Signer);

        XMEMCPY(mem, &hdr, sizeof(CertCacheHeader));
        current = (byte*)mem + sizeof(CertCacheHeader);

        for (i = 0; i < CA_TABLE_SIZE; ++i)
            current += StoreCertRow(cm, current, i);
    }

    return ret;
}


#if !defined(NO_FILESYSTEM)

/* Persist cert cache to file */
int CM_SaveCertCache(WOLFSSL_CERT_MANAGER* cm, const char* fname)
{
    XFILE file;
    int   rc = WOLFSSL_SUCCESS;
    int   memSz;
    byte* mem;

    WOLFSSL_ENTER("CM_SaveCertCache");

    file = XFOPEN(fname, "w+b");
    if (file == XBADFILE) {
       WOLFSSL_MSG("Couldn't open cert cache save file");
       return WOLFSSL_BAD_FILE;
    }

    if (wc_LockMutex(&cm->caLock) != 0) {
        WOLFSSL_MSG("wc_LockMutex on caLock failed");
        XFCLOSE(file);
        return BAD_MUTEX_E;
    }

    memSz = GetCertCacheMemSize(cm);
    mem   = (byte*)XMALLOC(memSz, cm->heap, DYNAMIC_TYPE_TMP_BUFFER);
    if (mem == NULL) {
        WOLFSSL_MSG("Alloc for tmp buffer failed");
        rc = MEMORY_E;
    } else {
        rc = DoMemSaveCertCache(cm, mem, memSz);
        if (rc == WOLFSSL_SUCCESS) {
            int ret = (int)XFWRITE(mem, memSz, 1, file);
            if (ret != 1) {
                WOLFSSL_MSG("Cert cache file write failed");
                rc = FWRITE_ERROR;
            }
        }
        XFREE(mem, cm->heap, DYNAMIC_TYPE_TMP_BUFFER);
    }

    wc_UnLockMutex(&cm->caLock);
    XFCLOSE(file);

    return rc;
}


/* Restore cert cache from file */
int CM_RestoreCertCache(WOLFSSL_CERT_MANAGER* cm, const char* fname)
{
    XFILE file;
    int   rc = WOLFSSL_SUCCESS;
    int   ret;
    int   memSz;
    byte* mem;

    WOLFSSL_ENTER("CM_RestoreCertCache");

    file = XFOPEN(fname, "rb");
    if (file == XBADFILE) {
       WOLFSSL_MSG("Couldn't open cert cache save file");
       return WOLFSSL_BAD_FILE;
    }

    if(XFSEEK(file, 0, XSEEK_END) != 0) {
        XFCLOSE(file);
        return WOLFSSL_BAD_FILE;
    }
    memSz = (int)XFTELL(file);
    XREWIND(file);

    if (memSz > MAX_WOLFSSL_FILE_SIZE || memSz <= 0) {
        WOLFSSL_MSG("CM_RestoreCertCache file size error");
        XFCLOSE(file);
        return WOLFSSL_BAD_FILE;
    }

    mem = (byte*)XMALLOC(memSz, cm->heap, DYNAMIC_TYPE_TMP_BUFFER);
    if (mem == NULL) {
        WOLFSSL_MSG("Alloc for tmp buffer failed");
        XFCLOSE(file);
        return MEMORY_E;
    }

    ret = (int)XFREAD(mem, memSz, 1, file);
    if (ret != 1) {
        WOLFSSL_MSG("Cert file read error");
        rc = FREAD_ERROR;
    } else {
        rc = CM_MemRestoreCertCache(cm, mem, memSz);
        if (rc != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("Mem restore cert cache failed");
        }
    }

    XFREE(mem, cm->heap, DYNAMIC_TYPE_TMP_BUFFER);
    XFCLOSE(file);

    return rc;
}

#endif /* NO_FILESYSTEM */


/* Persist cert cache to memory */
int CM_MemSaveCertCache(WOLFSSL_CERT_MANAGER* cm, void* mem, int sz, int* used)
{
    int ret = WOLFSSL_SUCCESS;

    WOLFSSL_ENTER("CM_MemSaveCertCache");

    if (wc_LockMutex(&cm->caLock) != 0) {
        WOLFSSL_MSG("wc_LockMutex on caLock failed");
        return BAD_MUTEX_E;
    }

    ret = DoMemSaveCertCache(cm, mem, sz);
    if (ret == WOLFSSL_SUCCESS)
        *used  = GetCertCacheMemSize(cm);

    wc_UnLockMutex(&cm->caLock);

    return ret;
}


/* Restore cert cache from memory */
int CM_MemRestoreCertCache(WOLFSSL_CERT_MANAGER* cm, const void* mem, int sz)
{
    int ret = WOLFSSL_SUCCESS;
    int i;
    CertCacheHeader* hdr = (CertCacheHeader*)mem;
    byte*            current = (byte*)mem + sizeof(CertCacheHeader);
    byte*            end     = (byte*)mem + sz;  /* don't go over */

    WOLFSSL_ENTER("CM_MemRestoreCertCache");

    if (current > end) {
        WOLFSSL_MSG("Cert Cache Memory buffer too small");
        return BUFFER_E;
    }

    if (hdr->version  != WOLFSSL_CACHE_CERT_VERSION ||
        hdr->rows     != CA_TABLE_SIZE ||
        hdr->signerSz != (int)sizeof(Signer)) {

        WOLFSSL_MSG("Cert Cache Memory header mismatch");
        return CACHE_MATCH_ERROR;
    }

    if (wc_LockMutex(&cm->caLock) != 0) {
        WOLFSSL_MSG("wc_LockMutex on caLock failed");
        return BAD_MUTEX_E;
    }

    FreeSignerTable(cm->caTable, CA_TABLE_SIZE, cm->heap);

    for (i = 0; i < CA_TABLE_SIZE; ++i) {
        int added = RestoreCertRow(cm, current, i, hdr->columns[i], end);
        if (added < 0) {
            WOLFSSL_MSG("RestoreCertRow error");
            ret = added;
            break;
        }
        current += added;
    }

    wc_UnLockMutex(&cm->caLock);

    return ret;
}


/* get how big the the cert cache save buffer needs to be */
int CM_GetCertCacheMemSize(WOLFSSL_CERT_MANAGER* cm)
{
    int sz;

    WOLFSSL_ENTER("CM_GetCertCacheMemSize");

    if (wc_LockMutex(&cm->caLock) != 0) {
        WOLFSSL_MSG("wc_LockMutex on caLock failed");
        return BAD_MUTEX_E;
    }

    sz = GetCertCacheMemSize(cm);

    wc_UnLockMutex(&cm->caLock);

    return sz;
}

#endif /* PERSIST_CERT_CACHE */
#endif /* NO_CERTS */

#ifdef OPENSSL_EXTRA

/*
 * build enabled cipher list w/ TLS13 or w/o TLS13 suites
 * @param ctx    a pointer to WOLFSSL_CTX structure
 * @param suites currently enabled suites
 * @param onlytlsv13suites flag whether correcting w/ TLS13 suites
 *                         or w/o TLS13 suties
 * @param list   suites list that user wants to update
 * @return suites list on success, otherwise NULL
 */
static char* buildEnabledCipherList(WOLFSSL_CTX* ctx, Suites* suites,
           int tls13Only, const char* list)
{
    word32 idx = 0;
    word32 listsz = 0;
    word32 len = 0;
    word32 ianasz = 0;
    const char* enabledcs = NULL;
    char* locallist = NULL;
    char* head = NULL;
    byte cipherSuite0;
    byte cipherSuite;

    /* sanity check */
    if (ctx == NULL || suites == NULL || list == NULL)
        return NULL;

    if (!suites->setSuites)
        return NULL;

    listsz = (word32)XSTRLEN(list);

    /* calculate necessary buffer length */
    for(idx = 0; idx < suites->suiteSz; idx++) {

        cipherSuite0 = suites->suites[idx];
        cipherSuite  = suites->suites[++idx];

        if (tls13Only && cipherSuite0 == TLS13_BYTE) {
            enabledcs = GetCipherNameInternal(cipherSuite0, cipherSuite);
        }
        else if (!tls13Only && cipherSuite0 != TLS13_BYTE) {
            enabledcs = GetCipherNameInternal(cipherSuite0, cipherSuite);
        }
        else
            continue;

        if (XSTRCMP(enabledcs, "None") != 0) {
            len += (word32)XSTRLEN(enabledcs) + 2;
        }
    }

    len += listsz + 2;

    /* build string */
    if (len > (listsz + 2)) {
        locallist = (char*)XMALLOC(len, ctx->heap,
                                           DYNAMIC_TYPE_TMP_BUFFER);
        /* sanity check */
        if (!locallist)
            return NULL;

        XMEMSET(locallist, 0, len);

        head = locallist;

        if (!tls13Only)
        {
            /* always tls13 suites in the head position */
            XSTRNCPY(locallist, list, len);
            locallist += listsz;
            *locallist++ = ':';
            *locallist = 0;
            len -= listsz + 1;
        }

        for(idx = 0; idx < suites->suiteSz; idx++) {
            cipherSuite0 = suites->suites[idx];
            cipherSuite  = suites->suites[++idx];

            if (tls13Only && cipherSuite0 == TLS13_BYTE) {
                enabledcs = GetCipherNameInternal(cipherSuite0, cipherSuite);
            }
            else if (!tls13Only && cipherSuite0 != TLS13_BYTE) {
                enabledcs = GetCipherNameInternal(cipherSuite0, cipherSuite);
            }
            else
                continue;

            ianasz = (int)XSTRLEN(enabledcs);
            if (ianasz + 1 < len) {
                XSTRNCPY(locallist, enabledcs, len);
                locallist += ianasz;

                *locallist++ = ':';
                *locallist = 0;
                len -= ianasz + 1;
            }
            else{
                XFREE(locallist, ctx->heap, DYNAMIC_TYPE_TMP_BUFFER);
                return NULL;
            }
        }

        if (tls13Only) {
            XSTRNCPY(locallist, list, len);
            locallist += listsz;
            *locallist = 0;
        }

        return head;
    }
    else
        return NULL;
}

/*
 * check if the list has TLS13 and pre-TLS13 suites
 * @param list cipher suite list that user want to set
 * @return mixed: 0, only pre-TLS13: 1, only TLS13: 2
 */
static int CheckcipherList(const char* list)
{
    int ret;
    int findTLSv13Suites = 0;
    int findbeforeSuites = 0;
    byte cipherSuite0;
    byte cipherSuite1;
    int flags;
    char* next = (char*)list;

    do {
        char*  current = next;
        char   name[MAX_SUITE_NAME + 1];
        word32 length = MAX_SUITE_NAME;
        word32 current_length;

        next   = XSTRSTR(next, ":");

        current_length = (!next) ? (word32)XSTRLEN(current)
                                 : (word32)(next - current);

        if (current_length < length) {
            length = current_length;
        }
        XMEMCPY(name, current, length);
        name[length] = 0;

        ret = wolfSSL_get_cipher_suite_from_name(name, &cipherSuite0,
                                                        &cipherSuite1, &flags);
        if (ret == 0) {
            if (cipherSuite0 == TLS13_BYTE) {
                /* TLSv13 suite */
                findTLSv13Suites = 1;
                break;
            }
            else {
                findbeforeSuites = 1;
                break;
            }
        }

    #if defined(OPENSSL_EXTRA) || defined(OPENSSL_ALL)
        /* check if mixed due to names like RSA:ECDHE+AESGCM etc. */
        if (ret != 0) {
            char* subStr = name;
            char* subStrNext;

            do {
                subStrNext = XSTRSTR(subStr, "+");

                if ((XSTRCMP(subStr, "ECDHE") == 0) ||
                        (XSTRCMP(subStr, "RSA") == 0)) {
                    return 0;
                }

                if (subStrNext && (XSTRLEN(subStrNext) > 0)) {
                    subStr = subStrNext + 1; /* +1 to skip past '+' */
                }
            } while (subStrNext != NULL);
        }
    #endif

        if (findTLSv13Suites == 1 && findbeforeSuites == 1) {
            /* list has mixed suites */
            return 0;
        }
    }  while (next++); /* ++ needed to skip ':' */

    if (findTLSv13Suites == 0 && findbeforeSuites == 1) {
        return 1;/* only before TLSv13 suites */
    }
    else if (findTLSv13Suites == 1 && findbeforeSuites == 0) {
        return 2;/* only TLSv13 suties */
    }
    else {
        return 0;/* handle as mixed */
    }
}

/* parse some bulk lists like !eNULL / !aNULL
 *
 * returns WOLFSSL_SUCCESS on success and sets the cipher suite list
 */
static int wolfSSL_parse_cipher_list(WOLFSSL_CTX* ctx, Suites* suites,
        const char* list)
{
    int       ret          = 0;
    int listattribute = 0;
    char*     buildcipherList = NULL;
    int tls13Only = 0;

    if (suites == NULL || list == NULL) {
        WOLFSSL_MSG("NULL argument");
        return WOLFSSL_FAILURE;
    }

    listattribute = CheckcipherList(list);

    if (listattribute == 0) {
       /* list has mixed(pre-TLSv13 and TLSv13) suites
        * update cipher suites the same as before
        */
        return (SetCipherList(ctx, suites, list)) ? WOLFSSL_SUCCESS :
        WOLFSSL_FAILURE;
    }
    else if (listattribute == 1) {
       /* list has only pre-TLSv13 suites.
        * Only update before TLSv13 suites.
        */
        tls13Only = 1;
    }
    else if (listattribute == 2) {
       /* list has only TLSv13 suites. Only update TLv13 suites
        * simulate set_ciphersuites() compatibility layer API
        */
        tls13Only = 0;
    }

    buildcipherList = buildEnabledCipherList(ctx, ctx->suites,
                                            tls13Only, list);

    if (buildcipherList) {
        ret = SetCipherList(ctx, suites, buildcipherList);
        XFREE(buildcipherList, ctx->heap, DYNAMIC_TYPE_TMP_BUFFER);
    }
    else {
        ret = SetCipherList(ctx, suites, list);
    }

    return ret;
}

#endif


int wolfSSL_CTX_set_cipher_list(WOLFSSL_CTX* ctx, const char* list)
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_cipher_list");

    if (ctx == NULL)
        return WOLFSSL_FAILURE;

    /* alloc/init on demand only */
    if (ctx->suites == NULL) {
        ctx->suites = (Suites*)XMALLOC(sizeof(Suites), ctx->heap,
                                       DYNAMIC_TYPE_SUITES);
        if (ctx->suites == NULL) {
            WOLFSSL_MSG("Memory alloc for Suites failed");
            return WOLFSSL_FAILURE;
        }
        XMEMSET(ctx->suites, 0, sizeof(Suites));
    }

#ifdef OPENSSL_EXTRA
    return wolfSSL_parse_cipher_list(ctx, ctx->suites, list);
#else
    return (SetCipherList(ctx, ctx->suites, list)) ?
        WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
#endif
}

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_SET_CIPHER_BYTES)
int wolfSSL_CTX_set_cipher_list_bytes(WOLFSSL_CTX* ctx, const byte* list,
                                      const int listSz)
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_cipher_list_bytes");

    if (ctx == NULL)
        return WOLFSSL_FAILURE;

    /* alloc/init on demand only */
    if (ctx->suites == NULL) {
        ctx->suites = (Suites*)XMALLOC(sizeof(Suites), ctx->heap,
                                       DYNAMIC_TYPE_SUITES);
        if (ctx->suites == NULL) {
            WOLFSSL_MSG("Memory alloc for Suites failed");
            return WOLFSSL_FAILURE;
        }
        XMEMSET(ctx->suites, 0, sizeof(Suites));
    }

    return (SetCipherListFromBytes(ctx, ctx->suites, list, listSz)) ?
        WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
}
#endif /* OPENSSL_EXTRA || WOLFSSL_SET_CIPHER_BYTES */

int wolfSSL_set_cipher_list(WOLFSSL* ssl, const char* list)
{
    WOLFSSL_ENTER("wolfSSL_set_cipher_list");

    if (ssl == NULL || ssl->ctx == NULL) {
        return WOLFSSL_FAILURE;
    }

#ifdef SINGLE_THREADED
    if (ssl->ctx->suites == ssl->suites) {
        ssl->suites = (Suites*)XMALLOC(sizeof(Suites), ssl->heap,
                                       DYNAMIC_TYPE_SUITES);
        if (ssl->suites == NULL) {
            WOLFSSL_MSG("Suites Memory error");
            return MEMORY_E;
        }
        *ssl->suites = *ssl->ctx->suites;
        ssl->options.ownSuites = 1;
    }
#endif

#ifdef OPENSSL_EXTRA
    return wolfSSL_parse_cipher_list(ssl->ctx, ssl->suites, list);
#else
    return (SetCipherList(ssl->ctx, ssl->suites, list)) ?
        WOLFSSL_SUCCESS :
        WOLFSSL_FAILURE;
#endif
}

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_SET_CIPHER_BYTES)
int wolfSSL_set_cipher_list_bytes(WOLFSSL* ssl, const byte* list,
                                  const int listSz)
{
    WOLFSSL_ENTER("wolfSSL_set_cipher_list_bytes");

    if (ssl == NULL || ssl->ctx == NULL) {
        return WOLFSSL_FAILURE;
    }

#ifdef SINGLE_THREADED
    if (ssl->ctx->suites == ssl->suites) {
        ssl->suites = (Suites*)XMALLOC(sizeof(Suites), ssl->heap,
                                       DYNAMIC_TYPE_SUITES);
        if (ssl->suites == NULL) {
            WOLFSSL_MSG("Suites Memory error");
            return MEMORY_E;
        }
        *ssl->suites = *ssl->ctx->suites;
        ssl->options.ownSuites = 1;
    }
#endif

    return (SetCipherListFromBytes(ssl->ctx, ssl->suites, list, listSz))
           ? WOLFSSL_SUCCESS
           : WOLFSSL_FAILURE;
}
#endif /* OPENSSL_EXTRA || WOLFSSL_SET_CIPHER_BYTES */


#ifdef HAVE_KEYING_MATERIAL

#define TLS_PRF_LABEL_CLIENT_FINISHED     "client finished"
#define TLS_PRF_LABEL_SERVER_FINISHED     "server finished"
#define TLS_PRF_LABEL_MASTER_SECRET       "master secret"
#define TLS_PRF_LABEL_EXT_MASTER_SECRET   "extended master secret"
#define TLS_PRF_LABEL_KEY_EXPANSION       "key expansion"

static const struct ForbiddenLabels {
    const char* label;
    size_t labelLen;
} forbiddenLabels[] = {
    {TLS_PRF_LABEL_CLIENT_FINISHED, XSTR_SIZEOF(TLS_PRF_LABEL_CLIENT_FINISHED)},
    {TLS_PRF_LABEL_SERVER_FINISHED, XSTR_SIZEOF(TLS_PRF_LABEL_SERVER_FINISHED)},
    {TLS_PRF_LABEL_MASTER_SECRET, XSTR_SIZEOF(TLS_PRF_LABEL_MASTER_SECRET)},
    {TLS_PRF_LABEL_EXT_MASTER_SECRET, XSTR_SIZEOF(TLS_PRF_LABEL_EXT_MASTER_SECRET)},
    {TLS_PRF_LABEL_KEY_EXPANSION, XSTR_SIZEOF(TLS_PRF_LABEL_KEY_EXPANSION)},
    {NULL, 0},
};

/**
 * Implement RFC 5705
 * TLS 1.3 uses a different exporter definition (section 7.5 of RFC 8446)
 * @return WOLFSSL_SUCCESS on success and WOLFSSL_FAILURE on error
 */
int wolfSSL_export_keying_material(WOLFSSL *ssl,
        unsigned char *out, size_t outLen,
        const char *label, size_t labelLen,
        const unsigned char *context, size_t contextLen,
        int use_context)
{
    byte*  seed = NULL;
    word32 seedLen;
    const struct ForbiddenLabels* fl;

    WOLFSSL_ENTER("wolfSSL_export_keying_material");

    if (ssl == NULL || out == NULL || label == NULL ||
            (use_context && contextLen && context == NULL)) {
        WOLFSSL_MSG("Bad argument");
        return WOLFSSL_FAILURE;
    }

    /* clientRandom + serverRandom
     * OR
     * clientRandom + serverRandom + ctx len encoding + ctx */
    seedLen = !use_context ? (word32)SEED_LEN :
                             (word32)SEED_LEN + 2 + (word32)contextLen;

    if (ssl->options.saveArrays == 0 || ssl->arrays == NULL) {
        WOLFSSL_MSG("To export keying material wolfSSL needs to keep handshake "
                    "data. Call wolfSSL_KeepArrays before attempting to "
                    "export keyid material.");
        return WOLFSSL_FAILURE;
    }

    /* check forbidden labels */
    for (fl = &forbiddenLabels[0]; fl->label != NULL; fl++) {
        if (labelLen >= fl->labelLen &&
                XMEMCMP(label, fl->label, fl->labelLen) == 0) {
            WOLFSSL_MSG("Forbidden label");
            return WOLFSSL_FAILURE;
        }
    }

#ifdef WOLFSSL_TLS13
    if (IsAtLeastTLSv1_3(ssl->version)) {
        /* Path for TLS 1.3 */
        if (!use_context) {
            contextLen = 0;
            context = (byte*)""; /* Give valid pointer for 0 length memcpy */
        }

        if (Tls13_Exporter(ssl, out, (word32)outLen, label, labelLen,
                context, contextLen) != 0) {
            WOLFSSL_MSG("Tls13_Exporter error");
            return WOLFSSL_FAILURE;
        }
        return WOLFSSL_SUCCESS;
    }
#endif

    /* Path for <=TLS 1.2 */
    seed = (byte*)XMALLOC(seedLen, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    if (seed == NULL) {
        WOLFSSL_MSG("malloc error");
        return WOLFSSL_FAILURE;
    }

    XMEMCPY(seed,           ssl->arrays->clientRandom, RAN_LEN);
    XMEMCPY(seed + RAN_LEN, ssl->arrays->serverRandom, RAN_LEN);

    if (use_context) {
        /* Encode len in big endian */
        seed[SEED_LEN    ] = (contextLen >> 8) & 0xFF;
        seed[SEED_LEN + 1] = (contextLen) & 0xFF;
        if (contextLen) {
            /* 0 length context is allowed */
            XMEMCPY(seed + SEED_LEN + 2, context, contextLen);
        }
    }

    PRIVATE_KEY_UNLOCK();
    if (wc_PRF_TLS(out, (word32)outLen, ssl->arrays->masterSecret, SECRET_LEN,
            (byte*)label, (word32)labelLen, seed, seedLen, IsAtLeastTLSv1_2(ssl),
            ssl->specs.mac_algorithm, ssl->heap, ssl->devId) != 0) {
        WOLFSSL_MSG("wc_PRF_TLS error");
        PRIVATE_KEY_LOCK();
        XFREE(seed, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        return WOLFSSL_FAILURE;
    }
    PRIVATE_KEY_LOCK();

    XFREE(seed, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    return WOLFSSL_SUCCESS;
}
#endif /* HAVE_KEYING_MATERIAL */

int wolfSSL_dtls_get_using_nonblock(WOLFSSL* ssl)
{
    int useNb = 0;

    if (ssl == NULL)
        return WOLFSSL_FAILURE;

    WOLFSSL_ENTER("wolfSSL_dtls_get_using_nonblock");
    if (ssl->options.dtls) {
#ifdef WOLFSSL_DTLS
        useNb = ssl->options.dtlsUseNonblock;
#endif
    }
    else {
        WOLFSSL_MSG("wolfSSL_dtls_get_using_nonblock() is "
                    "DEPRECATED for non-DTLS use.");
    }
    return useNb;
}


#ifndef WOLFSSL_LEANPSK

void wolfSSL_dtls_set_using_nonblock(WOLFSSL* ssl, int nonblock)
{
    (void)nonblock;

    WOLFSSL_ENTER("wolfSSL_dtls_set_using_nonblock");

    if (ssl == NULL)
        return;

    if (ssl->options.dtls) {
#ifdef WOLFSSL_DTLS
        ssl->options.dtlsUseNonblock = (nonblock != 0);
#endif
    }
    else {
        WOLFSSL_MSG("wolfSSL_dtls_set_using_nonblock() is "
                    "DEPRECATED for non-DTLS use.");
    }
}


#ifdef WOLFSSL_DTLS

int wolfSSL_dtls_get_current_timeout(WOLFSSL* ssl)
{
    int timeout = 0;
    if (ssl)
        timeout = ssl->dtls_timeout;

    WOLFSSL_LEAVE("wolfSSL_dtls_get_current_timeout()", timeout);
    return timeout;
}

#ifdef WOLFSSL_DTLS13

/*
 * This API returns 1 when the user should set a short timeout for receiving
 * data. It is recommended that it is at most 1/4 the value returned by
 * wolfSSL_dtls_get_current_timeout().
 */
int wolfSSL_dtls13_use_quick_timeout(WOLFSSL* ssl)
{
    return ssl->dtls13FastTimeout;
}

/*
 * When this is set, a DTLS 1.3 connection will send acks immediately when a
 * disruption is detected to shortcut timeouts. This results in potentially
 * more traffic but may make the handshake quicker.
 */
void wolfSSL_dtls13_set_send_more_acks(WOLFSSL* ssl, int value)
{
    if (ssl != NULL)
        ssl->options.dtls13SendMoreAcks = !!value;
}
#endif /* WOLFSSL_DTLS13 */

int wolfSSL_DTLSv1_get_timeout(WOLFSSL* ssl, WOLFSSL_TIMEVAL* timeleft)
{
    if (ssl && timeleft) {
        XMEMSET(timeleft, 0, sizeof(WOLFSSL_TIMEVAL));
        timeleft->tv_sec = ssl->dtls_timeout;
    }
    return 0;
}

#ifndef NO_WOLFSSL_STUB
int wolfSSL_DTLSv1_handle_timeout(WOLFSSL* ssl)
{
    WOLFSSL_STUB("SSL_DTLSv1_handle_timeout");
    (void)ssl;
    return 0;
}
#endif

#ifndef NO_WOLFSSL_STUB
void wolfSSL_DTLSv1_set_initial_timeout_duration(WOLFSSL* ssl, word32 duration_ms)
{
    WOLFSSL_STUB("SSL_DTLSv1_set_initial_timeout_duration");
    (void)ssl;
    (void)duration_ms;
}
#endif

/* user may need to alter init dtls recv timeout, WOLFSSL_SUCCESS on ok */
int wolfSSL_dtls_set_timeout_init(WOLFSSL* ssl, int timeout)
{
    if (ssl == NULL || timeout < 0)
        return BAD_FUNC_ARG;

    if (timeout > ssl->dtls_timeout_max) {
        WOLFSSL_MSG("Can't set dtls timeout init greater than dtls timeout max");
        return BAD_FUNC_ARG;
    }

    ssl->dtls_timeout_init = timeout;
    ssl->dtls_timeout = timeout;

    return WOLFSSL_SUCCESS;
}


/* user may need to alter max dtls recv timeout, WOLFSSL_SUCCESS on ok */
int wolfSSL_dtls_set_timeout_max(WOLFSSL* ssl, int timeout)
{
    if (ssl == NULL || timeout < 0)
        return BAD_FUNC_ARG;

    if (timeout < ssl->dtls_timeout_init) {
        WOLFSSL_MSG("Can't set dtls timeout max less than dtls timeout init");
        return BAD_FUNC_ARG;
    }

    ssl->dtls_timeout_max = timeout;

    return WOLFSSL_SUCCESS;
}


int wolfSSL_dtls_got_timeout(WOLFSSL* ssl)
{
    int result = WOLFSSL_SUCCESS;
    WOLFSSL_ENTER("wolfSSL_dtls_got_timeout()");

    if (ssl == NULL)
        return WOLFSSL_FATAL_ERROR;

#ifdef WOLFSSL_DTLS13
    if (ssl->options.dtls && IsAtLeastTLSv1_3(ssl->version)) {
        result = Dtls13RtxTimeout(ssl);
        if (result < 0) {
            if (result == WANT_WRITE)
                ssl->dtls13SendingAckOrRtx = 1;
            ssl->error = result;
            WOLFSSL_ERROR(result);
            return WOLFSSL_FATAL_ERROR;
        }

        return WOLFSSL_SUCCESS;
    }
#endif /* WOLFSSL_DTLS13 */

    if ((IsSCR(ssl) || !ssl->options.handShakeDone)) {
        if (DtlsMsgPoolTimeout(ssl) < 0){
            ssl->error = SOCKET_ERROR_E;
            WOLFSSL_ERROR(ssl->error);
            result = WOLFSSL_FATAL_ERROR;
        }
        else if ((result = DtlsMsgPoolSend(ssl, 0)) < 0)  {
            ssl->error = result;
            WOLFSSL_ERROR(result);
            result = WOLFSSL_FATAL_ERROR;
        }
        else {
            /* Reset return value to success */
            result = WOLFSSL_SUCCESS;
        }
    }

    WOLFSSL_LEAVE("wolfSSL_dtls_got_timeout()", result);
    return result;
}


/* retransmit all the saves messages, WOLFSSL_SUCCESS on ok */
int wolfSSL_dtls_retransmit(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_dtls_retransmit()");

    if (ssl == NULL)
        return WOLFSSL_FATAL_ERROR;

    if (!ssl->options.handShakeDone) {
        int result = DtlsMsgPoolSend(ssl, 0);
        if (result < 0) {
            ssl->error = result;
            WOLFSSL_ERROR(result);
            return WOLFSSL_FATAL_ERROR;
        }
    }

    return 0;
}

#endif /* DTLS */
#endif /* LEANPSK */


#if defined(WOLFSSL_DTLS) && !defined(NO_WOLFSSL_SERVER)

/* Not an SSL function, return 0 for success, error code otherwise */
/* Prereq: ssl's RNG needs to be initialized. */
int wolfSSL_DTLS_SetCookieSecret(WOLFSSL* ssl,
                                 const byte* secret, word32 secretSz)
{
    int ret = 0;

    WOLFSSL_ENTER("wolfSSL_DTLS_SetCookieSecret");

    if (ssl == NULL) {
        WOLFSSL_MSG("need a SSL object");
        return BAD_FUNC_ARG;
    }

    if (secret != NULL && secretSz == 0) {
        WOLFSSL_MSG("can't have a new secret without a size");
        return BAD_FUNC_ARG;
    }

    /* If secretSz is 0, use the default size. */
    if (secretSz == 0)
        secretSz = COOKIE_SECRET_SZ;

    if (secretSz != ssl->buffers.dtlsCookieSecret.length) {
        byte* newSecret;

        if (ssl->buffers.dtlsCookieSecret.buffer != NULL) {
            ForceZero(ssl->buffers.dtlsCookieSecret.buffer,
                      ssl->buffers.dtlsCookieSecret.length);
            XFREE(ssl->buffers.dtlsCookieSecret.buffer,
                  ssl->heap, DYNAMIC_TYPE_COOKIE_PWD);
        }

        newSecret = (byte*)XMALLOC(secretSz, ssl->heap,DYNAMIC_TYPE_COOKIE_PWD);
        if (newSecret == NULL) {
            ssl->buffers.dtlsCookieSecret.buffer = NULL;
            ssl->buffers.dtlsCookieSecret.length = 0;
            WOLFSSL_MSG("couldn't allocate new cookie secret");
            return MEMORY_ERROR;
        }
        ssl->buffers.dtlsCookieSecret.buffer = newSecret;
        ssl->buffers.dtlsCookieSecret.length = secretSz;
    #ifdef WOLFSSL_CHECK_MEM_ZERO
        wc_MemZero_Add("wolfSSL_DTLS_SetCookieSecret secret",
            ssl->buffers.dtlsCookieSecret.buffer,
            ssl->buffers.dtlsCookieSecret.length);
    #endif
    }

    /* If the supplied secret is NULL, randomly generate a new secret. */
    if (secret == NULL) {
        ret = wc_RNG_GenerateBlock(ssl->rng,
                             ssl->buffers.dtlsCookieSecret.buffer, secretSz);
    }
    else
        XMEMCPY(ssl->buffers.dtlsCookieSecret.buffer, secret, secretSz);

    WOLFSSL_LEAVE("wolfSSL_DTLS_SetCookieSecret", 0);
    return ret;
}

#endif /* WOLFSSL_DTLS && !NO_WOLFSSL_SERVER */


/* EITHER SIDE METHODS */
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_EITHER_SIDE)
    WOLFSSL_METHOD* wolfSSLv23_method(void)
    {
        return wolfSSLv23_method_ex(NULL);
    }
    WOLFSSL_METHOD* wolfSSLv23_method_ex(void* heap)
    {
        WOLFSSL_METHOD* m = NULL;
        WOLFSSL_ENTER("SSLv23_method");
    #if !defined(NO_WOLFSSL_CLIENT)
        m = wolfSSLv23_client_method_ex(heap);
    #elif !defined(NO_WOLFSSL_SERVER)
        m = wolfSSLv23_server_method_ex(heap);
    #else
        (void)heap;
    #endif
        if (m != NULL) {
            m->side = WOLFSSL_NEITHER_END;
        }

        return m;
    }

    #ifdef WOLFSSL_ALLOW_SSLV3
    WOLFSSL_METHOD* wolfSSLv3_method(void)
    {
        return wolfSSLv3_method_ex(NULL);
    }
    WOLFSSL_METHOD* wolfSSLv3_method_ex(void* heap)
    {
        WOLFSSL_METHOD* m = NULL;
        WOLFSSL_ENTER("SSLv3_method");
    #if !defined(NO_WOLFSSL_CLIENT)
        m = wolfSSLv3_client_method_ex(heap);
    #elif !defined(NO_WOLFSSL_SERVER)
        m = wolfSSLv3_server_method_ex(heap);
    #endif
        if (m != NULL) {
            m->side = WOLFSSL_NEITHER_END;
        }

        return m;
    }
    #endif
#endif /* OPENSSL_EXTRA || WOLFSSL_EITHER_SIDE */

/* client only parts */
#ifndef NO_WOLFSSL_CLIENT

    #if defined(OPENSSL_EXTRA) && !defined(NO_OLD_TLS)
    WOLFSSL_METHOD* wolfSSLv2_client_method(void)
    {
        WOLFSSL_STUB("wolfSSLv2_client_method");
        return NULL;
    }
    #endif

    #if defined(WOLFSSL_ALLOW_SSLV3) && !defined(NO_OLD_TLS)
    WOLFSSL_METHOD* wolfSSLv3_client_method(void)
    {
        return wolfSSLv3_client_method_ex(NULL);
    }
    WOLFSSL_METHOD* wolfSSLv3_client_method_ex(void* heap)
    {
        WOLFSSL_METHOD* method =
                              (WOLFSSL_METHOD*) XMALLOC(sizeof(WOLFSSL_METHOD),
                                                     heap, DYNAMIC_TYPE_METHOD);
        (void)heap;
        WOLFSSL_ENTER("SSLv3_client_method_ex");
        if (method)
            InitSSL_Method(method, MakeSSLv3());
        return method;
    }
    #endif /* WOLFSSL_ALLOW_SSLV3 && !NO_OLD_TLS */


    WOLFSSL_METHOD* wolfSSLv23_client_method(void)
    {
        return wolfSSLv23_client_method_ex(NULL);
    }
    WOLFSSL_METHOD* wolfSSLv23_client_method_ex(void* heap)
    {
        WOLFSSL_METHOD* method =
                              (WOLFSSL_METHOD*) XMALLOC(sizeof(WOLFSSL_METHOD),
                                                     heap, DYNAMIC_TYPE_METHOD);
        (void)heap;
        WOLFSSL_ENTER("SSLv23_client_method_ex");
        if (method) {
    #if !defined(NO_SHA256) || defined(WOLFSSL_SHA384) || defined(WOLFSSL_SHA512)
        #if defined(WOLFSSL_TLS13)
            InitSSL_Method(method, MakeTLSv1_3());
        #elif !defined(WOLFSSL_NO_TLS12)
            InitSSL_Method(method, MakeTLSv1_2());
        #elif !defined(NO_OLD_TLS)
            InitSSL_Method(method, MakeTLSv1_1());
        #endif
    #else
        #ifndef NO_OLD_TLS
            InitSSL_Method(method, MakeTLSv1_1());
        #endif
    #endif
    #if !defined(NO_OLD_TLS) || defined(WOLFSSL_TLS13)
            method->downgrade = 1;
    #endif
        }
        return method;
    }

    /* please see note at top of README if you get an error from connect */
    WOLFSSL_ABI
    int wolfSSL_connect(WOLFSSL* ssl)
    {
    #if !(defined(WOLFSSL_NO_TLS12) && defined(NO_OLD_TLS) && defined(WOLFSSL_TLS13))
        int neededState;
        byte advanceState;
    #endif
        int ret = 0;

        (void)ret;

        #ifdef HAVE_ERRNO_H
            errno = 0;
        #endif

        if (ssl == NULL)
            return BAD_FUNC_ARG;

    #if defined(OPENSSL_EXTRA) || defined(WOLFSSL_EITHER_SIDE)
        if (ssl->options.side == WOLFSSL_NEITHER_END) {
            ssl->error = InitSSL_Side(ssl, WOLFSSL_CLIENT_END);
            if (ssl->error != WOLFSSL_SUCCESS) {
                WOLFSSL_ERROR(ssl->error);
                return WOLFSSL_FATAL_ERROR;
            }
            ssl->error = 0; /* expected to be zero here */
        }

    #ifdef OPENSSL_EXTRA
        if (ssl->CBIS != NULL) {
            ssl->CBIS(ssl, SSL_ST_CONNECT, WOLFSSL_SUCCESS);
            ssl->cbmode = SSL_CB_WRITE;
        }
    #endif
    #endif /* OPENSSL_EXTRA || WOLFSSL_EITHER_SIDE */

    #if defined(WOLFSSL_NO_TLS12) && defined(NO_OLD_TLS) && defined(WOLFSSL_TLS13)
        return wolfSSL_connect_TLSv13(ssl);
    #else
        #ifdef WOLFSSL_TLS13
        if (ssl->options.tls1_3)
            return wolfSSL_connect_TLSv13(ssl);
        #endif

        WOLFSSL_ENTER("SSL_connect()");

        /* make sure this wolfSSL object has arrays and rng setup. Protects
         * case where the WOLFSSL object is re-used via wolfSSL_clear() */
        if ((ret = ReinitSSL(ssl, ssl->ctx, 0)) != 0) {
            return ret;
        }

#ifdef WOLFSSL_WOLFSENTRY_HOOKS
        if ((ssl->ConnectFilter != NULL) &&
            (ssl->options.connectState == CONNECT_BEGIN)) {
            wolfSSL_netfilter_decision_t res;
            if ((ssl->ConnectFilter(ssl, ssl->ConnectFilter_arg, &res) ==
                 WOLFSSL_SUCCESS) &&
                (res == WOLFSSL_NETFILTER_REJECT)) {
                ssl->error = SOCKET_FILTERED_E;
                WOLFSSL_ERROR(ssl->error);
                return WOLFSSL_FATAL_ERROR;
            }
        }
#endif /* WOLFSSL_WOLFSENTRY_HOOKS */

        if (ssl->options.side != WOLFSSL_CLIENT_END) {
            ssl->error = SIDE_ERROR;
            WOLFSSL_ERROR(ssl->error);
            return WOLFSSL_FATAL_ERROR;
        }

        #ifdef WOLFSSL_DTLS
        if (ssl->version.major == DTLS_MAJOR) {
            ssl->options.dtls   = 1;
            ssl->options.tls    = 1;
            ssl->options.tls1_1 = 1;
        }
        #endif

        /* fragOffset is non-zero when sending fragments. On the last
         * fragment, fragOffset is zero again, and the state can be
         * advanced. */
        advanceState = ssl->fragOffset == 0 &&
            (ssl->options.connectState == CONNECT_BEGIN ||
             ssl->options.connectState == HELLO_AGAIN ||
             (ssl->options.connectState >= FIRST_REPLY_DONE &&
              ssl->options.connectState <= FIRST_REPLY_FOURTH));

#ifdef WOLFSSL_DTLS13
        if (ssl->options.dtls && IsAtLeastTLSv1_3(ssl->version))
            advanceState = advanceState && !ssl->dtls13SendingAckOrRtx;
#endif /* WOLFSSL_DTLS13 */

        if (ssl->buffers.outputBuffer.length > 0
        #ifdef WOLFSSL_ASYNC_CRYPT
            /* do not send buffered or advance state if last error was an
                async pending operation */
            && ssl->error != WC_PENDING_E
        #endif
        ) {
            ret = SendBuffered(ssl);
            if (ret == 0) {
                if (ssl->fragOffset == 0 && !ssl->options.buildingMsg) {
                    if (advanceState) {
                        ssl->options.connectState++;
                        WOLFSSL_MSG("connect state: "
                                    "Advanced from last buffered fragment send");
                    #ifdef WOLFSSL_ASYNC_IO
                        /* Cleanup async */
                        FreeAsyncCtx(ssl, 0);
                    #endif
                    }
                }
                else {
                    WOLFSSL_MSG("connect state: "
                                "Not advanced, more fragments to send");
                }
            }
            else {
                ssl->error = ret;
                WOLFSSL_ERROR(ssl->error);
                return WOLFSSL_FATAL_ERROR;
            }
#ifdef WOLFSSL_DTLS13
            if (ssl->options.dtls)
                ssl->dtls13SendingAckOrRtx = 0;
#endif /* WOLFSSL_DTLS13 */
        }

        ret = RetrySendAlert(ssl);
        if (ret != 0) {
            ssl->error = ret;
            WOLFSSL_ERROR(ssl->error);
            return WOLFSSL_FATAL_ERROR;
        }

        switch (ssl->options.connectState) {

        case CONNECT_BEGIN :
            /* always send client hello first */
            if ( (ssl->error = SendClientHello(ssl)) != 0) {
                WOLFSSL_ERROR(ssl->error);
                return WOLFSSL_FATAL_ERROR;
            }
            ssl->options.connectState = CLIENT_HELLO_SENT;
            WOLFSSL_MSG("connect state: CLIENT_HELLO_SENT");
            FALL_THROUGH;

        case CLIENT_HELLO_SENT :
            neededState = ssl->options.resuming ? SERVER_FINISHED_COMPLETE :
                                          SERVER_HELLODONE_COMPLETE;
            #ifdef WOLFSSL_DTLS
                /* In DTLS, when resuming, we can go straight to FINISHED,
                 * or do a cookie exchange and then skip to FINISHED, assume
                 * we need the cookie exchange first. */
                if (IsDtlsNotSctpMode(ssl))
                    neededState = SERVER_HELLOVERIFYREQUEST_COMPLETE;
            #endif
            /* get response */
            while (ssl->options.serverState < neededState) {
                #ifdef WOLFSSL_TLS13
                    if (ssl->options.tls1_3)
                        return wolfSSL_connect_TLSv13(ssl);
                #endif
                if ( (ssl->error = ProcessReply(ssl)) < 0) {
                    WOLFSSL_ERROR(ssl->error);
                    return WOLFSSL_FATAL_ERROR;
                }
                /* if resumption failed, reset needed state */
                else if (neededState == SERVER_FINISHED_COMPLETE)
                    if (!ssl->options.resuming) {
                    #ifdef WOLFSSL_DTLS
                        if (IsDtlsNotSctpMode(ssl))
                            neededState = SERVER_HELLOVERIFYREQUEST_COMPLETE;
                        else
                    #endif
                            neededState = SERVER_HELLODONE_COMPLETE;
                    }
#ifdef WOLFSSL_DTLS13

                if (ssl->options.dtls && IsAtLeastTLSv1_3(ssl->version)
                    && ssl->dtls13Rtx.sendAcks == 1) {
                    ssl->dtls13Rtx.sendAcks = 0;
                    /* we aren't negotiated the version yet, so we aren't sure
                     * the other end can speak v1.3. On the other side we have
                     * received a unified records, assuming that the
                     * ServerHello got lost, we will send an empty ACK. In case
                     * the server is a DTLS with version less than 1.3, it
                     * should just ignore the message */
                    if ((ssl->error = SendDtls13Ack(ssl)) < 0) {
                        if (ssl->error == WANT_WRITE)
                            ssl->dtls13SendingAckOrRtx = 1;
                        WOLFSSL_ERROR(ssl->error);
                        return WOLFSSL_FATAL_ERROR;
                    }
                }


#endif /* WOLFSSL_DTLS13 */
            }

            ssl->options.connectState = HELLO_AGAIN;
            WOLFSSL_MSG("connect state: HELLO_AGAIN");
            FALL_THROUGH;

        case HELLO_AGAIN :

        #ifdef WOLFSSL_TLS13
            if (ssl->options.tls1_3)
                return wolfSSL_connect_TLSv13(ssl);
        #endif

            #ifdef WOLFSSL_DTLS
            if (ssl->options.serverState ==
                    SERVER_HELLOVERIFYREQUEST_COMPLETE) {
                if (IsDtlsNotSctpMode(ssl)) {
                    /* re-init hashes, exclude first hello and verify request */
                    if ((ssl->error = InitHandshakeHashes(ssl)) != 0) {
                        WOLFSSL_ERROR(ssl->error);
                        return WOLFSSL_FATAL_ERROR;
                    }
                    if ( (ssl->error = SendClientHello(ssl)) != 0) {
                        WOLFSSL_ERROR(ssl->error);
                        return WOLFSSL_FATAL_ERROR;
                    }
                }
            }
            #endif

            ssl->options.connectState = HELLO_AGAIN_REPLY;
            WOLFSSL_MSG("connect state: HELLO_AGAIN_REPLY");
            FALL_THROUGH;

        case HELLO_AGAIN_REPLY :
            #ifdef WOLFSSL_DTLS
                if (IsDtlsNotSctpMode(ssl)) {
                    neededState = ssl->options.resuming ?
                           SERVER_FINISHED_COMPLETE : SERVER_HELLODONE_COMPLETE;

                    /* get response */
                    while (ssl->options.serverState < neededState) {
                        if ( (ssl->error = ProcessReply(ssl)) < 0) {
                            WOLFSSL_ERROR(ssl->error);
                            return WOLFSSL_FATAL_ERROR;
                        }
                        /* if resumption failed, reset needed state */
                        if (neededState == SERVER_FINISHED_COMPLETE) {
                            if (!ssl->options.resuming)
                                neededState = SERVER_HELLODONE_COMPLETE;
                        }
                    }
                }
            #endif

            ssl->options.connectState = FIRST_REPLY_DONE;
            WOLFSSL_MSG("connect state: FIRST_REPLY_DONE");
            FALL_THROUGH;

        case FIRST_REPLY_DONE :
            if (ssl->options.certOnly)
                return WOLFSSL_SUCCESS;
            #if !defined(NO_CERTS) && !defined(WOLFSSL_NO_CLIENT_AUTH)
                #ifdef WOLFSSL_TLS13
                    if (ssl->options.tls1_3)
                        return wolfSSL_connect_TLSv13(ssl);
                #endif
                if (ssl->options.sendVerify) {
                    if ( (ssl->error = SendCertificate(ssl)) != 0) {
                    #ifdef WOLFSSL_CHECK_ALERT_ON_ERR
                        ProcessReplyEx(ssl, 1); /* See if an alert was sent. */
                    #endif
                        WOLFSSL_ERROR(ssl->error);
                        return WOLFSSL_FATAL_ERROR;
                    }
                    WOLFSSL_MSG("sent: certificate");
                }

            #endif
            ssl->options.connectState = FIRST_REPLY_FIRST;
            WOLFSSL_MSG("connect state: FIRST_REPLY_FIRST");
            FALL_THROUGH;

        case FIRST_REPLY_FIRST :
        #ifdef WOLFSSL_TLS13
            if (ssl->options.tls1_3)
                return wolfSSL_connect_TLSv13(ssl);
        #endif
            if (!ssl->options.resuming) {
                if ( (ssl->error = SendClientKeyExchange(ssl)) != 0) {
                #ifdef WOLFSSL_CHECK_ALERT_ON_ERR
                    ProcessReplyEx(ssl, 1); /* See if an alert was sent. */
                #endif
                    WOLFSSL_ERROR(ssl->error);
                    return WOLFSSL_FATAL_ERROR;
                }
                WOLFSSL_MSG("sent: client key exchange");
            }

            ssl->options.connectState = FIRST_REPLY_SECOND;
            WOLFSSL_MSG("connect state: FIRST_REPLY_SECOND");
            FALL_THROUGH;

    #if !defined(WOLFSSL_NO_TLS12) || !defined(NO_OLD_TLS)
        case FIRST_REPLY_SECOND :
            /* CLIENT: Fail-safe for Server Authentication. */
            if (!ssl->options.peerAuthGood) {
                WOLFSSL_MSG("Server authentication did not happen");
                ssl->error = NO_PEER_VERIFY;
                return WOLFSSL_FATAL_ERROR;
            }

            #if !defined(NO_CERTS) && !defined(WOLFSSL_NO_CLIENT_AUTH)
                if (ssl->options.sendVerify) {
                    if ( (ssl->error = SendCertificateVerify(ssl)) != 0) {
                    #ifdef WOLFSSL_CHECK_ALERT_ON_ERR
                        ProcessReplyEx(ssl, 1); /* See if an alert was sent. */
                    #endif
                        WOLFSSL_ERROR(ssl->error);
                        return WOLFSSL_FATAL_ERROR;
                    }
                    WOLFSSL_MSG("sent: certificate verify");
                }
            #endif /* !NO_CERTS && !WOLFSSL_NO_CLIENT_AUTH */
            ssl->options.connectState = FIRST_REPLY_THIRD;
            WOLFSSL_MSG("connect state: FIRST_REPLY_THIRD");
            FALL_THROUGH;

        case FIRST_REPLY_THIRD :
            if ( (ssl->error = SendChangeCipher(ssl)) != 0) {
            #ifdef WOLFSSL_CHECK_ALERT_ON_ERR
                ProcessReplyEx(ssl, 1); /* See if an alert was sent. */
            #endif
                WOLFSSL_ERROR(ssl->error);
                return WOLFSSL_FATAL_ERROR;
            }
            WOLFSSL_MSG("sent: change cipher spec");
            ssl->options.connectState = FIRST_REPLY_FOURTH;
            WOLFSSL_MSG("connect state: FIRST_REPLY_FOURTH");
            FALL_THROUGH;

        case FIRST_REPLY_FOURTH :
            if ( (ssl->error = SendFinished(ssl)) != 0) {
            #ifdef WOLFSSL_CHECK_ALERT_ON_ERR
                ProcessReplyEx(ssl, 1); /* See if an alert was sent. */
            #endif
                WOLFSSL_ERROR(ssl->error);
                return WOLFSSL_FATAL_ERROR;
            }
            WOLFSSL_MSG("sent: finished");
            ssl->options.connectState = FINISHED_DONE;
            WOLFSSL_MSG("connect state: FINISHED_DONE");
            FALL_THROUGH;

#ifdef WOLFSSL_DTLS13
        case WAIT_FINISHED_ACK:
            ssl->options.connectState = FINISHED_DONE;
            FALL_THROUGH;
#endif /* WOLFSSL_DTLS13 */

        case FINISHED_DONE :
            /* get response */
            while (ssl->options.serverState < SERVER_FINISHED_COMPLETE)
                if ( (ssl->error = ProcessReply(ssl)) < 0) {
                    WOLFSSL_ERROR(ssl->error);
                    return WOLFSSL_FATAL_ERROR;
                }

            ssl->options.connectState = SECOND_REPLY_DONE;
            WOLFSSL_MSG("connect state: SECOND_REPLY_DONE");
            FALL_THROUGH;

        case SECOND_REPLY_DONE:
        #ifndef NO_HANDSHAKE_DONE_CB
            if (ssl->hsDoneCb) {
                int cbret = ssl->hsDoneCb(ssl, ssl->hsDoneCtx);
                if (cbret < 0) {
                    ssl->error = cbret;
                    WOLFSSL_MSG("HandShake Done Cb don't continue error");
                    return WOLFSSL_FATAL_ERROR;
                }
            }
        #endif /* NO_HANDSHAKE_DONE_CB */

            if (!ssl->options.dtls) {
                if (!ssl->options.keepResources) {
                    FreeHandshakeResources(ssl);
                }
            }
        #ifdef WOLFSSL_DTLS
            else {
                ssl->options.dtlsHsRetain = 1;
            }
        #endif /* WOLFSSL_DTLS */

        #if defined(WOLFSSL_ASYNC_CRYPT) && defined(HAVE_SECURE_RENEGOTIATION)
            /* This may be necessary in async so that we don't try to
             * renegotiate again */
            if (ssl->secure_renegotiation && ssl->secure_renegotiation->startScr) {
                ssl->secure_renegotiation->startScr = 0;
            }
        #endif /* WOLFSSL_ASYNC_CRYPT && HAVE_SECURE_RENEGOTIATION */
        #if defined(WOLFSSL_ASYNC_IO) && !defined(WOLFSSL_ASYNC_CRYPT)
            /* Free the remaining async context if not using it for crypto */
            FreeAsyncCtx(ssl, 1);
        #endif

            ssl->error = 0; /* clear the error */

            WOLFSSL_LEAVE("SSL_connect()", WOLFSSL_SUCCESS);
            return WOLFSSL_SUCCESS;
    #endif /* !WOLFSSL_NO_TLS12 || !NO_OLD_TLS */

        default:
            WOLFSSL_MSG("Unknown connect state ERROR");
            return WOLFSSL_FATAL_ERROR; /* unknown connect state */
        }
    #endif /* !WOLFSSL_NO_TLS12 || !NO_OLD_TLS || !WOLFSSL_TLS13 */
    }

#endif /* NO_WOLFSSL_CLIENT */


/* server only parts */
#ifndef NO_WOLFSSL_SERVER

    #if defined(OPENSSL_EXTRA) && !defined(NO_OLD_TLS)
    WOLFSSL_METHOD* wolfSSLv2_server_method(void)
    {
        WOLFSSL_STUB("wolfSSLv2_server_method");
        return 0;
    }
    #endif

    #if defined(WOLFSSL_ALLOW_SSLV3) && !defined(NO_OLD_TLS)
    WOLFSSL_METHOD* wolfSSLv3_server_method(void)
    {
        return wolfSSLv3_server_method_ex(NULL);
    }
    WOLFSSL_METHOD* wolfSSLv3_server_method_ex(void* heap)
    {
        WOLFSSL_METHOD* method =
                              (WOLFSSL_METHOD*) XMALLOC(sizeof(WOLFSSL_METHOD),
                                                     heap, DYNAMIC_TYPE_METHOD);
        (void)heap;
        WOLFSSL_ENTER("SSLv3_server_method_ex");
        if (method) {
            InitSSL_Method(method, MakeSSLv3());
            method->side = WOLFSSL_SERVER_END;
        }
        return method;
    }
    #endif /* WOLFSSL_ALLOW_SSLV3 && !NO_OLD_TLS */

    WOLFSSL_METHOD* wolfSSLv23_server_method(void)
    {
        return wolfSSLv23_server_method_ex(NULL);
    }

    WOLFSSL_METHOD* wolfSSLv23_server_method_ex(void* heap)
    {
        WOLFSSL_METHOD* method =
                              (WOLFSSL_METHOD*) XMALLOC(sizeof(WOLFSSL_METHOD),
                                                     heap, DYNAMIC_TYPE_METHOD);
        (void)heap;
        WOLFSSL_ENTER("SSLv23_server_method_ex");
        if (method) {
    #if !defined(NO_SHA256) || defined(WOLFSSL_SHA384) || defined(WOLFSSL_SHA512)
        #ifdef WOLFSSL_TLS13
            InitSSL_Method(method, MakeTLSv1_3());
        #elif !defined(WOLFSSL_NO_TLS12)
            InitSSL_Method(method, MakeTLSv1_2());
        #elif !defined(NO_OLD_TLS)
            InitSSL_Method(method, MakeTLSv1_1());
        #endif
    #else
        #ifndef NO_OLD_TLS
            InitSSL_Method(method, MakeTLSv1_1());
        #else
            #error Must have SHA256, SHA384 or SHA512 enabled for TLS 1.2
        #endif
    #endif
    #if !defined(NO_OLD_TLS) || defined(WOLFSSL_TLS13)
            method->downgrade = 1;
    #endif
            method->side      = WOLFSSL_SERVER_END;
        }
        return method;
    }


    WOLFSSL_ABI
    int wolfSSL_accept(WOLFSSL* ssl)
    {
#if !(defined(WOLFSSL_NO_TLS12) && defined(NO_OLD_TLS) && defined(WOLFSSL_TLS13))
        word16 havePSK = 0;
        word16 haveAnon = 0;
        word16 haveMcast = 0;
#endif
        int ret = 0;

        (void)ret;

        if (ssl == NULL)
            return WOLFSSL_FATAL_ERROR;

    #if defined(OPENSSL_EXTRA) || defined(WOLFSSL_EITHER_SIDE)
        if (ssl->options.side == WOLFSSL_NEITHER_END) {
            WOLFSSL_MSG("Setting WOLFSSL_SSL to be server side");
            ssl->error = InitSSL_Side(ssl, WOLFSSL_SERVER_END);
            if (ssl->error != WOLFSSL_SUCCESS) {
                WOLFSSL_ERROR(ssl->error);
                return WOLFSSL_FATAL_ERROR;
            }
            ssl->error = 0; /* expected to be zero here */
        }
    #endif /* OPENSSL_EXTRA || WOLFSSL_EITHER_SIDE */

#if defined(WOLFSSL_NO_TLS12) && defined(NO_OLD_TLS) && defined(WOLFSSL_TLS13)
        return wolfSSL_accept_TLSv13(ssl);
#else
    #ifdef WOLFSSL_TLS13
        if (ssl->options.tls1_3)
            return wolfSSL_accept_TLSv13(ssl);
    #endif
        WOLFSSL_ENTER("SSL_accept()");

        /* make sure this wolfSSL object has arrays and rng setup. Protects
         * case where the WOLFSSL object is re-used via wolfSSL_clear() */
        if ((ret = ReinitSSL(ssl, ssl->ctx, 0)) != 0) {
            return ret;
        }

#ifdef WOLFSSL_WOLFSENTRY_HOOKS
        if ((ssl->AcceptFilter != NULL) &&
            ((ssl->options.acceptState == ACCEPT_BEGIN)
#ifdef HAVE_SECURE_RENEGOTIATION
             || (ssl->options.acceptState == ACCEPT_BEGIN_RENEG)
#endif
                ))
        {
            wolfSSL_netfilter_decision_t res;
            if ((ssl->AcceptFilter(ssl, ssl->AcceptFilter_arg, &res) ==
                 WOLFSSL_SUCCESS) &&
                (res == WOLFSSL_NETFILTER_REJECT)) {
                ssl->error = SOCKET_FILTERED_E;
                WOLFSSL_ERROR(ssl->error);
                return WOLFSSL_FATAL_ERROR;
            }
        }
#endif /* WOLFSSL_WOLFSENTRY_HOOKS */

        #ifdef HAVE_ERRNO_H
            errno = 0;
        #endif

        #ifndef NO_PSK
            havePSK = ssl->options.havePSK;
        #endif
        (void)havePSK;

        #ifdef HAVE_ANON
            haveAnon = ssl->options.haveAnon;
        #endif
        (void)haveAnon;

        #ifdef WOLFSSL_MULTICAST
            haveMcast = ssl->options.haveMcast;
        #endif
        (void)haveMcast;

        if (ssl->options.side != WOLFSSL_SERVER_END) {
            ssl->error = SIDE_ERROR;
            WOLFSSL_ERROR(ssl->error);
            return WOLFSSL_FATAL_ERROR;
        }

    #ifndef NO_CERTS
        /* in case used set_accept_state after init */
        if (!havePSK && !haveAnon && !haveMcast) {
        #ifdef OPENSSL_EXTRA
            if (ssl->ctx->certSetupCb != NULL) {
                WOLFSSL_MSG("CertSetupCb set. server cert and "
                            "key not checked");
            }
            else
        #endif
            {
                if (!ssl->buffers.certificate ||
                    !ssl->buffers.certificate->buffer) {

                    WOLFSSL_MSG("accept error: server cert required");
                    ssl->error = NO_PRIVATE_KEY;
                    WOLFSSL_ERROR(ssl->error);
                    return WOLFSSL_FATAL_ERROR;
                }

                if (!ssl->buffers.key || !ssl->buffers.key->buffer) {
                    /* allow no private key if using existing key */
                #ifdef WOLF_PRIVATE_KEY_ID
                    if (ssl->devId != INVALID_DEVID
                    #ifdef HAVE_PK_CALLBACKS
                        || wolfSSL_CTX_IsPrivatePkSet(ssl->ctx)
                    #endif
                    ) {
                        WOLFSSL_MSG("Allowing no server private key "
                                    "(external)");
                    }
                    else
                #endif
                    {
                        WOLFSSL_MSG("accept error: server key required");
                        ssl->error = NO_PRIVATE_KEY;
                        WOLFSSL_ERROR(ssl->error);
                        return WOLFSSL_FATAL_ERROR;
                    }
                }
            }
        }
    #endif

    #ifdef WOLFSSL_DTLS
        if (ssl->version.major == DTLS_MAJOR) {
            ssl->options.dtls   = 1;
            ssl->options.tls    = 1;
            ssl->options.tls1_1 = 1;
        }
    #endif

        if (ssl->buffers.outputBuffer.length > 0
        #ifdef WOLFSSL_ASYNC_CRYPT
            /* do not send buffered or advance state if last error was an
                async pending operation */
            && ssl->error != WC_PENDING_E
        #endif
        ) {
            ret = SendBuffered(ssl);
            if (ret == 0) {
                /* fragOffset is non-zero when sending fragments. On the last
                 * fragment, fragOffset is zero again, and the state can be
                 * advanced. */
                if (ssl->fragOffset == 0 && !ssl->options.buildingMsg) {
                    if (ssl->options.acceptState == ACCEPT_FIRST_REPLY_DONE ||
                        ssl->options.acceptState == SERVER_HELLO_SENT ||
                        ssl->options.acceptState == CERT_SENT ||
                        ssl->options.acceptState == CERT_STATUS_SENT ||
                        ssl->options.acceptState == KEY_EXCHANGE_SENT ||
                        ssl->options.acceptState == CERT_REQ_SENT ||
                        ssl->options.acceptState == ACCEPT_SECOND_REPLY_DONE ||
                        ssl->options.acceptState == TICKET_SENT ||
                        ssl->options.acceptState == CHANGE_CIPHER_SENT) {
                        ssl->options.acceptState++;
                        WOLFSSL_MSG("accept state: "
                                    "Advanced from last buffered fragment send");
                    #ifdef WOLFSSL_ASYNC_IO
                        /* Cleanup async */
                        FreeAsyncCtx(ssl, 0);
                    #endif
                    }
                }
                else {
                    WOLFSSL_MSG("accept state: "
                                "Not advanced, more fragments to send");
                }
            }
            else {
                ssl->error = ret;
                WOLFSSL_ERROR(ssl->error);
                return WOLFSSL_FATAL_ERROR;
            }
#ifdef WOLFSSL_DTLS13
            if (ssl->options.dtls)
                ssl->dtls13SendingAckOrRtx = 0;
#endif /* WOLFSSL_DTLS13 */
        }

        ret = RetrySendAlert(ssl);
        if (ret != 0) {
            ssl->error = ret;
            WOLFSSL_ERROR(ssl->error);
            return WOLFSSL_FATAL_ERROR;
        }

        switch (ssl->options.acceptState) {

        case ACCEPT_BEGIN :
#ifdef HAVE_SECURE_RENEGOTIATION
        case ACCEPT_BEGIN_RENEG:
#endif
            /* get response */
            while (ssl->options.clientState < CLIENT_HELLO_COMPLETE)
                if ( (ssl->error = ProcessReply(ssl)) < 0) {
                    WOLFSSL_ERROR(ssl->error);
                    return WOLFSSL_FATAL_ERROR;
                }
#ifdef WOLFSSL_TLS13
            ssl->options.acceptState = ACCEPT_CLIENT_HELLO_DONE;
            WOLFSSL_MSG("accept state ACCEPT_CLIENT_HELLO_DONE");
            FALL_THROUGH;

        case ACCEPT_CLIENT_HELLO_DONE :
            if (ssl->options.tls1_3) {
                return wolfSSL_accept_TLSv13(ssl);
            }
#endif

#ifdef WOLFSSL_DTLS
            if (ssl->chGoodCb != NULL && !IsSCR(ssl)) {
                int cbret = ssl->chGoodCb(ssl, ssl->chGoodCtx);
                if (cbret < 0) {
                    ssl->error = cbret;
                    WOLFSSL_MSG("ClientHello Good Cb don't continue error");
                    return WOLFSSL_FATAL_ERROR;
                }
            }
#endif

            ssl->options.acceptState = ACCEPT_FIRST_REPLY_DONE;
            WOLFSSL_MSG("accept state ACCEPT_FIRST_REPLY_DONE");
            FALL_THROUGH;

        case ACCEPT_FIRST_REPLY_DONE :
            if ( (ssl->error = SendServerHello(ssl)) != 0) {
                WOLFSSL_ERROR(ssl->error);
                return WOLFSSL_FATAL_ERROR;
            }
            ssl->options.acceptState = SERVER_HELLO_SENT;
            WOLFSSL_MSG("accept state SERVER_HELLO_SENT");
            FALL_THROUGH;

        case SERVER_HELLO_SENT :
        #ifdef WOLFSSL_TLS13
            if (ssl->options.tls1_3) {
                return wolfSSL_accept_TLSv13(ssl);
            }
        #endif
            #ifndef NO_CERTS
                if (!ssl->options.resuming)
                    if ( (ssl->error = SendCertificate(ssl)) != 0) {
                        WOLFSSL_ERROR(ssl->error);
                        return WOLFSSL_FATAL_ERROR;
                    }
            #endif
            ssl->options.acceptState = CERT_SENT;
            WOLFSSL_MSG("accept state CERT_SENT");
            FALL_THROUGH;

        case CERT_SENT :
            #ifndef NO_CERTS
            if (!ssl->options.resuming)
                if ( (ssl->error = SendCertificateStatus(ssl)) != 0) {
                    WOLFSSL_ERROR(ssl->error);
                    return WOLFSSL_FATAL_ERROR;
                }
            #endif
            ssl->options.acceptState = CERT_STATUS_SENT;
            WOLFSSL_MSG("accept state CERT_STATUS_SENT");
            FALL_THROUGH;

        case CERT_STATUS_SENT :
        #ifdef WOLFSSL_TLS13
            if (ssl->options.tls1_3) {
                return wolfSSL_accept_TLSv13(ssl);
            }
        #endif
            if (!ssl->options.resuming)
                if ( (ssl->error = SendServerKeyExchange(ssl)) != 0) {
                    WOLFSSL_ERROR(ssl->error);
                    return WOLFSSL_FATAL_ERROR;
                }
            ssl->options.acceptState = KEY_EXCHANGE_SENT;
            WOLFSSL_MSG("accept state KEY_EXCHANGE_SENT");
            FALL_THROUGH;

        case KEY_EXCHANGE_SENT :
            #ifndef NO_CERTS
                if (!ssl->options.resuming) {
                    if (ssl->options.verifyPeer) {
                        if ( (ssl->error = SendCertificateRequest(ssl)) != 0) {
                            WOLFSSL_ERROR(ssl->error);
                            return WOLFSSL_FATAL_ERROR;
                        }
                    }
                    else {
                        /* SERVER: Peer auth good if not verifying client. */
                        ssl->options.peerAuthGood = 1;
                    }
                }
            #endif
            ssl->options.acceptState = CERT_REQ_SENT;
            WOLFSSL_MSG("accept state CERT_REQ_SENT");
            FALL_THROUGH;

        case CERT_REQ_SENT :
            if (!ssl->options.resuming)
                if ( (ssl->error = SendServerHelloDone(ssl)) != 0) {
                    WOLFSSL_ERROR(ssl->error);
                    return WOLFSSL_FATAL_ERROR;
                }
            ssl->options.acceptState = SERVER_HELLO_DONE;
            WOLFSSL_MSG("accept state SERVER_HELLO_DONE");
            FALL_THROUGH;

        case SERVER_HELLO_DONE :
            if (!ssl->options.resuming) {
                while (ssl->options.clientState < CLIENT_FINISHED_COMPLETE)
                    if ( (ssl->error = ProcessReply(ssl)) < 0) {
                        WOLFSSL_ERROR(ssl->error);
                        return WOLFSSL_FATAL_ERROR;
                    }
            }
            ssl->options.acceptState = ACCEPT_SECOND_REPLY_DONE;
            WOLFSSL_MSG("accept state  ACCEPT_SECOND_REPLY_DONE");
            FALL_THROUGH;

        case ACCEPT_SECOND_REPLY_DONE :
        #ifndef NO_CERTS
            /* SERVER: When not resuming and verifying peer but no certificate
             * received and not failing when not received then peer auth good.
             */
            if (!ssl->options.resuming && ssl->options.verifyPeer &&
                !ssl->options.havePeerCert && !ssl->options.failNoCert) {
                ssl->options.peerAuthGood = 1;
            }
        #endif /* !NO_CERTS  */
        #ifdef WOLFSSL_NO_CLIENT_AUTH
            if (!ssl->options.resuming) {
                ssl->options.peerAuthGood = 1;
            }
        #endif

#ifdef HAVE_SESSION_TICKET
            if (ssl->options.createTicket && !ssl->options.noTicketTls12) {
                if ( (ssl->error = SendTicket(ssl)) != 0) {
                    WOLFSSL_MSG("Thought we need ticket but failed");
                    WOLFSSL_ERROR(ssl->error);
                    return WOLFSSL_FATAL_ERROR;
                }
            }
#endif /* HAVE_SESSION_TICKET */
            ssl->options.acceptState = TICKET_SENT;
            WOLFSSL_MSG("accept state  TICKET_SENT");
            FALL_THROUGH;

        case TICKET_SENT:
            /* SERVER: Fail-safe for CLient Authentication. */
            if (!ssl->options.peerAuthGood) {
                WOLFSSL_MSG("Client authentication did not happen");
                return WOLFSSL_FATAL_ERROR;
            }

            if ( (ssl->error = SendChangeCipher(ssl)) != 0) {
                WOLFSSL_ERROR(ssl->error);
                return WOLFSSL_FATAL_ERROR;
            }
            ssl->options.acceptState = CHANGE_CIPHER_SENT;
            WOLFSSL_MSG("accept state  CHANGE_CIPHER_SENT");
            FALL_THROUGH;

        case CHANGE_CIPHER_SENT :
            if ( (ssl->error = SendFinished(ssl)) != 0) {
                WOLFSSL_ERROR(ssl->error);
                return WOLFSSL_FATAL_ERROR;
            }

            ssl->options.acceptState = ACCEPT_FINISHED_DONE;
            WOLFSSL_MSG("accept state ACCEPT_FINISHED_DONE");
            FALL_THROUGH;

        case ACCEPT_FINISHED_DONE :
            if (ssl->options.resuming) {
                while (ssl->options.clientState < CLIENT_FINISHED_COMPLETE) {
                    if ( (ssl->error = ProcessReply(ssl)) < 0) {
                        WOLFSSL_ERROR(ssl->error);
                        return WOLFSSL_FATAL_ERROR;
                    }
                }
            }
            ssl->options.acceptState = ACCEPT_THIRD_REPLY_DONE;
            WOLFSSL_MSG("accept state ACCEPT_THIRD_REPLY_DONE");
            FALL_THROUGH;

        case ACCEPT_THIRD_REPLY_DONE :
#ifndef NO_HANDSHAKE_DONE_CB
            if (ssl->hsDoneCb) {
                int cbret = ssl->hsDoneCb(ssl, ssl->hsDoneCtx);
                if (cbret < 0) {
                    ssl->error = cbret;
                    WOLFSSL_MSG("HandShake Done Cb don't continue error");
                    return WOLFSSL_FATAL_ERROR;
                }
            }
#endif /* NO_HANDSHAKE_DONE_CB */

            if (!ssl->options.dtls) {
                if (!ssl->options.keepResources) {
                    FreeHandshakeResources(ssl);
                }
            }
#ifdef WOLFSSL_DTLS
            else {
                ssl->options.dtlsHsRetain = 1;
            }
#endif /* WOLFSSL_DTLS */

#if defined(WOLFSSL_ASYNC_CRYPT) && defined(HAVE_SECURE_RENEGOTIATION)
            /* This may be necessary in async so that we don't try to
             * renegotiate again */
            if (ssl->secure_renegotiation && ssl->secure_renegotiation->startScr) {
                ssl->secure_renegotiation->startScr = 0;
            }
#endif /* WOLFSSL_ASYNC_CRYPT && HAVE_SECURE_RENEGOTIATION */
#if defined(WOLFSSL_ASYNC_IO) && !defined(WOLFSSL_ASYNC_CRYPT)
            /* Free the remaining async context if not using it for crypto */
            FreeAsyncCtx(ssl, 1);
#endif

#if defined(WOLFSSL_SESSION_EXPORT) && defined(WOLFSSL_DTLS)
            if (ssl->dtls_export) {
                if ((ssl->error = wolfSSL_send_session(ssl)) != 0) {
                    WOLFSSL_MSG("Export DTLS session error");
                    WOLFSSL_ERROR(ssl->error);
                    return WOLFSSL_FATAL_ERROR;
                }
            }
#endif
            ssl->error = 0; /* clear the error */

            WOLFSSL_LEAVE("SSL_accept()", WOLFSSL_SUCCESS);
            return WOLFSSL_SUCCESS;

        default :
            WOLFSSL_MSG("Unknown accept state ERROR");
            return WOLFSSL_FATAL_ERROR;
        }
#endif /* !WOLFSSL_NO_TLS12 */
    }

#endif /* NO_WOLFSSL_SERVER */

#if defined(WOLFSSL_DTLS) && !defined(NO_WOLFSSL_SERVER)
int wolfDTLS_SetChGoodCb(WOLFSSL* ssl, ClientHelloGoodCb cb, void* user_ctx)
{
    WOLFSSL_ENTER("wolfDTLS_SetChGoodCb");

    if (ssl == NULL)
        return BAD_FUNC_ARG;

    ssl->chGoodCb  = cb;
    ssl->chGoodCtx = user_ctx;

    return WOLFSSL_SUCCESS;
}
#endif

#ifndef NO_HANDSHAKE_DONE_CB

int wolfSSL_SetHsDoneCb(WOLFSSL* ssl, HandShakeDoneCb cb, void* user_ctx)
{
    WOLFSSL_ENTER("wolfSSL_SetHsDoneCb");

    if (ssl == NULL)
        return BAD_FUNC_ARG;

    ssl->hsDoneCb  = cb;
    ssl->hsDoneCtx = user_ctx;


    return WOLFSSL_SUCCESS;
}

#endif /* NO_HANDSHAKE_DONE_CB */

WOLFSSL_ABI
int wolfSSL_Cleanup(void)
{
    int ret = WOLFSSL_SUCCESS; /* Only the first error will be returned */
    int release = 0;
#if !defined(NO_SESSION_CACHE) && defined(ENABLE_SESSION_CACHE_ROW_LOCK)
    int i;
#endif

    WOLFSSL_ENTER("wolfSSL_Cleanup");

    if (initRefCount == 0)
        return ret;  /* possibly no init yet, but not failure either way */

    if ((count_mutex_valid == 1) && (wc_LockMutex(&count_mutex) != 0)) {
        WOLFSSL_MSG("Bad Lock Mutex count");
        ret = BAD_MUTEX_E;
    }

    release = initRefCount-- == 1;
    if (initRefCount < 0)
        initRefCount = 0;

    if (count_mutex_valid == 1) {
        wc_UnLockMutex(&count_mutex);
    }

    if (!release)
        return ret;

#ifdef OPENSSL_EXTRA
    if (bn_one) {
        wolfSSL_BN_free(bn_one);
        bn_one = NULL;
    }
#endif

#ifndef NO_SESSION_CACHE
    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
    for (i = 0; i < SESSION_ROWS; ++i) {
        if ((SessionCache[i].mutex_valid == 1) &&
            (wc_FreeMutex(&SessionCache[i].row_mutex) != 0)) {
            if (ret == WOLFSSL_SUCCESS)
                ret = BAD_MUTEX_E;
        }
        SessionCache[i].mutex_valid = 0;
    }
    #else
    if ((session_mutex_valid == 1) && (wc_FreeMutex(&session_mutex) != 0)) {
        if (ret == WOLFSSL_SUCCESS)
            ret = BAD_MUTEX_E;
    }
    session_mutex_valid = 0;
    #endif
    #ifndef NO_CLIENT_CACHE
    if ((clisession_mutex_valid == 1) &&
        (wc_FreeMutex(&clisession_mutex) != 0)) {
        if (ret == WOLFSSL_SUCCESS)
            ret = BAD_MUTEX_E;
    }
    clisession_mutex_valid = 0;
    #endif
#endif /* !NO_SESSION_CACHE */

    if ((count_mutex_valid == 1) && (wc_FreeMutex(&count_mutex) != 0)) {
        if (ret == WOLFSSL_SUCCESS)
            ret = BAD_MUTEX_E;
    }
    count_mutex_valid = 0;

#ifdef OPENSSL_EXTRA
    wolfSSL_RAND_Cleanup();
#endif

    if (wolfCrypt_Cleanup() != 0) {
        WOLFSSL_MSG("Error with wolfCrypt_Cleanup call");
        if (ret == WOLFSSL_SUCCESS)
            ret = WC_CLEANUP_E;
    }

#if FIPS_VERSION_GE(5,1)
    if (wolfCrypt_SetPrivateKeyReadEnable_fips(0, WC_KEYTYPE_ALL) < 0) {
        if (ret == WOLFSSL_SUCCESS)
            ret = WC_CLEANUP_E;
    }
#endif

#ifdef HAVE_GLOBAL_RNG
    if ((globalRNGMutex_valid == 1) && (wc_FreeMutex(&globalRNGMutex) != 0)) {
        if (ret == WOLFSSL_SUCCESS)
            ret = BAD_MUTEX_E;
    }
    globalRNGMutex_valid = 0;

    #if defined(OPENSSL_EXTRA) && defined(HAVE_HASHDRBG)
    wolfSSL_FIPS_drbg_free(gDrbgDefCtx);
    gDrbgDefCtx = NULL;
    #endif
#endif

    return ret;
}


#ifndef NO_SESSION_CACHE

WOLFSSL_ABI
void wolfSSL_flush_sessions(WOLFSSL_CTX* ctx, long tm)
{
    /* static table now, no flushing needed */
    (void)ctx;
    (void)tm;
}


/* set ssl session timeout in seconds */
WOLFSSL_ABI
int wolfSSL_set_timeout(WOLFSSL* ssl, unsigned int to)
{
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    if (to == 0)
        to = WOLFSSL_SESSION_TIMEOUT;
    ssl->timeout = to;

    return WOLFSSL_SUCCESS;
}


/**
 * Sets ctx session timeout in seconds.
 * The timeout value set here should be reflected in the
 * "session ticket lifetime hint" if this API works in the openssl compat-layer.
 * Therefore wolfSSL_CTX_set_TicketHint is called internally.
 * Arguments:
 *  - ctx  WOLFSSL_CTX object which the timeout is set to
 *  - to   timeout value in second
 * Returns:
 *  WOLFSSL_SUCCESS on success, BAD_FUNC_ARG on failure.
 *  When WOLFSSL_ERROR_CODE_OPENSSL is defined, returns previous timeout value
 *  on success, BAD_FUNC_ARG on failure.
 */
WOLFSSL_ABI
int wolfSSL_CTX_set_timeout(WOLFSSL_CTX* ctx, unsigned int to)
{
    #if defined(WOLFSSL_ERROR_CODE_OPENSSL)
    word32 prev_timeout = 0;
    #endif

    int ret = WOLFSSL_SUCCESS;
    (void)ret;

    if (ctx == NULL)
        ret = BAD_FUNC_ARG;

    if (ret == WOLFSSL_SUCCESS) {
    #if defined(WOLFSSL_ERROR_CODE_OPENSSL)
        prev_timeout = ctx->timeout;
    #endif
        if (to == 0) {
            ctx->timeout = WOLFSSL_SESSION_TIMEOUT;
        }
        else {
            ctx->timeout = to;
        }
    }
#if defined(OPENSSL_EXTRA) && defined(HAVE_SESSION_TICKET) && \
   !defined(NO_WOLFSSL_SERVER)
    if (ret == WOLFSSL_SUCCESS) {
        if (to == 0) {
            ret = wolfSSL_CTX_set_TicketHint(ctx, SESSION_TICKET_HINT_DEFAULT);
        }
        else {
            ret = wolfSSL_CTX_set_TicketHint(ctx, to);
        }
    }
#endif /* OPENSSL_EXTRA && HAVE_SESSION_TICKET && !NO_WOLFSSL_SERVER */

#if defined(WOLFSSL_ERROR_CODE_OPENSSL)
    if (ret == WOLFSSL_SUCCESS) {
        return prev_timeout;
    }
    else {
        return ret;
    }
#else
    return ret;
#endif /* WOLFSSL_ERROR_CODE_OPENSSL */
}


#ifndef NO_CLIENT_CACHE

/* Get Session from Client cache based on id/len, return NULL on failure */
WOLFSSL_SESSION* wolfSSL_GetSessionClient(WOLFSSL* ssl, const byte* id, int len)
{
    WOLFSSL_SESSION* ret = NULL;
    word32          row;
    int             idx;
    int             count;
    int             error = 0;
    ClientSession*  clSess;

    WOLFSSL_ENTER("GetSessionClient");

    if (ssl->ctx->sessionCacheOff) {
        WOLFSSL_MSG("Session Cache off");
        return NULL;
    }

    if (ssl->options.side == WOLFSSL_SERVER_END)
        return NULL;

    len = min(SERVER_ID_LEN, (word32)len);

#ifdef HAVE_EXT_CACHE
    if (ssl->ctx->get_sess_cb != NULL) {
        int copy = 0;
        WOLFSSL_MSG("Calling external session cache");
        ret = ssl->ctx->get_sess_cb(ssl, (byte*)id, len, &copy);
        if (ret != NULL) {
            WOLFSSL_MSG("Session found in external cache");
            return ret;
        }
        WOLFSSL_MSG("Session not found in external cache");
    }

    if (ssl->ctx->internalCacheLookupOff) {
        WOLFSSL_MSG("Internal cache turned off");
        return NULL;
    }
#endif

    row = HashObject(id, len, &error) % CLIENT_SESSION_ROWS;
    if (error != 0) {
        WOLFSSL_MSG("Hash session failed");
        return NULL;
    }

    if (wc_LockMutex(&clisession_mutex) != 0) {
        WOLFSSL_MSG("Client cache mutex lock failed");
        return NULL;
    }

    /* start from most recently used */
    count = min((word32)ClientCache[row].totalCount, CLIENT_SESSIONS_PER_ROW);
    idx = ClientCache[row].nextIdx - 1;
    if (idx < 0 || idx >= CLIENT_SESSIONS_PER_ROW) {
        idx = CLIENT_SESSIONS_PER_ROW - 1; /* if back to front, the previous was end */
    }
    clSess = ClientCache[row].Clients;

    for (; count > 0; --count) {
        WOLFSSL_SESSION* current;
        SessionRow* sessRow;

        if (clSess[idx].serverRow >= SESSION_ROWS) {
            WOLFSSL_MSG("Client cache serverRow invalid");
            break;
        }

        /* lock row */
        sessRow = &SessionCache[clSess[idx].serverRow];
        if (SESSION_ROW_LOCK(sessRow) != 0) {
            WOLFSSL_MSG("Session cache row lock failure");
            break;
        }

        current = &sessRow->Sessions[clSess[idx].serverIdx];
        if (XMEMCMP(current->serverID, id, len) == 0) {
            WOLFSSL_MSG("Found a serverid match for client");
            if (LowResTimer() < (current->bornOn + current->timeout)) {
                WOLFSSL_MSG("Session valid");
                ret = current;
                SESSION_ROW_UNLOCK(sessRow);
                break;
            } else {
                WOLFSSL_MSG("Session timed out");  /* could have more for id */
            }
        } else {
            WOLFSSL_MSG("ServerID not a match from client table");
        }
        SESSION_ROW_UNLOCK(sessRow);

        idx = idx > 0 ? idx - 1 : CLIENT_SESSIONS_PER_ROW - 1;
    }

    wc_UnLockMutex(&clisession_mutex);

    return ret;
}

#endif /* !NO_CLIENT_CACHE */

static int SslSessionCacheOff(const WOLFSSL* ssl, const WOLFSSL_SESSION* session)
{
    (void)session;
    return ssl->options.sessionCacheOff
    #if defined(HAVE_SESSION_TICKET) && defined(WOLFSSL_FORCE_CACHE_ON_TICKET)
                && session->ticketLen == 0
    #endif
    #ifdef OPENSSL_EXTRA
                && ssl->options.side != WOLFSSL_CLIENT_END
    #endif
                ;
}

#if defined(HAVE_SESSION_TICKET) && defined(WOLFSSL_TLS13) &&                  \
    defined(WOLFSSL_TICKET_NONCE_MALLOC) && \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
/**
 * SessionTicketNoncePrealloc() - prealloc a buffer for ticket nonces
 * @output: [in] pointer to WOLFSSL_SESSION object that will soon be a
 * destination of a session duplication
 * @buf: [out] address of the preallocated buf
 * @len: [out] len of the preallocated buf
 *
 * prealloc a buffer that will likely suffice to contain a ticket nonce. It's
 * used when copying session under lock, when syscalls need to be avoided. If
 * output already has a dynamic buffer, it's reused.
 */
static int SessionTicketNoncePrealloc(byte** buf, byte* len, void *heap)
{
    (void)heap;

    *buf = (byte*)XMALLOC(PREALLOC_SESSION_TICKET_NONCE_LEN, heap,
        DYNAMIC_TYPE_SESSION_TICK);
    if (*buf == NULL) {
        WOLFSSL_MSG("Failed to preallocate ticket nonce buffer");
        *len = 0;
        return WOLFSSL_FAILURE;
    }

    *len = PREALLOC_SESSION_TICKET_NONCE_LEN;
    return 0;
}
#endif /* HAVE_SESSION_TICKET && WOLFSSL_TLS13 */

static int wolfSSL_DupSessionEx(const WOLFSSL_SESSION* input,
    WOLFSSL_SESSION* output, int avoidSysCalls, byte* ticketNonceBuf,
    byte* ticketNonceLen, byte* preallocUsed);

void TlsSessionCacheUnlockRow(word32 row)
{
    SessionRow* sessRow;

    sessRow = &SessionCache[row];
    (void)sessRow;
    SESSION_ROW_UNLOCK(sessRow);
}

int TlsSessionCacheGetAndLock(const byte *id, WOLFSSL_SESSION **sess,
    word32 *lockedRow)
{
    SessionRow *sessRow;
    WOLFSSL_SESSION *s;
    word32 row;
    int count;
    int error;
    int idx;

    *sess = NULL;
    row = HashObject(id, ID_LEN, &error) % SESSION_ROWS;
    if (error != 0)
        return error;
    sessRow = &SessionCache[row];
    if (SESSION_ROW_LOCK(sessRow) != 0)
        return FATAL_ERROR;

    /* start from most recently used */
    count = min((word32)sessRow->totalCount, SESSIONS_PER_ROW);
    idx = sessRow->nextIdx - 1;
    if (idx < 0 || idx >= SESSIONS_PER_ROW) {
        idx = SESSIONS_PER_ROW - 1; /* if back to front, the previous was end */
    }
    for (; count > 0; --count) {
        s = &sessRow->Sessions[idx];
        if (XMEMCMP(s->sessionID, id, ID_LEN) == 0) {
            *sess = s;
            break;
        }
        idx = idx > 0 ? idx - 1 : SESSIONS_PER_ROW - 1;
    }
    if (*sess == NULL) {
        SESSION_ROW_UNLOCK(sessRow);
    }
    else {
        *lockedRow = row;
    }

    return 0;
}

int wolfSSL_GetSessionFromCache(WOLFSSL* ssl, WOLFSSL_SESSION* output)
{
    WOLFSSL_SESSION* sess = NULL;
    const byte*  id = NULL;
    word32       row;
    int          error = 0;
#ifdef HAVE_SESSION_TICKET
#ifndef WOLFSSL_SMALL_STACK
    byte         tmpTicket[PREALLOC_SESSION_TICKET_LEN];
#else
    byte*        tmpTicket = NULL;
#endif
#ifdef WOLFSSL_TLS13
    byte *preallocNonce = NULL;
    byte preallocNonceLen = 0;
    byte preallocNonceUsed = 0;
#endif /* WOLFSSL_TLS13 */
    byte         tmpBufSet = 0;
#endif
#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
    WOLFSSL_X509* peer = NULL;
#endif
    byte         bogusID[ID_LEN];
    byte         bogusIDSz = 0;

    WOLFSSL_ENTER("wolfSSL_GetSessionFromCache");

    if (output == NULL) {
        WOLFSSL_MSG("NULL output");
        return WOLFSSL_FAILURE;
    }

    if (SslSessionCacheOff(ssl, ssl->session))
        return WOLFSSL_FAILURE;

    if (ssl->options.haveSessionId == 0)
        return WOLFSSL_FAILURE;

#ifdef HAVE_SESSION_TICKET
    if (ssl->options.side == WOLFSSL_SERVER_END && ssl->options.useTicket == 1)
        return WOLFSSL_FAILURE;
#endif

    XMEMSET(bogusID, 0, sizeof(bogusID));
    if (!IsAtLeastTLSv1_3(ssl->version) && ssl->arrays != NULL)
        id = ssl->arrays->sessionID;
    else if (ssl->session->haveAltSessionID) {
        id = ssl->session->altSessionID;
        /* We want to restore the bogus ID for TLS compatibility */
        if (output == ssl->session) {
            XMEMCPY(bogusID, ssl->session->sessionID, ID_LEN);
            bogusIDSz = ssl->session->sessionIDSz;
        }
    }
    else
        id = ssl->session->sessionID;


#ifdef HAVE_EXT_CACHE
    if (ssl->ctx->get_sess_cb != NULL) {
        int copy = 0;
        /* Attempt to retrieve the session from the external cache. */
        WOLFSSL_MSG("Calling external session cache");
        sess = ssl->ctx->get_sess_cb(ssl, (byte*)id, ID_LEN, &copy);
        if ((sess != NULL)
        #if defined(WOLFSSL_TLS13) && defined(HAVE_SESSION_TICKET)
            && (IsAtLeastTLSv1_3(ssl->version) ==
                IsAtLeastTLSv1_3(sess->version))
        #endif
            ) {
            WOLFSSL_MSG("Session found in external cache");
            error = wolfSSL_DupSession(sess, output, 0);
#ifdef HAVE_EX_DATA
            output->ownExData = 0; /* Session cache owns external data */
#endif
            /* If copy not set then free immediately */
            if (!copy)
                wolfSSL_FreeSession(ssl->ctx, sess);
            /* We want to restore the bogus ID for TLS compatibility */
            if (ssl->session->haveAltSessionID &&
                    output == ssl->session) {
                XMEMCPY(ssl->session->sessionID, bogusID, ID_LEN);
                ssl->session->sessionIDSz = bogusIDSz;
            }
            return error;
        }
        WOLFSSL_MSG("Session not found in external cache");
    }

    if (ssl->ctx->internalCacheLookupOff) {
        WOLFSSL_MSG("Internal cache lookup turned off");
        return WOLFSSL_FAILURE;
    }
#endif

#ifdef HAVE_SESSION_TICKET
    if (output->ticket == NULL ||
            output->ticketLenAlloc < PREALLOC_SESSION_TICKET_LEN) {
#ifdef WOLFSSL_SMALL_STACK
        tmpTicket = (byte*)XMALLOC(PREALLOC_SESSION_TICKET_LEN, output->heap,
                DYNAMIC_TYPE_TMP_BUFFER);
        if (tmpTicket == NULL) {
            WOLFSSL_MSG("tmpTicket malloc failed");
            return WOLFSSL_FAILURE;
        }
#endif
        if (output->ticketLenAlloc)
            XFREE(output->ticket, output->heap, DYNAMIC_TYPE_SESSION_TICK);
        output->ticket = tmpTicket;
        output->ticketLenAlloc = PREALLOC_SESSION_TICKET_LEN;
        output->ticketLen = 0;
        tmpBufSet = 1;
    }
#endif

#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
    if (output->peer != NULL) {
        wolfSSL_X509_free(output->peer);
        output->peer = NULL;
    }
#endif

#if defined(WOLFSSL_TLS13) && defined(HAVE_SESSION_TICKET) &&                  \
    defined(WOLFSSL_TICKET_NONCE_MALLOC) &&                                    \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
    if (output->ticketNonce.data != output->ticketNonce.dataStatic) {
        XFREE(output->ticketNonce.data, output->heap,
            DYNAMIC_TYPE_SESSION_TICK);
        output->ticketNonce.data = output->ticketNonce.dataStatic;
        output->ticketNonce.len = 0;
    }
    error = SessionTicketNoncePrealloc(&preallocNonce, &preallocNonceLen,
        output->heap);
    if (error != 0) {
        if (tmpBufSet) {
            output->ticket = output->staticTicket;
            output->ticketLenAlloc = 0;
        }
#ifdef WOLFSSL_SMALL_STACK
        if (tmpTicket != NULL)
            XFREE(tmpTicket, output->heap, DYNAMIC_TYPE_TMP_BUFFER);
#endif
        return WOLFSSL_FAILURE;
    }
#endif /* WOLFSSL_TLS13 && HAVE_SESSION_TICKET*/

    /* init to avoid clang static analyzer false positive */
    row = 0;
    error = TlsSessionCacheGetAndLock(id, &sess, &row);
    error = (error == 0) ? WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
    if (error != WOLFSSL_SUCCESS || sess == NULL) {
        WOLFSSL_MSG("Get Session from cache failed");
        error = WOLFSSL_FAILURE;
#ifdef HAVE_SESSION_TICKET
        if (tmpBufSet) {
            output->ticket = output->staticTicket;
            output->ticketLenAlloc = 0;
        }
#ifdef WOLFSSL_TLS13
        if (preallocNonce != NULL) {
            XFREE(preallocNonce, output->heap, DYNAMIC_TYPE_SESSION_TICK);
            preallocNonce = NULL;
        }
#endif /* WOLFSSL_TLS13 */
#ifdef WOLFSSL_SMALL_STACK
        if (tmpTicket != NULL) {
            XFREE(tmpTicket, output->heap, DYNAMIC_TYPE_TMP_BUFFER);
            tmpTicket = NULL;
        }
#endif
#endif
    }
    else {
#if defined(WOLFSSL_TLS13) && defined(HAVE_SESSION_TICKET)
        if (IsAtLeastTLSv1_3(ssl->version) != IsAtLeastTLSv1_3(sess->version)) {
            WOLFSSL_MSG("Invalid session: different protocol version");
            TlsSessionCacheUnlockRow(row);
            error = WOLFSSL_FAILURE;
        }
        else if (LowResTimer() >= (sess->bornOn + sess->timeout)) {
            WOLFSSL_MSG("Invalid session: timed out");
            TlsSessionCacheUnlockRow(row);
            error = WOLFSSL_FAILURE;
        }
#endif /* HAVE_SESSION_TICKET && WOLFSSL_TLS13 */
    }

    if (error == WOLFSSL_SUCCESS) {
#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
        /* We don't want the peer member. We will free it at the end. */
        if (sess->peer != NULL) {
            peer = sess->peer;
            sess->peer = NULL;
        }
#endif
#if defined(HAVE_SESSION_TICKET) && defined(WOLFSSL_TLS13)
        error = wolfSSL_DupSessionEx(sess, output, 1,
            preallocNonce, &preallocNonceLen, &preallocNonceUsed);
#else
        error = wolfSSL_DupSession(sess, output, 1);
#endif /* HAVE_SESSION_TICKET && WOLFSSL_TLS13 */
#ifdef HAVE_EX_DATA
        output->ownExData = 0; /* Session cache owns external data */
#endif
        TlsSessionCacheUnlockRow(row);
    }

    /* We want to restore the bogus ID for TLS compatibility */
    if (ssl->session->haveAltSessionID &&
            output == ssl->session) {
        XMEMCPY(ssl->session->sessionID, bogusID, ID_LEN);
        ssl->session->sessionIDSz = bogusIDSz;
    }

#ifdef HAVE_SESSION_TICKET
    if (tmpBufSet) {
        if (error == WOLFSSL_SUCCESS) {
            if (output->ticketLen > SESSION_TICKET_LEN) {
                output->ticket = (byte*)XMALLOC(output->ticketLen, output->heap,
                        DYNAMIC_TYPE_SESSION_TICK);
                if (output->ticket == NULL) {
                    error = WOLFSSL_FAILURE;
                    output->ticket = output->staticTicket;
                    output->ticketLenAlloc = 0;
                    output->ticketLen = 0;
                }
            }
            else {
                output->ticket = output->staticTicket;
                output->ticketLenAlloc = 0;
            }
        }
        else {
            output->ticket = output->staticTicket;
            output->ticketLenAlloc = 0;
            output->ticketLen = 0;
        }
        if (error == WOLFSSL_SUCCESS) {
            XMEMCPY(output->ticket, tmpTicket, output->ticketLen);
        }
    }
#ifdef WOLFSSL_SMALL_STACK
    if (tmpTicket != NULL)
        XFREE(tmpTicket, output->heap, DYNAMIC_TYPE_TMP_BUFFER);
#endif

#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_TICKET_NONCE_MALLOC) &&          \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
    if (error == WOLFSSL_SUCCESS && preallocNonceUsed) {
        if (preallocNonceLen < PREALLOC_SESSION_TICKET_NONCE_LEN) {
            /* buffer bigger than needed */
#ifndef XREALLOC
            output->ticketNonce.data = (byte*)XMALLOC(preallocNonceLen,
                output->heap, DYNAMIC_TYPE_SESSION_TICK);
            if (output->ticketNonce.data != NULL)
                XMEMCPY(output->ticketNonce.data, preallocNonce,
                    preallocNonceLen);
            XFREE(preallocNonce, output->heap, DYNAMIC_TYPE_SESSION_TICK);
            preallocNonce = NULL;
#else
            output->ticketNonce.data = XREALLOC(preallocNonce,
                preallocNonceLen, output->heap, DYNAMIC_TYPE_SESSION_TICK);
            if (output->ticketNonce.data != NULL) {
                /* don't free the reallocated pointer */
                preallocNonce = NULL;
            }
#endif /* !XREALLOC */
            if (output->ticketNonce.data == NULL) {
                output->ticketNonce.data = output->ticketNonce.dataStatic;
                output->ticketNonce.len = 0;
                error = WOLFSSL_FAILURE;
                /* preallocNonce will be free'd after the if */
            }
        }
        else {
            output->ticketNonce.data = preallocNonce;
            output->ticketNonce.len = preallocNonceLen;
            preallocNonce = NULL;
        }
    }
    if (preallocNonce != NULL)
        XFREE(preallocNonce, output->heap, DYNAMIC_TYPE_SESSION_TICK);
#endif /* WOLFSSL_TLS13 && WOLFSSL_TICKET_NONCE_MALLOC && FIPS_VERSION_GE(5,3)*/

#endif

#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
    if (peer != NULL) {
        wolfSSL_X509_free(peer);
    }
#endif

    return error;
}

WOLFSSL_SESSION* wolfSSL_GetSession(WOLFSSL* ssl, byte* masterSecret,
        byte restoreSessionCerts)
{
    WOLFSSL_SESSION* ret = NULL;

    (void)restoreSessionCerts; /* Kept for compatibility */

    if (wolfSSL_GetSessionFromCache(ssl, ssl->session) == WOLFSSL_SUCCESS) {
        ret = ssl->session;
    }
    else {
        WOLFSSL_MSG("wolfSSL_GetSessionFromCache did not return a session");
    }

    if (ret != NULL && masterSecret != NULL)
        XMEMCPY(masterSecret, ret->masterSecret, SECRET_LEN);

    return ret;
}

int wolfSSL_SetSession(WOLFSSL* ssl, WOLFSSL_SESSION* session)
{
    SessionRow* sessRow = NULL;
    int ret = WOLFSSL_SUCCESS;

    session = ClientSessionToSession(session);

    if (ssl == NULL || session == NULL) {
        return WOLFSSL_FAILURE;
    }

    if (session->type == WOLFSSL_SESSION_TYPE_CACHE) {
        if (session->cacheRow < SESSION_ROWS) {
            sessRow = &SessionCache[session->cacheRow];
            if (SESSION_ROW_LOCK(sessRow) != 0) {
                WOLFSSL_MSG("Session row lock failed");
                return WOLFSSL_FAILURE;
            }
        }
    }

    if (ret == WOLFSSL_SUCCESS && SslSessionCacheOff(ssl, session)) {
        WOLFSSL_MSG("Session cache off");
        ret = WOLFSSL_FAILURE;
    }

    if (ret == WOLFSSL_SUCCESS && ssl->options.side != WOLFSSL_NEITHER_END &&
            (byte)ssl->options.side != session->side) {
        WOLFSSL_MSG("Setting session for wrong role");
        ret = WOLFSSL_FAILURE;
    }


    if (ret == WOLFSSL_SUCCESS &&
            wolfSSL_DupSession(session, ssl->session, 0) != WOLFSSL_SUCCESS) {
        WOLFSSL_MSG("Session duplicate failed");
        ret = WOLFSSL_FAILURE;
    }

    /* Let's copy over the altSessionID for local cache purposes */
    if (ret == WOLFSSL_SUCCESS && session->haveAltSessionID) {
        ssl->session->haveAltSessionID = 1;
        XMEMCPY(ssl->session->altSessionID, session->altSessionID, ID_LEN);
    }

    if (sessRow != NULL) {
        SESSION_ROW_UNLOCK(sessRow);
        sessRow = NULL;
    }

    /* Note: the `session` variable cannot be used below, since the row is
     * un-locked */

    if (ret != WOLFSSL_SUCCESS)
        return ret;

#ifdef OPENSSL_EXTRA
    /* check for application context id */
    if (ssl->sessionCtxSz > 0) {
        if (XMEMCMP(ssl->sessionCtx, ssl->session->sessionCtx, ssl->sessionCtxSz)) {
            /* context id did not match! */
            WOLFSSL_MSG("Session context did not match");
            return WOLFSSL_FAILURE;
        }
    }
#endif /* OPENSSL_EXTRA */

    if (LowResTimer() < (ssl->session->bornOn + ssl->session->timeout)) {
        ssl->options.resuming = 1;
        ssl->options.haveEMS = ssl->session->haveEMS;

#if defined(SESSION_CERTS) || (defined(WOLFSSL_TLS13) && \
                               defined(HAVE_SESSION_TICKET))
        ssl->version              = ssl->session->version;
        if (IsAtLeastTLSv1_3(ssl->version))
            ssl->options.tls1_3 = 1;
#endif
#if defined(SESSION_CERTS) || !defined(NO_RESUME_SUITE_CHECK) || \
                        (defined(WOLFSSL_TLS13) && defined(HAVE_SESSION_TICKET))
        ssl->options.cipherSuite0 = ssl->session->cipherSuite0;
        ssl->options.cipherSuite  = ssl->session->cipherSuite;
#endif
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
        ssl->peerVerifyRet = (unsigned long)ssl->session->peerVerifyRet;
#endif
        ret = WOLFSSL_SUCCESS;
    }
    else {
#if defined(OPENSSL_EXTRA) && defined(WOLFSSL_ERROR_CODE_OPENSSL)
        WOLFSSL_MSG("Session is expired but return success for \
                              OpenSSL compatibility");
        ret = WOLFSSL_SUCCESS;
#else
        ret = WOLFSSL_FAILURE;  /* session timed out */
#endif /* OPENSSL_EXTRA && WOLFSSL_ERROR_CODE_OPENSSL */
    }
    return ret;
}


#ifdef WOLFSSL_SESSION_STATS
static int get_locked_session_stats(word32* active, word32* total,
                                    word32* peak);
#endif

#ifndef NO_CLIENT_CACHE
ClientSession* AddSessionToClientCache(int side, int row, int idx, byte* serverID,
                            word16 idLen, const byte* sessionID,
                            word16 useTicket)
{
    int error = -1;
    word32 clientRow = 0, clientIdx = 0, sessionIDHash = 0;
    (void)useTicket;
    if (side == WOLFSSL_CLIENT_END
            && row != INVALID_SESSION_ROW
            && (idLen
#ifdef HAVE_SESSION_TICKET
                || useTicket == 1
#endif
                || serverID != NULL
                )) {

        WOLFSSL_MSG("Trying to add client cache entry");

        if (idLen) {
            clientRow = HashObject(serverID,
                    idLen, &error) % CLIENT_SESSION_ROWS;
        }
        else if (serverID != NULL) {
            clientRow = HashObject(sessionID,
                    ID_LEN, &error) % CLIENT_SESSION_ROWS;
        }
        else {
            error = -1;
        }
        if (error == 0 && wc_LockMutex(&clisession_mutex) == 0) {
            clientIdx = ClientCache[clientRow].nextIdx;
            if (clientIdx < CLIENT_SESSIONS_PER_ROW) {
                ClientCache[clientRow].Clients[clientIdx].serverRow =
                                                                (word16)row;
                ClientCache[clientRow].Clients[clientIdx].serverIdx =
                                                                (word16)idx;
                if (sessionID != NULL) {
                    sessionIDHash = HashObject(sessionID, ID_LEN, &error);
                    if (error == 0) {
                        ClientCache[clientRow].Clients[clientIdx].sessionIDHash
                            = sessionIDHash;
                    }
                }
            }
            else {
                error = -1;
                ClientCache[clientRow].nextIdx = 0; /* reset index as saftey */
                WOLFSSL_MSG("Invalid client cache index! "
                            "Possible corrupted memory");
            }
            if (error == 0) {
                WOLFSSL_MSG("Adding client cache entry");
                if (ClientCache[clientRow].totalCount < CLIENT_SESSIONS_PER_ROW)
                    ClientCache[clientRow].totalCount++;
                ClientCache[clientRow].nextIdx++;
                ClientCache[clientRow].nextIdx %= CLIENT_SESSIONS_PER_ROW;
            }

            wc_UnLockMutex(&clisession_mutex);
        }
        else {
            WOLFSSL_MSG("Hash session or lock failed");
            error = -1;
        }
    }
    else {
        WOLFSSL_MSG("Skipping client cache");
    }
    if (error == 0)
        return &ClientCache[clientRow].Clients[clientIdx];
    else
        return NULL;
}
#endif /* !NO_CLIENT_CACHE */

/**
 * For backwards compatibility, this API needs to be used in *ALL* functions
 * that access the WOLFSSL_SESSION members directly.
 *
 * This API checks if the passed in session is actually a ClientSession object
 * and returns the matching session cache object. Otherwise just return the
 * input. ClientSession objects only occur in the ClientCache. They are not
 * allocated anywhere else.
 */
WOLFSSL_SESSION* ClientSessionToSession(const WOLFSSL_SESSION* session)
{
    WOLFSSL_ENTER("ClientSessionToSession");
#ifdef NO_SESSION_CACHE_REF
    return (WOLFSSL_SESSION*)session;
#else
#ifndef NO_CLIENT_CACHE
    if (session == NULL)
        return NULL;
    /* Check if session points into ClientCache */
    if ((byte*)session >= (byte*)ClientCache &&
            /* Cast to byte* to make pointer arithmetic work per byte */
            (byte*)session < ((byte*)ClientCache) + sizeof(ClientCache)) {
        ClientSession* clientSession = (ClientSession*)session;
        SessionRow* sessRow = NULL;
        WOLFSSL_SESSION* cacheSession = NULL;
        word32 sessionIDHash = 0;
        int error = 0;
        session = NULL; /* Default to NULL for failure case */
        if (wc_LockMutex(&clisession_mutex) != 0) {
            WOLFSSL_MSG("Client cache mutex lock failed");
            return NULL;
        }
        if (clientSession->serverRow >= SESSION_ROWS ||
                clientSession->serverIdx >= SESSIONS_PER_ROW) {
            WOLFSSL_MSG("Client cache serverRow or serverIdx invalid");
            error = -1;
        }
        if (error == 0) {
            /* Lock row */
            sessRow = &SessionCache[clientSession->serverRow];
            error = SESSION_ROW_LOCK(sessRow);
            if (error != 0) {
                WOLFSSL_MSG("Session cache row lock failure");
                sessRow = NULL;
            }
        }
        if (error == 0) {
            cacheSession = &sessRow->Sessions[clientSession->serverIdx];
            if (cacheSession->sessionIDSz == 0) {
                cacheSession = NULL;
                WOLFSSL_MSG("Session cache entry not set");
                error = -1;
            }
        }
        if (error == 0) {
            /* Calculate the hash of the session ID */
            sessionIDHash = HashObject(cacheSession->sessionID, ID_LEN,
                    &error);
        }
        if (error == 0) {
            /* Check the session ID hash matches */
            error = clientSession->sessionIDHash != sessionIDHash;
        }
        if (error == 0) {
            /* Hashes match */
            session = cacheSession;
            WOLFSSL_MSG("Found session cache matching client session object");
        }
        if (sessRow != NULL) {
            SESSION_ROW_UNLOCK(sessRow);
        }
        wc_UnLockMutex(&clisession_mutex);
        return (WOLFSSL_SESSION*)session;
    }
    else {
        /* Plain WOLFSSL_SESSION object */
        return (WOLFSSL_SESSION*)session;
    }
#else
    return (WOLFSSL_SESSION*)session;
#endif
#endif
}

int AddSessionToCache(WOLFSSL_CTX* ctx, WOLFSSL_SESSION* addSession,
        const byte* id, byte idSz, int* sessionIndex, int side,
        word16 useTicket, ClientSession** clientCacheEntry)
{
    WOLFSSL_SESSION* cacheSession = NULL;
    SessionRow* sessRow = NULL;
    word32 idx = 0;
#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
    WOLFSSL_X509* peer = NULL;
#endif
#ifdef HAVE_SESSION_TICKET
    byte*  cacheTicBuff = NULL;
    byte   ticBuffUsed = 0;
    byte*  ticBuff = NULL;
    int    ticLen  = 0;
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_TICKET_NONCE_MALLOC) &&          \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
    byte *preallocNonce = NULL;
    byte preallocNonceLen = 0;
    byte preallocNonceUsed = 0;
    byte *toFree = NULL;
#endif /* WOLFSSL_TLS13 && WOLFSSL_TICKET_NONCE_MALLOC */
#endif /* HAVE_SESSION_TICKET */
    int ret = 0;
    int row;
    int i;
    int overwrite = 0;

    (void)ctx;
    (void)sessionIndex;
    (void)useTicket;
    (void)clientCacheEntry;

    if (idSz == 0) {
        WOLFSSL_MSG("AddSessionToCache idSz == 0");
        return BAD_FUNC_ARG;
    }

    addSession = ClientSessionToSession(addSession);
    if (addSession == NULL) {
        WOLFSSL_MSG("AddSessionToCache is NULL");
        return MEMORY_E;
    }

#ifdef HAVE_SESSION_TICKET
    ticLen = addSession->ticketLen;
    /* Alloc Memory here to avoid syscalls during lock */
    if (ticLen > SESSION_TICKET_LEN) {
        ticBuff = (byte*)XMALLOC(ticLen, NULL,
                DYNAMIC_TYPE_SESSION_TICK);
        if (ticBuff == NULL) {
            return MEMORY_E;
        }
    }
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_TICKET_NONCE_MALLOC) &&          \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
    if (addSession->ticketNonce.data != addSession->ticketNonce.dataStatic) {
        /* use the AddSession->heap even if the buffer maybe saved in
         * CachedSession objects. CachedSession heap and AddSession heap should
         * be the same */
        preallocNonce = (byte*)XMALLOC(addSession->ticketNonce.len,
            addSession->heap, DYNAMIC_TYPE_SESSION_TICK);
        if (preallocNonce == NULL) {
            if (ticBuff != NULL)
                XFREE(ticBuff, addSession->heap, DYNAMIC_TYPE_SESSION_TICK);
            return MEMORY_E;
        }
        preallocNonceLen = addSession->ticketNonce.len;
    }
#endif /* WOLFSSL_TLS13 && WOLFSL_TICKET_NONCE_MALLOC && FIPS_VERSION_GE(5,3) */
#endif /* HAVE_SESSION_TICKET */

    /* Find a position for the new session in cache and use that */
    /* Use the session object in the cache for external cache if required */
    row = (int)(HashObject(id, ID_LEN, &ret) % SESSION_ROWS);
    if (ret != 0) {
        WOLFSSL_MSG("Hash session failed");
    #ifdef HAVE_SESSION_TICKET
        XFREE(ticBuff, NULL, DYNAMIC_TYPE_SESSION_TICK);
    #if defined(WOLFSSL_TLS13) && defined(WOLFSSL_TICKE_NONCE_MALLOC)
        if (preallocNonce != NULL)
            XFREE(preallocNonce, addSession->heap, DYNAMIC_TYPE_SESSION_TICK);
    #endif
    #endif
        return ret;
    }

    sessRow = &SessionCache[row];
    if (SESSION_ROW_LOCK(sessRow) != 0) {
    #ifdef HAVE_SESSION_TICKET
        XFREE(ticBuff, NULL, DYNAMIC_TYPE_SESSION_TICK);
    #if defined(WOLFSSL_TLS13) && defined(WOLFSSL_TICKE_NONCE_MALLOC)
        if (preallocNonce != NULL)
            XFREE(preallocNonce, addSession->heap, DYNAMIC_TYPE_SESSION_TICK);
    #endif
    #endif
        WOLFSSL_MSG("Session row lock failed");
        return BAD_MUTEX_E;
    }

    for (i = 0; i < SESSIONS_PER_ROW && i < sessRow->totalCount; i++) {
        if (XMEMCMP(id,
                sessRow->Sessions[i].sessionID, ID_LEN) == 0 &&
                sessRow->Sessions[i].side == side) {
            WOLFSSL_MSG("Session already exists. Overwriting.");
            overwrite = 1;
            idx = i;
            break;
        }
    }

    if (!overwrite)
        idx = sessRow->nextIdx;
#ifdef SESSION_INDEX
    if (sessionIndex != NULL)
        *sessionIndex = (row << SESSIDX_ROW_SHIFT) | idx;
#endif
    cacheSession = &sessRow->Sessions[idx];

#ifdef HAVE_EX_DATA
    if (cacheSession->rem_sess_cb && cacheSession->ownExData) {
        cacheSession->rem_sess_cb(NULL, cacheSession);
        /* Make sure not to call remove functions again */
        cacheSession->ownExData = 0;
        cacheSession->rem_sess_cb = NULL;
    }
#endif

    cacheSession->type = WOLFSSL_SESSION_TYPE_CACHE;
    cacheSession->cacheRow = row;

#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
    /* Save the peer field to free after unlocking the row */
    if (cacheSession->peer != NULL)
        peer = cacheSession->peer;
    cacheSession->peer = NULL;
#endif
#ifdef HAVE_SESSION_TICKET
    /* If we can re-use the existing buffer in cacheSession then we won't touch
     * ticBuff at all making it a very cheap malloc/free. The page on a modern
     * OS will most likely not even be allocated to the process. */
    if (ticBuff != NULL && cacheSession->ticketLenAlloc < ticLen) {
        /* Save pointer only if separately allocated */
        if (cacheSession->ticket != cacheSession->staticTicket)
            cacheTicBuff = cacheSession->ticket;
        ticBuffUsed = 1;
        cacheSession->ticket = ticBuff;
        cacheSession->ticketLenAlloc = (word16) ticLen;
    }
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_TICKET_NONCE_MALLOC) &&          \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
    /* cache entry never used */
    if (cacheSession->ticketNonce.data == NULL)
        cacheSession->ticketNonce.data = cacheSession->ticketNonce.dataStatic;

    if (cacheSession->ticketNonce.data !=
            cacheSession->ticketNonce.dataStatic) {
        toFree = cacheSession->ticketNonce.data;
        cacheSession->ticketNonce.data = cacheSession->ticketNonce.dataStatic;
        cacheSession->ticketNonce.len = 0;
    }
#endif /* WOFLSSL_TLS13 && WOLFSSL_TICKET_NONCE_MALLOC && FIPS_VERSION_GE(5,3)*/
#endif
#ifdef SESSION_CERTS
    if (overwrite &&
            addSession->chain.count == 0 &&
            cacheSession->chain.count > 0) {
        /* Copy in the certs from the session */
        addSession->chain.count = cacheSession->chain.count;
        XMEMCPY(addSession->chain.certs, cacheSession->chain.certs,
                sizeof(x509_buffer) * cacheSession->chain.count);
    }
#endif /* SESSION_CERTS */
    cacheSession->heap = NULL;
    /* Copy data into the cache object */
#if defined(HAVE_SESSION_TICKET) && defined(WOLFSSL_TLS13) &&                  \
    defined(WOLFSSL_TICKET_NONCE_MALLOC) &&                                   \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
    ret = wolfSSL_DupSessionEx(addSession, cacheSession, 1, preallocNonce,
        &preallocNonceLen, &preallocNonceUsed) == WOLFSSL_FAILURE;
#else
    ret = wolfSSL_DupSession(addSession, cacheSession, 1) == WOLFSSL_FAILURE;
#endif /* HAVE_SESSION_TICKET && WOLFSSL_TLS13 && WOLFSSL_TICKET_NONCE_MALLOC
          && FIPS_VERSION_GE(5,3)*/

    if (ret == 0) {
        /* Increment the totalCount and the nextIdx */
        if (sessRow->totalCount < SESSIONS_PER_ROW)
            sessRow->totalCount++;
        sessRow->nextIdx = (sessRow->nextIdx + 1) % SESSIONS_PER_ROW;
        if (id != addSession->sessionID) {
            /* ssl->session->sessionID may contain the bogus ID or we want the
             * ID from the arrays object */
            XMEMCPY(cacheSession->sessionID, id, ID_LEN);
            cacheSession->sessionIDSz = ID_LEN;
        }
#ifdef HAVE_EX_DATA
        if (ctx->rem_sess_cb != NULL) {
            addSession->ownExData = 0;
            cacheSession->ownExData = 1;
            cacheSession->rem_sess_cb = ctx->rem_sess_cb;
        }
#endif
#if defined(HAVE_SESSION_TICKET) && defined(WOLFSSL_TLS13) &&                  \
    defined(WOLFSSL_TICKET_NONCE_MALLOC) &&                                    \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
        if (preallocNonce != NULL && preallocNonceUsed) {
            cacheSession->ticketNonce.data = preallocNonce;
            cacheSession->ticketNonce.len = preallocNonceLen;
            preallocNonce = NULL;
            preallocNonceLen = 0;
        }
#endif /* HAVE_SESSION_TICKET && WOLFSSL_TLS13 && WOLFSSL_TICKET_NONCE_MALLOC
        * && FIPS_VERSION_GE(5,3)*/
    }
#ifdef HAVE_SESSION_TICKET
    else if (ticBuffUsed) {
        /* Error occured. Need to clean up the ticket buffer. */
        cacheSession->ticket = cacheSession->staticTicket;
        cacheSession->ticketLenAlloc = 0;
        cacheSession->ticketLen = 0;
    }
#endif

    SESSION_ROW_UNLOCK(sessRow);
    cacheSession = NULL; /* Can't access after unlocked */

#ifndef NO_CLIENT_CACHE
    if (ret == 0 && clientCacheEntry != NULL) {
        ClientSession* clientCache = AddSessionToClientCache(side, row, idx,
                addSession->serverID, addSession->idLen, id, useTicket);
        if (clientCache != NULL)
            *clientCacheEntry = clientCache;
    }
#endif

#ifdef HAVE_SESSION_TICKET
    if (ticBuff != NULL && !ticBuffUsed)
        XFREE(ticBuff, NULL, DYNAMIC_TYPE_SESSION_TICK);
    if (cacheTicBuff != NULL)
        XFREE(cacheTicBuff, NULL, DYNAMIC_TYPE_SESSION_TICK);
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_TICKET_NONCE_MALLOC) &&         \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
    if (preallocNonce != NULL)
        XFREE(preallocNonce, addSession->heap, DYNAMIC_TYPE_SESSION_TICK);
    if (toFree != NULL)
        XFREE(toFree, addSession->heap, DYNAMIC_TYPE_SESSION_TICK);
#endif /* WOLFSSL_TLS13 && WOLFSSL_TICKET_NONCE_MALLOC && FIPS_VERSION_GE(5,3)*/
#endif

#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
    if (peer != NULL) {
        wolfSSL_X509_free(peer);
        peer = NULL; /* Make sure not use after this point */
    }
#endif

    return ret;
}

#ifndef NO_CLIENT_CACHE
#endif

void AddSession(WOLFSSL* ssl)
{
    int    error = 0;
    const byte* id = NULL;
    byte idSz = 0;
    WOLFSSL_SESSION* session = ssl->session;
#ifdef HAVE_EXT_CACHE
    int cbRet = 0;
#endif

    (void)error;

    WOLFSSL_ENTER("AddSession");

    if (SslSessionCacheOff(ssl, session)) {
        WOLFSSL_MSG("Cache off");
        return;
    }

    if (ssl->options.haveSessionId == 0) {
        WOLFSSL_MSG("Don't have session id");
        return;
    }

#if defined(HAVE_SESSION_TICKET) && !defined(OPENSSL_EXTRA)
    /* For the compat layer generate a session object to use */
    if (ssl->options.side == WOLFSSL_SERVER_END && ssl->options.useTicket == 1) {
        WOLFSSL_MSG("Using tickets instead of cache");
        return;
    }
#endif

    if (session->haveAltSessionID) {
        id = session->altSessionID;
        idSz = ID_LEN;
    }
    else {
        if (!IsAtLeastTLSv1_3(ssl->version) && ssl->arrays != NULL) {
            /* Make sure the session ID is available when the user calls any
             * get_session API */
            XMEMCPY(session->sessionID, ssl->arrays->sessionID, ID_LEN);
            session->sessionIDSz = ssl->arrays->sessionIDSz;
        }
        id = session->sessionID;
        idSz = session->sessionIDSz;
    }

    session->timeout = ssl->timeout;
    session->side = (byte)ssl->options.side;
    if (!IsAtLeastTLSv1_3(ssl->version) && ssl->arrays != NULL)
        XMEMCPY(session->masterSecret, ssl->arrays->masterSecret, SECRET_LEN);
    session->haveEMS = ssl->options.haveEMS;
#ifdef OPENSSL_EXTRA
    /* If using compatibility layer then check for and copy over session context
     * id. */
    if (ssl->sessionCtxSz > 0 && ssl->sessionCtxSz < ID_LEN) {
        XMEMCPY(ssl->session->sessionCtx, ssl->sessionCtx, ssl->sessionCtxSz);
        session->sessionCtxSz = ssl->sessionCtxSz;
    }
#endif
    session->timeout = ssl->timeout;
    session->bornOn  = LowResTimer();
#if defined(SESSION_CERTS) || (defined(WOLFSSL_TLS13) && \
                               defined(HAVE_SESSION_TICKET))
    session->version = ssl->version;
#endif
#if defined(SESSION_CERTS) || !defined(NO_RESUME_SUITE_CHECK) || \
                        (defined(WOLFSSL_TLS13) && defined(HAVE_SESSION_TICKET))
    session->cipherSuite0 = ssl->options.cipherSuite0;
    session->cipherSuite = ssl->options.cipherSuite;
#endif
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
    session->peerVerifyRet = (byte)ssl->peerVerifyRet;
#endif
    /* Do this last so that if it fails, the rest of the session is setup. Do
     * this only for the client because if the server doesn't have an ID at
     * this point, it won't on resumption. */
    if (idSz == 0 && ssl->options.side == WOLFSSL_CLIENT_END) {
        WC_RNG* rng = NULL;
        if (ssl->rng != NULL)
            rng = ssl->rng;
#if defined(HAVE_GLOBAL_RNG) && defined(OPENSSL_EXTRA)
        else if (initGlobalRNG == 1 || wolfSSL_RAND_Init() == WOLFSSL_SUCCESS) {
            rng = &globalRNG;
        }
#endif
        if (wc_RNG_GenerateBlock(rng, ssl->session->altSessionID,
                ID_LEN) != 0)
            return;
        ssl->session->haveAltSessionID = 1;
        id = ssl->session->altSessionID;
        idSz = ID_LEN;
    }
    /* Setup done */

    if (ssl->options.side == WOLFSSL_SERVER_END /* No point in adding a
                                                 * client session */
#ifdef HAVE_EXT_CACHE
            && !ssl->options.internalCacheOff
#endif
            )
    {
        /* Try to add the session to cache. Its ok if we don't succeed. */
        (void)AddSessionToCache(ssl->ctx, session, id, idSz,
#ifdef SESSION_INDEX
                &ssl->sessionIndex,
#else
                NULL,
#endif
                ssl->options.side,
#ifdef HAVE_SESSION_TICKET
                ssl->options.useTicket,
#else
                0,
#endif
                NULL
                );
    }

#ifdef HAVE_EXT_CACHE
    if (error == 0 && ssl->ctx->new_sess_cb != NULL) {
        wolfSSL_SESSION_up_ref(session);
        cbRet = ssl->ctx->new_sess_cb(ssl, session);
        if (cbRet == 0)
            wolfSSL_FreeSession(ssl->ctx, session);
    }
#endif

#if defined(WOLFSSL_SESSION_STATS) && defined(WOLFSSL_PEAK_SESSIONS)
    if (error == 0) {
        word32 active = 0;

        error = get_locked_session_stats(&active, NULL, NULL);
        if (error == WOLFSSL_SUCCESS) {
            error = 0;  /* back to this function ok */

            if (PeakSessions < active) {
                PeakSessions = active;
            }
        }
    }
#endif /* WOLFSSL_SESSION_STATS && WOLFSSL_PEAK_SESSIONS */
    (void)error;
}


#ifdef SESSION_INDEX

int wolfSSL_GetSessionIndex(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_GetSessionIndex");
    WOLFSSL_LEAVE("wolfSSL_GetSessionIndex", ssl->sessionIndex);
    return ssl->sessionIndex;
}


int wolfSSL_GetSessionAtIndex(int idx, WOLFSSL_SESSION* session)
{
    int row, col, result = WOLFSSL_FAILURE;
    SessionRow* sessRow;

    WOLFSSL_ENTER("wolfSSL_GetSessionAtIndex");

    session = ClientSessionToSession(session);

    row = idx >> SESSIDX_ROW_SHIFT;
    col = idx & SESSIDX_IDX_MASK;

    if (session == NULL ||
            row < 0 || row >= SESSION_ROWS || col >= SESSIONS_PER_ROW) {
        return WOLFSSL_FAILURE;
    }

    sessRow = &SessionCache[row];
    if (SESSION_ROW_LOCK(sessRow) != 0) {
        return BAD_MUTEX_E;
    }

    XMEMCPY(session, &sessRow->Sessions[col], sizeof(WOLFSSL_SESSION));
    result = WOLFSSL_SUCCESS;

    SESSION_ROW_UNLOCK(sessRow);

    WOLFSSL_LEAVE("wolfSSL_GetSessionAtIndex", result);
    return result;
}

#endif /* SESSION_INDEX */

#if defined(SESSION_CERTS)

WOLFSSL_X509_CHAIN* wolfSSL_SESSION_get_peer_chain(WOLFSSL_SESSION* session)
{
    WOLFSSL_X509_CHAIN* chain = NULL;

    WOLFSSL_ENTER("wolfSSL_SESSION_get_peer_chain");

    session = ClientSessionToSession(session);

    if (session)
        chain = &session->chain;

    WOLFSSL_LEAVE("wolfSSL_SESSION_get_peer_chain", chain ? 1 : 0);
    return chain;
}


#ifdef OPENSSL_EXTRA
/* gets the peer certificate associated with the session passed in
 * returns null on failure, the caller should not free the returned pointer */
WOLFSSL_X509* wolfSSL_SESSION_get0_peer(WOLFSSL_SESSION* session)
{
    WOLFSSL_ENTER("wolfSSL_SESSION_get_peer_chain");

    session = ClientSessionToSession(session);
    if (session) {
        int count;

        count = wolfSSL_get_chain_count(&session->chain);
        if (count < 1 || count >= MAX_CHAIN_DEPTH) {
            WOLFSSL_MSG("bad count found");
            return NULL;
        }

        if (session->peer == NULL) {
            session->peer = wolfSSL_get_chain_X509(&session->chain, 0);
        }
        return session->peer;
    }
    WOLFSSL_MSG("No session passed in");

    return NULL;
}
#endif /* OPENSSL_EXTRA */
#endif /* SESSION_INDEX && SESSION_CERTS */


#ifdef WOLFSSL_SESSION_STATS

static int get_locked_session_stats(word32* active, word32* total, word32* peak)
{
    int result = WOLFSSL_SUCCESS;
    int i;
    int count;
    int idx;
    word32 now   = 0;
    word32 seen  = 0;
    word32 ticks = LowResTimer();

    WOLFSSL_ENTER("get_locked_session_stats");

#ifndef ENABLE_SESSION_CACHE_ROW_LOCK
    wc_LockMutex(&session_mutex);
#endif
    for (i = 0; i < SESSION_ROWS; i++) {
        SessionRow* row = &SessionCache[i];
    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
        if (SESSION_ROW_LOCK(row) != 0) {
            WOLFSSL_MSG("Session row cache mutex lock failed");
            return BAD_MUTEX_E;
        }
    #endif

        seen += row->totalCount;

        if (active == NULL) {
            SESSION_ROW_UNLOCK(row);
            continue;
        }

        count = min((word32)row->totalCount, SESSIONS_PER_ROW);
        idx   = row->nextIdx - 1;
        if (idx < 0 || idx >= SESSIONS_PER_ROW) {
            idx = SESSIONS_PER_ROW - 1; /* if back to front previous was end */
        }

        for (; count > 0; --count) {
            /* if not expired then good */
            if (ticks < (row->Sessions[idx].bornOn +
                            row->Sessions[idx].timeout) ) {
                now++;
            }

            idx = idx > 0 ? idx - 1 : SESSIONS_PER_ROW - 1;
        }

    #ifdef ENABLE_SESSION_CACHE_ROW_LOCK
        SESSION_ROW_UNLOCK(row);
    #endif
    }
#ifndef ENABLE_SESSION_CACHE_ROW_LOCK
    wc_UnLockMutex(&session_mutex);
#endif

    if (active) {
        *active = now;
    }
    if (total) {
        *total = seen;
    }

#ifdef WOLFSSL_PEAK_SESSIONS
    if (peak) {
        *peak = PeakSessions;
    }
#else
    (void)peak;
#endif

    WOLFSSL_LEAVE("get_locked_session_stats", result);

    return result;
}


/* return WOLFSSL_SUCCESS on ok */
int wolfSSL_get_session_stats(word32* active, word32* total, word32* peak,
                              word32* maxSessions)
{
    int result = WOLFSSL_SUCCESS;

    WOLFSSL_ENTER("wolfSSL_get_session_stats");

    if (maxSessions) {
        *maxSessions = SESSIONS_PER_ROW * SESSION_ROWS;

        if (active == NULL && total == NULL && peak == NULL)
            return result;  /* we're done */
    }

    /* user must provide at least one query value */
    if (active == NULL && total == NULL && peak == NULL) {
        return BAD_FUNC_ARG;
    }

    result = get_locked_session_stats(active, total, peak);

    WOLFSSL_LEAVE("wolfSSL_get_session_stats", result);

    return result;
}

#endif /* WOLFSSL_SESSION_STATS */


    #ifdef PRINT_SESSION_STATS

    /* WOLFSSL_SUCCESS on ok */
    int wolfSSL_PrintSessionStats(void)
    {
        word32 totalSessionsSeen = 0;
        word32 totalSessionsNow = 0;
        word32 peak = 0;
        word32 maxSessions = 0;
        int    i;
        int    ret;
        double E;               /* expected freq */
        double chiSquare = 0;

        ret = wolfSSL_get_session_stats(&totalSessionsNow, &totalSessionsSeen,
                                        &peak, &maxSessions);
        if (ret != WOLFSSL_SUCCESS)
            return ret;
        printf("Total Sessions Seen = %u\n", totalSessionsSeen);
        printf("Total Sessions Now  = %u\n", totalSessionsNow);
#ifdef WOLFSSL_PEAK_SESSIONS
        printf("Peak  Sessions      = %u\n", peak);
#endif
        printf("Max   Sessions      = %u\n", maxSessions);

        E = (double)totalSessionsSeen / SESSION_ROWS;

        for (i = 0; i < SESSION_ROWS; i++) {
            double diff = SessionCache[i].totalCount - E;
            diff *= diff;                /* square    */
            diff /= E;                   /* normalize */

            chiSquare += diff;
        }
        printf("  chi-square = %5.1f, d.f. = %d\n", chiSquare,
                                                     SESSION_ROWS - 1);
        #if (SESSION_ROWS == 11)
            printf(" .05 p value =  18.3, chi-square should be less\n");
        #elif (SESSION_ROWS == 211)
            printf(".05 p value  = 244.8, chi-square should be less\n");
        #elif (SESSION_ROWS == 5981)
            printf(".05 p value  = 6161.0, chi-square should be less\n");
        #elif (SESSION_ROWS == 3)
            printf(".05 p value  =   6.0, chi-square should be less\n");
        #elif (SESSION_ROWS == 2861)
            printf(".05 p value  = 2985.5, chi-square should be less\n");
        #endif
        printf("\n");

        return ret;
    }

    #endif /* SESSION_STATS */

#else  /* NO_SESSION_CACHE */

WOLFSSL_SESSION* ClientSessionToSession(const WOLFSSL_SESSION* session)
{
    return (WOLFSSL_SESSION*)session;
}

/* No session cache version */
WOLFSSL_SESSION* wolfSSL_GetSession(WOLFSSL* ssl, byte* masterSecret,
        byte restoreSessionCerts)
{
    (void)ssl;
    (void)masterSecret;
    (void)restoreSessionCerts;

    return NULL;
}

#endif /* NO_SESSION_CACHE */


/* call before SSL_connect, if verifying will add name check to
   date check and signature check */
WOLFSSL_ABI
int wolfSSL_check_domain_name(WOLFSSL* ssl, const char* dn)
{
    WOLFSSL_ENTER("wolfSSL_check_domain_name");

    if (ssl == NULL || dn == NULL) {
        WOLFSSL_MSG("Bad function argument: NULL");
        return WOLFSSL_FAILURE;
    }

    if (ssl->buffers.domainName.buffer)
        XFREE(ssl->buffers.domainName.buffer, ssl->heap, DYNAMIC_TYPE_DOMAIN);

    ssl->buffers.domainName.length = (word32)XSTRLEN(dn);
    ssl->buffers.domainName.buffer = (byte*)XMALLOC(
            ssl->buffers.domainName.length + 1, ssl->heap, DYNAMIC_TYPE_DOMAIN);

    if (ssl->buffers.domainName.buffer) {
        unsigned char* domainName = ssl->buffers.domainName.buffer;
        XMEMCPY(domainName, dn, ssl->buffers.domainName.length);
        domainName[ssl->buffers.domainName.length] = '\0';
        return WOLFSSL_SUCCESS;
    }
    else {
        ssl->error = MEMORY_ERROR;
        return WOLFSSL_FAILURE;
    }
}


/* turn on wolfSSL zlib compression
   returns WOLFSSL_SUCCESS for success, else error (not built in)
*/
int wolfSSL_set_compression(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_set_compression");
    (void)ssl;
#ifdef HAVE_LIBZ
    ssl->options.usingCompression = 1;
    return WOLFSSL_SUCCESS;
#else
    return NOT_COMPILED_IN;
#endif
}


#ifndef USE_WINDOWS_API
    #ifndef NO_WRITEV

        /* simulate writev semantics, doesn't actually do block at a time though
           because of SSL_write behavior and because front adds may be small */
        int wolfSSL_writev(WOLFSSL* ssl, const struct iovec* iov, int iovcnt)
        {
        #ifdef WOLFSSL_SMALL_STACK
            byte   staticBuffer[1]; /* force heap usage */
        #else
            byte   staticBuffer[FILE_BUFFER_SIZE];
        #endif
            byte* myBuffer  = staticBuffer;
            int   dynamic   = 0;
            int   sending   = 0;
            int   idx       = 0;
            int   i;
            int   ret;

            WOLFSSL_ENTER("wolfSSL_writev");

            for (i = 0; i < iovcnt; i++)
                sending += (int)iov[i].iov_len;

            if (sending > (int)sizeof(staticBuffer)) {
                myBuffer = (byte*)XMALLOC(sending, ssl->heap,
                                                           DYNAMIC_TYPE_WRITEV);
                if (!myBuffer)
                    return MEMORY_ERROR;

                dynamic = 1;
            }

            for (i = 0; i < iovcnt; i++) {
                XMEMCPY(&myBuffer[idx], iov[i].iov_base, iov[i].iov_len);
                idx += (int)iov[i].iov_len;
            }

           /* myBuffer may not be initialized fully, but the span up to the
            * sending length will be.
            */
            PRAGMA_GCC_DIAG_PUSH;
            PRAGMA_GCC("GCC diagnostic ignored \"-Wmaybe-uninitialized\"");
            ret = wolfSSL_write(ssl, myBuffer, sending);
            PRAGMA_GCC_DIAG_POP;

            if (dynamic)
                XFREE(myBuffer, ssl->heap, DYNAMIC_TYPE_WRITEV);

            return ret;
        }
    #endif
#endif


#ifdef WOLFSSL_CALLBACKS

    typedef struct itimerval Itimerval;

    /* don't keep calling simple functions while setting up timer and signals
       if no inlining these are the next best */

    #define AddTimes(a, b, c)                       \
        do {                                        \
            (c).tv_sec  = (a).tv_sec + (b).tv_sec;  \
            (c).tv_usec = (a).tv_usec + (b).tv_usec;\
            if ((c).tv_usec >=  1000000) {          \
                (c).tv_sec++;                       \
                (c).tv_usec -= 1000000;             \
            }                                       \
        } while (0)


    #define SubtractTimes(a, b, c)                  \
        do {                                        \
            (c).tv_sec  = (a).tv_sec - (b).tv_sec;  \
            (c).tv_usec = (a).tv_usec - (b).tv_usec;\
            if ((c).tv_usec < 0) {                  \
                (c).tv_sec--;                       \
                (c).tv_usec += 1000000;             \
            }                                       \
        } while (0)

    #define CmpTimes(a, b, cmp)                     \
        (((a).tv_sec  ==  (b).tv_sec) ?             \
            ((a).tv_usec cmp (b).tv_usec) :         \
            ((a).tv_sec  cmp (b).tv_sec))           \


    /* do nothing handler */
    static void myHandler(int signo)
    {
        (void)signo;
        return;
    }


    static int wolfSSL_ex_wrapper(WOLFSSL* ssl, HandShakeCallBack hsCb,
                                 TimeoutCallBack toCb, WOLFSSL_TIMEVAL timeout)
    {
        int       ret        = WOLFSSL_FATAL_ERROR;
        int       oldTimerOn = 0;   /* was timer already on */
        WOLFSSL_TIMEVAL startTime;
        WOLFSSL_TIMEVAL endTime;
        WOLFSSL_TIMEVAL totalTime;
        Itimerval myTimeout;
        Itimerval oldTimeout; /* if old timer adjust from total time to reset */
        struct sigaction act, oact;

        #define ERR_OUT(x) { ssl->hsInfoOn = 0; ssl->toInfoOn = 0; return x; }

        if (hsCb) {
            ssl->hsInfoOn = 1;
            InitHandShakeInfo(&ssl->handShakeInfo, ssl);
        }
        if (toCb) {
            ssl->toInfoOn = 1;
            InitTimeoutInfo(&ssl->timeoutInfo);

            if (gettimeofday(&startTime, 0) < 0)
                ERR_OUT(GETTIME_ERROR);

            /* use setitimer to simulate getitimer, init 0 myTimeout */
            myTimeout.it_interval.tv_sec  = 0;
            myTimeout.it_interval.tv_usec = 0;
            myTimeout.it_value.tv_sec     = 0;
            myTimeout.it_value.tv_usec    = 0;
            if (setitimer(ITIMER_REAL, &myTimeout, &oldTimeout) < 0)
                ERR_OUT(SETITIMER_ERROR);

            if (oldTimeout.it_value.tv_sec || oldTimeout.it_value.tv_usec) {
                oldTimerOn = 1;

                /* is old timer going to expire before ours */
                if (CmpTimes(oldTimeout.it_value, timeout, <)) {
                    timeout.tv_sec  = oldTimeout.it_value.tv_sec;
                    timeout.tv_usec = oldTimeout.it_value.tv_usec;
                }
            }
            myTimeout.it_value.tv_sec  = timeout.tv_sec;
            myTimeout.it_value.tv_usec = timeout.tv_usec;

            /* set up signal handler, don't restart socket send/recv */
            act.sa_handler = myHandler;
            sigemptyset(&act.sa_mask);
            act.sa_flags = 0;
#ifdef SA_INTERRUPT
            act.sa_flags |= SA_INTERRUPT;
#endif
            if (sigaction(SIGALRM, &act, &oact) < 0)
                ERR_OUT(SIGACT_ERROR);

            if (setitimer(ITIMER_REAL, &myTimeout, 0) < 0)
                ERR_OUT(SETITIMER_ERROR);
        }

        /* do main work */
#ifndef NO_WOLFSSL_CLIENT
        if (ssl->options.side == WOLFSSL_CLIENT_END)
            ret = wolfSSL_connect(ssl);
#endif
#ifndef NO_WOLFSSL_SERVER
        if (ssl->options.side == WOLFSSL_SERVER_END)
            ret = wolfSSL_accept(ssl);
#endif

        /* do callbacks */
        if (toCb) {
            if (oldTimerOn) {
                if (gettimeofday(&endTime, 0) < 0)
                    ERR_OUT(SYSLIB_FAILED_E);
                SubtractTimes(endTime, startTime, totalTime);
                /* adjust old timer for elapsed time */
                if (CmpTimes(totalTime, oldTimeout.it_value, <))
                    SubtractTimes(oldTimeout.it_value, totalTime,
                                  oldTimeout.it_value);
                else {
                    /* reset value to interval, may be off */
                    oldTimeout.it_value.tv_sec = oldTimeout.it_interval.tv_sec;
                    oldTimeout.it_value.tv_usec =oldTimeout.it_interval.tv_usec;
                }
                /* keep iter the same whether there or not */
            }
            /* restore old handler */
            if (sigaction(SIGALRM, &oact, 0) < 0)
                ret = SIGACT_ERROR;    /* more pressing error, stomp */
            else
                /* use old settings which may turn off (expired or not there) */
                if (setitimer(ITIMER_REAL, &oldTimeout, 0) < 0)
                    ret = SETITIMER_ERROR;

            /* if we had a timeout call callback */
            if (ssl->timeoutInfo.timeoutName[0]) {
                ssl->timeoutInfo.timeoutValue.tv_sec  = timeout.tv_sec;
                ssl->timeoutInfo.timeoutValue.tv_usec = timeout.tv_usec;
                (toCb)(&ssl->timeoutInfo);
            }
            ssl->toInfoOn = 0;
        }

        /* clean up buffers allocated by AddPacketInfo */
        FreeTimeoutInfo(&ssl->timeoutInfo, ssl->heap);

        if (hsCb) {
            FinishHandShakeInfo(&ssl->handShakeInfo);
            (hsCb)(&ssl->handShakeInfo);
            ssl->hsInfoOn = 0;
        }
        return ret;
    }


#ifndef NO_WOLFSSL_CLIENT

    int wolfSSL_connect_ex(WOLFSSL* ssl, HandShakeCallBack hsCb,
                          TimeoutCallBack toCb, WOLFSSL_TIMEVAL timeout)
    {
        WOLFSSL_ENTER("wolfSSL_connect_ex");
        return wolfSSL_ex_wrapper(ssl, hsCb, toCb, timeout);
    }

#endif


#ifndef NO_WOLFSSL_SERVER

    int wolfSSL_accept_ex(WOLFSSL* ssl, HandShakeCallBack hsCb,
                         TimeoutCallBack toCb, WOLFSSL_TIMEVAL timeout)
    {
        WOLFSSL_ENTER("wolfSSL_accept_ex");
        return wolfSSL_ex_wrapper(ssl, hsCb, toCb, timeout);
    }

#endif

#endif /* WOLFSSL_CALLBACKS */


#ifndef NO_PSK

    void wolfSSL_CTX_set_psk_client_callback(WOLFSSL_CTX* ctx,
                                         wc_psk_client_callback cb)
    {
        WOLFSSL_ENTER("SSL_CTX_set_psk_client_callback");

        if (ctx == NULL)
            return;

        ctx->havePSK = 1;
        ctx->client_psk_cb = cb;
    }

    void wolfSSL_set_psk_client_callback(WOLFSSL* ssl,wc_psk_client_callback cb)
    {
        byte haveRSA = 1;
        int  keySz   = 0;

        WOLFSSL_ENTER("SSL_set_psk_client_callback");

        if (ssl == NULL)
            return;

        ssl->options.havePSK = 1;
        ssl->options.client_psk_cb = cb;

        #ifdef NO_RSA
            haveRSA = 0;
        #endif
        #ifndef NO_CERTS
            keySz = ssl->buffers.keySz;
        #endif
        InitSuites(ssl->suites, ssl->version, keySz, haveRSA, TRUE,
                   ssl->options.haveDH, ssl->options.haveECDSAsig,
                   ssl->options.haveECC, TRUE, ssl->options.haveStaticECC,
                   ssl->options.haveFalconSig, ssl->options.haveDilithiumSig,
                   ssl->options.haveAnon, TRUE, ssl->options.side);
    }
    #ifdef OPENSSL_EXTRA
    /**
     * set call back function for psk session use
     * @param ssl  a pointer to WOLFSSL structure
     * @param cb   a function pointer to wc_psk_use_session_cb
     * @return none
     */
    void wolfSSL_set_psk_use_session_callback(WOLFSSL* ssl,
                                                wc_psk_use_session_cb_func cb)
    {
        WOLFSSL_ENTER("wolfSSL_set_psk_use_session_callback");

        ssl->options.havePSK = 1;
        ssl->options.session_psk_cb = cb;

        WOLFSSL_LEAVE("wolfSSL_set_psk_use_session_callback", WOLFSSL_SUCCESS);
    }
    #endif

    void wolfSSL_CTX_set_psk_server_callback(WOLFSSL_CTX* ctx,
                                         wc_psk_server_callback cb)
    {
        WOLFSSL_ENTER("SSL_CTX_set_psk_server_callback");
        if (ctx == NULL)
            return;
        ctx->havePSK = 1;
        ctx->server_psk_cb = cb;
    }

    void wolfSSL_set_psk_server_callback(WOLFSSL* ssl,wc_psk_server_callback cb)
    {
        byte haveRSA = 1;
        int  keySz   = 0;

        WOLFSSL_ENTER("SSL_set_psk_server_callback");
        if (ssl == NULL)
            return;

        ssl->options.havePSK = 1;
        ssl->options.server_psk_cb = cb;

        #ifdef NO_RSA
            haveRSA = 0;
        #endif
        #ifndef NO_CERTS
            keySz = ssl->buffers.keySz;
        #endif
        InitSuites(ssl->suites, ssl->version, keySz, haveRSA, TRUE,
                   ssl->options.haveDH, ssl->options.haveECDSAsig,
                   ssl->options.haveECC, TRUE, ssl->options.haveStaticECC,
                   ssl->options.haveFalconSig, ssl->options.haveDilithiumSig,
                   ssl->options.haveAnon, TRUE, ssl->options.side);
    }

    const char* wolfSSL_get_psk_identity_hint(const WOLFSSL* ssl)
    {
        WOLFSSL_ENTER("SSL_get_psk_identity_hint");

        if (ssl == NULL || ssl->arrays == NULL)
            return NULL;

        return ssl->arrays->server_hint;
    }


    const char* wolfSSL_get_psk_identity(const WOLFSSL* ssl)
    {
        WOLFSSL_ENTER("SSL_get_psk_identity");

        if (ssl == NULL || ssl->arrays == NULL)
            return NULL;

        return ssl->arrays->client_identity;
    }

    int wolfSSL_CTX_use_psk_identity_hint(WOLFSSL_CTX* ctx, const char* hint)
    {
        WOLFSSL_ENTER("SSL_CTX_use_psk_identity_hint");
        if (hint == 0)
            ctx->server_hint[0] = '\0';
        else {
            /* Qt does not call CTX_set_*_psk_callbacks where havePSK is set */
            #ifdef WOLFSSL_QT
            ctx->havePSK=1;
            #endif
            XSTRNCPY(ctx->server_hint, hint, MAX_PSK_ID_LEN);
            ctx->server_hint[MAX_PSK_ID_LEN] = '\0'; /* null term */
        }
        return WOLFSSL_SUCCESS;
    }

    int wolfSSL_use_psk_identity_hint(WOLFSSL* ssl, const char* hint)
    {
        WOLFSSL_ENTER("SSL_use_psk_identity_hint");

        if (ssl == NULL || ssl->arrays == NULL)
            return WOLFSSL_FAILURE;

        if (hint == 0)
            ssl->arrays->server_hint[0] = 0;
        else {
            XSTRNCPY(ssl->arrays->server_hint, hint,
                                            sizeof(ssl->arrays->server_hint)-1);
            ssl->arrays->server_hint[sizeof(ssl->arrays->server_hint)-1] = '\0';
        }
        return WOLFSSL_SUCCESS;
    }

    void* wolfSSL_get_psk_callback_ctx(WOLFSSL* ssl)
    {
        return ssl ? ssl->options.psk_ctx : NULL;
    }
    void* wolfSSL_CTX_get_psk_callback_ctx(WOLFSSL_CTX* ctx)
    {
        return ctx ? ctx->psk_ctx : NULL;
    }
    int wolfSSL_set_psk_callback_ctx(WOLFSSL* ssl, void* psk_ctx)
    {
        if (ssl == NULL)
            return WOLFSSL_FAILURE;
        ssl->options.psk_ctx = psk_ctx;
        return WOLFSSL_SUCCESS;
    }
    int wolfSSL_CTX_set_psk_callback_ctx(WOLFSSL_CTX* ctx, void* psk_ctx)
    {
        if (ctx == NULL)
            return WOLFSSL_FAILURE;
        ctx->psk_ctx = psk_ctx;
        return WOLFSSL_SUCCESS;
    }
#endif /* NO_PSK */


#ifdef HAVE_ANON

    int wolfSSL_CTX_allow_anon_cipher(WOLFSSL_CTX* ctx)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_allow_anon_cipher");

        if (ctx == NULL)
            return WOLFSSL_FAILURE;

        ctx->haveAnon = 1;

        return WOLFSSL_SUCCESS;
    }

#endif /* HAVE_ANON */


#ifndef NO_CERTS
/* used to be defined on NO_FILESYSTEM only, but are generally useful */

    int wolfSSL_CTX_load_verify_buffer_ex(WOLFSSL_CTX* ctx,
                                         const unsigned char* in,
                                         long sz, int format, int userChain,
                                         word32 flags)
    {
        int verify;
        int ret = WOLFSSL_FAILURE;

        WOLFSSL_ENTER("wolfSSL_CTX_load_verify_buffer_ex");

        verify = GET_VERIFY_SETTING_CTX(ctx);
        if (flags & WOLFSSL_LOAD_FLAG_DATE_ERR_OKAY)
            verify = VERIFY_SKIP_DATE;

        if (format == WOLFSSL_FILETYPE_PEM)
            ret = ProcessChainBuffer(ctx, in, sz, format, CA_TYPE, NULL,
                                      verify);
        else
            ret = ProcessBuffer(ctx, in, sz, format, CA_TYPE, NULL, NULL,
                                 userChain, verify);
#if defined(WOLFSSL_TRUST_PEER_CERT) && defined(OPENSSL_COMPATIBLE_DEFAULTS)
        if (ret == WOLFSSL_SUCCESS)
            ret = wolfSSL_CTX_trust_peer_buffer(ctx, in, sz, format);
#endif

        WOLFSSL_LEAVE("wolfSSL_CTX_load_verify_buffer_ex", ret);
        return ret;
    }

    /* wolfSSL extension allows DER files to be loaded from buffers as well */
    int wolfSSL_CTX_load_verify_buffer(WOLFSSL_CTX* ctx,
                                       const unsigned char* in,
                                       long sz, int format)
    {
        return wolfSSL_CTX_load_verify_buffer_ex(ctx, in, sz, format, 0,
            WOLFSSL_LOAD_VERIFY_DEFAULT_FLAGS);
    }

    int wolfSSL_CTX_load_verify_chain_buffer_format(WOLFSSL_CTX* ctx,
                                       const unsigned char* in,
                                       long sz, int format)
    {
        return wolfSSL_CTX_load_verify_buffer_ex(ctx, in, sz, format, 1,
            WOLFSSL_LOAD_VERIFY_DEFAULT_FLAGS);
    }


#ifdef WOLFSSL_TRUST_PEER_CERT
    int wolfSSL_CTX_trust_peer_buffer(WOLFSSL_CTX* ctx,
                                       const unsigned char* in,
                                       long sz, int format)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_trust_peer_buffer");

        /* sanity check on arguments */
        if (sz < 0 || in == NULL || ctx == NULL) {
            return BAD_FUNC_ARG;
        }

        if (format == WOLFSSL_FILETYPE_PEM)
            return ProcessChainBuffer(ctx, in, sz, format, TRUSTED_PEER_TYPE,
                                      NULL, GET_VERIFY_SETTING_CTX(ctx));
        else
            return ProcessBuffer(ctx, in, sz, format, TRUSTED_PEER_TYPE, NULL,
                                 NULL, 0, GET_VERIFY_SETTING_CTX(ctx));
    }
#endif /* WOLFSSL_TRUST_PEER_CERT */


    int wolfSSL_CTX_use_certificate_buffer(WOLFSSL_CTX* ctx,
                                 const unsigned char* in, long sz, int format)
    {
        int ret = WOLFSSL_FAILURE;

        WOLFSSL_ENTER("wolfSSL_CTX_use_certificate_buffer");
        ret = ProcessBuffer(ctx, in, sz, format, CERT_TYPE, NULL, NULL, 0,
                             GET_VERIFY_SETTING_CTX(ctx));
        WOLFSSL_LEAVE("wolfSSL_CTX_use_certificate_buffer", ret);
        return ret;
    }


    int wolfSSL_CTX_use_PrivateKey_buffer(WOLFSSL_CTX* ctx,
                                 const unsigned char* in, long sz, int format)
    {
        int ret = WOLFSSL_FAILURE;

        WOLFSSL_ENTER("wolfSSL_CTX_use_PrivateKey_buffer");
        ret = ProcessBuffer(ctx, in, sz, format, PRIVATEKEY_TYPE, NULL, NULL,
                             0, GET_VERIFY_SETTING_CTX(ctx));
        WOLFSSL_LEAVE("wolfSSL_CTX_use_PrivateKey_buffer", ret);
        return ret;
    }

#ifdef WOLF_PRIVATE_KEY_ID
    int wolfSSL_CTX_use_PrivateKey_id(WOLFSSL_CTX* ctx, const unsigned char* id,
                                      long sz, int devId, long keySz)
    {
        int ret = wolfSSL_CTX_use_PrivateKey_Id(ctx, id, sz, devId);

        if (ret == WOLFSSL_SUCCESS)
            ctx->privateKeySz = (word32)keySz;

        return ret;
    }

    int wolfSSL_CTX_use_PrivateKey_Id(WOLFSSL_CTX* ctx, const unsigned char* id,
                                      long sz, int devId)
    {
        int ret = WOLFSSL_FAILURE;

        FreeDer(&ctx->privateKey);
        if (AllocDer(&ctx->privateKey, (word32)sz, PRIVATEKEY_TYPE,
                                                              ctx->heap) == 0) {
            XMEMCPY(ctx->privateKey->buffer, id, sz);
            ctx->privateKeyId = 1;
            if (devId != INVALID_DEVID)
                ctx->privateKeyDevId = devId;
            else
                ctx->privateKeyDevId = ctx->devId;

            ret = WOLFSSL_SUCCESS;
        }

        return ret;
    }

    int wolfSSL_CTX_use_PrivateKey_Label(WOLFSSL_CTX* ctx, const char* label,
                                         int devId)
    {
        int ret = WOLFSSL_FAILURE;
        word32 sz = (word32)XSTRLEN(label) + 1;

        FreeDer(&ctx->privateKey);
        if (AllocDer(&ctx->privateKey, (word32)sz, PRIVATEKEY_TYPE,
                                                              ctx->heap) == 0) {
            XMEMCPY(ctx->privateKey->buffer, label, sz);
            ctx->privateKeyLabel = 1;
            if (devId != INVALID_DEVID)
                ctx->privateKeyDevId = devId;
            else
                ctx->privateKeyDevId = ctx->devId;

            ret = WOLFSSL_SUCCESS;
        }

        return ret;
    }
#endif /* WOLF_PRIVATE_KEY_ID */

    int wolfSSL_CTX_use_certificate_chain_buffer_format(WOLFSSL_CTX* ctx,
                                 const unsigned char* in, long sz, int format)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_use_certificate_chain_buffer_format");
        return ProcessBuffer(ctx, in, sz, format, CERT_TYPE, NULL, NULL, 1,
                             GET_VERIFY_SETTING_CTX(ctx));
    }

    int wolfSSL_CTX_use_certificate_chain_buffer(WOLFSSL_CTX* ctx,
                                 const unsigned char* in, long sz)
    {
        return wolfSSL_CTX_use_certificate_chain_buffer_format(ctx, in, sz,
                                                            WOLFSSL_FILETYPE_PEM);
    }


#ifndef NO_DH

    /* server wrapper for ctx or ssl Diffie-Hellman parameters */
    static int wolfSSL_SetTmpDH_buffer_wrapper(WOLFSSL_CTX* ctx, WOLFSSL* ssl,
                                               const unsigned char* buf,
                                               long sz, int format)
    {
        DerBuffer* der = NULL;
        int    ret      = 0;
        word32 pSz = MAX_DH_SIZE;
        word32 gSz = MAX_DH_SIZE;
    #ifdef WOLFSSL_SMALL_STACK
        byte*  p = NULL;
        byte*  g = NULL;
    #else
        byte   p[MAX_DH_SIZE];
        byte   g[MAX_DH_SIZE];
    #endif

        if (ctx == NULL || buf == NULL)
            return BAD_FUNC_ARG;

        ret = AllocDer(&der, 0, DH_PARAM_TYPE, ctx->heap);
        if (ret != 0) {
            return ret;
        }
        der->buffer = (byte*)buf;
        der->length = (word32)sz;

    #ifdef WOLFSSL_SMALL_STACK
        p = (byte*)XMALLOC(pSz, NULL, DYNAMIC_TYPE_PUBLIC_KEY);
        g = (byte*)XMALLOC(gSz, NULL, DYNAMIC_TYPE_PUBLIC_KEY);

        if (p == NULL || g == NULL) {
            XFREE(p, NULL, DYNAMIC_TYPE_PUBLIC_KEY);
            XFREE(g, NULL, DYNAMIC_TYPE_PUBLIC_KEY);
            return MEMORY_E;
        }
    #endif

        if (format != WOLFSSL_FILETYPE_ASN1 && format != WOLFSSL_FILETYPE_PEM)
            ret = WOLFSSL_BAD_FILETYPE;
        else {
            if (format == WOLFSSL_FILETYPE_PEM) {
#ifdef WOLFSSL_PEM_TO_DER
                FreeDer(&der);
                ret = PemToDer(buf, sz, DH_PARAM_TYPE, &der, ctx->heap,
                               NULL, NULL);
                if (ret < 0) {
                    /* Also try X9.42 format */
                    ret = PemToDer(buf, sz, X942_PARAM_TYPE, &der, ctx->heap,
                               NULL, NULL);
                }
    #ifdef WOLFSSL_WPAS
        #ifndef NO_DSA
                if (ret < 0) {
                    ret = PemToDer(buf, sz, DSA_PARAM_TYPE, &der, ctx->heap,
                               NULL, NULL);
                }
        #endif
    #endif /* WOLFSSL_WPAS */
#else
                ret = NOT_COMPILED_IN;
#endif /* WOLFSSL_PEM_TO_DER */
            }

            if (ret == 0) {
                if (wc_DhParamsLoad(der->buffer, der->length, p, &pSz, g, &gSz) < 0)
                    ret = WOLFSSL_BAD_FILETYPE;
                else if (ssl)
                    ret = wolfSSL_SetTmpDH(ssl, p, pSz, g, gSz);
                else
                    ret = wolfSSL_CTX_SetTmpDH(ctx, p, pSz, g, gSz);
            }
        }

        FreeDer(&der);

    #ifdef WOLFSSL_SMALL_STACK
        XFREE(p, NULL, DYNAMIC_TYPE_PUBLIC_KEY);
        XFREE(g, NULL, DYNAMIC_TYPE_PUBLIC_KEY);
    #endif

        return ret;
    }


    /* server Diffie-Hellman parameters, WOLFSSL_SUCCESS on ok */
    int wolfSSL_SetTmpDH_buffer(WOLFSSL* ssl, const unsigned char* buf, long sz,
                               int format)
    {
        if (ssl == NULL)
            return BAD_FUNC_ARG;

        return wolfSSL_SetTmpDH_buffer_wrapper(ssl->ctx, ssl, buf, sz, format);
    }


    /* server ctx Diffie-Hellman parameters, WOLFSSL_SUCCESS on ok */
    int wolfSSL_CTX_SetTmpDH_buffer(WOLFSSL_CTX* ctx, const unsigned char* buf,
                                   long sz, int format)
    {
        return wolfSSL_SetTmpDH_buffer_wrapper(ctx, NULL, buf, sz, format);
    }

#endif /* NO_DH */


    int wolfSSL_use_certificate_buffer(WOLFSSL* ssl,
                                 const unsigned char* in, long sz, int format)
    {
        WOLFSSL_ENTER("wolfSSL_use_certificate_buffer");
        if (ssl == NULL)
            return BAD_FUNC_ARG;

        return ProcessBuffer(ssl->ctx, in, sz, format, CERT_TYPE, ssl, NULL, 0,
                             GET_VERIFY_SETTING_SSL(ssl));
    }


    int wolfSSL_use_PrivateKey_buffer(WOLFSSL* ssl,
                                 const unsigned char* in, long sz, int format)
    {
        WOLFSSL_ENTER("wolfSSL_use_PrivateKey_buffer");
        if (ssl == NULL)
            return BAD_FUNC_ARG;

        return ProcessBuffer(ssl->ctx, in, sz, format, PRIVATEKEY_TYPE,
                             ssl, NULL, 0, GET_VERIFY_SETTING_SSL(ssl));
    }

#ifdef WOLF_PRIVATE_KEY_ID
    int wolfSSL_use_PrivateKey_id(WOLFSSL* ssl, const unsigned char* id,
                                  long sz, int devId, long keySz)
    {
        int ret = wolfSSL_use_PrivateKey_Id(ssl, id, sz, devId);

        if (ret == WOLFSSL_SUCCESS)
            ssl->buffers.keySz = (word32)keySz;

        return ret;
    }

    int wolfSSL_use_PrivateKey_Id(WOLFSSL* ssl, const unsigned char* id,
                                  long sz, int devId)
    {
        int ret = WOLFSSL_FAILURE;

        if (ssl->buffers.weOwnKey)
            FreeDer(&ssl->buffers.key);
        if (AllocDer(&ssl->buffers.key, (word32)sz, PRIVATEKEY_TYPE,
                                                            ssl->heap) == 0) {
            XMEMCPY(ssl->buffers.key->buffer, id, sz);
            ssl->buffers.weOwnKey = 1;
            ssl->buffers.keyId = 1;
            if (devId != INVALID_DEVID)
                ssl->buffers.keyDevId = devId;
            else
                ssl->buffers.keyDevId = ssl->devId;

            ret = WOLFSSL_SUCCESS;
        }

        return ret;
    }

    int wolfSSL_use_PrivateKey_Label(WOLFSSL* ssl, const char* label, int devId)
    {
        int ret = WOLFSSL_FAILURE;
        word32 sz = (word32)XSTRLEN(label) + 1;

        if (ssl->buffers.weOwnKey)
            FreeDer(&ssl->buffers.key);
        if (AllocDer(&ssl->buffers.key, (word32)sz, PRIVATEKEY_TYPE,
                                                            ssl->heap) == 0) {
            XMEMCPY(ssl->buffers.key->buffer, label, sz);
            ssl->buffers.weOwnKey = 1;
            ssl->buffers.keyLabel = 1;
            if (devId != INVALID_DEVID)
                ssl->buffers.keyDevId = devId;
            else
                ssl->buffers.keyDevId = ssl->devId;

            ret = WOLFSSL_SUCCESS;
        }

        return ret;
    }
#endif /* WOLF_PRIVATE_KEY_ID */

    int wolfSSL_use_certificate_chain_buffer_format(WOLFSSL* ssl,
                                 const unsigned char* in, long sz, int format)
    {
        WOLFSSL_ENTER("wolfSSL_use_certificate_chain_buffer_format");
        if (ssl == NULL)
            return BAD_FUNC_ARG;

        return ProcessBuffer(ssl->ctx, in, sz, format, CERT_TYPE,
                             ssl, NULL, 1, GET_VERIFY_SETTING_SSL(ssl));
    }

    int wolfSSL_use_certificate_chain_buffer(WOLFSSL* ssl,
                                 const unsigned char* in, long sz)
    {
        return wolfSSL_use_certificate_chain_buffer_format(ssl, in, sz,
                                                            WOLFSSL_FILETYPE_PEM);
    }


    /* unload any certs or keys that SSL owns, leave CTX as is
       WOLFSSL_SUCCESS on ok */
    int wolfSSL_UnloadCertsKeys(WOLFSSL* ssl)
    {
        if (ssl == NULL) {
            WOLFSSL_MSG("Null function arg");
            return BAD_FUNC_ARG;
        }

        if (ssl->buffers.weOwnCert && !ssl->keepCert) {
            WOLFSSL_MSG("Unloading cert");
            FreeDer(&ssl->buffers.certificate);
            #ifdef KEEP_OUR_CERT
            wolfSSL_X509_free(ssl->ourCert);
            ssl->ourCert = NULL;
            #endif
            ssl->buffers.weOwnCert = 0;
        }

        if (ssl->buffers.weOwnCertChain) {
            WOLFSSL_MSG("Unloading cert chain");
            FreeDer(&ssl->buffers.certChain);
            ssl->buffers.weOwnCertChain = 0;
        }

        if (ssl->buffers.weOwnKey) {
            WOLFSSL_MSG("Unloading key");
            ForceZero(ssl->buffers.key->buffer, ssl->buffers.key->length);
            FreeDer(&ssl->buffers.key);
            ssl->buffers.weOwnKey = 0;
        }

        return WOLFSSL_SUCCESS;
    }


    int wolfSSL_CTX_UnloadCAs(WOLFSSL_CTX* ctx)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_UnloadCAs");

        if (ctx == NULL)
            return BAD_FUNC_ARG;

        return wolfSSL_CertManagerUnloadCAs(ctx->cm);
    }


#ifdef WOLFSSL_TRUST_PEER_CERT
    int wolfSSL_CTX_Unload_trust_peers(WOLFSSL_CTX* ctx)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_Unload_trust_peers");

        if (ctx == NULL)
            return BAD_FUNC_ARG;

        return wolfSSL_CertManagerUnload_trust_peers(ctx->cm);
    }

#ifdef WOLFSSL_LOCAL_X509_STORE
    int wolfSSL_Unload_trust_peers(WOLFSSL* ssl)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_Unload_trust_peers");

        if (ssl == NULL)
            return BAD_FUNC_ARG;

        return wolfSSL_CertManagerUnload_trust_peers(SSL_CM(ssl));
    }
#endif /* WOLFSSL_LOCAL_X509_STORE */
#endif /* WOLFSSL_TRUST_PEER_CERT */
/* old NO_FILESYSTEM end */
#endif /* !NO_CERTS */


#ifdef OPENSSL_EXTRA

    int wolfSSL_add_all_algorithms(void)
    {
        WOLFSSL_ENTER("wolfSSL_add_all_algorithms");
        if (initRefCount != 0 || wolfSSL_Init() == WOLFSSL_SUCCESS)
            return WOLFSSL_SUCCESS;
        else
            return WOLFSSL_FATAL_ERROR;
    }

    int wolfSSL_OpenSSL_add_all_algorithms_noconf(void)
    {
        WOLFSSL_ENTER("wolfSSL_OpenSSL_add_all_algorithms_noconf");

        if  (wolfSSL_add_all_algorithms() == WOLFSSL_FATAL_ERROR)
            return WOLFSSL_FATAL_ERROR;

        return  WOLFSSL_SUCCESS;
    }

    int wolfSSL_OpenSSL_add_all_algorithms_conf(void)
    {
        WOLFSSL_ENTER("wolfSSL_OpenSSL_add_all_algorithms_conf");
        /* This function is currently the same as
        wolfSSL_OpenSSL_add_all_algorithms_noconf since we do not employ
        the use of a wolfssl.cnf type configuration file and is only used for
        OpenSSL compatability. */

        if (wolfSSL_add_all_algorithms() == WOLFSSL_FATAL_ERROR) {
            return WOLFSSL_FATAL_ERROR;
        }
        return WOLFSSL_SUCCESS;
    }

   /* returns previous set cache size which stays constant */
    long wolfSSL_CTX_sess_set_cache_size(WOLFSSL_CTX* ctx, long sz)
    {
        /* cache size fixed at compile time in wolfSSL */
        (void)ctx;
        (void)sz;
        WOLFSSL_MSG("session cache is set at compile time");
        #ifndef NO_SESSION_CACHE
            return (long)(SESSIONS_PER_ROW * SESSION_ROWS);
        #else
            return 0;
        #endif
    }

#endif

#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL) || \
    defined(WOLFSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
    void wolfSSL_CTX_set_quiet_shutdown(WOLFSSL_CTX* ctx, int mode)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_set_quiet_shutdown");
        if (mode)
            ctx->quietShutdown = 1;
    }


    void wolfSSL_set_quiet_shutdown(WOLFSSL* ssl, int mode)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_set_quiet_shutdown");
        if (mode)
            ssl->options.quietShutdown = 1;
    }
#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL ||
          WOLFSSL_EXTRA || WOLFSSL_WPAS_SMALL */

#ifdef OPENSSL_EXTRA
#ifndef NO_BIO
    void wolfSSL_set_bio(WOLFSSL* ssl, WOLFSSL_BIO* rd, WOLFSSL_BIO* wr)
    {
        WOLFSSL_ENTER("wolfSSL_set_bio");

        if (ssl == NULL) {
            WOLFSSL_MSG("Bad argument, ssl was NULL");
            return;
        }

        /* free any existing WOLFSSL_BIOs in use but don't free those in
         * a chain */
        if (ssl->biord != NULL) {
            if (ssl->biord != ssl->biowr) {
                if (ssl->biowr != NULL && ssl->biowr->prev != NULL)
                    wolfSSL_BIO_free(ssl->biowr);
                ssl->biowr = NULL;
            }
            if (ssl->biord->prev != NULL)
                wolfSSL_BIO_free(ssl->biord);
            ssl->biord = NULL;
        }
        /* set flag obviously */
        if (rd && !(rd->flags & WOLFSSL_BIO_FLAG_READ))
            rd->flags |= WOLFSSL_BIO_FLAG_READ;
        if (wr && !(wr->flags & WOLFSSL_BIO_FLAG_WRITE))
            wr->flags |= WOLFSSL_BIO_FLAG_WRITE;

        ssl->biord = rd;
        ssl->biowr = wr;

        /* set SSL to use BIO callbacks instead */
        if (((ssl->cbioFlag & WOLFSSL_CBIO_RECV) == 0)) {
            ssl->CBIORecv = BioReceive;
        }
        if (((ssl->cbioFlag & WOLFSSL_CBIO_SEND) == 0)) {
            ssl->CBIOSend = BioSend;
        }

        /* User programs should always retry reading from these BIOs */
        if (rd) {
            /* User writes to rd */
            BIO_set_retry_write(rd);
        }
        if (wr) {
            /* User reads from wr */
            BIO_set_retry_read(wr);
        }
    }
#endif /* !NO_BIO */
#endif /* OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_EXTRA)
    void wolfSSL_CTX_set_client_CA_list(WOLFSSL_CTX* ctx,
                                       WOLF_STACK_OF(WOLFSSL_X509_NAME)* names)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_set_client_CA_list");
        if (ctx != NULL) {
            wolfSSL_sk_X509_NAME_pop_free(ctx->ca_names, NULL);
            ctx->ca_names = names;
        }
    }

    void wolfSSL_set_client_CA_list(WOLFSSL* ssl,
                                       WOLF_STACK_OF(WOLFSSL_X509_NAME)* names)
    {
        WOLFSSL_ENTER("wolfSSL_set_client_CA_list");
        if (ssl != NULL) {
            if (ssl->ca_names != ssl->ctx->ca_names)
                wolfSSL_sk_X509_NAME_pop_free(ssl->ca_names, NULL);
            ssl->ca_names = names;
        }
    }

    #ifdef OPENSSL_EXTRA
    /* registers client cert callback, called during handshake if server
       requests client auth but user has not loaded client cert/key */
    void wolfSSL_CTX_set_client_cert_cb(WOLFSSL_CTX *ctx, client_cert_cb cb)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_set_client_cert_cb");

        if (ctx != NULL) {
            ctx->CBClientCert = cb;
        }
    }

    void wolfSSL_CTX_set_cert_cb(WOLFSSL_CTX* ctx,
        CertSetupCallback cb, void *arg)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_set_cert_cb");
        if (ctx == NULL)
            return;

        ctx->certSetupCb = cb;
        ctx->certSetupCbArg = arg;
    }

    /**
     * Internal wrapper for calling certSetupCb
     * @param ssl The SSL/TLS Object
     * @return 0 on success
     */
    int CertSetupCbWrapper(WOLFSSL* ssl)
    {
        int ret = 0;
        if (ssl->ctx->certSetupCb != NULL) {
            WOLFSSL_MSG("Calling user cert setup callback");
            ret = ssl->ctx->certSetupCb(ssl, ssl->ctx->certSetupCbArg);
            if (ret == 1) {
                WOLFSSL_MSG("User cert callback returned success");
                ret = 0;
            }
            else if (ret == 0) {
                SendAlert(ssl, alert_fatal, internal_error);
                ret = CLIENT_CERT_CB_ERROR;
            }
            else if (ret < 0) {
                ret = WOLFSSL_ERROR_WANT_X509_LOOKUP;
            }
            else {
                WOLFSSL_MSG("Unexpected user callback return");
                ret = CLIENT_CERT_CB_ERROR;
            }
        }
        return ret;
    }
    #endif /* OPENSSL_EXTRA */

#endif /* OPENSSL_EXTRA || WOLFSSL_EXTRA || HAVE_WEBSERVER */

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_EXTRA)
    WOLF_STACK_OF(WOLFSSL_X509_NAME)* wolfSSL_CTX_get_client_CA_list(
            const WOLFSSL_CTX *ctx)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_get_client_CA_list");

        if (ctx == NULL) {
            WOLFSSL_MSG("Bad argument passed to wolfSSL_CTX_get_client_CA_list");
            return NULL;
        }

        return ctx->ca_names;
    }

    /* returns the CA's set on server side or the CA's sent from server when
     * on client side */
    WOLF_STACK_OF(WOLFSSL_X509_NAME)* wolfSSL_get_client_CA_list(
            const WOLFSSL* ssl)
    {
        WOLFSSL_ENTER("wolfSSL_get_client_CA_list");

        if (ssl == NULL) {
            WOLFSSL_MSG("Bad argument passed to wolfSSL_get_client_CA_list");
            return NULL;
        }

        return SSL_CA_NAMES(ssl);
    }

    #if !defined(NO_CERTS)
    int wolfSSL_CTX_add_client_CA(WOLFSSL_CTX* ctx, WOLFSSL_X509* x509)
    {
        WOLFSSL_X509_NAME *nameCopy = NULL;

        WOLFSSL_ENTER("wolfSSL_CTX_add_client_CA");

        if (ctx == NULL || x509 == NULL){
            WOLFSSL_MSG("Bad argument");
            return WOLFSSL_FAILURE;
        }

        if (ctx->ca_names == NULL) {
            ctx->ca_names = wolfSSL_sk_X509_NAME_new(NULL);
            if (ctx->ca_names == NULL) {
                WOLFSSL_MSG("wolfSSL_sk_X509_NAME_new error");
                return WOLFSSL_FAILURE;
            }
        }

        nameCopy = wolfSSL_X509_NAME_dup(wolfSSL_X509_get_subject_name(x509));
        if (nameCopy == NULL) {
            WOLFSSL_MSG("wolfSSL_X509_NAME_dup error");
            return WOLFSSL_FAILURE;
        }

        if (wolfSSL_sk_X509_NAME_push(ctx->ca_names, nameCopy) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("wolfSSL_sk_X509_NAME_push error");
            wolfSSL_X509_NAME_free(nameCopy);
            return WOLFSSL_FAILURE;
        }

        return WOLFSSL_SUCCESS;
    }
    #endif

    #ifndef NO_BIO
        #if !defined(NO_RSA) && !defined(NO_CERTS)
        WOLF_STACK_OF(WOLFSSL_X509_NAME)* wolfSSL_load_client_CA_file(const char* fname)
        {
            /* The webserver build is using this to load a CA into the server
             * for client authentication as an option. Have this return NULL in
             * that case. If OPENSSL_EXTRA is enabled, go ahead and include
             * the function. */
        #ifdef OPENSSL_EXTRA
            WOLFSSL_STACK *list = NULL;
            WOLFSSL_BIO* bio = NULL;
            WOLFSSL_X509 *cert = NULL;
            WOLFSSL_X509_NAME *nameCopy = NULL;
            unsigned long err = WOLFSSL_FAILURE;

            WOLFSSL_ENTER("wolfSSL_load_client_CA_file");

            bio = wolfSSL_BIO_new_file(fname, "rb");
            if (bio == NULL) {
                WOLFSSL_MSG("wolfSSL_BIO_new_file error");
                goto cleanup;
            }

            list = wolfSSL_sk_X509_NAME_new(NULL);
            if (list == NULL) {
                WOLFSSL_MSG("wolfSSL_sk_X509_NAME_new error");
                goto cleanup;
            }

            /* Read each certificate in the chain out of the file. */
            while (wolfSSL_PEM_read_bio_X509(bio, &cert, NULL, NULL) != NULL) {
                /* Need a persistent copy of the subject name. */
                nameCopy = wolfSSL_X509_NAME_dup(
                        wolfSSL_X509_get_subject_name(cert));
                if (nameCopy == NULL) {
                    WOLFSSL_MSG("wolfSSL_X509_NAME_dup error");
                    goto cleanup;
                }
                /*
                * Original cert will be freed so make sure not to try to access
                * it in the future.
                */
                nameCopy->x509 = NULL;

                if (wolfSSL_sk_X509_NAME_push(list, nameCopy) !=
                        WOLFSSL_SUCCESS) {
                    WOLFSSL_MSG("wolfSSL_sk_X509_NAME_push error");
                    /* Do free in loop because nameCopy is now responsibility
                     * of list to free and adding jumps to cleanup after this
                     * might result in a double free. */
                    wolfSSL_X509_NAME_free(nameCopy);
                    goto cleanup;
                }

                wolfSSL_X509_free(cert);
                cert = NULL;
            }

            CLEAR_ASN_NO_PEM_HEADER_ERROR(err);

            err = WOLFSSL_SUCCESS;
cleanup:
            wolfSSL_X509_free(cert);
            wolfSSL_BIO_free(bio);
            if (err != WOLFSSL_SUCCESS) {
                /* We failed so return NULL */
                wolfSSL_sk_X509_NAME_pop_free(list, NULL);
                list = NULL;
            }
            return list;
        #else
            (void)fname;
            return NULL;
        #endif
        }
        #endif
    #endif /* !NO_BIO */
#endif /* OPENSSL_EXTRA || WOLFSSL_EXTRA */

#ifdef OPENSSL_EXTRA

    #ifdef WOLFSSL_SYS_CA_CERTS
    /*
     * This is an OpenSSL compatibility layer function, but it doesn't mirror
     * the exact functionality of its OpenSSL counterpart. We don't support the
     * notion of an "OpenSSL directory," nor do we support the environment
     * variables SSL_CERT_DIR or SSL_CERT_FILE. This function is simply a
     * wrapper around our native wolfSSL_CTX_load_system_CA_certs function. This
     * function does conform to OpenSSL's return value conventions, though.
     */
    int wolfSSL_CTX_set_default_verify_paths(WOLFSSL_CTX* ctx)
    {
        int ret;

        WOLFSSL_ENTER("wolfSSL_CTX_set_default_verify_paths");

        ret = wolfSSL_CTX_load_system_CA_certs(ctx);
        if (ret == WOLFSSL_BAD_PATH) {
            /*
             * OpenSSL doesn't treat the lack of a system CA cert directory as a
             * failure. We do the same here.
             */
            ret = WOLFSSL_SUCCESS;
        }

        WOLFSSL_LEAVE("wolfSSL_CTX_set_default_verify_paths", ret);

        return ret;
    }
    #endif /* WOLFSSL_SYS_CA_CERTS */

    #if defined(WOLFCRYPT_HAVE_SRP) && !defined(NO_SHA256) \
        && !defined(WC_NO_RNG)
    static const byte srp_N[] = {
        0xEE, 0xAF, 0x0A, 0xB9, 0xAD, 0xB3, 0x8D, 0xD6, 0x9C, 0x33, 0xF8,
        0x0A, 0xFA, 0x8F, 0xC5, 0xE8, 0x60, 0x72, 0x61, 0x87, 0x75, 0xFF,
        0x3C, 0x0B, 0x9E, 0xA2, 0x31, 0x4C, 0x9C, 0x25, 0x65, 0x76, 0xD6,
        0x74, 0xDF, 0x74, 0x96, 0xEA, 0x81, 0xD3, 0x38, 0x3B, 0x48, 0x13,
        0xD6, 0x92, 0xC6, 0xE0, 0xE0, 0xD5, 0xD8, 0xE2, 0x50, 0xB9, 0x8B,
        0xE4, 0x8E, 0x49, 0x5C, 0x1D, 0x60, 0x89, 0xDA, 0xD1, 0x5D, 0xC7,
        0xD7, 0xB4, 0x61, 0x54, 0xD6, 0xB6, 0xCE, 0x8E, 0xF4, 0xAD, 0x69,
        0xB1, 0x5D, 0x49, 0x82, 0x55, 0x9B, 0x29, 0x7B, 0xCF, 0x18, 0x85,
        0xC5, 0x29, 0xF5, 0x66, 0x66, 0x0E, 0x57, 0xEC, 0x68, 0xED, 0xBC,
        0x3C, 0x05, 0x72, 0x6C, 0xC0, 0x2F, 0xD4, 0xCB, 0xF4, 0x97, 0x6E,
        0xAA, 0x9A, 0xFD, 0x51, 0x38, 0xFE, 0x83, 0x76, 0x43, 0x5B, 0x9F,
        0xC6, 0x1D, 0x2F, 0xC0, 0xEB, 0x06, 0xE3
    };
    static const byte srp_g[] = {
        0x02
    };

    int wolfSSL_CTX_set_srp_username(WOLFSSL_CTX* ctx, char* username)
    {
        int r = 0;
        SrpSide srp_side = SRP_CLIENT_SIDE;
        byte salt[SRP_SALT_SIZE];

        WOLFSSL_ENTER("wolfSSL_CTX_set_srp_username");
        if (ctx == NULL || ctx->srp == NULL || username==NULL)
            return SSL_FAILURE;

        if (ctx->method->side == WOLFSSL_SERVER_END){
            srp_side = SRP_SERVER_SIDE;
        } else if (ctx->method->side == WOLFSSL_CLIENT_END){
            srp_side = SRP_CLIENT_SIDE;
        } else {
            WOLFSSL_MSG("Init CTX failed");
            return SSL_FAILURE;
        }

        if (wc_SrpInit(ctx->srp, SRP_TYPE_SHA256, srp_side) < 0) {
            WOLFSSL_MSG("Init SRP CTX failed");
            XFREE(ctx->srp, ctx->heap, DYNAMIC_TYPE_SRP);
            ctx->srp = NULL;
            return SSL_FAILURE;
        }
        r = wc_SrpSetUsername(ctx->srp, (const byte*)username,
                              (word32)XSTRLEN(username));
        if (r < 0) {
            WOLFSSL_MSG("fail to set srp username.");
            return SSL_FAILURE;
        }

        /* if wolfSSL_CTX_set_srp_password has already been called, */
        /* execute wc_SrpSetPassword here */
        if (ctx->srp_password != NULL) {
            WC_RNG rng;
            if (wc_InitRng(&rng) < 0){
                WOLFSSL_MSG("wc_InitRng failed");
                return SSL_FAILURE;
            }
            XMEMSET(salt, 0, sizeof(salt)/sizeof(salt[0]));
            r = wc_RNG_GenerateBlock(&rng, salt, sizeof(salt)/sizeof(salt[0]));
            wc_FreeRng(&rng);
            if (r <  0) {
                WOLFSSL_MSG("wc_RNG_GenerateBlock failed");
                return SSL_FAILURE;
            }

            if (wc_SrpSetParams(ctx->srp, srp_N, sizeof(srp_N)/sizeof(srp_N[0]),
                                srp_g, sizeof(srp_g)/sizeof(srp_g[0]),
                                salt, sizeof(salt)/sizeof(salt[0])) < 0) {
                WOLFSSL_MSG("wc_SrpSetParam failed");
                return SSL_FAILURE;
            }
            r = wc_SrpSetPassword(ctx->srp,
                     (const byte*)ctx->srp_password,
                     (word32)XSTRLEN((char *)ctx->srp_password));
            if (r < 0) {
                WOLFSSL_MSG("fail to set srp password.");
                return SSL_FAILURE;
            }

            XFREE(ctx->srp_password, ctx->heap, DYNAMIC_TYPE_SRP);
            ctx->srp_password = NULL;
        }

        return WOLFSSL_SUCCESS;
    }

    int wolfSSL_CTX_set_srp_password(WOLFSSL_CTX* ctx, char* password)
    {
        int r;
        byte salt[SRP_SALT_SIZE];

        WOLFSSL_ENTER("wolfSSL_CTX_set_srp_password");
        if (ctx == NULL || ctx->srp == NULL || password == NULL)
            return SSL_FAILURE;

        if (ctx->srp->user != NULL) {
            WC_RNG rng;
            if (wc_InitRng(&rng) < 0) {
                WOLFSSL_MSG("wc_InitRng failed");
                return SSL_FAILURE;
            }
            XMEMSET(salt, 0, sizeof(salt)/sizeof(salt[0]));
            r = wc_RNG_GenerateBlock(&rng, salt, sizeof(salt)/sizeof(salt[0]));
            wc_FreeRng(&rng);
            if (r <  0) {
                WOLFSSL_MSG("wc_RNG_GenerateBlock failed");
                return SSL_FAILURE;
            }
            if (wc_SrpSetParams(ctx->srp, srp_N, sizeof(srp_N)/sizeof(srp_N[0]),
                                srp_g, sizeof(srp_g)/sizeof(srp_g[0]),
                                salt, sizeof(salt)/sizeof(salt[0])) < 0){
                WOLFSSL_MSG("wc_SrpSetParam failed");
                wc_FreeRng(&rng);
                return SSL_FAILURE;
            }
            r = wc_SrpSetPassword(ctx->srp, (const byte*)password,
                                  (word32)XSTRLEN(password));
            if (r < 0) {
                WOLFSSL_MSG("wc_SrpSetPassword failed.");
                wc_FreeRng(&rng);
                return SSL_FAILURE;
            }
            if (ctx->srp_password != NULL){
                XFREE(ctx->srp_password,NULL,
                      DYNAMIC_TYPE_SRP);
                ctx->srp_password = NULL;
            }
            wc_FreeRng(&rng);
        } else {
            /* save password for wolfSSL_set_srp_username */
            if (ctx->srp_password != NULL)
                XFREE(ctx->srp_password,ctx->heap, DYNAMIC_TYPE_SRP);

            ctx->srp_password = (byte*)XMALLOC(XSTRLEN(password) + 1, ctx->heap,
                                               DYNAMIC_TYPE_SRP);
            if (ctx->srp_password == NULL){
                WOLFSSL_MSG("memory allocation error");
                return SSL_FAILURE;
            }
            XMEMCPY(ctx->srp_password, password, XSTRLEN(password) + 1);
        }
        return WOLFSSL_SUCCESS;
    }

    /**
     * The modulus passed to wc_SrpSetParams in ssl.c is constant so check
     * that the requested strength is less than or equal to the size of the
     * static modulus size.
     * @param ctx Not used
     * @param strength Minimum number of bits for the modulus
     * @return 1 if strength is less than or equal to static modulus
     *         0 if strength is greater than static modulus
     */
    int  wolfSSL_CTX_set_srp_strength(WOLFSSL_CTX *ctx, int strength)
    {
        (void)ctx;
        WOLFSSL_ENTER("wolfSSL_CTX_set_srp_strength");
        if (strength > (int)(sizeof(srp_N)*8)) {
            WOLFSSL_MSG("Bad Parameter");
            return WOLFSSL_FAILURE;
        }
        return WOLFSSL_SUCCESS;
    }

    char* wolfSSL_get_srp_username(WOLFSSL *ssl)
    {
        if (ssl && ssl->ctx && ssl->ctx->srp) {
            return (char*) ssl->ctx->srp->user;
        }
        return NULL;
    }
    #endif /* WOLFCRYPT_HAVE_SRP && !NO_SHA256 && !WC_NO_RNG */

    /* keyblock size in bytes or -1 */
    int wolfSSL_get_keyblock_size(WOLFSSL* ssl)
    {
        if (ssl == NULL)
            return WOLFSSL_FATAL_ERROR;

        return 2 * (ssl->specs.key_size + ssl->specs.iv_size +
                    ssl->specs.hash_size);
    }

#endif /* OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)

    /* store keys returns WOLFSSL_SUCCESS or -1 on error */
    int wolfSSL_get_keys(WOLFSSL* ssl, unsigned char** ms, unsigned int* msLen,
                                     unsigned char** sr, unsigned int* srLen,
                                     unsigned char** cr, unsigned int* crLen)
    {
        if (ssl == NULL || ssl->arrays == NULL)
            return WOLFSSL_FATAL_ERROR;

        *ms = ssl->arrays->masterSecret;
        *sr = ssl->arrays->serverRandom;
        *cr = ssl->arrays->clientRandom;

        *msLen = SECRET_LEN;
        *srLen = RAN_LEN;
        *crLen = RAN_LEN;

        return WOLFSSL_SUCCESS;
    }

    void wolfSSL_set_accept_state(WOLFSSL* ssl)
    {
        WOLFSSL_ENTER("wolfSSL_set_accept_state");

        if (ssl == NULL)
            return;

        if (ssl->options.side == WOLFSSL_CLIENT_END) {
    #ifdef HAVE_ECC
        #ifdef WOLFSSL_SMALL_STACK
            ecc_key* key = NULL;
        #else
            ecc_key key[1];
        #endif
            word32 idx = 0;

        #ifdef WOLFSSL_SMALL_STACK
            key = (ecc_key*)XMALLOC(sizeof(ecc_key), ssl->heap,
                                    DYNAMIC_TYPE_ECC);
            if (key == NULL) {
                WOLFSSL_MSG("Error allocating memory for ecc_key");
            }
        #endif
            if (ssl->options.haveStaticECC && ssl->buffers.key != NULL) {
                if (wc_ecc_init(key) >= 0) {
                    if (wc_EccPrivateKeyDecode(ssl->buffers.key->buffer, &idx,
                            key, ssl->buffers.key->length) != 0) {
                        ssl->options.haveECDSAsig = 0;
                        ssl->options.haveECC = 0;
                        ssl->options.haveStaticECC = 0;
                    }
                    wc_ecc_free(key);
                }
            }
        #ifdef WOLFSSL_SMALL_STACK
            XFREE(key, ssl->heap, DYNAMIC_TYPE_ECC);
        #endif
    #endif

    #ifndef NO_DH
            if (!ssl->options.haveDH && ssl->ctx->haveDH) {
                ssl->buffers.serverDH_P = ssl->ctx->serverDH_P;
                ssl->buffers.serverDH_G = ssl->ctx->serverDH_G;
                ssl->options.haveDH = 1;
            }
    #endif
        }

        if (InitSSL_Side(ssl, WOLFSSL_SERVER_END) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("Error initializing server side");
        }
    }

#endif /* OPENSSL_EXTRA || WOLFSSL_EXTRA || WOLFSSL_WPAS_SMALL */

    /* return true if connection established */
    int wolfSSL_is_init_finished(WOLFSSL* ssl)
    {
        if (ssl == NULL)
            return 0;

        if (ssl->options.handShakeState == HANDSHAKE_DONE)
            return 1;

        return 0;
    }

#ifdef OPENSSL_EXTRA
    void wolfSSL_CTX_set_tmp_rsa_callback(WOLFSSL_CTX* ctx,
                                      WOLFSSL_RSA*(*f)(WOLFSSL*, int, int))
    {
        /* wolfSSL verifies all these internally */
        (void)ctx;
        (void)f;
    }


    void wolfSSL_set_shutdown(WOLFSSL* ssl, int opt)
    {
        WOLFSSL_ENTER("wolfSSL_set_shutdown");
        if(ssl==NULL) {
            WOLFSSL_MSG("Shutdown not set. ssl is null");
            return;
        }

        ssl->options.sentNotify =  (opt&WOLFSSL_SENT_SHUTDOWN) > 0;
        ssl->options.closeNotify = (opt&WOLFSSL_RECEIVED_SHUTDOWN) > 0;
    }
#endif

    long wolfSSL_CTX_get_options(WOLFSSL_CTX* ctx)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_get_options");
        WOLFSSL_MSG("wolfSSL options are set through API calls and macros");
        if(ctx == NULL)
            return BAD_FUNC_ARG;
        return ctx->mask;
    }

    static long wolf_set_options(long old_op, long op);
    long wolfSSL_CTX_set_options(WOLFSSL_CTX* ctx, long opt)
    {
        WOLFSSL_ENTER("SSL_CTX_set_options");

        if (ctx == NULL)
            return BAD_FUNC_ARG;

        ctx->mask = wolf_set_options(ctx->mask, opt);
#if defined(HAVE_SESSION_TICKET) && (defined(OPENSSL_EXTRA) \
        || defined(HAVE_WEBSERVER) || defined(WOLFSSL_WPAS_SMALL))
        if ((ctx->mask & WOLFSSL_OP_NO_TICKET) == WOLFSSL_OP_NO_TICKET) {
          ctx->noTicketTls12 = 1;
        }
#endif

        return ctx->mask;
    }

    long wolfSSL_CTX_clear_options(WOLFSSL_CTX* ctx, long opt)
    {
        WOLFSSL_ENTER("SSL_CTX_clear_options");
        if(ctx == NULL)
            return BAD_FUNC_ARG;
        ctx->mask &= ~opt;
        return ctx->mask;
    }

#ifdef OPENSSL_EXTRA

    int wolfSSL_set_rfd(WOLFSSL* ssl, int rfd)
    {
        WOLFSSL_ENTER("SSL_set_rfd");
        ssl->rfd = rfd;      /* not used directly to allow IO callbacks */

        ssl->IOCB_ReadCtx  = &ssl->rfd;

    #ifdef WOLFSSL_DTLS
        if (ssl->options.dtls) {
            ssl->IOCB_ReadCtx = &ssl->buffers.dtlsCtx;
            ssl->buffers.dtlsCtx.rfd = rfd;
        }
    #endif

        return WOLFSSL_SUCCESS;
    }


    int wolfSSL_set_wfd(WOLFSSL* ssl, int wfd)
    {
        WOLFSSL_ENTER("SSL_set_wfd");
        ssl->wfd = wfd;      /* not used directly to allow IO callbacks */

        ssl->IOCB_WriteCtx  = &ssl->wfd;

        return WOLFSSL_SUCCESS;
    }
#endif /* OPENSSL_EXTRA */

#if !defined(NO_CERTS) && (defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL))

#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
    /**
     * Implemented in a similar way that ngx_ssl_ocsp_validate does it when
     * SSL_get0_verified_chain is not available.
     * @param ssl WOLFSSL object to extract certs from
     * @return Stack of verified certs
     */
    WOLF_STACK_OF(WOLFSSL_X509) *wolfSSL_get0_verified_chain(const WOLFSSL *ssl)
    {
        WOLF_STACK_OF(WOLFSSL_X509)* chain = NULL;
        WOLFSSL_X509_STORE_CTX* storeCtx = NULL;
        WOLFSSL_X509* peerCert = NULL;

        WOLFSSL_ENTER("wolfSSL_get0_verified_chain");

        if (ssl == NULL || ssl->ctx == NULL) {
            WOLFSSL_MSG("Bad parameter");
            return NULL;
        }

        peerCert = wolfSSL_get_peer_certificate((WOLFSSL*)ssl);
        if (peerCert == NULL) {
            WOLFSSL_MSG("wolfSSL_get_peer_certificate error");
            return NULL;
        }
        /* wolfSSL_get_peer_certificate returns a copy. We want the internal
         * member so that we don't have to worry about free'ing it. We call
         * wolfSSL_get_peer_certificate so that we don't have to worry about
         * setting up the internal pointer. */
        wolfSSL_X509_free(peerCert);
        peerCert = (WOLFSSL_X509*)&ssl->peerCert;
        chain = wolfSSL_get_peer_cert_chain(ssl);
        if (chain == NULL) {
            WOLFSSL_MSG("wolfSSL_get_peer_cert_chain error");
            return NULL;
        }
        storeCtx = wolfSSL_X509_STORE_CTX_new();
        if (storeCtx == NULL) {
            WOLFSSL_MSG("wolfSSL_X509_STORE_CTX_new error");
            return NULL;
        }
        if (wolfSSL_X509_STORE_CTX_init(storeCtx, SSL_STORE(ssl),
                peerCert, chain) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("wolfSSL_X509_STORE_CTX_init error");
            wolfSSL_X509_STORE_CTX_free(storeCtx);
            return NULL;
        }
        if (wolfSSL_X509_verify_cert(storeCtx) <= 0) {
            WOLFSSL_MSG("wolfSSL_X509_verify_cert error");
            wolfSSL_X509_STORE_CTX_free(storeCtx);
            return NULL;
        }
        wolfSSL_X509_STORE_CTX_free(storeCtx);
        return chain;
    }
#endif /* SESSION_CERTS && OPENSSL_EXTRA */

    WOLFSSL_X509_STORE* wolfSSL_CTX_get_cert_store(WOLFSSL_CTX* ctx)
    {
        if (ctx == NULL) {
            return NULL;
        }

        if (ctx->x509_store_pt != NULL)
            return ctx->x509_store_pt;
        return &ctx->x509_store;
    }

    void wolfSSL_CTX_set_cert_store(WOLFSSL_CTX* ctx, WOLFSSL_X509_STORE* str)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_set_cert_store");
        if (ctx == NULL || str == NULL || ctx->cm == str->cm) {
            return;
        }

        if (wolfSSL_CertManager_up_ref(str->cm) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("wolfSSL_CertManager_up_ref error");
            return;
        }
        /* free cert manager if have one */
        if (ctx->cm != NULL) {
            wolfSSL_CertManagerFree(ctx->cm);
        }
        ctx->cm               = str->cm;
        ctx->x509_store.cm    = str->cm;

        /* free existing store if it exists */
        wolfSSL_X509_STORE_free(ctx->x509_store_pt);
        ctx->x509_store.cache = str->cache;
        ctx->x509_store_pt    = str; /* take ownership of store and free it
                                        with CTX free */
        ctx->cm->x509_store_p = ctx->x509_store_pt;/* CTX has onwership
                                                    and free it with CTX free*/
    }


    int wolfSSL_set0_verify_cert_store(WOLFSSL *ssl, WOLFSSL_X509_STORE* str)
    {
        WOLFSSL_ENTER("wolfSSL_set0_verify_cert_store");

        if (ssl == NULL || str == NULL) {
            WOLFSSL_MSG("Bad parameter");
            return WOLFSSL_FAILURE;
        }

        /* NO-OP when setting existing store */
        if (str == SSL_STORE(ssl))
            return WOLFSSL_SUCCESS;

        /* free existing store if it exists */
        wolfSSL_X509_STORE_free(ssl->x509_store_pt);
        if (str == ssl->ctx->x509_store_pt)
            ssl->x509_store_pt = NULL; /* if setting ctx store then just revert
                                          to using that instead */
        else
            ssl->x509_store_pt = str; /* take ownership of store and free it
                                         with SSL free */
        return WOLFSSL_SUCCESS;
    }


    int wolfSSL_set1_verify_cert_store(WOLFSSL *ssl, WOLFSSL_X509_STORE* str)
    {
        WOLFSSL_ENTER("wolfSSL_set1_verify_cert_store");

        if (ssl == NULL || str == NULL) {
            WOLFSSL_MSG("Bad parameter");
            return WOLFSSL_FAILURE;
        }

        /* NO-OP when setting existing store */
        if (str == SSL_STORE(ssl))
            return WOLFSSL_SUCCESS;

        if (wolfSSL_X509_STORE_up_ref(str) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("wolfSSL_X509_STORE_up_ref error");
            return WOLFSSL_FAILURE;
        }

        /* free existing store if it exists */
        wolfSSL_X509_STORE_free(ssl->x509_store_pt);
        if (str == ssl->ctx->x509_store_pt)
            ssl->x509_store_pt = NULL; /* if setting ctx store then just revert
                                          to using that instead */
        else
            ssl->x509_store_pt = str; /* take ownership of store and free it
                                         with SSL free */
        return WOLFSSL_SUCCESS;
    }
#endif /* !NO_CERTS && (OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL) */

#ifdef WOLFSSL_ENCRYPTED_KEYS

    void wolfSSL_CTX_set_default_passwd_cb_userdata(WOLFSSL_CTX* ctx,
                                                   void* userdata)
    {
        WOLFSSL_ENTER("SSL_CTX_set_default_passwd_cb_userdata");
        if (ctx)
            ctx->passwd_userdata = userdata;
    }


    void wolfSSL_CTX_set_default_passwd_cb(WOLFSSL_CTX* ctx, wc_pem_password_cb*
                                           cb)
    {
        WOLFSSL_ENTER("SSL_CTX_set_default_passwd_cb");
        if (ctx)
            ctx->passwd_cb = cb;
    }

    wc_pem_password_cb* wolfSSL_CTX_get_default_passwd_cb(WOLFSSL_CTX *ctx)
    {
        if (ctx == NULL || ctx->passwd_cb == NULL) {
            return NULL;
        }

        return ctx->passwd_cb;
    }


    void* wolfSSL_CTX_get_default_passwd_cb_userdata(WOLFSSL_CTX *ctx)
    {
        if (ctx == NULL) {
            return NULL;
        }

        return ctx->passwd_userdata;
    }

#endif /* WOLFSSL_ENCRYPTED_KEYS */


#if defined(OPENSSL_EXTRA) || defined(HAVE_WEBSERVER)
    int wolfSSL_num_locks(void)
    {
        return 0;
    }

    void wolfSSL_set_locking_callback(void (*f)(int, int, const char*, int))
    {
        WOLFSSL_ENTER("wolfSSL_set_locking_callback");

        if (wc_SetMutexCb(f) != 0) {
            WOLFSSL_MSG("Error when setting mutex call back");
        }
    }


    typedef unsigned long (idCb)(void);
    static idCb* inner_idCb = NULL;

    unsigned long wolfSSL_thread_id(void)
    {
        if (inner_idCb != NULL) {
            return inner_idCb();
        }
        else {
            return 0;
        }
    }


    void wolfSSL_set_id_callback(unsigned long (*f)(void))
    {
        inner_idCb = f;
    }

    unsigned long wolfSSL_ERR_get_error(void)
    {
        WOLFSSL_ENTER("wolfSSL_ERR_get_error");
#ifdef WOLFSSL_HAVE_ERROR_QUEUE
        return wc_GetErrorNodeErr();
#else
        return (unsigned long)(0 - NOT_COMPILED_IN);
#endif
    }

#ifdef WOLFSSL_HAVE_ERROR_QUEUE
#ifndef NO_BIO
    /* print out and clear all errors */
    void wolfSSL_ERR_print_errors(WOLFSSL_BIO* bio)
    {
        const char* file = NULL;
        const char* reason = NULL;
        int ret;
        int line = 0;
        char buf[WOLFSSL_MAX_ERROR_SZ * 2];

        WOLFSSL_ENTER("wolfSSL_ERR_print_errors");

        if (bio == NULL) {
            WOLFSSL_MSG("BIO passed in was null");
            return;
        }

        do {
        ret = wc_PeekErrorNode(0, &file, &reason, &line);
        if (ret >= 0) {
            const char* r = wolfSSL_ERR_reason_error_string(0 - ret);
            if (XSNPRINTF(buf, sizeof(buf),
                          "error:%d:wolfSSL library:%s:%s:%d\n",
                          ret, r, file, line)
                >= (int)sizeof(buf))
            {
                WOLFSSL_MSG("Buffer overrun formatting error message");
            }
            wolfSSL_BIO_write(bio, buf, (int)XSTRLEN(buf));
            wc_RemoveErrorNode(0);
        }
        } while (ret >= 0);
        if (wolfSSL_BIO_write(bio, "", 1) != 1) {
            WOLFSSL_MSG("Issue writing final string terminator");
        }
    }
#endif /* !NO_BIO */
#endif /* WOLFSSL_HAVE_ERROR_QUEUE */

#endif /* OPENSSL_EXTRA || HAVE_WEBSERVER */

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL) || \
    defined(HAVE_SECRET_CALLBACK)
#if !defined(NO_WOLFSSL_SERVER)
/* Return the amount of random bytes copied over or error case.
 * ssl : ssl struct after handshake
 * out : buffer to hold random bytes
 * outSz : either 0 (return max buffer sz) or size of out buffer
 */
size_t wolfSSL_get_server_random(const WOLFSSL *ssl, unsigned char *out,
                                                                   size_t outSz)
{
    size_t size;

    /* return max size of buffer */
    if (outSz == 0) {
        return RAN_LEN;
    }

    if (ssl == NULL || out == NULL) {
        return 0;
    }

    if (ssl->arrays == NULL) {
        WOLFSSL_MSG("Arrays struct not saved after handshake");
        return 0;
    }

    if (outSz > RAN_LEN) {
        size = RAN_LEN;
    }
    else {
        size = outSz;
    }

    XMEMCPY(out, ssl->arrays->serverRandom, size);
    return size;
}
#endif /* !NO_WOLFSSL_SERVER */
#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL || HAVE_SECRET_CALLBACK */

#ifdef OPENSSL_EXTRA
#if !defined(NO_WOLFSSL_SERVER)
/* Used to get the peer ephemeral public key sent during the connection
 * NOTE: currently wolfSSL_KeepHandshakeResources(WOLFSSL* ssl) must be called
 *       before the ephemeral key is stored.
 * return WOLFSSL_SUCCESS on success */
int wolfSSL_get_server_tmp_key(const WOLFSSL* ssl, WOLFSSL_EVP_PKEY** pkey)
{
    WOLFSSL_EVP_PKEY* ret = NULL;

    WOLFSSL_ENTER("wolfSSL_get_server_tmp_key");

    if (ssl == NULL || pkey == NULL) {
        WOLFSSL_MSG("Bad argument passed in");
        return WOLFSSL_FAILURE;
    }

#ifdef HAVE_ECC
    if (ssl->peerEccKey != NULL) {
        unsigned char* der;
        const unsigned char* pt;
        unsigned int   derSz = 0;
        int sz;

        PRIVATE_KEY_UNLOCK();
        if (wc_ecc_export_x963(ssl->peerEccKey, NULL, &derSz) !=
                LENGTH_ONLY_E) {
            WOLFSSL_MSG("get ecc der size failed");
            PRIVATE_KEY_LOCK();
            return WOLFSSL_FAILURE;
        }
        PRIVATE_KEY_LOCK();

        derSz += MAX_SEQ_SZ + (2 * MAX_ALGO_SZ) + MAX_SEQ_SZ + TRAILING_ZERO;
        der = (unsigned char*)XMALLOC(derSz, ssl->heap, DYNAMIC_TYPE_KEY);
        if (der == NULL) {
            WOLFSSL_MSG("Memory error");
            return WOLFSSL_FAILURE;
        }

        if ((sz = wc_EccPublicKeyToDer(ssl->peerEccKey, der, derSz, 1)) <= 0) {
            WOLFSSL_MSG("get ecc der failed");
            XFREE(der, ssl->heap, DYNAMIC_TYPE_KEY);
            return WOLFSSL_FAILURE;
        }
        pt = der; /* in case pointer gets advanced */
        ret = wolfSSL_d2i_PUBKEY(NULL, &pt, sz);
        XFREE(der, ssl->heap, DYNAMIC_TYPE_KEY);
    }
#endif

    *pkey = ret;
#ifdef HAVE_ECC
    if (ret != NULL)
        return WOLFSSL_SUCCESS;
    else
#endif
        return WOLFSSL_FAILURE;
}

#endif /* !NO_WOLFSSL_SERVER */

/**
 * This function checks if any compiled in protocol versions are
 * left enabled after calls to set_min or set_max API.
 * @param major The SSL/TLS major version
 * @return WOLFSSL_SUCCESS on valid settings and WOLFSSL_FAILURE when no
 *         protocol versions are left enabled.
 */
static int CheckSslMethodVersion(byte major, unsigned long options)
{
    int sanityConfirmed = 0;

    (void)options;

    switch (major) {
    #ifndef NO_TLS
        case SSLv3_MAJOR:
            #ifdef WOLFSSL_ALLOW_SSLV3
                if (!(options & WOLFSSL_OP_NO_SSLv3)) {
                    sanityConfirmed = 1;
                }
            #endif
            #ifndef NO_OLD_TLS
                if (!(options & WOLFSSL_OP_NO_TLSv1))
                    sanityConfirmed = 1;
                if (!(options & WOLFSSL_OP_NO_TLSv1_1))
                    sanityConfirmed = 1;
            #endif
            #ifndef WOLFSSL_NO_TLS12
                if (!(options & WOLFSSL_OP_NO_TLSv1_2))
                    sanityConfirmed = 1;
            #endif
            #ifdef WOLFSSL_TLS13
                if (!(options & WOLFSSL_OP_NO_TLSv1_3))
                    sanityConfirmed = 1;
            #endif
            break;
    #endif
    #ifdef WOLFSSL_DTLS
        case DTLS_MAJOR:
            sanityConfirmed = 1;
            break;
    #endif
        default:
            WOLFSSL_MSG("Invalid major version");
            return WOLFSSL_FAILURE;
    }
    if (!sanityConfirmed) {
        WOLFSSL_MSG("All compiled in TLS versions disabled");
        return WOLFSSL_FAILURE;
    }
    return WOLFSSL_SUCCESS;
}

/**
 * protoVerTbl holds (D)TLS version numbers in ascending order.
 * Except DTLS versions, the newer version is located in the latter part of
 * the table. This table is referred by wolfSSL_CTX_set_min_proto_version and
 * wolfSSL_CTX_set_max_proto_version.
 */
static const int protoVerTbl[] = {
    SSL3_VERSION,
    TLS1_VERSION,
    TLS1_1_VERSION,
    TLS1_2_VERSION,
    TLS1_3_VERSION,
    DTLS1_VERSION,
    DTLS1_2_VERSION
};
/* number of protocol versions listed in protoVerTbl */
#define NUMBER_OF_PROTOCOLS (sizeof(protoVerTbl)/sizeof(int))

/**
 * wolfSSL_CTX_set_min_proto_version attempts to set the minimum protocol
 * version to use by SSL objects created from this WOLFSSL_CTX.
 * This API guarantees that a version of SSL/TLS lower than specified
 * here will not be allowed. If the version specified is not compiled in
 * then this API sets the lowest compiled in protocol version.
 * This API also accept 0 as version, to set the minimum version automatically.
 * CheckSslMethodVersion() is called to check if any remaining protocol versions
 * are enabled.
 * @param ctx The wolfSSL CONTEXT factory for spawning SSL/TLS objects
 * @param version Any of the following
 *          * 0
 *          * SSL3_VERSION
 *          * TLS1_VERSION
 *          * TLS1_1_VERSION
 *          * TLS1_2_VERSION
 *          * TLS1_3_VERSION
 *          * DTLS1_VERSION
 *          * DTLS1_2_VERSION
 * @return WOLFSSL_SUCCESS on valid settings and WOLFSSL_FAILURE when no
 *         protocol versions are left enabled.
 */
static int Set_CTX_min_proto_version(WOLFSSL_CTX* ctx, int version)
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_min_proto_version_ex");

    if (ctx == NULL) {
        return WOLFSSL_FAILURE;
    }

    switch (version) {
#ifndef NO_TLS
        case SSL3_VERSION:
#if defined(WOLFSSL_ALLOW_SSLV3) && !defined(NO_OLD_TLS)
            ctx->minDowngrade = SSLv3_MINOR;
            break;
#endif
        case TLS1_VERSION:
        #ifdef WOLFSSL_ALLOW_TLSV10
            ctx->minDowngrade = TLSv1_MINOR;
            break;
        #endif
        case TLS1_1_VERSION:
        #ifndef NO_OLD_TLS
            ctx->minDowngrade = TLSv1_1_MINOR;
            break;
        #endif
        case TLS1_2_VERSION:
        #ifndef WOLFSSL_NO_TLS12
            ctx->minDowngrade = TLSv1_2_MINOR;
            break;
        #endif
        case TLS1_3_VERSION:
        #ifdef WOLFSSL_TLS13
            ctx->minDowngrade = TLSv1_3_MINOR;
            break;
        #endif
#endif
#ifdef WOLFSSL_DTLS
        case DTLS1_VERSION:
    #ifndef NO_OLD_TLS
            ctx->minDowngrade = DTLS_MINOR;
            break;
    #endif
        case DTLS1_2_VERSION:
            ctx->minDowngrade = DTLSv1_2_MINOR;
            break;
#endif
        default:
            WOLFSSL_MSG("Unrecognized protocol version or not compiled in");
            return WOLFSSL_FAILURE;
    }

    switch (version) {
#ifndef NO_TLS
    case TLS1_3_VERSION:
        wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1_2);
        FALL_THROUGH;
    case TLS1_2_VERSION:
        wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1_1);
        FALL_THROUGH;
    case TLS1_1_VERSION:
        wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1);
        FALL_THROUGH;
    case TLS1_VERSION:
        wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_SSLv3);
        break;
    case SSL3_VERSION:
    case SSL2_VERSION:
        /* Nothing to do here */
        break;
#endif
#ifdef WOLFSSL_DTLS
    case DTLS1_VERSION:
    case DTLS1_2_VERSION:
        break;
#endif
    default:
        WOLFSSL_MSG("Unrecognized protocol version or not compiled in");
        return WOLFSSL_FAILURE;
    }

    return CheckSslMethodVersion(ctx->method->version.major, ctx->mask);
}

/* Sets the min protocol version allowed with WOLFSSL_CTX
 * returns WOLFSSL_SUCCESS on success */
int wolfSSL_CTX_set_min_proto_version(WOLFSSL_CTX* ctx, int version)
{
    int ret;
    int proto    = 0;
    int maxProto = 0;
    int i;
    int idx = 0;

    WOLFSSL_ENTER("wolfSSL_CTX_set_min_proto_version");

    if (ctx == NULL) {
        return WOLFSSL_FAILURE;
    }
    if (version != 0) {
        proto = version;
        ctx->minProto = 0; /* turn min proto flag off */
        for (i = 0; (unsigned)i < NUMBER_OF_PROTOCOLS; i++) {
            if (protoVerTbl[i] == version) {
                break;
            }
        }
    }
    else {
        /* when 0 is specified as version, try to find out the min version */
        for (i = 0; (unsigned)i < NUMBER_OF_PROTOCOLS; i++) {
            ret = Set_CTX_min_proto_version(ctx, protoVerTbl[i]);
            if (ret == WOLFSSL_SUCCESS) {
                proto = protoVerTbl[i];
                ctx->minProto = 1; /* turn min proto flag on */
                break;
            }
        }
    }

    /* check case where max > min , if so then clear the NO_* options
     * i is the index into the table for proto version used, see if the max
     * proto version index found is smaller */
    maxProto = wolfSSL_CTX_get_max_proto_version(ctx);
    for (idx = 0; (unsigned)idx < NUMBER_OF_PROTOCOLS; idx++) {
        if (protoVerTbl[idx] == maxProto) {
            break;
        }
    }
    if (idx < i) {
        wolfSSL_CTX_clear_options(ctx, WOLFSSL_OP_NO_TLSv1 |
                WOLFSSL_OP_NO_TLSv1_1 | WOLFSSL_OP_NO_TLSv1_2 |
                WOLFSSL_OP_NO_TLSv1_3);
    }

    ret = Set_CTX_min_proto_version(ctx, proto);
    return ret;
}

/**
 * wolfSSL_CTX_set_max_proto_version attempts to set the maximum protocol
 * version to use by SSL objects created from this WOLFSSL_CTX.
 * This API guarantees that a version of SSL/TLS higher than specified
 * here will not be allowed. If the version specified is not compiled in
 * then this API sets the highest compiled in protocol version.
 * This API also accept 0 as version, to set the maximum version automatically.
 * CheckSslMethodVersion() is called to check if any remaining protocol versions
 * are enabled.
 * @param ctx The wolfSSL CONTEXT factory for spawning SSL/TLS objects
 * @param ver Any of the following
 *          * 0
 *          * SSL3_VERSION
 *          * TLS1_VERSION
 *          * TLS1_1_VERSION
 *          * TLS1_2_VERSION
 *          * TLS1_3_VERSION
 *          * DTLS1_VERSION
 *          * DTLS1_2_VERSION
 * @return WOLFSSL_SUCCESS on valid settings and WOLFSSL_FAILURE when no
 *         protocol versions are left enabled.
 */
static int Set_CTX_max_proto_version(WOLFSSL_CTX* ctx, int ver)
{
    WOLFSSL_ENTER("Set_CTX_max_proto_version");

    if (!ctx || !ctx->method) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }

    switch (ver) {
    case SSL2_VERSION:
        WOLFSSL_MSG("wolfSSL does not support SSLv2");
        return WOLFSSL_FAILURE;
#ifndef NO_TLS
    case SSL3_VERSION:
        wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1);
        FALL_THROUGH;
    case TLS1_VERSION:
        wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1_1);
        FALL_THROUGH;
    case TLS1_1_VERSION:
        wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1_2);
        FALL_THROUGH;
    case TLS1_2_VERSION:
        wolfSSL_CTX_set_options(ctx, WOLFSSL_OP_NO_TLSv1_3);
        FALL_THROUGH;
    case TLS1_3_VERSION:
        /* Nothing to do here */
        break;
#endif
#ifdef WOLFSSL_DTLS
    case DTLS1_VERSION:
    case DTLS1_2_VERSION:
        break;
#endif
    default:
        WOLFSSL_MSG("Unrecognized protocol version or not compiled in");
        return WOLFSSL_FAILURE;
    }

    return CheckSslMethodVersion(ctx->method->version.major, ctx->mask);
}


/* Sets the max protocol version allowed with WOLFSSL_CTX
 * returns WOLFSSL_SUCCESS on success */
int wolfSSL_CTX_set_max_proto_version(WOLFSSL_CTX* ctx, int version)
{
    int i;
    int ret = WOLFSSL_FAILURE;
    int minProto;

    WOLFSSL_ENTER("wolfSSL_CTX_set_max_proto_version");

    if (ctx == NULL) {
        return ret;
    }

    /* clear out flags and reset min protocol version */
    minProto = wolfSSL_CTX_get_min_proto_version(ctx);
    wolfSSL_CTX_clear_options(ctx,
            WOLFSSL_OP_NO_TLSv1 | WOLFSSL_OP_NO_TLSv1_1 |
            WOLFSSL_OP_NO_TLSv1_2 | WOLFSSL_OP_NO_TLSv1_3);
    wolfSSL_CTX_set_min_proto_version(ctx, minProto);
    if (version != 0) {
        ctx->maxProto = 0; /* turn max proto flag off */
        return Set_CTX_max_proto_version(ctx, version);
    }

    /* when 0 is specified as version, try to find out the min version from
     * the bottom to top of the protoverTbl.
     */
    for (i = NUMBER_OF_PROTOCOLS -1; i >= 0; i--) {
        ret = Set_CTX_max_proto_version(ctx, protoVerTbl[i]);
        if (ret == WOLFSSL_SUCCESS) {
            ctx->maxProto = 1; /* turn max proto flag on */
            break;
        }
    }

    return ret;
}


static int Set_SSL_min_proto_version(WOLFSSL* ssl, int ver)
{
    WOLFSSL_ENTER("Set_SSL_min_proto_version");

    if (ssl == NULL) {
        return WOLFSSL_FAILURE;
    }

    switch (ver) {
#ifndef NO_TLS
        case SSL3_VERSION:
#if defined(WOLFSSL_ALLOW_SSLV3) && !defined(NO_OLD_TLS)
            ssl->options.minDowngrade = SSLv3_MINOR;
            break;
#endif
        case TLS1_VERSION:
        #ifdef WOLFSSL_ALLOW_TLSV10
            ssl->options.minDowngrade = TLSv1_MINOR;
            break;
        #endif
        case TLS1_1_VERSION:
        #ifndef NO_OLD_TLS
            ssl->options.minDowngrade = TLSv1_1_MINOR;
            break;
        #endif
        case TLS1_2_VERSION:
        #ifndef WOLFSSL_NO_TLS12
            ssl->options.minDowngrade = TLSv1_2_MINOR;
            break;
        #endif
        case TLS1_3_VERSION:
        #ifdef WOLFSSL_TLS13
            ssl->options.minDowngrade = TLSv1_3_MINOR;
            break;
        #endif
#endif
#ifdef WOLFSSL_DTLS
        case DTLS1_VERSION:
    #ifndef NO_OLD_TLS
            ssl->options.minDowngrade = DTLS_MINOR;
            break;
    #endif
        case DTLS1_2_VERSION:
            ssl->options.minDowngrade = DTLSv1_2_MINOR;
            break;
#endif
        default:
            WOLFSSL_MSG("Unrecognized protocol version or not compiled in");
            return WOLFSSL_FAILURE;
    }

    switch (ver) {
#ifndef NO_TLS
    case TLS1_3_VERSION:
        ssl->options.mask |= WOLFSSL_OP_NO_TLSv1_2;
        FALL_THROUGH;
    case TLS1_2_VERSION:
        ssl->options.mask |= WOLFSSL_OP_NO_TLSv1_1;
        FALL_THROUGH;
    case TLS1_1_VERSION:
        ssl->options.mask |= WOLFSSL_OP_NO_TLSv1;
        FALL_THROUGH;
    case TLS1_VERSION:
        ssl->options.mask |= WOLFSSL_OP_NO_SSLv3;
        break;
    case SSL3_VERSION:
    case SSL2_VERSION:
        /* Nothing to do here */
        break;
#endif
#ifdef WOLFSSL_DTLS
    case DTLS1_VERSION:
    case DTLS1_2_VERSION:
        break;
#endif
    default:
        WOLFSSL_MSG("Unrecognized protocol version or not compiled in");
        return WOLFSSL_FAILURE;
    }

    return CheckSslMethodVersion(ssl->version.major, ssl->options.mask);
}

int wolfSSL_set_min_proto_version(WOLFSSL* ssl, int version)
{
    int i;
    int ret = WOLFSSL_FAILURE;;

    WOLFSSL_ENTER("wolfSSL_set_min_proto_version");

    if (ssl == NULL) {
        return WOLFSSL_FAILURE;
    }
    if (version != 0) {
        return Set_SSL_min_proto_version(ssl, version);
    }

    /* when 0 is specified as version, try to find out the min version */
    for (i= 0; (unsigned)i < NUMBER_OF_PROTOCOLS; i++) {
        ret = Set_SSL_min_proto_version(ssl, protoVerTbl[i]);
        if (ret == WOLFSSL_SUCCESS)
            break;
    }

    return ret;
}

static int Set_SSL_max_proto_version(WOLFSSL* ssl, int ver)
{

    WOLFSSL_ENTER("Set_SSL_max_proto_version");

    if (!ssl) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }

    switch (ver) {
    case SSL2_VERSION:
        WOLFSSL_MSG("wolfSSL does not support SSLv2");
        return WOLFSSL_FAILURE;
#ifndef NO_TLS
    case SSL3_VERSION:
        ssl->options.mask |= WOLFSSL_OP_NO_TLSv1;
        FALL_THROUGH;
    case TLS1_VERSION:
        ssl->options.mask |= WOLFSSL_OP_NO_TLSv1_1;
        FALL_THROUGH;
    case TLS1_1_VERSION:
        ssl->options.mask |= WOLFSSL_OP_NO_TLSv1_2;
        FALL_THROUGH;
    case TLS1_2_VERSION:
        ssl->options.mask |= WOLFSSL_OP_NO_TLSv1_3;
        FALL_THROUGH;
    case TLS1_3_VERSION:
        /* Nothing to do here */
        break;
#endif
#ifdef WOLFSSL_DTLS
    case DTLS1_VERSION:
    case DTLS1_2_VERSION:
        break;
#endif
    default:
        WOLFSSL_MSG("Unrecognized protocol version or not compiled in");
        return WOLFSSL_FAILURE;
    }

    return CheckSslMethodVersion(ssl->version.major, ssl->options.mask);
}

int wolfSSL_set_max_proto_version(WOLFSSL* ssl, int version)
{
    int i;
    int ret = WOLFSSL_FAILURE;;

    WOLFSSL_ENTER("wolfSSL_set_max_proto_version");

    if (ssl == NULL) {
        return WOLFSSL_FAILURE;
    }
    if (version != 0) {
        return Set_SSL_max_proto_version(ssl, version);
    }

    /* when 0 is specified as version, try to find out the min version from
     * the bottom to top of the protoverTbl.
     */
    for (i = NUMBER_OF_PROTOCOLS -1; i >= 0; i--) {
        ret = Set_SSL_max_proto_version(ssl, protoVerTbl[i]);
        if (ret == WOLFSSL_SUCCESS)
            break;
    }

    return ret;
}

static int GetMinProtoVersion(int minDowngrade)
{
    int ret;

    switch (minDowngrade) {
#ifndef NO_OLD_TLS
    #ifdef WOLFSSL_ALLOW_SSLV3
        case SSLv3_MINOR:
            ret = SSL3_VERSION;
            break;
    #endif
    #ifdef WOLFSSL_ALLOW_TLSV10
        case TLSv1_MINOR:
            ret = TLS1_VERSION;
            break;
    #endif
        case TLSv1_1_MINOR:
            ret = TLS1_1_VERSION;
            break;
#endif
#ifndef WOLFSSL_NO_TLS12
        case TLSv1_2_MINOR:
            ret = TLS1_2_VERSION;
            break;
#endif
#ifdef WOLFSSL_TLS13
        case TLSv1_3_MINOR:
            ret = TLS1_3_VERSION;
            break;
#endif
        default:
            ret = 0;
            break;
    }

    return ret;
}

int wolfSSL_CTX_get_min_proto_version(WOLFSSL_CTX* ctx)
{
    int ret = 0;

    WOLFSSL_ENTER("wolfSSL_CTX_get_min_proto_version");

    if (ctx != NULL) {
        if (ctx->minProto) {
            ret = 0;
        }
        else {
            ret = GetMinProtoVersion(ctx->minDowngrade);
        }
    }
    else {
        ret = GetMinProtoVersion(WOLFSSL_MIN_DOWNGRADE);
    }

    WOLFSSL_LEAVE("wolfSSL_CTX_get_min_proto_version", ret);

    return ret;
}


/* returns the maximum allowed protocol version given the 'options' used
 * returns WOLFSSL_FATAL_ERROR on no match */
static int GetMaxProtoVersion(long options)
{
#ifndef NO_TLS
#ifdef WOLFSSL_TLS13
    if (!(options & WOLFSSL_OP_NO_TLSv1_3))
        return TLS1_3_VERSION;
#endif
#ifndef WOLFSSL_NO_TLS12
    if (!(options & WOLFSSL_OP_NO_TLSv1_2))
        return TLS1_2_VERSION;
#endif
#ifndef NO_OLD_TLS
    if (!(options & WOLFSSL_OP_NO_TLSv1_1))
        return TLS1_1_VERSION;
    #ifdef WOLFSSL_ALLOW_TLSV10
    if (!(options & WOLFSSL_OP_NO_TLSv1))
        return TLS1_VERSION;
    #endif
    #ifdef WOLFSSL_ALLOW_SSLV3
    if (!(options & WOLFSSL_OP_NO_SSLv3))
        return SSL3_VERSION;
    #endif
#endif
#else
    (void)options;
#endif /* NO_TLS */
    return WOLFSSL_FATAL_ERROR;
}


/* returns the maximum protocol version for 'ctx' */
int wolfSSL_CTX_get_max_proto_version(WOLFSSL_CTX* ctx)
{
    int ret = 0;
    long options = 0; /* default to nothing set */

    WOLFSSL_ENTER("wolfSSL_CTX_get_max_proto_version");

    if (ctx != NULL) {
        options = wolfSSL_CTX_get_options(ctx);
    }

    if ((ctx != NULL) && ctx->maxProto) {
        ret = 0;
    }
    else {
        ret = GetMaxProtoVersion(options);
    }

    WOLFSSL_LEAVE("wolfSSL_CTX_get_max_proto_version", ret);

    if (ret == WOLFSSL_FATAL_ERROR) {
        WOLFSSL_MSG("Error getting max proto version");
        ret = 0; /* setting ret to 0 to match compat return */
    }
    return ret;
}
#endif /* OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL) || \
    defined(HAVE_SECRET_CALLBACK)
#if !defined(NO_WOLFSSL_CLIENT)
/* Return the amount of random bytes copied over or error case.
 * ssl : ssl struct after handshake
 * out : buffer to hold random bytes
 * outSz : either 0 (return max buffer sz) or size of out buffer
 */
size_t wolfSSL_get_client_random(const WOLFSSL* ssl, unsigned char* out,
                                                                   size_t outSz)
{
    size_t size;

    /* return max size of buffer */
    if (outSz == 0) {
        return RAN_LEN;
    }

    if (ssl == NULL || out == NULL) {
        return 0;
    }

    if (ssl->arrays == NULL) {
        WOLFSSL_MSG("Arrays struct not saved after handshake");
        return 0;
    }

    if (outSz > RAN_LEN) {
        size = RAN_LEN;
    }
    else {
        size = outSz;
    }

    XMEMCPY(out, ssl->arrays->clientRandom, size);
    return size;
}
#endif /* !NO_WOLFSSL_CLIENT */
#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL || HAVE_SECRET_CALLBACK */

#ifdef OPENSSL_EXTRA

    unsigned long wolfSSLeay(void)
    {
        return SSLEAY_VERSION_NUMBER;
    }

    unsigned long wolfSSL_OpenSSL_version_num(void)
    {
        return OPENSSL_VERSION_NUMBER;
    }

    const char* wolfSSLeay_version(int type)
    {
        (void)type;
#if defined(OPENSSL_VERSION_NUMBER) && OPENSSL_VERSION_NUMBER >= 0x10100000L
        return wolfSSL_OpenSSL_version(type);
#else
        return wolfSSL_OpenSSL_version();
#endif
    }


#ifndef NO_MD5
    int wolfSSL_MD5_Init(WOLFSSL_MD5_CTX* md5)
    {
        int ret;
        typedef char md5_test[sizeof(MD5_CTX) >= sizeof(wc_Md5) ? 1 : -1];
        (void)sizeof(md5_test);

        WOLFSSL_ENTER("MD5_Init");
        ret = wc_InitMd5((wc_Md5*)md5);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_MD5_Update(WOLFSSL_MD5_CTX* md5, const void* input,
                           unsigned long sz)
    {
        int ret;

        WOLFSSL_ENTER("wolfSSL_MD5_Update");
        ret = wc_Md5Update((wc_Md5*)md5, (const byte*)input, (word32)sz);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }


    int wolfSSL_MD5_Final(byte* output, WOLFSSL_MD5_CTX* md5)
    {
        int ret;

        WOLFSSL_ENTER("MD5_Final");
        ret = wc_Md5Final((wc_Md5*)md5, output);

        /* have to actually free the resources (if any) here, because the
         * OpenSSL API doesn't include SHA*_Free().
         */
        wc_Md5Free((wc_Md5*)md5);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }
    /* Apply MD5 transformation to the data */
    int wolfSSL_MD5_Transform(WOLFSSL_MD5_CTX* md5, const unsigned char* data)
    {
        int ret;

        WOLFSSL_ENTER("MD5_Transform");

        /* sanity check */
        if (md5 == NULL || data == NULL) {
            return 0;
        }
    #if defined(BIG_ENDIAN_ORDER)
        ByteReverseWords((word32*)data, (word32*)data, WC_MD5_BLOCK_SIZE);
    #endif

        ret = wc_Md5Transform((wc_Md5*)md5, data);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    unsigned char *wolfSSL_MD5(const unsigned char* data, size_t len,
            unsigned char* hash)
    {
        static unsigned char out[WC_MD5_DIGEST_SIZE];

        WOLFSSL_ENTER("wolfSSL_MD5");

        if (hash == NULL)
            hash = out;
        if (wc_Md5Hash(data, (word32)len, hash) != 0) {
            WOLFSSL_MSG("wc_Md5Hash error");
            return NULL;
        }
        return hash;
    }
#endif /* !NO_MD5 */


#ifndef NO_SHA
    int wolfSSL_SHA_Init(WOLFSSL_SHA_CTX* sha)
    {
        int ret;

        typedef char sha_test[sizeof(SHA_CTX) >= sizeof(wc_Sha) ? 1 : -1];
        (void)sizeof(sha_test);

        WOLFSSL_ENTER("SHA_Init");
        ret = wc_InitSha((wc_Sha*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }


    int wolfSSL_SHA_Update(WOLFSSL_SHA_CTX* sha, const void* input,
                           unsigned long sz)
    {
        int ret;

        WOLFSSL_ENTER("SHA_Update");
        ret = wc_ShaUpdate((wc_Sha*)sha, (const byte*)input, (word32)sz);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }


    int wolfSSL_SHA_Final(byte* output, WOLFSSL_SHA_CTX* sha)
    {
        int ret;

        WOLFSSL_ENTER("SHA_Final");
        ret = wc_ShaFinal((wc_Sha*)sha, output);

        /* have to actually free the resources (if any) here, because the
         * OpenSSL API doesn't include SHA*_Free().
         */
        wc_ShaFree((wc_Sha*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    #if !defined(HAVE_SELFTEST) && (!defined(HAVE_FIPS) || \
        (defined(HAVE_FIPS_VERSION) && (HAVE_FIPS_VERSION > 2)))
    /* Apply SHA1 transformation to the data */
    int wolfSSL_SHA_Transform(WOLFSSL_SHA_CTX* sha,
                                         const unsigned char* data)
    {
        int ret;

        WOLFSSL_ENTER("SHA_Transform");
        /* sanity check */
        if (sha == NULL || data == NULL) {
            return 0;
        }
    #if defined(LITTLE_ENDIAN_ORDER)
        ByteReverseWords((word32*)data, (word32*)data, WC_SHA_BLOCK_SIZE);
    #endif
        ret = wc_ShaTransform((wc_Sha*)sha, data);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }
    #endif

    int wolfSSL_SHA1_Init(WOLFSSL_SHA_CTX* sha)
    {
        WOLFSSL_ENTER("SHA1_Init");
        return SHA_Init(sha);
    }


    int wolfSSL_SHA1_Update(WOLFSSL_SHA_CTX* sha, const void* input,
                            unsigned long sz)
    {
        WOLFSSL_ENTER("SHA1_Update");
        return SHA_Update(sha, input, sz);
    }


    int wolfSSL_SHA1_Final(byte* output, WOLFSSL_SHA_CTX* sha)
    {
        WOLFSSL_ENTER("SHA1_Final");
        return SHA_Final(output, sha);
    }

    #if !defined(HAVE_SELFTEST) && (!defined(HAVE_FIPS) || \
        (defined(HAVE_FIPS_VERSION) && (HAVE_FIPS_VERSION > 2)))
    /* Apply SHA1 transformation to the data */
    int wolfSSL_SHA1_Transform(WOLFSSL_SHA_CTX* sha,
                                         const unsigned char* data)
    {
       WOLFSSL_ENTER("SHA1_Transform");
       return (wolfSSL_SHA_Transform(sha, data));
    }
    #endif
#endif /* !NO_SHA */

#ifndef NO_SHA256
#ifdef WOLFSSL_SHA224

    int wolfSSL_SHA224_Init(WOLFSSL_SHA224_CTX* sha)
    {
        int ret;

        typedef char sha_test[sizeof(SHA224_CTX) >= sizeof(wc_Sha224) ? 1 : -1];
        (void)sizeof(sha_test);

        WOLFSSL_ENTER("SHA224_Init");
        ret = wc_InitSha224((wc_Sha224*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }


    int wolfSSL_SHA224_Update(WOLFSSL_SHA224_CTX* sha, const void* input,
                           unsigned long sz)
    {
        int ret;

        WOLFSSL_ENTER("SHA224_Update");
        ret = wc_Sha224Update((wc_Sha224*)sha, (const byte*)input, (word32)sz);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }


    int wolfSSL_SHA224_Final(byte* output, WOLFSSL_SHA224_CTX* sha)
    {
        int ret;

        WOLFSSL_ENTER("SHA224_Final");
        ret = wc_Sha224Final((wc_Sha224*)sha, output);

        /* have to actually free the resources (if any) here, because the
         * OpenSSL API doesn't include SHA*_Free().
         */
        wc_Sha224Free((wc_Sha224*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

#endif /* WOLFSSL_SHA224 */

    int wolfSSL_SHA256_Init(WOLFSSL_SHA256_CTX* sha256)
    {
        int ret;

        typedef char sha_test[sizeof(SHA256_CTX) >= sizeof(wc_Sha256) ? 1 : -1];
        (void)sizeof(sha_test);

        WOLFSSL_ENTER("SHA256_Init");
        ret = wc_InitSha256((wc_Sha256*)sha256);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA256_Update(WOLFSSL_SHA256_CTX* sha, const void* input,
                              unsigned long sz)
    {
        int ret;

        WOLFSSL_ENTER("SHA256_Update");
        ret = wc_Sha256Update((wc_Sha256*)sha, (const byte*)input, (word32)sz);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA256_Final(byte* output, WOLFSSL_SHA256_CTX* sha)
    {
        int ret;

        WOLFSSL_ENTER("SHA256_Final");
        ret = wc_Sha256Final((wc_Sha256*)sha, output);

        /* have to actually free the resources (if any) here, because the
         * OpenSSL API doesn't include SHA*_Free().
         */
        wc_Sha256Free((wc_Sha256*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    #if !defined(HAVE_SELFTEST) && (!defined(HAVE_FIPS) || \
        (defined(HAVE_FIPS_VERSION) && (HAVE_FIPS_VERSION > 2))) && \
        !defined(WOLFSSL_DEVCRYPTO_HASH) && !defined(WOLFSSL_AFALG_HASH) && \
        !defined(WOLFSSL_KCAPI_HASH) /* doesn't support direct transform */
    /* Apply SHA256 transformation to the data */
    int wolfSSL_SHA256_Transform(WOLFSSL_SHA256_CTX* sha256,
                                                const unsigned char* data)
    {
        int ret;

        WOLFSSL_ENTER("SHA256_Transform");
        /* sanity check */
        if (sha256 == NULL || data == NULL) {
            return 0;
        }
    #if defined(LITTLE_ENDIAN_ORDER)
        ByteReverseWords((word32*)data, (word32*)data, WC_SHA256_BLOCK_SIZE);
    #endif
        ret = wc_Sha256Transform((wc_Sha256*)sha256, data);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }
    #endif
#endif /* !NO_SHA256 */


#ifdef WOLFSSL_SHA384

    int wolfSSL_SHA384_Init(WOLFSSL_SHA384_CTX* sha)
    {
        int ret;

        typedef char sha_test[sizeof(SHA384_CTX) >= sizeof(wc_Sha384) ? 1 : -1];
        (void)sizeof(sha_test);

        WOLFSSL_ENTER("SHA384_Init");
        ret = wc_InitSha384((wc_Sha384*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA384_Update(WOLFSSL_SHA384_CTX* sha, const void* input,
                           unsigned long sz)
    {
        int ret;

        WOLFSSL_ENTER("SHA384_Update");
        ret = wc_Sha384Update((wc_Sha384*)sha, (const byte*)input, (word32)sz);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA384_Final(byte* output, WOLFSSL_SHA384_CTX* sha)
    {
        int ret;

        WOLFSSL_ENTER("SHA384_Final");
        ret = wc_Sha384Final((wc_Sha384*)sha, output);

        /* have to actually free the resources (if any) here, because the
         * OpenSSL API doesn't include SHA*_Free().
         */
        wc_Sha384Free((wc_Sha384*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

#endif /* WOLFSSL_SHA384 */


#ifdef WOLFSSL_SHA512

    int wolfSSL_SHA512_Init(WOLFSSL_SHA512_CTX* sha)
    {
        int ret;

        typedef char sha_test[sizeof(SHA512_CTX) >= sizeof(wc_Sha512) ? 1 : -1];
        (void)sizeof(sha_test);

        WOLFSSL_ENTER("SHA512_Init");
        ret = wc_InitSha512((wc_Sha512*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }


    int wolfSSL_SHA512_Update(WOLFSSL_SHA512_CTX* sha, const void* input,
                           unsigned long sz)
    {
        int ret;

        WOLFSSL_ENTER("SHA512_Update");
        ret = wc_Sha512Update((wc_Sha512*)sha, (const byte*)input, (word32)sz);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }


    int wolfSSL_SHA512_Final(byte* output, WOLFSSL_SHA512_CTX* sha)
    {
        int ret;

        WOLFSSL_ENTER("SHA512_Final");
        ret = wc_Sha512Final((wc_Sha512*)sha, output);

        /* have to actually free the resources (if any) here, because the
         * OpenSSL API doesn't include SHA*_Free().
         */
        wc_Sha512Free((wc_Sha512*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    #if !defined(HAVE_SELFTEST) && (!defined(HAVE_FIPS) || \
        (defined(HAVE_FIPS_VERSION) && (HAVE_FIPS_VERSION > 2))) && \
        !defined(WOLFSSL_KCAPI_HASH) /* doesn't support direct transform */
    /* Apply SHA512 transformation to the data */
    int wolfSSL_SHA512_Transform(WOLFSSL_SHA512_CTX* sha512,
                                          const unsigned char* data)
    {
        int ret;

        WOLFSSL_ENTER("SHA512_Transform");
        /* sanity check */
        if (sha512 == NULL || data == NULL) {
            return WOLFSSL_FAILURE;
        }

        ret = wc_Sha512Transform((wc_Sha512*)sha512, data);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }
    #endif /* !defined(HAVE_FIPS) || (defined(HAVE_FIPS_VERSION) && \
              (HAVE_FIPS_VERSION > 2)) && !WOLFSSL_KCAPI_HASH */

#if !defined(HAVE_FIPS) && !defined(HAVE_SELFTEST)
#if !defined(WOLFSSL_NOSHA512_224)
    int wolfSSL_SHA512_224_Init(WOLFSSL_SHA512_224_CTX* sha)
    {
        int ret;

        WOLFSSL_ENTER("SHA512_224_Init");
        ret = wc_InitSha512_224((wc_Sha512*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA512_224_Update(WOLFSSL_SHA512_224_CTX* sha,
                                        const void* input, unsigned long sz)
    {
        int ret;

        WOLFSSL_ENTER("SHA512_224_Update");
        ret = wc_Sha512_224Update((wc_Sha512*)sha, (const byte*)input, (word32)sz);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA512_224_Final(byte* output, WOLFSSL_SHA512_224_CTX* sha)
    {
        int ret;

        WOLFSSL_ENTER("SHA512_224_Final");
        ret = wc_Sha512_224Final((wc_Sha512*)sha, output);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    #if !defined(HAVE_SELFTEST) && (!defined(HAVE_FIPS) || \
        (defined(HAVE_FIPS_VERSION) && (HAVE_FIPS_VERSION > 2)))
    /* Apply SHA512 transformation to the data */
    int wolfSSL_SHA512_224_Transform(WOLFSSL_SHA512_CTX* sha512,
                                          const unsigned char* data)
    {
       int ret;

       WOLFSSL_ENTER("SHA512_224_Transform");
       /* sanity check */
       if (sha512 == NULL || data == NULL) {
            return WOLFSSL_FAILURE;
       }

       ret = wc_Sha512_224Transform((wc_Sha512*)sha512, data);

       /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }
    #endif /* !defined(HAVE_FIPS) || (defined(HAVE_FIPS_VERSION) && \
              (HAVE_FIPS_VERSION > 2)) */

#endif /* !WOLFSSL_NOSHA512_224 */
#if !defined(WOLFSSL_NOSHA512_256)
    int wolfSSL_SHA512_256_Init(WOLFSSL_SHA512_256_CTX* sha)
    {
        int ret;

        WOLFSSL_ENTER("SHA512_256_Init");
        ret = wc_InitSha512_256((wc_Sha512*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA512_256_Update(WOLFSSL_SHA512_256_CTX* sha,
                                        const void* input, unsigned long sz)
    {
        int ret;

        WOLFSSL_ENTER("SHA512_256_Update");
        ret = wc_Sha512_256Update((wc_Sha512*)sha, (const byte*)input, (word32)sz);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA512_256_Final(byte* output, WOLFSSL_SHA512_256_CTX* sha)
    {
        int ret;

        WOLFSSL_ENTER("SHA512_256_Final");
        ret = wc_Sha512_256Final((wc_Sha512*)sha, output);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    #if !defined(HAVE_SELFTEST) && (!defined(HAVE_FIPS) || \
        (defined(HAVE_FIPS_VERSION) && (HAVE_FIPS_VERSION > 2)))
    /* Apply SHA512 transformation to the data */
    int wolfSSL_SHA512_256_Transform(WOLFSSL_SHA512_CTX* sha512,
                                          const unsigned char* data)
    {
       int ret;

       WOLFSSL_ENTER("SHA512_256_Transform");
       /* sanity check */
       if (sha512 == NULL || data == NULL) {
            return WOLFSSL_FAILURE;
       }

       ret = wc_Sha512_256Transform((wc_Sha512*)sha512, data);

       /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }
    #endif /* !defined(HAVE_FIPS) || (defined(HAVE_FIPS_VERSION) && \
              (HAVE_FIPS_VERSION > 2)) */

#endif /* !WOLFSSL_NOSHA512_256 */
#endif /* !HAVE_FIPS && !HAVE_SELFTEST */

#endif /* WOLFSSL_SHA512 */

#ifdef WOLFSSL_SHA3
#ifndef WOLFSSL_NOSHA3_224
    int wolfSSL_SHA3_224_Init(WOLFSSL_SHA3_224_CTX* sha)
    {
        int ret;

        typedef char sha_test[sizeof(SHA3_224_CTX) >= sizeof(wc_Sha3) ? 1 : -1];
        (void)sizeof(sha_test);

        WOLFSSL_ENTER("SHA3_224_Init");
        ret = wc_InitSha3_224((wc_Sha3*)sha, NULL, INVALID_DEVID);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA3_224_Update(WOLFSSL_SHA3_224_CTX* sha, const void* input,
                           unsigned long sz)
    {
        int ret;

        WOLFSSL_ENTER("SHA3_224_Update");
        ret = wc_Sha3_224_Update((wc_Sha3*)sha, (const byte*)input, (word32)sz);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA3_224_Final(byte* output, WOLFSSL_SHA3_224_CTX* sha)
    {
        int ret;

        WOLFSSL_ENTER("SHA3_224_Final");
        ret = wc_Sha3_224_Final((wc_Sha3*)sha, output);

        /* have to actually free the resources (if any) here, because the
         * OpenSSL API doesn't include SHA*_Free().
         */
        wc_Sha3_224_Free((wc_Sha3*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

#endif /* WOLFSSL_NOSHA3_224 */

#ifndef WOLFSSL_NOSHA3_256
    int wolfSSL_SHA3_256_Init(WOLFSSL_SHA3_256_CTX* sha3_256)
    {
        int ret;

        typedef char sha_test[sizeof(SHA3_256_CTX) >= sizeof(wc_Sha3) ? 1 : -1];
        (void)sizeof(sha_test);

        WOLFSSL_ENTER("SHA3_256_Init");
        ret = wc_InitSha3_256((wc_Sha3*)sha3_256, NULL, INVALID_DEVID);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA3_256_Update(WOLFSSL_SHA3_256_CTX* sha, const void* input,
                              unsigned long sz)
    {
        int ret;

        WOLFSSL_ENTER("SHA3_256_Update");
        ret = wc_Sha3_256_Update((wc_Sha3*)sha, (const byte*)input, (word32)sz);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA3_256_Final(byte* output, WOLFSSL_SHA3_256_CTX* sha)
    {
        int ret;

        WOLFSSL_ENTER("SHA3_256_Final");
        ret = wc_Sha3_256_Final((wc_Sha3*)sha, output);

        /* have to actually free the resources (if any) here, because the
         * OpenSSL API doesn't include SHA*_Free().
         */
        wc_Sha3_256_Free((wc_Sha3*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }
#endif /* WOLFSSL_NOSHA3_256 */

    int wolfSSL_SHA3_384_Init(WOLFSSL_SHA3_384_CTX* sha)
    {
        int ret;

        typedef char sha_test[sizeof(SHA3_384_CTX) >= sizeof(wc_Sha3) ? 1 : -1];
        (void)sizeof(sha_test);

        WOLFSSL_ENTER("SHA3_384_Init");
        ret = wc_InitSha3_384((wc_Sha3*)sha, NULL, INVALID_DEVID);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA3_384_Update(WOLFSSL_SHA3_384_CTX* sha, const void* input,
                           unsigned long sz)
    {
        int ret;

        WOLFSSL_ENTER("SHA3_384_Update");
        ret = wc_Sha3_384_Update((wc_Sha3*)sha, (const byte*)input, (word32)sz);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA3_384_Final(byte* output, WOLFSSL_SHA3_384_CTX* sha)
    {
        int ret;

        WOLFSSL_ENTER("SHA3_384_Final");
        ret = wc_Sha3_384_Final((wc_Sha3*)sha, output);

        /* have to actually free the resources (if any) here, because the
         * OpenSSL API doesn't include SHA*_Free().
         */
        wc_Sha3_384_Free((wc_Sha3*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

#ifndef WOLFSSL_NOSHA3_512
    int wolfSSL_SHA3_512_Init(WOLFSSL_SHA3_512_CTX* sha)
    {
        int ret;

        typedef char sha_test[sizeof(SHA3_512_CTX) >= sizeof(wc_Sha3) ? 1 : -1];
        (void)sizeof(sha_test);

        WOLFSSL_ENTER("SHA3_512_Init");
        ret = wc_InitSha3_512((wc_Sha3*)sha, NULL, INVALID_DEVID);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA3_512_Update(WOLFSSL_SHA3_512_CTX* sha, const void* input,
                           unsigned long sz)
    {
        int ret;

        WOLFSSL_ENTER("SHA3_512_Update");
        ret = wc_Sha3_512_Update((wc_Sha3*)sha, (const byte*)input, (word32)sz);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }

    int wolfSSL_SHA3_512_Final(byte* output, WOLFSSL_SHA3_512_CTX* sha)
    {
        int ret;

        WOLFSSL_ENTER("SHA3_512_Final");
        ret = wc_Sha3_512_Final((wc_Sha3*)sha, output);

        /* have to actually free the resources (if any) here, because the
         * OpenSSL API doesn't include SHA*_Free().
         */
        wc_Sha3_512_Free((wc_Sha3*)sha);

        /* return 1 on success, 0 otherwise */
        if (ret == 0)
            return WOLFSSL_SUCCESS;
        return WOLFSSL_FAILURE;
    }
#endif /* WOLFSSL_NOSHA3_512 */
#endif /* WOLFSSL_SHA3 */

    unsigned char* wolfSSL_HMAC(const WOLFSSL_EVP_MD* evp_md, const void* key,
                                int key_len, const unsigned char* d, int n,
                                unsigned char* md, unsigned int* md_len)
    {
        int type;
        int mdlen;
        unsigned char* ret = NULL;
#ifdef WOLFSSL_SMALL_STACK
        Hmac* hmac = NULL;
#else
        Hmac  hmac[1];
#endif
        void* heap = NULL;

        WOLFSSL_ENTER("wolfSSL_HMAC");
        if (!md) {
            WOLFSSL_MSG("Static buffer not supported, pass in md buffer");
            return NULL;  /* no static buffer support */
        }

#ifndef NO_MD5
        if (XSTRCMP(evp_md, "MD5") == 0) {
            type = WC_MD5;
            mdlen = WC_MD5_DIGEST_SIZE;
        } else
#endif
#ifdef WOLFSSL_SHA224
        if (XSTRCMP(evp_md, "SHA224") == 0) {
            type = WC_SHA224;
            mdlen = WC_SHA224_DIGEST_SIZE;
        } else
#endif
#ifndef NO_SHA256
        if (XSTRCMP(evp_md, "SHA256") == 0) {
            type = WC_SHA256;
            mdlen = WC_SHA256_DIGEST_SIZE;
        } else
#endif
#ifdef WOLFSSL_SHA384
        if (XSTRCMP(evp_md, "SHA384") == 0) {
            type = WC_SHA384;
            mdlen = WC_SHA384_DIGEST_SIZE;
        } else
#endif
#ifdef WOLFSSL_SHA512
        if (XSTRCMP(evp_md, "SHA512") == 0) {
            type = WC_SHA512;
            mdlen = WC_SHA512_DIGEST_SIZE;
        } else
#endif
#ifdef WOLFSSL_SHA3
    #ifndef WOLFSSL_NOSHA3_224
        if (XSTRCMP(evp_md, "SHA3_224") == 0) {
            type = WC_SHA3_224;
            mdlen = WC_SHA3_224_DIGEST_SIZE;
        } else
    #endif
    #ifndef WOLFSSL_NOSHA3_256
        if (XSTRCMP(evp_md, "SHA3_256") == 0) {
            type = WC_SHA3_256;
            mdlen = WC_SHA3_256_DIGEST_SIZE;
        } else
    #endif
        if (XSTRCMP(evp_md, "SHA3_384") == 0) {
            type = WC_SHA3_384;
            mdlen = WC_SHA3_384_DIGEST_SIZE;
        } else
    #ifndef WOLFSSL_NOSHA3_512
        if (XSTRCMP(evp_md, "SHA3_512") == 0) {
            type = WC_SHA3_512;
            mdlen = WC_SHA3_512_DIGEST_SIZE;
        } else
    #endif
#endif
#ifndef NO_SHA
        if (XSTRCMP(evp_md, "SHA") == 0 || XSTRCMP(evp_md, "SHA1") == 0) {
            type = WC_SHA;
            mdlen = WC_SHA_DIGEST_SIZE;
        }
        else
#endif
        {
            return NULL;
        }

    #ifdef WOLFSSL_SMALL_STACK
        hmac = (Hmac*)XMALLOC(sizeof(Hmac), heap, DYNAMIC_TYPE_HMAC);
        if (hmac == NULL)
            return NULL;
    #endif

        if (wc_HmacInit(hmac, heap, INVALID_DEVID) == 0) {
            if (wc_HmacSetKey(hmac, type, (const byte*)key, key_len) == 0) {
                if (wc_HmacUpdate(hmac, d, n) == 0) {
                    if (wc_HmacFinal(hmac, md) == 0) {
                        if (md_len)
                            *md_len = mdlen;
                        ret = md;
                    }
                }
            }
            wc_HmacFree(hmac);
        }

    #ifdef WOLFSSL_SMALL_STACK
        XFREE(hmac, heap, DYNAMIC_TYPE_HMAC);
    #endif

        (void)evp_md;
        return ret;
    }

#ifndef NO_DES3
    /* 0 on ok */
    int wolfSSL_DES_key_sched(WOLFSSL_const_DES_cblock* key,
                              WOLFSSL_DES_key_schedule* schedule)
    {
        WOLFSSL_ENTER("wolfSSL_DES_key_sched");

        if (key == NULL || schedule == NULL) {
            WOLFSSL_MSG("Null argument passed in");
        }
        else {
            XMEMCPY(schedule, key, sizeof(WOLFSSL_const_DES_cblock));
        }

        return 0;
    }


    /* intended to behave similar to Kerberos mit_des_cbc_cksum
     * return the last 4 bytes of cipher text */
    WOLFSSL_DES_LONG wolfSSL_DES_cbc_cksum(const unsigned char* in,
            WOLFSSL_DES_cblock* out, long length, WOLFSSL_DES_key_schedule* sc,
            WOLFSSL_const_DES_cblock* iv)
    {
        WOLFSSL_DES_LONG ret;
        unsigned char* tmp;
        unsigned char* data   = (unsigned char*)in;
        long           dataSz = length;
        byte dynamicFlag = 0; /* when padding the buffer created needs free'd */

        WOLFSSL_ENTER("wolfSSL_DES_cbc_cksum");

        if (in == NULL || out == NULL || sc == NULL || iv == NULL) {
            WOLFSSL_MSG("Bad argument passed in");
            return 0;
        }

        /* if input length is not a multiple of DES_BLOCK_SIZE pad with 0s */
        if (dataSz % DES_BLOCK_SIZE) {
            dataSz += DES_BLOCK_SIZE - (dataSz % DES_BLOCK_SIZE);
            data = (unsigned char*)XMALLOC(dataSz, NULL,
                                           DYNAMIC_TYPE_TMP_BUFFER);
            if (data == NULL) {
                WOLFSSL_MSG("Issue creating temporary buffer");
                return 0;
            }
            dynamicFlag = 1; /* set to free buffer at end */
            XMEMCPY(data, in, length);
            XMEMSET(data + length, 0, dataSz - length); /* padding */
        }

        tmp = (unsigned char*)XMALLOC(dataSz, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        if (tmp == NULL) {
            WOLFSSL_MSG("Issue creating temporary buffer");
            if (dynamicFlag == 1) {
                XFREE(data, NULL, DYNAMIC_TYPE_TMP_BUFFER);
            }
            return 0;
        }

        wolfSSL_DES_cbc_encrypt(data, tmp, dataSz, sc,
                (WOLFSSL_DES_cblock*)iv, 1);
        XMEMCPY((unsigned char*)out, tmp + (dataSz - DES_BLOCK_SIZE),
                DES_BLOCK_SIZE);

        ret = (((*((unsigned char*)out + 4) & 0xFF) << 24)|
               ((*((unsigned char*)out + 5) & 0xFF) << 16)|
               ((*((unsigned char*)out + 6) & 0xFF) << 8) |
               (*((unsigned char*)out + 7) & 0xFF));

        XFREE(tmp, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        if (dynamicFlag == 1) {
            XFREE(data, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        }

        return ret;
    }


    void wolfSSL_DES_cbc_encrypt(const unsigned char* input,
                                 unsigned char* output, long length,
                                 WOLFSSL_DES_key_schedule* schedule,
                                 WOLFSSL_DES_cblock* ivec, int enc)
    {
        Des myDes;
        byte lastblock[DES_BLOCK_SIZE];
        int  lb_sz;
        long  blk;

        WOLFSSL_ENTER("DES_cbc_encrypt");

        /* OpenSSL compat, no ret */
        if (wc_Des_SetKey(&myDes, (const byte*)schedule, (const byte*)ivec,
                !enc) != 0) {
            WOLFSSL_MSG("wc_Des_SetKey return error.");
            return;
        }
        lb_sz = length%DES_BLOCK_SIZE;
        blk   = length/DES_BLOCK_SIZE;

        if (enc == DES_ENCRYPT){
            wc_Des_CbcEncrypt(&myDes, output, input, (word32)blk*DES_BLOCK_SIZE);
            if(lb_sz){
                XMEMSET(lastblock, 0, DES_BLOCK_SIZE);
                XMEMCPY(lastblock, input+length-lb_sz, lb_sz);
                wc_Des_CbcEncrypt(&myDes, output+blk*DES_BLOCK_SIZE,
                    lastblock, (word32)DES_BLOCK_SIZE);
            }
        }
        else {
            wc_Des_CbcDecrypt(&myDes, output, input, (word32)blk*DES_BLOCK_SIZE);
            if(lb_sz){
                wc_Des_CbcDecrypt(&myDes, lastblock, input+length-lb_sz, (word32)DES_BLOCK_SIZE);
                XMEMCPY(output+length-lb_sz, lastblock, lb_sz);
            }
        }
    }


    /* WOLFSSL_DES_key_schedule is a unsigned char array of size 8 */
    void wolfSSL_DES_ede3_cbc_encrypt(const unsigned char* input,
                                      unsigned char* output, long sz,
                                      WOLFSSL_DES_key_schedule* ks1,
                                      WOLFSSL_DES_key_schedule* ks2,
                                      WOLFSSL_DES_key_schedule* ks3,
                                      WOLFSSL_DES_cblock* ivec, int enc)
    {
        int ret;
        Des3 des;
        byte key[24];/* EDE uses 24 size key */
        byte lastblock[DES_BLOCK_SIZE];
        int  lb_sz;
        long  blk;

        WOLFSSL_ENTER("wolfSSL_DES_ede3_cbc_encrypt");

        XMEMSET(key, 0, sizeof(key));
        XMEMCPY(key, *ks1, DES_BLOCK_SIZE);
        XMEMCPY(&key[DES_BLOCK_SIZE], *ks2, DES_BLOCK_SIZE);
        XMEMCPY(&key[DES_BLOCK_SIZE * 2], *ks3, DES_BLOCK_SIZE);
        lb_sz = sz%DES_BLOCK_SIZE;
        blk   = sz/DES_BLOCK_SIZE;

        /* OpenSSL compat, no ret */
        (void)wc_Des3Init(&des, NULL, INVALID_DEVID);

        if (enc == DES_ENCRYPT) {
            if (wc_Des3_SetKey(&des, key, (const byte*)ivec,
                    DES_ENCRYPTION) == 0) {
                ret = wc_Des3_CbcEncrypt(&des, output, input, (word32)blk*DES_BLOCK_SIZE);
            #if defined(WOLFSSL_ASYNC_CRYPT)
                ret = wc_AsyncWait(ret, &des.asyncDev, WC_ASYNC_FLAG_NONE);
            #endif
                (void)ret; /* ignore return codes for processing */
                if(lb_sz){
                    XMEMSET(lastblock, 0, DES_BLOCK_SIZE);
                    XMEMCPY(lastblock, input+sz-lb_sz, lb_sz);
                    ret = wc_Des3_CbcEncrypt(&des, output+blk*DES_BLOCK_SIZE,
                        lastblock, (word32)DES_BLOCK_SIZE);
                #if defined(WOLFSSL_ASYNC_CRYPT)
                    ret = wc_AsyncWait(ret, &des.asyncDev, WC_ASYNC_FLAG_NONE);
                #endif
                    (void)ret; /* ignore return codes for processing */
                }
            }
        }
        else {
            if (wc_Des3_SetKey(&des, key, (const byte*)ivec,
                    DES_DECRYPTION) == 0) {
                ret = wc_Des3_CbcDecrypt(&des, output, input, (word32)blk*DES_BLOCK_SIZE);
            #if defined(WOLFSSL_ASYNC_CRYPT)
                ret = wc_AsyncWait(ret, &des.asyncDev, WC_ASYNC_FLAG_NONE);
            #endif
                (void)ret; /* ignore return codes for processing */
                if(lb_sz){
                    ret = wc_Des3_CbcDecrypt(&des, lastblock, input+sz-lb_sz, (word32)DES_BLOCK_SIZE);
                #if defined(WOLFSSL_ASYNC_CRYPT)
                    ret = wc_AsyncWait(ret, &des.asyncDev, WC_ASYNC_FLAG_NONE);
                #endif
                    (void)ret; /* ignore return codes for processing */
                    XMEMCPY(output+sz-lb_sz, lastblock, lb_sz);
                }
            }
        }
        wc_Des3Free(&des);
    }


    /* correctly sets ivec for next call */
    void wolfSSL_DES_ncbc_encrypt(const unsigned char* input,
                     unsigned char* output, long length,
                     WOLFSSL_DES_key_schedule* schedule, WOLFSSL_DES_cblock* ivec,
                     int enc)
    {
        Des myDes;
        byte lastblock[DES_BLOCK_SIZE];
        int  lb_sz;
        long idx = length;
        long blk;

        WOLFSSL_ENTER("DES_ncbc_encrypt");

        /* OpenSSL compat, no ret */
        if (wc_Des_SetKey(&myDes, (const byte*)schedule,
                         (const byte*)ivec, !enc) != 0) {
            WOLFSSL_MSG("wc_Des_SetKey return error.");
            return;
        }

        lb_sz = length%DES_BLOCK_SIZE;
        blk   = length/DES_BLOCK_SIZE;
        idx  -= sizeof(DES_cblock);
        if (lb_sz) {
            idx += DES_BLOCK_SIZE - lb_sz;
        }
        if (enc == DES_ENCRYPT){
            wc_Des_CbcEncrypt(&myDes, output, input,
                    (word32)blk * DES_BLOCK_SIZE);
            if (lb_sz){
                XMEMSET(lastblock, 0, DES_BLOCK_SIZE);
                XMEMCPY(lastblock, input+length-lb_sz, lb_sz);
                wc_Des_CbcEncrypt(&myDes, output + blk * DES_BLOCK_SIZE,
                    lastblock, (word32)DES_BLOCK_SIZE);
            }
            XMEMCPY(ivec, output + idx, sizeof(DES_cblock));
        } else {
            WOLFSSL_DES_cblock tmp;
            XMEMCPY(tmp, input + idx, sizeof(DES_cblock));
            wc_Des_CbcDecrypt(&myDes, output, input,
                    (word32)blk * DES_BLOCK_SIZE);
            if (lb_sz){
                wc_Des_CbcDecrypt(&myDes, lastblock, input + length - lb_sz,
                        (word32)DES_BLOCK_SIZE);
                XMEMCPY(output+length-lb_sz, lastblock, lb_sz);
            }
            XMEMCPY(ivec, tmp, sizeof(WOLFSSL_DES_cblock));
        }

    }

#endif /* NO_DES3 */

    void wolfSSL_ERR_free_strings(void)
    {
        /* handled internally */
    }

    void wolfSSL_cleanup_all_ex_data(void)
    {
        /* nothing to do here */
    }

#endif /* OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA) || defined(DEBUG_WOLFSSL_VERBOSE)
    void wolfSSL_ERR_clear_error(void)
    {
        WOLFSSL_ENTER("wolfSSL_ERR_clear_error");
        wc_ClearErrorNodes();
    }
#endif

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
    int wolfSSL_clear(WOLFSSL* ssl)
    {
        WOLFSSL_ENTER("wolfSSL_clear");

        if (ssl == NULL) {
            return WOLFSSL_FAILURE;
        }

        if (!ssl->options.handShakeDone) {
            /* Only reset the session if we didn't complete a handshake */
            wolfSSL_SESSION_free(ssl->session);
            ssl->session = wolfSSL_NewSession(ssl->heap);
            if (ssl->session == NULL) {
                return WOLFSSL_FAILURE;
            }
        }

        /* reset option bits */
        ssl->options.isClosed = 0;
        ssl->options.connReset = 0;
        ssl->options.sentNotify = 0;
        ssl->options.closeNotify = 0;
        ssl->options.sendVerify = 0;
        ssl->options.serverState = NULL_STATE;
        ssl->options.clientState = NULL_STATE;
        ssl->options.connectState = CONNECT_BEGIN;
        ssl->options.acceptState  = ACCEPT_BEGIN;
        ssl->options.handShakeState  = NULL_STATE;
        ssl->options.handShakeDone = 0;
        ssl->options.processReply = 0; /* doProcessInit */
        ssl->options.havePeerVerify = 0;
        ssl->options.havePeerCert = 0;
        ssl->options.peerAuthGood = 0;
        ssl->options.tls1_3 = 0;
        ssl->options.haveSessionId = 0;
        ssl->options.tls = 0;
        ssl->options.tls1_1 = 0;
        ssl->options.noPskDheKe = 0;
    #ifdef HAVE_SESSION_TICKET
        #ifdef WOLFSSL_TLS13
        ssl->options.ticketsSent = 0;
        #endif
        ssl->options.rejectTicket = 0;
    #endif
    #ifdef WOLFSSL_EARLY_DATA
        ssl->earlyData = no_early_data;
        ssl->earlyDataSz = 0;
    #endif

    #if defined(HAVE_TLS_EXTENSIONS) && !defined(NO_TLS)
        TLSX_FreeAll(ssl->extensions, ssl->heap);
        ssl->extensions = NULL;
    #endif

        ssl->keys.encryptionOn = 0;
        XMEMSET(&ssl->msgsReceived, 0, sizeof(ssl->msgsReceived));

        if (InitSSL_Suites(ssl) != WOLFSSL_SUCCESS)
            return WOLFSSL_FAILURE;

        if (InitHandshakeHashes(ssl) != 0)
            return WOLFSSL_FAILURE;

#ifdef KEEP_PEER_CERT
        FreeX509(&ssl->peerCert);
        InitX509(&ssl->peerCert, 0, ssl->heap);
#endif

#ifdef WOLFSSL_QUIC
        wolfSSL_quic_clear(ssl);
#endif

        return WOLFSSL_SUCCESS;
    }

#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL */

#if defined(OPENSSL_EXTRA) || defined(HAVE_WEBSERVER)
    long wolfSSL_CTX_set_mode(WOLFSSL_CTX* ctx, long mode)
    {
        /* WOLFSSL_MODE_ACCEPT_MOVING_WRITE_BUFFER is wolfSSL default mode */

        WOLFSSL_ENTER("SSL_CTX_set_mode");
        switch(mode) {
            case SSL_MODE_ENABLE_PARTIAL_WRITE:
                ctx->partialWrite = 1;
                break;
            #if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
            case SSL_MODE_RELEASE_BUFFERS:
                WOLFSSL_MSG("SSL_MODE_RELEASE_BUFFERS not implemented.");
                break;
            #endif
            case SSL_MODE_AUTO_RETRY:
                ctx->autoRetry = 1;
                break;
            default:
                WOLFSSL_MSG("Mode Not Implemented");
        }

        /* SSL_MODE_AUTO_RETRY
         * Should not return -1 with renegotiation on read/write */

        return mode;
    }

    long wolfSSL_CTX_clear_mode(WOLFSSL_CTX* ctx, long mode)
    {
        /* WOLFSSL_MODE_ACCEPT_MOVING_WRITE_BUFFER is wolfSSL default mode */

        WOLFSSL_ENTER("SSL_CTX_set_mode");
        switch(mode) {
            case SSL_MODE_ENABLE_PARTIAL_WRITE:
                ctx->partialWrite = 0;
                break;
            #if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
            case SSL_MODE_RELEASE_BUFFERS:
                WOLFSSL_MSG("SSL_MODE_RELEASE_BUFFERS not implemented.");
                break;
            #endif
            case SSL_MODE_AUTO_RETRY:
                ctx->autoRetry = 0;
                break;
            default:
                WOLFSSL_MSG("Mode Not Implemented");
        }

        /* SSL_MODE_AUTO_RETRY
         * Should not return -1 with renegotiation on read/write */

        return 0;
    }
#endif

#ifdef OPENSSL_EXTRA

    #ifndef NO_WOLFSSL_STUB
    long wolfSSL_SSL_get_mode(WOLFSSL* ssl)
    {
        /* TODO: */
        (void)ssl;
        WOLFSSL_STUB("SSL_get_mode");
        return 0;
    }
    #endif

    #ifndef NO_WOLFSSL_STUB
    long wolfSSL_CTX_get_mode(WOLFSSL_CTX* ctx)
    {
        /* TODO: */
        (void)ctx;
        WOLFSSL_STUB("SSL_CTX_get_mode");
        return 0;
    }
    #endif

    #ifndef NO_WOLFSSL_STUB
    void wolfSSL_CTX_set_default_read_ahead(WOLFSSL_CTX* ctx, int m)
    {
        /* TODO: maybe? */
        (void)ctx;
        (void)m;
        WOLFSSL_STUB("SSL_CTX_set_default_read_ahead");
    }
    #endif


    /* Storing app session context id, this value is inherited by WOLFSSL
     * objects created from WOLFSSL_CTX. Any session that is imported with a
     * different session context id will be rejected.
     *
     * ctx         structure to set context in
     * sid_ctx     value of context to set
     * sid_ctx_len length of sid_ctx buffer
     *
     * Returns WOLFSSL_SUCCESS in success case and SSL_FAILURE when failing
     */
    int wolfSSL_CTX_set_session_id_context(WOLFSSL_CTX* ctx,
                                           const unsigned char* sid_ctx,
                                           unsigned int sid_ctx_len)
    {
        WOLFSSL_ENTER("SSL_CTX_set_session_id_context");

        /* No application specific context needed for wolfSSL */
        if (sid_ctx_len > ID_LEN || ctx == NULL || sid_ctx == NULL) {
            return SSL_FAILURE;
        }
        XMEMCPY(ctx->sessionCtx, sid_ctx, sid_ctx_len);
        ctx->sessionCtxSz = (byte)sid_ctx_len;

        return WOLFSSL_SUCCESS;
    }



    /* Storing app session context id. Any session that is imported with a
     * different session context id will be rejected.
     *
     * ssl  structure to set context in
     * id   value of context to set
     * len  length of sid_ctx buffer
     *
     * Returns WOLFSSL_SUCCESS in success case and SSL_FAILURE when failing
     */
    int wolfSSL_set_session_id_context(WOLFSSL* ssl, const unsigned char* id,
                                   unsigned int len)
    {
        WOLFSSL_ENTER("wolfSSL_set_session_id_context");

        if (len > ID_LEN || ssl == NULL || id == NULL) {
            return SSL_FAILURE;
        }
        XMEMCPY(ssl->sessionCtx, id, len);
        ssl->sessionCtxSz = (byte)len;

        return WOLFSSL_SUCCESS;
    }


    long wolfSSL_CTX_sess_get_cache_size(WOLFSSL_CTX* ctx)
    {
        (void)ctx;
        #ifndef NO_SESSION_CACHE
            return (long)(SESSIONS_PER_ROW * SESSION_ROWS);
        #else
            return 0;
        #endif
    }


    /* returns the unsigned error value and increments the pointer into the
     * error queue.
     *
     * file  pointer to file name
     * line  gets set to line number of error when not NULL
     */
    unsigned long wolfSSL_ERR_get_error_line(const char** file, int* line)
    {
    #ifdef WOLFSSL_HAVE_ERROR_QUEUE
        int ret = wc_PullErrorNode(file, NULL, line);
        if (ret < 0) {
            if (ret == BAD_STATE_E) return 0; /* no errors in queue */
            WOLFSSL_MSG("Issue getting error node");
            WOLFSSL_LEAVE("wolfSSL_ERR_get_error_line", ret);
            ret = 0 - ret; /* return absolute value of error */

            /* panic and try to clear out nodes */
            wc_ClearErrorNodes();
        }
        return (unsigned long)ret;
    #else
        (void)file;
        (void)line;

        return 0;
    #endif
    }


#if (defined(DEBUG_WOLFSSL) || defined(OPENSSL_EXTRA)) && \
    (!defined(_WIN32) && !defined(NO_ERROR_QUEUE))
    static const char WOLFSSL_SYS_ACCEPT_T[]  = "accept";
    static const char WOLFSSL_SYS_BIND_T[]    = "bind";
    static const char WOLFSSL_SYS_CONNECT_T[] = "connect";
    static const char WOLFSSL_SYS_FOPEN_T[]   = "fopen";
    static const char WOLFSSL_SYS_FREAD_T[]   = "fread";
    static const char WOLFSSL_SYS_GETADDRINFO_T[] = "getaddrinfo";
    static const char WOLFSSL_SYS_GETSOCKOPT_T[]  = "getsockopt";
    static const char WOLFSSL_SYS_GETSOCKNAME_T[] = "getsockname";
    static const char WOLFSSL_SYS_GETHOSTBYNAME_T[] = "gethostbyname";
    static const char WOLFSSL_SYS_GETNAMEINFO_T[]   = "getnameinfo";
    static const char WOLFSSL_SYS_GETSERVBYNAME_T[] = "getservbyname";
    static const char WOLFSSL_SYS_IOCTLSOCKET_T[]   = "ioctlsocket";
    static const char WOLFSSL_SYS_LISTEN_T[]        = "listen";
    static const char WOLFSSL_SYS_OPENDIR_T[]       = "opendir";
    static const char WOLFSSL_SYS_SETSOCKOPT_T[]    = "setsockopt";
    static const char WOLFSSL_SYS_SOCKET_T[]        = "socket";

    /* switch with int mapped to function name for compatibility */
    static const char* wolfSSL_ERR_sys_func(int fun)
    {
        switch (fun) {
            case WOLFSSL_SYS_ACCEPT:      return WOLFSSL_SYS_ACCEPT_T;
            case WOLFSSL_SYS_BIND:        return WOLFSSL_SYS_BIND_T;
            case WOLFSSL_SYS_CONNECT:     return WOLFSSL_SYS_CONNECT_T;
            case WOLFSSL_SYS_FOPEN:       return WOLFSSL_SYS_FOPEN_T;
            case WOLFSSL_SYS_FREAD:       return WOLFSSL_SYS_FREAD_T;
            case WOLFSSL_SYS_GETADDRINFO: return WOLFSSL_SYS_GETADDRINFO_T;
            case WOLFSSL_SYS_GETSOCKOPT:  return WOLFSSL_SYS_GETSOCKOPT_T;
            case WOLFSSL_SYS_GETSOCKNAME: return WOLFSSL_SYS_GETSOCKNAME_T;
            case WOLFSSL_SYS_GETHOSTBYNAME: return WOLFSSL_SYS_GETHOSTBYNAME_T;
            case WOLFSSL_SYS_GETNAMEINFO: return WOLFSSL_SYS_GETNAMEINFO_T;
            case WOLFSSL_SYS_GETSERVBYNAME: return WOLFSSL_SYS_GETSERVBYNAME_T;
            case WOLFSSL_SYS_IOCTLSOCKET: return WOLFSSL_SYS_IOCTLSOCKET_T;
            case WOLFSSL_SYS_LISTEN:      return WOLFSSL_SYS_LISTEN_T;
            case WOLFSSL_SYS_OPENDIR:     return WOLFSSL_SYS_OPENDIR_T;
            case WOLFSSL_SYS_SETSOCKOPT:  return WOLFSSL_SYS_SETSOCKOPT_T;
            case WOLFSSL_SYS_SOCKET:      return WOLFSSL_SYS_SOCKET_T;
            default:
                return "NULL";
        }
    }
#endif /* DEBUG_WOLFSSL */


    void wolfSSL_ERR_put_error(int lib, int fun, int err, const char* file,
            int line)
    {
        WOLFSSL_ENTER("wolfSSL_ERR_put_error");

        #if !defined(DEBUG_WOLFSSL) && !defined(OPENSSL_EXTRA)
        (void)fun;
        (void)err;
        (void)file;
        (void)line;
        WOLFSSL_MSG("Not compiled in debug mode");
        #elif defined(OPENSSL_EXTRA) && \
                (defined(_WIN32) || defined(NO_ERROR_QUEUE))
        (void)fun;
        (void)file;
        (void)line;
        WOLFSSL_ERROR(err);
        #else
        WOLFSSL_ERROR_LINE(err, wolfSSL_ERR_sys_func(fun), (unsigned int)line,
            file, NULL);
        #endif
        (void)lib;
    }


    /* Similar to wolfSSL_ERR_get_error_line but takes in a flags argument for
     * more flexibility.
     *
     * file  output pointer to file where error happened
     * line  output to line number of error
     * data  output data. Is a string if ERR_TXT_STRING flag is used
     * flags output format of output
     *
     * Returns the error value or 0 if no errors are in the queue
     */
    unsigned long wolfSSL_ERR_get_error_line_data(const char** file, int* line,
                                                  const char** data, int *flags)
    {
#ifdef WOLFSSL_HAVE_ERROR_QUEUE
        int ret;

        WOLFSSL_ENTER("wolfSSL_ERR_get_error_line_data");

        if (flags != NULL)
            *flags = ERR_TXT_STRING; /* Clear the flags */

        ret = wc_PullErrorNode(file, data, line);
        if (ret < 0) {
            if (ret == BAD_STATE_E) return 0; /* no errors in queue */
            WOLFSSL_MSG("Error with pulling error node!");
            WOLFSSL_LEAVE("wolfSSL_ERR_get_error_line_data", ret);
            ret = 0 - ret; /* return absolute value of error */

            /* panic and try to clear out nodes */
            wc_ClearErrorNodes();
        }

        return (unsigned long)ret;
#else
        WOLFSSL_ENTER("wolfSSL_ERR_get_error_line_data");
        WOLFSSL_MSG("Error queue turned off, can not get error line");
        (void)file;
        (void)line;
        (void)data;
        (void)flags;
        return 0;
#endif
    }

#endif /* OPENSSL_EXTRA */


#if (defined(KEEP_PEER_CERT) && defined(SESSION_CERTS)) || \
    (defined(OPENSSL_EXTRA) && defined(SESSION_CERTS))
    /* Decode the X509 DER encoded certificate into a WOLFSSL_X509 object.
     *
     * x509  WOLFSSL_X509 object to decode into.
     * in    X509 DER data.
     * len   Length of the X509 DER data.
     * returns the new certificate on success, otherwise NULL.
     */
    static int DecodeToX509(WOLFSSL_X509* x509, const byte* in, int len)
    {
        int          ret;
    #ifdef WOLFSSL_SMALL_STACK
        DecodedCert* cert;
    #else
        DecodedCert  cert[1];
    #endif
        if (x509 == NULL || in == NULL || len <= 0)
            return BAD_FUNC_ARG;

    #ifdef WOLFSSL_SMALL_STACK
        cert = (DecodedCert*)XMALLOC(sizeof(DecodedCert), NULL,
                                     DYNAMIC_TYPE_DCERT);
        if (cert == NULL)
            return MEMORY_E;
    #endif

        /* Create a DecodedCert object and copy fields into WOLFSSL_X509 object.
         */
        InitDecodedCert(cert, (byte*)in, len, NULL);
        if ((ret = ParseCertRelative(cert, CERT_TYPE, 0, NULL)) == 0) {
        /* Check if x509 was not previously initialized by wolfSSL_X509_new() */
            if (x509->dynamicMemory != TRUE)
                InitX509(x509, 0, NULL);
            ret = CopyDecodedToX509(x509, cert);
            FreeDecodedCert(cert);
        }
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(cert, NULL, DYNAMIC_TYPE_DCERT);
    #endif

        return ret;
    }
#endif /* (KEEP_PEER_CERT & SESSION_CERTS) || (OPENSSL_EXTRA & SESSION_CERTS) */


#ifdef KEEP_PEER_CERT
    WOLFSSL_ABI
    WOLFSSL_X509* wolfSSL_get_peer_certificate(WOLFSSL* ssl)
    {
        WOLFSSL_X509* ret = NULL;
        WOLFSSL_ENTER("SSL_get_peer_certificate");
        if (ssl != NULL) {
            if (ssl->peerCert.issuer.sz)
                ret = wolfSSL_X509_dup(&ssl->peerCert);
#ifdef SESSION_CERTS
            else if (ssl->session->chain.count > 0) {
                if (DecodeToX509(&ssl->peerCert, ssl->session->chain.certs[0].buffer,
                        ssl->session->chain.certs[0].length) == 0) {
                    ret = wolfSSL_X509_dup(&ssl->peerCert);
                }
            }
#endif
        }
        WOLFSSL_LEAVE("SSL_get_peer_certificate", ret != NULL);
        return ret;
    }

#endif /* KEEP_PEER_CERT */

#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
/* Return stack of peer certs.
 * Caller does not need to free return. The stack is Free'd when WOLFSSL* ssl is.
 */
WOLF_STACK_OF(WOLFSSL_X509)* wolfSSL_get_peer_cert_chain(const WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_get_peer_cert_chain");

    if (ssl == NULL)
        return NULL;

    /* Try to populate if NULL or empty */
    if (ssl->peerCertChain == NULL ||
            wolfSSL_sk_X509_num(ssl->peerCertChain) == 0)
        wolfSSL_set_peer_cert_chain((WOLFSSL*) ssl);
    return ssl->peerCertChain;
}

#ifndef WOLFSSL_QT
static int x509GetIssuerFromCM(WOLFSSL_X509 **issuer, WOLFSSL_CERT_MANAGER* cm,
        WOLFSSL_X509 *x);
/**
 * Recursively push the issuer CA chain onto the stack
 * @param cm The cert manager that is queried for the issuer
 * @param x  This cert's issuer will be queried in cm
 * @param sk The issuer is pushed onto this stack
 * @return WOLFSSL_SUCCESS on success
 *         WOLFSSL_FAILURE on no issuer found
 *         WOLFSSL_FATAL_ERROR on a fatal error
 */
static int PushCAx509Chain(WOLFSSL_CERT_MANAGER* cm,
        WOLFSSL_X509 *x, WOLFSSL_STACK* sk)
{
    WOLFSSL_X509* issuer[MAX_CHAIN_DEPTH];
    int i;
    int push = 1;
    int ret = WOLFSSL_SUCCESS;

    for (i = 0; i < MAX_CHAIN_DEPTH; i++) {
        if (x509GetIssuerFromCM(&issuer[i], cm, x)
                != WOLFSSL_SUCCESS)
            break;
        x = issuer[i];
    }
    if (i == 0) /* No further chain found */
        return WOLFSSL_FAILURE;
    i--;
    for (; i >= 0; i--) {
        if (push) {
            if (wolfSSL_sk_X509_push(sk, issuer[i]) != WOLFSSL_SUCCESS) {
                wolfSSL_X509_free(issuer[i]);
                ret = WOLFSSL_FATAL_ERROR;
                push = 0; /* Free the rest of the unpushed certs */
            }
        }
        else {
            wolfSSL_X509_free(issuer[i]);
        }
    }
    return ret;
}
#endif /* !WOLFSSL_QT */

/* Builds up and creates a stack of peer certificates for ssl->peerCertChain
    based off of the ssl session chain. Attempts to place CA certificates
    at the bottom of the stack. Returns stack of WOLFSSL_X509 certs or
    NULL on failure */
WOLF_STACK_OF(WOLFSSL_X509)* wolfSSL_set_peer_cert_chain(WOLFSSL* ssl)
{
    WOLFSSL_STACK* sk;
    WOLFSSL_X509* x509;
    int i = 0;
    int ret;

    WOLFSSL_ENTER("wolfSSL_set_peer_cert_chain");
    if ((ssl == NULL) || (ssl->session->chain.count == 0))
        return NULL;

    sk = wolfSSL_sk_X509_new_null();
    i = ssl->session->chain.count-1;
    for (; i >= 0; i--) {
        x509 = wolfSSL_X509_new();
        if (x509 == NULL) {
            WOLFSSL_MSG("Error Creating X509");
            wolfSSL_sk_X509_pop_free(sk, NULL);
            return NULL;
        }
        ret = DecodeToX509(x509, ssl->session->chain.certs[i].buffer,
                             ssl->session->chain.certs[i].length);
#if !defined(WOLFSSL_QT)
        if (ret == 0 && i == ssl->session->chain.count-1) {
            /* On the last element in the chain try to add the CA chain
             * first if we have one for this cert */
            if (PushCAx509Chain(SSL_CM(ssl), x509, sk)
                    == WOLFSSL_FATAL_ERROR) {
                ret = WOLFSSL_FATAL_ERROR;
            }
        }
#endif

        if (ret != 0 || wolfSSL_sk_X509_push(sk, x509) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("Error decoding cert");
            wolfSSL_X509_free(x509);
            wolfSSL_sk_X509_pop_free(sk, NULL);
            return NULL;
        }
    }

    if (sk == NULL) {
        WOLFSSL_MSG("Null session chain");
    }
#if defined(OPENSSL_ALL)
    else if (ssl->options.side == WOLFSSL_SERVER_END) {
        /* to be compliant with openssl
           first element is kept as peer cert on server side.*/
        wolfSSL_sk_X509_pop(sk);
    }
#endif
    if (ssl->peerCertChain != NULL)
        wolfSSL_sk_X509_pop_free(ssl->peerCertChain, NULL);
    /* This is Free'd when ssl is Free'd */
    ssl->peerCertChain = sk;
    return sk;
}
#endif /* SESSION_CERTS && OPENSSL_EXTRA */

#ifndef NO_CERTS
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)

/* create a generic wolfSSL stack node
 * returns a new WOLFSSL_STACK structure on success */
WOLFSSL_STACK* wolfSSL_sk_new_node(void* heap)
{
    WOLFSSL_STACK* sk;
    WOLFSSL_ENTER("wolfSSL_sk_new_node");

    sk = (WOLFSSL_STACK*)XMALLOC(sizeof(WOLFSSL_STACK), heap,
                                                          DYNAMIC_TYPE_OPENSSL);
    if (sk != NULL) {
        XMEMSET(sk, 0, sizeof(*sk));
        sk->heap = heap;
    }

    return sk;
}

/* free's node but does not free internal data such as in->data.x509 */
void wolfSSL_sk_free_node(WOLFSSL_STACK* in)
{
    if (in != NULL) {
        XFREE(in, in->heap, DYNAMIC_TYPE_OPENSSL);
    }
}

/* pushes node "in" onto "stack" and returns pointer to the new stack on success
 * also handles internal "num" for number of nodes on stack
 * return WOLFSSL_SUCCESS on success
 */
int wolfSSL_sk_push_node(WOLFSSL_STACK** stack, WOLFSSL_STACK* in)
{
    if (stack == NULL || in == NULL) {
        return WOLFSSL_FAILURE;
    }

    if (*stack == NULL) {
        in->num = 1;
        *stack = in;
        return WOLFSSL_SUCCESS;
    }

    in->num  = (*stack)->num + 1;
    in->next = *stack;
    *stack   = in;
    return WOLFSSL_SUCCESS;
}

#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
static WC_INLINE int compare_WOLFSSL_CIPHER(
    WOLFSSL_CIPHER *a,
    WOLFSSL_CIPHER *b)
{
    if ((a->cipherSuite0 == b->cipherSuite0) &&
        (a->cipherSuite == b->cipherSuite) &&
        (a->ssl == b->ssl) &&
        (XMEMCMP(a->description, b->description, sizeof a->description) == 0) &&
        (a->offset == b->offset) &&
        (a->in_stack == b->in_stack) &&
        (a->bits == b->bits))
        return 0;
    else
        return -1;
}
#endif /* OPENSSL_ALL || WOLFSSL_QT */


/* return 1 on success 0 on fail */
int wolfSSL_sk_push(WOLFSSL_STACK* sk, const void *data)
{
    WOLFSSL_STACK* node;
#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
    WOLFSSL_CIPHER ciph;
#endif
    WOLFSSL_ENTER("wolfSSL_sk_push");

    if (!sk) {
        return WOLFSSL_FAILURE;
    }

    /* Check if empty data */
    switch (sk->type) {
        case STACK_TYPE_CIPHER:
#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
            /* check if entire struct is zero */
            XMEMSET(&ciph, 0, sizeof(WOLFSSL_CIPHER));
            if (compare_WOLFSSL_CIPHER(&sk->data.cipher, &ciph) == 0) {
                sk->data.cipher = *(WOLFSSL_CIPHER*)data;
                sk->num = 1;
                if (sk->hash_fn) {
                    sk->hash = sk->hash_fn(&sk->data.cipher);
                }
                return WOLFSSL_SUCCESS;
            }
            break;
#endif
        case STACK_TYPE_X509:
        case STACK_TYPE_GEN_NAME:
        case STACK_TYPE_BIO:
        case STACK_TYPE_OBJ:
        case STACK_TYPE_STRING:
        case STACK_TYPE_ACCESS_DESCRIPTION:
        case STACK_TYPE_X509_EXT:
        case STACK_TYPE_X509_REQ_ATTR:
        case STACK_TYPE_NULL:
        case STACK_TYPE_X509_NAME:
        case STACK_TYPE_X509_NAME_ENTRY:
        case STACK_TYPE_CONF_VALUE:
        case STACK_TYPE_X509_INFO:
        case STACK_TYPE_BY_DIR_entry:
        case STACK_TYPE_BY_DIR_hash:
        case STACK_TYPE_X509_OBJ:
        case STACK_TYPE_DIST_POINT:
        case STACK_TYPE_X509_CRL:
        default:
            /* All other types are pointers */
            if (!sk->data.generic) {
                sk->data.generic = (void*)data;
                sk->num = 1;
#ifdef OPENSSL_ALL
                if (sk->hash_fn) {
                    sk->hash = sk->hash_fn(sk->data.generic);
                }
#endif
                return WOLFSSL_SUCCESS;
            }
            break;
    }

    /* stack already has value(s) create a new node and add more */
    node = wolfSSL_sk_new_node(sk->heap);
    if (!node) {
        WOLFSSL_MSG("Memory error");
        return WOLFSSL_FAILURE;
    }

    /* push new x509 onto head of stack */
    node->next      = sk->next;
    node->type      = sk->type;
    sk->next        = node;
    sk->num        += 1;

#ifdef OPENSSL_ALL
    node->hash_fn = sk->hash_fn;
    node->hash = sk->hash;
    sk->hash = 0;
#endif
    switch (sk->type) {
        case STACK_TYPE_CIPHER:
#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
            node->data.cipher = sk->data.cipher;
            sk->data.cipher = *(WOLFSSL_CIPHER*)data;
            if (sk->hash_fn) {
                sk->hash = sk->hash_fn(&sk->data.cipher);
            }
            break;
#endif
        case STACK_TYPE_X509:
        case STACK_TYPE_GEN_NAME:
        case STACK_TYPE_BIO:
        case STACK_TYPE_OBJ:
        case STACK_TYPE_STRING:
        case STACK_TYPE_ACCESS_DESCRIPTION:
        case STACK_TYPE_X509_EXT:
        case STACK_TYPE_X509_REQ_ATTR:
        case STACK_TYPE_NULL:
        case STACK_TYPE_X509_NAME:
        case STACK_TYPE_X509_NAME_ENTRY:
        case STACK_TYPE_CONF_VALUE:
        case STACK_TYPE_X509_INFO:
        case STACK_TYPE_BY_DIR_entry:
        case STACK_TYPE_BY_DIR_hash:
        case STACK_TYPE_X509_OBJ:
        case STACK_TYPE_DIST_POINT:
        case STACK_TYPE_X509_CRL:
        default:
            /* All other types are pointers */
            node->data.generic = sk->data.generic;
            sk->data.generic = (void*)data;
#ifdef OPENSSL_ALL
            if (sk->hash_fn) {
                sk->hash = sk->hash_fn(sk->data.generic);
            }
#endif
            break;
    }

    return WOLFSSL_SUCCESS;
}

#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL */

#ifdef OPENSSL_EXTRA

/* returns the node at index "idx", NULL if not found */
WOLFSSL_STACK* wolfSSL_sk_get_node(WOLFSSL_STACK* sk, int idx)
{
    int i;
    WOLFSSL_STACK* ret = NULL;
    WOLFSSL_STACK* current;

    current = sk;
    for (i = 0; i <= idx && current != NULL; i++) {
        if (i == idx) {
            ret = current;
            break;
        }
        current = current->next;
    }
    return ret;
}


#endif /* OPENSSL_EXTRA */

#ifdef OPENSSL_EXTRA

#if defined(OPENSSL_ALL)

void *wolfSSL_lh_retrieve(WOLFSSL_STACK *sk, void *data)
{
    unsigned long hash;

    WOLFSSL_ENTER("wolfSSL_lh_retrieve");

    if (!sk || !data) {
        WOLFSSL_MSG("Bad parameters");
        return NULL;
    }

    if (!sk->hash_fn) {
        WOLFSSL_MSG("No hash function defined");
        return NULL;
    }

    hash = sk->hash_fn(data);

    while (sk) {
        /* Calc hash if not done so yet */
        if (!sk->hash) {
            switch (sk->type) {
                case STACK_TYPE_CIPHER:
                    sk->hash = sk->hash_fn(&sk->data.cipher);
                    break;
                case STACK_TYPE_X509:
                case STACK_TYPE_GEN_NAME:
                case STACK_TYPE_BIO:
                case STACK_TYPE_OBJ:
                case STACK_TYPE_STRING:
                case STACK_TYPE_ACCESS_DESCRIPTION:
                case STACK_TYPE_X509_EXT:
                case STACK_TYPE_X509_REQ_ATTR:
                case STACK_TYPE_NULL:
                case STACK_TYPE_X509_NAME:
                case STACK_TYPE_X509_NAME_ENTRY:
                case STACK_TYPE_CONF_VALUE:
                case STACK_TYPE_X509_INFO:
                case STACK_TYPE_BY_DIR_entry:
                case STACK_TYPE_BY_DIR_hash:
                case STACK_TYPE_X509_OBJ:
                case STACK_TYPE_DIST_POINT:
                case STACK_TYPE_X509_CRL:
                default:
                    sk->hash = sk->hash_fn(sk->data.generic);
                    break;
            }
        }
        if (sk->hash == hash) {
            switch (sk->type) {
                case STACK_TYPE_CIPHER:
                    return &sk->data.cipher;
                case STACK_TYPE_X509:
                case STACK_TYPE_GEN_NAME:
                case STACK_TYPE_BIO:
                case STACK_TYPE_OBJ:
                case STACK_TYPE_STRING:
                case STACK_TYPE_ACCESS_DESCRIPTION:
                case STACK_TYPE_X509_EXT:
                case STACK_TYPE_X509_REQ_ATTR:
                case STACK_TYPE_NULL:
                case STACK_TYPE_X509_NAME:
                case STACK_TYPE_X509_NAME_ENTRY:
                case STACK_TYPE_CONF_VALUE:
                case STACK_TYPE_X509_INFO:
                case STACK_TYPE_BY_DIR_entry:
                case STACK_TYPE_BY_DIR_hash:
                case STACK_TYPE_X509_OBJ:
                case STACK_TYPE_DIST_POINT:
                case STACK_TYPE_X509_CRL:
                default:
                    return sk->data.generic;
            }
        }
        sk = sk->next;
    }

    return NULL;
}

#endif /* OPENSSL_ALL */

#endif /* OPENSSL_EXTRA */

/* OPENSSL_EXTRA is needed for wolfSSL_X509_d21 function
   KEEP_OUR_CERT is to insure ability for returning ssl certificate */
#if (defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)) && \
    defined(KEEP_OUR_CERT)
WOLFSSL_X509* wolfSSL_get_certificate(WOLFSSL* ssl)
{
    if (ssl == NULL) {
        return NULL;
    }

    if (ssl->buffers.weOwnCert) {
        if (ssl->ourCert == NULL) {
            if (ssl->buffers.certificate == NULL) {
                WOLFSSL_MSG("Certificate buffer not set!");
                return NULL;
            }
            #ifndef WOLFSSL_X509_STORE_CERTS
            ssl->ourCert = wolfSSL_X509_d2i(NULL,
                                              ssl->buffers.certificate->buffer,
                                              ssl->buffers.certificate->length);
            #endif
        }
        return ssl->ourCert;
    }
    else { /* if cert not owned get parent ctx cert or return null */
        if (ssl->ctx) {
            if (ssl->ctx->ourCert == NULL) {
                if (ssl->ctx->certificate == NULL) {
                    WOLFSSL_MSG("Ctx Certificate buffer not set!");
                    return NULL;
                }
                #ifndef WOLFSSL_X509_STORE_CERTS
                ssl->ctx->ourCert = wolfSSL_X509_d2i(NULL,
                                               ssl->ctx->certificate->buffer,
                                               ssl->ctx->certificate->length);
                #endif
                ssl->ctx->ownOurCert = 1;
            }
            return ssl->ctx->ourCert;
        }
    }

    return NULL;
}

WOLFSSL_X509* wolfSSL_CTX_get0_certificate(WOLFSSL_CTX* ctx)
{
    if (ctx) {
        if (ctx->ourCert == NULL) {
            if (ctx->certificate == NULL) {
                WOLFSSL_MSG("Ctx Certificate buffer not set!");
                return NULL;
            }
            #ifndef WOLFSSL_X509_STORE_CERTS
            ctx->ourCert = wolfSSL_X509_d2i(NULL,
                                           ctx->certificate->buffer,
                                           ctx->certificate->length);
            #endif
            ctx->ownOurCert = 1;
        }
        return ctx->ourCert;
    }
    return NULL;
}
#endif /* OPENSSL_EXTRA && KEEP_OUR_CERT */
#endif /* NO_CERTS */


#if !defined(NO_ASN) && (defined(OPENSSL_EXTRA) || \
        defined(OPENSSL_EXTRA_X509_SMALL))
void wolfSSL_ASN1_OBJECT_free(WOLFSSL_ASN1_OBJECT* obj)
{
    if (obj == NULL) {
        return;
    }
    if ((obj->obj != NULL) && ((obj->dynamic & WOLFSSL_ASN1_DYNAMIC_DATA) != 0)) {
#ifdef WOLFSSL_DEBUG_OPENSSL
        WOLFSSL_MSG("Freeing ASN1 data");
#endif
        XFREE((void*)obj->obj, obj->heap, DYNAMIC_TYPE_ASN1);
        obj->obj = NULL;
    }
    #if defined(WOLFSSL_QT) || defined(OPENSSL_ALL)
    if (obj->pathlen != NULL) {
        wolfSSL_ASN1_INTEGER_free(obj->pathlen);
        obj->pathlen = NULL;
    }
    #endif
    if ((obj->dynamic & WOLFSSL_ASN1_DYNAMIC) != 0) {
#ifdef WOLFSSL_DEBUG_OPENSSL
        WOLFSSL_MSG("Freeing ASN1 OBJECT");
#endif
        XFREE(obj, NULL, DYNAMIC_TYPE_ASN1);
    }
}

WOLFSSL_ASN1_OBJECT* wolfSSL_ASN1_OBJECT_new(void)
{
    WOLFSSL_ASN1_OBJECT* obj;

    obj = (WOLFSSL_ASN1_OBJECT*)XMALLOC(sizeof(WOLFSSL_ASN1_OBJECT), NULL,
                                        DYNAMIC_TYPE_ASN1);
    if (obj == NULL) {
        return NULL;
    }

    XMEMSET(obj, 0, sizeof(WOLFSSL_ASN1_OBJECT));
    obj->d.ia5 = &(obj->d.ia5_internal);
#if defined(WOLFSSL_QT) || defined(OPENSSL_ALL)
    obj->d.iPAddress = &(obj->d.iPAddress_internal);
#endif
    obj->dynamic |= WOLFSSL_ASN1_DYNAMIC;
    return obj;
}

WOLFSSL_ASN1_OBJECT* wolfSSL_ASN1_OBJECT_dup(WOLFSSL_ASN1_OBJECT* obj)
{
    WOLFSSL_ASN1_OBJECT* dupl = NULL;

    WOLFSSL_ENTER("wolfSSL_ASN1_OBJECT_dup");

    if (!obj) {
        WOLFSSL_MSG("Bad parameter");
        return NULL;
    }
    dupl = wolfSSL_ASN1_OBJECT_new();
    if (!dupl) {
        WOLFSSL_MSG("wolfSSL_ASN1_OBJECT_new error");
        return NULL;
    }
    /* Copy data */
    XMEMCPY(dupl->sName, obj->sName, WOLFSSL_MAX_SNAME);
    dupl->type = obj->type;
    dupl->grp = obj->grp;
    dupl->nid = obj->nid;
    dupl->objSz = obj->objSz;
    if (obj->obj) {
        dupl->obj = (const unsigned char*)XMALLOC(
                obj->objSz, NULL, DYNAMIC_TYPE_ASN1);
        if (!dupl->obj) {
            WOLFSSL_MSG("ASN1 obj malloc error");
            wolfSSL_ASN1_OBJECT_free(dupl);
            return NULL;
        }
        XMEMCPY((byte*)dupl->obj, obj->obj, obj->objSz);
        dupl->dynamic |= WOLFSSL_ASN1_DYNAMIC_DATA;
    }
    return dupl;
}
#endif /* !NO_ASN && (OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL) */

#ifndef NO_ASN
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
/* Creates and returns a new WOLFSSL_CIPHER stack. */
WOLFSSL_STACK* wolfSSL_sk_new_asn1_obj(void)
{
    WOLFSSL_STACK* sk;
    WOLFSSL_ENTER("wolfSSL_sk_new_asn1_obj");

    sk = wolfSSL_sk_new_null();
    if (sk == NULL)
        return NULL;
    sk->type = STACK_TYPE_OBJ;

    return sk;
}

/* return 1 on success 0 on fail */
int wolfSSL_sk_ASN1_OBJECT_push(WOLF_STACK_OF(WOLFSSL_ASN1_OBJECT)* sk,
                                              WOLFSSL_ASN1_OBJECT* obj)
{
    WOLFSSL_ENTER("wolfSSL_sk_ASN1_OBJECT_push");

    if (sk == NULL || obj == NULL) {
        return WOLFSSL_FAILURE;
    }

    return wolfSSL_sk_push(sk, obj);
}


WOLFSSL_ASN1_OBJECT* wolfSSL_sk_ASN1_OBJECT_pop(
                                        WOLF_STACK_OF(WOLFSSL_ASN1_OBJECT)* sk)
{
    WOLFSSL_STACK* node;
    WOLFSSL_ASN1_OBJECT* obj;

    if (sk == NULL) {
        return NULL;
    }

    node = sk->next;
    obj = sk->data.obj;

    if (node != NULL) { /* update sk and remove node from stack */
        sk->data.obj = node->data.obj;
        sk->next = node->next;
        XFREE(node, NULL, DYNAMIC_TYPE_ASN1);
    }
    else { /* last obj in stack */
        sk->data.obj = NULL;
    }

    if (sk->num > 0) {
        sk->num -= 1;
    }

    return obj;
}


/* Free the structure for ASN1_OBJECT stack
 *
 * sk  stack to free nodes in
 */
void wolfSSL_sk_ASN1_OBJECT_free(WOLF_STACK_OF(WOLFSSL_ASN1_OBJECT)* sk)
{
    wolfSSL_sk_free(sk);
}

/* Free's all nodes in ASN1_OBJECT stack.
 * This is different then wolfSSL_ASN1_OBJECT_free in that it allows for
 * choosing the function to use when freeing an ASN1_OBJECT stack.
 *
 * sk  stack to free nodes in
 * f   X509 free function
 */
void wolfSSL_sk_ASN1_OBJECT_pop_free(WOLF_STACK_OF(WOLFSSL_ASN1_OBJECT)* sk,
                                     void (*f) (WOLFSSL_ASN1_OBJECT*))
{
    WOLFSSL_ENTER("wolfSSL_sk_ASN1_OBJECT_pop_free");
    wolfSSL_sk_pop_free(sk, (wolfSSL_sk_freefunc)f);
}

#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL */
#endif /* !NO_ASN */

#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
#ifndef NO_ASN

int wolfSSL_ASN1_STRING_to_UTF8(unsigned char **out, WOLFSSL_ASN1_STRING *in)
{
    /*
       ASN1_STRING_to_UTF8() converts the string in to UTF8 format,
       the converted data is allocated in a buffer in *out.
       The length of out is returned or a negative error code.
       The buffer *out should be free using OPENSSL_free().
       */
    unsigned char* buf;
    unsigned char* inPtr;
    int inLen;

    if (!out || !in) {
        return -1;
    }

    inPtr = wolfSSL_ASN1_STRING_data(in);
    inLen = wolfSSL_ASN1_STRING_length(in);
    if (!inPtr || inLen < 0) {
        return -1;
    }
    buf = (unsigned char*)XMALLOC(inLen + 1, NULL, DYNAMIC_TYPE_OPENSSL);
    if (!buf) {
        return -1;
    }
    XMEMCPY(buf, inPtr, inLen + 1);
    *out = buf;
    return inLen;
}
#endif /* !NO_ASN */
#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL */

#if defined(OPENSSL_EXTRA)
#ifndef NO_ASN

int wolfSSL_ASN1_UNIVERSALSTRING_to_string(WOLFSSL_ASN1_STRING *s)
{
    char *idx;
    char *copy;
    WOLFSSL_ENTER("wolfSSL_ASN1_UNIVERSALSTRING_to_string");

    if (!s) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }

    if (s->type != V_ASN1_UNIVERSALSTRING) {
        WOLFSSL_MSG("Input is not a universal string");
        return WOLFSSL_FAILURE;
    }

    if ((s->length % 4) != 0) {
        WOLFSSL_MSG("Input string must be divisible by 4");
        return WOLFSSL_FAILURE;
    }

    for (idx = s->data; idx < s->data + s->length; idx += 4)
        if ((idx[0] != '\0') || (idx[1] != '\0') || (idx[2] != '\0'))
            break;

    if (idx != s->data + s->length) {
        WOLFSSL_MSG("Wrong string format");
        return WOLFSSL_FAILURE;
    }

    for (copy = idx = s->data; idx < s->data + s->length; idx += 4)
        *copy++ = idx[3];
    *copy = '\0';
    s->length /= 4;
    s->type = V_ASN1_PRINTABLESTRING;
    return WOLFSSL_SUCCESS;
}

/* Returns string representation of ASN1_STRING */
char* wolfSSL_i2s_ASN1_STRING(WOLFSSL_v3_ext_method *method,
    const WOLFSSL_ASN1_STRING *s)
{
    int i;
    int tmpSz = 100;
    int valSz = 5;
    char* tmp;
    char val[5];
    unsigned char* str;

    WOLFSSL_ENTER("wolfSSL_i2s_ASN1_STRING");
    (void)method;

    if(s == NULL || s->data == NULL) {
        WOLFSSL_MSG("Bad Function Argument");
        return NULL;
    }
    str = (unsigned char*)XMALLOC(s->length, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    if (str == NULL) {
        WOLFSSL_MSG("Memory Error");
        return NULL;
    }
    XMEMCPY(str, (unsigned char*)s->data, s->length);

    tmp = (char*)XMALLOC(tmpSz, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    if (tmp == NULL) {
        WOLFSSL_MSG("Memory Error");
        XFREE(str, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        return NULL;
    }
    XMEMSET(tmp, 0, tmpSz);

    for (i = 0; i < tmpSz && i < (s->length - 1); i++) {
        if (XSNPRINTF(val, valSz, "%02X:", str[i])
            >= valSz)
        {
            WOLFSSL_MSG("Buffer overrun");
            XFREE(str, NULL, DYNAMIC_TYPE_TMP_BUFFER);
            return NULL;
        }
        XSTRNCAT(tmp, val, valSz);
    }
    if (XSNPRINTF(val, valSz, "%02X", str[i])
        >= valSz)
    {
        WOLFSSL_MSG("Buffer overrun");
        XFREE(str, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        return NULL;
    }

    XSTRNCAT(tmp, val, valSz);
    XFREE(str, NULL, DYNAMIC_TYPE_TMP_BUFFER);

    return tmp;
}
#endif /* NO_ASN */
#endif /* OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
void wolfSSL_set_connect_state(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_set_connect_state");
    if (ssl == NULL) {
        WOLFSSL_MSG("WOLFSSL struct pointer passed in was null");
        return;
    }

    #ifndef NO_DH
    /* client creates its own DH parameters on handshake */
    if (ssl->buffers.serverDH_P.buffer && ssl->buffers.weOwnDH) {
        XFREE(ssl->buffers.serverDH_P.buffer, ssl->heap,
            DYNAMIC_TYPE_PUBLIC_KEY);
    }
    ssl->buffers.serverDH_P.buffer = NULL;
    if (ssl->buffers.serverDH_G.buffer && ssl->buffers.weOwnDH) {
        XFREE(ssl->buffers.serverDH_G.buffer, ssl->heap,
            DYNAMIC_TYPE_PUBLIC_KEY);
    }
    ssl->buffers.serverDH_G.buffer = NULL;
    #endif

    if (InitSSL_Side(ssl, WOLFSSL_CLIENT_END) != WOLFSSL_SUCCESS) {
        WOLFSSL_MSG("Error initializing client side");
    }
}
#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL */


int wolfSSL_get_shutdown(const WOLFSSL* ssl)
{
    int isShutdown = 0;

    WOLFSSL_ENTER("wolfSSL_get_shutdown");

    if (ssl) {
#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
        if (ssl->options.handShakeState == NULL_STATE) {
            /* The SSL object was possibly cleared with wolfSSL_clear after
             * a successful shutdown. Simulate a response for a full
             * bidirectional shutdown. */
            isShutdown = WOLFSSL_SENT_SHUTDOWN | WOLFSSL_RECEIVED_SHUTDOWN;
        }
        else
#endif
        {
            /* in OpenSSL, WOLFSSL_SENT_SHUTDOWN = 1, when closeNotifySent   *
             * WOLFSSL_RECEIVED_SHUTDOWN = 2, from close notify or fatal err */
            if (ssl->options.sentNotify)
                isShutdown |= WOLFSSL_SENT_SHUTDOWN;
            if (ssl->options.closeNotify||ssl->options.connReset)
                isShutdown |= WOLFSSL_RECEIVED_SHUTDOWN;
        }

    }
    return isShutdown;
}


int wolfSSL_session_reused(WOLFSSL* ssl)
{
    int resuming = 0;
    WOLFSSL_ENTER("wolfSSL_session_reused");
    if (ssl)
        resuming = ssl->options.resuming;
    WOLFSSL_LEAVE("wolfSSL_session_reused", resuming);
    return resuming;
}

/* return a new malloc'd session with default settings on success */
WOLFSSL_SESSION* wolfSSL_NewSession(void* heap)
{
    WOLFSSL_SESSION* ret = NULL;

    ret = (WOLFSSL_SESSION*)XMALLOC(sizeof(WOLFSSL_SESSION), heap,
            DYNAMIC_TYPE_SESSION);
    if (ret != NULL) {
        XMEMSET(ret, 0, sizeof(WOLFSSL_SESSION));
    #ifndef SINGLE_THREADED
        if (wc_InitMutex(&ret->refMutex) != 0) {
            WOLFSSL_MSG("Error setting up session reference mutex");
            XFREE(ret, ret->heap, DYNAMIC_TYPE_SESSION);
            return NULL;
        }
    #endif
        ret->refCount = 1;
#ifndef NO_SESSION_CACHE
        ret->cacheRow = INVALID_SESSION_ROW; /* not in cache */
#endif
        ret->type = WOLFSSL_SESSION_TYPE_HEAP;
        ret->heap = heap;
#ifdef WOLFSSL_CHECK_MEM_ZERO
        wc_MemZero_Add("SESSION master secret", ret->masterSecret, SECRET_LEN);
        wc_MemZero_Add("SESSION id", ret->sessionID, ID_LEN);
#endif
    #ifdef HAVE_SESSION_TICKET
        ret->ticket = ret->staticTicket;
        #if defined(WOLFSSL_TLS13) && defined(WOLFSSL_TICKET_NONCE_MALLOC) &&  \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
        ret->ticketNonce.data = ret->ticketNonce.dataStatic;
        #endif
    #endif
#ifdef HAVE_STUNNEL
        /* stunnel has this funny mechanism of storing the "is_authenticated"
         * session info in the session ex data. This is basically their
         * default so let's just hard code it. */
        if (wolfSSL_SESSION_set_ex_data(ret, 0, (void *)(-1))
                != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("Error setting up ex data for stunnel");
            XFREE(ret, NULL, DYNAMIC_TYPE_SESSION);
            return NULL;
        }
#endif
#ifdef HAVE_EX_DATA
        ret->ownExData = 1;
#endif
    }
    return ret;
}


WOLFSSL_SESSION* wolfSSL_SESSION_new_ex(void* heap)
{
    return wolfSSL_NewSession(heap);
}

WOLFSSL_SESSION* wolfSSL_SESSION_new(void)
{
    return wolfSSL_SESSION_new_ex(NULL);
}

/* add one to session reference count
 * return WOLFSSL_SUCCESS on success and WOLFSSL_FAILURE on error */
int wolfSSL_SESSION_up_ref(WOLFSSL_SESSION* session)
{
    session = ClientSessionToSession(session);

    if (session == NULL || session->type != WOLFSSL_SESSION_TYPE_HEAP)
        return WOLFSSL_FAILURE;

#ifndef SINGLE_THREADED
    if (wc_LockMutex(&session->refMutex) != 0) {
        WOLFSSL_MSG("Failed to lock session mutex");
        return WOLFSSL_FAILURE;
    }
#endif
    session->refCount++;
#ifndef SINGLE_THREADED
    wc_UnLockMutex(&session->refMutex);
#endif
    return WOLFSSL_SUCCESS;
}

/**
 * Deep copy the contents from input to output.
 * @param input         The source of the copy.
 * @param output        The destination of the copy.
 * @param avoidSysCalls If true, then system calls will be avoided or an error
 *                      will be returned if it is not possible to proceed
 *                      without a system call. This is useful for fetching
 *                      sessions from cache. When a cache row is locked, we
 *                      don't want to block other threads with long running
 *                      system calls.
 * @param ticketNonceBuf If not null and @avoidSysCalls is true, the copy of the
 *                      ticketNonce will happen in this pre allocated buffer
 * @param ticketNonceLen @ticketNonceBuf len as input, used length on output
 * @param ticketNonceUsed if @ticketNonceBuf was used to copy the ticket noncet
 * @return              WOLFSSL_SUCCESS on success
 *                      WOLFSSL_FAILURE on failure
 */
static int wolfSSL_DupSessionEx(const WOLFSSL_SESSION* input,
    WOLFSSL_SESSION* output, int avoidSysCalls, byte* ticketNonceBuf,
    byte* ticketNonceLen, byte* preallocUsed)
{
#ifdef HAVE_SESSION_TICKET
    int   ticLenAlloc = 0;
    byte *ticBuff = NULL;
#endif
    const size_t copyOffset = OFFSETOF(WOLFSSL_SESSION, heap) + sizeof(input->heap);
    int ret = WOLFSSL_SUCCESS;

    (void)avoidSysCalls;
    (void)ticketNonceBuf;
    (void)ticketNonceLen;
    (void)preallocUsed;

    input = ClientSessionToSession(input);
    output = ClientSessionToSession(output);

    if (input == NULL || output == NULL || input == output) {
        WOLFSSL_MSG("input or output are null or same");
        return WOLFSSL_FAILURE;
    }

#ifdef HAVE_SESSION_TICKET
    if (output->ticket != output->staticTicket) {
        ticBuff = output->ticket;
        ticLenAlloc = output->ticketLenAlloc;
    }
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_TICKET_NONCE_MALLOC) &&          \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
        /* free the data, it would be better to re-use the buffer but this
         * maintain the code simpler. A smart allocator should re-use the free'd
         * buffer in the next malloc without much performance penalties. */
    if (output->ticketNonce.data != output->ticketNonce.dataStatic) {

        /*  Callers that avoid syscall should never calls this with
         * output->tickeNonce.data being a dynamic buffer.*/
        if (avoidSysCalls) {
            WOLFSSL_MSG("can't avoid syscalls with dynamic TicketNonce buffer");
            return WOLFSSL_FAILURE;
        }

        XFREE(output->ticketNonce.data,
            output->heap, DYNAMIC_TYPE_SESSION_TICK);
        output->ticketNonce.data = output->ticketNonce.dataStatic;
        output->ticketNonce.len = 0;
    }
#endif /* WOLFSSL_TLS13 && WOLFSSL_TICKET_NONCE_MALLOC && FIPS_VERSION_GE(5,3)*/
#endif /* HAVE_SESSION_TICKET */

#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
    if (output->peer != NULL) {
        if (avoidSysCalls) {
            WOLFSSL_MSG("Can't free cert when avoiding syscalls");
            return WOLFSSL_FAILURE;
        }
        wolfSSL_X509_free(output->peer);
        output->peer = NULL;
    }
#endif

    XMEMCPY((byte*)output + copyOffset, (byte*)input + copyOffset,
            sizeof(WOLFSSL_SESSION) - copyOffset);

#if defined(HAVE_SESSION_TICKET) && defined(WOLFSSL_TLS13) &&                  \
    defined(WOLFSSL_TICKET_NONCE_MALLOC) &&                                    \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
    /* fix pointer to static after the copy  */
    output->ticketNonce.data = output->ticketNonce.dataStatic;
#endif
    /* Set sane values for copy */
#ifndef NO_SESSION_CACHE
    if (output->type != WOLFSSL_SESSION_TYPE_CACHE)
        output->cacheRow = INVALID_SESSION_ROW;
#endif
#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
    if (input->peer != NULL && input->peer->dynamicMemory) {
        if (wolfSSL_X509_up_ref(input->peer) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("Can't increase peer cert ref count");
            output->peer = NULL;
        }
    }
    else if (!avoidSysCalls)
        output->peer = wolfSSL_X509_dup(input->peer);
    else
        /* output->peer is not that important to copy */
        output->peer = NULL;
#endif
#ifdef HAVE_SESSION_TICKET
    if (input->ticketLen > SESSION_TICKET_LEN) {
        /* Need dynamic buffer */
        if (ticBuff == NULL || ticLenAlloc < input->ticketLen) {
            /* allocate new one */
            byte* tmp;
            if (avoidSysCalls) {
                WOLFSSL_MSG("Failed to allocate memory for ticket when avoiding"
                        " syscalls");
                output->ticket = ticBuff;
                output->ticketLenAlloc = (word16) ticLenAlloc;
                output->ticketLen = 0;
                ret = WOLFSSL_FAILURE;
            }
            else {
                tmp = (byte*)XREALLOC(ticBuff, input->ticketLen,
                        output->heap, DYNAMIC_TYPE_SESSION_TICK);
                if (tmp == NULL) {
                    WOLFSSL_MSG("Failed to allocate memory for ticket");
                    XFREE(ticBuff, output->heap, DYNAMIC_TYPE_SESSION_TICK);
                    output->ticket = NULL;
                    output->ticketLen = 0;
                    output->ticketLenAlloc = 0;
                    ret = WOLFSSL_FAILURE;
                }
                else {
                    ticBuff = tmp;
                    ticLenAlloc = input->ticketLen;
                }
            }
        }
        if (ticBuff != NULL && ret == WOLFSSL_SUCCESS) {
            XMEMCPY(ticBuff, input->ticket, input->ticketLen);
            output->ticket = ticBuff;
            output->ticketLenAlloc = (word16) ticLenAlloc;
        }
    }
    else {
        /* Default ticket to non dynamic */
        if (avoidSysCalls) {
            /* Try to use ticBuf if available. Caller can later move it to
             * the static buffer. */
            if (ticBuff != NULL) {
                if (ticLenAlloc >= input->ticketLen) {
                    output->ticket = output->staticTicket;
                    output->ticketLenAlloc = 0;
                }
                else {
                    WOLFSSL_MSG("ticket dynamic buffer too small but we are "
                                "avoiding system calls");
                    ret = WOLFSSL_FAILURE;
                    output->ticket = ticBuff;
                    output->ticketLenAlloc = (word16) ticLenAlloc;
                    output->ticketLen = 0;
                }
            }
            else {
                output->ticket = output->staticTicket;
                output->ticketLenAlloc = 0;
            }
        }
        else {
            if (ticBuff != NULL)
                XFREE(ticBuff, output->heap, DYNAMIC_TYPE_SESSION_TICK);
            output->ticket = output->staticTicket;
            output->ticketLenAlloc = 0;
        }
        if (input->ticketLenAlloc > 0 && ret == WOLFSSL_SUCCESS) {
            /* Shouldn't happen as session should have placed this in
             * the static buffer */
            XMEMCPY(output->ticket, input->ticket,
                    input->ticketLen);
        }
    }
    ticBuff = NULL;

#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_TICKET_NONCE_MALLOC) &&          \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
    if (preallocUsed != NULL)
        *preallocUsed = 0;

    if (input->ticketNonce.len > MAX_TICKET_NONCE_STATIC_SZ &&
        ret == WOLFSSL_SUCCESS) {
        /* TicketNonce does not fit in the static buffer */
        if (!avoidSysCalls) {
            output->ticketNonce.data = (byte*)XMALLOC(input->ticketNonce.len,
                output->heap, DYNAMIC_TYPE_SESSION_TICK);

            if (output->ticketNonce.data == NULL) {
                WOLFSSL_MSG("Failed to allocate space for ticket nonce");
                output->ticketNonce.data = output->ticketNonce.dataStatic;
                output->ticketNonce.len = 0;
                ret = WOLFSSL_FAILURE;
            }
            else {
                output->ticketNonce.len = input->ticketNonce.len;
                XMEMCPY(output->ticketNonce.data, input->ticketNonce.data,
                    input->ticketNonce.len);
                ret = WOLFSSL_SUCCESS;
            }
        }
        /* we can't do syscalls. Use prealloc buffers if provided from the
         * caller. */
        else if (ticketNonceBuf != NULL &&
                 *ticketNonceLen >= input->ticketNonce.len) {
            XMEMCPY(ticketNonceBuf, input->ticketNonce.data,
                input->ticketNonce.len);
            *ticketNonceLen = input->ticketNonce.len;
            if (preallocUsed != NULL)
                *preallocUsed = 1;
            ret = WOLFSSL_SUCCESS;
        }
        else {
            WOLFSSL_MSG("TicketNonce bigger than static buffer, and we can't "
                        "do syscalls");
            ret = WOLFSSL_FAILURE;
        }
    }
#endif /* WOLFSSL_TLS13 && WOLFSSL_TICKET_NONCE_MALLOC && FIPS_VERSION_GE(5,3)*/

#endif /* HAVE_SESSION_TICKET */
    return ret;
}

/**
 * Deep copy the contents from input to output.
 * @param input         The source of the copy.
 * @param output        The destination of the copy.
 * @param avoidSysCalls If true, then system calls will be avoided or an error
 *                      will be returned if it is not possible to proceed
 *                      without a system call. This is useful for fetching
 *                      sessions from cache. When a cache row is locked, we
 *                      don't want to block other threads with long running
 *                      system calls.
 * @return              WOLFSSL_SUCCESS on success
 *                      WOLFSSL_FAILURE on failure
 */
int wolfSSL_DupSession(const WOLFSSL_SESSION* input, WOLFSSL_SESSION* output,
        int avoidSysCalls)
{
    return wolfSSL_DupSessionEx(input, output, avoidSysCalls, NULL, NULL, NULL);
}

WOLFSSL_SESSION* wolfSSL_SESSION_dup(WOLFSSL_SESSION* session)
{
#ifdef HAVE_EXT_CACHE
    WOLFSSL_SESSION* copy;

    WOLFSSL_ENTER("wolfSSL_SESSION_dup");

    session = ClientSessionToSession(session);
    if (session == NULL)
        return NULL;

#ifdef HAVE_SESSION_TICKET
    if (session->ticketLenAlloc > 0 && !session->ticket) {
        WOLFSSL_MSG("Session dynamic flag is set but ticket pointer is null");
        return NULL;
    }
#endif

    copy = wolfSSL_NewSession(session->heap);
    if (copy != NULL &&
            wolfSSL_DupSession(session, copy, 0) != WOLFSSL_SUCCESS) {
        wolfSSL_FreeSession(NULL, copy);
        copy = NULL;
    }
    return copy;
#else
    WOLFSSL_MSG("wolfSSL_SESSION_dup feature not compiled in");
    (void)session;
    return NULL;
#endif /* HAVE_EXT_CACHE */
}

void wolfSSL_FreeSession(WOLFSSL_CTX* ctx, WOLFSSL_SESSION* session)
{
    session = ClientSessionToSession(session);
    if (session == NULL)
        return;

    (void)ctx;

    /* refCount will always be 1 or more if created externally.
     * Internal cache sessions don't initialize a refMutex. */
    if (session->refCount > 0) {
#ifndef SINGLE_THREADED
        if (wc_LockMutex(&session->refMutex) != 0) {
            WOLFSSL_MSG("Failed to lock session mutex");
            return;
        }
#endif
        if (session->refCount > 1) {
            session->refCount--;
#ifndef SINGLE_THREADED
            wc_UnLockMutex(&session->refMutex);
#endif
            return;
        }
#ifndef SINGLE_THREADED
        wc_UnLockMutex(&session->refMutex);
        wc_FreeMutex(&session->refMutex);
#endif
    }

#if defined(HAVE_EXT_CACHE) || defined(HAVE_EX_DATA)
    if (ctx != NULL && ctx->rem_sess_cb
#ifdef HAVE_EX_DATA
            && session->ownExData /* This will be true if we are not using the
                                   * internal cache so it will get called for
                                   * externally cached sessions as well. */
#endif
    ) {
        ctx->rem_sess_cb(ctx, session);
    }
#endif

#ifdef HAVE_EX_DATA_CLEANUP_HOOKS
    wolfSSL_CRYPTO_cleanup_ex_data(&session->ex_data);
#endif

#if defined(SESSION_CERTS) && defined(OPENSSL_EXTRA)
    if (session->peer) {
        wolfSSL_X509_free(session->peer);
        session->peer = NULL;
    }
#endif

#ifdef HAVE_SESSION_TICKET
    if (session->ticketLenAlloc > 0) {
        XFREE(session->ticket, session->heap, DYNAMIC_TYPE_SESSION_TICK);
    }
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_TICKET_NONCE_MALLOC) &&          \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
    if (session->ticketNonce.data != session->ticketNonce.dataStatic) {
        XFREE(session->ticketNonce.data, session->heap,
            DYNAMIC_TYPE_SESSION_TICK);
    }
#endif /* WOLFSSL_TLS13 && WOLFSSL_TICKET_NONCE_MALLOC && FIPS_VERSION_GE(5,3)*/
#endif

#ifdef HAVE_EX_DATA_CLEANUP_HOOKS
    wolfSSL_CRYPTO_cleanup_ex_data(&session->ex_data);
#endif

    /* Make sure masterSecret is zeroed. */
    ForceZero(session->masterSecret, SECRET_LEN);
    /* Session ID is sensitive information too. */
    ForceZero(session->sessionID, ID_LEN);

    if (session->type == WOLFSSL_SESSION_TYPE_HEAP) {
        XFREE(session, session->heap, DYNAMIC_TYPE_SESSION);
    }
}

void wolfSSL_SESSION_free(WOLFSSL_SESSION* session)
{
    session = ClientSessionToSession(session);
    wolfSSL_FreeSession(NULL, session);
}

#ifndef NO_SESSION_CACHE
int wolfSSL_CTX_add_session(WOLFSSL_CTX* ctx, WOLFSSL_SESSION* session)
{
    int    error = 0;
    const byte* id = NULL;
    byte idSz = 0;

    WOLFSSL_ENTER("wolfSSL_CTX_add_session");

    session = ClientSessionToSession(session);
    if (session == NULL)
        return WOLFSSL_FAILURE;

    /* Session cache is global */
    (void)ctx;

    id = session->sessionID;
    idSz = session->sessionIDSz;
    if (session->haveAltSessionID) {
        id = session->altSessionID;
        idSz = ID_LEN;
    }

    error = AddSessionToCache(ctx, session, id, idSz,
            NULL, session->side,
#ifdef HAVE_SESSION_TICKET
            session->ticketLen > 0,
#else
            0,
#endif
            NULL);

    return error == 0 ? WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
}
#endif

#if defined(OPENSSL_EXTRA) || defined(HAVE_EXT_CACHE)

/**
* set cipher to WOLFSSL_SESSION from WOLFSSL_CIPHER
* @param session  a pointer to WOLFSSL_SESSION structure
* @param cipher   a function pointer to WOLFSSL_CIPHER
* @return WOLFSSL_SUCCESS on success, otherwise WOLFSSL_FAILURE
*/
int wolfSSL_SESSION_set_cipher(WOLFSSL_SESSION* session,
                                            const WOLFSSL_CIPHER* cipher)
{
    WOLFSSL_ENTER("wolfSSL_SESSION_set_cipher");

    session = ClientSessionToSession(session);
    /* sanity check */
    if (session == NULL || cipher == NULL) {
        WOLFSSL_MSG("bad argument");
        return WOLFSSL_FAILURE;
    }
    session->cipherSuite0 = cipher->cipherSuite0;
    session->cipherSuite  = cipher->cipherSuite;

    WOLFSSL_LEAVE("wolfSSL_SESSION_set_cipher", WOLFSSL_SUCCESS);
    return WOLFSSL_SUCCESS;
}
#endif /* OPENSSL_EXTRA || HAVE_EXT_CACHE */


/* helper function that takes in a protocol version struct and returns string */
static const char* wolfSSL_internal_get_version(const ProtocolVersion* version)
{
    WOLFSSL_ENTER("wolfSSL_get_version");

    if (version == NULL) {
        return "Bad arg";
    }

    if (version->major == SSLv3_MAJOR) {
        switch (version->minor) {
            case SSLv3_MINOR :
                return "SSLv3";
            case TLSv1_MINOR :
                return "TLSv1";
            case TLSv1_1_MINOR :
                return "TLSv1.1";
            case TLSv1_2_MINOR :
                return "TLSv1.2";
            case TLSv1_3_MINOR :
                return "TLSv1.3";
            default:
                return "unknown";
        }
    }
#ifdef WOLFSSL_DTLS
    else if (version->major == DTLS_MAJOR) {
        switch (version->minor) {
            case DTLS_MINOR :
                return "DTLS";
            case DTLSv1_2_MINOR :
                return "DTLSv1.2";
            case DTLSv1_3_MINOR :
                return "DTLSv1.3";
            default:
                return "unknown";
        }
    }
#endif /* WOLFSSL_DTLS */
    return "unknown";
}


const char* wolfSSL_get_version(const WOLFSSL* ssl)
{
    if (ssl == NULL) {
        WOLFSSL_MSG("Bad argument");
        return "unknown";
    }

    return wolfSSL_internal_get_version(&ssl->version);
}


/* current library version */
const char* wolfSSL_lib_version(void)
{
    return LIBWOLFSSL_VERSION_STRING;
}

#ifdef OPENSSL_EXTRA
#if defined(OPENSSL_VERSION_NUMBER) && OPENSSL_VERSION_NUMBER >= 0x10100000L
const char* wolfSSL_OpenSSL_version(int a)
{
    (void)a;
    return "wolfSSL " LIBWOLFSSL_VERSION_STRING;
}
#else
const char* wolfSSL_OpenSSL_version(void)
{
    return "wolfSSL " LIBWOLFSSL_VERSION_STRING;
}
#endif /* WOLFSSL_QT */
#endif


/* current library version in hex */
word32 wolfSSL_lib_version_hex(void)
{
    return LIBWOLFSSL_VERSION_HEX;
}


int wolfSSL_get_current_cipher_suite(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("SSL_get_current_cipher_suite");
    if (ssl)
        return (ssl->options.cipherSuite0 << 8) | ssl->options.cipherSuite;
    return 0;
}

WOLFSSL_CIPHER* wolfSSL_get_current_cipher(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("SSL_get_current_cipher");
    if (ssl) {
        ssl->cipher.cipherSuite0 = ssl->options.cipherSuite0;
        ssl->cipher.cipherSuite  = ssl->options.cipherSuite;
#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
        ssl->cipher.bits = ssl->specs.key_size * 8;
#endif
        return &ssl->cipher;
    }
    else
        return NULL;
}


const char* wolfSSL_CIPHER_get_name(const WOLFSSL_CIPHER* cipher)
{
    WOLFSSL_ENTER("wolfSSL_CIPHER_get_name");

    if (cipher == NULL) {
        return NULL;
    }

    #if !defined(WOLFSSL_CIPHER_INTERNALNAME) && !defined(NO_ERROR_STRINGS) && \
        !defined(WOLFSSL_QT)
        return GetCipherNameIana(cipher->cipherSuite0, cipher->cipherSuite);
    #else
        return wolfSSL_get_cipher_name_from_suite(cipher->cipherSuite0,
                cipher->cipherSuite);
    #endif
}

const char*  wolfSSL_CIPHER_get_version(const WOLFSSL_CIPHER* cipher)
{
    WOLFSSL_ENTER("SSL_CIPHER_get_version");

    if (cipher == NULL || cipher->ssl == NULL) {
        return NULL;
    }

    return wolfSSL_get_version(cipher->ssl);
}

const char* wolfSSL_SESSION_CIPHER_get_name(const WOLFSSL_SESSION* session)
{
    session = ClientSessionToSession(session);
    if (session == NULL) {
        return NULL;
    }

#if defined(SESSION_CERTS) || !defined(NO_RESUME_SUITE_CHECK) || \
                        (defined(WOLFSSL_TLS13) && defined(HAVE_SESSION_TICKET))
    #if !defined(WOLFSSL_CIPHER_INTERNALNAME) && !defined(NO_ERROR_STRINGS)
        return GetCipherNameIana(session->cipherSuite0, session->cipherSuite);
    #else
        return GetCipherNameInternal(session->cipherSuite0, session->cipherSuite);
    #endif
#else
    return NULL;
#endif
}

const char* wolfSSL_get_cipher(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_get_cipher");
    return wolfSSL_CIPHER_get_name(wolfSSL_get_current_cipher(ssl));
}

/* gets cipher name in the format DHE-RSA-... rather then TLS_DHE... */
const char* wolfSSL_get_cipher_name(WOLFSSL* ssl)
{
    /* get access to cipher_name_idx in internal.c */
    return wolfSSL_get_cipher_name_internal(ssl);
}

const char* wolfSSL_get_cipher_name_from_suite(const byte cipherSuite0,
    const byte cipherSuite)
{
    return GetCipherNameInternal(cipherSuite0, cipherSuite);
}

const char* wolfSSL_get_cipher_name_iana_from_suite(const byte cipherSuite0,
        const byte cipherSuite)
{
    return GetCipherNameIana(cipherSuite0, cipherSuite);
}

int wolfSSL_get_cipher_suite_from_name(const char* name, byte* cipherSuite0,
                                       byte* cipherSuite, int *flags) {
    if ((name == NULL) ||
        (cipherSuite0 == NULL) ||
        (cipherSuite == NULL) ||
        (flags == NULL))
        return BAD_FUNC_ARG;
    return GetCipherSuiteFromName(name, cipherSuite0, cipherSuite, flags);
}


#if defined(WOLFSSL_QT) || defined(OPENSSL_ALL)
/* Creates and returns a new WOLFSSL_CIPHER stack. */
WOLFSSL_STACK* wolfSSL_sk_new_cipher(void)
{
    WOLFSSL_STACK* sk;
    WOLFSSL_ENTER("wolfSSL_sk_new_cipher");

    sk = wolfSSL_sk_new_null();
    if (sk == NULL)
        return NULL;
    sk->type = STACK_TYPE_CIPHER;

    return sk;
}

/* return 1 on success 0 on fail */
int wolfSSL_sk_CIPHER_push(WOLF_STACK_OF(WOLFSSL_CIPHER)* sk,
                                                      WOLFSSL_CIPHER* cipher)
{
    return wolfSSL_sk_push(sk, cipher);
}

#ifndef NO_WOLFSSL_STUB
WOLFSSL_CIPHER* wolfSSL_sk_CIPHER_pop(WOLF_STACK_OF(WOLFSSL_CIPHER)* sk)
{
    WOLFSSL_STUB("wolfSSL_sk_CIPHER_pop");
    (void)sk;
    return NULL;
}
#endif /* NO_WOLFSSL_STUB */
#endif /* WOLFSSL_QT || OPENSSL_ALL */

word32 wolfSSL_CIPHER_get_id(const WOLFSSL_CIPHER* cipher)
{
    word16 cipher_id = 0;

    WOLFSSL_ENTER("SSL_CIPHER_get_id");

    if (cipher && cipher->ssl) {
        cipher_id = (cipher->ssl->options.cipherSuite0 << 8) |
                     cipher->ssl->options.cipherSuite;
    }

    return cipher_id;
}

const WOLFSSL_CIPHER* wolfSSL_get_cipher_by_value(word16 value)
{
    const WOLFSSL_CIPHER* cipher = NULL;
    byte cipherSuite0, cipherSuite;
    WOLFSSL_ENTER("SSL_get_cipher_by_value");

    /* extract cipher id information */
    cipherSuite =   (value       & 0xFF);
    cipherSuite0 = ((value >> 8) & 0xFF);

    /* TODO: lookup by cipherSuite0 / cipherSuite */
    (void)cipherSuite0;
    (void)cipherSuite;

    return cipher;
}


#if defined(OPENSSL_EXTRA)
/* Free the structure for WOLFSSL_CIPHER stack
 *
 * sk  stack to free nodes in
 */
void wolfSSL_sk_CIPHER_free(WOLF_STACK_OF(WOLFSSL_CIPHER)* sk)
{
    WOLFSSL_ENTER("wolfSSL_sk_CIPHER_free");

    wolfSSL_sk_free(sk);
}
#endif /* OPENSSL_ALL */

#if defined(HAVE_ECC) || defined(HAVE_CURVE25519) || defined(HAVE_CURVE448) || \
                                                                 !defined(NO_DH)
#ifdef HAVE_FFDHE
static const char* wolfssl_ffdhe_name(word16 group)
{
    const char* str = NULL;
    switch (group) {
        case WOLFSSL_FFDHE_2048:
            str = "FFDHE_2048";
            break;
        case WOLFSSL_FFDHE_3072:
            str = "FFDHE_3072";
            break;
        case WOLFSSL_FFDHE_4096:
            str = "FFDHE_4096";
            break;
        case WOLFSSL_FFDHE_6144:
            str = "FFDHE_6144";
            break;
        case WOLFSSL_FFDHE_8192:
            str = "FFDHE_8192";
            break;
        default:
            break;
    }
    return str;
}
#endif
/* Return the name of the curve used for key exchange as a printable string.
 *
 * ssl  The SSL/TLS object.
 * returns NULL if ECDH was not used, otherwise the name as a string.
 */
const char* wolfSSL_get_curve_name(WOLFSSL* ssl)
{
    const char* cName = NULL;

    if (ssl == NULL)
        return NULL;

#if defined(WOLFSSL_TLS13) && defined(HAVE_PQC)
    /* Check for post-quantum groups. Return now because we do not want the ECC
     * check to override this result in the case of a hybrid. */
    if (IsAtLeastTLSv1_3(ssl->version)) {
        switch (ssl->namedGroup) {
#ifdef HAVE_LIBOQS
        case WOLFSSL_KYBER_LEVEL1:
            return "KYBER_LEVEL1";
        case WOLFSSL_KYBER_LEVEL3:
            return "KYBER_LEVEL3";
        case WOLFSSL_KYBER_LEVEL5:
            return "KYBER_LEVEL5";
        case WOLFSSL_P256_KYBER_LEVEL1:
            return "P256_KYBER_LEVEL1";
        case WOLFSSL_P384_KYBER_LEVEL3:
            return "P384_KYBER_LEVEL3";
        case WOLFSSL_P521_KYBER_LEVEL5:
            return "P521_KYBER_LEVEL5";
#elif defined(HAVE_PQM4)
        case WOLFSSL_KYBER_LEVEL1:
            return "KYBER_LEVEL1";
#elif defined(WOLFSSL_WC_KYBER)
    #ifdef WOLFSSL_KYBER512
        case WOLFSSL_KYBER_LEVEL1:
            return "KYBER_LEVEL1";
    #endif
    #ifdef WOLFSSL_KYBER768
        case WOLFSSL_KYBER_LEVEL3:
            return "KYBER_LEVEL3";
    #endif
    #ifdef WOLFSSL_KYBER1024
        case WOLFSSL_KYBER_LEVEL5:
            return "KYBER_LEVEL5";
    #endif
#endif
        }
    }

#endif /* WOLFSSL_TLS13 && HAVE_PQC */
#ifdef HAVE_FFDHE
    if (ssl->namedGroup != 0) {
        cName = wolfssl_ffdhe_name(ssl->namedGroup);
    }
#endif

#ifdef HAVE_CURVE25519
    if (ssl->ecdhCurveOID == ECC_X25519_OID && cName == NULL) {
        cName = "X25519";
    }
#endif

#ifdef HAVE_CURVE448
    if (ssl->ecdhCurveOID == ECC_X448_OID && cName == NULL) {
        cName = "X448";
    }
#endif

#ifdef HAVE_ECC
    if (ssl->ecdhCurveOID != 0 && cName == NULL) {
        cName = wc_ecc_get_name(wc_ecc_get_oid(ssl->ecdhCurveOID, NULL,
                                NULL));
    }
#endif

    return cName;
}
#endif

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL) || \
    defined(OPENSSL_EXTRA_X509_SMALL)

    /* Creates a new WOLFSSL_ASN1_STRING structure.
     *
     * returns a pointer to the new structure created on success or NULL if fail
     */
    WOLFSSL_ASN1_STRING* wolfSSL_ASN1_STRING_new(void)
    {
        WOLFSSL_ASN1_STRING* asn1;

#ifdef WOLFSSL_DEBUG_OPENSSL
        WOLFSSL_ENTER("wolfSSL_ASN1_STRING_new");
#endif

        asn1 = (WOLFSSL_ASN1_STRING*)XMALLOC(sizeof(WOLFSSL_ASN1_STRING), NULL,
                DYNAMIC_TYPE_OPENSSL);
        if (asn1 != NULL) {
            XMEMSET(asn1, 0, sizeof(WOLFSSL_ASN1_STRING));
        }

        return asn1; /* no check for null because error case is returning null*/
    }

    /**
     * Used to duplicate a passed in WOLFSSL_ASN1_STRING*
     * @param asn1 WOLFSSL_ASN1_STRING* to be duplicated
     * @return WOLFSSL_ASN1_STRING* the duplicate struct or NULL on error
     */
    WOLFSSL_ASN1_STRING* wolfSSL_ASN1_STRING_dup(WOLFSSL_ASN1_STRING* asn1)
    {
        WOLFSSL_ASN1_STRING* dupl = NULL;

        WOLFSSL_ENTER("wolfSSL_ASN1_STRING_dup");
        if (!asn1) {
            WOLFSSL_MSG("Bad parameter");
            return NULL;
        }

        dupl = wolfSSL_ASN1_STRING_new();
        if (!dupl) {
            WOLFSSL_MSG("wolfSSL_ASN1_STRING_new error");
            return NULL;
        }

        dupl->type = asn1->type;
        dupl->flags = asn1->flags;

        if (wolfSSL_ASN1_STRING_set(dupl, asn1->data, asn1->length)
                != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("wolfSSL_ASN1_STRING_set error");
            wolfSSL_ASN1_STRING_free(dupl);
            return NULL;
        }

        return dupl;
    }


    /* used to free a WOLFSSL_ASN1_STRING structure */
    void wolfSSL_ASN1_STRING_free(WOLFSSL_ASN1_STRING* asn1)
    {
#ifdef WOLFSSL_DEBUG_OPENSSL
        WOLFSSL_ENTER("wolfSSL_ASN1_STRING_free");
#endif

        if (asn1 != NULL) {
            if (asn1->length > 0 && asn1->data != NULL && asn1->isDynamic) {
                XFREE(asn1->data, NULL, DYNAMIC_TYPE_OPENSSL);
            }
            XFREE(asn1, NULL, DYNAMIC_TYPE_OPENSSL);
        }
    }

    int wolfSSL_ASN1_STRING_cmp(const WOLFSSL_ASN1_STRING *a, const WOLFSSL_ASN1_STRING *b)
    {
        int i;
        WOLFSSL_ENTER("wolfSSL_ASN1_STRING_cmp");

        if (!a || !b) {
            return WOLFSSL_FATAL_ERROR;
        }

        if (a->length != b->length) {
            return a->length - b->length;
        }

        if ((i = XMEMCMP(a->data, b->data, a->length)) != 0) {
            return i;
        }

        return a->type - b->type;
    }
#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL */

#if !defined(NO_CERTS) && (defined(OPENSSL_EXTRA) || \
    defined(OPENSSL_EXTRA_X509_SMALL))

    int wolfSSL_ASN1_STRING_copy(WOLFSSL_ASN1_STRING* dest,
                            const WOLFSSL_ASN1_STRING* src)
    {
        if (src == NULL || dest == NULL) {
            return WOLFSSL_FAILURE;
        }
        dest->type = src->type;
        if(wolfSSL_ASN1_STRING_set(dest, src->data, src->length)
                    != WOLFSSL_SUCCESS) {
                return WOLFSSL_FAILURE;
        }
        dest->flags = src->flags;

        return WOLFSSL_SUCCESS;
    }
    /* Creates a new WOLFSSL_ASN1_STRING structure given the input type.
     *
     * type is the type of set when WOLFSSL_ASN1_STRING is created
     *
     * returns a pointer to the new structure created on success or NULL if fail
     */
    WOLFSSL_ASN1_STRING* wolfSSL_ASN1_STRING_type_new(int type)
    {
        WOLFSSL_ASN1_STRING* asn1;

#ifdef WOLFSSL_DEBUG_OPENSSL
        WOLFSSL_ENTER("wolfSSL_ASN1_STRING_type_new");
#endif

        asn1 = wolfSSL_ASN1_STRING_new();
        if (asn1 == NULL) {
            return NULL;
        }
        asn1->type = type;

        return asn1;
    }


/******************************************************************************
* wolfSSL_ASN1_STRING_type - returns the type of <asn1>
*
* RETURNS:
* returns the type set for <asn1>. Otherwise, returns WOLFSSL_FAILURE.
*/
    int wolfSSL_ASN1_STRING_type(const WOLFSSL_ASN1_STRING* asn1)
    {

#ifdef WOLFSSL_DEBUG_OPENSSL
        WOLFSSL_ENTER("wolfSSL_ASN1_STRING_type");
#endif

        if (asn1 == NULL) {
            return WOLFSSL_FAILURE;
        }

        return asn1->type;
    }

#endif /* !NO_CERTS && OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL) || \
    defined(OPENSSL_EXTRA_X509_SMALL)
    /* if dataSz is negative then use XSTRLEN to find length of data
     * return WOLFSSL_SUCCESS on success and WOLFSSL_FAILURE on failure */
    /* `data` can be NULL and only buffer will be allocated */
    int wolfSSL_ASN1_STRING_set(WOLFSSL_ASN1_STRING* asn1, const void* data,
            int dataSz)
    {
        int sz;

#ifdef WOLFSSL_DEBUG_OPENSSL
        WOLFSSL_ENTER("wolfSSL_ASN1_STRING_set");
#endif

        if (asn1 == NULL || (data == NULL && dataSz < 0)) {
            return WOLFSSL_FAILURE;
        }

        if (dataSz < 0) {
            sz = (int)XSTRLEN((const char*)data);
        }
        else {
            sz = dataSz;
        }

        if (sz < 0) {
            return WOLFSSL_FAILURE;
        }

        /* free any existing data before copying */
        if (asn1->data != NULL && asn1->isDynamic) {
            XFREE(asn1->data, NULL, DYNAMIC_TYPE_OPENSSL);
            asn1->data = NULL;
        }

        if (sz + 1 > CTC_NAME_SIZE) { /* account for null char */
            /* create new data buffer and copy over */
            asn1->data = (char*)XMALLOC(sz + 1, NULL, DYNAMIC_TYPE_OPENSSL);
            if (asn1->data == NULL) {
                return WOLFSSL_FAILURE;
            }
            asn1->isDynamic = 1;
        }
        else {
            XMEMSET(asn1->strData, 0, CTC_NAME_SIZE);
            asn1->data = asn1->strData;
            asn1->isDynamic = 0;
        }
        if (data != NULL) {
            XMEMCPY(asn1->data, data, sz);
            asn1->data[sz] = '\0';
        }
        asn1->length = sz;

        return WOLFSSL_SUCCESS;
    }
#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL */

#ifndef NO_CERTS
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
    const unsigned char* wolfSSL_ASN1_STRING_get0_data(
                                            const WOLFSSL_ASN1_STRING* asn)
    {
        WOLFSSL_ENTER("wolfSSL_ASN1_STRING_get0_data");

        if (asn) {
            return (const unsigned char*)asn->data;
        } else {
            return NULL;
        }
    }
    unsigned char* wolfSSL_ASN1_STRING_data(WOLFSSL_ASN1_STRING* asn)
    {
#ifdef WOLFSSL_DEBUG_OPENSSL
        WOLFSSL_ENTER("wolfSSL_ASN1_STRING_data");
#endif

        if (asn) {
            return (unsigned char*)asn->data;
        }
        else {
            return NULL;
        }
    }


    int wolfSSL_ASN1_STRING_length(WOLFSSL_ASN1_STRING* asn)
    {
#ifdef WOLFSSL_DEBUG_OPENSSL
        WOLFSSL_ENTER("wolfSSL_ASN1_STRING_length");
#endif

        if (asn) {
            return asn->length;
        }
        else {
            return 0;
        }
    }
#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL */

#ifdef OPENSSL_EXTRA
#ifndef NO_WOLFSSL_STUB
    WOLFSSL_ASN1_STRING* wolfSSL_d2i_DISPLAYTEXT(WOLFSSL_ASN1_STRING **asn,
                                             const unsigned char **in, long len)
    {
        WOLFSSL_STUB("d2i_DISPLAYTEXT");
        (void)asn;
        (void)in;
        (void)len;
        return NULL;
    }
#endif

#endif /* OPENSSL_EXTRA */

#endif /* !NO_CERTS */

#ifdef OPENSSL_EXTRA
#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
/* return authentication NID corresponding to cipher suite
 * @param cipher a pointer to WOLFSSL_CIPHER
 * return NID if found, NID_undef if not found
 */
int wolfSSL_CIPHER_get_auth_nid(const WOLFSSL_CIPHER* cipher)
{
    static const struct authnid {
        const char* alg_name;
        const int  nid;
    } authnid_tbl[] = {
        {"RSA",     NID_auth_rsa},
        {"PSK",     NID_auth_psk},
        {"SRP",     NID_auth_srp},
        {"ECDSA",   NID_auth_ecdsa},
        {"None",    NID_auth_null},
        {NULL,      NID_undef}
    };

    const struct authnid* sa;
    const char* authStr;
    char n[MAX_SEGMENTS][MAX_SEGMENT_SZ] = {{0}};

    if (GetCipherSegment(cipher, n) == NULL) {
        WOLFSSL_MSG("no suitable cipher name found");
        return NID_undef;
    }

    authStr = GetCipherAuthStr(n);

    if (authStr != NULL) {
        for(sa = authnid_tbl; sa->alg_name != NULL; sa++) {
            if (XSTRCMP(sa->alg_name, authStr) == 0) {
                return sa->nid;
            }
        }
    }

    return NID_undef;
}
/* return cipher NID corresponding to cipher suite
 * @param cipher a pointer to WOLFSSL_CIPHER
 * return NID if found, NID_undef if not found
 */
int wolfSSL_CIPHER_get_cipher_nid(const WOLFSSL_CIPHER* cipher)
{
    static const struct ciphernid {
        const char* alg_name;
        const int  nid;
    } ciphernid_tbl[] = {
        {"AESGCM(256)",             NID_aes_256_gcm},
        {"AESGCM(128)",             NID_aes_128_gcm},
        {"AESCCM(128)",             NID_aes_128_ccm},
        {"AES(128)",                NID_aes_128_cbc},
        {"AES(256)",                NID_aes_256_cbc},
        {"CAMELLIA(256)",           NID_camellia_256_cbc},
        {"CAMELLIA(128)",           NID_camellia_128_cbc},
        {"RC4",                     NID_rc4},
        {"3DES",                    NID_des_ede3_cbc},
        {"CHACHA20/POLY1305(256)",  NID_chacha20_poly1305},
        {"None",                    NID_undef},
        {NULL,                      NID_undef}
    };

    const struct ciphernid* c;
    const char* encStr;
    char n[MAX_SEGMENTS][MAX_SEGMENT_SZ] = {{0}};

    WOLFSSL_ENTER("wolfSSL_CIPHER_get_cipher_nid");

    if (GetCipherSegment(cipher, n) == NULL) {
        WOLFSSL_MSG("no suitable cipher name found");
        return NID_undef;
    }

    encStr = GetCipherEncStr(n);

    if (encStr != NULL) {
        for(c = ciphernid_tbl; c->alg_name != NULL; c++) {
            if (XSTRCMP(c->alg_name, encStr) == 0) {
                return c->nid;
            }
        }
    }

    return NID_undef;
}
/* return digest NID corresponding to cipher suite
 * @param cipher a pointer to WOLFSSL_CIPHER
 * return NID if found, NID_undef if not found
 */
int wolfSSL_CIPHER_get_digest_nid(const WOLFSSL_CIPHER* cipher)
{
    static const struct macnid {
        const char* alg_name;
        const int  nid;
    } macnid_tbl[] = {
        {"SHA1",    NID_sha1},
        {"SHA256",  NID_sha256},
        {"SHA384",  NID_sha384},
        {NULL,      NID_undef}
    };

    const struct macnid* mc;
    const char* name;
    const char* macStr;
    char n[MAX_SEGMENTS][MAX_SEGMENT_SZ] = {{0}};
    (void)name;

    WOLFSSL_ENTER("wolfSSL_CIPHER_get_digest_nid");

    if ((name = GetCipherSegment(cipher, n)) == NULL) {
        WOLFSSL_MSG("no suitable cipher name found");
        return NID_undef;
    }

    /* in MD5 case, NID will be NID_md5 */
    if (XSTRSTR(name, "MD5") != NULL) {
        return NID_md5;
    }

    macStr = GetCipherMacStr(n);

    if (macStr != NULL) {
        for(mc = macnid_tbl; mc->alg_name != NULL; mc++) {
            if (XSTRCMP(mc->alg_name, macStr) == 0) {
                return mc->nid;
            }
        }
    }

    return NID_undef;
}
/* return key exchange NID corresponding to cipher suite
 * @param cipher a pointer to WOLFSSL_CIPHER
 * return NID if found, NID_undef if not found
 */
int wolfSSL_CIPHER_get_kx_nid(const WOLFSSL_CIPHER* cipher)
{
    static const struct kxnid {
        const char* name;
        const int  nid;
    } kxnid_table[] = {
        {"ECDHEPSK",  NID_kx_ecdhe_psk},
        {"ECDH",      NID_kx_ecdhe},
        {"DHEPSK",    NID_kx_dhe_psk},
        {"DH",        NID_kx_dhe},
        {"RSAPSK",    NID_kx_rsa_psk},
        {"SRP",       NID_kx_srp},
        {"EDH",       NID_kx_dhe},
        {"RSA",       NID_kx_rsa},
        {NULL,        NID_undef}
    };

    const struct kxnid* k;
    const char* keaStr;
    char n[MAX_SEGMENTS][MAX_SEGMENT_SZ] = {{0}};

    WOLFSSL_ENTER("wolfSSL_CIPHER_get_kx_nid");

    if (GetCipherSegment(cipher, n) == NULL) {
        WOLFSSL_MSG("no suitable cipher name found");
        return NID_undef;
    }

    /* in TLS 1.3 case, NID will be NID_kx_any */
    if (XSTRCMP(n[0], "TLS13") == 0) {
        return NID_kx_any;
    }

    keaStr = GetCipherKeaStr(n);

    if (keaStr != NULL) {
        for(k = kxnid_table; k->name != NULL; k++) {
            if (XSTRCMP(k->name, keaStr) == 0) {
                return k->nid;
            }
        }
    }

    return NID_undef;
}
/* check if cipher suite is AEAD
 * @param cipher a pointer to WOLFSSL_CIPHER
 * return 1 if cipher is AEAD, 0 otherwise
 */
int wolfSSL_CIPHER_is_aead(const WOLFSSL_CIPHER* cipher)
{
    char n[MAX_SEGMENTS][MAX_SEGMENT_SZ] = {{0}};

    WOLFSSL_ENTER("wolfSSL_CIPHER_is_aead");

    if (GetCipherSegment(cipher, n) == NULL) {
        WOLFSSL_MSG("no suitable cipher name found");
        return NID_undef;
    }

    return IsCipherAEAD(n);
}
/* Creates cipher->description based on cipher->offset
 * cipher->offset is set in wolfSSL_get_ciphers_compat when it is added
 * to a stack of ciphers.
 * @param [in] cipher: A cipher from a stack of ciphers.
 * return WOLFSSL_SUCCESS if cipher->description is set, else WOLFSSL_FAILURE
 */
int wolfSSL_sk_CIPHER_description(WOLFSSL_CIPHER* cipher)
{
    int strLen;
    unsigned long offset;
    char* dp;
    const char* name;
    const char *keaStr, *authStr, *encStr, *macStr, *protocol;
    char n[MAX_SEGMENTS][MAX_SEGMENT_SZ] = {{0}};
    int len = MAX_DESCRIPTION_SZ-1;
    const CipherSuiteInfo* cipher_names;
    ProtocolVersion pv;
    WOLFSSL_ENTER("wolfSSL_sk_CIPHER_description");

    if (cipher == NULL)
        return WOLFSSL_FAILURE;

    dp = cipher->description;
    if (dp == NULL)
        return WOLFSSL_FAILURE;

    cipher_names = GetCipherNames();

    offset = cipher->offset;
    if (offset >= (unsigned long)GetCipherNamesSize())
        return WOLFSSL_FAILURE;
    pv.major = cipher_names[offset].major;
    pv.minor = cipher_names[offset].minor;
    protocol = wolfSSL_internal_get_version(&pv);

    if ((name = GetCipherSegment(cipher, n)) == NULL) {
        WOLFSSL_MSG("no suitable cipher name found");
        return WOLFSSL_FAILURE;
    }

    /* keaStr */
    keaStr = GetCipherKeaStr(n);
    /* authStr */
    authStr = GetCipherAuthStr(n);
    /* encStr */
    encStr = GetCipherEncStr(n);
    if ((cipher->bits = SetCipherBits(encStr)) == WOLFSSL_FAILURE) {
       WOLFSSL_MSG("Cipher Bits Not Set.");
    }
    /* macStr */
    macStr = GetCipherMacStr(n);


    /* Build up the string by copying onto the end. */
    XSTRNCPY(dp, name, len);
    dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
    len -= strLen; dp += strLen;

    XSTRNCPY(dp, " ", len);
    dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
    len -= strLen; dp += strLen;
    XSTRNCPY(dp, protocol, len);
    dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
    len -= strLen; dp += strLen;

    XSTRNCPY(dp, " Kx=", len);
    dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
    len -= strLen; dp += strLen;
    XSTRNCPY(dp, keaStr, len);
    dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
    len -= strLen; dp += strLen;

    XSTRNCPY(dp, " Au=", len);
    dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
    len -= strLen; dp += strLen;
    XSTRNCPY(dp, authStr, len);
    dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
    len -= strLen; dp += strLen;

    XSTRNCPY(dp, " Enc=", len);
    dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
    len -= strLen; dp += strLen;
    XSTRNCPY(dp, encStr, len);
    dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
    len -= strLen; dp += strLen;

    XSTRNCPY(dp, " Mac=", len);
    dp[len-1] = '\0'; strLen = (int)XSTRLEN(dp);
    len -= strLen; dp += strLen;
    XSTRNCPY(dp, macStr, len);
    dp[len-1] = '\0';

    return WOLFSSL_SUCCESS;
}
#endif /* OPENSSL_ALL || WOLFSSL_QT */

static WC_INLINE const char* wolfssl_kea_to_string(int kea)
{
    const char* keaStr;

    switch (kea) {
        case no_kea:
            keaStr = "None";
            break;
#ifndef NO_RSA
        case rsa_kea:
            keaStr = "RSA";
            break;
#endif
#ifndef NO_DH
        case diffie_hellman_kea:
            keaStr = "DHE";
            break;
#endif
        case fortezza_kea:
            keaStr = "FZ";
            break;
#ifndef NO_PSK
        case psk_kea:
            keaStr = "PSK";
            break;
    #ifndef NO_DH
        case dhe_psk_kea:
            keaStr = "DHEPSK";
            break;
    #endif
    #ifdef HAVE_ECC
        case ecdhe_psk_kea:
            keaStr = "ECDHEPSK";
            break;
    #endif
#endif
#ifdef HAVE_ECC
        case ecc_diffie_hellman_kea:
            keaStr = "ECDHE";
            break;
        case ecc_static_diffie_hellman_kea:
            keaStr = "ECDH";
            break;
#endif
        default:
            keaStr = "unknown";
            break;
    }

    return keaStr;
}

static WC_INLINE const char* wolfssl_sigalg_to_string(int sig_algo)
{
    const char* authStr;

    switch (sig_algo) {
        case anonymous_sa_algo:
            authStr = "None";
            break;
#ifndef NO_RSA
        case rsa_sa_algo:
            authStr = "RSA";
            break;
    #ifdef WC_RSA_PSS
        case rsa_pss_sa_algo:
            authStr = "RSA-PSS";
            break;
    #endif
#endif
#ifndef NO_DSA
        case dsa_sa_algo:
            authStr = "DSA";
            break;
#endif
#ifdef HAVE_ECC
        case ecc_dsa_sa_algo:
            authStr = "ECDSA";
            break;
#endif
#ifdef HAVE_ED25519
        case ed25519_sa_algo:
            authStr = "Ed25519";
            break;
#endif
#ifdef HAVE_ED448
        case ed448_sa_algo:
            authStr = "Ed448";
            break;
#endif
        default:
            authStr = "unknown";
            break;
    }

    return authStr;
}

static WC_INLINE const char* wolfssl_cipher_to_string(int cipher, int key_size)
{
    const char* encStr;

    (void)key_size;

    switch (cipher) {
        case wolfssl_cipher_null:
            encStr = "None";
            break;
#ifndef NO_RC4
        case wolfssl_rc4:
            encStr = "RC4(128)";
            break;
#endif
#ifndef NO_DES3
        case wolfssl_triple_des:
            encStr = "3DES(168)";
            break;
#endif
#ifndef NO_AES
        case wolfssl_aes:
            if (key_size == 128)
                encStr = "AES(128)";
            else if (key_size == 256)
                encStr = "AES(256)";
            else
                encStr = "AES(?)";
            break;
    #ifdef HAVE_AESGCM
        case wolfssl_aes_gcm:
            if (key_size == 128)
                encStr = "AESGCM(128)";
            else if (key_size == 256)
                encStr = "AESGCM(256)";
            else
                encStr = "AESGCM(?)";
            break;
    #endif
    #ifdef HAVE_AESCCM
        case wolfssl_aes_ccm:
            if (key_size == 128)
                encStr = "AESCCM(128)";
            else if (key_size == 256)
                encStr = "AESCCM(256)";
            else
                encStr = "AESCCM(?)";
            break;
    #endif
#endif
#ifdef HAVE_CHACHA
        case wolfssl_chacha:
            encStr = "CHACHA20/POLY1305(256)";
            break;
#endif
#ifdef HAVE_CAMELLIA
        case wolfssl_camellia:
            if (key_size == 128)
                encStr = "Camellia(128)";
            else if (key_size == 256)
                encStr = "Camellia(256)";
            else
                encStr = "Camellia(?)";
            break;
#endif
        default:
            encStr = "unknown";
            break;
    }

    return encStr;
}

static WC_INLINE const char* wolfssl_mac_to_string(int mac)
{
    const char* macStr;

    switch (mac) {
        case no_mac:
            macStr = "None";
            break;
#ifndef NO_MD5
        case md5_mac:
            macStr = "MD5";
            break;
#endif
#ifndef NO_SHA
        case sha_mac:
            macStr = "SHA1";
            break;
#endif
#ifdef HAVE_SHA224
        case sha224_mac:
            macStr = "SHA224";
            break;
#endif
#ifndef NO_SHA256
        case sha256_mac:
            macStr = "SHA256";
            break;
#endif
#ifdef HAVE_SHA384
        case sha384_mac:
            macStr = "SHA384";
            break;
#endif
#ifdef HAVE_SHA512
        case sha512_mac:
            macStr = "SHA512";
            break;
#endif
        default:
            macStr = "unknown";
            break;
    }

    return macStr;
}

char* wolfSSL_CIPHER_description(const WOLFSSL_CIPHER* cipher, char* in,
                                 int len)
{
    char *ret = in;
    const char *keaStr, *authStr, *encStr, *macStr;
    size_t strLen;
    WOLFSSL_ENTER("wolfSSL_CIPHER_description");

    if (cipher == NULL || in == NULL)
        return NULL;

#if defined(WOLFSSL_QT) || defined(OPENSSL_ALL)
    /* if cipher is in the stack from wolfSSL_get_ciphers_compat then
     * Return the description based on cipher_names[cipher->offset]
     */
    if (cipher->in_stack == TRUE) {
        wolfSSL_sk_CIPHER_description((WOLFSSL_CIPHER*)cipher);
        XSTRNCPY(in,cipher->description,len);
        return ret;
    }
#endif

    /* Get the cipher description based on the SSL session cipher */
    keaStr = wolfssl_kea_to_string(cipher->ssl->specs.kea);
    authStr = wolfssl_sigalg_to_string(cipher->ssl->specs.sig_algo);
    encStr = wolfssl_cipher_to_string(cipher->ssl->specs.bulk_cipher_algorithm,
                                      cipher->ssl->specs.key_size);
    macStr = wolfssl_mac_to_string(cipher->ssl->specs.mac_algorithm);

    /* Build up the string by copying onto the end. */
    XSTRNCPY(in, wolfSSL_CIPHER_get_name(cipher), len);
    in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;

    XSTRNCPY(in, " ", len);
    in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
    XSTRNCPY(in, wolfSSL_get_version(cipher->ssl), len);
    in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;

    XSTRNCPY(in, " Kx=", len);
    in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
    XSTRNCPY(in, keaStr, len);
    in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;

    XSTRNCPY(in, " Au=", len);
    in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
    XSTRNCPY(in, authStr, len);
    in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;

    XSTRNCPY(in, " Enc=", len);
    in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
    XSTRNCPY(in, encStr, len);
    in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;

    XSTRNCPY(in, " Mac=", len);
    in[len-1] = '\0'; strLen = XSTRLEN(in); len -= (int)strLen; in += strLen;
    XSTRNCPY(in, macStr, len);
    in[len-1] = '\0';

    return ret;
}


#ifndef NO_WOLFSSL_STUB
int wolfSSL_OCSP_parse_url(char* url, char** host, char** port, char** path,
                   int* ssl)
{
    (void)url;
    (void)host;
    (void)port;
    (void)path;
    (void)ssl;
    WOLFSSL_STUB("OCSP_parse_url");
    return 0;
}
#endif

#ifndef NO_MD4

void wolfSSL_MD4_Init(WOLFSSL_MD4_CTX* md4)
{
    /* make sure we have a big enough buffer */
    typedef char ok[sizeof(md4->buffer) >= sizeof(Md4) ? 1 : -1];
    (void) sizeof(ok);

    WOLFSSL_ENTER("MD4_Init");
    wc_InitMd4((Md4*)md4);
}


void wolfSSL_MD4_Update(WOLFSSL_MD4_CTX* md4, const void* data,
                       unsigned long len)
{
    WOLFSSL_ENTER("MD4_Update");
    wc_Md4Update((Md4*)md4, (const byte*)data, (word32)len);
}


void wolfSSL_MD4_Final(unsigned char* digest, WOLFSSL_MD4_CTX* md4)
{
    WOLFSSL_ENTER("MD4_Final");
    wc_Md4Final((Md4*)md4, digest);
}

#endif /* NO_MD4 */

#ifndef NO_WOLFSSL_STUB
void wolfSSL_RAND_screen(void)
{
    WOLFSSL_STUB("RAND_screen");
}
#endif



int wolfSSL_RAND_load_file(const char* fname, long len)
{
    (void)fname;
    /* wolfCrypt provides enough entropy internally or will report error */
    if (len == -1)
        return 1024;
    else
        return (int)len;
}


#ifndef NO_WOLFSSL_STUB
WOLFSSL_COMP_METHOD* wolfSSL_COMP_zlib(void)
{
    WOLFSSL_STUB("COMP_zlib");
    return 0;
}
#endif

#ifndef NO_WOLFSSL_STUB
WOLFSSL_COMP_METHOD* wolfSSL_COMP_rle(void)
{
    WOLFSSL_STUB("COMP_rle");
    return 0;
}
#endif

#ifndef NO_WOLFSSL_STUB
int wolfSSL_COMP_add_compression_method(int method, void* data)
{
    (void)method;
    (void)data;
    WOLFSSL_STUB("COMP_add_compression_method");
    return 0;
}
#endif

/*  wolfSSL_set_dynlock_create_callback
 *  CRYPTO_set_dynlock_create_callback has been deprecated since openSSL 1.0.1.
 *  This function exists for compatibility purposes because wolfSSL satisfies
 *  thread safety without relying on the callback.
 */
void wolfSSL_set_dynlock_create_callback(WOLFSSL_dynlock_value* (*f)(
                                                          const char*, int))
{
    WOLFSSL_STUB("CRYPTO_set_dynlock_create_callback");
    (void)f;
}
/*  wolfSSL_set_dynlock_lock_callback
 *  CRYPTO_set_dynlock_lock_callback has been deprecated since openSSL 1.0.1.
 *  This function exists for compatibility purposes because wolfSSL satisfies
 *  thread safety without relying on the callback.
 */
void wolfSSL_set_dynlock_lock_callback(
             void (*f)(int, WOLFSSL_dynlock_value*, const char*, int))
{
    WOLFSSL_STUB("CRYPTO_set_set_dynlock_lock_callback");
    (void)f;
}
/*  wolfSSL_set_dynlock_destroy_callback
 *  CRYPTO_set_dynlock_destroy_callback has been deprecated since openSSL 1.0.1.
 *  This function exists for compatibility purposes because wolfSSL satisfies
 *  thread safety without relying on the callback.
 */
void wolfSSL_set_dynlock_destroy_callback(
                  void (*f)(WOLFSSL_dynlock_value*, const char*, int))
{
    WOLFSSL_STUB("CRYPTO_set_set_dynlock_destroy_callback");
    (void)f;
}


#endif /* OPENSSL_EXTRA */

#ifdef OPENSSL_EXTRA
#ifndef NO_CERTS

#if !defined(NO_ASN) && !defined(NO_PWDBASED)
/* Copies unencrypted DER key buffer into "der". If "der" is null then the size
 * of buffer needed is returned. If *der == NULL then it allocates a buffer.
 * NOTE: This also advances the "der" pointer to be at the end of buffer.
 *
 * Returns size of key buffer on success
 */
int wolfSSL_i2d_PrivateKey(const WOLFSSL_EVP_PKEY* key, unsigned char** der)
{
    return wolfSSL_EVP_PKEY_get_der(key, der);
}

int wolfSSL_i2d_PublicKey(const WOLFSSL_EVP_PKEY *key, unsigned char **der)
{
    return wolfSSL_EVP_PKEY_get_der(key, der);
}
#endif /* !NO_ASN && !NO_PWDBASED */

#endif /* !NO_CERTS */
#endif /* OPENSSL_EXTRA */

#ifdef OPENSSL_EXTRA

/* Sets the DNS hostname to name.
 * Hostname is cleared if name is NULL or empty. */
int wolfSSL_set1_host(WOLFSSL * ssl, const char* name)
{
    if (ssl == NULL) {
        return WOLFSSL_FAILURE;
    }

    return wolfSSL_X509_VERIFY_PARAM_set1_host(ssl->param, name, 0);
}

/******************************************************************************
* wolfSSL_CTX_set1_param - set a pointer to the SSL verification parameters
*
* RETURNS:
*   WOLFSSL_SUCCESS on success, otherwise returns WOLFSSL_FAILURE
*   Note: Returns WOLFSSL_SUCCESS, in case either parameter is NULL,
*   same as openssl.
*/
int wolfSSL_CTX_set1_param(WOLFSSL_CTX* ctx, WOLFSSL_X509_VERIFY_PARAM *vpm)
{
    if (ctx == NULL || vpm == NULL)
        return WOLFSSL_SUCCESS;

    return wolfSSL_X509_VERIFY_PARAM_set1(ctx->param, vpm);
}

/******************************************************************************
* wolfSSL_CTX/_get0_param - return a pointer to the SSL verification parameters
*
* RETURNS:
* returns pointer to the SSL verification parameters on success,
* otherwise returns NULL
*/
WOLFSSL_X509_VERIFY_PARAM* wolfSSL_CTX_get0_param(WOLFSSL_CTX* ctx)
{
    if (ctx == NULL) {
        return NULL;
    }

    return ctx->param;
}

WOLFSSL_X509_VERIFY_PARAM* wolfSSL_get0_param(WOLFSSL* ssl)
{
    if (ssl == NULL) {
        return NULL;
    }
    return ssl->param;
}

#endif /* OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA)
int wolfSSL_i2d_ASN1_INTEGER(WOLFSSL_ASN1_INTEGER* a, unsigned char** out)
{
    int ret = 0;
    word32 idx = 0;
    int len;
    int preAlloc = 1;

    WOLFSSL_ENTER("wolfSSL_i2d_ASN1_INTEGER");

    if (a == NULL || a->data == NULL || a->length <= 0 || out == NULL) {
        WOLFSSL_MSG("Bad parameter.");
        ret = WOLFSSL_FATAL_ERROR;
    }

    if (ret == 0 && *out == NULL) {
        preAlloc = 0;
        *out = (unsigned char*)XMALLOC(a->length, NULL, DYNAMIC_TYPE_ASN1);
        if (*out == NULL) {
            WOLFSSL_MSG("Failed to allocate output buffer.");
            ret = WOLFSSL_FATAL_ERROR;
        }
    }
    if (ret == 0) {
        /*
         * A WOLFSSL_ASN1_INTEGER stores the DER buffer of the integer in its
         * "data" field, but it's only the magnitude of the number (i.e. the
         * sign isn't encoded). The "negative" field is 1 if the value should
         * be interpreted as negative and 0 otherwise. If the value is negative,
         * we need to output the 2's complement of the value in the DER output.
         */
        XMEMCPY(*out, a->data, a->length);
        if (a->negative) {
            if (GetLength(a->data, &idx, &len, a->length) < 0) {
                ret = WOLFSSL_FATAL_ERROR;
            }
            else {
                ++idx;
                for (; (int)idx < a->length; ++idx) {
                    (*out)[idx] = ~(*out)[idx];
                }
                do {
                    --idx;
                    ++(*out)[idx];
                } while ((*out)[idx] == 0);
            }
        }
    }
    if (ret == 0) {
        ret = a->length;
        if (preAlloc) {
            *out += a->length;
        }
    }

    WOLFSSL_LEAVE("wolfSSL_i2d_ASN1_INTEGER", ret);

    return ret;
}

WOLFSSL_ASN1_INTEGER* wolfSSL_d2i_ASN1_INTEGER(WOLFSSL_ASN1_INTEGER** a,
                                               const unsigned char** in,
                                               long inSz)
{
    WOLFSSL_ASN1_INTEGER* ret = NULL;
    int err = 0;
    word32 idx = 0;
    int len;

    WOLFSSL_ENTER("wolfSSL_d2i_ASN1_INTEGER");

    if (in == NULL || *in == NULL || inSz <= 0) {
        WOLFSSL_MSG("Bad parameter");
        err = 1;
    }

    if (err == 0 && (*in)[0] != ASN_INTEGER) {
        WOLFSSL_MSG("Tag doesn't indicate integer type.");
        err = 1;
    }
    if (err == 0) {
        ret = wolfSSL_ASN1_INTEGER_new();
        if (ret == NULL) {
            err = 1;
        }
        else {
            ret->type = V_ASN1_INTEGER;
        }
    }
    if (err == 0 && inSz > (long)sizeof(ret->intData)) {
        ret->data = (unsigned char*)XMALLOC(inSz, NULL, DYNAMIC_TYPE_ASN1);
        if (ret->data == NULL) {
            err = 1;
        }
        else {
            ret->isDynamic = 1;
            ret->dataMax = (word32)inSz;
        }
    }
    if (err == 0) {
        XMEMCPY(ret->data, *in, inSz);
        ret->length = (word32)inSz;
        /* Advance to the end of the length field.*/
        if (GetLength(*in, &idx, &len, (word32)inSz) < 0) {
            err = 1;
        }
        else {
            /* See 2's complement comment in wolfSSL_d2i_ASN1_INTEGER. */
            ret->negative = (*in)[idx+1] & 0x80;
            if (ret->negative) {
                ++idx;
                for (; (int)idx < inSz; ++idx) {
                    ret->data[idx] = ~ret->data[idx];
                }
                do {
                    --idx;
                    ++ret->data[idx];
                } while (ret->data[idx] == 0);
                ret->type |= V_ASN1_NEG_INTEGER;
            }
            if (a != NULL) {
                *a = ret;
            }
        }
    }

    if (err != 0) {
        wolfSSL_ASN1_INTEGER_free(ret);
        ret = NULL;
    }

    return ret;
}
#endif /* OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
/* Used to create a new WOLFSSL_ASN1_INTEGER structure.
 * returns a pointer to new structure on success and NULL on failure
 */
WOLFSSL_ASN1_INTEGER* wolfSSL_ASN1_INTEGER_new(void)
{
    WOLFSSL_ASN1_INTEGER* a;

    a = (WOLFSSL_ASN1_INTEGER*)XMALLOC(sizeof(WOLFSSL_ASN1_INTEGER), NULL,
                                       DYNAMIC_TYPE_OPENSSL);
    if (a == NULL) {
        return NULL;
    }

    XMEMSET(a, 0, sizeof(WOLFSSL_ASN1_INTEGER));
    a->data    = a->intData;
    a->isDynamic = 0;
    a->dataMax = WOLFSSL_ASN1_INTEGER_MAX;
    a->length  = 0;
    return a;
}


/* free's internal elements of WOLFSSL_ASN1_INTEGER and free's "in" itself */
void wolfSSL_ASN1_INTEGER_free(WOLFSSL_ASN1_INTEGER* in)
{
    if (in != NULL) {
        if (in->isDynamic) {
            XFREE(in->data, NULL, DYNAMIC_TYPE_OPENSSL);
        }
        XFREE(in, NULL, DYNAMIC_TYPE_OPENSSL);
    }
}


/* Duplicate all WOLFSSL_ASN1_INTEGER members from src to dup
 *  src : WOLFSSL_ASN1_INTEGER to duplicate
 *  Returns pointer to duplicate WOLFSSL_ASN1_INTEGER
 */
WOLFSSL_ASN1_INTEGER* wolfSSL_ASN1_INTEGER_dup(const WOLFSSL_ASN1_INTEGER* src)
{
    WOLFSSL_ASN1_INTEGER* copy;
    WOLFSSL_ENTER("wolfSSL_ASN1_INTEGER_dup");
    if (!src)
        return NULL;

    copy = wolfSSL_ASN1_INTEGER_new();

    if (copy == NULL)
        return NULL;

    copy->negative  = src->negative;
    copy->dataMax   = src->dataMax;
    copy->isDynamic = src->isDynamic;
#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
    copy->length    = src->length;
#endif
    XSTRNCPY((char*)copy->intData,(const char*)src->intData,WOLFSSL_ASN1_INTEGER_MAX);

    if (copy->isDynamic && src->data && copy->dataMax) {
        copy->data = (unsigned char*)
            XMALLOC(src->dataMax,NULL,DYNAMIC_TYPE_OPENSSL);
        if (copy->data == NULL) {
            wolfSSL_ASN1_INTEGER_free(copy);
            return NULL;
        }
        XMEMCPY(copy->data, src->data, copy->dataMax);
    }
    return copy;
}


/* sets the value of WOLFSSL_ASN1_INTEGER a to the long value v. */
int wolfSSL_ASN1_INTEGER_set(WOLFSSL_ASN1_INTEGER *a, long v)
{
    int ret = WOLFSSL_SUCCESS; /* return 1 for success and 0 for failure */
    int j;
    unsigned int i = 0;
    unsigned char tmp[sizeof(long)+1] = {0};
    int pad = 0;

    if (a != NULL) {
        /* dynamically create data buffer, +2 for type and length */
        a->data = (unsigned char*)XMALLOC((sizeof(long)+1) + 2, NULL,
                DYNAMIC_TYPE_OPENSSL);
        if (a->data == NULL) {
            wolfSSL_ASN1_INTEGER_free(a);
            ret = WOLFSSL_FAILURE;
        }
        else {
            a->dataMax   = (int)(sizeof(long)+1) + 2;
            a->isDynamic = 1;
        }
    }
    else {
        /* Invalid parameter */
        ret = WOLFSSL_FAILURE;
    }


    if (ret != WOLFSSL_FAILURE) {
        /* Set type */
        a->data[i++] = ASN_INTEGER;

        /* Check for negative */
        if (v < 0) {
            a->negative = 1;
            v *= -1;
        }

        /* Create char buffer */
        for (j = 0; j < (int)sizeof(long); j++) {
            if (v == 0) {
                break;
            }
            tmp[j] = (unsigned char)(v & 0xff);
            v >>= 8;
        }

        /* 0 pad to indicate positive number when top bit set. */
        if ((!a->negative) && (j > 0) && (tmp[j-1] & 0x80)) {
            pad = 1;
        }
        /* Set length */
        a->data[i++] = (unsigned char)(((j == 0) ? ++j : j) + pad);
        /* +2 for type and length */
        a->length = j + pad + 2;

        /* Add padding if required. */
        if (pad) {
            a->data[i++] = 0;
        }
        /* Copy to data */
        for (; j > 0; j--) {
            a->data[i++] = tmp[j-1];
        }
    }

    return ret;
}

#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL */

#if defined(WOLFSSL_MYSQL_COMPATIBLE) || defined(WOLFSSL_NGINX) || \
    defined(WOLFSSL_HAPROXY) || defined(OPENSSL_EXTRA) || defined(OPENSSL_ALL)
#ifndef NO_ASN_TIME
#ifndef NO_BIO
int wolfSSL_ASN1_TIME_print(WOLFSSL_BIO* bio, const WOLFSSL_ASN1_TIME* asnTime)
{
    char buf[MAX_TIME_STRING_SZ];
    int  ret = WOLFSSL_SUCCESS;

    WOLFSSL_ENTER("wolfSSL_ASN1_TIME_print");

    if (bio == NULL || asnTime == NULL) {
        WOLFSSL_MSG("NULL function argument");
        return WOLFSSL_FAILURE;
    }

    if (wolfSSL_ASN1_TIME_to_string((WOLFSSL_ASN1_TIME*)asnTime, buf,
                sizeof(buf)) == NULL) {
        XMEMSET(buf, 0, MAX_TIME_STRING_SZ);
        XSTRNCPY(buf, "Bad time value", sizeof(buf)-1);
        ret = WOLFSSL_FAILURE;
    }

    if (wolfSSL_BIO_write(bio, buf, (int)XSTRLEN(buf)) <= 0) {
        WOLFSSL_MSG("Unable to write to bio");
        return WOLFSSL_FAILURE;
    }

    return ret;
}
#endif /* !NO_BIO */

char* wolfSSL_ASN1_TIME_to_string(WOLFSSL_ASN1_TIME* t, char* buf, int len)
{
    WOLFSSL_ENTER("wolfSSL_ASN1_TIME_to_string");

    if (t == NULL || buf == NULL || len < 5) {
        WOLFSSL_MSG("Bad argument");
        return NULL;
    }

    if (t->length > len) {
        WOLFSSL_MSG("Length of date is longer then buffer");
        return NULL;
    }

    if (!GetTimeString(t->data, t->type, buf, len)) {
        return NULL;
    }

    return buf;
}

/* Converts a WOLFSSL_ASN1_TIME to a struct tm. Returns WOLFSSL_SUCCESS on
 * success and WOLFSSL_FAILURE on failure. */
static int Asn1TimeToTm(WOLFSSL_ASN1_TIME* asnTime, struct tm* tm)
{
    unsigned char* asn1TimeBuf;
    int asn1TimeBufLen;
    int i = 0;
    int bytesNeeded = 11;

    if (asnTime == NULL) {
        WOLFSSL_MSG("asnTime is NULL");
        return WOLFSSL_FAILURE;
    }
    if (tm == NULL) {
        WOLFSSL_MSG("tm is NULL");
        return WOLFSSL_FAILURE;
    }

    asn1TimeBuf = wolfSSL_ASN1_TIME_get_data(asnTime);
    if (asn1TimeBuf == NULL) {
        WOLFSSL_MSG("Failed to get WOLFSSL_ASN1_TIME buffer.");
        return WOLFSSL_FAILURE;
    }
    asn1TimeBufLen = wolfSSL_ASN1_TIME_get_length(asnTime);
    if (asn1TimeBufLen <= 0) {
        WOLFSSL_MSG("Failed to get WOLFSSL_ASN1_TIME buffer length.");
        return WOLFSSL_FAILURE;
    }
    XMEMSET(tm, 0, sizeof(struct tm));

    /* Convert ASN1_time to struct tm */
    /* Check type */
    if (asnTime->type == ASN_UTC_TIME) {
        /* 2-digit year */
        bytesNeeded += 2;
        if (bytesNeeded > asn1TimeBufLen) {
            WOLFSSL_MSG("WOLFSSL_ASN1_TIME buffer length is invalid.");
            return WOLFSSL_FAILURE;
        }
        if (asn1TimeBuf[bytesNeeded-1] != 'Z') {
            WOLFSSL_MSG("Expecting UTC time.");
            return WOLFSSL_FAILURE;
        }

        tm->tm_year = (asn1TimeBuf[i] - '0') * 10; i++;
        tm->tm_year += asn1TimeBuf[i] - '0'; i++;
        if (tm->tm_year < 70) {
            tm->tm_year += 100;
        }
    }
    else if (asnTime->type == ASN_GENERALIZED_TIME) {
        /* 4-digit year */
        bytesNeeded += 4;
        if (bytesNeeded > asn1TimeBufLen) {
            WOLFSSL_MSG("WOLFSSL_ASN1_TIME buffer length is invalid.");
            return WOLFSSL_FAILURE;
        }
        if (asn1TimeBuf[bytesNeeded-1] != 'Z') {
            WOLFSSL_MSG("Expecting UTC time.");
            return WOLFSSL_FAILURE;
        }

        tm->tm_year = (asn1TimeBuf[i] - '0') * 1000; i++;
        tm->tm_year += (asn1TimeBuf[i] - '0') * 100; i++;
        tm->tm_year += (asn1TimeBuf[i] - '0') * 10; i++;
        tm->tm_year += asn1TimeBuf[i] - '0'; i++;
        tm->tm_year -= 1900;
    }
    else {
        WOLFSSL_MSG("asnTime->type is invalid.");
        return WOLFSSL_FAILURE;
    }

    tm->tm_mon = (asn1TimeBuf[i] - '0') * 10; i++;
    tm->tm_mon += (asn1TimeBuf[i] - '0') - 1; i++; /* January is 0 not 1 */
    tm->tm_mday = (asn1TimeBuf[i] - '0') * 10; i++;
    tm->tm_mday += (asn1TimeBuf[i] - '0'); i++;
    tm->tm_hour = (asn1TimeBuf[i] - '0') * 10; i++;
    tm->tm_hour += (asn1TimeBuf[i] - '0'); i++;
    tm->tm_min = (asn1TimeBuf[i] - '0') * 10; i++;
    tm->tm_min += (asn1TimeBuf[i] - '0'); i++;
    tm->tm_sec = (asn1TimeBuf[i] - '0') * 10; i++;
    tm->tm_sec += (asn1TimeBuf[i] - '0');

#ifdef XMKTIME
    /* Call XMKTIME on tm to get the tm_wday and tm_yday fields populated. */
    XMKTIME(tm);
#endif

    return WOLFSSL_SUCCESS;
}

int wolfSSL_ASN1_TIME_to_tm(const WOLFSSL_ASN1_TIME* asnTime, struct tm* tm)
{
    time_t currentTime;
    struct tm *tmpTs;
#if defined(NEED_TMP_TIME)
    /* for use with gmtime_r */
    struct tm tmpTimeStorage;
    tmpTs = &tmpTimeStorage;
#else
    tmpTs = NULL;
#endif
    (void)tmpTs;

    WOLFSSL_ENTER("wolfSSL_ASN1_TIME_to_tm");

    /* If asnTime is NULL, then the current time is converted. */
    if (asnTime == NULL) {
        if (tm == NULL) {
            WOLFSSL_MSG("asnTime and tm are both NULL");
            return WOLFSSL_FAILURE;
        }

        currentTime = wc_Time(0);
        if (currentTime <= 0) {
            WOLFSSL_MSG("Failed to get current time.");
            return WOLFSSL_FAILURE;
        }

        tm = XGMTIME(&currentTime, tmpTs);
        if (tm == NULL) {
            WOLFSSL_MSG("Failed to convert current time to UTC.");
            return WOLFSSL_FAILURE;
        }

        return WOLFSSL_SUCCESS;
    }

    /* If tm is NULL this function performs a format check on asnTime only. */
    if (tm == NULL) {
        return wolfSSL_ASN1_TIME_check(asnTime);
    }

    return Asn1TimeToTm((WOLFSSL_ASN1_TIME*)asnTime, tm);
}
#endif /* !NO_ASN_TIME */
#endif /* WOLFSSL_MYSQL_COMPATIBLE || WOLFSSL_NGINX || WOLFSSL_HAPROXY ||
    OPENSSL_EXTRA*/


#ifdef OPENSSL_EXTRA

int wolfSSL_ASN1_INTEGER_cmp(const WOLFSSL_ASN1_INTEGER* a,
                             const WOLFSSL_ASN1_INTEGER* b)
{
    int ret = 0;

    WOLFSSL_ENTER("wolfSSL_ASN1_INTEGER_cmp");

    if (a == NULL || b == NULL) {
        WOLFSSL_MSG("Bad parameter.");
        ret = WOLFSSL_FATAL_ERROR;
    }

    if (ret == 0 && ((a->length != b->length) ||
                     ((a->negative == 0) != (b->negative == 0)))) {
        ret = WOLFSSL_FATAL_ERROR;
    }
    if (ret == 0) {
        ret = XMEMCMP(a->data, b->data, a->length);
    }

    WOLFSSL_LEAVE("wolfSSL_ASN1_INTEGER_cmp", ret);

    return ret;
}

long wolfSSL_ASN1_INTEGER_get(const WOLFSSL_ASN1_INTEGER* a)
{
    long ret = 1;
    WOLFSSL_BIGNUM* bn = NULL;

    WOLFSSL_ENTER("ASN1_INTEGER_get");

    if (a == NULL) {
        /* OpenSSL returns 0 when a is NULL and -1 if there is an error. Quoting
         * the documentation:
         *
         * "ASN1_INTEGER_get() also returns the value of a but it returns 0 if a
         * is NULL and -1 on error (which is ambiguous because -1 is a
         * legitimate value for an ASN1_INTEGER). New applications should use
         * ASN1_INTEGER_get_int64() instead."
         * */
        ret = 0;
    }

    if (ret > 0) {
        bn = wolfSSL_ASN1_INTEGER_to_BN(a, NULL);
        if (bn == NULL) {
            ret = -1;
        }
    }
    if (ret > 0) {
        ret = wolfSSL_BN_get_word(bn);
        if (a->negative == 1) {
            ret = -ret;
        }
    }

    if (bn != NULL) {
        wolfSSL_BN_free(bn);
    }

    WOLFSSL_LEAVE("ASN1_INTEGER_get", (int)ret);

    return ret;
}

#endif /* OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
/* Gets an index to store SSL structure at.
 *
 * Returns positive index on success and negative values on failure
 */
int wolfSSL_get_ex_data_X509_STORE_CTX_idx(void)
{
    WOLFSSL_ENTER("wolfSSL_get_ex_data_X509_STORE_CTX_idx");

    /* store SSL at index 0 */
    return 0;
}
#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL */

#ifdef OPENSSL_EXTRA
/* Sets a function callback that will send information about the state of all
 * WOLFSSL objects that have been created by the WOLFSSL_CTX structure passed
 * in.
 *
 * ctx WOLFSSL_CTX structure to set callback function in
 * f   callback function to use
 */
void wolfSSL_CTX_set_info_callback(WOLFSSL_CTX* ctx,
       void (*f)(const WOLFSSL* ssl, int type, int val))
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_info_callback");
    if (ctx == NULL) {
        WOLFSSL_MSG("Bad function argument");
    }
    else {
        ctx->CBIS = f;
    }
}


unsigned long wolfSSL_ERR_peek_error(void)
{
    WOLFSSL_ENTER("wolfSSL_ERR_peek_error");

    return wolfSSL_ERR_peek_error_line_data(NULL, NULL, NULL, NULL);
}

int wolfSSL_ERR_GET_LIB(unsigned long err)
{
    unsigned long value;

    value = (err & 0xFFFFFFL);
    switch (value) {
    case -SSL_R_HTTP_REQUEST:
        return ERR_LIB_SSL;
    case -ASN_NO_PEM_HEADER:
    case PEM_R_NO_START_LINE:
    case PEM_R_PROBLEMS_GETTING_PASSWORD:
    case PEM_R_BAD_PASSWORD_READ:
    case PEM_R_BAD_DECRYPT:
        return ERR_LIB_PEM;
    case EVP_R_BAD_DECRYPT:
    case EVP_R_BN_DECODE_ERROR:
    case EVP_R_DECODE_ERROR:
    case EVP_R_PRIVATE_KEY_DECODE_ERROR:
        return ERR_LIB_EVP;
    case ASN1_R_HEADER_TOO_LONG:
        return ERR_LIB_ASN1;
    default:
        return 0;
    }
}

/* This function is to find global error values that are the same through out
 * all library version. With wolfSSL having only one set of error codes the
 * return value is pretty straight forward. The only thing needed is all wolfSSL
 * error values are typically negative.
 *
 * Returns the error reason
 */
int wolfSSL_ERR_GET_REASON(unsigned long err)
{
    int ret = (int)err;

    WOLFSSL_ENTER("wolfSSL_ERR_GET_REASON");

#if defined(OPENSSL_ALL) || defined(WOLFSSL_NGINX) || defined(WOLFSSL_HAPROXY)
    /* Nginx looks for this error to know to stop parsing certificates.
     * Same for HAProxy. */
    if (err == ((ERR_LIB_PEM << 24) | PEM_R_NO_START_LINE)
        || (err & 0xFFFFFFL) == -ASN_NO_PEM_HEADER)
        return PEM_R_NO_START_LINE;
    if (err == ((ERR_LIB_SSL << 24) | -SSL_R_HTTP_REQUEST))
        return SSL_R_HTTP_REQUEST;
#endif
#if defined(OPENSSL_ALL) && defined(WOLFSSL_PYTHON)
    if (err == ((ERR_LIB_ASN1 << 24) | ASN1_R_HEADER_TOO_LONG))
        return ASN1_R_HEADER_TOO_LONG;
#endif

    /* check if error value is in range of wolfSSL errors */
    ret = 0 - ret; /* setting as negative value */
    /* wolfCrypt range is less than MAX (-100)
       wolfSSL range is MIN (-300) and lower */
    if (ret < MAX_CODE_E && ret > MIN_CODE_E) {
        return ret;
    }
    else {
        WOLFSSL_MSG("Not in range of typical error values");
        ret = (int)err;
    }

    return ret;
}

/* returns a string that describes the alert
 *
 * alertID the alert value to look up
 */
const char* wolfSSL_alert_type_string_long(int alertID)
{
    WOLFSSL_ENTER("wolfSSL_alert_type_string_long");

    return AlertTypeToString(alertID);
}


const char* wolfSSL_alert_desc_string_long(int alertID)
{
    WOLFSSL_ENTER("wolfSSL_alert_desc_string_long");

    return AlertTypeToString(alertID);
}

#define STATE_STRINGS_PROTO(s) \
    {                          \
        {"SSLv3 " s,           \
         "SSLv3 " s,           \
         "SSLv3 " s},          \
        {"TLSv1 " s,           \
         "TLSv1 " s,           \
         "TLSv1 " s},          \
        {"TLSv1_1 " s,         \
         "TLSv1_1 " s,         \
         "TLSv1_1 " s},        \
        {"TLSv1_2 " s,         \
         "TLSv1_2 " s,         \
         "TLSv1_2 " s},        \
        {"TLSv1_3 " s,         \
         "TLSv1_3 " s,         \
         "TLSv1_3 " s},        \
        {"DTLSv1 " s,          \
         "DTLSv1 " s,          \
         "DTLSv1 " s},         \
        {"DTLSv1_2 " s,        \
         "DTLSv1_2 " s,        \
         "DTLSv1_2 " s},       \
        {"DTLSv1_3 " s,        \
         "DTLSv1_3 " s,        \
         "DTLSv1_3 " s},       \
    }

#define STATE_STRINGS_PROTO_RW(s) \
    {                             \
        {"SSLv3 read " s,         \
         "SSLv3 write " s,        \
         "SSLv3 " s},             \
        {"TLSv1 read " s,         \
         "TLSv1 write " s,        \
         "TLSv1 " s},             \
        {"TLSv1_1 read " s,       \
         "TLSv1_1 write " s,      \
         "TLSv1_1 " s},           \
        {"TLSv1_2 read " s,       \
         "TLSv1_2 write " s,      \
         "TLSv1_2 " s},           \
        {"TLSv1_3 read " s,       \
         "TLSv1_3 write " s,      \
         "TLSv1_3 " s},           \
        {"DTLSv1 read " s,        \
         "DTLSv1 write " s,       \
         "DTLSv1 " s},            \
        {"DTLSv1_2 read " s,      \
         "DTLSv1_2 write " s,     \
         "DTLSv1_2 " s},          \
        {"DTLSv1_3 read " s,      \
         "DTLSv1_3 write " s,     \
         "DTLSv1_3 " s},          \
    }

/* Gets the current state of the WOLFSSL structure
 *
 * ssl WOLFSSL structure to get state of
 *
 * Returns a human readable string of the WOLFSSL structure state
 */
const char* wolfSSL_state_string_long(const WOLFSSL* ssl)
{

    static const char* OUTPUT_STR[24][8][3] = {
        STATE_STRINGS_PROTO("Initialization"),
        STATE_STRINGS_PROTO_RW("Server Hello Request"),
        STATE_STRINGS_PROTO_RW("Server Hello Verify Request"),
        STATE_STRINGS_PROTO_RW("Server Hello Retry Request"),
        STATE_STRINGS_PROTO_RW("Server Hello"),
        STATE_STRINGS_PROTO_RW("Server Certificate Status"),
        STATE_STRINGS_PROTO_RW("Server Encrypted Extensions"),
        STATE_STRINGS_PROTO_RW("Server Session Ticket"),
        STATE_STRINGS_PROTO_RW("Server Certificate Request"),
        STATE_STRINGS_PROTO_RW("Server Cert"),
        STATE_STRINGS_PROTO_RW("Server Key Exchange"),
        STATE_STRINGS_PROTO_RW("Server Hello Done"),
        STATE_STRINGS_PROTO_RW("Server Change CipherSpec"),
        STATE_STRINGS_PROTO_RW("Server Finished"),
        STATE_STRINGS_PROTO_RW("server Key Update"),
        STATE_STRINGS_PROTO_RW("Client Hello"),
        STATE_STRINGS_PROTO_RW("Client Key Exchange"),
        STATE_STRINGS_PROTO_RW("Client Cert"),
        STATE_STRINGS_PROTO_RW("Client Change CipherSpec"),
        STATE_STRINGS_PROTO_RW("Client Certificate Verify"),
        STATE_STRINGS_PROTO_RW("Client End Of Early Data"),
        STATE_STRINGS_PROTO_RW("Client Finished"),
        STATE_STRINGS_PROTO_RW("Client Key Update"),
        STATE_STRINGS_PROTO("Handshake Done"),
    };
    enum ProtocolVer {
        SSL_V3 = 0,
        TLS_V1,
        TLS_V1_1,
        TLS_V1_2,
        TLS_V1_3,
        DTLS_V1,
        DTLS_V1_2,
        DTLS_V1_3,
        UNKNOWN = 100
    };

    enum IOMode {
        SS_READ = 0,
        SS_WRITE,
        SS_NEITHER
    };

    enum SslState {
        ss_null_state = 0,
        ss_server_hellorequest,
        ss_server_helloverify,
        ss_server_helloretryrequest,
        ss_server_hello,
        ss_server_certificatestatus,
        ss_server_encryptedextensions,
        ss_server_sessionticket,
        ss_server_certrequest,
        ss_server_cert,
        ss_server_keyexchange,
        ss_server_hellodone,
        ss_server_changecipherspec,
        ss_server_finished,
        ss_server_keyupdate,
        ss_client_hello,
        ss_client_keyexchange,
        ss_client_cert,
        ss_client_changecipherspec,
        ss_client_certverify,
        ss_client_endofearlydata,
        ss_client_finished,
        ss_client_keyupdate,
        ss_handshake_done
    };

    int protocol = 0;
    int cbmode = 0;
    int state = 0;

    WOLFSSL_ENTER("wolfSSL_state_string_long");
    if (ssl == NULL) {
        WOLFSSL_MSG("Null argument passed in");
        return NULL;
    }

    /* Get state of callback */
    if (ssl->cbmode == SSL_CB_MODE_WRITE) {
        cbmode =  SS_WRITE;
    }
    else if (ssl->cbmode == SSL_CB_MODE_READ) {
        cbmode =  SS_READ;
    }
    else {
        cbmode =  SS_NEITHER;
    }

    /* Get protocol version */
    switch (ssl->version.major) {
        case SSLv3_MAJOR:
            switch (ssl->version.minor) {
                case SSLv3_MINOR:
                    protocol = SSL_V3;
                    break;
                case TLSv1_MINOR:
                    protocol = TLS_V1;
                    break;
                case TLSv1_1_MINOR:
                    protocol = TLS_V1_1;
                    break;
                case TLSv1_2_MINOR:
                    protocol = TLS_V1_2;
                    break;
                case TLSv1_3_MINOR:
                    protocol = TLS_V1_3;
                    break;
                default:
                    protocol = UNKNOWN;
            }
            break;
        case DTLS_MAJOR:
            switch (ssl->version.minor) {
                case DTLS_MINOR:
                    protocol = DTLS_V1;
                    break;
                case DTLSv1_2_MINOR:
                    protocol = DTLS_V1_2;
                    break;
                case DTLSv1_3_MINOR:
                    protocol = DTLS_V1_3;
                    break;
                default:
                    protocol = UNKNOWN;
            }
            break;
    default:
        protocol = UNKNOWN;
    }

    /* accept process */
    if (ssl->cbmode == SSL_CB_MODE_READ) {
        state = ssl->cbtype;
        switch (state) {
            case hello_request:
                state = ss_server_hellorequest;
                break;
            case client_hello:
                state = ss_client_hello;
                break;
            case server_hello:
                state = ss_server_hello;
                break;
            case hello_verify_request:
                state = ss_server_helloverify;
                break;
            case session_ticket:
                state = ss_server_sessionticket;
                break;
            case end_of_early_data:
                state = ss_client_endofearlydata;
                break;
            case hello_retry_request:
                state = ss_server_helloretryrequest;
                break;
            case encrypted_extensions:
                state = ss_server_encryptedextensions;
                break;
            case certificate:
                if (ssl->options.side == WOLFSSL_SERVER_END)
                    state = ss_client_cert;
                else if (ssl->options.side == WOLFSSL_CLIENT_END)
                    state = ss_server_cert;
                else {
                    WOLFSSL_MSG("Unknown State");
                    state = ss_null_state;
                }
                break;
            case server_key_exchange:
                state = ss_server_keyexchange;
                break;
            case certificate_request:
                state = ss_server_certrequest;
                break;
            case server_hello_done:
                state = ss_server_hellodone;
                break;
            case certificate_verify:
                state = ss_client_certverify;
                break;
            case client_key_exchange:
                state = ss_client_keyexchange;
                break;
            case finished:
                if (ssl->options.side == WOLFSSL_SERVER_END)
                    state = ss_client_finished;
                else if (ssl->options.side == WOLFSSL_CLIENT_END)
                    state = ss_server_finished;
                else {
                    WOLFSSL_MSG("Unknown State");
                    state = ss_null_state;
                }
                break;
            case certificate_status:
                state = ss_server_certificatestatus;
                break;
            case key_update:
                if (ssl->options.side == WOLFSSL_SERVER_END)
                    state = ss_client_keyupdate;
                else if (ssl->options.side == WOLFSSL_CLIENT_END)
                    state = ss_server_keyupdate;
                else {
                    WOLFSSL_MSG("Unknown State");
                    state = ss_null_state;
                }
                break;
            case change_cipher_hs:
                if (ssl->options.side == WOLFSSL_SERVER_END)
                    state = ss_client_changecipherspec;
                else if (ssl->options.side == WOLFSSL_CLIENT_END)
                    state = ss_server_changecipherspec;
                else {
                    WOLFSSL_MSG("Unknown State");
                    state = ss_null_state;
                }
                break;
            default:
                WOLFSSL_MSG("Unknown State");
                state = ss_null_state;
        }
    }
    else {
        /* Send process */
        if (ssl->options.side == WOLFSSL_SERVER_END)
            state = ssl->options.serverState;
        else
            state = ssl->options.clientState;

        switch (state) {
            case SERVER_HELLOVERIFYREQUEST_COMPLETE:
                state = ss_server_helloverify;
                break;
            case SERVER_HELLO_RETRY_REQUEST_COMPLETE:
                state = ss_server_helloretryrequest;
                break;
            case SERVER_HELLO_COMPLETE:
                state = ss_server_hello;
                break;
            case SERVER_ENCRYPTED_EXTENSIONS_COMPLETE:
                state = ss_server_encryptedextensions;
                break;
            case SERVER_CERT_COMPLETE:
                state = ss_server_cert;
                break;
            case SERVER_KEYEXCHANGE_COMPLETE:
                state = ss_server_keyexchange;
                break;
            case SERVER_HELLODONE_COMPLETE:
                state = ss_server_hellodone;
                break;
            case SERVER_CHANGECIPHERSPEC_COMPLETE:
                state = ss_server_changecipherspec;
                break;
            case SERVER_FINISHED_COMPLETE:
                state = ss_server_finished;
                break;
            case CLIENT_HELLO_RETRY:
            case CLIENT_HELLO_COMPLETE:
                state = ss_client_hello;
                break;
            case CLIENT_KEYEXCHANGE_COMPLETE:
                state = ss_client_keyexchange;
                break;
            case CLIENT_CHANGECIPHERSPEC_COMPLETE:
                state = ss_client_changecipherspec;
                break;
            case CLIENT_FINISHED_COMPLETE:
                state = ss_client_finished;
                break;
            case HANDSHAKE_DONE:
                state = ss_handshake_done;
                break;
            default:
                WOLFSSL_MSG("Unknown State");
                state = ss_null_state;
        }
    }

    if (protocol == UNKNOWN) {
        WOLFSSL_MSG("Unknown protocol");
        return "";
    }
    else {
        return OUTPUT_STR[state][protocol][cbmode];
    }
}

/*
 * Sets default PEM callback password if null is passed into
 * the callback parameter of a PEM_read_bio_* function.
 *
 * Returns callback phrase size on success or WOLFSSL_FAILURE otherwise.
 */
int wolfSSL_PEM_def_callback(char* name, int num, int w, void* key)
{
    int sz;
    (void)w;
    WOLFSSL_ENTER("wolfSSL_PEM_def_callback");

    /* We assume that the user passes a default password as userdata */
    if (key) {
        sz = (int)XSTRLEN((const char*)key);
        sz = (sz > num) ? num : sz;
        XMEMCPY(name, key, sz);
        return sz;
    } else {
        WOLFSSL_MSG("Error, default password cannot be created.");
        return WOLFSSL_FAILURE;
    }
}

#endif /* OPENSSL_EXTRA */

static long wolf_set_options(long old_op, long op)
{
    /* if SSL_OP_ALL then turn all bug workarounds on */
    if ((op & WOLFSSL_OP_ALL) == WOLFSSL_OP_ALL) {
        WOLFSSL_MSG("\tSSL_OP_ALL");
    }

    /* by default cookie exchange is on with DTLS */
    if ((op & WOLFSSL_OP_COOKIE_EXCHANGE) == WOLFSSL_OP_COOKIE_EXCHANGE) {
        WOLFSSL_MSG("\tSSL_OP_COOKIE_EXCHANGE : on by default");
    }

    if ((op & WOLFSSL_OP_NO_SSLv2) == WOLFSSL_OP_NO_SSLv2) {
        WOLFSSL_MSG("\tWOLFSSL_OP_NO_SSLv2 : wolfSSL does not support SSLv2");
    }

#ifdef SSL_OP_NO_TLSv1_3
    if ((op & WOLFSSL_OP_NO_TLSv1_3) == WOLFSSL_OP_NO_TLSv1_3) {
        WOLFSSL_MSG("\tSSL_OP_NO_TLSv1_3");
    }
#endif

    if ((op & WOLFSSL_OP_NO_TLSv1_2) == WOLFSSL_OP_NO_TLSv1_2) {
        WOLFSSL_MSG("\tSSL_OP_NO_TLSv1_2");
    }

    if ((op & WOLFSSL_OP_NO_TLSv1_1) == WOLFSSL_OP_NO_TLSv1_1) {
        WOLFSSL_MSG("\tSSL_OP_NO_TLSv1_1");
    }

    if ((op & WOLFSSL_OP_NO_TLSv1) == WOLFSSL_OP_NO_TLSv1) {
        WOLFSSL_MSG("\tSSL_OP_NO_TLSv1");
    }

    if ((op & WOLFSSL_OP_NO_SSLv3) == WOLFSSL_OP_NO_SSLv3) {
        WOLFSSL_MSG("\tSSL_OP_NO_SSLv3");
    }

    if ((op & WOLFSSL_OP_CIPHER_SERVER_PREFERENCE) ==
            WOLFSSL_OP_CIPHER_SERVER_PREFERENCE) {
        WOLFSSL_MSG("\tWOLFSSL_OP_CIPHER_SERVER_PREFERENCE");
    }

    if ((op & WOLFSSL_OP_NO_COMPRESSION) == WOLFSSL_OP_NO_COMPRESSION) {
    #ifdef HAVE_LIBZ
        WOLFSSL_MSG("SSL_OP_NO_COMPRESSION");
    #else
        WOLFSSL_MSG("SSL_OP_NO_COMPRESSION: compression not compiled in");
    #endif
    }

    return old_op | op;
}

long wolfSSL_set_options(WOLFSSL* ssl, long op)
{
    word16 haveRSA = 1;
    word16 havePSK = 0;
    int    keySz   = 0;

    WOLFSSL_ENTER("wolfSSL_set_options");

    if (ssl == NULL) {
        return 0;
    }

    ssl->options.mask = wolf_set_options(ssl->options.mask, op);

    if ((ssl->options.mask & WOLFSSL_OP_NO_TLSv1_3) == WOLFSSL_OP_NO_TLSv1_3) {
        if (ssl->version.minor == TLSv1_3_MINOR)
            ssl->version.minor = TLSv1_2_MINOR;
    }

    if ((ssl->options.mask & WOLFSSL_OP_NO_TLSv1_2) == WOLFSSL_OP_NO_TLSv1_2) {
        if (ssl->version.minor == TLSv1_2_MINOR)
            ssl->version.minor = TLSv1_1_MINOR;
    }

    if ((ssl->options.mask & WOLFSSL_OP_NO_TLSv1_1) == WOLFSSL_OP_NO_TLSv1_1) {
        if (ssl->version.minor == TLSv1_1_MINOR)
            ssl->version.minor = TLSv1_MINOR;
    }

    if ((ssl->options.mask & WOLFSSL_OP_NO_TLSv1) == WOLFSSL_OP_NO_TLSv1) {
        if (ssl->version.minor == TLSv1_MINOR)
            ssl->version.minor = SSLv3_MINOR;
    }

    if ((ssl->options.mask & WOLFSSL_OP_NO_COMPRESSION)
        == WOLFSSL_OP_NO_COMPRESSION) {
    #ifdef HAVE_LIBZ
        ssl->options.usingCompression = 0;
    #endif
    }

#if defined(HAVE_SESSION_TICKET) && (defined(OPENSSL_EXTRA) \
        || defined(HAVE_WEBSERVER) || defined(WOLFSSL_WPAS_SMALL))
    if ((ssl->options.mask & WOLFSSL_OP_NO_TICKET) == WOLFSSL_OP_NO_TICKET) {
      ssl->options.noTicketTls12 = 1;
    }
#endif


    /* in the case of a version change the cipher suites should be reset */
#ifndef NO_PSK
    havePSK = ssl->options.havePSK;
#endif
#ifdef NO_RSA
    haveRSA = 0;
#endif
#ifndef NO_CERTS
    keySz = ssl->buffers.keySz;
#endif

    if (ssl->suites != NULL && ssl->options.side != WOLFSSL_NEITHER_END)
        InitSuites(ssl->suites, ssl->version, keySz, haveRSA, havePSK,
                   ssl->options.haveDH, ssl->options.haveECDSAsig,
                   ssl->options.haveECC, TRUE, ssl->options.haveStaticECC,
                   ssl->options.haveFalconSig, ssl->options.haveDilithiumSig,
                   ssl->options.haveAnon, TRUE, ssl->options.side);

    return ssl->options.mask;
}


long wolfSSL_get_options(const WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_get_options");
    if(ssl == NULL)
        return WOLFSSL_FAILURE;
    return ssl->options.mask;
}

#if defined(HAVE_SECURE_RENEGOTIATION) \
        || defined(HAVE_SERVER_RENEGOTIATION_INFO)
/* clears the counter for number of renegotiations done
 * returns the current count before it is cleared */
long wolfSSL_clear_num_renegotiations(WOLFSSL *s)
{
    long total;

    WOLFSSL_ENTER("wolfSSL_clear_num_renegotiations");
    if (s == NULL)
        return 0;

    total = s->secure_rene_count;
    s->secure_rene_count = 0;
    return total;
}


/* return the number of renegotiations since wolfSSL_new */
long wolfSSL_total_renegotiations(WOLFSSL *s)
{
    WOLFSSL_ENTER("wolfSSL_total_renegotiations");
    return wolfSSL_num_renegotiations(s);
}


/* return the number of renegotiations since wolfSSL_new */
long wolfSSL_num_renegotiations(WOLFSSL* s)
{
    if (s == NULL) {
        return 0;
    }

    return s->secure_rene_count;
}


/* Is there a renegotiation currently in progress? */
int  wolfSSL_SSL_renegotiate_pending(WOLFSSL *s)
{
    return s && s->options.handShakeDone &&
            s->options.handShakeState != HANDSHAKE_DONE ? 1 : 0;
}
#endif /* HAVE_SECURE_RENEGOTIATION || HAVE_SERVER_RENEGOTIATION_INFO */

#ifdef OPENSSL_EXTRA

long wolfSSL_clear_options(WOLFSSL* ssl, long opt)
{
    WOLFSSL_ENTER("SSL_clear_options");
    if(ssl == NULL)
        return WOLFSSL_FAILURE;
    ssl->options.mask &= ~opt;
    return ssl->options.mask;
}

#ifdef HAVE_PK_CALLBACKS
long wolfSSL_set_tlsext_debug_arg(WOLFSSL* ssl, void *arg)
{
    if (ssl == NULL) {
        return WOLFSSL_FAILURE;
    }

    ssl->loggingCtx = arg;
    return WOLFSSL_SUCCESS;
}
#endif /* HAVE_PK_CALLBACKS */

#if defined(OPENSSL_ALL) || defined(WOLFSSL_HAPROXY)
const unsigned char *SSL_SESSION_get0_id_context(const WOLFSSL_SESSION *sess, unsigned int *sid_ctx_length)
{
    sess = ClientSessionToSession(sess);
    return wolfSSL_SESSION_get_id((WOLFSSL_SESSION *)sess, sid_ctx_length);
}
#endif

/*** TBD ***/
#ifndef NO_WOLFSSL_STUB
int wolfSSL_sk_SSL_COMP_zero(WOLFSSL_STACK* st)
{
    (void)st;
    WOLFSSL_STUB("wolfSSL_sk_SSL_COMP_zero");
    /* wolfSSL_set_options(ssl, SSL_OP_NO_COMPRESSION); */
    return WOLFSSL_FAILURE;
}
#endif

#ifdef HAVE_CERTIFICATE_STATUS_REQUEST
long wolfSSL_set_tlsext_status_type(WOLFSSL *s, int type)
{
    WOLFSSL_ENTER("wolfSSL_set_tlsext_status_type");

    if (s == NULL){
        return BAD_FUNC_ARG;
    }

    if (type == TLSEXT_STATUSTYPE_ocsp){
        int r = TLSX_UseCertificateStatusRequest(&s->extensions, (byte)type, 0, s,
                                                             s->heap, s->devId);
        return (long)r;
    } else {
        WOLFSSL_MSG(
       "SSL_set_tlsext_status_type only supports TLSEXT_STATUSTYPE_ocsp type.");
        return SSL_FAILURE;
    }

}

long wolfSSL_get_tlsext_status_type(WOLFSSL *s)
{
    TLSX* extension;

    if (s == NULL)
        return WOLFSSL_FATAL_ERROR;
    extension = TLSX_Find(s->extensions, TLSX_STATUS_REQUEST);
    return extension != NULL ? TLSEXT_STATUSTYPE_ocsp : WOLFSSL_FATAL_ERROR;
}
#endif /* HAVE_CERTIFICATE_STATUS_REQUEST */

#ifndef NO_WOLFSSL_STUB
long wolfSSL_get_tlsext_status_exts(WOLFSSL *s, void *arg)
{
    (void)s;
    (void)arg;
    WOLFSSL_STUB("wolfSSL_get_tlsext_status_exts");
    return WOLFSSL_FAILURE;
}
#endif

/*** TBD ***/
#ifndef NO_WOLFSSL_STUB
long wolfSSL_set_tlsext_status_exts(WOLFSSL *s, void *arg)
{
    (void)s;
    (void)arg;
    WOLFSSL_STUB("wolfSSL_set_tlsext_status_exts");
    return WOLFSSL_FAILURE;
}
#endif

/*** TBD ***/
#ifndef NO_WOLFSSL_STUB
long wolfSSL_get_tlsext_status_ids(WOLFSSL *s, void *arg)
{
    (void)s;
    (void)arg;
    WOLFSSL_STUB("wolfSSL_get_tlsext_status_ids");
    return WOLFSSL_FAILURE;
}
#endif

/*** TBD ***/
#ifndef NO_WOLFSSL_STUB
long wolfSSL_set_tlsext_status_ids(WOLFSSL *s, void *arg)
{
    (void)s;
    (void)arg;
    WOLFSSL_STUB("wolfSSL_set_tlsext_status_ids");
    return WOLFSSL_FAILURE;
}
#endif

/*** TBD ***/
#ifndef NO_WOLFSSL_STUB
int wolfSSL_SESSION_set1_id(WOLFSSL_SESSION *s, const unsigned char *sid,
    unsigned int sid_len)
{
    (void)s;
    (void)sid;
    (void)sid_len;
    WOLFSSL_STUB("SSL_SESSION_set1_id");
    return WOLFSSL_FAILURE;
}
#endif

#ifndef NO_WOLFSSL_STUB
/*** TBD ***/
int wolfSSL_SESSION_set1_id_context(WOLFSSL_SESSION *s,
    const unsigned char *sid_ctx, unsigned int sid_ctx_len)
{
    (void)s;
    (void)sid_ctx;
    (void)sid_ctx_len;
    WOLFSSL_STUB("SSL_SESSION_set1_id_context");
    return WOLFSSL_FAILURE;
}
#endif

#if defined(OPENSSL_ALL) || defined(WOLFSSL_APACHE_HTTPD) \
    || defined(WOLFSSL_HAPROXY) || defined(WOLFSSL_WPAS)
/**
 * Set `a` in a smart way.
 *
 * @param a Object to set
 * @param type The type of object in value
 * @param value Object to set
 */
void wolfSSL_ASN1_TYPE_set(WOLFSSL_ASN1_TYPE *a, int type, void *value)
{
    if (!a) {
        return;
    }
    switch (type) {
        case V_ASN1_NULL:
            a->value.ptr = (char *)value;
            break;
        case V_ASN1_SEQUENCE:
            a->value.asn1_string = (WOLFSSL_ASN1_STRING*)value;
            break;
        case V_ASN1_OBJECT:
            a->value.object = (WOLFSSL_ASN1_OBJECT*)value;
            break;
        case V_ASN1_UTCTIME:
            a->value.utctime = (WOLFSSL_ASN1_TIME*)value;
            break;
        case V_ASN1_GENERALIZEDTIME:
            a->value.generalizedtime = (WOLFSSL_ASN1_TIME*)value;
            break;
        default:
            WOLFSSL_MSG("Unknown or unsupported ASN1_TYPE");
            return;
    }
    a->type = type;
}

#endif /* OPENSSL_ALL || WOLFSSL_APACHE_HTTPD || WOLFSSL_HAPROXY || WOLFSSL_WPAS */

#if defined(OPENSSL_ALL) || defined(WOLFSSL_APACHE_HTTPD) \
    || defined(WOLFSSL_HAPROXY) || defined(WOLFSSL_WPAS) \
    || defined(OPENSSL_EXTRA)
/**
 * Allocate a new WOLFSSL_ASN1_TYPE object.
 *
 * @return New zero'ed WOLFSSL_ASN1_TYPE object
 */
WOLFSSL_ASN1_TYPE* wolfSSL_ASN1_TYPE_new(void)
{
    WOLFSSL_ASN1_TYPE* ret = (WOLFSSL_ASN1_TYPE*)XMALLOC(sizeof(WOLFSSL_ASN1_TYPE),
                                                        NULL, DYNAMIC_TYPE_OPENSSL);
    if (!ret)
        return NULL;
    XMEMSET(ret, 0, sizeof(WOLFSSL_ASN1_TYPE));
    return ret;
}

/**
 * Free WOLFSSL_ASN1_TYPE and all its members.
 *
 * @param at Object to free
 */
void wolfSSL_ASN1_TYPE_free(WOLFSSL_ASN1_TYPE* at)
{
    if (at) {
        switch (at->type) {
            case V_ASN1_OBJECT:
                wolfSSL_ASN1_OBJECT_free(at->value.object);
                break;
            case V_ASN1_UTCTIME:
            #ifndef NO_ASN_TIME
                wolfSSL_ASN1_TIME_free(at->value.utctime);
            #endif
                break;
            case V_ASN1_GENERALIZEDTIME:
            #ifndef NO_ASN_TIME
                wolfSSL_ASN1_TIME_free(at->value.generalizedtime);
            #endif
                break;
            case V_ASN1_UTF8STRING:
            case V_ASN1_PRINTABLESTRING:
            case V_ASN1_T61STRING:
            case V_ASN1_IA5STRING:
            case V_ASN1_UNIVERSALSTRING:
            case V_ASN1_SEQUENCE:
                wolfSSL_ASN1_STRING_free(at->value.asn1_string);
                break;
            default:
                WOLFSSL_MSG("Unknown or unsupported ASN1_TYPE");
                break;
        }
        XFREE(at, NULL, DYNAMIC_TYPE_OPENSSL);
    }
}
#endif /* OPENSSL_ALL || WOLFSSL_APACHE_HTTPD || WOLFSSL_HAPROXY || WOLFSSL_WPAS
        || OPENSSL_EXTRA */



#ifndef NO_WOLFSSL_STUB
/*** TBD ***/
WOLFSSL_EVP_PKEY *wolfSSL_get_privatekey(const WOLFSSL *ssl)
{
    (void)ssl;
    WOLFSSL_STUB("SSL_get_privatekey");
    return NULL;
}
#endif

/**
 * Get a textual representation of given WOLFSSL_ASN1_OBJECT then write it to
 * buf at most buf_len bytes.
 *
 * params
 * - buf: buffer where the textual representation is to be written to
 * - buf_len: buffer size in bytes
 * - a: WOLFSSL_ASN1_OBJECT
 *
 * return the string length written on success, WOLFSSL_FAILURE on failure.
 */
int wolfSSL_i2t_ASN1_OBJECT(char *buf, int buf_len, WOLFSSL_ASN1_OBJECT *a)
{
    WOLFSSL_ENTER("wolfSSL_i2t_ASN1_OBJECT");
    return wolfSSL_OBJ_obj2txt(buf, buf_len, a, 0);
}

WOLFSSL_ASN1_OBJECT *wolfSSL_d2i_ASN1_OBJECT(WOLFSSL_ASN1_OBJECT **a,
                                             const unsigned char **der,
                                             long length)
{
    const unsigned char *d;
    long len;
    int tag, cls;
    WOLFSSL_ASN1_OBJECT* ret = NULL;

    WOLFSSL_ENTER("wolfSSL_d2i_ASN1_OBJECT");

    if (!der || !*der || length <= 0) {
        WOLFSSL_MSG("Bad parameter");
        return NULL;
    }

    d = *der;

    if (wolfSSL_ASN1_get_object(&d, &len, &tag, &cls, length) & 0x80) {
        WOLFSSL_MSG("wolfSSL_ASN1_get_object error");
        return NULL;
    }
    /* d now points to value */

    if (tag != ASN_OBJECT_ID) {
        WOLFSSL_MSG("Not an ASN object");
        return NULL;
    }

    ret = wolfSSL_c2i_ASN1_OBJECT(a, &d, len);
    if (ret)
        *der = d;
    return ret;
}

/**
 * Parse an ASN1 encoded input and output information about the parsed object
 * @param in    ASN1 encoded data. *in is moved to the value of the ASN1 object
 * @param len   Length of parsed ASN1 object
 * @param tag   Tag value of parsed ASN1 object
 * @param cls   Class of parsed ASN1 object
 * @param inLen Length of *in buffer
 * @return int  Depends on which bits are set in the returned int:
 *              0x80 an error occurred during parsing
 *              0x20 parsed object is constructed
 *              0x01 the parsed object length is infinite
 */
int wolfSSL_ASN1_get_object(const unsigned char **in, long *len, int *tag,
                            int *cls, long inLen)
{
    word32 inOutIdx = 0;
    int l;
    byte t;
    int ret = 0x80;

    WOLFSSL_ENTER("wolfSSL_ASN1_get_object");

    if (!in || !*in || !len || !tag || !cls || inLen == 0) {
        WOLFSSL_MSG("Bad parameter");
        return ret;
    }

    if (GetASNTag(*in, &inOutIdx, &t, (word32)inLen) != 0) {
        WOLFSSL_MSG("GetASNTag error");
        return ret;
    }

    if (GetLength(*in, &inOutIdx, &l, (word32)inLen) < 0) {
        WOLFSSL_MSG("GetLength error");
        return ret;
    }

    *tag = t & 0x1F; /* Tag number is 5 lsb */
    *cls = t & 0xC0; /* Class is 2 msb */
    *len = l;
    ret = t & ASN_CONSTRUCTED;

    if (l > (int)(inLen - inOutIdx)) {
        /* Still return other values but indicate error in msb */
        ret |= 0x80;
    }

    *in += inOutIdx;
    return ret;
}

WOLFSSL_ASN1_OBJECT *wolfSSL_c2i_ASN1_OBJECT(WOLFSSL_ASN1_OBJECT **a,
        const unsigned char **pp, long len)
{
    WOLFSSL_ASN1_OBJECT* ret = NULL;

    WOLFSSL_ENTER("wolfSSL_c2i_ASN1_OBJECT");

    if (!pp || !*pp || len <= 0) {
        WOLFSSL_MSG("Bad parameter");
        return NULL;
    }

    if (!(ret = wolfSSL_ASN1_OBJECT_new())) {
        WOLFSSL_MSG("wolfSSL_ASN1_OBJECT_new error");
        return NULL;
    }

    ret->obj = (const unsigned char*)XMALLOC(len, NULL, DYNAMIC_TYPE_ASN1);
    if (!ret->obj) {
        WOLFSSL_MSG("error allocating asn data memory");
        wolfSSL_ASN1_OBJECT_free(ret);
        return NULL;
    }

    XMEMCPY((byte*)ret->obj, *pp, len);
    ret->objSz = (unsigned int)len;
    ret->dynamic |= WOLFSSL_ASN1_DYNAMIC_DATA;

    *pp += len;

    if (a)
        *a = ret;
    return ret;
}

#ifndef NO_BIO
/* Return number of bytes written to BIO on success. 0 on failure. */
int wolfSSL_i2a_ASN1_OBJECT(WOLFSSL_BIO *bp, WOLFSSL_ASN1_OBJECT *a)
{
    int length = 0;
    word32 idx = 0;
    const char null_str[] = "NULL";

    WOLFSSL_ENTER("wolfSSL_i2a_ASN1_OBJECT");

    if (bp == NULL)
        return WOLFSSL_FAILURE;

    if (a == NULL) {
        /* Write "NULL" */
        if (wolfSSL_BIO_write(bp, null_str, (int)XSTRLEN(null_str)) ==
                (int)XSTRLEN(null_str)) {
            return (int)XSTRLEN(null_str);
        }
        else {
            return WOLFSSL_FAILURE;
        }
    }


    if ((a->obj == NULL) || (a->obj[idx++] != ASN_OBJECT_ID)) {
        WOLFSSL_MSG("Bad ASN1 Object");
        return WOLFSSL_FAILURE;
    }

    if (GetLength((const byte*)a->obj, &idx, &length,
                   a->objSz) < 0 || length < 0) {
        return WOLFSSL_FAILURE;
    }

    if (wolfSSL_BIO_write(bp, a->obj + idx, length) == (int)length) {
        return length;
    }

    return WOLFSSL_FAILURE;
}
#endif /* !NO_BIO */

/* Returns object data for an ASN1_OBJECT */
/* If pp is NULL then only the size is returned */
/* If pp has pointer to pointer then its used directly */
/* If pp has pointer to pointer that is NULL then new variable is allocated */
/* Failure returns WOLFSSL_FAILURE (0) */
int wolfSSL_i2d_ASN1_OBJECT(WOLFSSL_ASN1_OBJECT *a, unsigned char **pp)
{
    byte *p;

    WOLFSSL_ENTER("wolfSSL_i2d_ASN1_OBJECT");

    if (!a || !a->obj) {
        WOLFSSL_MSG("Bad parameters");
        return WOLFSSL_FAILURE;
    }

    if (!pp)
        return a->objSz;

    if (*pp)
        p = *pp;
    else {
        p = (byte*)XMALLOC(a->objSz, NULL, DYNAMIC_TYPE_OPENSSL);
        if (!p) {
            WOLFSSL_MSG("Bad malloc");
            return WOLFSSL_FAILURE;
        }
    }

    XMEMCPY(p, a->obj, a->objSz);
    *pp = p + a->objSz;
    return a->objSz;
}

#ifndef NO_WOLFSSL_STUB
/*** TBD ***/
void SSL_CTX_set_tmp_dh_callback(WOLFSSL_CTX *ctx,
    WOLFSSL_DH *(*dh) (WOLFSSL *ssl, int is_export, int keylength))
{
    (void)ctx;
    (void)dh;
    WOLFSSL_STUB("SSL_CTX_set_tmp_dh_callback");
}
#endif

#ifndef NO_WOLFSSL_STUB
/*** TBD ***/
WOLF_STACK_OF(SSL_COMP) *SSL_COMP_get_compression_methods(void)
{
    WOLFSSL_STUB("SSL_COMP_get_compression_methods");
    return NULL;
}
#endif


int wolfSSL_sk_SSL_CIPHER_num(const WOLF_STACK_OF(WOLFSSL_CIPHER)* p)
{
    WOLFSSL_ENTER("wolfSSL_sk_SSL_CIPHER_num");
    if (p == NULL) {
        return WOLFSSL_FATAL_ERROR;
    }
    return (int)p->num;
}

WOLFSSL_CIPHER* wolfSSL_sk_SSL_CIPHER_value(WOLFSSL_STACK* sk, int i)
{
    WOLFSSL_ENTER("wolfSSL_sk_SSL_CIPHER_value");
    return (WOLFSSL_CIPHER*)wolfSSL_sk_value(sk, i);
}

#if !defined(NETOS)
void ERR_load_SSL_strings(void)
{

}
#endif

#ifdef HAVE_OCSP
long wolfSSL_get_tlsext_status_ocsp_resp(WOLFSSL *s, unsigned char **resp)
{
    if (s == NULL || resp == NULL)
        return 0;

    *resp = s->ocspResp;
    return s->ocspRespSz;
}

long wolfSSL_set_tlsext_status_ocsp_resp(WOLFSSL *s, unsigned char *resp,
    int len)
{
    if (s == NULL)
        return WOLFSSL_FAILURE;

    s->ocspResp   = resp;
    s->ocspRespSz = len;

    return WOLFSSL_SUCCESS;
}
#endif /* HAVE_OCSP */

#ifdef HAVE_MAX_FRAGMENT
#ifndef NO_WOLFSSL_CLIENT
/**
 * Set max fragment tls extension
 * @param c a pointer to WOLFSSL_CTX object
 * @param mode maximum fragment length mode
 * @return 1 on success, otherwise 0 or negative error code
 */
int wolfSSL_CTX_set_tlsext_max_fragment_length(WOLFSSL_CTX *c,
                                               unsigned char mode)
{
    if (c == NULL || (mode < WOLFSSL_MFL_2_9 || mode > WOLFSSL_MFL_2_12 ))
        return BAD_FUNC_ARG;

    return wolfSSL_CTX_UseMaxFragment(c, mode);
}
/**
 * Set max fragment tls extension
 * @param c a pointer to WOLFSSL object
 * @param mode maximum fragment length mode
 * @return 1 on success, otherwise 0 or negative error code
 */
int wolfSSL_set_tlsext_max_fragment_length(WOLFSSL *s, unsigned char mode)
{
    if (s == NULL || (mode < WOLFSSL_MFL_2_9 || mode > WOLFSSL_MFL_2_12 ))
        return BAD_FUNC_ARG;

    return wolfSSL_UseMaxFragment(s, mode);
}
#endif /* NO_WOLFSSL_CLIENT */
#endif /* HAVE_MAX_FRAGMENT */

#endif /* OPENSSL_EXTRA */

#ifdef WOLFSSL_HAVE_TLS_UNIQUE
size_t wolfSSL_get_finished(const WOLFSSL *ssl, void *buf, size_t count)
{
    byte len = 0;

    WOLFSSL_ENTER("SSL_get_finished");

    if (!ssl || !buf || count < TLS_FINISHED_SZ) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }

    if (ssl->options.side == WOLFSSL_SERVER_END) {
        len = ssl->serverFinished_len;
        XMEMCPY(buf, ssl->serverFinished, len);
    }
    else {
        len = ssl->clientFinished_len;
        XMEMCPY(buf, ssl->clientFinished, len);
    }
    return len;
}

size_t wolfSSL_get_peer_finished(const WOLFSSL *ssl, void *buf, size_t count)
{
    byte len = 0;
    WOLFSSL_ENTER("SSL_get_peer_finished");

    if (!ssl || !buf || count < TLS_FINISHED_SZ) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }

    if (ssl->options.side == WOLFSSL_CLIENT_END) {
        len = ssl->serverFinished_len;
        XMEMCPY(buf, ssl->serverFinished, len);
    }
    else {
        len = ssl->clientFinished_len;
        XMEMCPY(buf, ssl->clientFinished, len);
    }

    return len;
}
#endif /* WOLFSSL_HAVE_TLS_UNIQUE */

#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
long wolfSSL_get_verify_result(const WOLFSSL *ssl)
{
    if (ssl == NULL) {
        return WOLFSSL_FAILURE;
    }

    return ssl->peerVerifyRet;
}
#endif

#ifdef OPENSSL_EXTRA

#ifndef NO_WOLFSSL_STUB
/* shows the number of accepts attempted by CTX in it's lifetime */
long wolfSSL_CTX_sess_accept(WOLFSSL_CTX* ctx)
{
    WOLFSSL_STUB("wolfSSL_CTX_sess_accept");
    (void)ctx;
    return 0;
}
#endif

#ifndef NO_WOLFSSL_STUB
/* shows the number of connects attempted CTX in it's lifetime */
long wolfSSL_CTX_sess_connect(WOLFSSL_CTX* ctx)
{
    WOLFSSL_STUB("wolfSSL_CTX_sess_connect");
    (void)ctx;
    return 0;
}
#endif


#ifndef NO_WOLFSSL_STUB
/* shows the number of accepts completed by CTX in it's lifetime */
long wolfSSL_CTX_sess_accept_good(WOLFSSL_CTX* ctx)
{
    WOLFSSL_STUB("wolfSSL_CTX_sess_accept_good");
    (void)ctx;
    return 0;
}
#endif


#ifndef NO_WOLFSSL_STUB
/* shows the number of connects completed by CTX in it's lifetime */
long wolfSSL_CTX_sess_connect_good(WOLFSSL_CTX* ctx)
{
    WOLFSSL_STUB("wolfSSL_CTX_sess_connect_good");
    (void)ctx;
    return 0;
}
#endif


#ifndef NO_WOLFSSL_STUB
/* shows the number of renegotiation accepts attempted by CTX */
long wolfSSL_CTX_sess_accept_renegotiate(WOLFSSL_CTX* ctx)
{
    WOLFSSL_STUB("wolfSSL_CTX_sess_accept_renegotiate");
    (void)ctx;
    return 0;
}
#endif


#ifndef NO_WOLFSSL_STUB
/* shows the number of renegotiation accepts attempted by CTX */
long wolfSSL_CTX_sess_connect_renegotiate(WOLFSSL_CTX* ctx)
{
    WOLFSSL_STUB("wolfSSL_CTX_sess_connect_renegotiate");
    (void)ctx;
    return 0;
}
#endif


#ifndef NO_WOLFSSL_STUB
long wolfSSL_CTX_sess_hits(WOLFSSL_CTX* ctx)
{
    WOLFSSL_STUB("wolfSSL_CTX_sess_hits");
    (void)ctx;
    return 0;
}
#endif


#ifndef NO_WOLFSSL_STUB
long wolfSSL_CTX_sess_cb_hits(WOLFSSL_CTX* ctx)
{
    WOLFSSL_STUB("wolfSSL_CTX_sess_cb_hits");
    (void)ctx;
    return 0;
}
#endif


#ifndef NO_WOLFSSL_STUB
long wolfSSL_CTX_sess_cache_full(WOLFSSL_CTX* ctx)
{
    WOLFSSL_STUB("wolfSSL_CTX_sess_cache_full");
    (void)ctx;
    return 0;
}
#endif


#ifndef NO_WOLFSSL_STUB
long wolfSSL_CTX_sess_misses(WOLFSSL_CTX* ctx)
{
    WOLFSSL_STUB("wolfSSL_CTX_sess_misses");
    (void)ctx;
    return 0;
}
#endif


#ifndef NO_WOLFSSL_STUB
long wolfSSL_CTX_sess_timeouts(WOLFSSL_CTX* ctx)
{
    WOLFSSL_STUB("wolfSSL_CTX_sess_timeouts");
    (void)ctx;
    return 0;
}
#endif


/* Return the total number of sessions */
long wolfSSL_CTX_sess_number(WOLFSSL_CTX* ctx)
{
    word32 total = 0;

    WOLFSSL_ENTER("wolfSSL_CTX_sess_number");
    (void)ctx;

#if defined(WOLFSSL_SESSION_STATS) && !defined(NO_SESSION_CACHE)
    if (wolfSSL_get_session_stats(NULL, &total, NULL, NULL) != WOLFSSL_SUCCESS) {
        WOLFSSL_MSG("Error getting session stats");
    }
#else
    WOLFSSL_MSG("Please use macro WOLFSSL_SESSION_STATS for session stats");
#endif

    return (long)total;
}


#ifndef NO_CERTS
long wolfSSL_CTX_add_extra_chain_cert(WOLFSSL_CTX* ctx, WOLFSSL_X509* x509)
{
    byte* chain = NULL;
    long  chainSz = 0;
    int   derSz;
    const byte* der;
    int   ret;
    int   idx = 0;
    DerBuffer *derBuffer = NULL;

    WOLFSSL_ENTER("wolfSSL_CTX_add_extra_chain_cert");

    if (ctx == NULL || x509 == NULL) {
        WOLFSSL_MSG("Bad Argument");
        return WOLFSSL_FAILURE;
    }

    der = wolfSSL_X509_get_der(x509, &derSz);
    if (der == NULL || derSz <= 0) {
        WOLFSSL_MSG("Error getting X509 DER");
        return WOLFSSL_FAILURE;
    }

    if (ctx->certificate == NULL) {
        WOLFSSL_ENTER("wolfSSL_use_certificate_chain_buffer_format");

        /* Process buffer makes first certificate the leaf. */
        ret = ProcessBuffer(ctx, der, derSz, WOLFSSL_FILETYPE_ASN1, CERT_TYPE,
                            NULL, NULL, 1, GET_VERIFY_SETTING_CTX(ctx));
        if (ret != WOLFSSL_SUCCESS) {
            WOLFSSL_LEAVE("wolfSSL_CTX_add_extra_chain_cert", ret);
            return WOLFSSL_FAILURE;
        }
    }
    else {
        /* TODO: Do this elsewhere. */
        ret = AllocDer(&derBuffer, derSz, CERT_TYPE, ctx->heap);
        if (ret != 0) {
            WOLFSSL_MSG("Memory Error");
            return WOLFSSL_FAILURE;
        }
        XMEMCPY(derBuffer->buffer, der, derSz);
        ret = AddCA(ctx->cm, &derBuffer, WOLFSSL_USER_CA,
            GET_VERIFY_SETTING_CTX(ctx));
        if (ret != WOLFSSL_SUCCESS) {
            WOLFSSL_LEAVE("wolfSSL_CTX_add_extra_chain_cert", ret);
            return WOLFSSL_FAILURE;
        }

        /* adding cert to existing chain */
        if (ctx->certChain != NULL && ctx->certChain->length > 0) {
            chainSz += ctx->certChain->length;
        }
        chainSz += OPAQUE24_LEN + derSz;

        chain = (byte*)XMALLOC(chainSz, ctx->heap, DYNAMIC_TYPE_DER);
        if (chain == NULL) {
            WOLFSSL_MSG("Memory Error");
            return WOLFSSL_FAILURE;
        }

        if (ctx->certChain != NULL && ctx->certChain->length > 0) {
            XMEMCPY(chain, ctx->certChain->buffer, ctx->certChain->length);
            idx = ctx->certChain->length;
        }
        c32to24(derSz, chain + idx);
        idx += OPAQUE24_LEN;
        XMEMCPY(chain + idx, der, derSz);
        idx += derSz;
#ifdef WOLFSSL_TLS13
        ctx->certChainCnt++;
#endif

        FreeDer(&ctx->certChain);
        ret = AllocDer(&ctx->certChain, idx, CERT_TYPE, ctx->heap);
        if (ret == 0) {
            XMEMCPY(ctx->certChain->buffer, chain, idx);
        }
    }

    /* on success WOLFSSL_X509 memory is responsibility of ctx */
    wolfSSL_X509_free(x509);
    if (chain != NULL)
        XFREE(chain, ctx->heap, DYNAMIC_TYPE_DER);

    return WOLFSSL_SUCCESS;
}


long wolfSSL_CTX_set_tlsext_status_arg(WOLFSSL_CTX* ctx, void* arg)
{
    if (ctx == NULL || ctx->cm == NULL) {
        return WOLFSSL_FAILURE;
    }

    ctx->cm->ocspIOCtx = arg;
    return WOLFSSL_SUCCESS;
}

#endif /* !NO_CERTS */

int wolfSSL_get_read_ahead(const WOLFSSL* ssl)
{
    if (ssl == NULL) {
        return WOLFSSL_FAILURE;
    }

    return ssl->readAhead;
}


int wolfSSL_set_read_ahead(WOLFSSL* ssl, int v)
{
    if (ssl == NULL) {
        return WOLFSSL_FAILURE;
    }

    ssl->readAhead = (byte)v;

    return WOLFSSL_SUCCESS;
}


int wolfSSL_CTX_get_read_ahead(WOLFSSL_CTX* ctx)
{
    if (ctx == NULL) {
        return WOLFSSL_FAILURE;
    }

    return ctx->readAhead;
}


int wolfSSL_CTX_set_read_ahead(WOLFSSL_CTX* ctx, int v)
{
    if (ctx == NULL) {
        return WOLFSSL_FAILURE;
    }

    ctx->readAhead = (byte)v;

    return WOLFSSL_SUCCESS;
}


long wolfSSL_CTX_set_tlsext_opaque_prf_input_callback_arg(WOLFSSL_CTX* ctx,
        void* arg)
{
    if (ctx == NULL) {
        return WOLFSSL_FAILURE;
    }

    ctx->userPRFArg = arg;
    return WOLFSSL_SUCCESS;
}


#ifndef NO_DES3
/* 0 on success */
int wolfSSL_DES_set_key(WOLFSSL_const_DES_cblock* myDes,
                                               WOLFSSL_DES_key_schedule* key)
{
#ifdef WOLFSSL_CHECK_DESKEY
    return wolfSSL_DES_set_key_checked(myDes, key);
#else
    wolfSSL_DES_set_key_unchecked(myDes, key);
    return 0;
#endif
}



/* return true in fail case (1) */
static int DES_check(word32 mask, word32 mask2, unsigned char* key)
{
    word32 value[2];

    /* sanity check on length made in wolfSSL_DES_set_key_checked */
    value[0] = mask;
    value[1] = mask2;
    return (XMEMCMP(value, key, sizeof(value)) == 0)? 1: 0;
}


/* check that the key is odd parity and is not a weak key
 * returns -1 if parity is wrong, -2 if weak/null key and 0 on success */
int wolfSSL_DES_set_key_checked(WOLFSSL_const_DES_cblock* myDes,
                                               WOLFSSL_DES_key_schedule* key)
{
    if (myDes == NULL || key == NULL) {
        WOLFSSL_MSG("Bad argument passed to wolfSSL_DES_set_key_checked");
        return -2;
    }
    else {
        word32 sz = sizeof(WOLFSSL_DES_key_schedule);

        /* sanity check before call to DES_check */
        if (sz != (sizeof(word32) * 2)) {
            WOLFSSL_MSG("Unexpected WOLFSSL_DES_key_schedule size");
            return -2;
        }

        /* check odd parity */
        if (wolfSSL_DES_check_key_parity(myDes) != 1) {
            WOLFSSL_MSG("Odd parity test fail");
            return -1;
        }

        if (wolfSSL_DES_is_weak_key(myDes) == 1) {
            WOLFSSL_MSG("Weak key found");
            return -2;
        }

        /* passed tests, now copy over key */
        XMEMCPY(key, myDes, sizeof(WOLFSSL_const_DES_cblock));

        return 0;
    }
}


/* check is not weak. Weak key list from Nist "Recommendation for the Triple
 * Data Encryption Algorithm (TDEA) Block Cipher"
 *
 * returns 1 if is weak 0 if not
 */
int wolfSSL_DES_is_weak_key(WOLFSSL_const_DES_cblock* key)
{
    word32 mask, mask2;

    WOLFSSL_ENTER("wolfSSL_DES_is_weak_key");

    if (key == NULL) {
        WOLFSSL_MSG("NULL key passed in");
        return 1;
    }

    mask = 0x01010101; mask2 = 0x01010101;
    if (DES_check(mask, mask2, *key)) {
        WOLFSSL_MSG("Weak key found");
        return 1;
    }

    mask = 0xFEFEFEFE; mask2 = 0xFEFEFEFE;
    if (DES_check(mask, mask2, *key)) {
        WOLFSSL_MSG("Weak key found");
        return 1;
    }

    mask = 0xE0E0E0E0; mask2 = 0xF1F1F1F1;
    if (DES_check(mask, mask2, *key)) {
        WOLFSSL_MSG("Weak key found");
        return 1;
    }

    mask = 0x1F1F1F1F; mask2 = 0x0E0E0E0E;
    if (DES_check(mask, mask2, *key)) {
        WOLFSSL_MSG("Weak key found");
        return 1;
    }

    /* semi-weak *key check (list from same Nist paper) */
    mask  = 0x011F011F; mask2 = 0x010E010E;
    if (DES_check(mask, mask2, *key) ||
       DES_check(ByteReverseWord32(mask), ByteReverseWord32(mask2), *key)) {
        WOLFSSL_MSG("Weak key found");
        return 1;
    }

    mask  = 0x01E001E0; mask2 = 0x01F101F1;
    if (DES_check(mask, mask2, *key) ||
       DES_check(ByteReverseWord32(mask), ByteReverseWord32(mask2), *key)) {
        WOLFSSL_MSG("Weak key found");
        return 1;
    }

    mask  = 0x01FE01FE; mask2 = 0x01FE01FE;
    if (DES_check(mask, mask2, *key) ||
       DES_check(ByteReverseWord32(mask), ByteReverseWord32(mask2), *key)) {
        WOLFSSL_MSG("Weak key found");
        return 1;
    }

    mask  = 0x1FE01FE0; mask2 = 0x0EF10EF1;
    if (DES_check(mask, mask2, *key) ||
       DES_check(ByteReverseWord32(mask), ByteReverseWord32(mask2), *key)) {
        WOLFSSL_MSG("Weak key found");
        return 1;
    }

    mask  = 0x1FFE1FFE; mask2 = 0x0EFE0EFE;
    if (DES_check(mask, mask2, *key) ||
       DES_check(ByteReverseWord32(mask), ByteReverseWord32(mask2), *key)) {
        WOLFSSL_MSG("Weak key found");
        return 1;
    }

    return 0;
}


void wolfSSL_DES_set_key_unchecked(WOLFSSL_const_DES_cblock* myDes,
                                               WOLFSSL_DES_key_schedule* key)
{
    if (myDes != NULL && key != NULL) {
        XMEMCPY(key, myDes, sizeof(WOLFSSL_const_DES_cblock));
    }
}


/* Sets the parity of the DES key for use */
void wolfSSL_DES_set_odd_parity(WOLFSSL_DES_cblock* myDes)
{
    word32 i;
    word32 sz = sizeof(WOLFSSL_DES_cblock);

    WOLFSSL_ENTER("wolfSSL_DES_set_odd_parity");

    for (i = 0; i < sz; i++) {
        unsigned char c = (*myDes)[i];
        if ((
            ((c >> 1) & 0x01) ^
            ((c >> 2) & 0x01) ^
            ((c >> 3) & 0x01) ^
            ((c >> 4) & 0x01) ^
            ((c >> 5) & 0x01) ^
            ((c >> 6) & 0x01) ^
            ((c >> 7) & 0x01)) == (c & 0x01)) {
            WOLFSSL_MSG("Flipping parity bit");
            (*myDes)[i] = c ^ 0x01;
        }
    }
}

int wolfSSL_DES_check_key_parity(WOLFSSL_DES_cblock *myDes)
{
    word32 i;
    word32 sz = sizeof(WOLFSSL_DES_cblock);

    WOLFSSL_ENTER("wolfSSL_DES_check_key_parity");

    for (i = 0; i < sz; i++) {
        unsigned char c = (*myDes)[i];
        if ((
            ((c >> 1) & 0x01) ^
            ((c >> 2) & 0x01) ^
            ((c >> 3) & 0x01) ^
            ((c >> 4) & 0x01) ^
            ((c >> 5) & 0x01) ^
            ((c >> 6) & 0x01) ^
            ((c >> 7) & 0x01)) == (c & 0x01)) {
            return 0;
        }
    }
    return 1;
}

#ifdef WOLFSSL_DES_ECB
/* Encrypt or decrypt input message desa with key and get output in desb.
 * if enc is DES_ENCRYPT,input message is encrypted or
 * if enc is DES_DECRYPT,input message is decrypted.
 * */
void wolfSSL_DES_ecb_encrypt(WOLFSSL_DES_cblock* desa,
             WOLFSSL_DES_cblock* desb, WOLFSSL_DES_key_schedule* key, int enc)
{
    Des myDes;

    WOLFSSL_ENTER("wolfSSL_DES_ecb_encrypt");

    if (desa == NULL || key == NULL || desb == NULL ||
        (enc != DES_ENCRYPT && enc != DES_DECRYPT)) {
        WOLFSSL_MSG("Bad argument passed to wolfSSL_DES_ecb_encrypt");
    } else {
        if (wc_Des_SetKey(&myDes, (const byte*) key,
                           (const byte*) NULL, !enc) != 0) {
            WOLFSSL_MSG("wc_Des_SetKey return error.");
            return;
        }
        if (enc == DES_ENCRYPT){
            if (wc_Des_EcbEncrypt(&myDes, (byte*) desb, (const byte*) desa,
                        sizeof(WOLFSSL_DES_cblock)) != 0){
                WOLFSSL_MSG("wc_Des_EcbEncrypt return error.");
            }
        } else {
            if (wc_Des_EcbDecrypt(&myDes, (byte*) desb, (const byte*) desa,
                        sizeof(WOLFSSL_DES_cblock)) != 0){
                WOLFSSL_MSG("wc_Des_EcbDecrpyt return error.");
            }
        }
    }
}
#endif
#endif /* NO_DES3 */

#ifndef NO_RC4
/* Set the key state for Arc4 structure.
 *
 * key  Arc4 structure to use
 * len  length of data buffer
 * data initial state to set Arc4 structure
 */
void wolfSSL_RC4_set_key(WOLFSSL_RC4_KEY* key, int len,
        const unsigned char* data)
{
    typedef char rc4_test[sizeof(WOLFSSL_RC4_KEY) >= sizeof(Arc4) ? 1 : -1];
    (void)sizeof(rc4_test);

    WOLFSSL_ENTER("wolfSSL_RC4_set_key");

    if (key == NULL || len < 0) {
        WOLFSSL_MSG("bad argument passed in");
        return;
    }

    XMEMSET(key, 0, sizeof(WOLFSSL_RC4_KEY));
    wc_Arc4SetKey((Arc4*)key, data, (word32)len);
}


/* Encrypt/decrypt with Arc4 structure.
 *
 * len length of buffer to encrypt/decrypt (in/out)
 * in  buffer to encrypt/decrypt
 * out results of encryption/decryption
 */
void wolfSSL_RC4(WOLFSSL_RC4_KEY* key, size_t len,
        const unsigned char* in, unsigned char* out)
{
    WOLFSSL_ENTER("wolfSSL_RC4");

    if (key == NULL || in == NULL || out == NULL) {
        WOLFSSL_MSG("Bad argument passed in");
        return;
    }

    wc_Arc4Process((Arc4*)key, out, in, (word32)len);
}
#endif /* NO_RC4 */

#ifndef NO_AES

#ifdef WOLFSSL_AES_DIRECT
/* AES encrypt direct, it is expected to be blocks of AES_BLOCK_SIZE for input.
 *
 * input  Data to encrypt
 * output Encrypted data after done
 * key    AES key to use for encryption
 */
void wolfSSL_AES_encrypt(const unsigned char* input, unsigned char* output,
        AES_KEY *key)
{
    WOLFSSL_ENTER("wolfSSL_AES_encrypt");

    if (input == NULL || output == NULL || key == NULL) {
        WOLFSSL_MSG("Null argument passed in");
        return;
    }

#if !defined(HAVE_SELFTEST) && \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
    if (wc_AesEncryptDirect((Aes*)key, output, input) != 0) {
        WOLFSSL_MSG("wc_AesEncryptDirect failed");
        return;
    }
#else
    wc_AesEncryptDirect((Aes*)key, output, input);
#endif
}


/* AES decrypt direct, it is expected to be blocks of AES_BLOCK_SIZE for input.
 *
 * input  Data to decrypt
 * output Decrypted data after done
 * key    AES key to use for encryption
 */
void wolfSSL_AES_decrypt(const unsigned char* input, unsigned char* output,
        AES_KEY *key)
{
    WOLFSSL_ENTER("wolfSSL_AES_decrypt");

    if (input == NULL || output == NULL || key == NULL) {
        WOLFSSL_MSG("Null argument passed in");
        return;
    }

#if !defined(HAVE_SELFTEST) && \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
    if (wc_AesDecryptDirect((Aes*)key, output, input) != 0) {
        WOLFSSL_MSG("wc_AesDecryptDirect failed");
        return;
    }
#else
    wc_AesDecryptDirect((Aes*)key, output, input);
#endif
}
#endif /* WOLFSSL_AES_DIRECT */

/* Setup of an AES key to use for encryption.
 *
 * key  key in bytes to use for encryption
 * bits size of key in bits
 * aes  AES structure to initialize
 */
int wolfSSL_AES_set_encrypt_key(const unsigned char *key, const int bits,
        AES_KEY *aes)
{
    typedef char aes_test[sizeof(AES_KEY) >= sizeof(Aes) ? 1 : -1];
    (void)sizeof(aes_test);

    WOLFSSL_ENTER("wolfSSL_AES_set_encrypt_key");

    if (key == NULL || aes == NULL) {
        WOLFSSL_MSG("Null argument passed in");
        return -1;
    }

    XMEMSET(aes, 0, sizeof(AES_KEY));
    if (wc_AesSetKey((Aes*)aes, key, ((bits)/8), NULL, AES_ENCRYPT) != 0) {
        WOLFSSL_MSG("Error in setting AES key");
        return -1;
    }
    return 0;
}


/* Setup of an AES key to use for decryption.
 *
 * key  key in bytes to use for decryption
 * bits size of key in bits
 * aes  AES structure to initialize
 */
int wolfSSL_AES_set_decrypt_key(const unsigned char *key, const int bits,
        AES_KEY *aes)
{
    typedef char aes_test[sizeof(AES_KEY) >= sizeof(Aes) ? 1 : -1];
    (void)sizeof(aes_test);

    WOLFSSL_ENTER("wolfSSL_AES_set_decrypt_key");

    if (key == NULL || aes == NULL) {
        WOLFSSL_MSG("Null argument passed in");
        return -1;
    }

    XMEMSET(aes, 0, sizeof(AES_KEY));
    if (wc_AesSetKey((Aes*)aes, key, ((bits)/8), NULL, AES_DECRYPT) != 0) {
        WOLFSSL_MSG("Error in setting AES key");
        return -1;
    }
    return 0;
}


#ifdef HAVE_AES_ECB
/* Encrypt/decrypt a 16 byte block of data using the key passed in.
 *
 * in  buffer to encrypt/decrypt
 * out buffer to hold result of encryption/decryption
 * key AES structure to use with encryption/decryption
 * enc AES_ENCRPT for encryption and AES_DECRYPT for decryption
 */
void wolfSSL_AES_ecb_encrypt(const unsigned char *in, unsigned char* out,
                             AES_KEY *key, const int enc)
{
    Aes* aes;

    WOLFSSL_ENTER("wolfSSL_AES_ecb_encrypt");

    if (key == NULL || in == NULL || out == NULL) {
        WOLFSSL_MSG("Error, Null argument passed in");
        return;
    }

    aes = (Aes*)key;
    if (enc == AES_ENCRYPT) {
        if (wc_AesEcbEncrypt(aes, out, in, AES_BLOCK_SIZE) != 0) {
            WOLFSSL_MSG("Error with AES CBC encrypt");
        }
    }
    else {
    #ifdef HAVE_AES_DECRYPT
        if (wc_AesEcbDecrypt(aes, out, in, AES_BLOCK_SIZE) != 0) {
            WOLFSSL_MSG("Error with AES CBC decrypt");
        }
    #else
        WOLFSSL_MSG("AES decryption not compiled in");
    #endif
    }
}
#endif /* HAVE_AES_ECB */

#ifdef HAVE_AES_CBC
/* Encrypt data using key and iv passed in. iv gets updated to most recent iv
 * state after encryption/decryption.
 *
 * in  buffer to encrypt/decrypt
 * out buffer to hold result of encryption/decryption
 * len length of input buffer
 * key AES structure to use with encryption/decryption
 * iv  iv to use with operation
 * enc 1 for encryption and 0 for decryption
 */
void wolfSSL_AES_cbc_encrypt(const unsigned char *in, unsigned char* out,
        size_t len, AES_KEY *key, unsigned char* iv, const int enc)
{
    Aes* aes;

    WOLFSSL_ENTER("wolfSSL_AES_cbc_encrypt");

    if (key == NULL || in == NULL || out == NULL || iv == NULL || len == 0) {
        WOLFSSL_MSG("Error, Null argument passed in");
        return;
    }

    aes = (Aes*)key;
    if (wc_AesSetIV(aes, (const byte*)iv) != 0) {
        WOLFSSL_MSG("Error with setting iv");
        return;
    }

    if (enc == AES_ENCRYPT) {
        if (wc_AesCbcEncrypt(aes, out, in, (word32)len) != 0) {
            WOLFSSL_MSG("Error with AES CBC encrypt");
            return;
        }
    }
    else {
        if (wc_AesCbcDecrypt(aes, out, in, (word32)len) != 0) {
            WOLFSSL_MSG("Error with AES CBC decrypt");
            return;
        }
    }

    /* to be compatible copy iv to iv buffer after completing operation */
    XMEMCPY(iv, (byte*)(aes->reg), AES_BLOCK_SIZE);
}
#endif /* HAVE_AES_CBC */


/* Encrypt data using CFB mode with key and iv passed in. iv gets updated to
 * most recent iv state after encryption/decryption.
 *
 * in  buffer to encrypt/decrypt
 * out buffer to hold result of encryption/decryption
 * len length of input buffer
 * key AES structure to use with encryption/decryption
 * iv  iv to use with operation
 * num contains the amount of block used
 * enc AES_ENCRYPT for encryption and AES_DECRYPT for decryption
 */
void wolfSSL_AES_cfb128_encrypt(const unsigned char *in, unsigned char* out,
        size_t len, AES_KEY *key, unsigned char* iv, int* num,
        const int enc)
{
#ifndef WOLFSSL_AES_CFB
    WOLFSSL_MSG("CFB mode not enabled please use macro WOLFSSL_AES_CFB");
    (void)in;
    (void)out;
    (void)len;
    (void)key;
    (void)iv;
    (void)num;
    (void)enc;

    return;
#else
    Aes* aes;

    WOLFSSL_ENTER("wolfSSL_AES_cbc_encrypt");
    if (key == NULL || in == NULL || out == NULL || iv == NULL) {
        WOLFSSL_MSG("Error, Null argument passed in");
        return;
    }

    aes = (Aes*)key;

    /*
     * We copy the IV directly into reg here because using wc_AesSetIV will
     * clear the leftover bytes field "left", and this function relies on the
     * leftover bytes being preserved between calls.
     */
    XMEMCPY(aes->reg, iv, AES_BLOCK_SIZE);

    if (enc == AES_ENCRYPT) {
        if (wc_AesCfbEncrypt(aes, out, in, (word32)len) != 0) {
            WOLFSSL_MSG("Error with AES CBC encrypt");
            return;
        }
    }
    else {
        if (wc_AesCfbDecrypt(aes, out, in, (word32)len) != 0) {
            WOLFSSL_MSG("Error with AES CBC decrypt");
            return;
        }
    }

    /* to be compatible copy iv to iv buffer after completing operation */
    XMEMCPY(iv, (byte*)(aes->reg), AES_BLOCK_SIZE);

    /* store number of left over bytes to num */
    *num = (aes->left)? AES_BLOCK_SIZE - aes->left : 0;
#endif /* WOLFSSL_AES_CFB */
}

/* wc_AesKey*Wrap_ex API not available in FIPS and SELFTEST */
#if defined(HAVE_AES_KEYWRAP) && !defined(HAVE_FIPS) && !defined(HAVE_SELFTEST)
int wolfSSL_AES_wrap_key(AES_KEY *key, const unsigned char *iv,
                 unsigned char *out,
                 const unsigned char *in, unsigned int inlen)
{
    int ret;

    WOLFSSL_ENTER("wolfSSL_AES_wrap_key");

    if (out == NULL || in == NULL) {
        WOLFSSL_MSG("Error, Null argument passed in");
        return WOLFSSL_FAILURE;
    }

    ret = wc_AesKeyWrap_ex((Aes*)key, in, inlen, out, inlen + KEYWRAP_BLOCK_SIZE, iv);

    return ret < 0 ? WOLFSSL_FAILURE : ret;
}

int wolfSSL_AES_unwrap_key(AES_KEY *key, const unsigned char *iv,
                   unsigned char *out,
                   const unsigned char *in, unsigned int inlen)
{
    int ret;

    WOLFSSL_ENTER("wolfSSL_AES_wrap_key");

    if (out == NULL || in == NULL) {
        WOLFSSL_MSG("Error, Null argument passed in");
        return WOLFSSL_FAILURE;
    }

    ret = wc_AesKeyUnWrap_ex((Aes*)key, in, inlen, out, inlen + KEYWRAP_BLOCK_SIZE, iv);

    return ret < 0 ? WOLFSSL_FAILURE : ret;
}
#endif /* HAVE_AES_KEYWRAP && !HAVE_FIPS && !HAVE_SELFTEST */

#ifdef HAVE_CTS
/*
 * Ciphertext stealing interface compatible with RFC2040 and RFC3962.
 */
size_t wolfSSL_CRYPTO_cts128_encrypt(const unsigned char *in,
        unsigned char *out, size_t len, const void *key,
        unsigned char *iv, WOLFSSL_CBC128_CB cbc)
{
    byte lastBlk[WOLFSSL_CTS128_BLOCK_SZ];
    int lastBlkLen = len % WOLFSSL_CTS128_BLOCK_SZ;
    WOLFSSL_ENTER("wolfSSL_CRYPTO_cts128_encrypt");

    if (in == NULL || out == NULL || len < WOLFSSL_CTS128_BLOCK_SZ ||
            cbc == NULL) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }

    if (lastBlkLen == 0)
        lastBlkLen = WOLFSSL_CTS128_BLOCK_SZ;

    /* Encrypt data up to last block */
    (*cbc)(in, out, len - lastBlkLen, key, iv, AES_ENCRYPT);

    /* Move to last block */
    in += len - lastBlkLen;
    out += len - lastBlkLen;

    /* RFC2040: Pad Pn with zeros at the end to create P of length BB. */
    XMEMCPY(lastBlk, in, lastBlkLen);
    XMEMSET(lastBlk + lastBlkLen, 0, WOLFSSL_CTS128_BLOCK_SZ - lastBlkLen);
    /* RFC2040: Select the first Ln bytes of En-1 to create Cn */
    XMEMCPY(out, out - WOLFSSL_CTS128_BLOCK_SZ, lastBlkLen);
    (*cbc)(lastBlk, out - WOLFSSL_CTS128_BLOCK_SZ, WOLFSSL_CTS128_BLOCK_SZ,
            key, iv, AES_ENCRYPT);

    return len;
}

size_t wolfSSL_CRYPTO_cts128_decrypt(const unsigned char *in,
        unsigned char *out, size_t len, const void *key,
        unsigned char *iv, WOLFSSL_CBC128_CB cbc)
{
    byte lastBlk[WOLFSSL_CTS128_BLOCK_SZ];
    byte prevBlk[WOLFSSL_CTS128_BLOCK_SZ];
    int lastBlkLen = len % WOLFSSL_CTS128_BLOCK_SZ;
    WOLFSSL_ENTER("wolfSSL_CRYPTO_cts128_decrypt");

    if (in == NULL || out == NULL || len <= WOLFSSL_CTS128_BLOCK_SZ ||
            cbc == NULL) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }

    if (lastBlkLen == 0)
        lastBlkLen = WOLFSSL_CTS128_BLOCK_SZ;

    /* Decrypt up to last two blocks */
    (*cbc)(in, out, len - lastBlkLen - WOLFSSL_CTS128_BLOCK_SZ, key, iv,
            AES_DECRYPTION);

    /* Move to last two blocks */
    in += len - lastBlkLen - WOLFSSL_CTS128_BLOCK_SZ;
    out += len - lastBlkLen - WOLFSSL_CTS128_BLOCK_SZ;

    /* RFC2040: Decrypt Cn-1 to create Dn.
     * Use 0 buffer as IV to do straight decryption.
     * This places the Cn-1 block at lastBlk */
    XMEMSET(lastBlk, 0, WOLFSSL_CTS128_BLOCK_SZ);
    (*cbc)(in, prevBlk, WOLFSSL_CTS128_BLOCK_SZ, key, lastBlk, AES_DECRYPT);
    /* RFC2040: Append the tail (BB minus Ln) bytes of Xn to Cn
     *          to create En. */
    XMEMCPY(prevBlk, in + WOLFSSL_CTS128_BLOCK_SZ, lastBlkLen);
    /* Cn and Cn-1 can now be decrypted */
    (*cbc)(prevBlk, out, WOLFSSL_CTS128_BLOCK_SZ, key, iv, AES_DECRYPT);
    (*cbc)(lastBlk, lastBlk, WOLFSSL_CTS128_BLOCK_SZ, key, iv, AES_DECRYPT);
    XMEMCPY(out + WOLFSSL_CTS128_BLOCK_SZ, lastBlk, lastBlkLen);
    return len;
}
#endif /* HAVE_CTS */
#endif /* NO_AES */

#ifndef NO_ASN_TIME
#ifndef NO_BIO
int wolfSSL_ASN1_UTCTIME_print(WOLFSSL_BIO* bio, const WOLFSSL_ASN1_UTCTIME* a)
{
    WOLFSSL_ENTER("ASN1_UTCTIME_print");
    if (bio == NULL || a == NULL) {
        return WOLFSSL_FAILURE;
    }
    if (a->type != ASN_UTC_TIME) {
        WOLFSSL_MSG("Error, not UTC_TIME");
        return WOLFSSL_FAILURE;
    }

    return wolfSSL_ASN1_TIME_print(bio, a);
}

#endif /* !NO_BIO */

/* Checks the ASN1 syntax of "a"
 * returns WOLFSSL_SUCCESS (1)  if correct otherwise WOLFSSL_FAILURE (0) */
int wolfSSL_ASN1_TIME_check(const WOLFSSL_ASN1_TIME* a)
{
    char buf[MAX_TIME_STRING_SZ];

    WOLFSSL_ENTER("wolfSSL_ASN1_TIME_check");

    /* if can parse the WOLFSSL_ASN1_TIME passed in then consider syntax good */
    if (wolfSSL_ASN1_TIME_to_string((WOLFSSL_ASN1_TIME*)a, buf,
                MAX_TIME_STRING_SZ) == NULL) {
        return WOLFSSL_FAILURE;
    }
    return WOLFSSL_SUCCESS;
}

/*
 * Convert time to Unix time (GMT).
 */
static long long TimeToUnixTime(int sec, int minute, int hour, int mday,
                                int mon, int year)
{
    /* Number of cumulative days from the previous months, starting from
     * beginning of January. */
    static const int monthDaysCumulative [12] = {
        0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334
    };
    int leapDays = year;

    if (mon <= 1) {
        --leapDays;
    }
    leapDays = leapDays / 4 - leapDays / 100 + leapDays / 400 - 1969 / 4 +
               1969 / 100 - 1969 / 400;

    return ((((long long) (year - 1970) * 365 + leapDays +
           monthDaysCumulative[mon] + mday - 1) * 24 + hour) * 60 + minute) *
           60 + sec;
}

int wolfSSL_ASN1_TIME_diff(int *days, int *secs, const WOLFSSL_ASN1_TIME *from,
    const WOLFSSL_ASN1_TIME *to)
{
    const int SECS_PER_DAY = 24 * 60 * 60;
    struct tm fromTm_s, *fromTmGmt = &fromTm_s;
    struct tm toTm_s, *toTmGmt = &toTm_s;
    time_t currTime;
    long long fromSecs;
    long long toSecs;
    double diffSecs;
    struct tm *tmpTs;
#if defined(NEED_TMP_TIME)
    /* for use with gmtime_r */
    struct tm tmpTimeStorage;
    tmpTs = &tmpTimeStorage;
#else
    tmpTs = NULL;
#endif
    (void)tmpTs;

    WOLFSSL_ENTER("wolfSSL_ASN1_TIME_diff");

    if (days == NULL) {
        WOLFSSL_MSG("days is NULL");
        return WOLFSSL_FAILURE;
    }
    if (secs == NULL) {
        WOLFSSL_MSG("secs is NULL");
        return WOLFSSL_FAILURE;
    }

    if (from == NULL && to == NULL) {
        *days = 0;
        *secs = 0;
        return WOLFSSL_SUCCESS;
    }

    if (from == NULL) {
        currTime = wc_Time(0);
        fromTmGmt = XGMTIME(&currTime, tmpTs);
        if (fromTmGmt == NULL) {
            WOLFSSL_MSG("XGMTIME for from time failed.");
            return WOLFSSL_FAILURE;
        }
    }
    else if (wolfSSL_ASN1_TIME_to_tm(from, fromTmGmt) != WOLFSSL_SUCCESS) {
        WOLFSSL_MSG("Failed to convert from time to struct tm.");
        return WOLFSSL_FAILURE;
    }

    /* We use TimeToUnixTime here instead of XMKTIME to avoid the Year 2038
     * Problem on platforms where time_t is 32 bits. struct tm stores the year
     * as years since 1900, so we add 1900 to the year. */
    fromSecs = TimeToUnixTime(fromTmGmt->tm_sec, fromTmGmt->tm_min,
                          fromTmGmt->tm_hour, fromTmGmt->tm_mday,
                          fromTmGmt->tm_mon, fromTmGmt->tm_year + 1900);

    if (to == NULL) {
        currTime = wc_Time(0);
        toTmGmt = XGMTIME(&currTime, tmpTs);
        if (toTmGmt == NULL) {
            WOLFSSL_MSG("XGMTIME for to time failed.");
            return WOLFSSL_FAILURE;
        }
    }
    else if (wolfSSL_ASN1_TIME_to_tm(to, toTmGmt) != WOLFSSL_SUCCESS) {
        WOLFSSL_MSG("Failed to convert to time to struct tm.");
        return WOLFSSL_FAILURE;
    }

    toSecs = TimeToUnixTime(toTmGmt->tm_sec, toTmGmt->tm_min, toTmGmt->tm_hour,
                        toTmGmt->tm_mday, toTmGmt->tm_mon,
                        toTmGmt->tm_year + 1900);

    diffSecs = (double)(toSecs - fromSecs);
    *days = (int) (diffSecs / SECS_PER_DAY);
    *secs = (int) (diffSecs - (((double)*days) * SECS_PER_DAY));

    return WOLFSSL_SUCCESS;
}

int wolfSSL_ASN1_TIME_compare(const WOLFSSL_ASN1_TIME *a,
                              const WOLFSSL_ASN1_TIME *b)
{
    int ret;
    int days;
    int secs;

    WOLFSSL_ENTER("wolfSSL_ASN1_TIME_compare");

    if (wolfSSL_ASN1_TIME_diff(&days, &secs, a, b) != WOLFSSL_SUCCESS) {
        WOLFSSL_MSG("Failed to get time difference.");
        ret = -2;
    }
    else {
        if (days == 0 && secs == 0) {
            /* a and b are the same time. */
            ret = 0;
        }
        else if (days >= 0 && secs >= 0) {
            /* a is before b. */
            ret = -1;
        }
        else if (days <= 0 && secs <= 0) {
            /* a is after b. */
            ret = 1;
        }
        else {
            WOLFSSL_MSG("Incoherent time difference.");
            ret = -2;
        }
    }

    WOLFSSL_LEAVE("wolfSSL_ASN1_TIME_compare", ret);

    return ret;
}
#endif /* !NO_ASN_TIME */

#ifndef NO_WOLFSSL_STUB
WOLFSSL_ASN1_TIME *wolfSSL_ASN1_TIME_set(WOLFSSL_ASN1_TIME *s, time_t t)
{
    WOLFSSL_STUB("wolfSSL_ASN1_TIME_set");
    (void)s;
    (void)t;
    return s;
}
#endif /* !NO_WOLFSSL_STUB */

int wolfSSL_ASN1_TIME_set_string(WOLFSSL_ASN1_TIME *s, const char *str)
{
    int slen;
    WOLFSSL_ENTER("wolfSSL_ASN1_TIME_set_string");

    if (!str) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }
    slen = (int)XSTRLEN(str)+1;
    if (slen > CTC_DATE_SIZE) {
        WOLFSSL_MSG("Date string too long");
        return WOLFSSL_FAILURE;
    }
    if (s) {
        XMEMCPY(s->data, str, slen);
        s->length = slen - 1; /* do not include null terminator in length */
        s->type = slen == ASN_UTC_TIME_SIZE ? V_ASN1_UTCTIME :
            V_ASN1_GENERALIZEDTIME;
    }
    return WOLFSSL_SUCCESS;
}

#ifndef NO_BIO

/* Return the month as a string.
 *
 * n  The number of the month as a two characters (1 based).
 * returns the month as a string.
 */
static WC_INLINE const char* MonthStr(const char* n)
{
    static const char monthStr[12][4] = {
            "Jan", "Feb", "Mar", "Apr", "May", "Jun",
            "Jul", "Aug", "Sep", "Oct", "Nov", "Dec" };
    return monthStr[(n[0] - '0') * 10 + (n[1] - '0') - 1];
}

int wolfSSL_ASN1_GENERALIZEDTIME_print(WOLFSSL_BIO* bio,
    const WOLFSSL_ASN1_GENERALIZEDTIME* asnTime)
{
    const char* p;
    WOLFSSL_ENTER("wolfSSL_ASN1_GENERALIZEDTIME_print");

    if (bio == NULL || asnTime == NULL)
        return BAD_FUNC_ARG;

    if (asnTime->type != ASN_GENERALIZED_TIME) {
        WOLFSSL_MSG("Error, not GENERALIZED_TIME");
        return WOLFSSL_FAILURE;
    }
    p = (const char *)(asnTime->data);
    /* GetTimeString not always available. */
    if (wolfSSL_BIO_write(bio, MonthStr(p + 4), 3) <= 0)
        return WOLFSSL_FAILURE;
    if (wolfSSL_BIO_write(bio, " ", 1) <= 0)
        return WOLFSSL_FAILURE;

    /* Day */
    if (wolfSSL_BIO_write(bio, p + 6, 2) <= 0)
        return WOLFSSL_FAILURE;
    if (wolfSSL_BIO_write(bio, " ", 1) <= 0)
        return WOLFSSL_FAILURE;

    /* Hour */
    if (wolfSSL_BIO_write(bio, p + 8, 2) <= 0)
        return WOLFSSL_FAILURE;
    if (wolfSSL_BIO_write(bio, ":", 1) <= 0)
        return WOLFSSL_FAILURE;

    /* Min */
    if (wolfSSL_BIO_write(bio, p + 10, 2) <= 0)
        return WOLFSSL_FAILURE;
    if (wolfSSL_BIO_write(bio, ":", 1) <= 0)
        return WOLFSSL_FAILURE;

    /* Secs */
    if (wolfSSL_BIO_write(bio, p + 12, 2) <= 0)
        return WOLFSSL_FAILURE;
    if (wolfSSL_BIO_write(bio, " ", 1) <= 0)
        return WOLFSSL_FAILURE;
    if (wolfSSL_BIO_write(bio, p, 4) <= 0)
        return WOLFSSL_FAILURE;

    return 0;
}
#endif /* !NO_BIO */

void wolfSSL_ASN1_GENERALIZEDTIME_free(WOLFSSL_ASN1_TIME* asn1Time)
{
    WOLFSSL_ENTER("wolfSSL_ASN1_GENERALIZEDTIME_free");
    if (asn1Time == NULL)
        return;
    XMEMSET(asn1Time->data, 0, sizeof(asn1Time->data));
}

#endif /* OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL)
int wolfSSL_sk_num(const WOLFSSL_STACK* sk)
{
    WOLFSSL_ENTER("wolfSSL_sk_num");
    if (sk == NULL)
        return 0;
    return (int)sk->num;
}

void* wolfSSL_sk_value(const WOLFSSL_STACK* sk, int i)
{
    WOLFSSL_ENTER("wolfSSL_sk_value");

    for (; sk != NULL && i > 0; i--)
        sk = sk->next;
    if (sk == NULL)
        return NULL;

    switch (sk->type) {
        case STACK_TYPE_X509:
            return (void*)sk->data.x509;
        case STACK_TYPE_GEN_NAME:
            return (void*)sk->data.gn;
        case STACK_TYPE_BIO:
            return (void*)sk->data.bio;
        case STACK_TYPE_OBJ:
            return (void*)sk->data.obj;
        case STACK_TYPE_STRING:
            return (void*)sk->data.string;
        case STACK_TYPE_CIPHER:
            return (void*)&sk->data.cipher;
        case STACK_TYPE_ACCESS_DESCRIPTION:
            return (void*)sk->data.access;
        case STACK_TYPE_X509_EXT:
            return (void*)sk->data.ext;
        case STACK_TYPE_X509_REQ_ATTR:
            return (void*)sk->data.generic;
        case STACK_TYPE_NULL:
            return (void*)sk->data.generic;
        case STACK_TYPE_X509_NAME:
            return (void*)sk->data.name;
        case STACK_TYPE_X509_NAME_ENTRY:
            return (void*)sk->data.name_entry;
        case STACK_TYPE_CONF_VALUE:
    #ifdef OPENSSL_EXTRA
            return (void*)sk->data.conf;
    #else
            return NULL;
    #endif
        case STACK_TYPE_X509_INFO:
            return (void*)sk->data.info;
        case STACK_TYPE_BY_DIR_entry:
            return (void*)sk->data.dir_entry;
        case STACK_TYPE_BY_DIR_hash:
            return (void*)sk->data.dir_hash;
        case STACK_TYPE_X509_OBJ:
            return (void*)sk->data.x509_obj;
        case STACK_TYPE_DIST_POINT:
            return (void*)sk->data.dp;
        case STACK_TYPE_X509_CRL:
            return (void*)sk->data.crl;
        default:
            return (void*)sk->data.generic;
    }
}

/* copies over data of "in" to "out" */
static void wolfSSL_CIPHER_copy(WOLFSSL_CIPHER* in, WOLFSSL_CIPHER* out)
{
    if (in == NULL || out == NULL)
        return;

    *out = *in;
}

WOLFSSL_STACK* wolfSSL_sk_dup(WOLFSSL_STACK* sk)
{

    WOLFSSL_STACK* ret = NULL;
    WOLFSSL_STACK* last = NULL;

    WOLFSSL_ENTER("wolfSSL_sk_dup");

    while (sk) {
        WOLFSSL_STACK* cur = wolfSSL_sk_new_node(sk->heap);

        if (!cur) {
            WOLFSSL_MSG("wolfSSL_sk_new_node error");
            goto error;
        }

        if (!ret) {
            /* Set first node */
            ret = cur;
        }

        if (last) {
            last->next = cur;
        }

        XMEMCPY(cur, sk, sizeof(WOLFSSL_STACK));

        /* We will allocate new memory for this */
        XMEMSET(&cur->data, 0, sizeof(cur->data));
        cur->next = NULL;

        switch (sk->type) {
            case STACK_TYPE_X509:
                if (!sk->data.x509)
                    break;
                cur->data.x509 = wolfSSL_X509_dup(sk->data.x509);
                if (!cur->data.x509) {
                    WOLFSSL_MSG("wolfSSL_X509_dup error");
                    goto error;
                }
                break;
            case STACK_TYPE_CIPHER:
                wolfSSL_CIPHER_copy(&sk->data.cipher, &cur->data.cipher);
                break;
            case STACK_TYPE_GEN_NAME:
                if (!sk->data.gn)
                    break;
                cur->data.gn = wolfSSL_GENERAL_NAME_dup(sk->data.gn);
                if (!cur->data.gn) {
                    WOLFSSL_MSG("wolfSSL_GENERAL_NAME_new error");
                    goto error;
                }
                break;
            case STACK_TYPE_OBJ:
                if (!sk->data.obj)
                    break;
                cur->data.obj = wolfSSL_ASN1_OBJECT_dup(sk->data.obj);
                if (!cur->data.obj) {
                    WOLFSSL_MSG("wolfSSL_ASN1_OBJECT_dup error");
                    goto error;
                }
                break;
            case STACK_TYPE_BIO:
            case STACK_TYPE_STRING:
            case STACK_TYPE_ACCESS_DESCRIPTION:
            case STACK_TYPE_X509_EXT:
            case STACK_TYPE_X509_REQ_ATTR:
            case STACK_TYPE_NULL:
            case STACK_TYPE_X509_NAME:
            case STACK_TYPE_X509_NAME_ENTRY:
            case STACK_TYPE_CONF_VALUE:
            case STACK_TYPE_X509_INFO:
            case STACK_TYPE_BY_DIR_entry:
            case STACK_TYPE_BY_DIR_hash:
            case STACK_TYPE_X509_OBJ:
            case STACK_TYPE_DIST_POINT:
            case STACK_TYPE_X509_CRL:
            default:
                WOLFSSL_MSG("Unsupported stack type");
                goto error;
        }

        sk = sk->next;
        last = cur;
    }
    return ret;

error:
    if (ret) {
        wolfSSL_sk_GENERAL_NAME_free(ret);
    }
    return NULL;
}

/* Free the just the stack structure */
void wolfSSL_sk_free(WOLFSSL_STACK* sk)
{
    WOLFSSL_ENTER("wolfSSL_sk_free");

    while (sk != NULL) {
        WOLFSSL_STACK* next = sk->next;
        XFREE(sk, NULL, DYNAMIC_TYPE_OPENSSL);
        sk = next;
    }
}

/* Frees each node in the stack and frees the stack.
 */
void wolfSSL_sk_GENERIC_pop_free(WOLFSSL_STACK* sk,
    void (*f) (void*))
{
    WOLFSSL_ENTER("wolfSSL_sk_GENERIC_pop_free");
    wolfSSL_sk_pop_free(sk, (wolfSSL_sk_freefunc)f);
}

/* return 1 on success 0 on fail */
int wolfSSL_sk_GENERIC_push(WOLFSSL_STACK* sk, void* generic)
{
    WOLFSSL_ENTER("wolfSSL_sk_GENERIC_push");

    return wolfSSL_sk_push(sk, generic);
}
void wolfSSL_sk_GENERIC_free(WOLFSSL_STACK* sk)
{
    wolfSSL_sk_free(sk);
}

/* Free all nodes in a stack including the pushed objects */
void wolfSSL_sk_pop_free(WOLF_STACK_OF(WOLFSSL_ASN1_OBJECT)* sk,
                                                       wolfSSL_sk_freefunc func)
{
    WOLFSSL_ENTER("wolfSSL_sk_pop_free");

    if (sk == NULL) {
        /* pop_free can be called with NULL, do not print bad argument */
        return;
    }
    #if defined(WOLFSSL_QT)
    /* In Qt v15.5, it calls OPENSSL_sk_free(xxx, OPENSSL_sk_free).
    *  By using OPENSSL_sk_free for free causes access violation.
    *  Therefore, switching free func to wolfSSL_ACCESS_DESCRIPTION_free
    *  is needed even the func isn't NULL.
    */
    if (sk->type == STACK_TYPE_ACCESS_DESCRIPTION) {
        func = (wolfSSL_sk_freefunc)wolfSSL_ACCESS_DESCRIPTION_free;
    }
    #endif
    if (func == NULL) {
        switch(sk->type) {
            case STACK_TYPE_ACCESS_DESCRIPTION:
            #if defined(OPENSSL_ALL)
                func = (wolfSSL_sk_freefunc)wolfSSL_ACCESS_DESCRIPTION_free;
            #endif
                break;
            case STACK_TYPE_X509:
                func = (wolfSSL_sk_freefunc)wolfSSL_X509_free;
                break;
            case STACK_TYPE_X509_OBJ:
            #ifdef OPENSSL_ALL
                func = (wolfSSL_sk_freefunc)wolfSSL_X509_OBJECT_free;
            #endif
                break;
            case STACK_TYPE_OBJ:
                func = (wolfSSL_sk_freefunc)wolfSSL_ASN1_OBJECT_free;
                break;
            case STACK_TYPE_DIST_POINT:
            #ifdef OPENSSL_EXTRA
                func = (wolfSSL_sk_freefunc)wolfSSL_DIST_POINT_free;
            #endif
                break;
            case STACK_TYPE_GEN_NAME:
                func = (wolfSSL_sk_freefunc)wolfSSL_GENERAL_NAME_free;
                break;
            case STACK_TYPE_STRING:
            #if defined(WOLFSSL_NGINX) || defined(WOLFSSL_HAPROXY) || \
                defined(OPENSSL_EXTRA) || defined(OPENSSL_ALL)
                func = (wolfSSL_sk_freefunc)wolfSSL_WOLFSSL_STRING_free;
            #endif
                break;
            case STACK_TYPE_X509_NAME:
            #if (defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)) \
                && !defined(WOLFCRYPT_ONLY)
                func = (wolfSSL_sk_freefunc)wolfSSL_X509_NAME_free;
            #endif
                break;
            case STACK_TYPE_X509_NAME_ENTRY:
            #if (defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)) \
                && !defined(WOLFCRYPT_ONLY)
                func = (wolfSSL_sk_freefunc)wolfSSL_X509_NAME_ENTRY_free;
            #endif
                break;
            case STACK_TYPE_X509_EXT:
            #if defined(OPENSSL_ALL) || defined(OPENSSL_EXTRA)
                func = (wolfSSL_sk_freefunc)wolfSSL_X509_EXTENSION_free;
            #endif
                break;
            case STACK_TYPE_X509_REQ_ATTR:
            #if defined(OPENSSL_ALL) && \
                (defined(WOLFSSL_CERT_GEN) || defined(WOLFSSL_CERT_REQ))
                func = (wolfSSL_sk_freefunc)wolfSSL_X509_ATTRIBUTE_free;
            #endif
                break;
            case STACK_TYPE_CONF_VALUE:
            #if defined(OPENSSL_ALL)
                func = (wolfSSL_sk_freefunc)wolfSSL_X509V3_conf_free;
            #endif
                break;
            case STACK_TYPE_X509_INFO:
            #if defined(OPENSSL_ALL)
                func = (wolfSSL_sk_freefunc)wolfSSL_X509_INFO_free;
            #endif
                break;
            case STACK_TYPE_BIO:
#if !defined(NO_BIO) && defined(OPENSSL_EXTRA)
                func = (wolfSSL_sk_freefunc)wolfSSL_BIO_vfree;
#endif
                break;
            case STACK_TYPE_BY_DIR_entry:
#if defined(OPENSSL_ALL) && !defined(NO_FILESYSTEM) && !defined(NO_WOLFSSL_DIR)
                func = (wolfSSL_sk_freefunc)wolfSSL_BY_DIR_entry_free;
#endif
                break;
            case STACK_TYPE_BY_DIR_hash:
#if defined(OPENSSL_ALL) && !defined(NO_FILESYSTEM) && !defined(NO_WOLFSSL_DIR)
                func = (wolfSSL_sk_freefunc)wolfSSL_BY_DIR_HASH_free;
#endif
                break;
            case STACK_TYPE_X509_CRL:
#if defined(HAVE_CRL) && (defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL))
                func = (wolfSSL_sk_freefunc)wolfSSL_X509_CRL_free;
#endif
                break;
            case STACK_TYPE_CIPHER:
            case STACK_TYPE_NULL:
            default:
                break;
        }
    }

    while (sk != NULL) {
        WOLFSSL_STACK* next = sk->next;

        if (func != NULL) {
            if (sk->type != STACK_TYPE_CIPHER)
                func(sk->data.generic);
        }
        XFREE(sk, NULL, DYNAMIC_TYPE_OPENSSL);
        sk = next;
    }
}

/* Creates and returns a new null stack. */
WOLFSSL_STACK* wolfSSL_sk_new_null(void)
{
    WOLFSSL_STACK* sk;
    WOLFSSL_ENTER("wolfSSL_sk_new_null");

    sk = (WOLFSSL_STACK*)XMALLOC(sizeof(WOLFSSL_STACK), NULL,
                                 DYNAMIC_TYPE_OPENSSL);
    if (sk == NULL) {
        WOLFSSL_MSG("WOLFSSL_STACK memory error");
        return NULL;
    }

    XMEMSET(sk, 0, sizeof(WOLFSSL_STACK));
    sk->type = STACK_TYPE_NULL;

    return sk;
}

int wolfSSL_sk_SSL_COMP_num(WOLF_STACK_OF(WOLFSSL_COMP)* sk)
{
    if (sk == NULL)
        return 0;
    return (int)sk->num;
}

#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL */

#if !defined(NO_SESSION_CACHE) && (defined(OPENSSL_EXTRA) || \
        defined(HAVE_EXT_CACHE))
/* stunnel 4.28 needs
 *
 * Callback that is called if a session tries to resume but could not find
 * the session to resume it.
 */
void wolfSSL_CTX_sess_set_get_cb(WOLFSSL_CTX* ctx,
                    WOLFSSL_SESSION*(*f)(WOLFSSL*, const unsigned char*, int, int*))
{
    if (ctx == NULL)
        return;

#ifdef HAVE_EXT_CACHE
    ctx->get_sess_cb = f;
#else
    (void)f;
#endif
}

void wolfSSL_CTX_sess_set_new_cb(WOLFSSL_CTX* ctx,
                             int (*f)(WOLFSSL*, WOLFSSL_SESSION*))
{
    if (ctx == NULL)
        return;

#ifdef HAVE_EXT_CACHE
    ctx->new_sess_cb = f;
#else
    (void)f;
#endif
}

void wolfSSL_CTX_sess_set_remove_cb(WOLFSSL_CTX* ctx, void (*f)(WOLFSSL_CTX*,
                                                        WOLFSSL_SESSION*))
{
    if (ctx == NULL)
        return;

#if defined(HAVE_EXT_CACHE) || defined(HAVE_EX_DATA)
    ctx->rem_sess_cb = f;
#else
    (void)f;
#endif
}


/*
 *
 * Note: It is expected that the importing and exporting function have been
 *       built with the same settings. For example if session tickets was
 *       enabled with the wolfSSL library exporting a session then it is
 *       expected to be turned on with the wolfSSL library importing the session.
 */
int wolfSSL_i2d_SSL_SESSION(WOLFSSL_SESSION* sess, unsigned char** p)
{
    int size = 0;
#ifdef HAVE_EXT_CACHE
    int idx = 0;
#ifdef SESSION_CERTS
    int i;
#endif
    unsigned char *data;

    WOLFSSL_ENTER("wolfSSL_i2d_SSL_SESSION");

    sess = ClientSessionToSession(sess);
    if (sess == NULL) {
        return BAD_FUNC_ARG;
    }

    /* side | bornOn | timeout | sessionID len | sessionID | masterSecret |
     * haveEMS  */
    size += OPAQUE8_LEN + OPAQUE32_LEN + OPAQUE32_LEN + OPAQUE8_LEN +
            sess->sessionIDSz + SECRET_LEN + OPAQUE8_LEN;
    /* altSessionID */
    size += OPAQUE8_LEN + (sess->haveAltSessionID ? ID_LEN : 0);
#ifdef SESSION_CERTS
    /* Peer chain */
    size += OPAQUE8_LEN;
    for (i = 0; i < sess->chain.count; i++)
        size += OPAQUE16_LEN + sess->chain.certs[i].length;
#endif
#if defined(SESSION_CERTS) || (defined(WOLFSSL_TLS13) && \
                               defined(HAVE_SESSION_TICKET))
    /* Protocol version */
    size += OPAQUE16_LEN;
#endif
#if defined(SESSION_CERTS) || !defined(NO_RESUME_SUITE_CHECK) || \
                        (defined(WOLFSSL_TLS13) && defined(HAVE_SESSION_TICKET))
    /* cipher suite */
    size += OPAQUE16_LEN;
#endif
#ifndef NO_CLIENT_CACHE
    /* ServerID len | ServerID */
    size += OPAQUE16_LEN + sess->idLen;
#endif
#ifdef OPENSSL_EXTRA
    /* session context ID len | session context ID */
    size += OPAQUE8_LEN + sess->sessionCtxSz;
#endif
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
    /* peerVerifyRet */
    size += OPAQUE8_LEN;
#endif
#ifdef WOLFSSL_TLS13
    /* namedGroup */
    size += OPAQUE16_LEN;
#endif
#if defined(HAVE_SESSION_TICKET) || !defined(NO_PSK)
#ifdef WOLFSSL_TLS13
#ifdef WOLFSSL_32BIT_MILLI_TIME
    /* ticketSeen | ticketAdd */
    size += OPAQUE32_LEN + OPAQUE32_LEN;
#else
    /* ticketSeen Hi 32 bits | ticketSeen Lo 32 bits | ticketAdd */
    size += OPAQUE32_LEN + OPAQUE32_LEN + OPAQUE32_LEN;
#endif
    /* ticketNonce */
    size += OPAQUE8_LEN + sess->ticketNonce.len;
#endif
#ifdef WOLFSSL_EARLY_DATA
    size += OPAQUE32_LEN;
#endif
#endif
#ifdef HAVE_SESSION_TICKET
    /* ticket len | ticket */
    size += OPAQUE16_LEN + sess->ticketLen;
#endif

    if (p != NULL) {
        if (*p == NULL)
            *p = (unsigned char*)XMALLOC(size, NULL, DYNAMIC_TYPE_OPENSSL);
        if (*p == NULL)
            return 0;
        data = *p;

        data[idx++] = sess->side;
        c32toa(sess->bornOn, data + idx); idx += OPAQUE32_LEN;
        c32toa(sess->timeout, data + idx); idx += OPAQUE32_LEN;
        data[idx++] = sess->sessionIDSz;
        XMEMCPY(data + idx, sess->sessionID, sess->sessionIDSz);
        idx += sess->sessionIDSz;
        XMEMCPY(data + idx, sess->masterSecret, SECRET_LEN); idx += SECRET_LEN;
        data[idx++] = (byte)sess->haveEMS;
        data[idx++] = sess->haveAltSessionID ? ID_LEN : 0;
        if (sess->haveAltSessionID) {
            XMEMCPY(data + idx, sess->altSessionID, ID_LEN);
            idx += ID_LEN;
        }
#ifdef SESSION_CERTS
        data[idx++] = (byte)sess->chain.count;
        for (i = 0; i < sess->chain.count; i++) {
            c16toa((word16)sess->chain.certs[i].length, data + idx);
            idx += OPAQUE16_LEN;
            XMEMCPY(data + idx, sess->chain.certs[i].buffer,
                    sess->chain.certs[i].length);
            idx += sess->chain.certs[i].length;
        }
#endif
#if defined(SESSION_CERTS) || (defined(WOLFSSL_TLS13) && \
                               defined(HAVE_SESSION_TICKET))
        data[idx++] = sess->version.major;
        data[idx++] = sess->version.minor;
#endif
#if defined(SESSION_CERTS) || !defined(NO_RESUME_SUITE_CHECK) || \
                        (defined(WOLFSSL_TLS13) && defined(HAVE_SESSION_TICKET))
        data[idx++] = sess->cipherSuite0;
        data[idx++] = sess->cipherSuite;
#endif
#ifndef NO_CLIENT_CACHE
        c16toa(sess->idLen, data + idx); idx += OPAQUE16_LEN;
        XMEMCPY(data + idx, sess->serverID, sess->idLen);
        idx += sess->idLen;
#endif
#ifdef OPENSSL_EXTRA
        data[idx++] = sess->sessionCtxSz;
        XMEMCPY(data + idx, sess->sessionCtx, sess->sessionCtxSz);
        idx += sess->sessionCtxSz;
#endif
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
        data[idx++] = sess->peerVerifyRet;
#endif
#ifdef WOLFSSL_TLS13
        c16toa(sess->namedGroup, data + idx);
        idx += OPAQUE16_LEN;
#endif
#if defined(HAVE_SESSION_TICKET) || !defined(NO_PSK)
#ifdef WOLFSSL_TLS13
#ifdef WOLFSSL_32BIT_MILLI_TIME
        c32toa(sess->ticketSeen, data + idx);
        idx += OPAQUE32_LEN;
#else
        c32toa((word32)(sess->ticketSeen >> 32), data + idx);
        idx += OPAQUE32_LEN;
        c32toa((word32)sess->ticketSeen, data + idx);
        idx += OPAQUE32_LEN;
#endif
        c32toa(sess->ticketAdd, data + idx);
        idx += OPAQUE32_LEN;
        data[idx++] = sess->ticketNonce.len;
        XMEMCPY(data + idx, sess->ticketNonce.data, sess->ticketNonce.len);
        idx += sess->ticketNonce.len;
#endif
#ifdef WOLFSSL_EARLY_DATA
        c32toa(sess->maxEarlyDataSz, data + idx);
        idx += OPAQUE32_LEN;
#endif
#endif
#ifdef HAVE_SESSION_TICKET
        c16toa(sess->ticketLen, data + idx); idx += OPAQUE16_LEN;
        XMEMCPY(data + idx, sess->ticket, sess->ticketLen);
        idx += sess->ticketLen;
#endif
    }
#endif

    (void)sess;
    (void)p;
#ifdef HAVE_EXT_CACHE
    (void)idx;
#endif

    return size;
}


/* TODO: no function to free new session.
 *
 * Note: It is expected that the importing and exporting function have been
 *       built with the same settings. For example if session tickets was
 *       enabled with the wolfSSL library exporting a session then it is
 *       expected to be turned on with the wolfSSL library importing the session.
 */
WOLFSSL_SESSION* wolfSSL_d2i_SSL_SESSION(WOLFSSL_SESSION** sess,
                                const unsigned char** p, long i)
{
    WOLFSSL_SESSION* s = NULL;
    int ret = 0;
#if defined(HAVE_EXT_CACHE)
    int idx;
    byte* data;
#ifdef SESSION_CERTS
    int j;
    word16 length;
#endif
#endif /* HAVE_EXT_CACHE */

    (void)p;
    (void)i;
    (void)ret;
    (void)sess;

#ifdef HAVE_EXT_CACHE
    if (p == NULL || *p == NULL)
        return NULL;

    s = wolfSSL_SESSION_new();
    if (s == NULL)
        return NULL;

    idx = 0;
    data = (byte*)*p;

    /* side | bornOn | timeout | sessionID len */
    if (i < OPAQUE8_LEN + OPAQUE32_LEN + OPAQUE32_LEN + OPAQUE8_LEN) {
        ret = BUFFER_ERROR;
        goto end;
    }
    s->side = data[idx++];
    ato32(data + idx, &s->bornOn); idx += OPAQUE32_LEN;
    ato32(data + idx, &s->timeout); idx += OPAQUE32_LEN;
    s->sessionIDSz = data[idx++];

    /* sessionID | secret | haveEMS | haveAltSessionID */
    if (i - idx < s->sessionIDSz + SECRET_LEN + OPAQUE8_LEN + OPAQUE8_LEN) {
        ret = BUFFER_ERROR;
        goto end;
    }
    XMEMCPY(s->sessionID, data + idx, s->sessionIDSz);
    idx  += s->sessionIDSz;
    XMEMCPY(s->masterSecret, data + idx, SECRET_LEN); idx += SECRET_LEN;
    s->haveEMS = data[idx++];
    if (data[idx] != ID_LEN && data[idx] != 0) {
        ret = BUFFER_ERROR;
        goto end;
    }
    s->haveAltSessionID = data[idx++] == ID_LEN;

    /* altSessionID */
    if (s->haveAltSessionID) {
        if (i - idx < ID_LEN) {
            ret = BUFFER_ERROR;
            goto end;
        }
        XMEMCPY(s->altSessionID, data + idx, ID_LEN); idx += ID_LEN;
    }

#ifdef SESSION_CERTS
    /* Certificate chain */
    if (i - idx == 0) {
        ret = BUFFER_ERROR;
        goto end;
    }
    s->chain.count = data[idx++];
    for (j = 0; j < s->chain.count; j++) {
        if (i - idx < OPAQUE16_LEN) {
            ret = BUFFER_ERROR;
            goto end;
        }
        ato16(data + idx, &length); idx += OPAQUE16_LEN;
        s->chain.certs[j].length = length;
        if (i - idx < length) {
            ret = BUFFER_ERROR;
            goto end;
        }
        XMEMCPY(s->chain.certs[j].buffer, data + idx, length);
        idx += length;
    }
#endif
#if defined(SESSION_CERTS) || (defined(WOLFSSL_TLS13) && \
                               defined(HAVE_SESSION_TICKET))
    /* Protocol Version */
    if (i - idx < OPAQUE16_LEN) {
        ret = BUFFER_ERROR;
        goto end;
    }
    s->version.major = data[idx++];
    s->version.minor = data[idx++];
#endif
#if defined(SESSION_CERTS) || !defined(NO_RESUME_SUITE_CHECK) || \
                        (defined(WOLFSSL_TLS13) && defined(HAVE_SESSION_TICKET))
    /* Cipher suite */
    if (i - idx < OPAQUE16_LEN) {
        ret = BUFFER_ERROR;
        goto end;
    }
    s->cipherSuite0 = data[idx++];
    s->cipherSuite = data[idx++];
#endif
#ifndef NO_CLIENT_CACHE
    /* ServerID len */
    if (i - idx < OPAQUE16_LEN) {
        ret = BUFFER_ERROR;
        goto end;
    }
    ato16(data + idx, &s->idLen); idx += OPAQUE16_LEN;

    /* ServerID */
    if (i - idx < s->idLen) {
        ret = BUFFER_ERROR;
        goto end;
    }
    XMEMCPY(s->serverID, data + idx, s->idLen); idx += s->idLen;
#endif
#ifdef OPENSSL_EXTRA
    /* byte for length of session context ID */
    if (i - idx < OPAQUE8_LEN) {
        ret = BUFFER_ERROR;
        goto end;
    }
    s->sessionCtxSz = data[idx++];

    /* app session context ID */
    if (i - idx < s->sessionCtxSz) {
        ret = BUFFER_ERROR;
        goto end;
    }
    XMEMCPY(s->sessionCtx, data + idx, s->sessionCtxSz); idx += s->sessionCtxSz;
#endif
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
    /* byte for peerVerifyRet */
    if (i - idx < OPAQUE8_LEN) {
        ret = BUFFER_ERROR;
        goto end;
    }
    s->peerVerifyRet = data[idx++];
#endif
#ifdef WOLFSSL_TLS13
    if (i - idx < OPAQUE16_LEN) {
        ret = BUFFER_ERROR;
        goto end;
    }
    ato16(data + idx, &s->namedGroup);
    idx += OPAQUE16_LEN;
#endif
#if defined(HAVE_SESSION_TICKET) || !defined(NO_PSK)
#ifdef WOLFSSL_TLS13
    if (i - idx < (OPAQUE32_LEN * 2)) {
        ret = BUFFER_ERROR;
        goto end;
    }
#ifdef WOLFSSL_32BIT_MILLI_TIME
    ato32(data + idx, &s->ticketSeen);
    idx += OPAQUE32_LEN;
#else
    {
        word32 seenHi, seenLo;

        ato32(data + idx, &seenHi);
        idx += OPAQUE32_LEN;
        ato32(data + idx, &seenLo);
        idx += OPAQUE32_LEN;
        s->ticketSeen = ((sword64)seenHi << 32) + seenLo;
    }
#endif
    ato32(data + idx, &s->ticketAdd);
    idx += OPAQUE32_LEN;
    if (i - idx < OPAQUE8_LEN) {
        ret = BUFFER_ERROR;
        goto end;
    }
    s->ticketNonce.len = data[idx++];

    if (i - idx < s->ticketNonce.len) {
        ret = BUFFER_ERROR;
        goto end;
    }
#if defined(WOLFSSL_TICKET_NONCE_MALLOC) &&                     \
    (!defined(HAVE_FIPS) || (defined(FIPS_VERSION_GE) && FIPS_VERSION_GE(5,3)))
    ret = SessionTicketNoncePopulate(s, data + idx, s->ticketNonce.len);
    if (ret != 0)
        goto end;
#else
    if (s->ticketNonce.len > MAX_TICKET_NONCE_STATIC_SZ) {
        ret = BUFFER_ERROR;
        goto end;
    }
    XMEMCPY(s->ticketNonce.data, data + idx, s->ticketNonce.len);
#endif /* defined(WOLFSSL_TICKET_NONCE_MALLOC) && FIPS_VERSION_GE(5,3) */

    idx += s->ticketNonce.len;
#endif
#ifdef WOLFSSL_EARLY_DATA
    if (i - idx < OPAQUE32_LEN) {
        ret = BUFFER_ERROR;
        goto end;
    }
    ato32(data + idx, &s->maxEarlyDataSz);
    idx += OPAQUE32_LEN;
#endif
#endif
#ifdef HAVE_SESSION_TICKET
    /* ticket len */
    if (i - idx < OPAQUE16_LEN) {
        ret = BUFFER_ERROR;
        goto end;
    }
    ato16(data + idx, &s->ticketLen); idx += OPAQUE16_LEN;

    /* Dispose of ol dynamic ticket and ensure space for new ticket. */
    if (s->ticketLenAlloc > 0) {
        XFREE(s->ticket, NULL, DYNAMIC_TYPE_SESSION_TICK);
    }
    if (s->ticketLen <= SESSION_TICKET_LEN)
        s->ticket = s->staticTicket;
    else {
        s->ticket = (byte*)XMALLOC(s->ticketLen, NULL,
                                   DYNAMIC_TYPE_SESSION_TICK);
        if (s->ticket == NULL) {
            ret = MEMORY_ERROR;
            goto end;
        }
        s->ticketLenAlloc = (word16)s->ticketLen;
    }

    /* ticket */
    if (i - idx < s->ticketLen) {
        ret = BUFFER_ERROR;
        goto end;
    }
    XMEMCPY(s->ticket, data + idx, s->ticketLen); idx += s->ticketLen;
#endif
    (void)idx;

    if (sess != NULL) {
        *sess = s;
    }

    *p += idx;

end:
    if (ret != 0 && (sess == NULL || *sess != s)) {
        wolfSSL_SESSION_free(s);
        s = NULL;
    }
#endif /* HAVE_EXT_CACHE */
    return s;
}

/* Check if there is a session ticket associated with this WOLFSSL_SESSION.
 *
 * sess - pointer to WOLFSSL_SESSION struct
 *
 * Returns 1 if has session ticket, otherwise 0 */
int wolfSSL_SESSION_has_ticket(const WOLFSSL_SESSION* sess)
{
    WOLFSSL_ENTER("wolfSSL_SESSION_has_ticket");
#ifdef HAVE_SESSION_TICKET
    sess = ClientSessionToSession(sess);
    if (sess) {
        if ((sess->ticketLen > 0) && (sess->ticket != NULL)) {
            return WOLFSSL_SUCCESS;
        }
    }
#else
    (void)sess;
#endif
    return WOLFSSL_FAILURE;
}

unsigned long wolfSSL_SESSION_get_ticket_lifetime_hint(
                  const WOLFSSL_SESSION* sess)
{
    WOLFSSL_ENTER("wolfSSL_SESSION_get_ticket_lifetime_hint");
    sess = ClientSessionToSession(sess);
    if (sess) {
        return sess->timeout;
    }
    return 0;
}

long wolfSSL_SESSION_get_timeout(const WOLFSSL_SESSION* sess)
{
    long timeout = 0;
    WOLFSSL_ENTER("wolfSSL_SESSION_get_timeout");
    sess = ClientSessionToSession(sess);
    if (sess)
        timeout = sess->timeout;
    return timeout;
}


long wolfSSL_SESSION_get_time(const WOLFSSL_SESSION* sess)
{
    long bornOn = 0;
    WOLFSSL_ENTER("wolfSSL_SESSION_get_time");
    sess = ClientSessionToSession(sess);
    if (sess)
        bornOn = sess->bornOn;
    return bornOn;
}

long wolfSSL_SSL_SESSION_set_timeout(WOLFSSL_SESSION* ses, long t)
{
    word32 tmptime;

    ses = ClientSessionToSession(ses);
    if (ses == NULL || t < 0) {
        return BAD_FUNC_ARG;
    }

    tmptime = t & 0xFFFFFFFF;
    ses->timeout = tmptime;

    return WOLFSSL_SUCCESS;
}

#endif /* !NO_SESSION_CACHE && OPENSSL_EXTRA || HAVE_EXT_CACHE */

#ifdef OPENSSL_EXTRA

#if defined(HAVE_EX_DATA) && !defined(NO_FILESYSTEM)
int wolfSSL_cmp_peer_cert_to_file(WOLFSSL* ssl, const char *fname)
{
    int ret = WOLFSSL_FATAL_ERROR;

    WOLFSSL_ENTER("wolfSSL_cmp_peer_cert_to_file");
    if (ssl != NULL && fname != NULL)
    {
    #ifdef WOLFSSL_SMALL_STACK
        byte           staticBuffer[1]; /* force heap usage */
    #else
        byte           staticBuffer[FILE_BUFFER_SIZE];
    #endif
        byte*          myBuffer  = staticBuffer;
        int            dynamic   = 0;
        XFILE          file;
        long           sz        = 0;
        WOLFSSL_CTX*   ctx       = ssl->ctx;
        WOLFSSL_X509*  peer_cert = &ssl->peerCert;
        DerBuffer*     fileDer = NULL;

        file = XFOPEN(fname, "rb");
        if (file == XBADFILE)
            return WOLFSSL_BAD_FILE;

        if (XFSEEK(file, 0, XSEEK_END) != 0) {
            XFCLOSE(file);
            return WOLFSSL_BAD_FILE;
        }
        sz = XFTELL(file);
        XREWIND(file);

        if (sz > MAX_WOLFSSL_FILE_SIZE || sz < 0) {
            WOLFSSL_MSG("cmp_peer_cert_to_file size error");
            XFCLOSE(file);
            return WOLFSSL_BAD_FILE;
        }

        if (sz > (long)sizeof(staticBuffer)) {
            WOLFSSL_MSG("Getting dynamic buffer");
            myBuffer = (byte*)XMALLOC(sz, ctx->heap, DYNAMIC_TYPE_FILE);
            dynamic = 1;
        }

        if ((myBuffer != NULL) &&
            (sz > 0) &&
            (XFREAD(myBuffer, 1, sz, file) == (size_t)sz) &&
            (PemToDer(myBuffer, (long)sz, CERT_TYPE,
                      &fileDer, ctx->heap, NULL, NULL) == 0) &&
            (fileDer->length != 0) &&
            (fileDer->length == peer_cert->derCert->length) &&
            (XMEMCMP(peer_cert->derCert->buffer, fileDer->buffer,
                                                fileDer->length) == 0))
        {
            ret = 0;
        }

        FreeDer(&fileDer);

        if (dynamic)
            XFREE(myBuffer, ctx->heap, DYNAMIC_TYPE_FILE);

        XFCLOSE(file);
    }

    return ret;
}
#endif
#endif /* OPENSSL_EXTRA */
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
const WOLFSSL_ObjectInfo wolfssl_object_info[] = {
#ifndef NO_CERTS
    /* oidCertExtType */
    { NID_basic_constraints, BASIC_CA_OID, oidCertExtType, "basicConstraints",
                                                "X509v3 Basic Constraints"},
    { NID_subject_alt_name, ALT_NAMES_OID, oidCertExtType, "subjectAltName",
                                         "X509v3 Subject Alternative Name"},
    { NID_crl_distribution_points, CRL_DIST_OID, oidCertExtType, "crlDistributionPoints",
                                          "X509v3 CRL Distribution Points"},
    { NID_info_access, AUTH_INFO_OID, oidCertExtType, "authorityInfoAccess",
                                            "Authority Information Access"},
    { NID_authority_key_identifier, AUTH_KEY_OID, oidCertExtType,
               "authorityKeyIdentifier", "X509v3 Authority Key Identifier"},
    { NID_subject_key_identifier, SUBJ_KEY_OID, oidCertExtType,
                   "subjectKeyIdentifier", "X509v3 Subject Key Identifier"},
    { NID_key_usage, KEY_USAGE_OID, oidCertExtType, "keyUsage",
                                                        "X509v3 Key Usage"},
    { NID_inhibit_any_policy, INHIBIT_ANY_OID, oidCertExtType,
                           "inhibitAnyPolicy", "X509v3 Inhibit Any Policy"},
    { NID_ext_key_usage, EXT_KEY_USAGE_OID, oidCertExtType,
                           "extendedKeyUsage", "X509v3 Extended Key Usage"},
    { NID_name_constraints, NAME_CONS_OID, oidCertExtType,
                              "nameConstraints", "X509v3 Name Constraints"},
    { NID_certificate_policies, CERT_POLICY_OID, oidCertExtType,
                      "certificatePolicies", "X509v3 Certificate Policies"},

    /* oidCertAuthInfoType */
    { NID_ad_OCSP, AIA_OCSP_OID, oidCertAuthInfoType, "OCSP",
                                            "OCSP"},
    { NID_ad_ca_issuers, AIA_CA_ISSUER_OID, oidCertAuthInfoType,
                                                 "caIssuers", "CA Issuers"},

    /* oidCertPolicyType */
    { NID_any_policy, CP_ANY_OID, oidCertPolicyType, "anyPolicy",
                                                       "X509v3 Any Policy"},

    /* oidCertAltNameType */
    { NID_hw_name_oid, HW_NAME_OID, oidCertAltNameType, "Hardware name",""},

    /* oidCertKeyUseType */
    { NID_anyExtendedKeyUsage, EKU_ANY_OID, oidCertKeyUseType,
                           "anyExtendedKeyUsage", "Any Extended Key Usage"},
    { EKU_SERVER_AUTH_OID, EKU_SERVER_AUTH_OID, oidCertKeyUseType,
                             "serverAuth", "TLS Web Server Authentication"},
    { EKU_CLIENT_AUTH_OID, EKU_CLIENT_AUTH_OID, oidCertKeyUseType,
                             "clientAuth", "TLS Web Client Authentication"},
    { EKU_OCSP_SIGN_OID, EKU_OCSP_SIGN_OID, oidCertKeyUseType,
                                             "OCSPSigning", "OCSP Signing"},

    /* oidCertNameType */
    { NID_commonName, NID_commonName, oidCertNameType, "CN", "commonName"},
    { NID_surname, NID_surname, oidCertNameType, "SN", "surname"},
    { NID_serialNumber, NID_serialNumber, oidCertNameType, "serialNumber",
                                                            "serialNumber"},
    { NID_userId, NID_userId, oidCertNameType, "UID", "userid"},
    { NID_countryName, NID_countryName, oidCertNameType, "C", "countryName"},
    { NID_localityName, NID_localityName, oidCertNameType, "L", "localityName"},
    { NID_stateOrProvinceName, NID_stateOrProvinceName, oidCertNameType, "ST",
                                                        "stateOrProvinceName"},
    { NID_streetAddress, NID_streetAddress, oidCertNameType, "street",
                                                        "streetAddress"},
    { NID_organizationName, NID_organizationName, oidCertNameType, "O",
                                                        "organizationName"},
    { NID_organizationalUnitName, NID_organizationalUnitName, oidCertNameType,
                                                "OU", "organizationalUnitName"},
    { NID_emailAddress, NID_emailAddress, oidCertNameType, "emailAddress",
                                                            "emailAddress"},
    { NID_domainComponent, NID_domainComponent, oidCertNameType, "DC",
                                                            "domainComponent"},
    { NID_favouriteDrink, NID_favouriteDrink, oidCertNameType, "favouriteDrink",
                                                            "favouriteDrink"},
    { NID_businessCategory, NID_businessCategory, oidCertNameType, "businessCategory",
                                                            "businessCategory"},
    { NID_jurisdictionCountryName, NID_jurisdictionCountryName, oidCertNameType, "jurisdictionC",
                                                            "jurisdictionCountryName"},
    { NID_jurisdictionStateOrProvinceName, NID_jurisdictionStateOrProvinceName,
            oidCertNameType, "jurisdictionST", "jurisdictionStateOrProvinceName"},
    { NID_postalCode, NID_postalCode, oidCertNameType, "postalCode", "postalCode"},
    { NID_userId, NID_userId, oidCertNameType, "UID", "userId"},

#ifdef WOLFSSL_CERT_REQ
    { NID_pkcs9_challengePassword, CHALLENGE_PASSWORD_OID,
            oidCsrAttrType, "challengePassword", "challengePassword"},
    { NID_pkcs9_contentType, PKCS9_CONTENT_TYPE_OID,
        oidCsrAttrType, "contentType", "contentType" },
    { NID_pkcs9_unstructuredName, UNSTRUCTURED_NAME_OID,
        oidCsrAttrType, "unstructuredName", "unstructuredName" },
    { NID_name, NAME_OID, oidCsrAttrType, "name", "name" },
    { NID_surname, SURNAME_OID,
        oidCsrAttrType, "surname", "surname" },
    { NID_givenName, GIVEN_NAME_OID,
        oidCsrAttrType, "givenName", "givenName" },
    { NID_initials, INITIALS_OID,
        oidCsrAttrType, "initials", "initials" },
    { NID_dnQualifier, DNQUALIFIER_OID,
        oidCsrAttrType, "dnQualifer", "dnQualifier" },
#endif
#endif
#ifdef OPENSSL_EXTRA /* OPENSSL_EXTRA_X509_SMALL only needs the above */
        /* oidHashType */
    #ifdef WOLFSSL_MD2
        { NID_md2, MD2h, oidHashType, "MD2", "md2"},
    #endif
    #ifdef WOLFSSL_MD5
        { NID_md5, MD5h, oidHashType, "MD5", "md5"},
    #endif
    #ifndef NO_SHA
        { NID_sha1, SHAh, oidHashType, "SHA1", "sha1"},
    #endif
    #ifdef WOLFSSL_SHA224
        { NID_sha224, SHA224h, oidHashType, "SHA224", "sha224"},
    #endif
    #ifndef NO_SHA256
        { NID_sha256, SHA256h, oidHashType, "SHA256", "sha256"},
    #endif
    #ifdef WOLFSSL_SHA384
        { NID_sha384, SHA384h, oidHashType, "SHA384", "sha384"},
    #endif
    #ifdef WOLFSSL_SHA512
        { NID_sha512, SHA512h, oidHashType, "SHA512", "sha512"},
    #endif
    #ifdef WOLFSSL_SHA3
        #ifndef WOLFSSL_NOSHA3_224
        { NID_sha3_224, SHA3_224h, oidHashType, "SHA3-224", "sha3-224"},
        #endif
        #ifndef WOLFSSL_NOSHA3_256
        { NID_sha3_256, SHA3_256h, oidHashType, "SHA3-256", "sha3-256"},
        #endif
        #ifndef WOLFSSL_NOSHA3_384
        { NID_sha3_384, SHA3_384h, oidHashType, "SHA3-384", "sha3-384"},
        #endif
        #ifndef WOLFSSL_NOSHA3_512
        { NID_sha3_512, SHA3_512h, oidHashType, "SHA3-512", "sha3-512"},
        #endif
    #endif /* WOLFSSL_SHA3 */
        /* oidSigType */
    #ifndef NO_DSA
        #ifndef NO_SHA
        { NID_dsaWithSHA1, CTC_SHAwDSA, oidSigType, "DSA-SHA1", "dsaWithSHA1"},
        { NID_dsa_with_SHA256, CTC_SHA256wDSA, oidSigType, "dsa_with_SHA256",
                                                        "dsa_with_SHA256"},
        #endif
    #endif /* NO_DSA */
    #ifndef NO_RSA
        #ifdef WOLFSSL_MD2
        { NID_md2WithRSAEncryption, CTC_MD2wRSA, oidSigType, "RSA-MD2",
                                                        "md2WithRSAEncryption"},
        #endif
        #ifndef NO_MD5
        { NID_md5WithRSAEncryption, CTC_MD5wRSA, oidSigType, "RSA-MD5",
                                                        "md5WithRSAEncryption"},
        #endif
        #ifndef NO_SHA
        { NID_sha1WithRSAEncryption, CTC_SHAwRSA, oidSigType, "RSA-SHA1",
                                                       "sha1WithRSAEncryption"},
        #endif
        #ifdef WOLFSSL_SHA224
        { NID_sha224WithRSAEncryption, CTC_SHA224wRSA, oidSigType, "RSA-SHA224",
                                                     "sha224WithRSAEncryption"},
        #endif
        #ifndef NO_SHA256
        { NID_sha256WithRSAEncryption, CTC_SHA256wRSA, oidSigType, "RSA-SHA256",
                                                     "sha256WithRSAEncryption"},
        #endif
        #ifdef WOLFSSL_SHA384
        { NID_sha384WithRSAEncryption, CTC_SHA384wRSA, oidSigType, "RSA-SHA384",
                                                     "sha384WithRSAEncryption"},
        #endif
        #ifdef WOLFSSL_SHA512
        { NID_sha512WithRSAEncryption, CTC_SHA512wRSA, oidSigType, "RSA-SHA512",
                                                     "sha512WithRSAEncryption"},
        #endif
        #ifdef WOLFSSL_SHA3
        #ifndef WOLFSSL_NOSHA3_224
        { NID_RSA_SHA3_224, CTC_SHA3_224wRSA, oidSigType, "RSA-SHA3-224",
                                                     "sha3-224WithRSAEncryption"},
        #endif
        #ifndef WOLFSSL_NOSHA3_256
        { NID_RSA_SHA3_256, CTC_SHA3_256wRSA, oidSigType, "RSA-SHA3-256",
                                                     "sha3-256WithRSAEncryption"},
        #endif
        #ifndef WOLFSSL_NOSHA3_384
        { NID_RSA_SHA3_384, CTC_SHA3_384wRSA, oidSigType, "RSA-SHA3-384",
                                                     "sha3-384WithRSAEncryption"},
        #endif
        #ifndef WOLFSSL_NOSHA3_512
        { NID_RSA_SHA3_512, CTC_SHA3_512wRSA, oidSigType, "RSA-SHA3-512",
                                                     "sha3-512WithRSAEncryption"},
        #endif
        #endif
    #endif /* NO_RSA */
    #ifdef HAVE_ECC
        #ifndef NO_SHA
        { NID_ecdsa_with_SHA1, CTC_SHAwECDSA, oidSigType, "ecdsa-with-SHA1", "shaWithECDSA"},
        #endif
        #ifdef WOLFSSL_SHA224
        { NID_ecdsa_with_SHA224, CTC_SHA224wECDSA, oidSigType, "ecdsa-with-SHA224","sha224WithECDSA"},
        #endif
        #ifndef NO_SHA256
        { NID_ecdsa_with_SHA256, CTC_SHA256wECDSA, oidSigType, "ecdsa-with-SHA256","sha256WithECDSA"},
        #endif
        #ifdef WOLFSSL_SHA384
        { NID_ecdsa_with_SHA384, CTC_SHA384wECDSA, oidSigType, "ecdsa-with-SHA384","sha384WithECDSA"},
        #endif
        #ifdef WOLFSSL_SHA512
        { NID_ecdsa_with_SHA512, CTC_SHA512wECDSA, oidSigType, "ecdsa-with-SHA512","sha512WithECDSA"},
        #endif
        #ifdef WOLFSSL_SHA3
        #ifndef WOLFSSL_NOSHA3_224
        { NID_ecdsa_with_SHA3_224, CTC_SHA3_224wECDSA, oidSigType, "id-ecdsa-with-SHA3-224",
                "ecdsa_with_SHA3-224"},
        #endif
        #ifndef WOLFSSL_NOSHA3_256
        { NID_ecdsa_with_SHA3_256, CTC_SHA3_256wECDSA, oidSigType, "id-ecdsa-with-SHA3-256",
                "ecdsa_with_SHA3-256"},
        #endif
        #ifndef WOLFSSL_NOSHA3_384
        { NID_ecdsa_with_SHA3_384, CTC_SHA3_384wECDSA, oidSigType, "id-ecdsa-with-SHA3-384",
                "ecdsa_with_SHA3-384"},
        #endif
        #ifndef WOLFSSL_NOSHA3_512
        { NID_ecdsa_with_SHA3_512, CTC_SHA3_512wECDSA, oidSigType, "id-ecdsa-with-SHA3-512",
                "ecdsa_with_SHA3-512"},
        #endif
        #endif
    #endif /* HAVE_ECC */

        /* oidKeyType */
    #ifndef NO_DSA
        { NID_dsa, DSAk, oidKeyType, "DSA", "dsaEncryption"},
    #endif /* NO_DSA */
    #ifndef NO_RSA
        { NID_rsaEncryption, RSAk, oidKeyType, "rsaEncryption", "rsaEncryption"},
    #endif /* NO_RSA */
    #ifdef HAVE_ECC
        { NID_X9_62_id_ecPublicKey, ECDSAk, oidKeyType, "id-ecPublicKey",
                                                        "id-ecPublicKey"},
    #endif /* HAVE_ECC */
    #ifndef NO_DH
        { NID_dhKeyAgreement, DHk, oidKeyType, "dhKeyAgreement", "dhKeyAgreement"},
    #endif
    #ifdef HAVE_ED448
        { NID_ED448, ED448k,  oidKeyType, "ED448", "ED448"},
    #endif
    #ifdef HAVE_ED25519
        { NID_ED25519, ED25519k,  oidKeyType, "ED25519", "ED25519"},
    #endif
    #ifdef HAVE_PQC
    #ifdef HAVE_FALCON
        { CTC_FALCON_LEVEL1, FALCON_LEVEL1k,  oidKeyType, "Falcon Level 1",
                                                          "Falcon Level 1"},
        { CTC_FALCON_LEVEL5, FALCON_LEVEL5k,  oidKeyType, "Falcon Level 5",
                                                          "Falcon Level 5"},
    #endif /* HAVE_FALCON */
    #ifdef HAVE_DILITHIUM
        { CTC_DILITHIUM_LEVEL2, DILITHIUM_LEVEL2k,  oidKeyType,
          "Dilithium Level 2", "Dilithium Level 2"},
        { CTC_DILITHIUM_LEVEL3, DILITHIUM_LEVEL3k,  oidKeyType,
          "Dilithium Level 3", "Dilithium Level 3"},
        { CTC_DILITHIUM_LEVEL5, DILITHIUM_LEVEL5k,  oidKeyType,
          "Dilithium Level 5", "Dilithium Level 5"},
    #endif /* HAVE_DILITHIUM */
    #endif /* HAVE_PQC */

        /* oidCurveType */
    #ifdef HAVE_ECC
        { NID_X9_62_prime192v1, ECC_SECP192R1_OID, oidCurveType, "prime192v1", "prime192v1"},
        { NID_X9_62_prime192v2, ECC_PRIME192V2_OID, oidCurveType, "prime192v2", "prime192v2"},
        { NID_X9_62_prime192v3, ECC_PRIME192V3_OID, oidCurveType, "prime192v3", "prime192v3"},

        { NID_X9_62_prime239v1, ECC_PRIME239V1_OID, oidCurveType, "prime239v1", "prime239v1"},
        { NID_X9_62_prime239v2, ECC_PRIME239V2_OID, oidCurveType, "prime239v2", "prime239v2"},
        { NID_X9_62_prime239v3, ECC_PRIME239V3_OID, oidCurveType, "prime239v3", "prime239v3"},

        { NID_X9_62_prime256v1, ECC_SECP256R1_OID, oidCurveType, "prime256v1", "prime256v1"},

        { NID_secp112r1, ECC_SECP112R1_OID,  oidCurveType, "secp112r1", "secp112r1"},
        { NID_secp112r2, ECC_SECP112R2_OID,  oidCurveType, "secp112r2", "secp112r2"},

        { NID_secp128r1, ECC_SECP128R1_OID,  oidCurveType, "secp128r1", "secp128r1"},
        { NID_secp128r2, ECC_SECP128R2_OID,  oidCurveType, "secp128r2", "secp128r2"},

        { NID_secp160r1, ECC_SECP160R1_OID,  oidCurveType, "secp160r1", "secp160r1"},
        { NID_secp160r2, ECC_SECP160R2_OID,  oidCurveType, "secp160r2", "secp160r2"},

        { NID_secp224r1, ECC_SECP224R1_OID,  oidCurveType, "secp224r1", "secp224r1"},
        { NID_secp384r1, ECC_SECP384R1_OID,  oidCurveType, "secp384r1", "secp384r1"},
        { NID_secp521r1, ECC_SECP521R1_OID,  oidCurveType, "secp521r1", "secp521r1"},

        { NID_secp160k1, ECC_SECP160K1_OID,  oidCurveType, "secp160k1", "secp160k1"},
        { NID_secp192k1, ECC_SECP192K1_OID,  oidCurveType, "secp192k1", "secp192k1"},
        { NID_secp224k1, ECC_SECP224K1_OID,  oidCurveType, "secp224k1", "secp224k1"},
        { NID_secp256k1, ECC_SECP256K1_OID,  oidCurveType, "secp256k1", "secp256k1"},

        { NID_brainpoolP160r1, ECC_BRAINPOOLP160R1_OID,  oidCurveType, "brainpoolP160r1", "brainpoolP160r1"},
        { NID_brainpoolP192r1, ECC_BRAINPOOLP192R1_OID,  oidCurveType, "brainpoolP192r1", "brainpoolP192r1"},
        { NID_brainpoolP224r1, ECC_BRAINPOOLP224R1_OID,  oidCurveType, "brainpoolP224r1", "brainpoolP224r1"},
        { NID_brainpoolP256r1, ECC_BRAINPOOLP256R1_OID,  oidCurveType, "brainpoolP256r1", "brainpoolP256r1"},
        { NID_brainpoolP320r1, ECC_BRAINPOOLP320R1_OID,  oidCurveType, "brainpoolP320r1", "brainpoolP320r1"},
        { NID_brainpoolP384r1, ECC_BRAINPOOLP384R1_OID,  oidCurveType, "brainpoolP384r1", "brainpoolP384r1"},
        { NID_brainpoolP512r1, ECC_BRAINPOOLP512R1_OID,  oidCurveType, "brainpoolP512r1", "brainpoolP512r1"},
    #endif /* HAVE_ECC */

        /* oidBlkType */
    #ifdef WOLFSSL_AES_128
        { AES128CBCb, AES128CBCb, oidBlkType, "AES-128-CBC", "aes-128-cbc"},
    #endif
    #ifdef WOLFSSL_AES_192
        { AES192CBCb, AES192CBCb, oidBlkType, "AES-192-CBC", "aes-192-cbc"},
    #endif
    #ifdef WOLFSSL_AES_256
        { AES256CBCb, AES256CBCb, oidBlkType, "AES-256-CBC", "aes-256-cbc"},
    #endif
    #ifndef NO_DES3
        { NID_des, DESb, oidBlkType, "DES-CBC", "des-cbc"},
        { NID_des3, DES3b, oidBlkType, "DES-EDE3-CBC", "des-ede3-cbc"},
    #endif /* !NO_DES3 */
    #if defined(HAVE_CHACHA) && defined(HAVE_POLY1305)
        { NID_chacha20_poly1305, NID_chacha20_poly1305, oidBlkType, "ChaCha20-Poly1305", "chacha20-poly1305"},
    #endif

        /* oidOcspType */
    #ifdef HAVE_OCSP
        { NID_id_pkix_OCSP_basic, OCSP_BASIC_OID, oidOcspType, "basicOCSPResponse",
                                                         "Basic OCSP Response"},
        { OCSP_NONCE_OID, OCSP_NONCE_OID, oidOcspType, "Nonce",
                                                                  "OCSP Nonce"},
    #endif /* HAVE_OCSP */

    #ifndef NO_PWDBASED
        /* oidKdfType */
        { PBKDF2_OID, PBKDF2_OID, oidKdfType, "PBKDFv2", "PBKDF2"},

        /* oidPBEType */
        { PBE_SHA1_RC4_128, PBE_SHA1_RC4_128, oidPBEType,
                                 "PBE-SHA1-RC4-128", "pbeWithSHA1And128BitRC4"},
        { PBE_SHA1_DES, PBE_SHA1_DES, oidPBEType, "PBE-SHA1-DES",
                                                       "pbeWithSHA1AndDES-CBC"},
        { PBE_SHA1_DES3, PBE_SHA1_DES3, oidPBEType, "PBE-SHA1-3DES",
                                            "pbeWithSHA1And3-KeyTripleDES-CBC"},
    #endif

        /* oidKeyWrapType */
    #ifdef WOLFSSL_AES_128
        { AES128_WRAP, AES128_WRAP, oidKeyWrapType, "AES-128 wrap", "aes128-wrap"},
    #endif
    #ifdef WOLFSSL_AES_192
        { AES192_WRAP, AES192_WRAP, oidKeyWrapType, "AES-192 wrap", "aes192-wrap"},
    #endif
    #ifdef WOLFSSL_AES_256
        { AES256_WRAP, AES256_WRAP, oidKeyWrapType, "AES-256 wrap", "aes256-wrap"},
    #endif

    #ifndef NO_PKCS7
        #ifndef NO_DH
        /* oidCmsKeyAgreeType */
            #ifndef NO_SHA
        { dhSinglePass_stdDH_sha1kdf_scheme, dhSinglePass_stdDH_sha1kdf_scheme,
                oidCmsKeyAgreeType, "dhSinglePass-stdDH-sha1kdf-scheme", "dhSinglePass-stdDH-sha1kdf-scheme"},
            #endif
            #ifdef WOLFSSL_SHA224
        { dhSinglePass_stdDH_sha224kdf_scheme,
                dhSinglePass_stdDH_sha224kdf_scheme, oidCmsKeyAgreeType,
                "dhSinglePass-stdDH-sha224kdf-scheme", "dhSinglePass-stdDH-sha224kdf-scheme"},
            #endif
            #ifndef NO_SHA256
        { dhSinglePass_stdDH_sha256kdf_scheme,
                        dhSinglePass_stdDH_sha256kdf_scheme, oidCmsKeyAgreeType,
                        "dhSinglePass-stdDH-sha256kdf-scheme", "dhSinglePass-stdDH-sha256kdf-scheme"},
            #endif
            #ifdef WOLFSSL_SHA384
        { dhSinglePass_stdDH_sha384kdf_scheme,
                        dhSinglePass_stdDH_sha384kdf_scheme, oidCmsKeyAgreeType,
                        "dhSinglePass-stdDH-sha384kdf-scheme", "dhSinglePass-stdDH-sha384kdf-scheme"},
            #endif
            #ifdef WOLFSSL_SHA512
        { dhSinglePass_stdDH_sha512kdf_scheme,
                        dhSinglePass_stdDH_sha512kdf_scheme, oidCmsKeyAgreeType,
                        "dhSinglePass-stdDH-sha512kdf-scheme", "dhSinglePass-stdDH-sha512kdf-scheme"},
            #endif
        #endif
    #endif
    #if defined(WOLFSSL_APACHE_HTTPD)
        /* "1.3.6.1.5.5.7.8.7" */
        { NID_id_on_dnsSRV, NID_id_on_dnsSRV, oidCertNameType,
            WOLFSSL_SN_DNS_SRV, WOLFSSL_LN_DNS_SRV },

        /* "1.3.6.1.4.1.311.20.2.3" */
        { NID_ms_upn, WOLFSSL_MS_UPN_SUM, oidCertExtType, WOLFSSL_SN_MS_UPN,
            WOLFSSL_LN_MS_UPN },

        /* "1.3.6.1.5.5.7.1.24" */
        { NID_tlsfeature, WOLFSSL_TLS_FEATURE_SUM, oidTlsExtType,
            WOLFSSL_SN_TLS_FEATURE, WOLFSSL_LN_TLS_FEATURE },
    #endif
#endif /* OPENSSL_EXTRA */
};

#define WOLFSSL_OBJECT_INFO_SZ \
                (sizeof(wolfssl_object_info) / sizeof(*wolfssl_object_info))
const size_t wolfssl_object_info_sz = WOLFSSL_OBJECT_INFO_SZ;
#endif

#ifdef OPENSSL_EXTRA

WOLFSSL_ASN1_INTEGER* wolfSSL_BN_to_ASN1_INTEGER(const WOLFSSL_BIGNUM *bn, WOLFSSL_ASN1_INTEGER *ai)
{
    WOLFSSL_ASN1_INTEGER* a;
    int len;
    const int extraTagSz = MAX_LENGTH_SZ + 1;
    byte intTag[MAX_LENGTH_SZ + 1];
    int idx = 0;
    WOLFSSL_ENTER("wolfSSL_BN_to_ASN1_INTEGER");

    if (ai == NULL) {
        a = wolfSSL_ASN1_INTEGER_new();

        if (a == NULL)
            return NULL;

        a->type = V_ASN1_INTEGER;
    }
    else {
        a = ai;
    }
    if (a) {
        if (wolfSSL_BN_is_negative(bn) && !wolfSSL_BN_is_zero(bn)) {
            a->type |= V_ASN1_NEG_INTEGER;
            a->negative = 1;
        }

        len = wolfSSL_BN_num_bytes(bn);
        if (len == 0)
            len = 1;

        /* allocate buffer */
        if (len + extraTagSz > (int)sizeof(a->intData)) {
            /* create new data buffer and copy over */
            a->data = (byte*)XMALLOC(len + extraTagSz, NULL,
                    DYNAMIC_TYPE_OPENSSL);
            if (a->data == NULL) {
                if (a != ai)
                    wolfSSL_ASN1_INTEGER_free(a);
                return NULL;
            }
            a->isDynamic = 1;
        }
        else {
            XMEMSET(a->intData, 0, sizeof(a->intData));
            a->data = a->intData;
            a->isDynamic = 0;
        }

        /* populate data */
        if (wolfSSL_BN_is_zero(bn)) {
            a->data[0] = 0;
        }
        else {
            len = wolfSSL_BN_bn2bin(bn, a->data);
            if (len < 0) {
                wolfSSL_ASN1_INTEGER_free(a);
                return NULL;
            }
        }
        a->length = len;

        /* Write ASN tag */
        idx = SetASNInt(a->length, a->data[0], intTag);
        XMEMMOVE(a->data + idx, a->data, a->length);
        XMEMCPY(a->data, intTag, idx);
        a->dataMax = a->length += idx;
    }

    return a;
}

#ifdef OPENSSL_ALL
void *wolfSSL_ASN1_item_new(const WOLFSSL_ASN1_ITEM *tpl)
{
    void *ret = NULL;
    const WOLFSSL_ASN1_TEMPLATE *member = NULL;
    size_t i;
    WOLFSSL_ENTER("wolfSSL_ASN1_item_new");
    if (!tpl) {
        return NULL;
    }
    if (!(ret = (void *)XMALLOC(tpl->size, NULL, DYNAMIC_TYPE_OPENSSL))) {
        return NULL;
    }
    XMEMSET(ret, 0, tpl->size);
    for (member = tpl->members, i = 0; i < tpl->mcount;
            member++, i++) {
        switch (member->type) {
            case WOLFSSL_X509_ALGOR_ASN1:
            {
                WOLFSSL_X509_ALGOR* algor = wolfSSL_X509_ALGOR_new();
                if (!algor) {
                    goto error;
                }
                *(WOLFSSL_X509_ALGOR**)(((byte*)ret) + member->offset) = algor;
                break;
            }
            case WOLFSSL_ASN1_BIT_STRING_ASN1:
            {
                WOLFSSL_ASN1_BIT_STRING* bit_str = wolfSSL_ASN1_BIT_STRING_new();
                if (!bit_str) {
                    goto error;
                }
                *(WOLFSSL_ASN1_BIT_STRING**)(((byte*)ret) + member->offset) = bit_str;
                break;
            }
            default:
                WOLFSSL_MSG("Type not supported in wolfSSL_ASN1_item_new");
                goto error;
        }
    }
    return ret;
error:
    wolfSSL_ASN1_item_free(ret, tpl);
    return NULL;
}

void wolfSSL_ASN1_item_free(void *val, const WOLFSSL_ASN1_ITEM *tpl)
{
    const WOLFSSL_ASN1_TEMPLATE *member = NULL;
    size_t i;
    WOLFSSL_ENTER("wolfSSL_ASN1_item_free");
    if (val) {
        for (member = tpl->members, i = 0; i < tpl->mcount;
                member++, i++) {
            switch (member->type) {
                case WOLFSSL_X509_ALGOR_ASN1:
                {
                    WOLFSSL_X509_ALGOR* algor = *(WOLFSSL_X509_ALGOR**)
                                                 (((byte*)val) + member->offset);
                    if (algor) {
                        wolfSSL_X509_ALGOR_free(algor);
                    }
                    break;
                }
                case WOLFSSL_ASN1_BIT_STRING_ASN1:
                {
                    WOLFSSL_ASN1_BIT_STRING* bit_str = *(WOLFSSL_ASN1_BIT_STRING**)
                                                        (((byte*)val) + member->offset);
                    if (bit_str) {
                        wolfSSL_ASN1_BIT_STRING_free(bit_str);
                    }
                    break;
                }
                default:
                    WOLFSSL_MSG("Type not supported in wolfSSL_ASN1_item_free");
            }
        }
        XFREE(val, NULL, DYNAMIC_TYPE_OPENSSL);
    }
}

#define bufLenOrNull(buf, len) ((buf) ? (buf) + (len) : NULL)

static int i2dProcessMembers(const void *src, byte *buf,
                          const WOLFSSL_ASN1_TEMPLATE *members, size_t mcount)
{
    const WOLFSSL_ASN1_TEMPLATE *member = NULL;
    int len = 0, ret;
    size_t i;
    WOLFSSL_ENTER("processMembers");
    for (member = members, i = 0; i < mcount; member++, i++) {
        switch (member->type) {
            case WOLFSSL_X509_ALGOR_ASN1:
            {
                word32 oid = 0;
                word32 idx = 0;
                const WOLFSSL_X509_ALGOR* algor = *(const WOLFSSL_X509_ALGOR**)
                                                   (((byte*)src) + member->offset);
                if (!algor->algorithm) {
                    WOLFSSL_LEAVE("processMembers", WOLFSSL_FAILURE);
                    return WOLFSSL_FAILURE;
                }

                if (GetObjectId(algor->algorithm->obj, &idx, &oid,
                        algor->algorithm->grp, algor->algorithm->objSz) < 0) {
                    WOLFSSL_MSG("Issue getting OID of object");
                    return -1;
                }

                ret = SetAlgoID(oid, bufLenOrNull(buf, len),
                                algor->algorithm->grp, 0);
                if (!ret) {
                    return WOLFSSL_FAILURE;
                }
                len += ret;
                break;
            }
            case WOLFSSL_ASN1_BIT_STRING_ASN1:
            {
                const WOLFSSL_ASN1_BIT_STRING* bit_str;
                bit_str = *(const WOLFSSL_ASN1_BIT_STRING**)
                           (((byte*)src) + member->offset);
                len += SetBitString(bit_str->length, 0, bufLenOrNull(buf, len));
                if (buf && bit_str->data) {
                    XMEMCPY(buf + len, bit_str->data, bit_str->length);
                }
                len += bit_str->length;
                break;
            }
            default:
                WOLFSSL_MSG("Type not support in processMembers");
                WOLFSSL_LEAVE("processMembers", WOLFSSL_FAILURE);
                return WOLFSSL_FAILURE;
        }
    }
    WOLFSSL_LEAVE("processMembers", len);
    return len;
}

static int wolfSSL_ASN1_item_i2d_1(const void *src, byte *buf,
                                       const WOLFSSL_ASN1_ITEM *tpl, int *len)
{
    *len = 0;

    switch (tpl->type) {
        case ASN_SEQUENCE:
        {
            int seq_len = i2dProcessMembers(src, NULL, tpl->members,
                                         tpl->mcount);
            if (seq_len == WOLFSSL_FAILURE)
                return WOLFSSL_FAILURE;
            *len += SetSequence(seq_len, bufLenOrNull(buf, *len));
            if (buf) {
                if (i2dProcessMembers(src, bufLenOrNull(buf, *len), tpl->members,
                                      tpl->mcount) != seq_len) {
                    WOLFSSL_MSG("Inconsistent sequence length");
                    return WOLFSSL_FAILURE;
                }
            }
            *len += seq_len;
            break;
        }
        default:
            WOLFSSL_MSG("Type not supported in wolfSSL_ASN1_item_i2d");
            return WOLFSSL_FAILURE;
    }

    return WOLFSSL_SUCCESS;
}

int wolfSSL_ASN1_item_i2d(const void *src, byte **dest,
                          const WOLFSSL_ASN1_ITEM *tpl)
{
    int len;
    byte *buf = NULL;

    WOLFSSL_ENTER("wolfSSL_ASN1_item_i2d");

    if ((src == NULL) || (tpl == NULL))
        goto error;

    if (wolfSSL_ASN1_item_i2d_1(src, NULL, tpl, &len) != WOLFSSL_SUCCESS)
        goto error;

    if (dest == NULL) {
        WOLFSSL_LEAVE("wolfSSL_ASN1_item_i2d", WOLFSSL_SUCCESS);
        return len;
    }

    if (*dest == NULL) {
        buf = (byte*)XMALLOC(len, NULL, DYNAMIC_TYPE_ASN1);
        if (buf == NULL)
            goto error;
    } else
        buf = *dest;

    if (wolfSSL_ASN1_item_i2d_1(src, buf, tpl, &len) != WOLFSSL_SUCCESS)
        goto error;

    if (*dest == NULL)
        *dest = buf;
    else {
        /* XXX *dest length is not checked because the user is responsible
         * for providing a long enough buffer
         */
        XMEMCPY(*dest, buf, len);
    }

    WOLFSSL_LEAVE("wolfSSL_ASN1_item_i2d", len);
    return len;
error:
    if (buf) {
        XFREE(buf, NULL, DYNAMIC_TYPE_ASN1);
    }
    WOLFSSL_LEAVE("wolfSSL_ASN1_item_i2d", WOLFSSL_FAILURE);
    return WOLFSSL_FAILURE;
}

#endif /* OPENSSL_ALL */

#endif /* OPENSSL_EXTRA */

#ifdef OPENSSL_EXTRA
WOLFSSL_HMAC_CTX* wolfSSL_HMAC_CTX_new(void)
{
    WOLFSSL_HMAC_CTX* hmac_ctx = (WOLFSSL_HMAC_CTX*)XMALLOC(
        sizeof(WOLFSSL_HMAC_CTX), NULL, DYNAMIC_TYPE_OPENSSL);
    if (hmac_ctx != NULL) {
        XMEMSET(hmac_ctx, 0, sizeof(WOLFSSL_HMAC_CTX));
    }
    return hmac_ctx;
}

int wolfSSL_HMAC_CTX_Init(WOLFSSL_HMAC_CTX* ctx)
{
    WOLFSSL_MSG("wolfSSL_HMAC_CTX_Init");

    if (ctx != NULL) {
        /* wc_HmacSetKey sets up ctx->hmac */
        XMEMSET(ctx, 0, sizeof(WOLFSSL_HMAC_CTX));
    }

    return WOLFSSL_SUCCESS;
}


int wolfSSL_HMAC_Init_ex(WOLFSSL_HMAC_CTX* ctx, const void* key,
                             int keylen, const EVP_MD* type, WOLFSSL_ENGINE* e)
{
    WOLFSSL_ENTER("wolfSSL_HMAC_Init_ex");

    /* WOLFSSL_ENGINE not used, call wolfSSL_HMAC_Init */
    (void)e;
    return wolfSSL_HMAC_Init(ctx, key, keylen, type);
}


/* helper function for Deep copy of internal wolfSSL hmac structure
 * returns WOLFSSL_SUCCESS on success */
int wolfSSL_HmacCopy(Hmac* des, Hmac* src)
{
    void* heap;
    int ret;

#ifndef HAVE_FIPS
    heap = src->heap;
#else
    heap = NULL;
#endif
    if (wc_HmacInit(des, heap, 0) != 0) {
        return WOLFSSL_FAILURE;
    }

    /* requires that hash structures have no dynamic parts to them */
    switch (src->macType) {
    #ifndef NO_MD5
        case WC_MD5:
            ret = wc_Md5Copy(&src->hash.md5, &des->hash.md5);
            break;
    #endif /* !NO_MD5 */

    #ifndef NO_SHA
        case WC_SHA:
            ret = wc_ShaCopy(&src->hash.sha, &des->hash.sha);
            break;
    #endif /* !NO_SHA */

    #ifdef WOLFSSL_SHA224
        case WC_SHA224:
            ret = wc_Sha224Copy(&src->hash.sha224, &des->hash.sha224);
            break;
    #endif /* WOLFSSL_SHA224 */

    #ifndef NO_SHA256
        case WC_SHA256:
            ret = wc_Sha256Copy(&src->hash.sha256, &des->hash.sha256);
            break;
    #endif /* !NO_SHA256 */

    #ifdef WOLFSSL_SHA384
        case WC_SHA384:
            ret = wc_Sha384Copy(&src->hash.sha384, &des->hash.sha384);
            break;
    #endif /* WOLFSSL_SHA384 */
    #ifdef WOLFSSL_SHA512
        case WC_SHA512:
            ret = wc_Sha512Copy(&src->hash.sha512, &des->hash.sha512);
            break;
    #endif /* WOLFSSL_SHA512 */
#ifdef WOLFSSL_SHA3
    #ifndef WOLFSSL_NOSHA3_224
        case WC_SHA3_224:
            ret = wc_Sha3_224_Copy(&src->hash.sha3, &des->hash.sha3);
            break;
    #endif /* WOLFSSL_NO_SHA3_224 */
    #ifndef WOLFSSL_NOSHA3_256
        case WC_SHA3_256:
            ret = wc_Sha3_256_Copy(&src->hash.sha3, &des->hash.sha3);
            break;
    #endif /* WOLFSSL_NO_SHA3_256 */
    #ifndef WOLFSSL_NOSHA3_384
        case WC_SHA3_384:
            ret = wc_Sha3_384_Copy(&src->hash.sha3, &des->hash.sha3);
            break;
    #endif /* WOLFSSL_NO_SHA3_384 */
    #ifndef WOLFSSL_NOSHA3_512
        case WC_SHA3_512:
            ret = wc_Sha3_512_Copy(&src->hash.sha3, &des->hash.sha3);
            break;
    #endif /* WOLFSSL_NO_SHA3_512 */
#endif /* WOLFSSL_SHA3 */

        default:
            return WOLFSSL_FAILURE;
    }

    if (ret != 0)
        return WOLFSSL_FAILURE;

    XMEMCPY((byte*)des->ipad, (byte*)src->ipad, WC_HMAC_BLOCK_SIZE);
    XMEMCPY((byte*)des->opad, (byte*)src->opad, WC_HMAC_BLOCK_SIZE);
    XMEMCPY((byte*)des->innerHash, (byte*)src->innerHash, WC_MAX_DIGEST_SIZE);
#ifndef HAVE_FIPS
    des->heap    = heap;
#endif
    des->macType = src->macType;
    des->innerHashKeyed = src->innerHashKeyed;

#ifdef WOLFSSL_ASYNC_CRYPT
    XMEMCPY(&des->asyncDev, &src->asyncDev, sizeof(WC_ASYNC_DEV));
    des->keyLen = src->keyLen;
    #ifdef HAVE_CAVIUM
        des->data = (byte*)XMALLOC(src->dataLen, des->heap,
                DYNAMIC_TYPE_HMAC);
        if (des->data == NULL) {
            return BUFFER_E;
        }
        XMEMCPY(des->data, src->data, src->dataLen);
        des->dataLen = src->dataLen;
    #endif /* HAVE_CAVIUM */
#endif /* WOLFSSL_ASYNC_CRYPT */
        return WOLFSSL_SUCCESS;
}


/* Deep copy of information from src to des structure
 *
 * des destination to copy information to
 * src structure to get information from
 *
 * Returns WOLFSSL_SUCCESS on success and WOLFSSL_FAILURE on error
 */
int wolfSSL_HMAC_CTX_copy(WOLFSSL_HMAC_CTX* des, WOLFSSL_HMAC_CTX* src)
{
    WOLFSSL_ENTER("wolfSSL_HMAC_CTX_copy");

    if (des == NULL || src == NULL) {
        return WOLFSSL_FAILURE;
    }

    des->type = src->type;
    XMEMCPY((byte *)&des->save_ipad, (byte *)&src->hmac.ipad,
                                        WC_HMAC_BLOCK_SIZE);
    XMEMCPY((byte *)&des->save_opad, (byte *)&src->hmac.opad,
                                        WC_HMAC_BLOCK_SIZE);

    return wolfSSL_HmacCopy(&des->hmac, &src->hmac);
}


#if defined(HAVE_FIPS) && \
    (!defined(HAVE_FIPS_VERSION) || (HAVE_FIPS_VERSION < 2))

static int _HMAC_Init(Hmac* hmac, int type, void* heap)
{
    int ret = 0;

    switch (type) {
    #ifndef NO_MD5
        case WC_MD5:
            ret = wc_InitMd5(&hmac->hash.md5);
            break;
    #endif /* !NO_MD5 */

    #ifndef NO_SHA
        case WC_SHA:
            ret = wc_InitSha(&hmac->hash.sha);
            break;
    #endif /* !NO_SHA */

    #ifdef WOLFSSL_SHA224
        case WC_SHA224:
            ret = wc_InitSha224(&hmac->hash.sha224);
            break;
    #endif /* WOLFSSL_SHA224 */

    #ifndef NO_SHA256
        case WC_SHA256:
            ret = wc_InitSha256(&hmac->hash.sha256);
            break;
    #endif /* !NO_SHA256 */

    #ifdef WOLFSSL_SHA384
        case WC_SHA384:
            ret = wc_InitSha384(&hmac->hash.sha384);
            break;
    #endif /* WOLFSSL_SHA384 */
    #ifdef WOLFSSL_SHA512
        case WC_SHA512:
            ret = wc_InitSha512(&hmac->hash.sha512);
            break;
    #endif /* WOLFSSL_SHA512 */

    #ifdef WOLFSSL_SHA3
        case WC_SHA3_224:
            ret = wc_InitSha3_224(&hmac->hash.sha3, heap, INVALID_DEVID);
            break;
        case WC_SHA3_256:
            ret = wc_InitSha3_256(&hmac->hash.sha3, heap, INVALID_DEVID);
            break;
        case WC_SHA3_384:
            ret = wc_InitSha3_384(&hmac->hash.sha3, heap, INVALID_DEVID);
            break;
        case WC_SHA3_512:
            ret = wc_InitSha3_512(&hmac->hash.sha3, heap, INVALID_DEVID);
            break;
    #endif

        default:
            ret = BAD_FUNC_ARG;
            break;
    }

    (void)heap;

    return ret;
}

#else
    #define _HMAC_Init _InitHmac
#endif


int wolfSSL_HMAC_Init(WOLFSSL_HMAC_CTX* ctx, const void* key, int keylen,
                  const EVP_MD* type)
{
    int hmac_error = 0;
    void* heap = NULL;
    int inited;

    WOLFSSL_MSG("wolfSSL_HMAC_Init");

    if (ctx == NULL) {
        WOLFSSL_MSG("no ctx on init");
        return WOLFSSL_FAILURE;
    }

#ifndef HAVE_FIPS
    heap = ctx->hmac.heap;
#endif

    if (type) {
        WOLFSSL_MSG("init has type");

#ifndef NO_MD5
        if (XSTRNCMP(type, "MD5", 3) == 0) {
            WOLFSSL_MSG("md5 hmac");
            ctx->type = WC_MD5;
        }
        else
#endif
#ifdef WOLFSSL_SHA224
        if (XSTRNCMP(type, "SHA224", 6) == 0) {
            WOLFSSL_MSG("sha224 hmac");
            ctx->type = WC_SHA224;
        }
        else
#endif
#ifndef NO_SHA256
        if (XSTRNCMP(type, "SHA256", 6) == 0) {
            WOLFSSL_MSG("sha256 hmac");
            ctx->type = WC_SHA256;
        }
        else
#endif
#ifdef WOLFSSL_SHA384
        if (XSTRNCMP(type, "SHA384", 6) == 0) {
            WOLFSSL_MSG("sha384 hmac");
            ctx->type = WC_SHA384;
        }
        else
#endif
#ifdef WOLFSSL_SHA512
        if (XSTRNCMP(type, "SHA512", 6) == 0) {
            WOLFSSL_MSG("sha512 hmac");
            ctx->type = WC_SHA512;
        }
        else
#endif
#ifdef WOLFSSL_SHA3
    #ifndef WOLFSSL_NOSHA3_224
        if (XSTRNCMP(type, "SHA3_224", 8) == 0) {
            WOLFSSL_MSG("sha3_224 hmac");
            ctx->type = WC_SHA3_224;
        }
        else
    #endif
    #ifndef WOLFSSL_NOSHA3_256
        if (XSTRNCMP(type, "SHA3_256", 8) == 0) {
            WOLFSSL_MSG("sha3_256 hmac");
            ctx->type = WC_SHA3_256;
        }
        else
    #endif
        if (XSTRNCMP(type, "SHA3_384", 8) == 0) {
            WOLFSSL_MSG("sha3_384 hmac");
            ctx->type = WC_SHA3_384;
        }
        else
    #ifndef WOLFSSL_NOSHA3_512
        if (XSTRNCMP(type, "SHA3_512", 8) == 0) {
            WOLFSSL_MSG("sha3_512 hmac");
            ctx->type = WC_SHA3_512;
        }
        else
    #endif
#endif

#ifndef NO_SHA
        /* has to be last since would pick or 256, 384, or 512 too */
        if (XSTRNCMP(type, "SHA", 3) == 0) {
            WOLFSSL_MSG("sha hmac");
            ctx->type = WC_SHA;
        }
        else
#endif
        {
            WOLFSSL_MSG("bad init type");
            return WOLFSSL_FAILURE;
        }
    }

    /* Check if init has been called before */
    inited = (ctx->hmac.macType != WC_HASH_TYPE_NONE);
    /* Free if needed */
    if (inited) {
        wc_HmacFree(&ctx->hmac);
    }
    if (key != NULL) {
        WOLFSSL_MSG("keying hmac");

        if (wc_HmacInit(&ctx->hmac, NULL, INVALID_DEVID) == 0) {
            hmac_error = wc_HmacSetKey(&ctx->hmac, ctx->type, (const byte*)key,
                                       (word32)keylen);
            if (hmac_error < 0){
                /* in FIPS mode a key < 14 characters will fail here */
                WOLFSSL_MSG("hmac set key error");
                WOLFSSL_ERROR(hmac_error);
                wc_HmacFree(&ctx->hmac);
                return WOLFSSL_FAILURE;
            }
            XMEMCPY((byte *)&ctx->save_ipad, (byte *)&ctx->hmac.ipad,
                                        WC_HMAC_BLOCK_SIZE);
            XMEMCPY((byte *)&ctx->save_opad, (byte *)&ctx->hmac.opad,
                                        WC_HMAC_BLOCK_SIZE);
        }
        /* OpenSSL compat, no error */
    }
    else if (!inited) {
        return WOLFSSL_FAILURE;
    }
    else if (ctx->type >= 0) { /* MD5 == 0 */
        WOLFSSL_MSG("recover hmac");
        if (wc_HmacInit(&ctx->hmac, NULL, INVALID_DEVID) == 0) {
            ctx->hmac.macType = (byte)ctx->type;
            ctx->hmac.innerHashKeyed = 0;
            XMEMCPY((byte *)&ctx->hmac.ipad, (byte *)&ctx->save_ipad,
                                       WC_HMAC_BLOCK_SIZE);
            XMEMCPY((byte *)&ctx->hmac.opad, (byte *)&ctx->save_opad,
                                       WC_HMAC_BLOCK_SIZE);
            if ((hmac_error = _HMAC_Init(&ctx->hmac, ctx->hmac.macType, heap))
                    !=0) {
                WOLFSSL_MSG("hmac init error");
                WOLFSSL_ERROR(hmac_error);
                return WOLFSSL_FAILURE;
            }
        }
    }

    (void)hmac_error;

    return WOLFSSL_SUCCESS;
}


int wolfSSL_HMAC_Update(WOLFSSL_HMAC_CTX* ctx, const unsigned char* data,
                    int len)
{
    int hmac_error = 0;

    WOLFSSL_MSG("wolfSSL_HMAC_Update");

    if (ctx == NULL) {
        WOLFSSL_MSG("no ctx");
        return WOLFSSL_FAILURE;
    }

    if (data) {
        WOLFSSL_MSG("updating hmac");
        hmac_error = wc_HmacUpdate(&ctx->hmac, data, (word32)len);
        if (hmac_error < 0){
            WOLFSSL_MSG("hmac update error");
            return WOLFSSL_FAILURE;
        }
    }

    return WOLFSSL_SUCCESS;
}


int wolfSSL_HMAC_Final(WOLFSSL_HMAC_CTX* ctx, unsigned char* hash,
                   unsigned int* len)
{
    int hmac_error;

    WOLFSSL_MSG("wolfSSL_HMAC_Final");

    /* "len" parameter is optional. */
    if (ctx == NULL || hash == NULL) {
        WOLFSSL_MSG("invalid parameter");
        return WOLFSSL_FAILURE;
    }

    WOLFSSL_MSG("final hmac");
    hmac_error = wc_HmacFinal(&ctx->hmac, hash);
    if (hmac_error < 0){
        WOLFSSL_MSG("final hmac error");
        return WOLFSSL_FAILURE;
    }

    if (len) {
        WOLFSSL_MSG("setting output len");
        switch (ctx->type) {
            #ifndef NO_MD5
            case WC_MD5:
                *len = WC_MD5_DIGEST_SIZE;
                break;
            #endif

            #ifndef NO_SHA
            case WC_SHA:
                *len = WC_SHA_DIGEST_SIZE;
                break;
            #endif

            #ifdef WOLFSSL_SHA224
            case WC_SHA224:
                *len = WC_SHA224_DIGEST_SIZE;
                break;
            #endif

            #ifndef NO_SHA256
            case WC_SHA256:
                *len = WC_SHA256_DIGEST_SIZE;
                break;
            #endif

            #ifdef WOLFSSL_SHA384
            case WC_SHA384:
                *len = WC_SHA384_DIGEST_SIZE;
                break;
            #endif

            #ifdef WOLFSSL_SHA512
            case WC_SHA512:
                *len = WC_SHA512_DIGEST_SIZE;
                break;
            #endif

        #ifdef WOLFSSL_SHA3
            #ifndef WOLFSSL_NOSHA3_224
            case WC_SHA3_224:
                *len = WC_SHA3_224_DIGEST_SIZE;
                break;
            #endif
            #ifndef WOLFSSL_NOSHA3_256
            case WC_SHA3_256:
                *len = WC_SHA3_256_DIGEST_SIZE;
                break;
            #endif
            #ifndef WOLFSSL_NOSHA3_384
            case WC_SHA3_384:
                *len = WC_SHA3_384_DIGEST_SIZE;
                break;
            #endif
            #ifndef WOLFSSL_NOSHA3_512
            case WC_SHA3_512:
                *len = WC_SHA3_512_DIGEST_SIZE;
                break;
            #endif
        #endif

            default:
                WOLFSSL_MSG("bad hmac type");
                return WOLFSSL_FAILURE;
        }
    }

    return WOLFSSL_SUCCESS;
}


int wolfSSL_HMAC_cleanup(WOLFSSL_HMAC_CTX* ctx)
{
    WOLFSSL_MSG("wolfSSL_HMAC_cleanup");

    if (ctx) {
        wc_HmacFree(&ctx->hmac);
    }

    return WOLFSSL_SUCCESS;
}

void wolfSSL_HMAC_CTX_cleanup(WOLFSSL_HMAC_CTX* ctx)
{
    if (ctx) {
        wolfSSL_HMAC_cleanup(ctx);
    }
}

void wolfSSL_HMAC_CTX_free(WOLFSSL_HMAC_CTX* ctx)
{
    if (ctx) {
        wolfSSL_HMAC_CTX_cleanup(ctx);
        XFREE(ctx, NULL, DYNAMIC_TYPE_OPENSSL);
    }
}

size_t wolfSSL_HMAC_size(const WOLFSSL_HMAC_CTX *ctx)
{
    if (!ctx) {
        return 0;
    }

    return (size_t)wc_HashGetDigestSize((enum wc_HashType)ctx->hmac.macType);
}

const WOLFSSL_EVP_MD *wolfSSL_HMAC_CTX_get_md(const WOLFSSL_HMAC_CTX *ctx)
{
    if (!ctx) {
        return NULL;
    }

    return wolfSSL_macType2EVP_md((enum wc_HashType)ctx->type);
}

#if defined(WOLFSSL_CMAC) && defined(OPENSSL_EXTRA) && \
    defined(WOLFSSL_AES_DIRECT)
WOLFSSL_CMAC_CTX* wolfSSL_CMAC_CTX_new(void)
{
    WOLFSSL_CMAC_CTX* ctx = NULL;

    ctx = (WOLFSSL_CMAC_CTX*)XMALLOC(sizeof(WOLFSSL_CMAC_CTX), NULL,
                                     DYNAMIC_TYPE_OPENSSL);
    if (ctx != NULL) {
        ctx->internal = (Cmac*)XMALLOC(sizeof(Cmac), NULL, DYNAMIC_TYPE_CMAC);
        if (ctx->internal == NULL) {
            XFREE(ctx, NULL, DYNAMIC_TYPE_OPENSSL);
            ctx = NULL;
        }
    }
    if (ctx != NULL) {
        ctx->cctx = wolfSSL_EVP_CIPHER_CTX_new();
        if (ctx->cctx == NULL) {
            XFREE(ctx->internal, NULL, DYNAMIC_TYPE_CMAC);
            XFREE(ctx, NULL, DYNAMIC_TYPE_OPENSSL);
            ctx = NULL;
        }
    }

    return ctx;
}

void wolfSSL_CMAC_CTX_free(WOLFSSL_CMAC_CTX *ctx)
{
    if (ctx != NULL) {
        if (ctx->internal != NULL) {
            XFREE(ctx->internal, NULL, DYNAMIC_TYPE_CMAC);
        }
        if (ctx->cctx != NULL) {
            wolfSSL_EVP_CIPHER_CTX_free(ctx->cctx);
        }
        XFREE(ctx, NULL, DYNAMIC_TYPE_OPENSSL);
    }
}

WOLFSSL_EVP_CIPHER_CTX* wolfSSL_CMAC_CTX_get0_cipher_ctx(WOLFSSL_CMAC_CTX* ctx)
{
    WOLFSSL_EVP_CIPHER_CTX* cctx = NULL;

    if (ctx != NULL) {
        cctx = ctx->cctx;
    }

    return cctx;
}

int wolfSSL_CMAC_Init(WOLFSSL_CMAC_CTX* ctx, const void *key, size_t keyLen,
                      const WOLFSSL_EVP_CIPHER* cipher, WOLFSSL_ENGINE* engine)
{
    int ret = WOLFSSL_SUCCESS;

    (void)engine;

    WOLFSSL_ENTER("wolfSSL_CMAC_Init");

    if (ctx == NULL || cipher == NULL || (
            cipher != EVP_AES_128_CBC &&
            cipher != EVP_AES_192_CBC &&
            cipher != EVP_AES_256_CBC)) {
        ret = WOLFSSL_FAILURE;
    }

    if (ret == WOLFSSL_SUCCESS) {
        ret = wc_InitCmac((Cmac*)ctx->internal, (const byte*)key,
                          (word32)keyLen, WC_CMAC_AES, NULL);
        if (ret != 0) {
            ret = WOLFSSL_FAILURE;
        }
        else {
            ret = WOLFSSL_SUCCESS;
        }
    }
    if (ret == WOLFSSL_SUCCESS) {
        ret = wolfSSL_EVP_CipherInit(ctx->cctx, cipher, (const byte*)key, NULL,
                                     1);
    }

    WOLFSSL_LEAVE("wolfSSL_CMAC_Init", ret);

    return ret;
}

int wolfSSL_CMAC_Update(WOLFSSL_CMAC_CTX* ctx, const void* data, size_t len)
{
    int ret = WOLFSSL_SUCCESS;

    WOLFSSL_ENTER("wolfSSL_CMAC_Update");

    if (ctx == NULL || ctx->internal == NULL) {
        ret = WOLFSSL_FAILURE;
    }

    if (ret == WOLFSSL_SUCCESS) {
        if (data) {
            ret = wc_CmacUpdate((Cmac*)ctx->internal, (const byte*)data,
                                (word32)len);
            if (ret != 0){
                ret = WOLFSSL_FAILURE;
            }
            else {
                ret = WOLFSSL_SUCCESS;
            }
        }
    }

    WOLFSSL_LEAVE("wolfSSL_CMAC_Update", ret);

    return ret;
}

int wolfSSL_CMAC_Final(WOLFSSL_CMAC_CTX* ctx, unsigned char* out,
                       size_t* len)
{
    int ret = WOLFSSL_SUCCESS;
    int blockSize;

    WOLFSSL_ENTER("wolfSSL_CMAC_Final");

    if (ctx == NULL || ctx->cctx == NULL || ctx->internal == NULL ||
                                                                  len == NULL) {
        ret = WOLFSSL_FAILURE;
    }

    if (ret == WOLFSSL_SUCCESS) {
        blockSize = EVP_CIPHER_CTX_block_size(ctx->cctx);
        if (blockSize <= 0) {
            ret = WOLFSSL_FAILURE;
        }
        else {
            *len = blockSize;
        }
    }
    if (ret == WOLFSSL_SUCCESS) {
        word32 len32 = (word32)*len;

        ret = wc_CmacFinal((Cmac*)ctx->internal, out, &len32);
        *len = (size_t)len32;
        if (ret != 0) {
            ret = WOLFSSL_FAILURE;
        }
        else {
            ret = WOLFSSL_SUCCESS;
        }
    }

    WOLFSSL_LEAVE("wolfSSL_CMAC_Final", ret);

    return ret;
}
#endif /* WOLFSSL_CMAC && OPENSSL_EXTRA && WOLFSSL_AES_DIRECT */
#endif /* OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
/* Free the dynamically allocated data.
 *
 * p  Pointer to dynamically allocated memory.
 */
void wolfSSL_OPENSSL_free(void* p)
{
    WOLFSSL_MSG("wolfSSL_OPENSSL_free");

    XFREE(p, NULL, DYNAMIC_TYPE_OPENSSL);
}
#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL */

#ifdef OPENSSL_EXTRA

void *wolfSSL_OPENSSL_malloc(size_t a)
{
    return (void *)XMALLOC(a, NULL, DYNAMIC_TYPE_OPENSSL);
}

int wolfSSL_OPENSSL_hexchar2int(unsigned char c)
{
    /* 'char' is unsigned on some platforms. */
    return (int)(signed char)HexCharToByte((char)c);
}

unsigned char *wolfSSL_OPENSSL_hexstr2buf(const char *str, long *len)
{
    unsigned char* targetBuf;
    int srcDigitHigh = 0;
    int srcDigitLow = 0;
    size_t srcLen;
    size_t srcIdx = 0;
    long targetIdx = 0;

    srcLen = XSTRLEN(str);
    targetBuf = (unsigned char*)XMALLOC(srcLen / 2, NULL, DYNAMIC_TYPE_OPENSSL);
    if (targetBuf == NULL) {
        return NULL;
    }

    while (srcIdx < srcLen) {
        if (str[srcIdx] == ':') {
            srcIdx++;
            continue;
        }

        srcDigitHigh = wolfSSL_OPENSSL_hexchar2int(str[srcIdx++]);
        srcDigitLow = wolfSSL_OPENSSL_hexchar2int(str[srcIdx++]);
        if (srcDigitHigh < 0 || srcDigitLow < 0) {
            WOLFSSL_MSG("Invalid hex character.");
            XFREE(targetBuf, NULL, DYNAMIC_TYPE_OPENSSL);
            return NULL;
        }

        targetBuf[targetIdx++] = (unsigned char)((srcDigitHigh << 4) | srcDigitLow);
    }

    if (len != NULL)
        *len = targetIdx;

    return targetBuf;
}

int wolfSSL_OPENSSL_init_ssl(word64 opts, const OPENSSL_INIT_SETTINGS *settings)
{
    (void)opts;
    (void)settings;
    return wolfSSL_library_init();
}

int wolfSSL_OPENSSL_init_crypto(word64 opts, const OPENSSL_INIT_SETTINGS* settings)
{
    (void)opts;
    (void)settings;
    return wolfSSL_library_init();
}

#if defined(WOLFSSL_KEY_GEN) && defined(WOLFSSL_PEM_TO_DER)

int EncryptDerKey(byte *der, int *derSz, const EVP_CIPHER* cipher,
                  unsigned char* passwd, int passwdSz, byte **cipherInfo,
                  int maxDerSz)
{
    int ret, paddingSz;
    word32 idx, cipherInfoSz;
#ifdef WOLFSSL_SMALL_STACK
    EncryptedInfo* info = NULL;
#else
    EncryptedInfo  info[1];
#endif

    WOLFSSL_ENTER("EncryptDerKey");

    if (der == NULL || derSz == NULL || cipher == NULL ||
        passwd == NULL || cipherInfo == NULL)
        return BAD_FUNC_ARG;

#ifdef WOLFSSL_SMALL_STACK
    info = (EncryptedInfo*)XMALLOC(sizeof(EncryptedInfo), NULL,
                                   DYNAMIC_TYPE_ENCRYPTEDINFO);
    if (info == NULL) {
        WOLFSSL_MSG("malloc failed");
        return WOLFSSL_FAILURE;
    }
#endif

    XMEMSET(info, 0, sizeof(EncryptedInfo));

    /* set the cipher name on info */
    XSTRNCPY(info->name, cipher, NAME_SZ-1);
    info->name[NAME_SZ-1] = '\0'; /* null term */

    ret = wc_EncryptedInfoGet(info, info->name);
    if (ret != 0) {
        WOLFSSL_MSG("unsupported cipher");
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(info, NULL, DYNAMIC_TYPE_ENCRYPTEDINFO);
    #endif
        return WOLFSSL_FAILURE;
    }

    /* Generate a random salt */
    if (wolfSSL_RAND_bytes(info->iv, info->ivSz) != WOLFSSL_SUCCESS) {
        WOLFSSL_MSG("generate iv failed");
#ifdef WOLFSSL_SMALL_STACK
        XFREE(info, NULL, DYNAMIC_TYPE_ENCRYPTEDINFO);
#endif
        return WOLFSSL_FAILURE;
    }

    /* add the padding before encryption */
    paddingSz = ((*derSz)/info->ivSz + 1) * info->ivSz - (*derSz);
    if (paddingSz == 0)
        paddingSz = info->ivSz;
    if (maxDerSz < *derSz + paddingSz) {
        WOLFSSL_MSG("not enough DER buffer allocated");
#ifdef WOLFSSL_SMALL_STACK
        XFREE(info, NULL, DYNAMIC_TYPE_ENCRYPTEDINFO);
#endif
        return WOLFSSL_FAILURE;
    }
    XMEMSET(der+(*derSz), (byte)paddingSz, paddingSz);
    (*derSz) += paddingSz;

    /* encrypt buffer */
    if (wc_BufferKeyEncrypt(info, der, *derSz, passwd, passwdSz, WC_MD5) != 0) {
        WOLFSSL_MSG("encrypt key failed");
#ifdef WOLFSSL_SMALL_STACK
        XFREE(info, NULL, DYNAMIC_TYPE_ENCRYPTEDINFO);
#endif
        return WOLFSSL_FAILURE;
    }

    /* create cipher info : 'cipher_name,Salt(hex)' */
    cipherInfoSz = (word32)(2*info->ivSz + XSTRLEN(info->name) + 2);
    *cipherInfo = (byte*)XMALLOC(cipherInfoSz, NULL,
                                DYNAMIC_TYPE_STRING);
    if (*cipherInfo == NULL) {
        WOLFSSL_MSG("malloc failed");
#ifdef WOLFSSL_SMALL_STACK
        XFREE(info, NULL, DYNAMIC_TYPE_ENCRYPTEDINFO);
#endif
        return WOLFSSL_FAILURE;
    }
    XSTRLCPY((char*)*cipherInfo, info->name, cipherInfoSz);
    XSTRLCAT((char*)*cipherInfo, ",", cipherInfoSz);

    idx = (word32)XSTRLEN((char*)*cipherInfo);
    cipherInfoSz -= idx;
    ret = Base16_Encode(info->iv, info->ivSz, *cipherInfo+idx, &cipherInfoSz);

#ifdef WOLFSSL_SMALL_STACK
    XFREE(info, NULL, DYNAMIC_TYPE_ENCRYPTEDINFO);
#endif
    if (ret != 0) {
        WOLFSSL_MSG("Base16_Encode failed");
        XFREE(*cipherInfo, NULL, DYNAMIC_TYPE_STRING);
        return WOLFSSL_FAILURE;
    }

    return WOLFSSL_SUCCESS;
}
#endif /* WOLFSSL_KEY_GEN || WOLFSSL_PEM_TO_DER */

#if !defined(NO_BIO)
static int pem_write_pubkey(WOLFSSL_EVP_PKEY* key, void* heap, byte** derBuf,
    int* derSz)
{
    byte* buf = NULL;
    int sz = 0;

    (void)heap;

    if (key == NULL) {
        WOLFSSL_MSG("Bad parameters");
        return WOLFSSL_FAILURE;
    }

    switch (key->type) {
#if defined(WOLFSSL_KEY_GEN) && !defined(NO_RSA) && !defined(HAVE_USER_RSA)
        case EVP_PKEY_RSA:
            if ((sz = wolfSSL_RSA_To_Der(key->rsa, &buf, 1, heap))
                    < 0) {
                WOLFSSL_MSG("wolfSSL_RSA_To_Der failed");
                break;
            }
            break;
#endif /* WOLFSSL_KEY_GEN && !NO_RSA && !HAVE_USER_RSA */
#if !defined(NO_DSA) && !defined(HAVE_SELFTEST) && (defined(WOLFSSL_KEY_GEN) || \
        defined(WOLFSSL_CERT_GEN))
        case EVP_PKEY_DSA:
            if (key->dsa == NULL) {
                WOLFSSL_MSG("key->dsa is null");
                break;
            }
            sz = MAX_DSA_PUBKEY_SZ;
            buf = (byte*)XMALLOC(sz, heap, DYNAMIC_TYPE_TMP_BUFFER);
            if (buf == NULL) {
                WOLFSSL_MSG("malloc failed");
                break;
            }
            /* Key to DER */
            sz = wc_DsaKeyToPublicDer((DsaKey*)key->dsa->internal, buf, sz);
            if (sz < 0) {
                WOLFSSL_MSG("wc_DsaKeyToDer failed");
                break;
            }
            break;
#endif /* !NO_DSA && !HAVE_SELFTEST && (WOLFSSL_KEY_GEN || WOLFSSL_CERT_GEN) */
#if defined(HAVE_ECC) && defined(HAVE_ECC_KEY_EXPORT)
        case EVP_PKEY_EC:
        {
            if (key->ecc == NULL) {
                WOLFSSL_MSG("key->ecc is null");
                break;
            }
            sz = wc_EccPublicKeyDerSize((ecc_key*)key->ecc->internal, 1);
            if (sz <= 0) {
                WOLFSSL_MSG("wc_EccPublicKeyDerSize failed");
                break;
            }
            buf = (byte*)XMALLOC(sz, heap, DYNAMIC_TYPE_TMP_BUFFER);
            if (buf == NULL) {
                WOLFSSL_MSG("malloc failed");
                break;
            }
            sz = wc_EccPublicKeyToDer((ecc_key*)key->ecc->internal, buf, sz, 1);
            if (sz < 0) {
                WOLFSSL_MSG("wc_EccPublicKeyToDer failed");
                break;
            }
            break;
        }
#endif /* HAVE_ECC && HAVE_ECC_KEY_EXPORT */
#if !defined(NO_DH) && (defined(WOLFSSL_QT) || defined(OPENSSL_ALL))
        case EVP_PKEY_DH:
            WOLFSSL_MSG("Writing DH PUBKEY not supported!");
            break;
#endif /* !NO_DH && (WOLFSSL_QT || OPENSSL_ALL) */
        default:
            WOLFSSL_MSG("Unknown Key type!");
            break;
    }

    if (buf == NULL || sz <= 0) {
        if (buf != NULL)
            XFREE(buf, heap, DYNAMIC_TYPE_DER);
        return WOLFSSL_FAILURE;
    }

    *derBuf = buf;
    *derSz = sz;
    return WOLFSSL_SUCCESS;
}
#endif

#ifndef NO_BIO
static int pem_write_bio_pubkey(WOLFSSL_BIO* bio, WOLFSSL_EVP_PKEY* key)
{
    int ret;
    int derSz = 0;
    byte* derBuf = NULL;

    ret = pem_write_pubkey(key, bio->heap, &derBuf, &derSz);
    if (ret == WOLFSSL_SUCCESS) {
        ret = der_write_to_bio_as_pem(derBuf, derSz, bio, PUBLICKEY_TYPE);
        XFREE(derBuf, bio->heap, DYNAMIC_TYPE_DER);
    }

    return ret;
}

/* Takes a public key and writes it out to a WOLFSSL_BIO
 * Returns WOLFSSL_SUCCESS or WOLFSSL_FAILURE
 */
int wolfSSL_PEM_write_bio_PUBKEY(WOLFSSL_BIO* bio, WOLFSSL_EVP_PKEY* key)
{
    int ret;

    WOLFSSL_ENTER("wolfSSL_PEM_write_bio_PUBKEY");

    if ((bio == NULL) || (key == NULL)) {
        ret = WOLFSSL_FAILURE;
    }
    else {
        ret = pem_write_bio_pubkey(bio, key);
    }

    return ret;
}

/* Takes a private key and writes it out to a WOLFSSL_BIO
 * Returns WOLFSSL_SUCCESS or WOLFSSL_FAILURE
 */
int wolfSSL_PEM_write_bio_PrivateKey(WOLFSSL_BIO* bio, WOLFSSL_EVP_PKEY* key,
                                     const WOLFSSL_EVP_CIPHER* cipher,
                                     unsigned char* passwd, int len,
                                     wc_pem_password_cb* cb, void* arg)
{
    byte* keyDer;
    int type;

    (void)cipher;
    (void)passwd;
    (void)len;
    (void)cb;
    (void)arg;

    WOLFSSL_ENTER("wolfSSL_PEM_write_bio_PrivateKey");

    if (bio == NULL || key == NULL) {
        WOLFSSL_MSG("Bad Function Arguments");
        return WOLFSSL_FAILURE;
    }

    keyDer = (byte*)key->pkey.ptr;

    switch (key->type) {
#ifndef NO_RSA
        case EVP_PKEY_RSA:
            type = PRIVATEKEY_TYPE;
            break;
#endif

#ifndef NO_DSA
        case EVP_PKEY_DSA:
            type = DSA_PRIVATEKEY_TYPE;
            break;
#endif

#ifdef HAVE_ECC
        case EVP_PKEY_EC:
            type = ECC_PRIVATEKEY_TYPE;
            break;
#endif

#if !defined(NO_DH) && (defined(WOLFSSL_QT) || defined(OPENSSL_ALL))
        case EVP_PKEY_DH:
            type = DH_PRIVATEKEY_TYPE;
            break;
#endif

        default:
            WOLFSSL_MSG("Unknown Key type!");
            type = PRIVATEKEY_TYPE;
    }

    return der_write_to_bio_as_pem(keyDer, key->pkey_sz, bio, type);
}
#endif /* !NO_BIO */

/* Colon separated list of <public key>+<digest> algorithms.
 * Replaces list in context.
 */
int wolfSSL_CTX_set1_sigalgs_list(WOLFSSL_CTX* ctx, const char* list)
{
    WOLFSSL_MSG("wolfSSL_CTX_set1_sigalg_list");

    if (ctx == NULL || list == NULL) {
        WOLFSSL_MSG("Bad function arguments");
        return WOLFSSL_FAILURE;
    }

    /* alloc/init on demand only */
    if (ctx->suites == NULL) {
        ctx->suites = (Suites*)XMALLOC(sizeof(Suites), ctx->heap,
                                       DYNAMIC_TYPE_SUITES);
        if (ctx->suites == NULL) {
            WOLFSSL_MSG("Memory alloc for Suites failed");
            return WOLFSSL_FAILURE;
        }
        XMEMSET(ctx->suites, 0, sizeof(Suites));
    }

    return SetSuitesHashSigAlgo(ctx->suites, list);
}

/* Colon separated list of <public key>+<digest> algorithms.
 * Replaces list in SSL.
 */
int wolfSSL_set1_sigalgs_list(WOLFSSL* ssl, const char* list)
{
    WOLFSSL_MSG("wolfSSL_set1_sigalg_list");

    if (ssl == NULL) {
        WOLFSSL_MSG("Bad function arguments");
        return WOLFSSL_FAILURE;
    }

#ifdef SINGLE_THREADED
    if (ssl->ctx->suites == ssl->suites) {
        ssl->suites = (Suites*)XMALLOC(sizeof(Suites), ssl->heap,
                                       DYNAMIC_TYPE_SUITES);
        if (ssl->suites == NULL) {
            WOLFSSL_MSG("Suites Memory error");
            return MEMORY_E;
        }
        *ssl->suites = *ssl->ctx->suites;
        ssl->options.ownSuites = 1;
    }
#endif
    if (ssl == NULL || list == NULL) {
        WOLFSSL_MSG("Bad function arguments");
        return WOLFSSL_FAILURE;
    }

    return SetSuitesHashSigAlgo(ssl->suites, list);
}

struct WOLFSSL_HashSigInfo {
    int hashAlgo;
    int sigAlgo;
    int nid;
}  wolfssl_hash_sig_info[] =
{
#ifndef NO_RSA
    #ifndef NO_SHA256
        { sha256_mac, rsa_sa_algo, CTC_SHA256wRSA },
    #endif
    #ifdef WOLFSSL_SHA384
        { sha384_mac, rsa_sa_algo, CTC_SHA384wRSA },
    #endif
    #ifdef WOLFSSL_SHA512
        { sha512_mac, rsa_sa_algo, CTC_SHA512wRSA },
    #endif
    #ifdef WOLFSSL_SHA224
        { sha224_mac, rsa_sa_algo, CTC_SHA224wRSA },
    #endif
    #ifndef NO_SHA
        { sha_mac,    rsa_sa_algo, CTC_SHAwRSA },
    #endif
    #ifdef WC_RSA_PSS
        #ifndef NO_SHA256
            { sha256_mac, rsa_pss_sa_algo, CTC_SHA256wRSA },
        #endif
        #ifdef WOLFSSL_SHA384
            { sha384_mac, rsa_pss_sa_algo, CTC_SHA384wRSA },
        #endif
        #ifdef WOLFSSL_SHA512
            { sha512_mac, rsa_pss_sa_algo, CTC_SHA512wRSA },
        #endif
        #ifdef WOLFSSL_SHA224
            { sha224_mac, rsa_pss_sa_algo, CTC_SHA224wRSA },
        #endif
    #endif
#endif
#ifdef HAVE_ECC
    #ifndef NO_SHA256
        { sha256_mac, ecc_dsa_sa_algo, CTC_SHA256wECDSA },
    #endif
    #ifdef WOLFSSL_SHA384
        { sha384_mac, ecc_dsa_sa_algo, CTC_SHA384wECDSA },
    #endif
    #ifdef WOLFSSL_SHA512
        { sha512_mac, ecc_dsa_sa_algo, CTC_SHA512wECDSA },
    #endif
    #ifdef WOLFSSL_SHA224
        { sha224_mac, ecc_dsa_sa_algo, CTC_SHA224wECDSA },
    #endif
    #ifndef NO_SHA
        { sha_mac,    ecc_dsa_sa_algo, CTC_SHAwECDSA },
    #endif
#endif
#ifdef HAVE_ED25519
    { no_mac, ed25519_sa_algo, CTC_ED25519 },
#endif
#ifdef HAVE_ED448
    { no_mac, ed448_sa_algo, CTC_ED448 },
#endif
#ifdef HAVE_PQC
#ifdef HAVE_FALCON
    { no_mac, falcon_level1_sa_algo, CTC_FALCON_LEVEL1 },
    { no_mac, falcon_level5_sa_algo, CTC_FALCON_LEVEL5 },
#endif /* HAVE_FALCON */
#ifdef HAVE_DILITHIUM
    { no_mac, dilithium_level2_sa_algo, CTC_DILITHIUM_LEVEL2 },
    { no_mac, dilithium_level3_sa_algo, CTC_DILITHIUM_LEVEL3 },
    { no_mac, dilithium_level5_sa_algo, CTC_DILITHIUM_LEVEL5 },
#endif /* HAVE_DILITHIUM */
#endif /* HAVE_PQC */
#ifndef NO_DSA
    #ifndef NO_SHA
        { sha_mac,    dsa_sa_algo, CTC_SHAwDSA },
    #endif
#endif
};
#define WOLFSSL_HASH_SIG_INFO_SZ \
    (int)(sizeof(wolfssl_hash_sig_info)/sizeof(*wolfssl_hash_sig_info))

int wolfSSL_get_signature_nid(WOLFSSL *ssl, int* nid)
{
    int i;
    int ret = WOLFSSL_FAILURE;

    WOLFSSL_MSG("wolfSSL_get_signature_nid");

    if (ssl == NULL) {
        WOLFSSL_MSG("Bad function arguments");
        return WOLFSSL_FAILURE;
    }

    for (i = 0; i < WOLFSSL_HASH_SIG_INFO_SZ; i++) {
        if (ssl->suites->hashAlgo == wolfssl_hash_sig_info[i].hashAlgo &&
                     ssl->suites->sigAlgo == wolfssl_hash_sig_info[i].sigAlgo) {
            *nid = wolfssl_hash_sig_info[i].nid;
            ret = WOLFSSL_SUCCESS;
            break;
        }
    }

    return ret;
}

#ifdef HAVE_ECC

#if defined(WOLFSSL_TLS13) && defined(HAVE_SUPPORTED_CURVES)
static int populate_groups(int* groups, int max_count, char *list)
{
    char *end;
    int len;
    int count = 0;
    const WOLF_EC_NIST_NAME* nist_name;

    if (!groups || !list) {
        return -1;
    }

    for (end = list; ; list = ++end) {
        if (count > max_count) {
            WOLFSSL_MSG("Too many curves in list");
            return -1;
        }
        while (*end != ':' && *end != '\0') end++;
        len = (int)(end - list); /* end points to char after end
                                  * of curve name so no need for -1 */
        if ((len < kNistCurves_MIN_NAME_LEN) ||
                (len > kNistCurves_MAX_NAME_LEN)) {
            WOLFSSL_MSG("Unrecognized curve name in list");
            return -1;
        }
        for (nist_name = kNistCurves; nist_name->name != NULL; nist_name++) {
            if (len == nist_name->name_len &&
                    XSTRNCMP(list, nist_name->name, nist_name->name_len) == 0) {
                break;
            }
        }
        if (!nist_name->name) {
            WOLFSSL_MSG("Unrecognized curve name in list");
            return -1;
        }
        groups[count++] = nist_name->nid;
        if (*end == '\0') break;
    }

    return count;
}

int wolfSSL_CTX_set1_groups_list(WOLFSSL_CTX *ctx, char *list)
{
    int groups[WOLFSSL_MAX_GROUP_COUNT];
    int count;

    if (!ctx || !list) {
        return WOLFSSL_FAILURE;
    }

    if ((count = populate_groups(groups,
            WOLFSSL_MAX_GROUP_COUNT, list)) == -1) {
        return WOLFSSL_FAILURE;
    }

    return wolfSSL_CTX_set1_groups(ctx, groups, count);
}

int wolfSSL_set1_groups_list(WOLFSSL *ssl, char *list)
{
    int groups[WOLFSSL_MAX_GROUP_COUNT];
    int count;

    if (!ssl || !list) {
        return WOLFSSL_FAILURE;
    }

    if ((count = populate_groups(groups,
            WOLFSSL_MAX_GROUP_COUNT, list)) == -1) {
        return WOLFSSL_FAILURE;
    }

    return wolfSSL_set1_groups(ssl, groups, count);
}
#endif /* WOLFSSL_TLS13 */

#endif /* HAVE_ECC */

#ifndef NO_BIO
WOLFSSL_EVP_PKEY* wolfSSL_PEM_read_bio_PrivateKey(WOLFSSL_BIO* bio,
                                                  WOLFSSL_EVP_PKEY** key,
                                                  wc_pem_password_cb* cb,
                                                  void* pass)
{
    WOLFSSL_EVP_PKEY* pkey = NULL;
    DerBuffer*         der = NULL;
    int             keyFormat = 0;
    int                 type = -1;

    WOLFSSL_ENTER("wolfSSL_PEM_read_bio_PrivateKey");

    if (bio == NULL)
        return pkey;

    if (pem_read_bio_key(bio, cb, pass, PRIVATEKEY_TYPE, &keyFormat, &der)
            >= 0) {
        const unsigned char* ptr = der->buffer;

        if (keyFormat) {
            /* keyFormat is Key_Sum enum */
            if (keyFormat == RSAk)
                type = EVP_PKEY_RSA;
            else if (keyFormat == ECDSAk)
                type = EVP_PKEY_EC;
            else if (keyFormat == DSAk)
                type = EVP_PKEY_DSA;
            else if (keyFormat == DHk)
                type = EVP_PKEY_DH;
        }
        else {
            /* Default to RSA if format is not set */
            type = EVP_PKEY_RSA;
        }

        /* handle case where reuse is attempted */
        if (key != NULL && *key != NULL)
            pkey = *key;

        wolfSSL_d2i_PrivateKey(type, &pkey, &ptr, der->length);
        if (pkey == NULL) {
            WOLFSSL_MSG("Error loading DER buffer into WOLFSSL_EVP_PKEY");
        }
    }

    FreeDer(&der);

    if (key != NULL && pkey != NULL)
        *key = pkey;

    WOLFSSL_LEAVE("wolfSSL_PEM_read_bio_PrivateKey", 0);

    return pkey;
}

WOLFSSL_EVP_PKEY *wolfSSL_PEM_read_bio_PUBKEY(WOLFSSL_BIO* bio,
                                              WOLFSSL_EVP_PKEY **key,
                                              wc_pem_password_cb *cb,
                                              void *pass)
{
    WOLFSSL_EVP_PKEY* pkey = NULL;
    DerBuffer*        der = NULL;
    int               keyFormat = 0;

    WOLFSSL_ENTER("wolfSSL_PEM_read_bio_PUBKEY");

    if (bio == NULL)
        return pkey;

    if (pem_read_bio_key(bio, cb, pass, PUBLICKEY_TYPE, &keyFormat, &der)
            >= 0) {
        const unsigned char* ptr = der->buffer;

        /* handle case where reuse is attempted */
        if (key != NULL && *key != NULL)
            pkey = *key;

        wolfSSL_d2i_PUBKEY(&pkey, &ptr, der->length);
        if (pkey == NULL) {
            WOLFSSL_MSG("Error loading DER buffer into WOLFSSL_EVP_PKEY");
        }
    }

    FreeDer(&der);

    if (key != NULL && pkey != NULL)
        *key = pkey;

    WOLFSSL_LEAVE("wolfSSL_PEM_read_bio_PUBKEY", 0);

    return pkey;
}
#endif /* !NO_BIO */

#if !defined(NO_FILESYSTEM)
WOLFSSL_EVP_PKEY *wolfSSL_PEM_read_PUBKEY(XFILE fp, WOLFSSL_EVP_PKEY **key,
                                          wc_pem_password_cb *cb, void *pass)
{
    WOLFSSL_EVP_PKEY* pkey = NULL;
    DerBuffer*        der = NULL;
    int               keyFormat = 0;

    WOLFSSL_ENTER("wolfSSL_PEM_read_bio_PUBKEY");

    if (pem_read_file_key(fp, cb, pass, PUBLICKEY_TYPE, &keyFormat, &der)
            >= 0) {
        const unsigned char* ptr = der->buffer;

        /* handle case where reuse is attempted */
        if (key != NULL && *key != NULL)
            pkey = *key;

        wolfSSL_d2i_PUBKEY(&pkey, &ptr, der->length);
        if (pkey == NULL) {
            WOLFSSL_MSG("Error loading DER buffer into WOLFSSL_EVP_PKEY");
        }
    }

    FreeDer(&der);

    if (key != NULL && pkey != NULL)
        *key = pkey;

    WOLFSSL_LEAVE("wolfSSL_PEM_read_bio_PUBKEY", 0);

    return pkey;
}
#endif /* NO_FILESYSTEM */
#endif /* OPENSSL_EXTRA */

#ifdef WOLFSSL_ALT_CERT_CHAINS
int wolfSSL_is_peer_alt_cert_chain(const WOLFSSL* ssl)
{
    int isUsing = 0;
    if (ssl)
        isUsing = ssl->options.usingAltCertChain;
    return isUsing;
}
#endif /* WOLFSSL_ALT_CERT_CHAINS */


#ifdef SESSION_CERTS

#ifdef WOLFSSL_ALT_CERT_CHAINS
/* Get peer's alternate certificate chain */
WOLFSSL_X509_CHAIN* wolfSSL_get_peer_alt_chain(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_get_peer_alt_chain");
    if (ssl)
        return &ssl->session->altChain;

    return 0;
}
#endif /* WOLFSSL_ALT_CERT_CHAINS */


/* Get peer's certificate chain */
WOLFSSL_X509_CHAIN* wolfSSL_get_peer_chain(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_get_peer_chain");
    if (ssl)
        return &ssl->session->chain;

    return 0;
}


/* Get peer's certificate chain total count */
int wolfSSL_get_chain_count(WOLFSSL_X509_CHAIN* chain)
{
    WOLFSSL_ENTER("wolfSSL_get_chain_count");
    if (chain)
        return chain->count;

    return 0;
}


/* Get peer's ASN.1 DER certificate at index (idx) length in bytes */
int wolfSSL_get_chain_length(WOLFSSL_X509_CHAIN* chain, int idx)
{
    WOLFSSL_ENTER("wolfSSL_get_chain_length");
    if (chain)
        return chain->certs[idx].length;

    return 0;
}


/* Get peer's ASN.1 DER certificate at index (idx) */
byte* wolfSSL_get_chain_cert(WOLFSSL_X509_CHAIN* chain, int idx)
{
    WOLFSSL_ENTER("wolfSSL_get_chain_cert");
    if (chain)
        return chain->certs[idx].buffer;

    return 0;
}


/* Get peer's wolfSSL X509 certificate at index (idx) */
WOLFSSL_X509* wolfSSL_get_chain_X509(WOLFSSL_X509_CHAIN* chain, int idx)
{
    int          ret;
    WOLFSSL_X509* x509 = NULL;
#ifdef WOLFSSL_SMALL_STACK
    DecodedCert* cert = NULL;
#else
    DecodedCert  cert[1];
#endif

    WOLFSSL_ENTER("wolfSSL_get_chain_X509");
    if (chain != NULL) {
    #ifdef WOLFSSL_SMALL_STACK
        cert = (DecodedCert*)XMALLOC(sizeof(DecodedCert), NULL,
                                                       DYNAMIC_TYPE_DCERT);
        if (cert != NULL)
    #endif
        {
            InitDecodedCert(cert, chain->certs[idx].buffer,
                                  chain->certs[idx].length, NULL);

            if ((ret = ParseCertRelative(cert, CERT_TYPE, 0, NULL)) != 0) {
                WOLFSSL_MSG("Failed to parse cert");
            }
            else {
                x509 = (WOLFSSL_X509*)XMALLOC(sizeof(WOLFSSL_X509), NULL,
                                                             DYNAMIC_TYPE_X509);
                if (x509 == NULL) {
                    WOLFSSL_MSG("Failed alloc X509");
                }
                else {
                    InitX509(x509, 1, NULL);

                    if ((ret = CopyDecodedToX509(x509, cert)) != 0) {
                        WOLFSSL_MSG("Failed to copy decoded");
                        wolfSSL_X509_free(x509);
                        x509 = NULL;
                    }
                }
            }

            FreeDecodedCert(cert);
        #ifdef WOLFSSL_SMALL_STACK
            XFREE(cert, NULL, DYNAMIC_TYPE_DCERT);
        #endif
        }
    }
    (void)ret;

    return x509;
}


/* Get peer's PEM certificate at index (idx), output to buffer if inLen big
   enough else return error (-1). If buffer is NULL only calculate
   outLen. Output length is in *outLen WOLFSSL_SUCCESS on ok */
int  wolfSSL_get_chain_cert_pem(WOLFSSL_X509_CHAIN* chain, int idx,
                               unsigned char* buf, int inLen, int* outLen)
{
#if defined(WOLFSSL_PEM_TO_DER) || defined(WOLFSSL_DER_TO_PEM)
    const char* header = NULL;
    const char* footer = NULL;
    int headerLen;
    int footerLen;
    int i;
    int err;
    word32 szNeeded = 0;

    WOLFSSL_ENTER("wolfSSL_get_chain_cert_pem");
    if (!chain || !outLen || idx < 0 || idx >= wolfSSL_get_chain_count(chain))
        return BAD_FUNC_ARG;

    err = wc_PemGetHeaderFooter(CERT_TYPE, &header, &footer);
    if (err != 0)
        return err;

    headerLen = (int)XSTRLEN(header);
    footerLen = (int)XSTRLEN(footer);

    /* Null output buffer return size needed in outLen */
    if(!buf) {
        if(Base64_Encode(chain->certs[idx].buffer, chain->certs[idx].length,
                    NULL, &szNeeded) != LENGTH_ONLY_E)
            return WOLFSSL_FAILURE;
        *outLen = szNeeded + headerLen + footerLen;
        return LENGTH_ONLY_E;
    }

    /* don't even try if inLen too short */
    if (inLen < headerLen + footerLen + chain->certs[idx].length)
        return BAD_FUNC_ARG;

    /* header */
    if (XMEMCPY(buf, header, headerLen) == NULL)
        return WOLFSSL_FATAL_ERROR;

    i = headerLen;

    /* body */
    *outLen = inLen;  /* input to Base64_Encode */
    if ( (err = Base64_Encode(chain->certs[idx].buffer,
                       chain->certs[idx].length, buf + i, (word32*)outLen)) < 0)
        return err;
    i += *outLen;

    /* footer */
    if ( (i + footerLen) > inLen)
        return BAD_FUNC_ARG;
    if (XMEMCPY(buf + i, footer, footerLen) == NULL)
        return WOLFSSL_FATAL_ERROR;
    *outLen += headerLen + footerLen;

    return WOLFSSL_SUCCESS;
#else
    (void)chain;
    (void)idx;
    (void)buf;
    (void)inLen;
    (void)outLen;
    return WOLFSSL_FAILURE;
#endif /* WOLFSSL_PEM_TO_DER || WOLFSSL_DER_TO_PEM */
}


/* get session ID */
WOLFSSL_ABI
const byte* wolfSSL_get_sessionID(const WOLFSSL_SESSION* session)
{
    WOLFSSL_ENTER("wolfSSL_get_sessionID");
    session = ClientSessionToSession(session);
    if (session)
        return session->sessionID;

    return NULL;
}


#endif /* SESSION_CERTS */

#ifdef HAVE_FUZZER
void wolfSSL_SetFuzzerCb(WOLFSSL* ssl, CallbackFuzzer cbf, void* fCtx)
{
    if (ssl) {
        ssl->fuzzerCb  = cbf;
        ssl->fuzzerCtx = fCtx;
    }
}
#endif

#ifndef NO_CERTS
#ifdef  HAVE_PK_CALLBACKS

#ifdef HAVE_ECC
void  wolfSSL_CTX_SetEccKeyGenCb(WOLFSSL_CTX* ctx, CallbackEccKeyGen cb)
{
    if (ctx)
        ctx->EccKeyGenCb = cb;
}
void  wolfSSL_SetEccKeyGenCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->EccKeyGenCtx = ctx;
}
void* wolfSSL_GetEccKeyGenCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->EccKeyGenCtx;

    return NULL;
}
void  wolfSSL_CTX_SetEccSignCtx(WOLFSSL_CTX* ctx, void *userCtx)
{
    if (ctx)
        ctx->EccSignCtx = userCtx;
}
void* wolfSSL_CTX_GetEccSignCtx(WOLFSSL_CTX* ctx)
{
    if (ctx)
        return ctx->EccSignCtx;

    return NULL;
}

WOLFSSL_ABI
void  wolfSSL_CTX_SetEccSignCb(WOLFSSL_CTX* ctx, CallbackEccSign cb)
{
    if (ctx)
        ctx->EccSignCb = cb;
}
void  wolfSSL_SetEccSignCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->EccSignCtx = ctx;
}
void* wolfSSL_GetEccSignCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->EccSignCtx;

    return NULL;
}

void  wolfSSL_CTX_SetEccVerifyCb(WOLFSSL_CTX* ctx, CallbackEccVerify cb)
{
    if (ctx)
        ctx->EccVerifyCb = cb;
}
void  wolfSSL_SetEccVerifyCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->EccVerifyCtx = ctx;
}
void* wolfSSL_GetEccVerifyCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->EccVerifyCtx;

    return NULL;
}

void wolfSSL_CTX_SetEccSharedSecretCb(WOLFSSL_CTX* ctx, CallbackEccSharedSecret cb)
{
    if (ctx)
        ctx->EccSharedSecretCb = cb;
}
void  wolfSSL_SetEccSharedSecretCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->EccSharedSecretCtx = ctx;
}
void* wolfSSL_GetEccSharedSecretCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->EccSharedSecretCtx;

    return NULL;
}
#endif /* HAVE_ECC */

#ifdef HAVE_ED25519
void  wolfSSL_CTX_SetEd25519SignCb(WOLFSSL_CTX* ctx, CallbackEd25519Sign cb)
{
    if (ctx)
        ctx->Ed25519SignCb = cb;
}
void  wolfSSL_SetEd25519SignCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->Ed25519SignCtx = ctx;
}
void* wolfSSL_GetEd25519SignCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->Ed25519SignCtx;

    return NULL;
}

void  wolfSSL_CTX_SetEd25519VerifyCb(WOLFSSL_CTX* ctx, CallbackEd25519Verify cb)
{
    if (ctx)
        ctx->Ed25519VerifyCb = cb;
}
void  wolfSSL_SetEd25519VerifyCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->Ed25519VerifyCtx = ctx;
}
void* wolfSSL_GetEd25519VerifyCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->Ed25519VerifyCtx;

    return NULL;
}
#endif /* HAVE_ED25519 */

#ifdef HAVE_CURVE25519
void wolfSSL_CTX_SetX25519KeyGenCb(WOLFSSL_CTX* ctx,
        CallbackX25519KeyGen cb)
{
    if (ctx)
        ctx->X25519KeyGenCb = cb;
}
void  wolfSSL_SetX25519KeyGenCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->X25519KeyGenCtx = ctx;
}
void* wolfSSL_GetX25519KeyGenCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->X25519KeyGenCtx;

    return NULL;
}

void wolfSSL_CTX_SetX25519SharedSecretCb(WOLFSSL_CTX* ctx,
        CallbackX25519SharedSecret cb)
{
    if (ctx)
        ctx->X25519SharedSecretCb = cb;
}
void  wolfSSL_SetX25519SharedSecretCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->X25519SharedSecretCtx = ctx;
}
void* wolfSSL_GetX25519SharedSecretCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->X25519SharedSecretCtx;

    return NULL;
}
#endif /* HAVE_CURVE25519 */

#ifdef HAVE_ED448
void  wolfSSL_CTX_SetEd448SignCb(WOLFSSL_CTX* ctx, CallbackEd448Sign cb)
{
    if (ctx)
        ctx->Ed448SignCb = cb;
}
void  wolfSSL_SetEd448SignCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->Ed448SignCtx = ctx;
}
void* wolfSSL_GetEd448SignCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->Ed448SignCtx;

    return NULL;
}

void  wolfSSL_CTX_SetEd448VerifyCb(WOLFSSL_CTX* ctx, CallbackEd448Verify cb)
{
    if (ctx)
        ctx->Ed448VerifyCb = cb;
}
void  wolfSSL_SetEd448VerifyCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->Ed448VerifyCtx = ctx;
}
void* wolfSSL_GetEd448VerifyCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->Ed448VerifyCtx;

    return NULL;
}
#endif /* HAVE_ED448 */

#ifdef HAVE_CURVE448
void wolfSSL_CTX_SetX448KeyGenCb(WOLFSSL_CTX* ctx,
        CallbackX448KeyGen cb)
{
    if (ctx)
        ctx->X448KeyGenCb = cb;
}
void  wolfSSL_SetX448KeyGenCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->X448KeyGenCtx = ctx;
}
void* wolfSSL_GetX448KeyGenCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->X448KeyGenCtx;

    return NULL;
}

void wolfSSL_CTX_SetX448SharedSecretCb(WOLFSSL_CTX* ctx,
        CallbackX448SharedSecret cb)
{
    if (ctx)
        ctx->X448SharedSecretCb = cb;
}
void  wolfSSL_SetX448SharedSecretCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->X448SharedSecretCtx = ctx;
}
void* wolfSSL_GetX448SharedSecretCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->X448SharedSecretCtx;

    return NULL;
}
#endif /* HAVE_CURVE448 */

#ifndef NO_RSA
void  wolfSSL_CTX_SetRsaSignCb(WOLFSSL_CTX* ctx, CallbackRsaSign cb)
{
    if (ctx)
        ctx->RsaSignCb = cb;
}
void  wolfSSL_CTX_SetRsaSignCheckCb(WOLFSSL_CTX* ctx, CallbackRsaVerify cb)
{
    if (ctx)
        ctx->RsaSignCheckCb = cb;
}
void  wolfSSL_SetRsaSignCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->RsaSignCtx = ctx;
}
void* wolfSSL_GetRsaSignCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->RsaSignCtx;

    return NULL;
}


void  wolfSSL_CTX_SetRsaVerifyCb(WOLFSSL_CTX* ctx, CallbackRsaVerify cb)
{
    if (ctx)
        ctx->RsaVerifyCb = cb;
}
void  wolfSSL_SetRsaVerifyCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->RsaVerifyCtx = ctx;
}
void* wolfSSL_GetRsaVerifyCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->RsaVerifyCtx;

    return NULL;
}

#ifdef WC_RSA_PSS
void  wolfSSL_CTX_SetRsaPssSignCb(WOLFSSL_CTX* ctx, CallbackRsaPssSign cb)
{
    if (ctx)
        ctx->RsaPssSignCb = cb;
}
void  wolfSSL_CTX_SetRsaPssSignCheckCb(WOLFSSL_CTX* ctx, CallbackRsaPssVerify cb)
{
    if (ctx)
        ctx->RsaPssSignCheckCb = cb;
}
void  wolfSSL_SetRsaPssSignCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->RsaPssSignCtx = ctx;
}
void* wolfSSL_GetRsaPssSignCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->RsaPssSignCtx;

    return NULL;
}

void  wolfSSL_CTX_SetRsaPssVerifyCb(WOLFSSL_CTX* ctx, CallbackRsaPssVerify cb)
{
    if (ctx)
        ctx->RsaPssVerifyCb = cb;
}
void  wolfSSL_SetRsaPssVerifyCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->RsaPssVerifyCtx = ctx;
}
void* wolfSSL_GetRsaPssVerifyCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->RsaPssVerifyCtx;

    return NULL;
}
#endif /* WC_RSA_PSS */

void  wolfSSL_CTX_SetRsaEncCb(WOLFSSL_CTX* ctx, CallbackRsaEnc cb)
{
    if (ctx)
        ctx->RsaEncCb = cb;
}
void  wolfSSL_SetRsaEncCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->RsaEncCtx = ctx;
}
void* wolfSSL_GetRsaEncCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->RsaEncCtx;

    return NULL;
}

void  wolfSSL_CTX_SetRsaDecCb(WOLFSSL_CTX* ctx, CallbackRsaDec cb)
{
    if (ctx)
        ctx->RsaDecCb = cb;
}
void  wolfSSL_SetRsaDecCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->RsaDecCtx = ctx;
}
void* wolfSSL_GetRsaDecCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->RsaDecCtx;

    return NULL;
}
#endif /* NO_RSA */

/* callback for premaster secret generation */
void  wolfSSL_CTX_SetGenPreMasterCb(WOLFSSL_CTX* ctx, CallbackGenPreMaster cb)
{
    if (ctx)
        ctx->GenPreMasterCb = cb;
}
/* Set premaster secret generation callback context */
void  wolfSSL_SetGenPreMasterCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->GenPreMasterCtx = ctx;
}
/* Get premaster secret generation callback context */
void* wolfSSL_GetGenPreMasterCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->GenPreMasterCtx;

    return NULL;
}

/* callback for master secret generation */
void  wolfSSL_CTX_SetGenMasterSecretCb(WOLFSSL_CTX* ctx, CallbackGenMasterSecret cb)
{
    if (ctx)
        ctx->GenMasterCb = cb;
}
/* Set master secret generation callback context */
void  wolfSSL_SetGenMasterSecretCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->GenMasterCtx = ctx;
}
/* Get master secret generation callback context */
void* wolfSSL_GetGenMasterSecretCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->GenMasterCtx;

    return NULL;
}

/* callback for session key generation */
void  wolfSSL_CTX_SetGenSessionKeyCb(WOLFSSL_CTX* ctx, CallbackGenSessionKey cb)
{
    if (ctx)
        ctx->GenSessionKeyCb = cb;
}
/* Set session key generation callback context */
void  wolfSSL_SetGenSessionKeyCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->GenSessionKeyCtx = ctx;
}
/* Get session key generation callback context */
void* wolfSSL_GetGenSessionKeyCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->GenSessionKeyCtx;

    return NULL;
}

/* callback for setting encryption keys */
void  wolfSSL_CTX_SetEncryptKeysCb(WOLFSSL_CTX* ctx, CallbackEncryptKeys cb)
{
    if (ctx)
        ctx->EncryptKeysCb = cb;
}
/* Set encryption keys callback context */
void  wolfSSL_SetEncryptKeysCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->EncryptKeysCtx = ctx;
}
/* Get encryption keys callback context */
void* wolfSSL_GetEncryptKeysCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->EncryptKeysCtx;

    return NULL;
}

/* callback for Tls finished */
/* the callback can be used to build TLS Finished message if enabled */
void  wolfSSL_CTX_SetTlsFinishedCb(WOLFSSL_CTX* ctx, CallbackTlsFinished cb)
{
    if (ctx)
        ctx->TlsFinishedCb = cb;
}
/* Set Tls finished callback context */
void  wolfSSL_SetTlsFinishedCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->TlsFinishedCtx = ctx;
}
/* Get Tls finished callback context */
void* wolfSSL_GetTlsFinishedCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->TlsFinishedCtx;

    return NULL;
}
#if !defined(WOLFSSL_NO_TLS12) && !defined(WOLFSSL_AEAD_ONLY)
/* callback for verify data */
void  wolfSSL_CTX_SetVerifyMacCb(WOLFSSL_CTX* ctx, CallbackVerifyMac cb)
{
    if (ctx)
        ctx->VerifyMacCb = cb;
}

/* Set set keys callback context */
void  wolfSSL_SetVerifyMacCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->VerifyMacCtx = ctx;
}
/* Get set  keys callback context */
void* wolfSSL_GetVerifyMacCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->VerifyMacCtx;

    return NULL;
}
#endif /* !WOLFSSL_NO_TLS12 && !WOLFSSL_AEAD_ONLY */

void wolfSSL_CTX_SetHKDFExpandLabelCb(WOLFSSL_CTX* ctx,
                                      CallbackHKDFExpandLabel cb)
{
    if (ctx)
        ctx->HKDFExpandLabelCb = cb;
}
#ifdef WOLFSSL_PUBLIC_ASN
void wolfSSL_CTX_SetProcessPeerCertCb(WOLFSSL_CTX* ctx,
                                        CallbackProcessPeerCert cb)
{
    if (ctx)
        ctx->ProcessPeerCertCb = cb;
}
#endif /* WOLFSSL_PUBLIC_ASN */
void wolfSSL_CTX_SetProcessServerSigKexCb(WOLFSSL_CTX* ctx,
                                       CallbackProcessServerSigKex cb)
{
    if (ctx)
        ctx->ProcessServerSigKexCb = cb;
}
void wolfSSL_CTX_SetPerformTlsRecordProcessingCb(WOLFSSL_CTX* ctx,
                                          CallbackPerformTlsRecordProcessing cb)
{
    if (ctx)
        ctx->PerformTlsRecordProcessingCb = cb;
}
#endif /* HAVE_PK_CALLBACKS */
#endif /* NO_CERTS */

#if defined(HAVE_PK_CALLBACKS) && !defined(NO_DH)
void wolfSSL_CTX_SetDhGenerateKeyPair(WOLFSSL_CTX* ctx,
                                      CallbackDhGenerateKeyPair cb) {
    if (ctx)
        ctx->DhGenerateKeyPairCb = cb;
}
void wolfSSL_CTX_SetDhAgreeCb(WOLFSSL_CTX* ctx, CallbackDhAgree cb)
{
    if (ctx)
        ctx->DhAgreeCb = cb;
}
void wolfSSL_SetDhAgreeCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->DhAgreeCtx = ctx;
}
void* wolfSSL_GetDhAgreeCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->DhAgreeCtx;

    return NULL;
}
#endif /* HAVE_PK_CALLBACKS && !NO_DH */

#if defined(HAVE_PK_CALLBACKS) && defined(HAVE_HKDF)

void wolfSSL_CTX_SetHKDFExtractCb(WOLFSSL_CTX* ctx, CallbackHKDFExtract cb)
{
    if (ctx)
        ctx->HkdfExtractCb = cb;
}

void wolfSSL_SetHKDFExtractCtx(WOLFSSL* ssl, void *ctx)
{
    if (ssl)
        ssl->HkdfExtractCtx = ctx;
}

void* wolfSSL_GetHKDFExtractCtx(WOLFSSL* ssl)
{
    if (ssl)
        return ssl->HkdfExtractCtx;

    return NULL;
}
#endif /* HAVE_PK_CALLBACKS && HAVE_HKDF */

#ifdef WOLFSSL_HAVE_WOLFSCEP
    /* Used by autoconf to see if wolfSCEP is available */
    void wolfSSL_wolfSCEP(void) {}
#endif


#ifdef WOLFSSL_HAVE_CERT_SERVICE
    /* Used by autoconf to see if cert service is available */
    void wolfSSL_cert_service(void) {}
#endif

#if (defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)) && \
    !defined(WOLFCRYPT_ONLY)
#ifndef NO_CERTS

#if defined(OPENSSL_ALL) || defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
/* Convert ASN1 input string into canonical ASN1 string                     */
/*  , which has the following rules:                                        */
/*   convert to UTF8                                                        */
/*   convert to lower case                                                  */
/*   multi-spaces collapsed                                                 */
/* @param  asn_out a pointer to ASN1_STRING to be converted                 */
/* @param  asn_in  a pointer to input ASN1_STRING                           */
/* @return WOLFSSL_SUCCESS on successful converted, otherwise <=0 error code*/
int wolfSSL_ASN1_STRING_canon(WOLFSSL_ASN1_STRING* asn_out,
                              const WOLFSSL_ASN1_STRING* asn_in)
{
    char* dst;
    char* src;
    int i, len;

    WOLFSSL_ENTER("wolfSSL_ASN1_STRING_canon");

    /* sanity check */
    if (asn_out == NULL || asn_in == NULL) {
        WOLFSSL_MSG("invalid function arguments");
        return BAD_FUNC_ARG;
    }

    switch (asn_in->type) {
        case MBSTRING_UTF8:
        case V_ASN1_PRINTABLESTRING:
             break;
        default:
           WOLFSSL_MSG("just copy string");
           return wolfSSL_ASN1_STRING_copy(asn_out, asn_in);
    }
    /* type is set as UTF8 */
    asn_out->type = MBSTRING_UTF8;
    asn_out->length = wolfSSL_ASN1_STRING_to_UTF8(
        (unsigned char**)&asn_out->data, (WOLFSSL_ASN1_STRING*)asn_in);

    if (asn_out->length < 0) {
        return WOLFSSL_FAILURE;
    }
    /* point to the last */
    dst = asn_out->data + asn_out->length;
    /* point to the start */
    src = asn_out->data;

    len = asn_out->length;

    /* trimming spaces at the head and tail */
    dst--;
    for (; (len > 0 && XISSPACE((unsigned char)*dst)); len--) {
        dst--;
    }
    for (; (len > 0 && XISSPACE((unsigned char)*src)); len--) {
        src++;
    }

    /* point to the start */
    dst = asn_out->data;

    for (i = 0; i < len; dst++, i++) {
        if (!XISASCII(*src)) {
            /* keep non-ascii code */
            *dst = *src++;
        } else if ((*src) > 0 && XISSPACE((unsigned char)*src)) {
            *dst = 0x20; /* space */
            /* remove the rest of spaces */
            while (XISSPACE((unsigned char)*++src) && i++ < len);
        } else {
            *dst = (char)XTOLOWER((unsigned char)*src++);
        }
    }
    /* put actual length */
    asn_out->length = (int)(dst - asn_out->data);
    return WOLFSSL_SUCCESS;
}

#if defined(OPENSSL_EXTRA) || defined(OPENSSL_ALL)
#if !defined(NO_FILESYSTEM)
    WOLFSSL_EVP_PKEY* wolfSSL_PEM_read_PrivateKey(XFILE fp,
        WOLFSSL_EVP_PKEY **key, wc_pem_password_cb *cb, void *pass)
    {
        WOLFSSL_EVP_PKEY* pkey = NULL;
        DerBuffer*         der = NULL;
        int             keyFormat = 0;
        int                 type = -1;

        WOLFSSL_ENTER("wolfSSL_PEM_read_PrivateKey");

        if (pem_read_file_key(fp, cb, pass, PRIVATEKEY_TYPE, &keyFormat,
                                                                   &der) >= 0) {
            const unsigned char* ptr = der->buffer;

            if (keyFormat) {
                /* keyFormat is Key_Sum enum */
                if (keyFormat == RSAk)
                    type = EVP_PKEY_RSA;
                else if (keyFormat == ECDSAk)
                    type = EVP_PKEY_EC;
                else if (keyFormat == DSAk)
                    type = EVP_PKEY_DSA;
                else if (keyFormat == DHk)
                    type = EVP_PKEY_DH;
            }
            else {
                /* Default to RSA if format is not set */
                type = EVP_PKEY_RSA;
            }

            /* handle case where reuse is attempted */
            if (key != NULL && *key != NULL)
                pkey = *key;

            wolfSSL_d2i_PrivateKey(type, &pkey, &ptr, der->length);
            if (pkey == NULL) {
                WOLFSSL_MSG("Error loading DER buffer into WOLFSSL_EVP_PKEY");
            }
        }

        FreeDer(&der);

        if (key != NULL && pkey != NULL)
            *key = pkey;

        WOLFSSL_LEAVE("wolfSSL_PEM_read_PrivateKey", 0);

        return pkey;
    }
#endif
#endif

#endif /* OPENSSL_ALL || OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL*/

#if defined(OPENSSL_EXTRA) || defined(OPENSSL_ALL)

    #define PEM_BEGIN              "-----BEGIN "
    #define PEM_BEGIN_SZ           11
    #define PEM_END                "-----END "
    #define PEM_END_SZ             9
    #define PEM_HDR_FIN            "-----"
    #define PEM_HDR_FIN_SZ         5
    #define PEM_HDR_FIN_EOL_NEWLINE   "-----\n"
    #define PEM_HDR_FIN_EOL_NULL_TERM "-----\0"
    #define PEM_HDR_FIN_EOL_SZ     6

#ifndef NO_BIO

    int wolfSSL_PEM_read_bio(WOLFSSL_BIO* bio, char **name, char **header,
                             unsigned char **data, long *len)
    {
        int ret = WOLFSSL_SUCCESS;
        char pem[256];
        int pemLen;
        char* p;
        char* nameStr = NULL;
        int nameLen = 0;
        char* headerStr = NULL;
        int headerLen;
        int headerFound = 0;
        unsigned char* der = NULL;
        word32 derLen = 0;

        if (bio == NULL || name == NULL || header == NULL || data == NULL ||
                                                                  len == NULL) {
            return WOLFSSL_FAILURE;
        }

        /* Find header line. */
        pem[sizeof(pem) - 1] = '\0';
        while ((pemLen = wolfSSL_BIO_gets(bio, pem, sizeof(pem) - 1)) > 0) {
            if (XSTRNCMP(pem, PEM_BEGIN, PEM_BEGIN_SZ) == 0)
                break;
        }
        if (pemLen <= 0)
            ret = WOLFSSL_FAILURE;
        /* Have a header line. */
        if (ret == WOLFSSL_SUCCESS) {
            while (pem[pemLen - 1] == '\r' || pem[pemLen - 1] == '\n')
                pemLen--;
            pem[pemLen] = '\0';
            if (XSTRNCMP(pem + pemLen - PEM_HDR_FIN_SZ, PEM_HDR_FIN,
                                                         PEM_HDR_FIN_SZ) != 0) {
                ret = WOLFSSL_FAILURE;
            }
        }

        /* Get out name. */
        if (ret == WOLFSSL_SUCCESS) {
            nameLen = pemLen - PEM_BEGIN_SZ - PEM_HDR_FIN_SZ;
            nameStr = (char*)XMALLOC(nameLen + 1, NULL,
                                                       DYNAMIC_TYPE_TMP_BUFFER);
            if (nameStr == NULL)
                ret = WOLFSSL_FAILURE;
        }
        if (ret == WOLFSSL_SUCCESS) {
            XSTRNCPY(nameStr, pem + PEM_BEGIN_SZ, nameLen);
            nameStr[nameLen] = '\0';

            /* Get header of PEM - encryption header. */
            headerLen = 0;
            while ((pemLen = wolfSSL_BIO_gets(bio, pem, sizeof(pem) - 1)) > 0) {
                while (pemLen > 0 && (pem[pemLen - 1] == '\r' ||
                                                     pem[pemLen - 1] == '\n')) {
                    pemLen--;
                }
                pem[pemLen++] = '\n';
                pem[pemLen] = '\0';

                /* Header separator is a blank line. */
                if (pem[0] == '\n') {
                    headerFound = 1;
                    break;
                }

                /* Didn't find a blank line - no header. */
                if (XSTRNCMP(pem, PEM_END, PEM_END_SZ) == 0) {
                    der = (unsigned char*)headerStr;
                    derLen = headerLen;
                    /* Empty header - empty string. */
                    headerStr = (char*)XMALLOC(1, NULL,
                                                       DYNAMIC_TYPE_TMP_BUFFER);
                    if (headerStr == NULL)
                        ret = WOLFSSL_FAILURE;
                    else
                        headerStr[0] = '\0';
                    break;
                }

                p = (char*)XREALLOC(headerStr, headerLen + pemLen + 1, NULL,
                                                       DYNAMIC_TYPE_TMP_BUFFER);
                if (p == NULL) {
                    ret = WOLFSSL_FAILURE;
                    break;
                }

                headerStr = p;
                XMEMCPY(headerStr + headerLen, pem, pemLen + 1);
                headerLen += pemLen;
            }
            if (pemLen <= 0)
                ret = WOLFSSL_FAILURE;
        }

        /* Get body of PEM - if there was a header */
        if (ret == WOLFSSL_SUCCESS && headerFound) {
            derLen = 0;
            while ((pemLen = wolfSSL_BIO_gets(bio, pem, sizeof(pem) - 1)) > 0) {
                while (pemLen > 0 && (pem[pemLen - 1] == '\r' ||
                                                     pem[pemLen - 1] == '\n')) {
                    pemLen--;
                }
                pem[pemLen++] = '\n';
                pem[pemLen] = '\0';

                if (XSTRNCMP(pem, PEM_END, PEM_END_SZ) == 0)
                    break;

                p = (char*)XREALLOC(der, derLen + pemLen + 1, NULL,
                                                       DYNAMIC_TYPE_TMP_BUFFER);
                if (p == NULL) {
                    ret = WOLFSSL_FAILURE;
                    break;
                }

                der = (unsigned char*)p;
                XMEMCPY(der + derLen, pem, pemLen + 1);
                derLen += pemLen;
            }
            if (pemLen <= 0)
                ret = WOLFSSL_FAILURE;
        }

        /* Check trailer. */
        if (ret == WOLFSSL_SUCCESS) {
            if (XSTRNCMP(pem + PEM_END_SZ, nameStr, nameLen) != 0)
                ret = WOLFSSL_FAILURE;
        }
        if (ret == WOLFSSL_SUCCESS) {
            if (XSTRNCMP(pem + PEM_END_SZ + nameLen,
                    PEM_HDR_FIN_EOL_NEWLINE,
                    PEM_HDR_FIN_EOL_SZ) != 0 &&
                XSTRNCMP(pem + PEM_END_SZ + nameLen,
                        PEM_HDR_FIN_EOL_NULL_TERM,
                        PEM_HDR_FIN_EOL_SZ) != 0) {
                ret = WOLFSSL_FAILURE;
            }
        }

        /* Base64 decode body. */
        if (ret == WOLFSSL_SUCCESS) {
            if (Base64_Decode(der, derLen, der, &derLen) != 0)
                ret = WOLFSSL_FAILURE;
        }

        if (ret == WOLFSSL_SUCCESS) {
            *name = nameStr;
            *header = headerStr;
            *data = der;
            *len = derLen;
            nameStr = NULL;
            headerStr = NULL;
            der = NULL;
        }

        if (nameStr != NULL)
            XFREE(nameStr, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        if (headerStr != NULL)
            XFREE(headerStr, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        if (der != NULL)
            XFREE(der, NULL, DYNAMIC_TYPE_TMP_BUFFER);

        return ret;
    }

    int wolfSSL_PEM_write_bio(WOLFSSL_BIO* bio, const char *name,
                              const char *header, const unsigned char *data,
                              long len)
    {
        int err = 0;
        int outSz = 0;
        int nameLen;
        int headerLen;
        byte* pem = NULL;
        word32 pemLen;
        word32 derLen = (word32)len;

        if (bio == NULL || name == NULL || header == NULL || data == NULL)
            return 0;

        nameLen = (int)XSTRLEN(name);
        headerLen = (int)XSTRLEN(header);

        pemLen = (derLen + 2) / 3 * 4;
        pemLen += (pemLen + 63) / 64;

        pem = (byte*)XMALLOC(pemLen, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        err = pem == NULL;
        if (!err)
            err = Base64_Encode(data, derLen, pem, &pemLen) != 0;

        if (!err) {
            err = wolfSSL_BIO_write(bio, PEM_BEGIN, PEM_BEGIN_SZ) !=
                                                              (int)PEM_BEGIN_SZ;
        }
        if (!err)
            err = wolfSSL_BIO_write(bio, name, nameLen) != nameLen;
        if (!err) {
            err = wolfSSL_BIO_write(bio, PEM_HDR_FIN_EOL_NEWLINE,
                    PEM_HDR_FIN_EOL_SZ) != (int)PEM_HDR_FIN_EOL_SZ;
        }
        if (!err && headerLen > 0) {
            err = wolfSSL_BIO_write(bio, header, headerLen) != headerLen;
            /* Blank line after a header and before body. */
            if (!err)
                err = wolfSSL_BIO_write(bio, "\n", 1) != 1;
            headerLen++;
        }
        if (!err)
            err = wolfSSL_BIO_write(bio, pem, pemLen) != (int)pemLen;
        if (!err)
            err = wolfSSL_BIO_write(bio, PEM_END, PEM_END_SZ) !=
                                                                (int)PEM_END_SZ;
        if (!err)
            err = wolfSSL_BIO_write(bio, name, nameLen) != nameLen;
        if (!err) {
            err = wolfSSL_BIO_write(bio, PEM_HDR_FIN_EOL_NEWLINE,
                    PEM_HDR_FIN_EOL_SZ) != (int)PEM_HDR_FIN_EOL_SZ;
        }

        if (!err) {
            outSz = PEM_BEGIN_SZ + nameLen + PEM_HDR_FIN_EOL_SZ + headerLen +
                             pemLen + PEM_END_SZ + nameLen + PEM_HDR_FIN_EOL_SZ;
        }

        if (pem != NULL)
            XFREE(pem, NULL, DYNAMIC_TYPE_TMP_BUFFER);

        return outSz;
    }

#if !defined(NO_FILESYSTEM)
    int wolfSSL_PEM_read(XFILE fp, char **name, char **header,
                         unsigned char **data, long *len)
    {
        int ret;
        WOLFSSL_BIO* bio;

        if (name == NULL || header == NULL || data == NULL || len == NULL)
            return WOLFSSL_FAILURE;

        bio = wolfSSL_BIO_new_fp(fp, BIO_NOCLOSE);
        if (bio == NULL)
            return 0;

        ret = wolfSSL_PEM_read_bio(bio, name, header, data, len);

        if (bio != NULL)
            wolfSSL_BIO_free(bio);

        return ret;
    }

    int wolfSSL_PEM_write(XFILE fp, const char *name, const char *header,
                          const unsigned char *data, long len)
    {
        int ret;
        WOLFSSL_BIO* bio;

        if (name == NULL || header == NULL || data == NULL)
            return 0;

        bio = wolfSSL_BIO_new_fp(fp, BIO_NOCLOSE);
        if (bio == NULL)
            return 0;

        ret = wolfSSL_PEM_write_bio(bio, name, header, data, len);

        if (bio != NULL)
            wolfSSL_BIO_free(bio);

        return ret;
    }
#endif
#endif /* !NO_BIO */

    int wolfSSL_PEM_get_EVP_CIPHER_INFO(const char* header,
                                        EncryptedInfo* cipher)
    {
        if (header == NULL || cipher == NULL)
            return WOLFSSL_FAILURE;

        XMEMSET(cipher, 0, sizeof(*cipher));

        if (wc_EncryptedInfoParse(cipher, &header, XSTRLEN(header)) != 0)
            return WOLFSSL_FAILURE;

        return WOLFSSL_SUCCESS;
    }

    int wolfSSL_PEM_do_header(EncryptedInfo* cipher, unsigned char* data,
                              long* len, wc_pem_password_cb* callback,
                              void* ctx)
    {
        int ret = WOLFSSL_SUCCESS;
        char password[NAME_SZ];
        int passwordSz;

        if (cipher == NULL || data == NULL || len == NULL || callback == NULL)
            return WOLFSSL_FAILURE;

        passwordSz = callback(password, sizeof(password), PEM_PASS_READ, ctx);
        if (passwordSz < 0)
            ret = WOLFSSL_FAILURE;

        if (ret == WOLFSSL_SUCCESS) {
            if (wc_BufferKeyDecrypt(cipher, data, (word32)*len, (byte*)password,
                                                     passwordSz, WC_MD5) != 0) {
                ret = WOLFSSL_FAILURE;
            }
        }

        if (passwordSz > 0)
            XMEMSET(password, 0, passwordSz);

        return ret;
    }

#ifndef NO_BIO
    /*
     * bp : bio to read X509 from
     * x  : x509 to write to
     * cb : password call back for reading PEM
     * u  : password
     * _AUX is for working with a trusted X509 certificate
     */
    WOLFSSL_X509 *wolfSSL_PEM_read_bio_X509_AUX(WOLFSSL_BIO *bp,
                               WOLFSSL_X509 **x, wc_pem_password_cb *cb,
                               void *u)
    {
        WOLFSSL_ENTER("wolfSSL_PEM_read_bio_X509");

        /* AUX info is; trusted/rejected uses, friendly name, private key id,
         * and potentially a stack of "other" info. wolfSSL does not store
         * friendly name or private key id yet in WOLFSSL_X509 for human
         * readability and does not support extra trusted/rejected uses for
         * root CA. */
        return wolfSSL_PEM_read_bio_X509(bp, x, cb, u);
    }
#endif /* !NO_BIO */


#endif /* OPENSSL_EXTRA || OPENSSL_ALL */
#endif /* !NO_CERTS */

    /* NID variables are dependent on compatibility header files currently
     *
     * returns a pointer to a new WOLFSSL_ASN1_OBJECT struct on success and NULL
     *         on fail
     */

    WOLFSSL_ASN1_OBJECT* wolfSSL_OBJ_nid2obj(int id)
    {
        return wolfSSL_OBJ_nid2obj_ex(id, NULL);
    }


    WOLFSSL_LOCAL WOLFSSL_ASN1_OBJECT* wolfSSL_OBJ_nid2obj_ex(int id,
                                                WOLFSSL_ASN1_OBJECT* arg_obj)
    {
        word32 oidSz = 0;
        int nid = 0;
        const byte* oid;
        word32 type = 0;
        WOLFSSL_ASN1_OBJECT* obj = arg_obj;
        byte objBuf[MAX_OID_SZ + MAX_LENGTH_SZ + 1]; /* +1 for object tag */
        word32 objSz = 0;
        const char* sName = NULL;
        int i;

#ifdef WOLFSSL_DEBUG_OPENSSL
        WOLFSSL_ENTER("wolfSSL_OBJ_nid2obj()");
#endif

        for (i = 0; i < (int)WOLFSSL_OBJECT_INFO_SZ; i++) {
            if (wolfssl_object_info[i].nid == id) {
                nid = id;
                id = wolfssl_object_info[i].id;
                sName = wolfssl_object_info[i].sName;
                type = wolfssl_object_info[i].type;
                break;
            }
        }
        if (i == (int)WOLFSSL_OBJECT_INFO_SZ) {
            WOLFSSL_MSG("NID not in table");
        #ifdef WOLFSSL_QT
            sName = NULL;
            type = id;
        #else
            return NULL;
        #endif
        }

    #ifdef HAVE_ECC
         if (type == 0 && wc_ecc_get_oid(id, &oid, &oidSz) > 0) {
             type = oidCurveType;
         }
    #endif /* HAVE_ECC */

        if (sName != NULL) {
            if (XSTRLEN(sName) > WOLFSSL_MAX_SNAME - 1) {
                WOLFSSL_MSG("Attempted short name is too large");
                return NULL;
            }
        }

        oid = OidFromId(id, type, &oidSz);

        /* set object ID to buffer */
        if (obj == NULL){
            obj = wolfSSL_ASN1_OBJECT_new();
            if (obj == NULL) {
                WOLFSSL_MSG("Issue creating WOLFSSL_ASN1_OBJECT struct");
                return NULL;
            }
        }
        obj->nid     = nid;
        obj->type    = id;
        obj->grp     = type;

        obj->sName[0] = '\0';
        if (sName != NULL) {
            XMEMCPY(obj->sName, (char*)sName, XSTRLEN((char*)sName));
        }

        objBuf[0] = ASN_OBJECT_ID; objSz++;
        objSz += SetLength(oidSz, objBuf + 1);
        if (oidSz) {
            XMEMCPY(objBuf + objSz, oid, oidSz);
            objSz     += oidSz;
        }

        if (obj->objSz == 0 || objSz != obj->objSz) {
            obj->objSz = objSz;
            if(((obj->dynamic & WOLFSSL_ASN1_DYNAMIC_DATA) != 0) ||
                                                           (obj->obj == NULL)) {
                if (obj->obj != NULL)
                    XFREE((byte*)obj->obj, NULL, DYNAMIC_TYPE_ASN1);
                obj->obj = (byte*)XMALLOC(obj->objSz, NULL, DYNAMIC_TYPE_ASN1);
                if (obj->obj == NULL) {
                    wolfSSL_ASN1_OBJECT_free(obj);
                    return NULL;
                }
                obj->dynamic |= WOLFSSL_ASN1_DYNAMIC_DATA ;
            }
            else {
                obj->dynamic &= ~WOLFSSL_ASN1_DYNAMIC_DATA ;
            }
        }
        XMEMCPY((byte*)obj->obj, objBuf, obj->objSz);

        (void)type;

        return obj;
    }

    static const char* oid_translate_num_to_str(const char* oid)
    {
        const struct oid_dict {
            const char* num;
            const char* desc;
        } oid_dict[] = {
            { "2.5.29.37.0",       "Any Extended Key Usage" },
            { "1.3.6.1.5.5.7.3.1", "TLS Web Server Authentication" },
            { "1.3.6.1.5.5.7.3.2", "TLS Web Client Authentication" },
            { "1.3.6.1.5.5.7.3.3", "Code Signing" },
            { "1.3.6.1.5.5.7.3.4", "E-mail Protection" },
            { "1.3.6.1.5.5.7.3.8", "Time Stamping" },
            { "1.3.6.1.5.5.7.3.9", "OCSP Signing" },
            { NULL, NULL }
        };
        const struct oid_dict* idx;

        for (idx = oid_dict; idx->num != NULL; idx++) {
            if (!XSTRCMP(oid, idx->num)) {
                return idx->desc;
            }
        }
        return NULL;
    }

    static int wolfssl_obj2txt_numeric(char *buf, int bufLen,
                                       const WOLFSSL_ASN1_OBJECT *a)
    {
        int bufSz;
        int    length;
        word32 idx = 0;
        byte   tag;

        if (GetASNTag(a->obj, &idx, &tag, a->objSz) != 0) {
            return WOLFSSL_FAILURE;
        }

        if (tag != ASN_OBJECT_ID) {
            WOLFSSL_MSG("Bad ASN1 Object");
            return WOLFSSL_FAILURE;
        }

        if (GetLength((const byte*)a->obj, &idx, &length,
                       a->objSz) < 0 || length < 0) {
            return ASN_PARSE_E;
        }

        if (bufLen < MAX_OID_STRING_SZ) {
            bufSz = bufLen - 1;
        }
        else {
            bufSz = MAX_OID_STRING_SZ;
        }

        if ((bufSz = DecodePolicyOID(buf, (word32)bufSz, a->obj + idx,
                    (word32)length)) <= 0) {
            WOLFSSL_MSG("Error decoding OID");
            return WOLFSSL_FAILURE;
        }

        buf[bufSz] = '\0';

        return bufSz;
    }

    /* If no_name is one then use numerical form, otherwise short name.
     *
     * Returns the buffer size on success, WOLFSSL_FAILURE on error
     */
    int wolfSSL_OBJ_obj2txt(char *buf, int bufLen, const WOLFSSL_ASN1_OBJECT *a,
                            int no_name)
    {
        int bufSz;
        const char* desc;
        const char* name;

        WOLFSSL_ENTER("wolfSSL_OBJ_obj2txt()");

        if (buf == NULL || bufLen <= 1 || a == NULL) {
            WOLFSSL_MSG("Bad input argument");
            return WOLFSSL_FAILURE;
        }

        if (no_name == 1) {
            return wolfssl_obj2txt_numeric(buf, bufLen, a);
        }

        /* return long name unless using x509small, then return short name */
#if defined(OPENSSL_EXTRA_X509_SMALL) && !defined(OPENSSL_EXTRA)
        name = a->sName;
#else
        name = wolfSSL_OBJ_nid2ln(wolfSSL_OBJ_obj2nid(a));
#endif

        if (name == NULL) {
            WOLFSSL_MSG("Name not found");
            bufSz = 0;
        }
        else if (XSTRLEN(name) + 1 < (word32)bufLen - 1) {
            bufSz = (int)XSTRLEN(name);
        }
        else {
            bufSz = bufLen - 1;
        }
        if (bufSz) {
            XMEMCPY(buf, name, bufSz);
        }
        else if (a->type == GEN_DNS || a->type == GEN_EMAIL ||
                 a->type == GEN_URI) {
            bufSz = (int)XSTRLEN((const char*)a->obj);
            XMEMCPY(buf, a->obj, min(bufSz, bufLen));
        }
        else if ((bufSz = wolfssl_obj2txt_numeric(buf, bufLen, a)) > 0) {
            if ((desc = oid_translate_num_to_str(buf))) {
                bufSz = (int)XSTRLEN(desc);
                bufSz = min(bufSz, bufLen - 1);
                XMEMCPY(buf, desc, bufSz);
            }
        }

        buf[bufSz] = '\0';

        return bufSz;
    }
#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL */

#if defined(OPENSSL_EXTRA) || defined(HAVE_LIGHTY) || \
    defined(WOLFSSL_MYSQL_COMPATIBLE) || defined(HAVE_STUNNEL) || \
    defined(WOLFSSL_NGINX) || defined(HAVE_POCO_LIB) || \
    defined(WOLFSSL_HAPROXY) || defined(WOLFSSL_WPAS_SMALL)
    /* Returns the long name that corresponds with an ASN1_OBJECT nid value.
     *  n : NID value of ASN1_OBJECT to search */
    const char* wolfSSL_OBJ_nid2ln(int n)
    {
        const WOLFSSL_ObjectInfo *obj_info = wolfssl_object_info;
        size_t i;
        WOLFSSL_ENTER("wolfSSL_OBJ_nid2ln");
        for (i = 0; i < WOLFSSL_OBJECT_INFO_SZ; i++, obj_info++) {
            if (obj_info->nid == n) {
                return obj_info->lName;
            }
        }
        WOLFSSL_MSG("NID not found in table");
        return NULL;
    }
#endif /* OPENSSL_EXTRA, HAVE_LIGHTY, WOLFSSL_MYSQL_COMPATIBLE, HAVE_STUNNEL,
          WOLFSSL_NGINX, HAVE_POCO_LIB, WOLFSSL_HAPROXY, WOLFSSL_WPAS_SMALL */

#if defined(OPENSSL_EXTRA) || defined(HAVE_LIGHTY) || \
    defined(WOLFSSL_MYSQL_COMPATIBLE) || defined(HAVE_STUNNEL) || \
    defined(WOLFSSL_NGINX) || defined(HAVE_POCO_LIB) || \
    defined(WOLFSSL_HAPROXY)
    char wolfSSL_CTX_use_certificate(WOLFSSL_CTX *ctx, WOLFSSL_X509 *x)
    {
        int ret;

        WOLFSSL_ENTER("wolfSSL_CTX_use_certificate");
        if (!ctx || !x || !x->derCert) {
            WOLFSSL_MSG("Bad parameter");
            return WOLFSSL_FAILURE;
        }

        FreeDer(&ctx->certificate); /* Make sure previous is free'd */
        ret = AllocDer(&ctx->certificate, x->derCert->length, CERT_TYPE,
                       ctx->heap);
        if (ret != 0)
            return WOLFSSL_FAILURE;

        XMEMCPY(ctx->certificate->buffer, x->derCert->buffer,
                x->derCert->length);
#ifdef KEEP_OUR_CERT
        if (ctx->ourCert != NULL && ctx->ownOurCert) {
            wolfSSL_X509_free(ctx->ourCert);
        }
        #ifndef WOLFSSL_X509_STORE_CERTS
        ctx->ourCert = x;
        if (wolfSSL_X509_up_ref(x) != 1) {
            return WOLFSSL_FAILURE;
        }
        #else
        ctx->ourCert = wolfSSL_X509_d2i(NULL, x->derCert->buffer,x->derCert->length);
        if(ctx->ourCert == NULL){
            return WOLFSSL_FAILURE;
        }
        #endif

        /* We own the cert because either we up its reference counter
         * or we create our own copy of the cert object. */
        ctx->ownOurCert = 1;
#endif

        /* Update the available options with public keys. */
        switch (x->pubKeyOID) {
    #ifndef NO_RSA
        #ifdef WC_RSA_PSS
            case RSAPSSk:
        #endif
            case RSAk:
                ctx->haveRSA = 1;
                break;
    #endif
        #ifdef HAVE_ED25519
            case ED25519k:
        #endif
        #ifdef HAVE_ED448
            case ED448k:
        #endif
            case ECDSAk:
                ctx->haveECC = 1;
        #if defined(HAVE_ECC) || defined(HAVE_ED25519) || defined(HAVE_ED448)
                ctx->pkCurveOID = x->pkCurveOID;
        #endif
                break;
        }

        return WOLFSSL_SUCCESS;
    }

    static int PushCertToDerBuffer(DerBuffer** inOutDer, int weOwn,
            byte* cert, word32 certSz, void* heap)
    {
        int ret;
        DerBuffer* inChain = NULL;
        DerBuffer* der = NULL;
        word32 len = 0;
        if (inOutDer == NULL)
            return BAD_FUNC_ARG;
        inChain = *inOutDer;
        if (inChain != NULL)
            len = inChain->length;
        ret = AllocDer(&der, len + CERT_HEADER_SZ + certSz, CERT_TYPE,
                heap);
        if (ret != 0) {
            WOLFSSL_MSG("AllocDer error");
            return ret;
        }
        if (inChain != NULL)
            XMEMCPY(der->buffer, inChain->buffer, len);
        c32to24(certSz, der->buffer + len);
        XMEMCPY(der->buffer + len + CERT_HEADER_SZ, cert, certSz);
        if (weOwn)
            FreeDer(inOutDer);
        *inOutDer = der;
        return WOLFSSL_SUCCESS;
    }

    /**
     * wolfSSL_CTX_add1_chain_cert makes a copy of the cert so we free it
     * on success
     */
    int wolfSSL_CTX_add0_chain_cert(WOLFSSL_CTX* ctx, WOLFSSL_X509* x509)
    {
        WOLFSSL_ENTER("wolfSSL_CTX_add0_chain_cert");
        if (wolfSSL_CTX_add1_chain_cert(ctx, x509) != WOLFSSL_SUCCESS) {
            return WOLFSSL_FAILURE;
        }
        wolfSSL_X509_free(x509);
        return WOLFSSL_SUCCESS;
    }

    int wolfSSL_CTX_add1_chain_cert(WOLFSSL_CTX* ctx, WOLFSSL_X509* x509)
    {
        int ret;
        WOLFSSL_ENTER("wolfSSL_CTX_add1_chain_cert");
        if (ctx == NULL || x509 == NULL || x509->derCert == NULL) {
            return WOLFSSL_FAILURE;
        }

        if (ctx->certificate == NULL)
            ret = (int)wolfSSL_CTX_use_certificate(ctx, x509);
        else {
            if (wolfSSL_X509_up_ref(x509) != WOLFSSL_SUCCESS) {
                WOLFSSL_MSG("wolfSSL_X509_up_ref error");
                return WOLFSSL_FAILURE;
            }
            ret = wolfSSL_CTX_load_verify_buffer(ctx, x509->derCert->buffer,
                x509->derCert->length, WOLFSSL_FILETYPE_ASN1);
            if (ret == WOLFSSL_SUCCESS) {
                /* push to ctx->certChain */
                ret = PushCertToDerBuffer(&ctx->certChain, 1,
                    x509->derCert->buffer, x509->derCert->length, ctx->heap);
            }
            /* Store cert to free it later */
            if (ret == WOLFSSL_SUCCESS && ctx->x509Chain == NULL) {
                ctx->x509Chain = wolfSSL_sk_X509_new_null();
                if (ctx->x509Chain == NULL) {
                    WOLFSSL_MSG("wolfSSL_sk_X509_new_null error");
                    ret =  WOLFSSL_FAILURE;
                }
            }
            if (ret == WOLFSSL_SUCCESS &&
                    wolfSSL_sk_X509_push(ctx->x509Chain, x509)
                        != WOLFSSL_SUCCESS) {
                WOLFSSL_MSG("wolfSSL_sk_X509_push error");
                ret = WOLFSSL_FAILURE;
            }
            if (ret != WOLFSSL_SUCCESS)
                wolfSSL_X509_free(x509); /* Decrease ref counter */
        }

        return (ret == WOLFSSL_SUCCESS) ? WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
    }

#ifdef KEEP_OUR_CERT
    int wolfSSL_add0_chain_cert(WOLFSSL* ssl, WOLFSSL_X509* x509)
    {
        int ret;

        WOLFSSL_ENTER("wolfSSL_add0_chain_cert");

        if (ssl == NULL || ssl->ctx == NULL || x509 == NULL ||
                x509->derCert == NULL)
            return WOLFSSL_FAILURE;

        if (ssl->buffers.certificate == NULL) {
            ret = wolfSSL_use_certificate(ssl, x509);
            /* Store cert to free it later */
            if (ret == WOLFSSL_SUCCESS) {
                if (ssl->buffers.weOwnCert)
                    wolfSSL_X509_free(ssl->ourCert);
                ssl->ourCert = x509;
                ssl->buffers.weOwnCert = 1;
            }
        }
        else {
            ret = PushCertToDerBuffer(&ssl->buffers.certChain,
                    ssl->buffers.weOwnCertChain, x509->derCert->buffer,
                    x509->derCert->length, ssl->heap);
            if (ret == WOLFSSL_SUCCESS) {
                ssl->buffers.weOwnCertChain = 1;
                /* Store cert to free it later */
                if (ssl->ourCertChain == NULL) {
                    ssl->ourCertChain = wolfSSL_sk_X509_new_null();
                    if (ssl->ourCertChain == NULL) {
                        WOLFSSL_MSG("wolfSSL_sk_X509_new_null error");
                        return WOLFSSL_FAILURE;
                    }
                }
                if (wolfSSL_sk_X509_push(ssl->ourCertChain, x509)
                        != WOLFSSL_SUCCESS) {
                    WOLFSSL_MSG("wolfSSL_sk_X509_push error");
                    return WOLFSSL_FAILURE;
                }
            }
        }
        return ret == WOLFSSL_SUCCESS ? WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
    }

    int wolfSSL_add1_chain_cert(WOLFSSL* ssl, WOLFSSL_X509* x509)
    {
        int ret;

        WOLFSSL_ENTER("wolfSSL_add1_chain_cert");
        if (ssl == NULL || ssl->ctx == NULL || x509 == NULL ||
                x509->derCert == NULL)
            return WOLFSSL_FAILURE;

        if (wolfSSL_X509_up_ref(x509) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("wolfSSL_X509_up_ref error");
            return WOLFSSL_FAILURE;
        }
        ret = wolfSSL_add0_chain_cert(ssl, x509);
        /* Decrease ref counter on error */
        if (ret != WOLFSSL_SUCCESS)
            wolfSSL_X509_free(x509);
        return ret;
    }
#endif

    /* Return the corresponding short name for the nid <n>.
     * or NULL if short name can't be found.
     */
    const char * wolfSSL_OBJ_nid2sn(int n) {
        const WOLFSSL_ObjectInfo *obj_info = wolfssl_object_info;
        size_t i;
        WOLFSSL_ENTER("wolfSSL_OBJ_nid2sn");

        if (n == NID_md5) {
            /* NID_surname == NID_md5 and NID_surname comes before NID_md5 in
             * wolfssl_object_info. As a result, the loop below will incorrectly
             * return "SN" instead of "MD5." NID_surname isn't the true OpenSSL
             * NID, but other functions rely on this table and modifying it to
             * conform with OpenSSL's NIDs isn't trivial. */
             return "MD5";
        }
        for (i = 0; i < WOLFSSL_OBJECT_INFO_SZ; i++, obj_info++) {
            if (obj_info->nid == n) {
                return obj_info->sName;
            }
        }
        WOLFSSL_MSG("SN not found");
        return NULL;
    }

#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
    int wolfSSL_OBJ_sn2nid(const char *sn) {
        WOLFSSL_ENTER("wolfSSL_OBJ_sn2nid");
        if (sn == NULL)
            return NID_undef;
        return wc_OBJ_sn2nid(sn);
    }
#endif

    size_t wolfSSL_OBJ_length(const WOLFSSL_ASN1_OBJECT* o)
    {
        size_t ret = 0;
        int err = 0;
        word32 idx = 0;
        int len = 0;

        WOLFSSL_ENTER("wolfSSL_OBJ_length");

        if (o == NULL || o->obj == NULL) {
            WOLFSSL_MSG("Bad argument.");
            err = 1;
        }

        if (err == 0 && GetASNObjectId(o->obj, &idx, &len, o->objSz)) {
            WOLFSSL_MSG("Error parsing ASN.1 header.");
            err = 1;
        }
        if (err == 0) {
            ret = len;
        }

        WOLFSSL_LEAVE("wolfSSL_OBJ_length", (int)ret);

        return ret;
    }

    const unsigned char* wolfSSL_OBJ_get0_data(const WOLFSSL_ASN1_OBJECT* o)
    {
        const unsigned char* ret = NULL;
        int err = 0;
        word32 idx = 0;
        int len = 0;

        WOLFSSL_ENTER("wolfSSL_OBJ_get0_data");

        if (o == NULL || o->obj == NULL) {
            WOLFSSL_MSG("Bad argument.");
            err = 1;
        }

        if (err == 0 && GetASNObjectId(o->obj, &idx, &len, o->objSz)) {
            WOLFSSL_MSG("Error parsing ASN.1 header.");
            err = 1;
        }
        if (err == 0) {
            ret = o->obj + idx;
        }

        return ret;
    }


    /* Gets the NID value that corresponds with the ASN1 object.
     *
     * o ASN1 object to get NID of
     *
     * Return NID on success and a negative value on failure
     */
    int wolfSSL_OBJ_obj2nid(const WOLFSSL_ASN1_OBJECT *o)
    {
        word32 oid = 0;
        word32 idx = 0;
        int ret;

#ifdef WOLFSSL_DEBUG_OPENSSL
        WOLFSSL_ENTER("wolfSSL_OBJ_obj2nid");
#endif

        if (o == NULL) {
            return -1;
        }

        #ifdef WOLFSSL_QT
        if (o->grp == oidCertExtType) {
            /* If nid is an unknown extension, return NID_undef */
            if (wolfSSL_OBJ_nid2sn(o->nid) == NULL)
                return NID_undef;
        }
        #endif

        if (o->nid > 0)
            return o->nid;
        if ((ret = GetObjectId(o->obj, &idx, &oid, o->grp, o->objSz)) < 0) {
            if (ret == ASN_OBJECT_ID_E) {
                /* Put ASN object tag in front and try again */
                int len = SetObjectId(o->objSz, NULL) + o->objSz;
                byte* buf = (byte*)XMALLOC(len, NULL, DYNAMIC_TYPE_TMP_BUFFER);
                if (!buf) {
                    WOLFSSL_MSG("malloc error");
                    return -1;
                }
                idx = SetObjectId(o->objSz, buf);
                XMEMCPY(buf + idx, o->obj, o->objSz);
                idx = 0;
                ret = GetObjectId(buf, &idx, &oid, o->grp, len);
                XFREE(buf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
                if (ret < 0) {
                    WOLFSSL_MSG("Issue getting OID of object");
                    return -1;
                }
            }
            else {
                WOLFSSL_MSG("Issue getting OID of object");
                return -1;
            }
        }

        return oid2nid(oid, o->grp);
    }

    /* Return the corresponding NID for the long name <ln>
     * or NID_undef if NID can't be found.
     */
    int wolfSSL_OBJ_ln2nid(const char *ln)
    {
        const WOLFSSL_ObjectInfo *obj_info = wolfssl_object_info;
        size_t i, lnlen;
        WOLFSSL_ENTER("wolfSSL_OBJ_ln2nid");
        if (ln && (lnlen = XSTRLEN(ln)) > 0) {
            /* Accept input like "/commonName=" */
            if (ln[0] == '/') {
                ln++;
                lnlen--;
            }
            if (lnlen) {
                if (ln[lnlen-1] == '=') {
                    lnlen--;
                }
                for (i = 0; i < WOLFSSL_OBJECT_INFO_SZ; i++, obj_info++) {
                    if (lnlen == XSTRLEN(obj_info->lName) &&
                            XSTRNCMP(ln, obj_info->lName, lnlen) == 0) {
                        return obj_info->nid;
                    }
                }
            }
        }
        return NID_undef;
    }

    /* compares two objects, return 0 if equal */
    int wolfSSL_OBJ_cmp(const WOLFSSL_ASN1_OBJECT* a,
                        const WOLFSSL_ASN1_OBJECT* b)
    {
        WOLFSSL_ENTER("wolfSSL_OBJ_cmp");

        if (a && b && a->obj && b->obj) {
            if (a->objSz == b->objSz) {
                return XMEMCMP(a->obj, b->obj, a->objSz);
            }
            else if (a->type == EXT_KEY_USAGE_OID ||
                     b->type == EXT_KEY_USAGE_OID) {
                /* Special case for EXT_KEY_USAGE_OID so that
                 * cmp will be treated as a substring search */
                /* Used in libest to check for id-kp-cmcRA in
                 * EXT_KEY_USAGE extension */
                unsigned int idx;
                const byte* s; /* shorter */
                unsigned int sLen;
                const byte* l; /* longer */
                unsigned int lLen;
                if (a->objSz > b->objSz) {
                    s = b->obj; sLen = b->objSz;
                    l = a->obj; lLen = a->objSz;
                }
                else {
                    s = a->obj; sLen = a->objSz;
                    l = b->obj; lLen = b->objSz;
                }
                for (idx = 0; idx <= lLen - sLen; idx++) {
                    if (XMEMCMP(l + idx, s, sLen) == 0) {
                        /* Found substring */
                        return 0;
                    }
                }
            }
        }

        return WOLFSSL_FATAL_ERROR;
    }
#endif /* OPENSSL_EXTRA, HAVE_LIGHTY, WOLFSSL_MYSQL_COMPATIBLE, HAVE_STUNNEL,
          WOLFSSL_NGINX, HAVE_POCO_LIB, WOLFSSL_HAPROXY */
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL) || \
    defined(HAVE_LIGHTY) || defined(WOLFSSL_MYSQL_COMPATIBLE) || \
    defined(HAVE_STUNNEL) || defined(WOLFSSL_NGINX) || \
    defined(HAVE_POCO_LIB) || defined(WOLFSSL_HAPROXY)
    /* Gets the NID value that is related to the OID string passed in. Example
     * string would be "2.5.29.14" for subject key ID.
     *
     * returns NID value on success and NID_undef on error
     */
    int wolfSSL_OBJ_txt2nid(const char* s)
    {
        unsigned int i;
    #ifdef WOLFSSL_CERT_EXT
        int ret;
        unsigned int sum = 0;
        unsigned int outSz = MAX_OID_SZ;
        unsigned char out[MAX_OID_SZ];
    #endif

        WOLFSSL_ENTER("OBJ_txt2nid");

        if (s == NULL) {
            return NID_undef;
        }

    #ifdef WOLFSSL_CERT_EXT
        ret = EncodePolicyOID(out, &outSz, s, NULL);
        if (ret == 0) {
            /* sum OID */
            for (i = 0; i < outSz; i++) {
                sum += out[i];
            }
        }
    #endif /* WOLFSSL_CERT_EXT */

        /* get the group that the OID's sum is in
         * @TODO possible conflict with multiples */
        for (i = 0; i < WOLFSSL_OBJECT_INFO_SZ; i++) {
            int len;
        #ifdef WOLFSSL_CERT_EXT
            if (ret == 0) {
                if (wolfssl_object_info[i].id == (int)sum) {
                    return wolfssl_object_info[i].nid;
                }
            }
        #endif

            /* try as a short name */
            len = (int)XSTRLEN(s);
            if ((int)XSTRLEN(wolfssl_object_info[i].sName) == len &&
                XSTRNCMP(wolfssl_object_info[i].sName, s, len) == 0) {
                return wolfssl_object_info[i].nid;
            }

            /* try as a long name */
            if ((int)XSTRLEN(wolfssl_object_info[i].lName) == len &&
                XSTRNCMP(wolfssl_object_info[i].lName, s, len) == 0) {
                return wolfssl_object_info[i].nid;
            }
        }

        return NID_undef;
    }
#endif
#if defined(OPENSSL_EXTRA) || defined(HAVE_LIGHTY) || \
    defined(WOLFSSL_MYSQL_COMPATIBLE) || defined(HAVE_STUNNEL) || \
    defined(WOLFSSL_NGINX) || defined(HAVE_POCO_LIB) || \
    defined(WOLFSSL_HAPROXY)

    /* Creates new ASN1_OBJECT from short name, long name, or text
     * representation of oid. If no_name is 0, then short name, long name, and
     * numerical value of oid are interpreted. If no_name is 1, then only the
     * numerical value of the oid is interpreted.
     *
     * Returns pointer to ASN1_OBJECT on success, or NULL on error.
     */
#if defined(WOLFSSL_CERT_EXT) && defined(WOLFSSL_CERT_GEN)
    WOLFSSL_ASN1_OBJECT* wolfSSL_OBJ_txt2obj(const char* s, int no_name)
    {
        int i, ret;
        int nid = NID_undef;
        unsigned int outSz = MAX_OID_SZ;
        unsigned char out[MAX_OID_SZ];
        WOLFSSL_ASN1_OBJECT* obj;

        WOLFSSL_ENTER("wolfSSL_OBJ_txt2obj");

        if (s == NULL)
            return NULL;

        /* If s is numerical value, try to sum oid */
        ret = EncodePolicyOID(out, &outSz, s, NULL);
        if (ret == 0 && outSz > 0) {
            /* If numerical encode succeeded then just
             * create object from that because sums are
             * not unique and can cause confusion. */
            obj = wolfSSL_ASN1_OBJECT_new();
            if (obj == NULL) {
                WOLFSSL_MSG("Issue creating WOLFSSL_ASN1_OBJECT struct");
                return NULL;
            }
            obj->dynamic |= WOLFSSL_ASN1_DYNAMIC;
            obj->obj = (byte*)XMALLOC(1 + MAX_LENGTH_SZ + outSz, NULL,
                    DYNAMIC_TYPE_ASN1);
            if (obj->obj == NULL) {
                wolfSSL_ASN1_OBJECT_free(obj);
                return NULL;
            }
            obj->dynamic |= WOLFSSL_ASN1_DYNAMIC_DATA ;
            i = SetObjectId(outSz, (byte*)obj->obj);
            XMEMCPY((byte*)obj->obj + i, out, outSz);
            obj->objSz = i + outSz;
            return obj;
        }

        /* TODO: update short names in wolfssl_object_info and check OID sums
           are correct */
        for (i = 0; i < (int)WOLFSSL_OBJECT_INFO_SZ; i++) {
            /* Short name, long name, and numerical value are interpreted */
            if (no_name == 0 &&
                ((XSTRCMP(s, wolfssl_object_info[i].sName) == 0) ||
                 (XSTRCMP(s, wolfssl_object_info[i].lName) == 0)))
            {
                    nid = wolfssl_object_info[i].nid;
            }
        }

        if (nid != NID_undef)
            return wolfSSL_OBJ_nid2obj(nid);

        return NULL;
    }
#endif

    /* compatibility function. Its intended use is to remove OID's from an
     * internal table that have been added with OBJ_create. wolfSSL manages its
     * own internal OID values and does not currently support OBJ_create. */
    void wolfSSL_OBJ_cleanup(void)
    {
        WOLFSSL_ENTER("wolfSSL_OBJ_cleanup()");
    }

    #ifndef NO_WOLFSSL_STUB
    int wolfSSL_OBJ_create(const char *oid, const char *sn, const char *ln)
    {
        (void)oid;
        (void)sn;
        (void)ln;
        WOLFSSL_STUB("wolfSSL_OBJ_create");
        return WOLFSSL_FAILURE;
    }
    #endif

    void wolfSSL_set_verify_depth(WOLFSSL *ssl, int depth)
    {
    #if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
        WOLFSSL_ENTER("wolfSSL_set_verify_depth");
        ssl->options.verifyDepth = (byte)depth;
    #endif
    }

#endif /* OPENSSL_ALL || HAVE_LIGHTY || WOLFSSL_MYSQL_COMPATIBLE ||
    HAVE_STUNNEL || WOLFSSL_NGINX || HAVE_POCO_LIB || WOLFSSL_HAPROXY */
#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL) || \
    defined(HAVE_LIGHTY) || defined(WOLFSSL_MYSQL_COMPATIBLE) || \
    defined(HAVE_STUNNEL) || defined(WOLFSSL_NGINX) || \
    defined(HAVE_POCO_LIB) || defined(WOLFSSL_HAPROXY)
    WOLFSSL_ASN1_OBJECT * wolfSSL_X509_NAME_ENTRY_get_object(WOLFSSL_X509_NAME_ENTRY *ne)
    {
#ifdef WOLFSSL_DEBUG_OPENSSL
        WOLFSSL_ENTER("wolfSSL_X509_NAME_ENTRY_get_object");
#endif
        if (ne == NULL) {
            return NULL;
        }

        ne->object = wolfSSL_OBJ_nid2obj_ex(ne->nid, ne->object);

        return ne->object;
    }


#endif /* OPENSSL_ALL || HAVE_LIGHTY || WOLFSSL_MYSQL_COMPATIBLE ||
    HAVE_STUNNEL || WOLFSSL_NGINX || HAVE_POCO_LIB || WOLFSSL_HAPROXY */

#ifdef OPENSSL_EXTRA

/* wolfSSL uses negative values for error states. This function returns an
 * unsigned type so the value returned is the absolute value of the error.
 */
unsigned long wolfSSL_ERR_peek_last_error_line(const char **file, int *line)
{
    WOLFSSL_ENTER("wolfSSL_ERR_peek_last_error");

    (void)line;
    (void)file;
#ifdef WOLFSSL_HAVE_ERROR_QUEUE
    {
        int ret;

        if ((ret = wc_PeekErrorNode(-1, file, NULL, line)) < 0) {
            WOLFSSL_MSG("Issue peeking at error node in queue");
            return 0;
        }
    #if defined(OPENSSL_ALL) || defined(WOLFSSL_NGINX) \
        || defined(WOLFSSL_HAPROXY)
        if (ret == -ASN_NO_PEM_HEADER)
            return (ERR_LIB_PEM << 24) | PEM_R_NO_START_LINE;
    #endif
    #if defined(OPENSSL_ALL) && defined(WOLFSSL_PYTHON)
        if (ret == ASN1_R_HEADER_TOO_LONG) {
            return (ERR_LIB_ASN1 << 24) | ASN1_R_HEADER_TOO_LONG;
        }
    #endif
        return (unsigned long)ret;
    }
#else
    return (unsigned long)(0 - NOT_COMPILED_IN);
#endif
}


#ifndef NO_CERTS
int wolfSSL_CTX_use_PrivateKey(WOLFSSL_CTX *ctx, WOLFSSL_EVP_PKEY *pkey)
{
    WOLFSSL_ENTER("wolfSSL_CTX_use_PrivateKey");

    if (ctx == NULL || pkey == NULL) {
        return WOLFSSL_FAILURE;
    }

    switch (pkey->type) {
#if defined(WOLFSSL_KEY_GEN) && !defined(HAVE_USER_RSA) && !defined(NO_RSA)
    case EVP_PKEY_RSA:
        WOLFSSL_MSG("populating RSA key");
        if (PopulateRSAEvpPkeyDer(pkey) != WOLFSSL_SUCCESS)
            return WOLFSSL_FAILURE;
        break;
#endif /* (WOLFSSL_KEY_GEN || OPENSSL_EXTRA) && !NO_RSA */
#if !defined(HAVE_SELFTEST) && (defined(WOLFSSL_KEY_GEN) || \
        defined(WOLFSSL_CERT_GEN)) && !defined(NO_DSA)
    case EVP_PKEY_DSA:
        break;
#endif /* !HAVE_SELFTEST && (WOLFSSL_KEY_GEN || WOLFSSL_CERT_GEN) && !NO_DSA */
#ifdef HAVE_ECC
    case EVP_PKEY_EC:
        WOLFSSL_MSG("populating ECC key");
        if (ECC_populate_EVP_PKEY(pkey, pkey->ecc)
                != WOLFSSL_SUCCESS)
            return WOLFSSL_FAILURE;
        break;
#endif
    default:
        return WOLFSSL_FAILURE;
    }

    if (pkey->pkey.ptr != NULL) {
        /* ptr for WOLFSSL_EVP_PKEY struct is expected to be DER format */
        return wolfSSL_CTX_use_PrivateKey_buffer(ctx,
                                       (const unsigned char*)pkey->pkey.ptr,
                                       pkey->pkey_sz, SSL_FILETYPE_ASN1);
    }

    WOLFSSL_MSG("wolfSSL private key not set");
    return BAD_FUNC_ARG;
}
#endif /* !NO_CERTS */

#endif /* OPENSSL_EXTRA */

#if defined(HAVE_EX_DATA) && \
   (defined(OPENSSL_ALL) || defined(WOLFSSL_NGINX) || \
    defined(WOLFSSL_HAPROXY) || defined(OPENSSL_EXTRA) || \
    defined(HAVE_LIGHTY)) || defined(HAVE_EX_DATA) || \
    defined(WOLFSSL_WPAS_SMALL)
/**
 * get_ex_new_index is a helper function for the following
 * xx_get_ex_new_index functions:
 *  - wolfSSL_CRYPTO_get_ex_new_index
 *  - wolfSSL_CTX_get_ex_new_index
 *  - wolfSSL_get_ex_new_index
 * Issues a unique index number for the specified class-index.
 * Returns an index number greater or equal to zero on success,
 * -1 on failure.
 */
int wolfssl_get_ex_new_index(int class_index)
{
    /* index counter for each class index*/
    static int ctx_idx = 0;
    static int ssl_idx = 0;
    static int ssl_session_idx = 0;
    static int x509_idx = 0;

    int idx = -1;

    switch(class_index) {
        case WOLF_CRYPTO_EX_INDEX_SSL:
            idx = ssl_idx++;
            break;
        case WOLF_CRYPTO_EX_INDEX_SSL_CTX:
            idx = ctx_idx++;
            break;
        case WOLF_CRYPTO_EX_INDEX_X509:
            idx = x509_idx++;
            break;
        case WOLF_CRYPTO_EX_INDEX_SSL_SESSION:
            idx = ssl_session_idx++;
            break;

        /* following class indexes are not supoprted */
        case WOLF_CRYPTO_EX_INDEX_X509_STORE:
        case WOLF_CRYPTO_EX_INDEX_X509_STORE_CTX:
        case WOLF_CRYPTO_EX_INDEX_DH:
        case WOLF_CRYPTO_EX_INDEX_DSA:
        case WOLF_CRYPTO_EX_INDEX_EC_KEY:
        case WOLF_CRYPTO_EX_INDEX_RSA:
        case WOLF_CRYPTO_EX_INDEX_ENGINE:
        case WOLF_CRYPTO_EX_INDEX_UI:
        case WOLF_CRYPTO_EX_INDEX_BIO:
        case WOLF_CRYPTO_EX_INDEX_APP:
        case WOLF_CRYPTO_EX_INDEX_UI_METHOD:
        case WOLF_CRYPTO_EX_INDEX_DRBG:
        default:
            break;
    }
    return idx;
}
#endif /* HAVE_EX_DATA || WOLFSSL_WPAS_SMALL */

#if defined(HAVE_EX_DATA) || defined(WOLFSSL_WPAS_SMALL)
void* wolfSSL_CTX_get_ex_data(const WOLFSSL_CTX* ctx, int idx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_get_ex_data");
#ifdef HAVE_EX_DATA
    if(ctx != NULL) {
        return wolfSSL_CRYPTO_get_ex_data(&ctx->ex_data, idx);
    }
#else
    (void)ctx;
    (void)idx;
#endif
    return NULL;
}

int wolfSSL_CTX_get_ex_new_index(long idx, void* arg, void* a, void* b,
                                void* c)
{

    WOLFSSL_ENTER("wolfSSL_CTX_get_ex_new_index");

    WOLFSSL_CRYPTO_EX_DATA_IGNORE_PARAMS(idx, arg, a, b, c);

    return wolfssl_get_ex_new_index(WOLF_CRYPTO_EX_INDEX_SSL_CTX);
}

/* Return the index that can be used for the WOLFSSL structure to store
 * application data.
 *
 */
int wolfSSL_get_ex_new_index(long argValue, void* arg,
        WOLFSSL_CRYPTO_EX_new* cb1, WOLFSSL_CRYPTO_EX_dup* cb2,
        WOLFSSL_CRYPTO_EX_free* cb3)
{
    WOLFSSL_ENTER("wolfSSL_get_ex_new_index");

    WOLFSSL_CRYPTO_EX_DATA_IGNORE_PARAMS(argValue, arg, cb1, cb2, cb3);

    return wolfssl_get_ex_new_index(WOLF_CRYPTO_EX_INDEX_SSL);
}


int wolfSSL_CTX_set_ex_data(WOLFSSL_CTX* ctx, int idx, void* data)
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_ex_data");
    #ifdef HAVE_EX_DATA
    if (ctx != NULL)
    {
        return wolfSSL_CRYPTO_set_ex_data(&ctx->ex_data, idx, data);
    }
    #else
    (void)ctx;
    (void)idx;
    (void)data;
    #endif
    return WOLFSSL_FAILURE;
}

#ifdef HAVE_EX_DATA_CLEANUP_HOOKS
int wolfSSL_CTX_set_ex_data_with_cleanup(
    WOLFSSL_CTX* ctx,
    int idx,
    void* data,
    wolfSSL_ex_data_cleanup_routine_t cleanup_routine)
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_ex_data_with_cleanup");
    if (ctx != NULL)
    {
        return wolfSSL_CRYPTO_set_ex_data_with_cleanup(&ctx->ex_data, idx, data,
                                                       cleanup_routine);
    }
    return WOLFSSL_FAILURE;
}
#endif /* HAVE_EX_DATA_CLEANUP_HOOKS */

#endif /* defined(HAVE_EX_DATA) || defined(WOLFSSL_WPAS_SMALL) */

#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)

/* Returns char* to app data stored in ex[0].
 *
 * ssl WOLFSSL structure to get app data from
 */
void* wolfSSL_get_app_data(const WOLFSSL *ssl)
{
    /* checkout exdata stuff... */
    WOLFSSL_ENTER("wolfSSL_get_app_data");

    return wolfSSL_get_ex_data(ssl, 0);
}


/* Set ex array 0 to have app data
 *
 * ssl WOLFSSL struct to set app data in
 * arg data to be stored
 *
 * Returns WOLFSSL_SUCCESS on success and SSL_FAILURE on failure
 */
int wolfSSL_set_app_data(WOLFSSL *ssl, void* arg) {
    WOLFSSL_ENTER("wolfSSL_set_app_data");

    return wolfSSL_set_ex_data(ssl, 0, arg);
}

#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL */

#if defined(HAVE_EX_DATA) || defined(OPENSSL_EXTRA) || \
    defined(OPENSSL_EXTRA_X509_SMALL) || defined(WOLFSSL_WPAS_SMALL)

int wolfSSL_set_ex_data(WOLFSSL* ssl, int idx, void* data)
{
    WOLFSSL_ENTER("wolfSSL_set_ex_data");
#ifdef HAVE_EX_DATA
    if (ssl != NULL)
    {
        return wolfSSL_CRYPTO_set_ex_data(&ssl->ex_data, idx, data);
    }
#else
    WOLFSSL_MSG("HAVE_EX_DATA macro is not defined");
    (void)ssl;
    (void)idx;
    (void)data;
#endif
    return WOLFSSL_FAILURE;
}

#ifdef HAVE_EX_DATA_CLEANUP_HOOKS
int wolfSSL_set_ex_data_with_cleanup(
    WOLFSSL* ssl,
    int idx,
    void* data,
    wolfSSL_ex_data_cleanup_routine_t cleanup_routine)
{
    WOLFSSL_ENTER("wolfSSL_set_ex_data_with_cleanup");
    if (ssl != NULL)
    {
        return wolfSSL_CRYPTO_set_ex_data_with_cleanup(&ssl->ex_data, idx, data,
                                                       cleanup_routine);
    }
    return WOLFSSL_FAILURE;
}
#endif /* HAVE_EX_DATA_CLEANUP_HOOKS */

void* wolfSSL_get_ex_data(const WOLFSSL* ssl, int idx)
{
    WOLFSSL_ENTER("wolfSSL_get_ex_data");
#ifdef HAVE_EX_DATA
    if (ssl != NULL) {
        return wolfSSL_CRYPTO_get_ex_data(&ssl->ex_data, idx);
    }
#else
    WOLFSSL_MSG("HAVE_EX_DATA macro is not defined");
    (void)ssl;
    (void)idx;
#endif
    return 0;
}

#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL || WOLFSSL_WPAS_SMALL */

#if defined(HAVE_LIGHTY) || defined(HAVE_STUNNEL) \
    || defined(WOLFSSL_MYSQL_COMPATIBLE) || defined(OPENSSL_EXTRA)

#if defined(OPENSSL_EXTRA) && !defined(NO_DH)
/* Initialize ctx->dh with dh's params. Return WOLFSSL_SUCCESS on ok */
long wolfSSL_CTX_set_tmp_dh(WOLFSSL_CTX* ctx, WOLFSSL_DH* dh)
{
    int pSz, gSz;
    byte *p, *g;
    int ret=0;

    WOLFSSL_ENTER("wolfSSL_CTX_set_tmp_dh");

    if(!ctx || !dh)
        return BAD_FUNC_ARG;

    /* Get needed size for p and g */
    pSz = wolfSSL_BN_bn2bin(dh->p, NULL);
    gSz = wolfSSL_BN_bn2bin(dh->g, NULL);

    if(pSz <= 0 || gSz <= 0)
        return WOLFSSL_FATAL_ERROR;

    p = (byte*)XMALLOC(pSz, ctx->heap, DYNAMIC_TYPE_PUBLIC_KEY);
    if(!p)
        return MEMORY_E;

    g = (byte*)XMALLOC(gSz, ctx->heap, DYNAMIC_TYPE_PUBLIC_KEY);
    if(!g) {
        XFREE(p, ctx->heap, DYNAMIC_TYPE_PUBLIC_KEY);
        return MEMORY_E;
    }

    pSz = wolfSSL_BN_bn2bin(dh->p, p);
    gSz = wolfSSL_BN_bn2bin(dh->g, g);

    if(pSz >= 0 && gSz >= 0) /* Conversion successful */
        ret = wolfSSL_CTX_SetTmpDH(ctx, p, pSz, g, gSz);

    XFREE(p, ctx->heap, DYNAMIC_TYPE_PUBLIC_KEY);
    XFREE(g, ctx->heap, DYNAMIC_TYPE_PUBLIC_KEY);

    return pSz > 0 && gSz > 0 ? ret : WOLFSSL_FATAL_ERROR;
}
#endif /* OPENSSL_EXTRA && !NO_DH */


/* returns the enum value associated with handshake state
 *
 * ssl the WOLFSSL structure to get state of
 */
int wolfSSL_get_state(const WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_get_state");

    if (ssl == NULL) {
        WOLFSSL_MSG("Null argument passed in");
        return SSL_FAILURE;
    }

    return ssl->options.handShakeState;
}
#endif /* HAVE_LIGHTY || HAVE_STUNNEL || WOLFSSL_MYSQL_COMPATIBLE */

#ifdef OPENSSL_EXTRA
void wolfSSL_certs_clear(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_certs_clear()");

    if (ssl == NULL)
        return;

    /* ctx still owns certificate, certChain, key, dh, and cm */
    if (ssl->buffers.weOwnCert)
        FreeDer(&ssl->buffers.certificate);
    ssl->buffers.certificate = NULL;
    if (ssl->buffers.weOwnCertChain)
        FreeDer(&ssl->buffers.certChain);
    ssl->buffers.certChain = NULL;
#ifdef WOLFSSL_TLS13
    ssl->buffers.certChainCnt = 0;
#endif
    if (ssl->buffers.weOwnKey)
        FreeDer(&ssl->buffers.key);
    ssl->buffers.key      = NULL;
    ssl->buffers.keyType  = 0;
    ssl->buffers.keyId    = 0;
    ssl->buffers.keyLabel = 0;
    ssl->buffers.keySz    = 0;
    ssl->buffers.keyDevId = 0;
}
#endif

#if defined(OPENSSL_ALL) || defined(WOLFSSL_ASIO) || defined(WOLFSSL_HAPROXY) \
    || defined(WOLFSSL_NGINX) || defined(WOLFSSL_QT)

long wolfSSL_ctrl(WOLFSSL* ssl, int cmd, long opt, void* pt)
{
    WOLFSSL_ENTER("wolfSSL_ctrl");
    if (ssl == NULL)
        return BAD_FUNC_ARG;

    switch (cmd) {
        #if defined(WOLFSSL_NGINX) || defined(WOLFSSL_QT) || defined(OPENSSL_ALL)
        #ifdef HAVE_SNI
        case SSL_CTRL_SET_TLSEXT_HOSTNAME:
            WOLFSSL_MSG("Entering Case: SSL_CTRL_SET_TLSEXT_HOSTNAME.");
            if (pt == NULL) {
                WOLFSSL_MSG("Passed in NULL Host Name.");
                break;
            }
            return wolfSSL_set_tlsext_host_name(ssl, (const char*) pt);
        #endif /* HAVE_SNI */
        #endif /* WOLFSSL_NGINX || WOLFSSL_QT || OPENSSL_ALL */
        default:
            WOLFSSL_MSG("Case not implemented.");
    }
    (void)opt;
    (void)pt;
    return WOLFSSL_FAILURE;
}

long wolfSSL_CTX_ctrl(WOLFSSL_CTX* ctx, int cmd, long opt, void* pt)
{
#if defined(OPENSSL_EXTRA) || defined(HAVE_WEBSERVER)
    long ctrl_opt;
#endif
    long ret = WOLFSSL_SUCCESS;

    WOLFSSL_ENTER("wolfSSL_CTX_ctrl");
    if (ctx == NULL)
        return WOLFSSL_FAILURE;

    switch (cmd) {
    case SSL_CTRL_CHAIN:
#ifdef SESSION_CERTS
    {
        /*
         * We don't care about opt here because a copy of the certificate is
         * stored anyway so increasing the reference counter is not necessary.
         * Just check to make sure that it is set to one of the correct values.
         */
        WOLF_STACK_OF(WOLFSSL_X509)* sk = (WOLF_STACK_OF(WOLFSSL_X509)*) pt;
        WOLFSSL_X509* x509;
        int i;
        if (opt != 0 && opt != 1) {
            ret = WOLFSSL_FAILURE;
            break;
        }
        /* Clear certificate chain */
        FreeDer(&ctx->certChain);
        if (sk) {
            for (i = 0; i < wolfSSL_sk_X509_num(sk); i++) {
                x509 = wolfSSL_sk_X509_value(sk, i);
                /* Prevent wolfSSL_CTX_add_extra_chain_cert from freeing cert */
                if (wolfSSL_X509_up_ref(x509) != 1) {
                    WOLFSSL_MSG("Error increasing reference count");
                    continue;
                }
                if (wolfSSL_CTX_add_extra_chain_cert(ctx, x509) !=
                        WOLFSSL_SUCCESS) {
                    WOLFSSL_MSG("Error adding certificate to context");
                    /* Decrease reference count on failure */
                    wolfSSL_X509_free(x509);
                }
            }
        }
        /* Free previous chain */
        wolfSSL_sk_X509_pop_free(ctx->x509Chain, NULL);
        ctx->x509Chain = sk;
        if (sk && opt == 1) {
            /* up all refs when opt == 1 */
            for (i = 0; i < wolfSSL_sk_X509_num(sk); i++) {
                x509 = wolfSSL_sk_X509_value(sk, i);
                if (wolfSSL_X509_up_ref(x509) != 1) {
                    WOLFSSL_MSG("Error increasing reference count");
                    continue;
                }
            }
        }
    }
#else
        WOLFSSL_MSG("Session certificates not compiled in");
        ret = WOLFSSL_FAILURE;
#endif
        break;

#if defined(OPENSSL_EXTRA) || defined(HAVE_WEBSERVER)
    case SSL_CTRL_OPTIONS:
        WOLFSSL_MSG("Entering Case: SSL_CTRL_OPTIONS.");
        ctrl_opt = wolfSSL_CTX_set_options(ctx, opt);

        #ifdef WOLFSSL_QT
        /* Set whether to use client or server cipher preference */
        if ((ctrl_opt & WOLFSSL_OP_CIPHER_SERVER_PREFERENCE)
                     == WOLFSSL_OP_CIPHER_SERVER_PREFERENCE) {
            WOLFSSL_MSG("Using Server's Cipher Preference.");
            ctx->useClientOrder = FALSE;
        } else {
            WOLFSSL_MSG("Using Client's Cipher Preference.");
            ctx->useClientOrder = TRUE;
        }
        #endif /* WOLFSSL_QT */

        return ctrl_opt;
#endif /* OPENSSL_EXTRA || HAVE_WEBSERVER */
    case SSL_CTRL_EXTRA_CHAIN_CERT:
        WOLFSSL_MSG("Entering Case: SSL_CTRL_EXTRA_CHAIN_CERT.");
        if (pt == NULL) {
            WOLFSSL_MSG("Passed in x509 pointer NULL.");
            ret = WOLFSSL_FAILURE;
            break;
        }
        return wolfSSL_CTX_add_extra_chain_cert(ctx, (WOLFSSL_X509*)pt);

#ifndef NO_DH
    case SSL_CTRL_SET_TMP_DH:
        WOLFSSL_MSG("Entering Case: SSL_CTRL_SET_TMP_DH.");
        if (pt == NULL) {
            WOLFSSL_MSG("Passed in DH pointer NULL.");
            ret = WOLFSSL_FAILURE;
            break;
        }
        return wolfSSL_CTX_set_tmp_dh(ctx, (WOLFSSL_DH*)pt);
#endif

#ifdef HAVE_ECC
    case SSL_CTRL_SET_TMP_ECDH:
        WOLFSSL_MSG("Entering Case: SSL_CTRL_SET_TMP_ECDH.");
        if (pt == NULL) {
            WOLFSSL_MSG("Passed in ECDH pointer NULL.");
            ret = WOLFSSL_FAILURE;
            break;
        }
        return wolfSSL_SSL_CTX_set_tmp_ecdh(ctx, (WOLFSSL_EC_KEY*)pt);
#endif
    case SSL_CTRL_MODE:
        wolfSSL_CTX_set_mode(ctx,opt);
        break;
    case SSL_CTRL_SET_MIN_PROTO_VERSION:
        WOLFSSL_MSG("set min proto version");
        return wolfSSL_CTX_set_min_proto_version(ctx, (int)opt);
    case SSL_CTRL_SET_MAX_PROTO_VERSION:
        WOLFSSL_MSG("set max proto version");
        return wolfSSL_CTX_set_max_proto_version(ctx, (int)opt);
    case SSL_CTRL_GET_MIN_PROTO_VERSION:
        WOLFSSL_MSG("get min proto version");
        return wolfSSL_CTX_get_min_proto_version(ctx);
    case SSL_CTRL_GET_MAX_PROTO_VERSION:
        WOLFSSL_MSG("get max proto version");
        return wolfSSL_CTX_get_max_proto_version(ctx);
    default:
        WOLFSSL_MSG("CTX_ctrl cmd not implemented");
        ret = WOLFSSL_FAILURE;
        break;
    }

    (void)ctx;
    (void)cmd;
    (void)opt;
    (void)pt;
    WOLFSSL_LEAVE("wolfSSL_CTX_ctrl", (int)ret);
    return ret;
}

#ifndef WOLFSSL_NO_STUB
long wolfSSL_CTX_callback_ctrl(WOLFSSL_CTX* ctx, int cmd, void (*fp)(void))
{
    (void) ctx;
    (void) cmd;
    (void) fp;
    WOLFSSL_STUB("wolfSSL_CTX_callback_ctrl");
    return WOLFSSL_FAILURE;

}
#endif /* WOLFSSL_NO_STUB */

#ifndef NO_WOLFSSL_STUB
long wolfSSL_CTX_clear_extra_chain_certs(WOLFSSL_CTX* ctx)
{
    return wolfSSL_CTX_ctrl(ctx, SSL_CTRL_CLEAR_EXTRA_CHAIN_CERTS, 0L, NULL);
}
#endif

/* Returns the verifyCallback from the ssl structure if successful.
Returns NULL otherwise. */
VerifyCallback wolfSSL_get_verify_callback(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_get_verify_callback()");
    if (ssl) {
        return ssl->verifyCallback;
    }
    return NULL;
}

/* Adds the ASN1 certificate to the user ctx.
Returns WOLFSSL_SUCCESS if no error, returns WOLFSSL_FAILURE otherwise.*/
int wolfSSL_CTX_use_certificate_ASN1(WOLFSSL_CTX *ctx, int derSz,
                                                       const unsigned char *der)
{
    WOLFSSL_ENTER("wolfSSL_CTX_use_certificate_ASN1()");
    if (der != NULL && ctx != NULL) {
        if (wolfSSL_CTX_use_certificate_buffer(ctx, der, derSz,
                                      WOLFSSL_FILETYPE_ASN1) == WOLFSSL_SUCCESS) {
            return WOLFSSL_SUCCESS;
        }

    }
    return WOLFSSL_FAILURE;
}


#if !defined(HAVE_FAST_RSA) && defined(WOLFSSL_KEY_GEN) && \
    !defined(NO_RSA) && !defined(HAVE_USER_RSA)
/* Adds the rsa private key to the user ctx.
Returns WOLFSSL_SUCCESS if no error, returns WOLFSSL_FAILURE otherwise.*/
int wolfSSL_CTX_use_RSAPrivateKey(WOLFSSL_CTX* ctx, WOLFSSL_RSA* rsa)
{
    int ret;
    int derSize;
    unsigned char *maxDerBuf;
    unsigned char* key = NULL;

    WOLFSSL_ENTER("wolfSSL_CTX_use_RSAPrivateKey()");

    if (ctx == NULL || rsa == NULL) {
        WOLFSSL_MSG("one or more inputs were NULL");
        return BAD_FUNC_ARG;
    }
    maxDerBuf = (unsigned char*)XMALLOC(4096, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    if (maxDerBuf == NULL) {
        WOLFSSL_MSG("Malloc failure");
        return MEMORY_E;
    }
    key = maxDerBuf;
    /* convert RSA struct to der encoded buffer and get the size */
    if ((derSize = wolfSSL_i2d_RSAPrivateKey(rsa, &key)) <= 0) {
        WOLFSSL_MSG("wolfSSL_i2d_RSAPrivateKey() failure");
        XFREE(maxDerBuf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        return WOLFSSL_FAILURE;
    }
    ret = wolfSSL_CTX_use_PrivateKey_buffer(ctx, (const unsigned char*)maxDerBuf,
                                                    derSize, SSL_FILETYPE_ASN1);
    if (ret != WOLFSSL_SUCCESS) {
        WOLFSSL_MSG("wolfSSL_CTX_USE_PrivateKey_buffer() failure");
        XFREE(maxDerBuf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        return WOLFSSL_FAILURE;
    }
    XFREE(maxDerBuf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    return ret;
}
#endif /* NO_RSA && !HAVE_FAST_RSA */


#ifndef NO_BIO
/* Converts EVP_PKEY data from a bio buffer to a WOLFSSL_EVP_PKEY structure.
Returns pointer to private EVP_PKEY struct upon success, NULL if there
is a failure.*/
WOLFSSL_EVP_PKEY* wolfSSL_d2i_PrivateKey_bio(WOLFSSL_BIO* bio,
                                                         WOLFSSL_EVP_PKEY** out)
{
    unsigned char* mem = NULL;
    int memSz = 0;
    WOLFSSL_EVP_PKEY* key = NULL;
    int i = 0, j = 0;
    unsigned char* extraBioMem = NULL;
    int extraBioMemSz = 0;
    int derLength = 0;

    WOLFSSL_ENTER("wolfSSL_d2i_PrivateKey_bio()");

    if (bio == NULL) {
        return NULL;
    }
    (void)out;

    memSz = wolfSSL_BIO_get_len(bio);
    if (memSz <= 0) {
        WOLFSSL_MSG("wolfSSL_BIO_get_len() failure");
        return NULL;
    }

    mem = (unsigned char*)XMALLOC(memSz, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
    if (mem == NULL) {
        WOLFSSL_MSG("Malloc failure");
        return NULL;
    }

    if (wolfSSL_BIO_read(bio, (unsigned char*)mem, memSz) == memSz) {
        /* Determines key type and returns the new private EVP_PKEY object */
        if ((key = wolfSSL_d2i_PrivateKey_EVP(NULL, &mem, (long)memSz)) == NULL) {
            WOLFSSL_MSG("wolfSSL_d2i_PrivateKey_EVP() failure");
            XFREE(mem, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
            return NULL;
        }

        /* Write extra data back into bio object if necessary. */
        derLength = key->pkey_sz;
        extraBioMemSz = (memSz - derLength);
        if (extraBioMemSz > 0) {
            extraBioMem = (unsigned char *)XMALLOC(extraBioMemSz, NULL,
                                                       DYNAMIC_TYPE_TMP_BUFFER);
            if (extraBioMem == NULL) {
                WOLFSSL_MSG("Malloc failure");
                XFREE((unsigned char*)extraBioMem, bio->heap,
                                                       DYNAMIC_TYPE_TMP_BUFFER);
                XFREE(mem, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
                return NULL;
            }

            for (i = derLength; i < memSz; i++) {
                *(extraBioMem + j) = *(mem + i);
                j++;
            }

            wolfSSL_BIO_write(bio, extraBioMem, extraBioMemSz);
            if (wolfSSL_BIO_get_len(bio) <= 0) {
                WOLFSSL_MSG("Failed to write memory to bio");
                XFREE((unsigned char*)extraBioMem, bio->heap,
                                                       DYNAMIC_TYPE_TMP_BUFFER);
                XFREE(mem, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
                return NULL;
            }
            XFREE((unsigned char*)extraBioMem, bio->heap,
                                                       DYNAMIC_TYPE_TMP_BUFFER);
        }

        if (out != NULL) {
            *out = key;
        }
    }
    XFREE(mem, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
    return key;
}
#endif /* !NO_BIO */

#endif /* OPENSSL_ALL || WOLFSSL_ASIO || WOLFSSL_HAPROXY || WOLFSSL_QT */


#if defined(OPENSSL_ALL) || defined(WOLFSSL_ASIO) || defined(WOLFSSL_HAPROXY) || \
    defined(WOLFSSL_NGINX) || defined(WOLFSSL_QT) || defined(WOLFSSL_WPAS_SMALL)

/* Converts a DER encoded private key to a WOLFSSL_EVP_PKEY structure.
 * returns a pointer to a new WOLFSSL_EVP_PKEY structure on success and NULL
 * on fail */
WOLFSSL_EVP_PKEY* wolfSSL_d2i_PrivateKey_EVP(WOLFSSL_EVP_PKEY** out,
                                                  unsigned char** in, long inSz)
{
    WOLFSSL_ENTER("wolfSSL_d2i_PrivateKey_EVP");
    return d2iGenericKey(out, (const unsigned char**)in, inSz, 1);
}

#endif /* OPENSSL_ALL || WOLFSSL_ASIO || WOLFSSL_HAPROXY || WOLFSSL_QT || WOLFSSL_WPAS_SMALL*/


/* stunnel compatibility functions*/
#if defined(OPENSSL_ALL) || (defined(OPENSSL_EXTRA) && (defined(HAVE_STUNNEL) || \
                             defined(WOLFSSL_NGINX) || defined(HAVE_LIGHTY) || \
                             defined(WOLFSSL_HAPROXY) || defined(WOLFSSL_OPENSSH)))
void wolfSSL_ERR_remove_thread_state(void* pid)
{
    (void) pid;
    return;
}

#ifndef NO_FILESYSTEM
/***TBD ***/
void wolfSSL_print_all_errors_fp(XFILE fp)
{
    (void)fp;
}
#endif /* !NO_FILESYSTEM */

#endif /* OPENSSL_ALL || OPENSSL_EXTRA || HAVE_STUNNEL || WOLFSSL_NGINX ||
    HAVE_LIGHTY || WOLFSSL_HAPROXY || WOLFSSL_OPENSSH */


#if defined(OPENSSL_EXTRA) || defined(WOLFSSL_WPAS_SMALL) || \
    defined(HAVE_EX_DATA)

#if defined(HAVE_EX_DATA) && !defined(NO_SESSION_CACHE)
static void SESSION_ex_data_cache_update(WOLFSSL_SESSION* session, int idx,
        void* data, byte get, void** getRet, int* setRet)
{
    int row;
    int i;
    int error = 0;
    SessionRow* sessRow = NULL;
    const byte* id;
    byte foundCache = 0;

    if (getRet != NULL)
        *getRet = NULL;
    if (setRet != NULL)
        *setRet = WOLFSSL_FAILURE;

    id = session->sessionID;
    if (session->haveAltSessionID)
        id = session->altSessionID;

    row = (int)(HashObject(id, ID_LEN, &error) % SESSION_ROWS);
    if (error != 0) {
        WOLFSSL_MSG("Hash session failed");
        return;
    }

    sessRow = &SessionCache[row];
    if (SESSION_ROW_LOCK(sessRow) != 0) {
        WOLFSSL_MSG("Session row lock failed");
        return;
    }

    for (i = 0; i < SESSIONS_PER_ROW && i < sessRow->totalCount; i++) {
        if (XMEMCMP(id, sessRow->Sessions[i].sessionID, ID_LEN) == 0
                && session->side == sessRow->Sessions[i].side
        #if defined(WOLFSSL_TLS13) && defined(HAVE_SESSION_TICKET)
                && (IsAtLeastTLSv1_3(session->version) ==
                    IsAtLeastTLSv1_3(sessRow->Sessions[i].version))
        #endif
            ) {
            if (get) {
                *getRet = wolfSSL_CRYPTO_get_ex_data(
                        &sessRow->Sessions[i].ex_data, idx);
            }
            else {
                *setRet = wolfSSL_CRYPTO_set_ex_data(
                        &sessRow->Sessions[i].ex_data, idx, data);
            }
            foundCache = 1;
            break;
        }
    }
    SESSION_ROW_UNLOCK(sessRow);
    /* If we don't have a session in cache then clear the ex_data and
     * own it */
    if (!foundCache) {
        XMEMSET(&session->ex_data, 0, sizeof(WOLFSSL_CRYPTO_EX_DATA));
        session->ownExData = 1;
        if (!get) {
            *setRet = wolfSSL_CRYPTO_set_ex_data(&session->ex_data, idx,
                    data);
        }
    }

}
#endif

int wolfSSL_SESSION_set_ex_data(WOLFSSL_SESSION* session, int idx, void* data)
{
    int ret = WOLFSSL_FAILURE;
    WOLFSSL_ENTER("wolfSSL_SESSION_set_ex_data");
#ifdef HAVE_EX_DATA
    session = ClientSessionToSession(session);
    if (session != NULL) {
#ifndef NO_SESSION_CACHE
        if (!session->ownExData) {
            /* Need to update in cache */
            SESSION_ex_data_cache_update(session, idx, data, 0, NULL, &ret);
        }
        else
#endif
        {
            ret = wolfSSL_CRYPTO_set_ex_data(&session->ex_data, idx, data);
        }
    }
#else
    (void)session;
    (void)idx;
    (void)data;
#endif
    return ret;
}

#ifdef HAVE_EX_DATA_CLEANUP_HOOKS
int wolfSSL_SESSION_set_ex_data_with_cleanup(
    WOLFSSL_SESSION* session,
    int idx,
    void* data,
    wolfSSL_ex_data_cleanup_routine_t cleanup_routine)
{
    WOLFSSL_ENTER("wolfSSL_SESSION_set_ex_data_with_cleanup");
    session = ClientSessionToSession(session);
    if(session != NULL) {
        return wolfSSL_CRYPTO_set_ex_data_with_cleanup(&session->ex_data, idx,
                                                       data, cleanup_routine);
    }
    return WOLFSSL_FAILURE;
}
#endif /* HAVE_EX_DATA_CLEANUP_HOOKS */

void* wolfSSL_SESSION_get_ex_data(const WOLFSSL_SESSION* session, int idx)
{
    void* ret = NULL;
    WOLFSSL_ENTER("wolfSSL_SESSION_get_ex_data");
#ifdef HAVE_EX_DATA
    session = ClientSessionToSession(session);
    if (session != NULL) {
#ifndef NO_SESSION_CACHE
        if (!session->ownExData) {
            /* Need to retrieve the data from the session cache */
            SESSION_ex_data_cache_update((WOLFSSL_SESSION*)session, idx, NULL,
                                         1, &ret, NULL);
        }
        else
#endif
        {
            ret = wolfSSL_CRYPTO_get_ex_data(&session->ex_data, idx);
        }
    }
#else
    (void)session;
    (void)idx;
#endif
    return ret;
}
#endif /* OPENSSL_EXTRA || WOLFSSL_WPAS_SMALL || HAVE_EX_DATA */

/* Note: This is a huge section of API's - through
 *       wolfSSL_X509_OBJECT_get0_X509_CRL */
#if defined(OPENSSL_ALL) || (defined(OPENSSL_EXTRA) && \
    (defined(HAVE_STUNNEL) || defined(WOLFSSL_NGINX) || \
    defined(HAVE_LIGHTY) || defined(WOLFSSL_HAPROXY) || \
    defined(WOLFSSL_OPENSSH) || defined(HAVE_SBLIM_SFCB)))
#ifdef HAVE_EX_DATA
int wolfSSL_SESSION_get_ex_new_index(long idx, void* data, void* cb1,
       void* cb2, CRYPTO_free_func* cb3)
{
    WOLFSSL_ENTER("wolfSSL_SESSION_get_ex_new_index");
    WOLFSSL_CRYPTO_EX_DATA_IGNORE_PARAMS(idx, data, cb1, cb2, cb3);
    return wolfssl_get_ex_new_index(WOLF_CRYPTO_EX_INDEX_SSL_SESSION);
}
#endif

#if defined(USE_WOLFSSL_MEMORY) && !defined(WOLFSSL_DEBUG_MEMORY)
static wolfSSL_OSSL_Malloc_cb  ossl_malloc  = NULL;
static wolfSSL_OSSL_Free_cb    ossl_free    = NULL;
static wolfSSL_OSSL_Realloc_cb ossl_realloc = NULL;

static void* OSSL_Malloc(size_t size)
{
    if (ossl_malloc != NULL)
        return ossl_malloc(size, NULL, 0);
    else
        return NULL;
}

static void  OSSL_Free(void *ptr)
{
    if (ossl_free != NULL)
        ossl_free(ptr, NULL, 0);
}

static void* OSSL_Realloc(void *ptr, size_t size)
{
    if (ossl_realloc != NULL)
        return ossl_realloc(ptr, size, NULL, 0);
    else
        return NULL;
}
#endif /* USE_WOLFSSL_MEMORY && !WOLFSSL_DEBUG_MEMORY */

int wolfSSL_CRYPTO_set_mem_functions(
        wolfSSL_OSSL_Malloc_cb  m,
        wolfSSL_OSSL_Realloc_cb r,
        wolfSSL_OSSL_Free_cb    f)
{
#ifdef USE_WOLFSSL_MEMORY
#ifdef WOLFSSL_DEBUG_MEMORY
    WOLFSSL_MSG("mem functions will receive function name instead of "
                "file name");
    if (wolfSSL_SetAllocators((wolfSSL_Malloc_cb)m, (wolfSSL_Free_cb)f,
            (wolfSSL_Realloc_cb)r) == 0)
        return WOLFSSL_SUCCESS;
#else
    WOLFSSL_MSG("wolfSSL was compiled without WOLFSSL_DEBUG_MEMORY mem "
                "functions will receive a NULL file name and 0 for the "
                "line number.");
    if (wolfSSL_SetAllocators((wolfSSL_Malloc_cb)OSSL_Malloc,
           (wolfSSL_Free_cb)OSSL_Free, (wolfSSL_Realloc_cb)OSSL_Realloc) == 0) {
        ossl_malloc = m;
        ossl_free = f;
        ossl_realloc = r;
        return WOLFSSL_SUCCESS;
    }
#endif
    else
        return WOLFSSL_FAILURE;
#else
    (void)m;
    (void)r;
    (void)f;
    WOLFSSL_MSG("wolfSSL allocator callback functions not compiled in");
    return WOLFSSL_FAILURE;
#endif
}

int wolfSSL_ERR_load_ERR_strings(void)
{
    return WOLFSSL_SUCCESS;
}

void wolfSSL_ERR_load_crypto_strings(void)
{
    WOLFSSL_ENTER("wolfSSL_ERR_load_crypto_strings");
    /* Do nothing */
    return;
}

int wolfSSL_FIPS_mode(void)
{
#ifdef HAVE_FIPS
    return 1;
#else
    return 0;
#endif
}

int wolfSSL_FIPS_mode_set(int r)
{
#ifdef HAVE_FIPS
    if (r == 0) {
        WOLFSSL_MSG("Cannot disable FIPS at runtime.");
        return WOLFSSL_FAILURE;
    }
    return WOLFSSL_SUCCESS;
#else
    if (r == 0) {
        return WOLFSSL_SUCCESS;
    }
    WOLFSSL_MSG("Cannot enable FIPS. This isn't the wolfSSL FIPS code.");
    return WOLFSSL_FAILURE;
#endif
}

int wolfSSL_CIPHER_get_bits(const WOLFSSL_CIPHER *c, int *alg_bits)
{
    int ret = WOLFSSL_FAILURE;
    WOLFSSL_ENTER("wolfSSL_CIPHER_get_bits");

    #if defined(WOLFSSL_QT) || defined(OPENSSL_ALL)
    (void)alg_bits;
    if (c!= NULL)
        ret = c->bits;
    #else
    if (c != NULL && c->ssl != NULL) {
        ret = 8 * c->ssl->specs.key_size;
        if (alg_bits != NULL) {
            *alg_bits = ret;
        }
    }
    #endif
    return ret;
}

/* returns value less than 0 on fail to match
 * On a successful match the priority level found is returned
 */
int wolfSSL_sk_SSL_CIPHER_find(
        WOLF_STACK_OF(WOLFSSL_CIPHER)* sk, const WOLFSSL_CIPHER* toFind)
{
    WOLFSSL_STACK* next;
    int i, sz;

    if (sk == NULL || toFind == NULL) {
        return WOLFSSL_FATAL_ERROR;
    }

    sz   = wolfSSL_sk_SSL_CIPHER_num(sk);
    next = sk;
    for (i = 0; i < sz && next != NULL; i++) {
        if (next->data.cipher.cipherSuite0 == toFind->cipherSuite0 &&
                next->data.cipher.cipherSuite == toFind->cipherSuite) {
            return sz - i; /* reverse because stack pushed highest on first */
        }
        next = next->next;
    }
    return WOLFSSL_FATAL_ERROR;
}

/* free's all nodes in the stack and there data */
void wolfSSL_sk_SSL_CIPHER_free(WOLF_STACK_OF(WOLFSSL_CIPHER)* sk)
{
    WOLFSSL_ENTER("wolfSSL_sk_SSL_CIPHER_free");
    wolfSSL_sk_free(sk);
}

#ifdef HAVE_SNI
int wolfSSL_set_tlsext_host_name(WOLFSSL* ssl, const char* host_name)
{
    int ret;
    WOLFSSL_ENTER("wolfSSL_set_tlsext_host_name");
    ret = wolfSSL_UseSNI(ssl, WOLFSSL_SNI_HOST_NAME,
            host_name, (word16)XSTRLEN(host_name));
    WOLFSSL_LEAVE("wolfSSL_set_tlsext_host_name", ret);
    return ret;
}


#ifndef NO_WOLFSSL_SERVER
const char * wolfSSL_get_servername(WOLFSSL* ssl, byte type)
{
    void * serverName = NULL;
    if (ssl == NULL)
        return NULL;
    TLSX_SNI_GetRequest(ssl->extensions, type, &serverName);
    return (const char *)serverName;
}
#endif /* NO_WOLFSSL_SERVER */
#endif /* HAVE_SNI */

WOLFSSL_CTX* wolfSSL_set_SSL_CTX(WOLFSSL* ssl, WOLFSSL_CTX* ctx)
{
    /* This method requires some explanation. Its sibling is
     *   int SetSSL_CTX(WOLFSSL* ssl, WOLFSSL_CTX* ctx, int writeDup)
     * which re-inits the WOLFSSL* with all settings in the new CTX.
     * That one is the right one to use *before* a handshake is started.
     *
     * This method was added by OpenSSL to be used *during* the handshake, e.g.
     * when a server inspects the SNI in a ClientHello callback and
     * decides which set of certificates to use.
     *
     * Since, at the time the SNI callback is run, some decisions on
     * Extensions or the ServerHello might already have been taken, this
     * method is very restricted in what it does:
     * - changing the server certificate(s)
     * - changing the server id for session handling
     * and everything else in WOLFSSL* needs to remain untouched.
     */
    WOLFSSL_ENTER("wolfSSL_set_SSL_CTX");
    if (ssl == NULL || ctx == NULL)
        return NULL;
    if (ssl->ctx == ctx)
        return ssl->ctx;

    if (SSL_CTX_RefCount(ctx, 1) < 0) {
        /* can only fail on serious stuff, like mutex not working
         * or ctx refcount out of whack. */
        return NULL;
    }
    if (ssl->ctx) {
        wolfSSL_CTX_free(ssl->ctx);
    }
    ssl->ctx = ctx;

#ifndef NO_CERTS
    /* ctx owns certificate, certChain and key */
    ssl->buffers.certificate = ctx->certificate;
    ssl->buffers.certChain = ctx->certChain;
#ifdef WOLFSSL_TLS13
    ssl->buffers.certChainCnt = ctx->certChainCnt;
#endif
    ssl->buffers.key      = ctx->privateKey;
    ssl->buffers.keyType  = ctx->privateKeyType;
    ssl->buffers.keyId    = ctx->privateKeyId;
    ssl->buffers.keyLabel = ctx->privateKeyLabel;
    ssl->buffers.keySz    = ctx->privateKeySz;
    ssl->buffers.keyDevId = ctx->privateKeyDevId;
    /* flags indicating what certs/keys are available */
    ssl->options.haveRSA          = ctx->haveRSA;
    ssl->options.haveDH           = ctx->haveDH;
    ssl->options.haveECDSAsig     = ctx->haveECDSAsig;
    ssl->options.haveECC          = ctx->haveECC;
    ssl->options.haveStaticECC    = ctx->haveStaticECC;
    ssl->options.haveFalconSig    = ctx->haveFalconSig;
    ssl->options.haveDilithiumSig = ctx->haveDilithiumSig;
#endif

#ifdef OPENSSL_EXTRA
    /* copy over application session context ID */
    ssl->sessionCtxSz = ctx->sessionCtxSz;
    XMEMCPY(ssl->sessionCtx, ctx->sessionCtx, ctx->sessionCtxSz);
#endif

    return ssl->ctx;
}


VerifyCallback wolfSSL_CTX_get_verify_callback(WOLFSSL_CTX* ctx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_get_verify_callback");
    if(ctx)
        return ctx->verifyCallback;
    return NULL;
}


#ifdef HAVE_SNI

void wolfSSL_CTX_set_servername_callback(WOLFSSL_CTX* ctx, CallbackSniRecv cb)
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_servername_callback");
    if (ctx)
        ctx->sniRecvCb = cb;
}

int wolfSSL_CTX_set_tlsext_servername_callback(WOLFSSL_CTX* ctx,
                                               CallbackSniRecv cb)
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_tlsext_servername_callback");
    if (ctx) {
        ctx->sniRecvCb = cb;
        return WOLFSSL_SUCCESS;
    }
    return WOLFSSL_FAILURE;
}

int wolfSSL_CTX_set_servername_arg(WOLFSSL_CTX* ctx, void* arg)
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_servername_arg");
    if (ctx) {
        ctx->sniRecvCbArg = arg;
        return WOLFSSL_SUCCESS;
    }
    return WOLFSSL_FAILURE;
}

#endif /* HAVE_SNI */


#ifndef NO_BIO
void wolfSSL_ERR_load_BIO_strings(void) {
    WOLFSSL_ENTER("ERR_load_BIO_strings");
    /* do nothing */
}
#endif

#ifndef NO_WOLFSSL_STUB
/* Set THREADID callback, return 1 on success, 0 on error */
int wolfSSL_THREADID_set_callback(
        void(*threadid_func)(WOLFSSL_CRYPTO_THREADID*))
{
    WOLFSSL_ENTER("wolfSSL_THREADID_set_callback");
    WOLFSSL_STUB("CRYPTO_THREADID_set_callback");
    (void)threadid_func;
    return 1;
}
#endif

#ifndef NO_WOLFSSL_STUB
void wolfSSL_THREADID_set_numeric(void* id, unsigned long val)
{
    WOLFSSL_ENTER("wolfSSL_THREADID_set_numeric");
    WOLFSSL_STUB("CRYPTO_THREADID_set_numeric");
    (void)id;
    (void)val;
    return;
}
#endif

#endif /* OPENSSL_ALL || (OPENSSL_EXTRA && (HAVE_STUNNEL || WOLFSSL_NGINX ||
        * HAVE_LIGHTY || WOLFSSL_HAPROXY || WOLFSSL_OPENSSH ||
        * HAVE_SBLIM_SFCB)) */


#if defined(OPENSSL_EXTRA)

int wolfSSL_CRYPTO_memcmp(const void *a, const void *b, size_t size)
{
    if (!a || !b)
        return 0;
    return ConstantCompare((const byte*)a, (const byte*)b, (int)size);
}

unsigned long wolfSSL_ERR_peek_last_error(void)
{
    WOLFSSL_ENTER("wolfSSL_ERR_peek_last_error");

#ifdef WOLFSSL_HAVE_ERROR_QUEUE
    {
        int ret;

        if ((ret = wc_PeekErrorNode(-1, NULL, NULL, NULL)) < 0) {
            WOLFSSL_MSG("Issue peeking at error node in queue");
            return 0;
        }
        if (ret == -ASN_NO_PEM_HEADER)
            return (ERR_LIB_PEM << 24) | PEM_R_NO_START_LINE;
    #if defined(WOLFSSL_PYTHON)
        if (ret == ASN1_R_HEADER_TOO_LONG)
            return (ERR_LIB_ASN1 << 24) | ASN1_R_HEADER_TOO_LONG;
    #endif
        return (unsigned long)ret;
    }
#else
    return (unsigned long)(0 - NOT_COMPILED_IN);
#endif
}

#endif /* OPENSSL_EXTRA */

int wolfSSL_version(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_version");
    if (ssl->version.major == SSLv3_MAJOR) {
        switch (ssl->version.minor) {
            case SSLv3_MINOR :
                return SSL3_VERSION;
            case TLSv1_MINOR :
                return TLS1_VERSION;
            case TLSv1_1_MINOR :
                return TLS1_1_VERSION;
            case TLSv1_2_MINOR :
                return TLS1_2_VERSION;
            case TLSv1_3_MINOR :
                return TLS1_3_VERSION;
            default:
                return WOLFSSL_FAILURE;
        }
    }
    else if (ssl->version.major == DTLS_MAJOR) {
        switch (ssl->version.minor) {
            case DTLS_MINOR :
                return DTLS1_VERSION;
            case DTLSv1_2_MINOR :
                return DTLS1_2_VERSION;
            default:
                return WOLFSSL_FAILURE;
        }
    }
    return WOLFSSL_FAILURE;
}

WOLFSSL_CTX* wolfSSL_get_SSL_CTX(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_get_SSL_CTX");
    return ssl->ctx;
}

#if defined(OPENSSL_ALL) || \
    defined(OPENSSL_EXTRA) || defined(HAVE_STUNNEL) || \
    defined(WOLFSSL_NGINX) || defined(WOLFSSL_HAPROXY)

const byte* wolfSSL_SESSION_get_id(const WOLFSSL_SESSION* sess,
        unsigned int* idLen)
{
    WOLFSSL_ENTER("wolfSSL_SESSION_get_id");
    sess = ClientSessionToSession(sess);
    if (sess == NULL || idLen == NULL) {
        WOLFSSL_MSG("Bad func args. Please provide idLen");
        return NULL;
    }
    *idLen = sess->sessionIDSz;
    return sess->sessionID;
}

#if (defined(HAVE_SESSION_TICKET) || defined(SESSION_CERTS)) && \
    !defined(NO_FILESYSTEM)

#ifndef NO_BIO

#if defined(SESSION_CERTS) || \
   (defined(WOLFSSL_TLS13) && defined(HAVE_SESSION_TICKET))
/* returns a pointer to the protocol used by the session */
static const char* wolfSSL_SESSION_get_protocol(const WOLFSSL_SESSION* in)
{
    in = ClientSessionToSession(in);
    return wolfSSL_internal_get_version((ProtocolVersion*)&in->version);
}
#endif

/* returns true (non 0) if the session has EMS (extended master secret) */
static int wolfSSL_SESSION_haveEMS(const WOLFSSL_SESSION* in)
{
    in = ClientSessionToSession(in);
    if (in == NULL)
        return 0;
    return in->haveEMS;
}

#if defined(HAVE_SESSION_TICKET)
/* prints out the ticket to bio passed in
 * return WOLFSSL_SUCCESS on success
 */
static int wolfSSL_SESSION_print_ticket(WOLFSSL_BIO* bio,
        const WOLFSSL_SESSION* in, const char* tab)
{
    unsigned short i, j, z, sz;
    short tag = 0;
    byte* pt;


    in = ClientSessionToSession(in);
    if (in == NULL || bio == NULL) {
        return BAD_FUNC_ARG;
    }

    sz = in->ticketLen;
    pt = in->ticket;

    if (wolfSSL_BIO_printf(bio, "%s\n", (sz == 0)? " NONE": "") <= 0)
        return WOLFSSL_FAILURE;

    for (i = 0; i < sz;) {
        char asc[16];

        if (sz - i < 16) {
            if (wolfSSL_BIO_printf(bio, "%s%04X -", tab, tag + (sz - i)) <= 0)
                return WOLFSSL_FAILURE;
        }
        else {
            if (wolfSSL_BIO_printf(bio, "%s%04X -", tab, tag) <= 0)
                return WOLFSSL_FAILURE;
        }
        for (j = 0; i < sz && j < 8; j++,i++) {
            asc[j] =  ((pt[i])&0x6f)>='A'?((pt[i])&0x6f):'.';
            if (wolfSSL_BIO_printf(bio, " %02X", pt[i]) <= 0)
                return WOLFSSL_FAILURE;
        }

        if (i < sz) {
            asc[j] =  ((pt[i])&0x6f)>='A'?((pt[i])&0x6f):'.';
            if (wolfSSL_BIO_printf(bio, "-%02X", pt[i]) <= 0)
                return WOLFSSL_FAILURE;
            j++;
            i++;
        }

        for (; i < sz && j < 16; j++,i++) {
            asc[j] =  ((pt[i])&0x6f)>='A'?((pt[i])&0x6f):'.';
            if (wolfSSL_BIO_printf(bio, " %02X", pt[i]) <= 0)
                return WOLFSSL_FAILURE;
        }

        /* pad out spacing */
        for (z = j; z < 17; z++) {
            if (wolfSSL_BIO_printf(bio, "   ") <= 0)
                return WOLFSSL_FAILURE;
        }

        for (z = 0; z < j; z++) {
            if (wolfSSL_BIO_printf(bio, "%c", asc[z]) <= 0)
                return WOLFSSL_FAILURE;
        }
        if (wolfSSL_BIO_printf(bio, "\n") <= 0)
            return WOLFSSL_FAILURE;

        tag += 16;
    }
    return WOLFSSL_SUCCESS;
}
#endif /* HAVE_SESSION_TICKET */


/* prints out the session information in human readable form
 * return WOLFSSL_SUCCESS on success
 */
int wolfSSL_SESSION_print(WOLFSSL_BIO *bp, const WOLFSSL_SESSION *session)
{
    const unsigned char* pt;
    unsigned char buf[SECRET_LEN];
    unsigned int sz = 0, i;
    int ret;

    session = ClientSessionToSession(session);
    if (session == NULL) {
        return WOLFSSL_FAILURE;
    }

    if (wolfSSL_BIO_printf(bp, "%s\n", "SSL-Session:") <= 0)
        return WOLFSSL_FAILURE;

#if defined(SESSION_CERTS) || (defined(WOLFSSL_TLS13) && \
                               defined(HAVE_SESSION_TICKET))
    if (wolfSSL_BIO_printf(bp, "    Protocol  : %s\n",
            wolfSSL_SESSION_get_protocol(session)) <= 0)
        return WOLFSSL_FAILURE;
#endif

    if (wolfSSL_BIO_printf(bp, "    Cipher    : %s\n",
            wolfSSL_SESSION_CIPHER_get_name(session)) <= 0)
        return WOLFSSL_FAILURE;

    pt = wolfSSL_SESSION_get_id(session, &sz);
    if (wolfSSL_BIO_printf(bp, "    Session-ID: ") <= 0)
        return WOLFSSL_FAILURE;

    for (i = 0; i < sz; i++) {
        if (wolfSSL_BIO_printf(bp, "%02X", pt[i]) <= 0)
            return WOLFSSL_FAILURE;
    }
    if (wolfSSL_BIO_printf(bp, "\n") <= 0)
        return WOLFSSL_FAILURE;

    if (wolfSSL_BIO_printf(bp, "    Session-ID-ctx: \n") <= 0)
        return WOLFSSL_FAILURE;

    ret = wolfSSL_SESSION_get_master_key(session, buf, sizeof(buf));
    if (wolfSSL_BIO_printf(bp, "    Master-Key: ") <= 0)
        return WOLFSSL_FAILURE;

    if (ret > 0) {
        sz = (unsigned int)ret;
        for (i = 0; i < sz; i++) {
            if (wolfSSL_BIO_printf(bp, "%02X", buf[i]) <= 0)
                return WOLFSSL_FAILURE;
        }
    }
    if (wolfSSL_BIO_printf(bp, "\n") <= 0)
        return WOLFSSL_FAILURE;

    /* @TODO PSK identity hint and SRP */

    if (wolfSSL_BIO_printf(bp, "    TLS session ticket:") <= 0)
        return WOLFSSL_FAILURE;

#ifdef HAVE_SESSION_TICKET
    if (wolfSSL_SESSION_print_ticket(bp, session, "    ") != WOLFSSL_SUCCESS)
        return WOLFSSL_FAILURE;
#endif

#if !defined(NO_SESSION_CACHE) && (defined(OPENSSL_EXTRA) || \
        defined(HAVE_EXT_CACHE))
    if (wolfSSL_BIO_printf(bp, "    Start Time: %ld\n",
                wolfSSL_SESSION_get_time(session)) <= 0)
        return WOLFSSL_FAILURE;

    if (wolfSSL_BIO_printf(bp, "    Timeout   : %ld (sec)\n",
            wolfSSL_SESSION_get_timeout(session)) <= 0)
        return WOLFSSL_FAILURE;
#endif /* !NO_SESSION_CACHE && OPENSSL_EXTRA || HAVE_EXT_CACHE */

    /* @TODO verify return code print */

    if (wolfSSL_BIO_printf(bp, "    Extended master secret: %s\n",
            (wolfSSL_SESSION_haveEMS(session) == 0)? "no" : "yes") <= 0)
        return WOLFSSL_FAILURE;

    return WOLFSSL_SUCCESS;
}

#endif /* !NO_BIO */
#endif /* (HAVE_SESSION_TICKET || SESSION_CERTS) && !NO_FILESYSTEM */

#endif /* OPENSSL_ALL || OPENSSL_EXTRA || HAVE_STUNNEL || WOLFSSL_NGINX || WOLFSSL_HAPROXY */

#if defined(OPENSSL_ALL) || (defined(OPENSSL_EXTRA) && defined(HAVE_STUNNEL)) \
    || defined(WOLFSSL_MYSQL_COMPATIBLE) || defined(WOLFSSL_NGINX)

/* TODO: Doesn't currently track SSL_VERIFY_CLIENT_ONCE */
int wolfSSL_get_verify_mode(const WOLFSSL* ssl) {
    int mode = 0;
    WOLFSSL_ENTER("wolfSSL_get_verify_mode");

    if (!ssl) {
        return WOLFSSL_FAILURE;
    }

    if (ssl->options.verifyNone) {
        mode = WOLFSSL_VERIFY_NONE;
    }
    else {
        if (ssl->options.verifyPeer) {
            mode |= WOLFSSL_VERIFY_PEER;
        }
        if (ssl->options.failNoCert) {
            mode |= WOLFSSL_VERIFY_FAIL_IF_NO_PEER_CERT;
        }
        if (ssl->options.failNoCertxPSK) {
            mode |= WOLFSSL_VERIFY_FAIL_EXCEPT_PSK;
        }
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_POST_HANDSHAKE_AUTH)
        if (ssl->options.verifyPostHandshake) {
            mode |= WOLFSSL_VERIFY_POST_HANDSHAKE;
        }
#endif
    }

    WOLFSSL_LEAVE("wolfSSL_get_verify_mode", mode);
    return mode;
}

int wolfSSL_CTX_get_verify_mode(const WOLFSSL_CTX* ctx)
{
    int mode = 0;
    WOLFSSL_ENTER("wolfSSL_CTX_get_verify_mode");

    if (!ctx) {
        return WOLFSSL_FAILURE;
    }

    if (ctx->verifyNone) {
        mode = WOLFSSL_VERIFY_NONE;
    }
    else {
        if (ctx->verifyPeer) {
            mode |= WOLFSSL_VERIFY_PEER;
        }
        if (ctx->failNoCert) {
            mode |= WOLFSSL_VERIFY_FAIL_IF_NO_PEER_CERT;
        }
        if (ctx->failNoCertxPSK) {
            mode |= WOLFSSL_VERIFY_FAIL_EXCEPT_PSK;
        }
#if defined(WOLFSSL_TLS13) && defined(WOLFSSL_POST_HANDSHAKE_AUTH)
        if (ctx->verifyPostHandshake) {
            mode |= WOLFSSL_VERIFY_POST_HANDSHAKE;
        }
#endif
    }

    WOLFSSL_LEAVE("wolfSSL_CTX_get_verify_mode", mode);
    return mode;
}

#endif
#if defined(OPENSSL_EXTRA) && defined(HAVE_CURVE25519)
/* return 1 if success, 0 if error
 * output keys are little endian format
 */
int wolfSSL_EC25519_generate_key(unsigned char *priv, unsigned int *privSz,
                                 unsigned char *pub, unsigned int *pubSz)
{
#ifndef WOLFSSL_KEY_GEN
    WOLFSSL_MSG("No Key Gen built in");
    (void) priv;
    (void) privSz;
    (void) pub;
    (void) pubSz;
    return WOLFSSL_FAILURE;
#else /* WOLFSSL_KEY_GEN */
    int ret = WOLFSSL_FAILURE;
    int initTmpRng = 0;
    WC_RNG *rng = NULL;
#ifdef WOLFSSL_SMALL_STACK
    WC_RNG *tmpRNG = NULL;
#else
    WC_RNG tmpRNG[1];
#endif

    WOLFSSL_ENTER("wolfSSL_EC25519_generate_key");

    if (priv == NULL || privSz == NULL || *privSz < CURVE25519_KEYSIZE ||
        pub == NULL || pubSz == NULL || *pubSz < CURVE25519_KEYSIZE) {
        WOLFSSL_MSG("Bad arguments");
        return WOLFSSL_FAILURE;
    }

#ifdef WOLFSSL_SMALL_STACK
    tmpRNG = (WC_RNG*)XMALLOC(sizeof(WC_RNG), NULL, DYNAMIC_TYPE_RNG);
    if (tmpRNG == NULL)
        return WOLFSSL_FAILURE;
#endif
    if (wc_InitRng(tmpRNG) == 0) {
        rng = tmpRNG;
        initTmpRng = 1;
    }
    else {
        WOLFSSL_MSG("Bad RNG Init, trying global");
        if (initGlobalRNG == 0)
            WOLFSSL_MSG("Global RNG no Init");
        else
            rng = &globalRNG;
    }

    if (rng) {
        curve25519_key key;

        if (wc_curve25519_init(&key) != MP_OKAY)
            WOLFSSL_MSG("wc_curve25519_init failed");
        else if (wc_curve25519_make_key(rng, CURVE25519_KEYSIZE, &key)!=MP_OKAY)
            WOLFSSL_MSG("wc_curve25519_make_key failed");
        /* export key pair */
        else if (wc_curve25519_export_key_raw_ex(&key, priv, privSz, pub,
                                                 pubSz, EC25519_LITTLE_ENDIAN)
                 != MP_OKAY)
            WOLFSSL_MSG("wc_curve25519_export_key_raw_ex failed");
        else
            ret = WOLFSSL_SUCCESS;

        wc_curve25519_free(&key);
    }

    if (initTmpRng)
        wc_FreeRng(tmpRNG);

#ifdef WOLFSSL_SMALL_STACK
    XFREE(tmpRNG, NULL, DYNAMIC_TYPE_RNG);
#endif

    return ret;
#endif /* WOLFSSL_KEY_GEN */
}

/* return 1 if success, 0 if error
 * input and output keys are little endian format
 */
int wolfSSL_EC25519_shared_key(unsigned char *shared, unsigned int *sharedSz,
                               const unsigned char *priv, unsigned int privSz,
                               const unsigned char *pub, unsigned int pubSz)
{
#ifndef WOLFSSL_KEY_GEN
    WOLFSSL_MSG("No Key Gen built in");
    (void) shared;
    (void) sharedSz;
    (void) priv;
    (void) privSz;
    (void) pub;
    (void) pubSz;
    return WOLFSSL_FAILURE;
#else /* WOLFSSL_KEY_GEN */
    int ret = WOLFSSL_FAILURE;
    curve25519_key privkey, pubkey;

    WOLFSSL_ENTER("wolfSSL_EC25519_shared_key");

    if (shared == NULL || sharedSz == NULL || *sharedSz < CURVE25519_KEYSIZE ||
        priv == NULL || privSz < CURVE25519_KEYSIZE ||
        pub == NULL || pubSz < CURVE25519_KEYSIZE) {
        WOLFSSL_MSG("Bad arguments");
        return WOLFSSL_FAILURE;
    }

    /* import private key */
    if (wc_curve25519_init(&privkey) != MP_OKAY) {
        WOLFSSL_MSG("wc_curve25519_init privkey failed");
        return ret;
    }
    if (wc_curve25519_import_private_ex(priv, privSz, &privkey,
                                        EC25519_LITTLE_ENDIAN) != MP_OKAY) {
        WOLFSSL_MSG("wc_curve25519_import_private_ex failed");
        wc_curve25519_free(&privkey);
        return ret;
    }

    /* import public key */
    if (wc_curve25519_init(&pubkey) != MP_OKAY) {
        WOLFSSL_MSG("wc_curve25519_init pubkey failed");
        wc_curve25519_free(&privkey);
        return ret;
    }
    if (wc_curve25519_import_public_ex(pub, pubSz, &pubkey,
                                       EC25519_LITTLE_ENDIAN) != MP_OKAY) {
        WOLFSSL_MSG("wc_curve25519_import_public_ex failed");
        wc_curve25519_free(&privkey);
        wc_curve25519_free(&pubkey);
        return ret;
    }

    if (wc_curve25519_shared_secret_ex(&privkey, &pubkey,
                                       shared, sharedSz,
                                       EC25519_LITTLE_ENDIAN) != MP_OKAY)
        WOLFSSL_MSG("wc_curve25519_shared_secret_ex failed");
    else
        ret = WOLFSSL_SUCCESS;

    wc_curve25519_free(&privkey);
    wc_curve25519_free(&pubkey);

    return ret;
#endif /* WOLFSSL_KEY_GEN */
}
#endif /* OPENSSL_EXTRA && HAVE_CURVE25519 */

#if defined(OPENSSL_EXTRA) && defined(HAVE_ED25519)
/* return 1 if success, 0 if error
 * output keys are little endian format
 */
int wolfSSL_ED25519_generate_key(unsigned char *priv, unsigned int *privSz,
                                 unsigned char *pub, unsigned int *pubSz)
{
#ifndef WOLFSSL_KEY_GEN
    WOLFSSL_MSG("No Key Gen built in");
    (void) priv;
    (void) privSz;
    (void) pub;
    (void) pubSz;
    return WOLFSSL_FAILURE;
#elif !defined(HAVE_ED25519_KEY_EXPORT)
    WOLFSSL_MSG("No ED25519 key export built in");
    (void) priv;
    (void) privSz;
    (void) pub;
    (void) pubSz;
    return WOLFSSL_FAILURE;
#else /* WOLFSSL_KEY_GEN && HAVE_ED25519_KEY_EXPORT */
    int ret = WOLFSSL_FAILURE;
    int initTmpRng = 0;
    WC_RNG *rng = NULL;
#ifdef WOLFSSL_SMALL_STACK
    WC_RNG *tmpRNG = NULL;
#else
    WC_RNG tmpRNG[1];
#endif

    WOLFSSL_ENTER("wolfSSL_ED25519_generate_key");

    if (priv == NULL || privSz == NULL || *privSz < ED25519_PRV_KEY_SIZE ||
        pub == NULL || pubSz == NULL || *pubSz < ED25519_PUB_KEY_SIZE) {
        WOLFSSL_MSG("Bad arguments");
        return WOLFSSL_FAILURE;
    }

#ifdef WOLFSSL_SMALL_STACK
    tmpRNG = (WC_RNG*)XMALLOC(sizeof(WC_RNG), NULL, DYNAMIC_TYPE_RNG);
    if (tmpRNG == NULL)
        return WOLFSSL_FATAL_ERROR;
#endif
    if (wc_InitRng(tmpRNG) == 0) {
        rng = tmpRNG;
        initTmpRng = 1;
    }
    else {
        WOLFSSL_MSG("Bad RNG Init, trying global");
        if (initGlobalRNG == 0)
            WOLFSSL_MSG("Global RNG no Init");
        else
            rng = &globalRNG;
    }

    if (rng) {
        ed25519_key key;

        if (wc_ed25519_init(&key) != MP_OKAY)
            WOLFSSL_MSG("wc_ed25519_init failed");
        else if (wc_ed25519_make_key(rng, ED25519_KEY_SIZE, &key)!=MP_OKAY)
            WOLFSSL_MSG("wc_ed25519_make_key failed");
        /* export private key */
        else if (wc_ed25519_export_key(&key, priv, privSz, pub, pubSz)!=MP_OKAY)
            WOLFSSL_MSG("wc_ed25519_export_key failed");
        else
            ret = WOLFSSL_SUCCESS;

        wc_ed25519_free(&key);
    }

    if (initTmpRng)
        wc_FreeRng(tmpRNG);

#ifdef WOLFSSL_SMALL_STACK
    XFREE(tmpRNG, NULL, DYNAMIC_TYPE_RNG);
#endif

    return ret;
#endif /* WOLFSSL_KEY_GEN && HAVE_ED25519_KEY_EXPORT */
}

/* return 1 if success, 0 if error
 * input and output keys are little endian format
 * priv is a buffer containing private and public part of key
 */
int wolfSSL_ED25519_sign(const unsigned char *msg, unsigned int msgSz,
                         const unsigned char *priv, unsigned int privSz,
                         unsigned char *sig, unsigned int *sigSz)
{
#if !defined(HAVE_ED25519_SIGN) || !defined(WOLFSSL_KEY_GEN) || !defined(HAVE_ED25519_KEY_IMPORT)
#if !defined(HAVE_ED25519_SIGN)
    WOLFSSL_MSG("No ED25519 sign built in");
#elif !defined(WOLFSSL_KEY_GEN)
     WOLFSSL_MSG("No Key Gen built in");
#elif !defined(HAVE_ED25519_KEY_IMPORT)
     WOLFSSL_MSG("No ED25519 Key import built in");
#endif
    (void) msg;
    (void) msgSz;
    (void) priv;
    (void) privSz;
    (void) sig;
    (void) sigSz;
    return WOLFSSL_FAILURE;
#else /* HAVE_ED25519_SIGN && WOLFSSL_KEY_GEN && HAVE_ED25519_KEY_IMPORT */
    ed25519_key key;
    int ret = WOLFSSL_FAILURE;

    WOLFSSL_ENTER("wolfSSL_ED25519_sign");

    if (priv == NULL || privSz != ED25519_PRV_KEY_SIZE ||
        msg == NULL || sig == NULL || *sigSz < ED25519_SIG_SIZE) {
        WOLFSSL_MSG("Bad arguments");
        return WOLFSSL_FAILURE;
    }

    /* import key */
    if (wc_ed25519_init(&key) != MP_OKAY) {
        WOLFSSL_MSG("wc_curve25519_init failed");
        return ret;
    }
    if (wc_ed25519_import_private_key(priv, privSz/2,
                                      priv+(privSz/2), ED25519_PUB_KEY_SIZE,
                                      &key) != MP_OKAY){
        WOLFSSL_MSG("wc_ed25519_import_private failed");
        wc_ed25519_free(&key);
        return ret;
    }

    if (wc_ed25519_sign_msg(msg, msgSz, sig, sigSz, &key) != MP_OKAY)
        WOLFSSL_MSG("wc_curve25519_shared_secret_ex failed");
    else
        ret = WOLFSSL_SUCCESS;

    wc_ed25519_free(&key);

    return ret;
#endif /* HAVE_ED25519_SIGN && WOLFSSL_KEY_GEN && HAVE_ED25519_KEY_IMPORT */
}

/* return 1 if success, 0 if error
 * input and output keys are little endian format
 * pub is a buffer containing public part of key
 */
int wolfSSL_ED25519_verify(const unsigned char *msg, unsigned int msgSz,
                           const unsigned char *pub, unsigned int pubSz,
                           const unsigned char *sig, unsigned int sigSz)
{
#if !defined(HAVE_ED25519_VERIFY) || !defined(WOLFSSL_KEY_GEN) || !defined(HAVE_ED25519_KEY_IMPORT)
#if !defined(HAVE_ED25519_VERIFY)
    WOLFSSL_MSG("No ED25519 verify built in");
#elif !defined(WOLFSSL_KEY_GEN)
     WOLFSSL_MSG("No Key Gen built in");
#elif !defined(HAVE_ED25519_KEY_IMPORT)
     WOLFSSL_MSG("No ED25519 Key import built in");
#endif
    (void) msg;
    (void) msgSz;
    (void) pub;
    (void) pubSz;
    (void) sig;
    (void) sigSz;
    return WOLFSSL_FAILURE;
#else /* HAVE_ED25519_VERIFY && WOLFSSL_KEY_GEN && HAVE_ED25519_KEY_IMPORT */
    ed25519_key key;
    int ret = WOLFSSL_FAILURE, check = 0;

    WOLFSSL_ENTER("wolfSSL_ED25519_verify");

    if (pub == NULL || pubSz != ED25519_PUB_KEY_SIZE ||
        msg == NULL || sig == NULL || sigSz != ED25519_SIG_SIZE) {
        WOLFSSL_MSG("Bad arguments");
        return WOLFSSL_FAILURE;
    }

    /* import key */
    if (wc_ed25519_init(&key) != MP_OKAY) {
        WOLFSSL_MSG("wc_curve25519_init failed");
        return ret;
    }
    if (wc_ed25519_import_public(pub, pubSz, &key) != MP_OKAY){
        WOLFSSL_MSG("wc_ed25519_import_public failed");
        wc_ed25519_free(&key);
        return ret;
    }

    if ((ret = wc_ed25519_verify_msg((byte*)sig, sigSz, msg, msgSz,
                                     &check, &key)) != MP_OKAY) {
        WOLFSSL_MSG("wc_ed25519_verify_msg failed");
    }
    else if (!check)
        WOLFSSL_MSG("wc_ed25519_verify_msg failed (signature invalid)");
    else
        ret = WOLFSSL_SUCCESS;

    wc_ed25519_free(&key);

    return ret;
#endif /* HAVE_ED25519_VERIFY && WOLFSSL_KEY_GEN && HAVE_ED25519_KEY_IMPORT */
}

#endif /* OPENSSL_EXTRA && HAVE_ED25519 */

#if defined(OPENSSL_EXTRA) && defined(HAVE_CURVE448)
/* return 1 if success, 0 if error
 * output keys are little endian format
 */
int wolfSSL_EC448_generate_key(unsigned char *priv, unsigned int *privSz,
                               unsigned char *pub, unsigned int *pubSz)
{
#ifndef WOLFSSL_KEY_GEN
    WOLFSSL_MSG("No Key Gen built in");
    (void) priv;
    (void) privSz;
    (void) pub;
    (void) pubSz;
    return WOLFSSL_FAILURE;
#else /* WOLFSSL_KEY_GEN */
    int ret = WOLFSSL_FAILURE;
    int initTmpRng = 0;
    WC_RNG *rng = NULL;
#ifdef WOLFSSL_SMALL_STACK
    WC_RNG *tmpRNG = NULL;
#else
    WC_RNG tmpRNG[1];
#endif

    WOLFSSL_ENTER("wolfSSL_EC448_generate_key");

    if (priv == NULL || privSz == NULL || *privSz < CURVE448_KEY_SIZE ||
        pub == NULL || pubSz == NULL || *pubSz < CURVE448_KEY_SIZE) {
        WOLFSSL_MSG("Bad arguments");
        return WOLFSSL_FAILURE;
    }

#ifdef WOLFSSL_SMALL_STACK
    tmpRNG = (WC_RNG*)XMALLOC(sizeof(WC_RNG), NULL, DYNAMIC_TYPE_RNG);
    if (tmpRNG == NULL)
        return WOLFSSL_FAILURE;
#endif
    if (wc_InitRng(tmpRNG) == 0) {
        rng = tmpRNG;
        initTmpRng = 1;
    }
    else {
        WOLFSSL_MSG("Bad RNG Init, trying global");
        if (initGlobalRNG == 0)
            WOLFSSL_MSG("Global RNG no Init");
        else
            rng = &globalRNG;
    }

    if (rng) {
        curve448_key key;

        if (wc_curve448_init(&key) != MP_OKAY)
            WOLFSSL_MSG("wc_curve448_init failed");
        else if (wc_curve448_make_key(rng, CURVE448_KEY_SIZE, &key)!=MP_OKAY)
            WOLFSSL_MSG("wc_curve448_make_key failed");
        /* export key pair */
        else if (wc_curve448_export_key_raw_ex(&key, priv, privSz, pub, pubSz,
                                               EC448_LITTLE_ENDIAN)
                 != MP_OKAY)
            WOLFSSL_MSG("wc_curve448_export_key_raw_ex failed");
        else
            ret = WOLFSSL_SUCCESS;

        wc_curve448_free(&key);
    }

    if (initTmpRng)
        wc_FreeRng(tmpRNG);

#ifdef WOLFSSL_SMALL_STACK
    XFREE(tmpRNG, NULL, DYNAMIC_TYPE_RNG);
#endif

    return ret;
#endif /* WOLFSSL_KEY_GEN */
}

/* return 1 if success, 0 if error
 * input and output keys are little endian format
 */
int wolfSSL_EC448_shared_key(unsigned char *shared, unsigned int *sharedSz,
                             const unsigned char *priv, unsigned int privSz,
                             const unsigned char *pub, unsigned int pubSz)
{
#ifndef WOLFSSL_KEY_GEN
    WOLFSSL_MSG("No Key Gen built in");
    (void) shared;
    (void) sharedSz;
    (void) priv;
    (void) privSz;
    (void) pub;
    (void) pubSz;
    return WOLFSSL_FAILURE;
#else /* WOLFSSL_KEY_GEN */
    int ret = WOLFSSL_FAILURE;
    curve448_key privkey, pubkey;

    WOLFSSL_ENTER("wolfSSL_EC448_shared_key");

    if (shared == NULL || sharedSz == NULL || *sharedSz < CURVE448_KEY_SIZE ||
            priv == NULL || privSz < CURVE448_KEY_SIZE ||
            pub == NULL || pubSz < CURVE448_KEY_SIZE) {
        WOLFSSL_MSG("Bad arguments");
        return WOLFSSL_FAILURE;
    }

    /* import private key */
    if (wc_curve448_init(&privkey) != MP_OKAY) {
        WOLFSSL_MSG("wc_curve448_init privkey failed");
        return ret;
    }
    if (wc_curve448_import_private_ex(priv, privSz, &privkey,
                                      EC448_LITTLE_ENDIAN) != MP_OKAY) {
        WOLFSSL_MSG("wc_curve448_import_private_ex failed");
        wc_curve448_free(&privkey);
        return ret;
    }

    /* import public key */
    if (wc_curve448_init(&pubkey) != MP_OKAY) {
        WOLFSSL_MSG("wc_curve448_init pubkey failed");
        wc_curve448_free(&privkey);
        return ret;
    }
    if (wc_curve448_import_public_ex(pub, pubSz, &pubkey,
                                     EC448_LITTLE_ENDIAN) != MP_OKAY) {
        WOLFSSL_MSG("wc_curve448_import_public_ex failed");
        wc_curve448_free(&privkey);
        wc_curve448_free(&pubkey);
        return ret;
    }

    if (wc_curve448_shared_secret_ex(&privkey, &pubkey, shared, sharedSz,
                                     EC448_LITTLE_ENDIAN) != MP_OKAY)
        WOLFSSL_MSG("wc_curve448_shared_secret_ex failed");
    else
        ret = WOLFSSL_SUCCESS;

    wc_curve448_free(&privkey);
    wc_curve448_free(&pubkey);

    return ret;
#endif /* WOLFSSL_KEY_GEN */
}
#endif /* OPENSSL_EXTRA && HAVE_CURVE448 */

#if defined(OPENSSL_EXTRA) && defined(HAVE_ED448)
/* return 1 if success, 0 if error
 * output keys are little endian format
 */
int wolfSSL_ED448_generate_key(unsigned char *priv, unsigned int *privSz,
                               unsigned char *pub, unsigned int *pubSz)
{
#ifndef WOLFSSL_KEY_GEN
    WOLFSSL_MSG("No Key Gen built in");
    (void) priv;
    (void) privSz;
    (void) pub;
    (void) pubSz;
    return WOLFSSL_FAILURE;
#elif !defined(HAVE_ED448_KEY_EXPORT)
    WOLFSSL_MSG("No ED448 key export built in");
    (void) priv;
    (void) privSz;
    (void) pub;
    (void) pubSz;
    return WOLFSSL_FAILURE;
#else /* WOLFSSL_KEY_GEN && HAVE_ED448_KEY_EXPORT */
    int ret = WOLFSSL_FAILURE;
    int initTmpRng = 0;
    WC_RNG *rng = NULL;
#ifdef WOLFSSL_SMALL_STACK
    WC_RNG *tmpRNG = NULL;
#else
    WC_RNG tmpRNG[1];
#endif

    WOLFSSL_ENTER("wolfSSL_ED448_generate_key");

    if (priv == NULL || privSz == NULL || *privSz < ED448_PRV_KEY_SIZE ||
            pub == NULL || pubSz == NULL || *pubSz < ED448_PUB_KEY_SIZE) {
        WOLFSSL_MSG("Bad arguments");
        return WOLFSSL_FAILURE;
    }

#ifdef WOLFSSL_SMALL_STACK
    tmpRNG = (WC_RNG*)XMALLOC(sizeof(WC_RNG), NULL, DYNAMIC_TYPE_RNG);
    if (tmpRNG == NULL)
        return WOLFSSL_FATAL_ERROR;
#endif
    if (wc_InitRng(tmpRNG) == 0) {
        rng = tmpRNG;
        initTmpRng = 1;
    }
    else {
        WOLFSSL_MSG("Bad RNG Init, trying global");
        if (initGlobalRNG == 0)
            WOLFSSL_MSG("Global RNG no Init");
        else
            rng = &globalRNG;
    }

    if (rng) {
        ed448_key key;

        if (wc_ed448_init(&key) != MP_OKAY)
            WOLFSSL_MSG("wc_ed448_init failed");
        else if (wc_ed448_make_key(rng, ED448_KEY_SIZE, &key) != MP_OKAY)
            WOLFSSL_MSG("wc_ed448_make_key failed");
        /* export private key */
        else if (wc_ed448_export_key(&key, priv, privSz, pub, pubSz) != MP_OKAY)
            WOLFSSL_MSG("wc_ed448_export_key failed");
        else
            ret = WOLFSSL_SUCCESS;

        wc_ed448_free(&key);
    }

    if (initTmpRng)
        wc_FreeRng(tmpRNG);

#ifdef WOLFSSL_SMALL_STACK
    XFREE(tmpRNG, NULL, DYNAMIC_TYPE_RNG);
#endif

    return ret;
#endif /* WOLFSSL_KEY_GEN && HAVE_ED448_KEY_EXPORT */
}

/* return 1 if success, 0 if error
 * input and output keys are little endian format
 * priv is a buffer containing private and public part of key
 */
int wolfSSL_ED448_sign(const unsigned char *msg, unsigned int msgSz,
                       const unsigned char *priv, unsigned int privSz,
                       unsigned char *sig, unsigned int *sigSz)
{
#if !defined(HAVE_ED448_SIGN) || !defined(WOLFSSL_KEY_GEN) || !defined(HAVE_ED448_KEY_IMPORT)
#if !defined(HAVE_ED448_SIGN)
    WOLFSSL_MSG("No ED448 sign built in");
#elif !defined(WOLFSSL_KEY_GEN)
    WOLFSSL_MSG("No Key Gen built in");
#elif !defined(HAVE_ED448_KEY_IMPORT)
    WOLFSSL_MSG("No ED448 Key import built in");
#endif
    (void) msg;
    (void) msgSz;
    (void) priv;
    (void) privSz;
    (void) sig;
    (void) sigSz;
    return WOLFSSL_FAILURE;
#else /* HAVE_ED448_SIGN && WOLFSSL_KEY_GEN && HAVE_ED448_KEY_IMPORT */
    ed448_key key;
    int ret = WOLFSSL_FAILURE;

    WOLFSSL_ENTER("wolfSSL_ED448_sign");

    if (priv == NULL || privSz != ED448_PRV_KEY_SIZE || msg == NULL ||
            sig == NULL || *sigSz < ED448_SIG_SIZE) {
        WOLFSSL_MSG("Bad arguments");
        return WOLFSSL_FAILURE;
    }

    /* import key */
    if (wc_ed448_init(&key) != MP_OKAY) {
        WOLFSSL_MSG("wc_curve448_init failed");
        return ret;
    }
    if (wc_ed448_import_private_key(priv, privSz/2, priv+(privSz/2),
                                    ED448_PUB_KEY_SIZE, &key) != MP_OKAY){
        WOLFSSL_MSG("wc_ed448_import_private failed");
        wc_ed448_free(&key);
        return ret;
    }

    if (wc_ed448_sign_msg(msg, msgSz, sig, sigSz, &key, NULL, 0) != MP_OKAY)
        WOLFSSL_MSG("wc_curve448_shared_secret_ex failed");
    else
        ret = WOLFSSL_SUCCESS;

    wc_ed448_free(&key);

    return ret;
#endif /* HAVE_ED448_SIGN && WOLFSSL_KEY_GEN && HAVE_ED448_KEY_IMPORT */
}

/* return 1 if success, 0 if error
 * input and output keys are little endian format
 * pub is a buffer containing public part of key
 */
int wolfSSL_ED448_verify(const unsigned char *msg, unsigned int msgSz,
                         const unsigned char *pub, unsigned int pubSz,
                         const unsigned char *sig, unsigned int sigSz)
{
#if !defined(HAVE_ED448_VERIFY) || !defined(WOLFSSL_KEY_GEN) || !defined(HAVE_ED448_KEY_IMPORT)
#if !defined(HAVE_ED448_VERIFY)
    WOLFSSL_MSG("No ED448 verify built in");
#elif !defined(WOLFSSL_KEY_GEN)
    WOLFSSL_MSG("No Key Gen built in");
#elif !defined(HAVE_ED448_KEY_IMPORT)
    WOLFSSL_MSG("No ED448 Key import built in");
#endif
    (void) msg;
    (void) msgSz;
    (void) pub;
    (void) pubSz;
    (void) sig;
    (void) sigSz;
    return WOLFSSL_FAILURE;
#else /* HAVE_ED448_VERIFY && WOLFSSL_KEY_GEN && HAVE_ED448_KEY_IMPORT */
    ed448_key key;
    int ret = WOLFSSL_FAILURE, check = 0;

    WOLFSSL_ENTER("wolfSSL_ED448_verify");

    if (pub == NULL || pubSz != ED448_PUB_KEY_SIZE || msg == NULL ||
            sig == NULL || sigSz != ED448_SIG_SIZE) {
        WOLFSSL_MSG("Bad arguments");
        return WOLFSSL_FAILURE;
    }

    /* import key */
    if (wc_ed448_init(&key) != MP_OKAY) {
        WOLFSSL_MSG("wc_curve448_init failed");
        return ret;
    }
    if (wc_ed448_import_public(pub, pubSz, &key) != MP_OKAY){
        WOLFSSL_MSG("wc_ed448_import_public failed");
        wc_ed448_free(&key);
        return ret;
    }

    if ((ret = wc_ed448_verify_msg((byte*)sig, sigSz, msg, msgSz, &check,
                                   &key, NULL, 0)) != MP_OKAY) {
        WOLFSSL_MSG("wc_ed448_verify_msg failed");
    }
    else if (!check)
        WOLFSSL_MSG("wc_ed448_verify_msg failed (signature invalid)");
    else
        ret = WOLFSSL_SUCCESS;

    wc_ed448_free(&key);

    return ret;
#endif /* HAVE_ED448_VERIFY && WOLFSSL_KEY_GEN */
}

#endif /* OPENSSL_EXTRA && HAVE_ED448 */

#ifdef WOLFSSL_JNI

int wolfSSL_set_jobject(WOLFSSL* ssl, void* objPtr)
{
    WOLFSSL_ENTER("wolfSSL_set_jobject");
    if (ssl != NULL)
    {
        ssl->jObjectRef = objPtr;
        return WOLFSSL_SUCCESS;
    }
    return WOLFSSL_FAILURE;
}

void* wolfSSL_get_jobject(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_get_jobject");
    if (ssl != NULL)
        return ssl->jObjectRef;
    return NULL;
}

#endif /* WOLFSSL_JNI */


#ifdef WOLFSSL_ASYNC_CRYPT
int wolfSSL_CTX_AsyncPoll(WOLFSSL_CTX* ctx, WOLF_EVENT** events, int maxEvents,
    WOLF_EVENT_FLAG flags, int* eventCount)
{
    if (ctx == NULL) {
        return BAD_FUNC_ARG;
    }

    return wolfAsync_EventQueuePoll(&ctx->event_queue, NULL,
                                        events, maxEvents, flags, eventCount);
}

int wolfSSL_AsyncPoll(WOLFSSL* ssl, WOLF_EVENT_FLAG flags)
{
    int ret, eventCount = 0;
    WOLF_EVENT* events[1];

    if (ssl == NULL) {
        return BAD_FUNC_ARG;
    }

    ret = wolfAsync_EventQueuePoll(&ssl->ctx->event_queue, ssl,
        events, sizeof(events)/sizeof(events[0]), flags, &eventCount);
    if (ret == 0) {
        ret = eventCount;
    }

    return ret;
}
#endif /* WOLFSSL_ASYNC_CRYPT */

#ifdef OPENSSL_EXTRA

static int peek_ignore_err(int err)
{
  switch(err) {
    case -WANT_READ:
    case -WANT_WRITE:
    case -ZERO_RETURN:
    case -WOLFSSL_ERROR_ZERO_RETURN:
    case -SOCKET_PEER_CLOSED_E:
    case -SOCKET_ERROR_E:
      return 1;
    default:
      return 0;
  }
}

unsigned long wolfSSL_ERR_peek_error_line_data(const char **file, int *line,
                                               const char **data, int *flags)
{
  unsigned long err;

    WOLFSSL_ENTER("wolfSSL_ERR_peek_error_line_data");
    err = wc_PeekErrorNodeLineData(file, line, data, flags, peek_ignore_err);

    if (err == -ASN_NO_PEM_HEADER)
        return (ERR_LIB_PEM << 24) | PEM_R_NO_START_LINE;
#ifdef OPENSSL_ALL
    /* PARSE_ERROR is returned if an HTTP request is detected. */
    else if (err == -SSL_R_HTTP_REQUEST)
        return (ERR_LIB_SSL << 24) | -SSL_R_HTTP_REQUEST;
#endif
#if defined(OPENSSL_ALL) && defined(WOLFSSL_PYTHON)
    else if (err == ASN1_R_HEADER_TOO_LONG)
        return (ERR_LIB_ASN1 << 24) | ASN1_R_HEADER_TOO_LONG;
#endif
  return err;
}
#endif

#if defined(OPENSSL_ALL) || defined(WOLFSSL_NGINX) || defined(WOLFSSL_HAPROXY)

#if !defined(WOLFSSL_USER_IO)
/* converts an IPv6 or IPv4 address into an octet string for use with rfc3280
 * example input would be "127.0.0.1" and the returned value would be 7F000001
 */
WOLFSSL_ASN1_STRING* wolfSSL_a2i_IPADDRESS(const char* ipa)
{
    int ipaSz = WOLFSSL_IP4_ADDR_LEN;
    char buf[WOLFSSL_IP6_ADDR_LEN + 1]; /* plus 1 for terminator */
    int  af = WOLFSSL_IP4;
    WOLFSSL_ASN1_STRING *ret = NULL;

    if (ipa == NULL)
        return NULL;

    if (XSTRSTR(ipa, ":") != NULL) {
        af = WOLFSSL_IP6;
        ipaSz = WOLFSSL_IP6_ADDR_LEN;
    }

    buf[WOLFSSL_IP6_ADDR_LEN] = '\0';
    if (XINET_PTON(af, ipa, (void*)buf) != 1) {
        WOLFSSL_MSG("Error parsing IP address");
        return NULL;
    }

    ret = wolfSSL_ASN1_STRING_new();
    if (ret != NULL) {
        if (wolfSSL_ASN1_STRING_set(ret, buf, ipaSz) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("Error setting the string");
            wolfSSL_ASN1_STRING_free(ret);
            ret = NULL;
        }
    }

    return ret;
}
#endif /* !WOLFSSL_USER_IO */

/* Is the specified cipher suite a fake one used an an extension proxy? */
static WC_INLINE int SCSV_Check(byte suite0, byte suite)
{
    (void)suite0;
    (void)suite;
#ifdef HAVE_RENEGOTIATION_INDICATION
    if (suite0 == CIPHER_BYTE && suite == TLS_EMPTY_RENEGOTIATION_INFO_SCSV)
        return 1;
#endif
    return 0;
}

static WC_INLINE int sslCipherMinMaxCheck(const WOLFSSL *ssl, byte suite0,
        byte suite)
{
    const CipherSuiteInfo* cipher_names = GetCipherNames();
    int cipherSz = GetCipherNamesSize();
    int i;
    for (i = 0; i < cipherSz; i++)
        if (cipher_names[i].cipherSuite0 == suite0 &&
                cipher_names[i].cipherSuite == suite)
            break;
    if (i == cipherSz)
        return 1;
    /* Check min version */
    if (cipher_names[i].minor < ssl->options.minDowngrade) {
        if (ssl->options.minDowngrade <= TLSv1_2_MINOR &&
                cipher_names[i].minor >= TLSv1_MINOR)
            /* 1.0 ciphersuites are in general available in 1.1 and
             * 1.1 ciphersuites are in general available in 1.2 */
            return 0;
        return 1;
    }
    /* Check max version */
    switch (cipher_names[i].minor) {
    case SSLv3_MINOR :
        return ssl->options.mask & WOLFSSL_OP_NO_SSLv3;
    case TLSv1_MINOR :
        return ssl->options.mask & WOLFSSL_OP_NO_TLSv1;
    case TLSv1_1_MINOR :
        return ssl->options.mask & WOLFSSL_OP_NO_TLSv1_1;
    case TLSv1_2_MINOR :
        return ssl->options.mask & WOLFSSL_OP_NO_TLSv1_2;
    case TLSv1_3_MINOR :
        return ssl->options.mask & WOLFSSL_OP_NO_TLSv1_3;
    default:
        WOLFSSL_MSG("Unrecognized minor version");
        return 1;
    }
}

/* returns a pointer to internal cipher suite list. Should not be free'd by
 * caller.
 */
WOLF_STACK_OF(WOLFSSL_CIPHER) *wolfSSL_get_ciphers_compat(const WOLFSSL *ssl)
{
    WOLF_STACK_OF(WOLFSSL_CIPHER)* ret = NULL;
    Suites* suites;
#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
    const CipherSuiteInfo* cipher_names = GetCipherNames();
    int cipherSz = GetCipherNamesSize();
#endif

    WOLFSSL_ENTER("wolfSSL_get_ciphers_compat");
    if (ssl == NULL || (ssl->suites == NULL && ssl->ctx->suites == NULL)) {
        return NULL;
    }

    if (ssl->suites != NULL) {
        if (ssl->suites->suiteSz == 0 &&
                InitSSL_Suites((WOLFSSL*)ssl) != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("Suite initialization failure");
            return NULL;
        }
        suites = ssl->suites;
    }
    else {
        suites = ssl->ctx->suites;
    }

    /* check if stack needs populated */
    if (suites->stack == NULL) {
        int i;
#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
        int j;

        /* higher priority of cipher suite will be on top of stack */
        for (i = suites->suiteSz - 2; i >=0; i-=2) {
#else
        for (i = 0; i < suites->suiteSz; i+=2) {
#endif
            WOLFSSL_STACK* add;

            /* A couple of suites are placeholders for special options,
             * skip those. */
            if (SCSV_Check(suites->suites[i], suites->suites[i+1])
                    || sslCipherMinMaxCheck(ssl, suites->suites[i],
                                            suites->suites[i+1])) {
                continue;
            }

            add = wolfSSL_sk_new_node(ssl->heap);
            if (add != NULL) {
                add->type = STACK_TYPE_CIPHER;
                add->data.cipher.cipherSuite0 = suites->suites[i];
                add->data.cipher.cipherSuite  = suites->suites[i+1];
                add->data.cipher.ssl          = ssl;
#if defined(OPENSSL_ALL) || defined(WOLFSSL_QT)
                for (j = 0; j < cipherSz; j++) {
                    if (cipher_names[j].cipherSuite0 ==
                            add->data.cipher.cipherSuite0 &&
                            cipher_names[j].cipherSuite ==
                                    add->data.cipher.cipherSuite) {
                        add->data.cipher.offset = j;
                        break;
                    }
                }
#endif
                #if defined(WOLFSSL_QT) || defined(OPENSSL_ALL)
                /* in_stack is checked in wolfSSL_CIPHER_description */
                add->data.cipher.in_stack     = 1;
                #endif

                add->next = ret;
                if (ret != NULL) {
                    add->num = ret->num + 1;
                }
                else {
                    add->num = 1;
                }
                ret = add;
            }
        }
        suites->stack = ret;
    }
    return suites->stack;
}
#endif /* OPENSSL_ALL || WOLFSSL_NGINX || WOLFSSL_HAPROXY */

#if defined(OPENSSL_ALL) || defined(WOLFSSL_NGINX) || defined(WOLFSSL_HAPROXY) \
    || defined(OPENSSL_EXTRA) || defined(HAVE_LIGHTY) || defined(HAVE_SECRET_CALLBACK)
long wolfSSL_SSL_CTX_get_timeout(const WOLFSSL_CTX *ctx)
{
    WOLFSSL_ENTER("wolfSSL_SSL_CTX_get_timeout");

    if (ctx == NULL)
        return 0;

    return ctx->timeout;
}


/* returns the time in seconds of the current timeout */
long wolfSSL_get_timeout(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("wolfSSL_get_timeout");

    if (ssl == NULL)
        return 0;
    return ssl->timeout;
}
#endif

#if defined(OPENSSL_ALL) || defined(WOLFSSL_NGINX) || defined(WOLFSSL_HAPROXY) \
    || defined(OPENSSL_EXTRA) || defined(HAVE_LIGHTY)

#ifdef HAVE_ECC
int wolfSSL_SSL_CTX_set_tmp_ecdh(WOLFSSL_CTX *ctx, WOLFSSL_EC_KEY *ecdh)
{
    WOLFSSL_ENTER("wolfSSL_SSL_CTX_set_tmp_ecdh");

    if (ctx == NULL || ecdh == NULL)
        return BAD_FUNC_ARG;

    ctx->ecdhCurveOID = ecdh->group->curve_oid;

    return WOLFSSL_SUCCESS;
}
#endif

/* Assumes that the session passed in is from the cache. */
int wolfSSL_SSL_CTX_remove_session(WOLFSSL_CTX *ctx, WOLFSSL_SESSION *s)
{
    WOLFSSL_ENTER("wolfSSL_SSL_CTX_remove_session");

    s = ClientSessionToSession(s);
    if (ctx == NULL || s == NULL)
        return BAD_FUNC_ARG;

#ifdef HAVE_EXT_CACHE
    if (!ctx->internalCacheOff)
#endif
    {
        /* Don't remove session just timeout session. */
        s->timeout = 0;
#ifndef NO_SESSION_CACHE
        /* Clear the timeout in the cache */
        {
            int row;
            int i;
            SessionRow* sessRow = NULL;
            WOLFSSL_SESSION *cacheSession;
            const byte* id;
            int ret = 0;

            id = s->sessionID;
            if (s->haveAltSessionID)
                id = s->altSessionID;

            row = (int)(HashObject(id, ID_LEN, &ret) % SESSION_ROWS);
            if (ret != 0) {
                WOLFSSL_MSG("Hash session failed");
                return ret;
            }

            sessRow = &SessionCache[row];
            if (SESSION_ROW_LOCK(sessRow) != 0) {
                WOLFSSL_MSG("Session row lock failed");
                return BAD_MUTEX_E;
            }

            for (i = 0; i < SESSIONS_PER_ROW && i < sessRow->totalCount; i++) {
                cacheSession = &sessRow->Sessions[i];
                if (XMEMCMP(id, cacheSession->sessionID, ID_LEN) == 0) {
                    if (ctx->method->side != cacheSession->side)
                        continue;
                    cacheSession->timeout = 0;
#ifdef HAVE_EX_DATA
                    if (cacheSession->ownExData) {
                        /* Most recent version of ex data is in cache. Copy it
                         * over so the user can free it. */
                        XMEMCPY(&s->ex_data, &cacheSession->ex_data,
                                sizeof(WOLFSSL_CRYPTO_EX_DATA));
                    }
                    cacheSession->ownExData = 0; /* We clear below */
                    s->ownExData = 1;
#endif
                    break;
                }
            }
            SESSION_ROW_UNLOCK(sessRow);
        }
#endif
    }

#if defined(HAVE_EXT_CACHE) || defined(HAVE_EX_DATA)
    if (ctx->rem_sess_cb != NULL) {
        ctx->rem_sess_cb(ctx, s);
    }
#endif

    return 0;
}

#ifndef NO_BIO
BIO *wolfSSL_SSL_get_rbio(const WOLFSSL *s)
{
    WOLFSSL_ENTER("wolfSSL_SSL_get_rbio");
    /* Nginx sets the buffer size if the read BIO is different to write BIO.
     * The setting buffer size doesn't do anything so return NULL for both.
     */
    if (s == NULL)
        return NULL;

    return s->biord;
}
BIO *wolfSSL_SSL_get_wbio(const WOLFSSL *s)
{
    WOLFSSL_ENTER("wolfSSL_SSL_get_wbio");
    (void)s;
    /* Nginx sets the buffer size if the read BIO is different to write BIO.
     * The setting buffer size doesn't do anything so return NULL for both.
     */
    if (s == NULL)
        return NULL;

    return s->biowr;
}
#endif /* !NO_BIO */

int wolfSSL_SSL_do_handshake_internal(WOLFSSL *s)
{
    WOLFSSL_ENTER("wolfSSL_SSL_do_handshake_internal");
    if (s == NULL)
        return WOLFSSL_FAILURE;

    if (s->options.side == WOLFSSL_CLIENT_END) {
    #ifndef NO_WOLFSSL_CLIENT
        return wolfSSL_connect(s);
    #else
        WOLFSSL_MSG("Client not compiled in");
        return WOLFSSL_FAILURE;
    #endif
    }

#ifndef NO_WOLFSSL_SERVER
    return wolfSSL_accept(s);
#else
    WOLFSSL_MSG("Server not compiled in");
    return WOLFSSL_FAILURE;
#endif
}

int wolfSSL_SSL_do_handshake(WOLFSSL *s)
{
    WOLFSSL_ENTER("wolfSSL_SSL_do_handshake");
#ifdef WOLFSSL_QUIC
    if (WOLFSSL_IS_QUIC(s)) {
        return wolfSSL_quic_do_handshake(s);
    }
#endif
    return wolfSSL_SSL_do_handshake_internal(s);
}

#if defined(OPENSSL_VERSION_NUMBER) && OPENSSL_VERSION_NUMBER >= 0x10100000L
int wolfSSL_SSL_in_init(const WOLFSSL *ssl)
#else
int wolfSSL_SSL_in_init(WOLFSSL *ssl)
#endif
{
    WOLFSSL_ENTER("SSL_in_init");

    if (ssl == NULL)
        return WOLFSSL_FAILURE;

    if (ssl->options.side == WOLFSSL_CLIENT_END) {
        return ssl->options.connectState < SECOND_REPLY_DONE;
    }
    return ssl->options.acceptState < ACCEPT_THIRD_REPLY_DONE;
}

int wolfSSL_SSL_in_connect_init(WOLFSSL* ssl)
{
    WOLFSSL_ENTER("SSL_connect_init");

    if (ssl == NULL)
        return WOLFSSL_FAILURE;

    if (ssl->options.side == WOLFSSL_CLIENT_END) {
        return ssl->options.connectState > CONNECT_BEGIN &&
            ssl->options.connectState < SECOND_REPLY_DONE;
    }

    return ssl->options.acceptState > ACCEPT_BEGIN &&
        ssl->options.acceptState < ACCEPT_THIRD_REPLY_DONE;
}

#ifndef NO_SESSION_CACHE

WOLFSSL_SESSION *wolfSSL_SSL_get0_session(const WOLFSSL *ssl)
{
    WOLFSSL_ENTER("wolfSSL_SSL_get0_session");

    return ssl->session;
}

#endif /* NO_SESSION_CACHE */

#ifndef NO_BIO
int wolfSSL_a2i_ASN1_INTEGER(WOLFSSL_BIO *bio, WOLFSSL_ASN1_INTEGER *asn1,
        char *buf, int size)
{
    int readNextLine;
    int lineLen;
    int len;
    byte isNumCheck;
    word32 outLen;
    const int extraTagSz = MAX_LENGTH_SZ + 1;
    byte intTag[MAX_LENGTH_SZ + 1];
    int idx = 0;

    WOLFSSL_ENTER("wolfSSL_a2i_ASN1_INTEGER");

    if (!bio || !asn1 || !buf || size <= 0) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }

    /* Reset asn1 */
    if (asn1->isDynamic && asn1->data) {
        XFREE(asn1->data, NULL, DYNAMIC_TYPE_OPENSSL);
    }
    XMEMSET(asn1->intData, 0, WOLFSSL_ASN1_INTEGER_MAX);
    asn1->data = asn1->intData;
    asn1->isDynamic = 0;
    asn1->length = 0;
    asn1->negative = 0;
    asn1->type = V_ASN1_INTEGER;

    lineLen = wolfSSL_BIO_gets(bio, buf, size);
    do {
        readNextLine = 0;
        if (lineLen <= 0) {
            WOLFSSL_MSG("wolfSSL_BIO_gets error");
            return WOLFSSL_FAILURE;
        }
        while (lineLen && (buf[lineLen-1] == '\n' || buf[lineLen-1] == '\r'))
            lineLen--;
        if (buf[lineLen-1] == '\\')
            readNextLine = 1;
        /* Ignore none-hex chars at the end of the line */
        outLen = 1;
        while (lineLen && Base16_Decode((byte*)buf + lineLen - 1, 1,
                &isNumCheck, &outLen) == ASN_INPUT_E)
            lineLen--;
        if (!lineLen || lineLen % 2) {
            WOLFSSL_MSG("Invalid line length");
            return WOLFSSL_FAILURE;
        }
        len = asn1->length + (lineLen/2);
        /* Check if it will fit in static memory and
         * save space for the ASN tag in front */
        if (len > (int)(WOLFSSL_ASN1_INTEGER_MAX - extraTagSz)) {
            /* Allocate mem for data */
            if (asn1->isDynamic) {
                byte* tmp = (byte*)XREALLOC(asn1->data, len + extraTagSz, NULL,
                        DYNAMIC_TYPE_OPENSSL);
                if (!tmp) {
                    WOLFSSL_MSG("realloc error");
                    return WOLFSSL_FAILURE;
                }
                asn1->data = tmp;
            }
            else {
                /* Up to this point asn1->data pointed to asn1->intData.
                 * Now that the size has grown larger than intData can handle
                 * the asn1 structure moves to a dynamic type with isDynamic
                 * flag being set and asn1->data being malloc'd. */
                asn1->data = (byte*)XMALLOC(len + extraTagSz, NULL,
                        DYNAMIC_TYPE_OPENSSL);
                if (!asn1->data) {
                    WOLFSSL_MSG("malloc error");
                    return WOLFSSL_FAILURE;
                }
                asn1->isDynamic = 1;
                XMEMCPY(asn1->data, asn1->intData, asn1->length);
            }
        }
        len = lineLen/2;
        if (Base16_Decode((byte*)buf, lineLen, asn1->data + asn1->length,
                (word32*)&len) != 0) {
            WOLFSSL_MSG("Base16_Decode error");
            return WOLFSSL_FAILURE;
        }
        asn1->length += len;
    } while (readNextLine);

    /* Write ASN tag */
    idx = SetASNInt(asn1->length, asn1->data[0], intTag);
    XMEMMOVE(asn1->data + idx, asn1->data, asn1->length);
    XMEMCPY(asn1->data, intTag, idx);
    asn1->dataMax = asn1->length += idx;

    return WOLFSSL_SUCCESS;
}

int wolfSSL_i2a_ASN1_INTEGER(BIO *bp, const WOLFSSL_ASN1_INTEGER *a)
{
    word32 idx = 1;
    int len = 0;
    byte buf[512];
    word32 bufLen = 512;

    WOLFSSL_ENTER("wolfSSL_i2a_ASN1_INTEGER");

    if (bp == NULL || a == NULL)
        return WOLFSSL_FAILURE;

    /* Skip ASN.1 INTEGER (type) byte. */
    if (a->data[idx] == 0x80 || /* Indefinite length, can't determine length */
            GetLength(a->data, &idx, &len, a->length) < 0) {
        return 0;
    }

    /* Zero length integer is the value zero. */
    if (len == 0) {
        return wolfSSL_BIO_write(bp, "00", 2);
    }

    if (Base16_Encode(a->data + idx, len, buf, &bufLen) != 0 ||
            bufLen == 0) {
        return 0;
    }

    return wolfSSL_BIO_write(bp, buf, bufLen - 1); /* Don't write out NULL char */
}
#endif /* !NO_BIO */


#if defined(HAVE_SESSION_TICKET) && !defined(NO_WOLFSSL_SERVER)
/* Expected return values from implementations of OpenSSL ticket key callback.
 */
#define TICKET_KEY_CB_RET_FAILURE    (-1)
#define TICKET_KEY_CB_RET_NOT_FOUND   0
#define TICKET_KEY_CB_RET_OK          1
#define TICKET_KEY_CB_RET_RENEW       2

/* Implementation of session ticket encryption/decryption using OpenSSL
 * callback to initialize the cipher and HMAC.
 *
 * ssl           The SSL/TLS object.
 * keyName       The key name - used to identify the key to be used.
 * iv            The IV to use.
 * mac           The MAC of the encrypted data.
 * enc           Encrypt ticket.
 * encTicket     The ticket data.
 * encTicketLen  The length of the ticket data.
 * encLen        The encrypted/decrypted ticket length - output length.
 * ctx           Ignored. Application specific data.
 * returns WOLFSSL_TICKET_RET_OK to indicate success,
 *         WOLFSSL_TICKET_RET_CREATE if a new ticket is required and
 *         WOLFSSL_TICKET_RET_FATAL on error.
 */
static int wolfSSL_TicketKeyCb(WOLFSSL* ssl,
        unsigned char keyName[WOLFSSL_TICKET_NAME_SZ],
        unsigned char iv[WOLFSSL_TICKET_IV_SZ],
        unsigned char mac[WOLFSSL_TICKET_MAC_SZ],
        int enc, unsigned char* encTicket,
        int encTicketLen, int* encLen, void* ctx)
{
    byte                    digest[WC_MAX_DIGEST_SIZE];
#ifdef WOLFSSL_SMALL_STACK
    WOLFSSL_EVP_CIPHER_CTX  *evpCtx;
#else
    WOLFSSL_EVP_CIPHER_CTX  evpCtx[1];
#endif
    WOLFSSL_HMAC_CTX        hmacCtx;
    unsigned int            mdSz = 0;
    int                     len = 0;
    int                     ret = WOLFSSL_TICKET_RET_FATAL;
    int                     res;
    int                     totalSz = 0;

    (void)ctx;

    WOLFSSL_ENTER("wolfSSL_TicketKeyCb");

    if (ssl == NULL || ssl->ctx == NULL || ssl->ctx->ticketEncWrapCb == NULL) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_TICKET_RET_FATAL;
    }

#ifdef WOLFSSL_SMALL_STACK
    evpCtx = (WOLFSSL_EVP_CIPHER_CTX *)XMALLOC(sizeof(*evpCtx), ssl->heap,
                                               DYNAMIC_TYPE_TMP_BUFFER);
    if (evpCtx == NULL) {
        WOLFSSL_MSG("out of memory");
        return WOLFSSL_TICKET_RET_FATAL;
    }
#endif

    /* Initialize the cipher and HMAC. */
    wolfSSL_EVP_CIPHER_CTX_init(evpCtx);
    if (wolfSSL_HMAC_CTX_Init(&hmacCtx) != WOLFSSL_SUCCESS) {
        WOLFSSL_MSG("wolfSSL_HMAC_CTX_Init error");
#ifdef WOLFSSL_SMALL_STACK
        XFREE(evpCtx, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
#endif
        return WOLFSSL_TICKET_RET_FATAL;
    }
    res = ssl->ctx->ticketEncWrapCb(ssl, keyName,
            iv, evpCtx, &hmacCtx, enc);
    if (res != TICKET_KEY_CB_RET_OK && res != TICKET_KEY_CB_RET_RENEW) {
        WOLFSSL_MSG("Ticket callback error");
        ret = WOLFSSL_TICKET_RET_FATAL;
        goto end;
    }

    if (wolfSSL_HMAC_size(&hmacCtx) > WOLFSSL_TICKET_MAC_SZ) {
        WOLFSSL_MSG("Ticket cipher MAC size error");
        goto end;
    }

    if (enc)
    {
        /* Encrypt in place. */
        if (!wolfSSL_EVP_CipherUpdate(evpCtx, encTicket, &len,
                                      encTicket, encTicketLen))
            goto end;
        totalSz = len;
        if (totalSz > *encLen)
            goto end;
        if (!wolfSSL_EVP_EncryptFinal(evpCtx, &encTicket[len], &len))
            goto end;
        /* Total length of encrypted data. */
        totalSz += len;
        if (totalSz > *encLen)
            goto end;

        /* HMAC the encrypted data into the parameter 'mac'. */
        if (!wolfSSL_HMAC_Update(&hmacCtx, encTicket, totalSz))
            goto end;
        if (!wolfSSL_HMAC_Final(&hmacCtx, mac, &mdSz))
            goto end;
    }
    else
    {
        /* HMAC the encrypted data and compare it to the passed in data. */
        if (!wolfSSL_HMAC_Update(&hmacCtx, encTicket, encTicketLen))
            goto end;
        if (!wolfSSL_HMAC_Final(&hmacCtx, digest, &mdSz))
            goto end;
        if (XMEMCMP(mac, digest, mdSz) != 0)
            goto end;

        /* Decrypt the ticket data in place. */
        if (!wolfSSL_EVP_CipherUpdate(evpCtx, encTicket, &len,
                                      encTicket, encTicketLen))
            goto end;
        totalSz = len;
        if (totalSz > encTicketLen)
            goto end;
        if (!wolfSSL_EVP_DecryptFinal(evpCtx, &encTicket[len], &len))
            goto end;
        /* Total length of decrypted data. */
        totalSz += len;
        if (totalSz > encTicketLen)
            goto end;
    }
    *encLen = totalSz;

    if (res == TICKET_KEY_CB_RET_RENEW && !IsAtLeastTLSv1_3(ssl->version)
            && !enc)
        ret = WOLFSSL_TICKET_RET_CREATE;
    else
        ret = WOLFSSL_TICKET_RET_OK;
end:

    (void)wc_HmacFree(&hmacCtx.hmac);
#ifdef WOLFSSL_SMALL_STACK
    XFREE(evpCtx, ssl->heap, DYNAMIC_TYPE_TMP_BUFFER);
#endif

    return ret;
}

/* Set the callback to use when encrypting/decrypting tickets.
 *
 * ctx  The SSL/TLS context object.
 * cb   The OpenSSL session ticket callback.
 * returns WOLFSSL_SUCCESS to indicate success.
 */
int wolfSSL_CTX_set_tlsext_ticket_key_cb(WOLFSSL_CTX *ctx, ticketCompatCb cb)
{

    /* Set the ticket encryption callback to be a wrapper around OpenSSL
     * callback.
     */
    ctx->ticketEncCb = wolfSSL_TicketKeyCb;
    ctx->ticketEncWrapCb = cb;

    return WOLFSSL_SUCCESS;
}

#endif /* HAVE_SESSION_TICKET */

#endif /* OPENSSL_ALL || WOLFSSL_NGINX || WOLFSSL_HAPROXY ||
    OPENSSL_EXTRA || HAVE_LIGHTY */

#if defined(HAVE_SESSION_TICKET) && !defined(WOLFSSL_NO_DEF_TICKET_ENC_CB) && \
    !defined(NO_WOLFSSL_SERVER)
/* Serialize the session ticket encryption keys.
 *
 * @param [in]  ctx     SSL/TLS context object.
 * @param [in]  keys    Buffer to hold session ticket keys.
 * @param [in]  keylen  Length of buffer.
 * @return  WOLFSSL_SUCCESS on success.
 * @return  WOLFSSL_FAILURE when ctx is NULL, keys is NULL or keylen is not the
 *          correct length.
 */
long wolfSSL_CTX_get_tlsext_ticket_keys(WOLFSSL_CTX *ctx,
     unsigned char *keys, int keylen)
{
    if (ctx == NULL || keys == NULL) {
        return WOLFSSL_FAILURE;
    }
    if (keylen != WOLFSSL_TICKET_KEYS_SZ) {
        return WOLFSSL_FAILURE;
    }

    XMEMCPY(keys, ctx->ticketKeyCtx.name, WOLFSSL_TICKET_NAME_SZ);
    keys += WOLFSSL_TICKET_NAME_SZ;
    XMEMCPY(keys, ctx->ticketKeyCtx.key[0], WOLFSSL_TICKET_KEY_SZ);
    keys += WOLFSSL_TICKET_KEY_SZ;
    XMEMCPY(keys, ctx->ticketKeyCtx.key[1], WOLFSSL_TICKET_KEY_SZ);
    keys += WOLFSSL_TICKET_KEY_SZ;
    c32toa(ctx->ticketKeyCtx.expirary[0], keys);
    keys += OPAQUE32_LEN;
    c32toa(ctx->ticketKeyCtx.expirary[1], keys);

    return WOLFSSL_SUCCESS;
}

/* Deserialize the session ticket encryption keys.
 *
 * @param [in]  ctx     SSL/TLS context object.
 * @param [in]  keys    Session ticket keys.
 * @param [in]  keylen  Length of data.
 * @return  WOLFSSL_SUCCESS on success.
 * @return  WOLFSSL_FAILURE when ctx is NULL, keys is NULL or keylen is not the
 *          correct length.
 */
long wolfSSL_CTX_set_tlsext_ticket_keys(WOLFSSL_CTX *ctx,
     unsigned char *keys, int keylen)
{
    if (ctx == NULL || keys == NULL) {
        return WOLFSSL_FAILURE;
    }
    if (keylen != WOLFSSL_TICKET_KEYS_SZ) {
        return WOLFSSL_FAILURE;
    }

    XMEMCPY(ctx->ticketKeyCtx.name, keys, WOLFSSL_TICKET_NAME_SZ);
    keys += WOLFSSL_TICKET_NAME_SZ;
    XMEMCPY(ctx->ticketKeyCtx.key[0], keys, WOLFSSL_TICKET_KEY_SZ);
    keys += WOLFSSL_TICKET_KEY_SZ;
    XMEMCPY(ctx->ticketKeyCtx.key[1], keys, WOLFSSL_TICKET_KEY_SZ);
    keys += WOLFSSL_TICKET_KEY_SZ;
    ato32(keys, &ctx->ticketKeyCtx.expirary[0]);
    keys += OPAQUE32_LEN;
    ato32(keys, &ctx->ticketKeyCtx.expirary[1]);

    return WOLFSSL_SUCCESS;
}
#endif

#if defined(OPENSSL_ALL) || defined(WOLFSSL_NGINX) || defined(WOLFSSL_HAPROXY)
#ifdef HAVE_OCSP
/* Not an OpenSSL API. */
int wolfSSL_get_ocsp_response(WOLFSSL* ssl, byte** response)
{
    *response = ssl->ocspResp;
    return ssl->ocspRespSz;
}

/* Not an OpenSSL API. */
char* wolfSSL_get_ocsp_url(WOLFSSL* ssl)
{
    return ssl->url;
}

/* Not an OpenSSL API. */
int wolfSSL_set_ocsp_url(WOLFSSL* ssl, char* url)
{
    if (ssl == NULL)
        return WOLFSSL_FAILURE;

    ssl->url = url;
    return WOLFSSL_SUCCESS;
}
#endif /* OCSP */
#endif /* OPENSSL_ALL || WOLFSSL_NGINX  || WOLFSSL_HAPROXY */

#if defined(HAVE_OCSP) && !defined(NO_ASN_TIME)
int wolfSSL_get_ocsp_producedDate(
    WOLFSSL *ssl,
    byte *producedDate,
    size_t producedDate_space,
    int *producedDateFormat)
{
    if ((ssl->ocspProducedDateFormat != ASN_UTC_TIME) &&
        (ssl->ocspProducedDateFormat != ASN_GENERALIZED_TIME))
        return BAD_FUNC_ARG;

    if ((producedDate == NULL) || (producedDateFormat == NULL))
        return BAD_FUNC_ARG;

    if (XSTRLEN((char *)ssl->ocspProducedDate) >= producedDate_space)
        return BUFFER_E;

    XSTRNCPY((char *)producedDate, (const char *)ssl->ocspProducedDate, producedDate_space);
    *producedDateFormat = ssl->ocspProducedDateFormat;

    return 0;
}

int wolfSSL_get_ocsp_producedDate_tm(WOLFSSL *ssl, struct tm *produced_tm) {
    int idx = 0;

    if ((ssl->ocspProducedDateFormat != ASN_UTC_TIME) &&
        (ssl->ocspProducedDateFormat != ASN_GENERALIZED_TIME))
        return BAD_FUNC_ARG;

    if (produced_tm == NULL)
        return BAD_FUNC_ARG;

    if (ExtractDate(ssl->ocspProducedDate,
            (unsigned char)ssl->ocspProducedDateFormat, produced_tm, &idx))
        return 0;
    else
        return ASN_PARSE_E;
}
#endif


#if defined(WOLFSSL_NGINX) || defined(WOLFSSL_HAPROXY) || \
    defined(OPENSSL_EXTRA) || defined(OPENSSL_ALL)
int wolfSSL_CTX_get_extra_chain_certs(WOLFSSL_CTX* ctx, WOLF_STACK_OF(X509)** chain)
{
    word32         idx;
    word32         length;
    WOLFSSL_STACK* node;
    WOLFSSL_STACK* last = NULL;

    if (ctx == NULL || chain == NULL) {
        chain = NULL;
        return WOLFSSL_FAILURE;
    }
    if (ctx->x509Chain != NULL) {
        *chain = ctx->x509Chain;
        return WOLFSSL_SUCCESS;
    }

    /* If there are no chains then success! */
    *chain = NULL;
    if (ctx->certChain == NULL || ctx->certChain->length == 0) {
        return WOLFSSL_SUCCESS;
    }

    /* Create a new stack of WOLFSSL_X509 object from chain buffer. */
    for (idx = 0; idx < ctx->certChain->length; ) {
        node = (WOLFSSL_STACK*)XMALLOC(sizeof(WOLFSSL_STACK), NULL,
                                       DYNAMIC_TYPE_OPENSSL);
        if (node == NULL)
            return WOLFSSL_FAILURE;
        node->next = NULL;

        /* 3 byte length | X509 DER data */
        ato24(ctx->certChain->buffer + idx, &length);
        idx += 3;

        /* Create a new X509 from DER encoded data. */
        node->data.x509 = wolfSSL_X509_d2i(NULL, ctx->certChain->buffer + idx,
            length);
        if (node->data.x509 == NULL) {
            XFREE(node, NULL, DYNAMIC_TYPE_OPENSSL);
            /* Return as much of the chain as we created. */
            ctx->x509Chain = *chain;
            return WOLFSSL_FAILURE;
        }
        idx += length;

        /* Add object to the end of the stack. */
        if (last == NULL) {
            node->num = 1;
            *chain = node;
        }
        else {
            (*chain)->num++;
            last->next = node;
        }

        last = node;
    }

    ctx->x509Chain = *chain;

    return WOLFSSL_SUCCESS;
}

int wolfSSL_CTX_get_tlsext_status_cb(WOLFSSL_CTX* ctx, tlsextStatusCb* cb)
{
    if (ctx == NULL || ctx->cm == NULL || cb == NULL)
        return WOLFSSL_FAILURE;

#if !defined(NO_WOLFSSL_SERVER) && (defined(HAVE_CERTIFICATE_STATUS_REQUEST) \
                               ||  defined(HAVE_CERTIFICATE_STATUS_REQUEST_V2))
    if (ctx->cm->ocsp_stapling == NULL)
        return WOLFSSL_FAILURE;

    *cb = ctx->cm->ocsp_stapling->statusCb;
#else
    (void)cb;
    *cb = NULL;
#endif

    return WOLFSSL_SUCCESS;

}

int wolfSSL_CTX_set_tlsext_status_cb(WOLFSSL_CTX* ctx, tlsextStatusCb cb)
{
    if (ctx == NULL || ctx->cm == NULL)
        return WOLFSSL_FAILURE;

#if !defined(NO_WOLFSSL_SERVER) && (defined(HAVE_CERTIFICATE_STATUS_REQUEST) \
                               ||  defined(HAVE_CERTIFICATE_STATUS_REQUEST_V2))
    /* Ensure stapling is on for callback to be used. */
    wolfSSL_CTX_EnableOCSPStapling(ctx);

    if (ctx->cm->ocsp_stapling == NULL)
        return WOLFSSL_FAILURE;

    ctx->cm->ocsp_stapling->statusCb = cb;
#else
    (void)cb;
#endif

    return WOLFSSL_SUCCESS;
}

int wolfSSL_CTX_get0_chain_certs(WOLFSSL_CTX *ctx,
        WOLF_STACK_OF(WOLFSSL_X509) **sk)
{
    WOLFSSL_ENTER("wolfSSL_CTX_get0_chain_certs");
    if (ctx == NULL || sk == NULL) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }
    *sk = ctx->x509Chain;
    return WOLFSSL_SUCCESS;
}

#ifdef KEEP_OUR_CERT
int wolfSSL_get0_chain_certs(WOLFSSL *ssl,
        WOLF_STACK_OF(WOLFSSL_X509) **sk)
{
    WOLFSSL_ENTER("wolfSSL_get0_chain_certs");
    if (ssl == NULL || sk == NULL) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }
    *sk = ssl->ourCertChain;
    return WOLFSSL_SUCCESS;
}
#endif

WOLF_STACK_OF(WOLFSSL_STRING)* wolfSSL_sk_WOLFSSL_STRING_new(void)
{
    WOLF_STACK_OF(WOLFSSL_STRING)* ret = wolfSSL_sk_new_node(NULL);

    if (ret) {
        ret->type = STACK_TYPE_STRING;
    }

    return ret;
}

void wolfSSL_WOLFSSL_STRING_free(WOLFSSL_STRING s)
{
    WOLFSSL_ENTER("wolfSSL_WOLFSSL_STRING_free");

    if (s != NULL)
        XFREE(s, NULL, DYNAMIC_TYPE_OPENSSL);
}

void wolfSSL_sk_WOLFSSL_STRING_free(WOLF_STACK_OF(WOLFSSL_STRING)* sk)
{
    WOLFSSL_STACK* tmp;
    WOLFSSL_ENTER("wolfSSL_sk_WOLFSSL_STRING_free");

    if (sk == NULL)
        return;

    /* parse through stack freeing each node */
    while (sk) {
        tmp = sk->next;
        XFREE(sk->data.string, NULL, DYNAMIC_TYPE_OPENSSL);
        XFREE(sk, NULL, DYNAMIC_TYPE_OPENSSL);
        sk = tmp;
    }
}

WOLFSSL_STRING wolfSSL_sk_WOLFSSL_STRING_value(WOLF_STACK_OF(WOLFSSL_STRING)* strings,
    int idx)
{
    for (; idx > 0 && strings != NULL; idx--)
        strings = strings->next;
    if (strings == NULL)
        return NULL;
    return strings->data.string;
}

int wolfSSL_sk_WOLFSSL_STRING_num(WOLF_STACK_OF(WOLFSSL_STRING)* strings)
{
    if (strings)
        return (int)strings->num;
    return 0;
}

#endif /* WOLFSSL_NGINX || WOLFSSL_HAPROXY || OPENSSL_EXTRA || OPENSSL_ALL */

#if defined(OPENSSL_ALL) || defined(WOLFSSL_NGINX) || \
    defined(WOLFSSL_HAPROXY) || defined(HAVE_LIGHTY) || \
    defined(WOLFSSL_QUIC)
#ifdef HAVE_ALPN
void wolfSSL_get0_alpn_selected(const WOLFSSL *ssl, const unsigned char **data,
                                unsigned int *len)
{
    word16 nameLen;

    if (ssl != NULL && data != NULL && len != NULL) {
        TLSX_ALPN_GetRequest(ssl->extensions, (void **)data, &nameLen);
        *len = nameLen;
    }
}

int wolfSSL_select_next_proto(unsigned char **out, unsigned char *outLen,
                              const unsigned char *in, unsigned int inLen,
                              const unsigned char *clientNames,
                              unsigned int clientLen)
{
    unsigned int i, j;
    byte lenIn, lenClient;

    if (out == NULL || outLen == NULL || in == NULL || clientNames == NULL)
        return OPENSSL_NPN_UNSUPPORTED;

    for (i = 0; i < inLen; i += lenIn) {
        lenIn = in[i++];
        for (j = 0; j < clientLen; j += lenClient) {
            lenClient = clientNames[j++];

            if (lenIn != lenClient)
                continue;

            if (XMEMCMP(in + i, clientNames + j, lenIn) == 0) {
                *out = (unsigned char *)(in + i);
                *outLen = lenIn;
                return OPENSSL_NPN_NEGOTIATED;
            }
        }
    }

    *out = (unsigned char *)clientNames + 1;
    *outLen = clientNames[0];
    return OPENSSL_NPN_NO_OVERLAP;
}

void wolfSSL_CTX_set_alpn_select_cb(WOLFSSL_CTX *ctx,
                                    int (*cb) (WOLFSSL *ssl,
                                               const unsigned char **out,
                                               unsigned char *outlen,
                                               const unsigned char *in,
                                               unsigned int inlen,
                                               void *arg), void *arg)
{
    if (ctx != NULL) {
        ctx->alpnSelect = cb;
        ctx->alpnSelectArg = arg;
    }
}

void wolfSSL_CTX_set_next_protos_advertised_cb(WOLFSSL_CTX *s,
                                           int (*cb) (WOLFSSL *ssl,
                                                      const unsigned char
                                                      **out,
                                                      unsigned int *outlen,
                                                      void *arg), void *arg)
{
    (void)s;
    (void)cb;
    (void)arg;
    WOLFSSL_STUB("wolfSSL_CTX_set_next_protos_advertised_cb");
}

void wolfSSL_CTX_set_next_proto_select_cb(WOLFSSL_CTX *s,
                                      int (*cb) (WOLFSSL *ssl,
                                                 unsigned char **out,
                                                 unsigned char *outlen,
                                                 const unsigned char *in,
                                                 unsigned int inlen,
                                                 void *arg), void *arg)
{
    (void)s;
    (void)cb;
    (void)arg;
    WOLFSSL_STUB("wolfSSL_CTX_set_next_proto_select_cb");
}

void wolfSSL_get0_next_proto_negotiated(const WOLFSSL *s, const unsigned char **data,
                                    unsigned *len)
{
    (void)s;
    (void)data;
    (void)len;
    WOLFSSL_STUB("wolfSSL_get0_next_proto_negotiated");
}
#endif /* HAVE_ALPN */

#endif /* WOLFSSL_NGINX  / WOLFSSL_HAPROXY */

#ifdef OPENSSL_EXTRA
int wolfSSL_curve_is_disabled(WOLFSSL* ssl, word16 curve_id)
{
    return (curve_id <= WOLFSSL_ECC_MAX &&
            ssl->disabledCurves &&
            ssl->disabledCurves & (1 << curve_id));
}
#endif

#if defined(OPENSSL_EXTRA) && (defined(HAVE_ECC) || \
    defined(HAVE_CURVE25519) || defined(HAVE_CURVE448))
static int set_curves_list(WOLFSSL* ssl, WOLFSSL_CTX *ctx, const char* names)
{
    int idx, start = 0, len, i, ret = WOLFSSL_FAILURE;
    word16 curve;
    word32 disabled;
    char name[MAX_CURVE_NAME_SZ];
    byte groups_len = 0;
#ifdef WOLFSSL_SMALL_STACK
    void *heap = ssl? ssl->heap : ctx->heap;
    int *groups;
#else
    int groups[WOLFSSL_MAX_GROUP_COUNT];
#endif

#ifdef WOLFSSL_SMALL_STACK
    groups = (int*)XMALLOC(sizeof(int)*WOLFSSL_MAX_GROUP_COUNT,
                           heap, DYNAMIC_TYPE_TMP_BUFFER);
    if (groups == NULL) {
        ret = MEMORY_E;
        goto leave;
    }
#endif

    for (idx = 1; names[idx-1] != '\0'; idx++) {
        if (names[idx] != ':' && names[idx] != '\0')
            continue;

        len = idx - start;
        if (len > MAX_CURVE_NAME_SZ - 1)
            goto leave;

        XMEMCPY(name, names + start, len);
        name[len++] = 0;

        /* Use XSTRNCMP to avoid valgrind error. */
        if ((XSTRNCMP(name, "prime256v1", len) == 0) ||
            (XSTRNCMP(name, "secp256r1", len) == 0) ||
            (XSTRNCMP(name, "P-256", len) == 0))
        {
            curve = WOLFSSL_ECC_SECP256R1;
        }
        else if ((XSTRNCMP(name, "secp384r1", len) == 0) ||
                 (XSTRNCMP(name, "P-384", len) == 0))
        {
            curve = WOLFSSL_ECC_SECP384R1;
        }
        else if ((XSTRNCMP(name, "secp521r1", len) == 0) ||
                 (XSTRNCMP(name, "P-521", len) == 0))
        {
            curve = WOLFSSL_ECC_SECP521R1;
        }
    #ifdef HAVE_CURVE25519
        else if (XSTRNCMP(name, "X25519", len) == 0)
        {
            curve = WOLFSSL_ECC_X25519;
        }
    #endif
    #ifdef HAVE_CURVE448
        else if (XSTRNCMP(name, "X448", len) == 0)
        {
            curve = WOLFSSL_ECC_X448;
        }
    #endif
        else {
        #if !defined(HAVE_FIPS) && !defined(HAVE_SELFTEST)
            int   nret;
            const ecc_set_type *eccSet;

            nret = wc_ecc_get_curve_idx_from_name(name);
            if (nret < 0) {
                WOLFSSL_MSG("Could not find name in set");
                goto leave;
            }

            eccSet = wc_ecc_get_curve_params(ret);
            if (eccSet == NULL) {
                WOLFSSL_MSG("NULL set returned");
                goto leave;
            }

            curve = GetCurveByOID(eccSet->oidSum);
        #else
            WOLFSSL_MSG("API not present to search farther using name");
            goto leave;
        #endif
        }

        if (curve >= (sizeof(word32) * WOLFSSL_BIT_SIZE)) {
            /* shift left more than size of ctx->disabledCurves causes static
             * analysis report */
            WOLFSSL_MSG("curve value is too large for upcoming shift");
            goto leave;
        }

        for (i = 0; i < groups_len; ++i) {
            if (groups[i] == curve) {
                /* silently drop duplicates */
                break;
            }
        }
        if (i >= groups_len) {
            if (groups_len >= WOLFSSL_MAX_GROUP_COUNT) {
                WOLFSSL_MSG_EX("setting %d or more supported "
                               "curves is not permitted", groups_len);
                goto leave;
            }
            groups[groups_len++] = (int)curve;
        }

        start = idx + 1;
    }

    /* Disable all curves so that only the ones the user wants are enabled. */
    disabled = 0xFFFFFFFFUL;
    for (i = 0; i < groups_len; ++i) {
        /* Switch the bit to off and therefore is enabled. */
        curve = (word16)groups[i];
        disabled &= ~(1U << curve);
    #ifdef HAVE_SUPPORTED_CURVES
    #if defined(WOLFSSL_TLS13) && !defined(WOLFSSL_OLD_SET_CURVES_LIST)
        /* using the wolfSSL API to set the groups, this will populate
         * (ssl|ctx)->groups and reset any TLSX_SUPPORTED_GROUPS.
         * The order in (ssl|ctx)->groups will then be respected
         * when TLSX_KEY_SHARE needs to be established */
        if ((ssl && wolfSSL_set_groups(ssl, groups, groups_len)
                        != WOLFSSL_SUCCESS)
            || (ctx && wolfSSL_CTX_set_groups(ctx, groups, groups_len)
                           != WOLFSSL_SUCCESS)) {
            WOLFSSL_MSG("Unable to set supported curve");
            goto leave;
        }
    #elif !defined(NO_WOLFSSL_CLIENT)
        /* set the supported curve so client TLS extension contains only the
         * desired curves */
        if ((ssl && wolfSSL_UseSupportedCurve(ssl, curve) != WOLFSSL_SUCCESS)
            || (ctx && wolfSSL_CTX_UseSupportedCurve(ctx, curve)
                           != WOLFSSL_SUCCESS)) {
            WOLFSSL_MSG("Unable to set supported curve");
            goto leave;
        }
    #endif
    #endif /* HAVE_SUPPORTED_CURVES */
    }

    if (ssl)
        ssl->disabledCurves = disabled;
    else
        ctx->disabledCurves = disabled;
    ret = WOLFSSL_SUCCESS;

leave:
#ifdef WOLFSSL_SMALL_STACK
    if (groups)
        XFREE((void*)groups, heap, DYNAMIC_TYPE_TMP_BUFFER);
#endif
    return ret;
}

int wolfSSL_CTX_set1_curves_list(WOLFSSL_CTX* ctx, const char* names)
{
    if (ctx == NULL || names == NULL) {
        WOLFSSL_MSG("ctx or names was NULL");
        return WOLFSSL_FAILURE;
    }
    return set_curves_list(NULL, ctx, names);
}

int wolfSSL_set1_curves_list(WOLFSSL* ssl, const char* names)
{
    if (ssl == NULL || names == NULL) {
        WOLFSSL_MSG("ssl or names was NULL");
        return WOLFSSL_FAILURE;
    }
    return set_curves_list(ssl, NULL, names);
}
#endif /* OPENSSL_EXTRA && (HAVE_ECC || HAVE_CURVE25519 || HAVE_CURVE448) */

#ifdef OPENSSL_EXTRA
/* Sets a callback for when sending and receiving protocol messages.
 * This callback is copied to all WOLFSSL objects created from the ctx.
 *
 * ctx WOLFSSL_CTX structure to set callback in
 * cb  callback to use
 *
 * return WOLFSSL_SUCCESS on success and SSL_FAILURE with error case
 */
int wolfSSL_CTX_set_msg_callback(WOLFSSL_CTX *ctx, SSL_Msg_Cb cb)
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_msg_callback");
    if (ctx == NULL) {
        WOLFSSL_MSG("Null ctx passed in");
        return WOLFSSL_FAILURE;
    }

    ctx->protoMsgCb = cb;
    return WOLFSSL_SUCCESS;
}


/* Sets a callback for when sending and receiving protocol messages.
 *
 * ssl WOLFSSL structure to set callback in
 * cb  callback to use
 *
 * return WOLFSSL_SUCCESS on success and SSL_FAILURE with error case
 */
int wolfSSL_set_msg_callback(WOLFSSL *ssl, SSL_Msg_Cb cb)
{
    WOLFSSL_ENTER("wolfSSL_set_msg_callback");

    if (ssl == NULL) {
        return SSL_FAILURE;
    }

    if (cb != NULL) {
        ssl->toInfoOn = 1;
    }

    ssl->protoMsgCb = cb;
    return WOLFSSL_SUCCESS;
}


/* set the user argument to pass to the msg callback when called
 * return WOLFSSL_SUCCESS on success */
int wolfSSL_CTX_set_msg_callback_arg(WOLFSSL_CTX *ctx, void* arg)
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_msg_callback_arg");
    if (ctx == NULL) {
        WOLFSSL_MSG("Null WOLFSSL_CTX passed in");
        return WOLFSSL_FAILURE;
    }

    ctx->protoMsgCtx = arg;
    return WOLFSSL_SUCCESS;
}


int wolfSSL_set_msg_callback_arg(WOLFSSL *ssl, void* arg)
{
    WOLFSSL_ENTER("wolfSSL_set_msg_callback_arg");
    if (ssl == NULL)
        return WOLFSSL_FAILURE;

    ssl->protoMsgCtx = arg;
    return WOLFSSL_SUCCESS;
}

void *wolfSSL_OPENSSL_memdup(const void *data, size_t siz, const char* file, int line)
{
    void *ret;
    (void)file;
    (void)line;

    if (data == NULL || siz >= INT_MAX)
        return NULL;

    ret = OPENSSL_malloc(siz);
    if (ret == NULL) {
        return NULL;
    }
    return XMEMCPY(ret, data, siz);
}

void wolfSSL_OPENSSL_cleanse(void *ptr, size_t len)
{
    if (ptr)
        ForceZero(ptr, (word32)len);
}

int wolfSSL_CTX_set_alpn_protos(WOLFSSL_CTX *ctx, const unsigned char *p,
                            unsigned int p_len)
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_alpn_protos");
    if (ctx == NULL)
        return BAD_FUNC_ARG;
    if (ctx->alpn_cli_protos != NULL) {
        XFREE((void*)ctx->alpn_cli_protos, ctx->heap, DYNAMIC_TYPE_OPENSSL);
    }

    ctx->alpn_cli_protos = (const unsigned char*)XMALLOC(p_len,
        ctx->heap, DYNAMIC_TYPE_OPENSSL);
    if (ctx->alpn_cli_protos == NULL) {
#if defined(WOLFSSL_ERROR_CODE_OPENSSL)
        /* 0 on success in OpenSSL, non-0 on failure in OpenSSL
         * the function reverses the return value convention.
         */
        return 1;
#else
        return WOLFSSL_FAILURE;
#endif
    }
    XMEMCPY((void*)ctx->alpn_cli_protos, p, p_len);
    ctx->alpn_cli_protos_len = p_len;

#if defined(WOLFSSL_ERROR_CODE_OPENSSL)
    /* 0 on success in OpenSSL, non-0 on failure in OpenSSL
     * the function reverses the return value convention.
     */
    return 0;
#else
    return WOLFSSL_SUCCESS;
#endif
}


#ifdef HAVE_ALPN
#ifndef NO_BIO
/* Sets the ALPN extension protos
 *
 * example format is
 * unsigned char p[] = {
 *      8, 'h', 't', 't', 'p', '/', '1', '.', '1'
 * };
 *
 * returns WOLFSSL_SUCCESS on success */
int wolfSSL_set_alpn_protos(WOLFSSL* ssl,
        const unsigned char* p, unsigned int p_len)
{
    WOLFSSL_BIO* bio;
    char* pt;

    unsigned int sz;
    unsigned int idx = 0;
    int alpn_opt = WOLFSSL_ALPN_CONTINUE_ON_MISMATCH;
    WOLFSSL_ENTER("wolfSSL_set_alpn_protos");

    if (ssl == NULL || p_len <= 1) {
#if defined(WOLFSSL_ERROR_CODE_OPENSSL)
        /* 0 on success in OpenSSL, non-0 on failure in OpenSSL
         * the function reverses the return value convention.
         */
        return 1;
#else
        return WOLFSSL_FAILURE;
#endif
    }

    bio = wolfSSL_BIO_new(wolfSSL_BIO_s_mem());
    if (bio == NULL) {
#if defined(WOLFSSL_ERROR_CODE_OPENSSL)
        /* 0 on success in OpenSSL, non-0 on failure in OpenSSL
         * the function reverses the return value convention.
         */
        return 1;
#else
        return WOLFSSL_FAILURE;
#endif
    }

    /* convert into comma separated list */
    while (idx < p_len - 1) {
        unsigned int i;

        sz = p[idx++];
        if (idx + sz > p_len) {
            WOLFSSL_MSG("Bad list format");
            wolfSSL_BIO_free(bio);
    #if defined(WOLFSSL_ERROR_CODE_OPENSSL)
            /* 0 on success in OpenSSL, non-0 on failure in OpenSSL
             * the function reverses the return value convention.
             */
            return 1;
    #else
            return WOLFSSL_FAILURE;
    #endif
        }
        if (sz > 0) {
            for (i = 0; i < sz; i++) {
                wolfSSL_BIO_write(bio, &p[idx++], 1);
            }
            if (idx < p_len - 1)
                wolfSSL_BIO_write(bio, ",", 1);
        }
    }
    wolfSSL_BIO_write(bio, "\0", 1);

    /* clears out all current ALPN extensions set */
    TLSX_Remove(&ssl->extensions, TLSX_APPLICATION_LAYER_PROTOCOL, ssl->heap);

    if ((sz = wolfSSL_BIO_get_mem_data(bio, &pt)) > 0) {
        wolfSSL_UseALPN(ssl, pt, sz, (byte) alpn_opt);
    }
    wolfSSL_BIO_free(bio);
#if defined(WOLFSSL_ERROR_CODE_OPENSSL)
    /* 0 on success in OpenSSL, non-0 on failure in OpenSSL
     * the function reverses the return value convention.
     */
    return 0;
#else
    return WOLFSSL_SUCCESS;
#endif
}
#endif /* !NO_BIO */
#endif /* HAVE_ALPN */
#endif /* OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA)

#ifndef NO_BIO
#define WOLFSSL_BIO_INCLUDED
#include "src/bio.c"
#endif

word32 nid2oid(int nid, int grp)
{
    /* get OID type */
    switch (grp) {
        /* oidHashType */
        case oidHashType:
            switch (nid) {
            #ifdef WOLFSSL_MD2
                case NID_md2:
                    return MD2h;
            #endif
            #ifndef NO_MD5
                case NID_md5:
                    return MD5h;
            #endif
            #ifndef NO_SHA
                case NID_sha1:
                    return SHAh;
            #endif
                case NID_sha224:
                    return SHA224h;
            #ifndef NO_SHA256
                case NID_sha256:
                    return SHA256h;
            #endif
            #ifdef WOLFSSL_SHA384
                case NID_sha384:
                    return SHA384h;
            #endif
            #ifdef WOLFSSL_SHA512
                case NID_sha512:
                    return SHA512h;
            #endif
            #ifndef WOLFSSL_NOSHA3_224
                case NID_sha3_224:
                    return SHA3_224h;
            #endif
            #ifndef WOLFSSL_NOSHA3_256
                case NID_sha3_256:
                    return SHA3_256h;
            #endif
            #ifndef WOLFSSL_NOSHA3_384
                case NID_sha3_384:
                    return SHA3_384h;
            #endif
            #ifndef WOLFSSL_NOSHA3_512
                case NID_sha3_512:
                    return SHA3_512h;
            #endif
            }
            break;

        /*  oidSigType */
        case oidSigType:
            switch (nid) {
            #ifndef NO_DSA
                case NID_dsaWithSHA1:
                    return CTC_SHAwDSA;
                case NID_dsa_with_SHA256:
                    return CTC_SHA256wDSA;
            #endif /* NO_DSA */
            #ifndef NO_RSA
                case NID_md2WithRSAEncryption:
                    return CTC_MD2wRSA;
                case NID_md5WithRSAEncryption:
                    return CTC_MD5wRSA;
                case NID_sha1WithRSAEncryption:
                    return CTC_SHAwRSA;
                case NID_sha224WithRSAEncryption:
                    return CTC_SHA224wRSA;
                case NID_sha256WithRSAEncryption:
                    return CTC_SHA256wRSA;
                case NID_sha384WithRSAEncryption:
                    return CTC_SHA384wRSA;
                case NID_sha512WithRSAEncryption:
                    return CTC_SHA512wRSA;
                #ifdef WOLFSSL_SHA3
                case NID_RSA_SHA3_224:
                    return CTC_SHA3_224wRSA;
                case NID_RSA_SHA3_256:
                    return CTC_SHA3_256wRSA;
                case NID_RSA_SHA3_384:
                    return CTC_SHA3_384wRSA;
                case NID_RSA_SHA3_512:
                    return CTC_SHA3_512wRSA;
                #endif
            #endif /* NO_RSA */
            #ifdef HAVE_ECC
                case NID_ecdsa_with_SHA1:
                    return CTC_SHAwECDSA;
                case NID_ecdsa_with_SHA224:
                    return CTC_SHA224wECDSA;
                case NID_ecdsa_with_SHA256:
                    return CTC_SHA256wECDSA;
                case NID_ecdsa_with_SHA384:
                    return CTC_SHA384wECDSA;
                case NID_ecdsa_with_SHA512:
                    return CTC_SHA512wECDSA;
                #ifdef WOLFSSL_SHA3
                case NID_ecdsa_with_SHA3_224:
                    return CTC_SHA3_224wECDSA;
                case NID_ecdsa_with_SHA3_256:
                    return CTC_SHA3_256wECDSA;
                case NID_ecdsa_with_SHA3_384:
                    return CTC_SHA3_384wECDSA;
                case NID_ecdsa_with_SHA3_512:
                    return CTC_SHA3_512wECDSA;
                #endif
            #endif /* HAVE_ECC */
            }
            break;

        /* oidKeyType */
        case oidKeyType:
            switch (nid) {
            #ifndef NO_DSA
                case NID_dsa:
                    return DSAk;
            #endif /* NO_DSA */
            #ifndef NO_RSA
                case NID_rsaEncryption:
                    return RSAk;
            #endif /* NO_RSA */
            #ifdef HAVE_ECC
                case NID_X9_62_id_ecPublicKey:
                    return ECDSAk;
            #endif /* HAVE_ECC */
            }
            break;


    #ifdef HAVE_ECC
        case oidCurveType:
            switch (nid) {
            case NID_X9_62_prime192v1:
                return ECC_SECP192R1_OID;
            case NID_X9_62_prime192v2:
                return ECC_PRIME192V2_OID;
            case NID_X9_62_prime192v3:
                return ECC_PRIME192V3_OID;
            case NID_X9_62_prime239v1:
                return ECC_PRIME239V1_OID;
            case NID_X9_62_prime239v2:
                return ECC_PRIME239V2_OID;
            case NID_X9_62_prime239v3:
                return ECC_PRIME239V3_OID;
            case NID_X9_62_prime256v1:
                return ECC_SECP256R1_OID;
            case NID_secp112r1:
                return ECC_SECP112R1_OID;
            case NID_secp112r2:
                return ECC_SECP112R2_OID;
            case NID_secp128r1:
                return ECC_SECP128R1_OID;
            case NID_secp128r2:
                return ECC_SECP128R2_OID;
            case NID_secp160r1:
                return ECC_SECP160R1_OID;
            case NID_secp160r2:
                return ECC_SECP160R2_OID;
            case NID_secp224r1:
                return ECC_SECP224R1_OID;
            case NID_secp384r1:
                return ECC_SECP384R1_OID;
            case NID_secp521r1:
                return ECC_SECP521R1_OID;
            case NID_secp160k1:
                return ECC_SECP160K1_OID;
            case NID_secp192k1:
                return ECC_SECP192K1_OID;
            case NID_secp224k1:
                return ECC_SECP224K1_OID;
            case NID_secp256k1:
                return ECC_SECP256K1_OID;
            case NID_brainpoolP160r1:
                return ECC_BRAINPOOLP160R1_OID;
            case NID_brainpoolP192r1:
                return ECC_BRAINPOOLP192R1_OID;
            case NID_brainpoolP224r1:
                return ECC_BRAINPOOLP224R1_OID;
            case NID_brainpoolP256r1:
                return ECC_BRAINPOOLP256R1_OID;
            case NID_brainpoolP320r1:
                return ECC_BRAINPOOLP320R1_OID;
            case NID_brainpoolP384r1:
                return ECC_BRAINPOOLP384R1_OID;
            case NID_brainpoolP512r1:
                return ECC_BRAINPOOLP512R1_OID;
            }
            break;
    #endif /* HAVE_ECC */

        /* oidBlkType */
        case oidBlkType:
            switch (nid) {
            #ifdef WOLFSSL_AES_128
                case AES128CBCb:
                    return AES128CBCb;
            #endif
            #ifdef WOLFSSL_AES_192
                case AES192CBCb:
                    return AES192CBCb;
            #endif
            #ifdef WOLFSSL_AES_256
                case AES256CBCb:
                    return AES256CBCb;
            #endif
            #ifndef NO_DES3
                case NID_des:
                    return DESb;
                case NID_des3:
                    return DES3b;
            #endif
            }
            break;

    #ifdef HAVE_OCSP
        case oidOcspType:
            switch (nid) {
                case NID_id_pkix_OCSP_basic:
                    return OCSP_BASIC_OID;
                case OCSP_NONCE_OID:
                    return OCSP_NONCE_OID;
            }
            break;
    #endif /* HAVE_OCSP */

        /* oidCertExtType */
        case oidCertExtType:
            switch (nid) {
                case NID_basic_constraints:
                    return BASIC_CA_OID;
                case NID_subject_alt_name:
                    return ALT_NAMES_OID;
                case NID_crl_distribution_points:
                    return CRL_DIST_OID;
                case NID_info_access:
                    return AUTH_INFO_OID;
                case NID_authority_key_identifier:
                    return AUTH_KEY_OID;
                case NID_subject_key_identifier:
                    return SUBJ_KEY_OID;
                case NID_inhibit_any_policy:
                    return INHIBIT_ANY_OID;
                case NID_key_usage:
                    return KEY_USAGE_OID;
                case NID_name_constraints:
                    return NAME_CONS_OID;
                case NID_certificate_policies:
                    return CERT_POLICY_OID;
                case NID_ext_key_usage:
                    return EXT_KEY_USAGE_OID;
            }
            break;

        /* oidCertAuthInfoType */
        case oidCertAuthInfoType:
            switch (nid) {
                case NID_ad_OCSP:
                    return AIA_OCSP_OID;
                case NID_ad_ca_issuers:
                    return AIA_CA_ISSUER_OID;
            }
            break;

        /* oidCertPolicyType */
        case oidCertPolicyType:
            switch (nid) {
                case NID_any_policy:
                    return CP_ANY_OID;
            }
            break;

        /* oidCertAltNameType */
        case oidCertAltNameType:
            switch (nid) {
                case NID_hw_name_oid:
                    return HW_NAME_OID;
            }
            break;

        /* oidCertKeyUseType */
        case oidCertKeyUseType:
            switch (nid) {
                case NID_anyExtendedKeyUsage:
                    return EKU_ANY_OID;
                case EKU_SERVER_AUTH_OID:
                    return EKU_SERVER_AUTH_OID;
                case EKU_CLIENT_AUTH_OID:
                    return EKU_CLIENT_AUTH_OID;
                case EKU_OCSP_SIGN_OID:
                    return EKU_OCSP_SIGN_OID;
            }
            break;

        /* oidKdfType */
        case oidKdfType:
            switch (nid) {
                case PBKDF2_OID:
                    return PBKDF2_OID;
            }
            break;

        /* oidPBEType */
        case oidPBEType:
            switch (nid) {
                case PBE_SHA1_RC4_128:
                    return PBE_SHA1_RC4_128;
                case PBE_SHA1_DES:
                    return PBE_SHA1_DES;
                case PBE_SHA1_DES3:
                    return PBE_SHA1_DES3;
            }
            break;

        /* oidKeyWrapType */
        case oidKeyWrapType:
            switch (nid) {
            #ifdef WOLFSSL_AES_128
                case AES128_WRAP:
                    return AES128_WRAP;
            #endif
            #ifdef WOLFSSL_AES_192
                case AES192_WRAP:
                    return AES192_WRAP;
            #endif
            #ifdef WOLFSSL_AES_256
                case AES256_WRAP:
                    return AES256_WRAP;
            #endif
            }
            break;

        /* oidCmsKeyAgreeType */
        case oidCmsKeyAgreeType:
            switch (nid) {
                #ifndef NO_SHA
                case dhSinglePass_stdDH_sha1kdf_scheme:
                    return dhSinglePass_stdDH_sha1kdf_scheme;
                #endif
                #ifdef WOLFSSL_SHA224
                case dhSinglePass_stdDH_sha224kdf_scheme:
                    return dhSinglePass_stdDH_sha224kdf_scheme;
                #endif
                #ifndef NO_SHA256
                case dhSinglePass_stdDH_sha256kdf_scheme:
                    return dhSinglePass_stdDH_sha256kdf_scheme;
                #endif
                #ifdef WOLFSSL_SHA384
                case dhSinglePass_stdDH_sha384kdf_scheme:
                    return dhSinglePass_stdDH_sha384kdf_scheme;
                #endif
                #ifdef WOLFSSL_SHA512
                case dhSinglePass_stdDH_sha512kdf_scheme:
                    return dhSinglePass_stdDH_sha512kdf_scheme;
                #endif
            }
            break;

        default:
            WOLFSSL_MSG("NID not in table");
            /* MSVC warns without the cast */
            return (word32)-1;
    }

    /* MSVC warns without the cast */
    return (word32)-1;
}

int oid2nid(word32 oid, int grp)
{
    size_t i;
    /* get OID type */
    switch (grp) {
        /* oidHashType */
        case oidHashType:
            switch (oid) {
            #ifdef WOLFSSL_MD2
                case MD2h:
                    return NID_md2;
            #endif
            #ifndef NO_MD5
                case MD5h:
                    return NID_md5;
            #endif
            #ifndef NO_SHA
                case SHAh:
                    return NID_sha1;
            #endif
                case SHA224h:
                    return NID_sha224;
            #ifndef NO_SHA256
                case SHA256h:
                    return NID_sha256;
            #endif
            #ifdef WOLFSSL_SHA384
                case SHA384h:
                    return NID_sha384;
            #endif
            #ifdef WOLFSSL_SHA512
                case SHA512h:
                    return NID_sha512;
            #endif
            }
            break;

        /*  oidSigType */
        case oidSigType:
            switch (oid) {
            #ifndef NO_DSA
                case CTC_SHAwDSA:
                    return NID_dsaWithSHA1;
                case CTC_SHA256wDSA:
                    return NID_dsa_with_SHA256;
            #endif /* NO_DSA */
            #ifndef NO_RSA
                case CTC_MD2wRSA:
                    return NID_md2WithRSAEncryption;
                case CTC_MD5wRSA:
                    return NID_md5WithRSAEncryption;
                case CTC_SHAwRSA:
                    return NID_sha1WithRSAEncryption;
                case CTC_SHA224wRSA:
                    return NID_sha224WithRSAEncryption;
                case CTC_SHA256wRSA:
                    return NID_sha256WithRSAEncryption;
                case CTC_SHA384wRSA:
                    return NID_sha384WithRSAEncryption;
                case CTC_SHA512wRSA:
                    return NID_sha512WithRSAEncryption;
                #ifdef WOLFSSL_SHA3
                case CTC_SHA3_224wRSA:
                    return NID_RSA_SHA3_224;
                case CTC_SHA3_256wRSA:
                    return NID_RSA_SHA3_256;
                case CTC_SHA3_384wRSA:
                    return NID_RSA_SHA3_384;
                case CTC_SHA3_512wRSA:
                    return NID_RSA_SHA3_512;
                #endif
            #endif /* NO_RSA */
            #ifdef HAVE_ECC
                case CTC_SHAwECDSA:
                    return NID_ecdsa_with_SHA1;
                case CTC_SHA224wECDSA:
                    return NID_ecdsa_with_SHA224;
                case CTC_SHA256wECDSA:
                    return NID_ecdsa_with_SHA256;
                case CTC_SHA384wECDSA:
                    return NID_ecdsa_with_SHA384;
                case CTC_SHA512wECDSA:
                    return NID_ecdsa_with_SHA512;
                #ifdef WOLFSSL_SHA3
                case CTC_SHA3_224wECDSA:
                    return NID_ecdsa_with_SHA3_224;
                case CTC_SHA3_256wECDSA:
                    return NID_ecdsa_with_SHA3_256;
                case CTC_SHA3_384wECDSA:
                    return NID_ecdsa_with_SHA3_384;
                case CTC_SHA3_512wECDSA:
                    return NID_ecdsa_with_SHA3_512;
                #endif
            #endif /* HAVE_ECC */
            }
            break;

        /* oidKeyType */
        case oidKeyType:
            switch (oid) {
            #ifndef NO_DSA
                case DSAk:
                    return NID_dsa;
            #endif /* NO_DSA */
            #ifndef NO_RSA
                case RSAk:
                    return NID_rsaEncryption;
            #endif /* NO_RSA */
            #ifdef HAVE_ECC
                case ECDSAk:
                    return NID_X9_62_id_ecPublicKey;
            #endif /* HAVE_ECC */
            }
            break;


    #ifdef HAVE_ECC
        case oidCurveType:
            switch (oid) {
            case ECC_SECP192R1_OID:
                return NID_X9_62_prime192v1;
            case ECC_PRIME192V2_OID:
                return NID_X9_62_prime192v2;
            case ECC_PRIME192V3_OID:
                return NID_X9_62_prime192v3;
            case ECC_PRIME239V1_OID:
                return NID_X9_62_prime239v1;
            case ECC_PRIME239V2_OID:
                return NID_X9_62_prime239v2;
            case ECC_PRIME239V3_OID:
                return NID_X9_62_prime239v3;
            case ECC_SECP256R1_OID:
                return NID_X9_62_prime256v1;
            case ECC_SECP112R1_OID:
                return NID_secp112r1;
            case ECC_SECP112R2_OID:
                return NID_secp112r2;
            case ECC_SECP128R1_OID:
                return NID_secp128r1;
            case ECC_SECP128R2_OID:
                return NID_secp128r2;
            case ECC_SECP160R1_OID:
                return NID_secp160r1;
            case ECC_SECP160R2_OID:
                return NID_secp160r2;
            case ECC_SECP224R1_OID:
                return NID_secp224r1;
            case ECC_SECP384R1_OID:
                return NID_secp384r1;
            case ECC_SECP521R1_OID:
                return NID_secp521r1;
            case ECC_SECP160K1_OID:
                return NID_secp160k1;
            case ECC_SECP192K1_OID:
                return NID_secp192k1;
            case ECC_SECP224K1_OID:
                return NID_secp224k1;
            case ECC_SECP256K1_OID:
                return NID_secp256k1;
            case ECC_BRAINPOOLP160R1_OID:
                return NID_brainpoolP160r1;
            case ECC_BRAINPOOLP192R1_OID:
                return NID_brainpoolP192r1;
            case ECC_BRAINPOOLP224R1_OID:
                return NID_brainpoolP224r1;
            case ECC_BRAINPOOLP256R1_OID:
                return NID_brainpoolP256r1;
            case ECC_BRAINPOOLP320R1_OID:
                return NID_brainpoolP320r1;
            case ECC_BRAINPOOLP384R1_OID:
                return NID_brainpoolP384r1;
            case ECC_BRAINPOOLP512R1_OID:
                return NID_brainpoolP512r1;
            }
            break;
    #endif /* HAVE_ECC */

        /* oidBlkType */
        case oidBlkType:
            switch (oid) {
            #ifdef WOLFSSL_AES_128
                case AES128CBCb:
                    return AES128CBCb;
            #endif
            #ifdef WOLFSSL_AES_192
                case AES192CBCb:
                    return AES192CBCb;
            #endif
            #ifdef WOLFSSL_AES_256
                case AES256CBCb:
                    return AES256CBCb;
            #endif
            #ifndef NO_DES3
                case DESb:
                    return NID_des;
                case DES3b:
                    return NID_des3;
            #endif
            }
            break;

    #ifdef HAVE_OCSP
        case oidOcspType:
            switch (oid) {
                case OCSP_BASIC_OID:
                    return NID_id_pkix_OCSP_basic;
                case OCSP_NONCE_OID:
                    return OCSP_NONCE_OID;
            }
            break;
    #endif /* HAVE_OCSP */

        /* oidCertExtType */
        case oidCertExtType:
            switch (oid) {
                case BASIC_CA_OID:
                    return NID_basic_constraints;
                case ALT_NAMES_OID:
                    return NID_subject_alt_name;
                case CRL_DIST_OID:
                    return NID_crl_distribution_points;
                case AUTH_INFO_OID:
                    return NID_info_access;
                case AUTH_KEY_OID:
                    return NID_authority_key_identifier;
                case SUBJ_KEY_OID:
                    return NID_subject_key_identifier;
                case INHIBIT_ANY_OID:
                    return NID_inhibit_any_policy;
                case KEY_USAGE_OID:
                    return NID_key_usage;
                case NAME_CONS_OID:
                    return NID_name_constraints;
                case CERT_POLICY_OID:
                    return NID_certificate_policies;
                case EXT_KEY_USAGE_OID:
                    return NID_ext_key_usage;
            }
            break;

        /* oidCertAuthInfoType */
        case oidCertAuthInfoType:
            switch (oid) {
                case AIA_OCSP_OID:
                    return NID_ad_OCSP;
                case AIA_CA_ISSUER_OID:
                    return NID_ad_ca_issuers;
            }
            break;

        /* oidCertPolicyType */
        case oidCertPolicyType:
            switch (oid) {
                case CP_ANY_OID:
                    return NID_any_policy;
            }
            break;

        /* oidCertAltNameType */
        case oidCertAltNameType:
            switch (oid) {
                case HW_NAME_OID:
                    return NID_hw_name_oid;
            }
            break;

        /* oidCertKeyUseType */
        case oidCertKeyUseType:
            switch (oid) {
                case EKU_ANY_OID:
                    return NID_anyExtendedKeyUsage;
                case EKU_SERVER_AUTH_OID:
                    return EKU_SERVER_AUTH_OID;
                case EKU_CLIENT_AUTH_OID:
                    return EKU_CLIENT_AUTH_OID;
                case EKU_OCSP_SIGN_OID:
                    return EKU_OCSP_SIGN_OID;
            }
            break;

        /* oidKdfType */
        case oidKdfType:
            switch (oid) {
                case PBKDF2_OID:
                    return PBKDF2_OID;
            }
            break;

        /* oidPBEType */
        case oidPBEType:
            switch (oid) {
                case PBE_SHA1_RC4_128:
                    return PBE_SHA1_RC4_128;
                case PBE_SHA1_DES:
                    return PBE_SHA1_DES;
                case PBE_SHA1_DES3:
                    return PBE_SHA1_DES3;
            }
            break;

        /* oidKeyWrapType */
        case oidKeyWrapType:
            switch (oid) {
            #ifdef WOLFSSL_AES_128
                case AES128_WRAP:
                    return AES128_WRAP;
            #endif
            #ifdef WOLFSSL_AES_192
                case AES192_WRAP:
                    return AES192_WRAP;
            #endif
            #ifdef WOLFSSL_AES_256
                case AES256_WRAP:
                    return AES256_WRAP;
            #endif
            }
            break;

        /* oidCmsKeyAgreeType */
        case oidCmsKeyAgreeType:
            switch (oid) {
                #ifndef NO_SHA
                case dhSinglePass_stdDH_sha1kdf_scheme:
                    return dhSinglePass_stdDH_sha1kdf_scheme;
                #endif
                #ifdef WOLFSSL_SHA224
                case dhSinglePass_stdDH_sha224kdf_scheme:
                    return dhSinglePass_stdDH_sha224kdf_scheme;
                #endif
                #ifndef NO_SHA256
                case dhSinglePass_stdDH_sha256kdf_scheme:
                    return dhSinglePass_stdDH_sha256kdf_scheme;
                #endif
                #ifdef WOLFSSL_SHA384
                case dhSinglePass_stdDH_sha384kdf_scheme:
                    return dhSinglePass_stdDH_sha384kdf_scheme;
                #endif
                #ifdef WOLFSSL_SHA512
                case dhSinglePass_stdDH_sha512kdf_scheme:
                    return dhSinglePass_stdDH_sha512kdf_scheme;
                #endif
            }
            break;

#ifdef WOLFSSL_CERT_REQ
        case oidCsrAttrType:
            switch (oid) {
                case PKCS9_CONTENT_TYPE_OID:
                    return NID_pkcs9_contentType;
                case CHALLENGE_PASSWORD_OID:
                    return NID_pkcs9_challengePassword;
                case SERIAL_NUMBER_OID:
                    return NID_serialNumber;
                case USER_ID_OID:
                    return NID_userId;
            }
            break;
#endif

        default:
            WOLFSSL_MSG("NID not in table");
    }
    /* If not found in above switch then try the table */
    for (i = 0; i < WOLFSSL_OBJECT_INFO_SZ; i++) {
        if (wolfssl_object_info[i].id == (int)oid) {
            return wolfssl_object_info[i].nid;
        }
    }

    return -1;
}

/* when calling SetIndividualInternal, mpi should be cleared by caller if no
 * longer used. ie mp_free(mpi). This is to free data when fastmath is
 * disabled since a copy of mpi is made by this function and placed into bn.
 */
int SetIndividualInternal(WOLFSSL_BIGNUM* bn, mp_int* mpi)
{
    WOLFSSL_MSG("Entering SetIndividualInternal");

    if (bn == NULL || bn->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        return WOLFSSL_FATAL_ERROR;
    }

    if (mpi == NULL) {
        WOLFSSL_MSG("mpi NULL error");
        return WOLFSSL_FATAL_ERROR;
    }

    if (mp_copy((mp_int*)bn->internal, mpi) != MP_OKAY) {
        WOLFSSL_MSG("mp_copy error");
        return WOLFSSL_FATAL_ERROR;
    }

    return WOLFSSL_SUCCESS;
}


#ifndef NO_ASN
WOLFSSL_BIGNUM *wolfSSL_ASN1_INTEGER_to_BN(const WOLFSSL_ASN1_INTEGER *ai,
                                       WOLFSSL_BIGNUM *bn)
{
#ifdef WOLFSSL_SMALL_STACK
    mp_int* mpi = NULL;
#else
    mp_int mpi[1];
#endif
    word32 idx = 0;
    int ret;

    WOLFSSL_ENTER("wolfSSL_ASN1_INTEGER_to_BN");

    if (ai == NULL) {
        return NULL;
    }

#ifdef WOLFSSL_SMALL_STACK
    mpi = (mp_int*)XMALLOC(sizeof(mp_int), NULL, DYNAMIC_TYPE_BIGINT);
    if (mpi == NULL) {
        return NULL;
    }
#endif

    ret = GetInt(mpi, ai->data, &idx, ai->dataMax);
    if (ret != 0) {
    #if defined(WOLFSSL_QT) || defined(WOLFSSL_HAPROXY)
        ret = mp_init(mpi); /* must init mpi */
        if (ret != MP_OKAY) {
        #ifdef WOLFSSL_SMALL_STACK
            XFREE(mpi, NULL, DYNAMIC_TYPE_BIGINT);
        #endif
            return NULL;
        }
        /* Serial number in QT starts at index 0 of data */
        if (mp_read_unsigned_bin(mpi, (byte*)ai->data, ai->length) != 0) {
                mp_clear(mpi);
            #ifdef WOLFSSL_SMALL_STACK
                XFREE(mpi, NULL, DYNAMIC_TYPE_BIGINT);
            #endif
                return NULL;
            }
    #else
        /* expecting ASN1 format for INTEGER */
        WOLFSSL_LEAVE("wolfSSL_ASN1_INTEGER_to_BN", ret);
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(mpi, NULL, DYNAMIC_TYPE_BIGINT);
    #endif
        return NULL;
    #endif
    }

    /* mp_clear needs called because mpi is copied and causes memory leak with
     * --disable-fastmath */
    ret = SetIndividualExternal(&bn, mpi);
    mp_clear(mpi);

#ifdef WOLFSSL_SMALL_STACK
    XFREE(mpi, NULL, DYNAMIC_TYPE_BIGINT);
#endif

    if (ret != WOLFSSL_SUCCESS) {
        return NULL;
    }
    return bn;
}
#endif /* !NO_ASN */

/* frees all nodes in the current threads error queue
 *
 * id  thread id. ERR_remove_state is depreciated and id is ignored. The
 *     current threads queue will be free'd.
 */
void wolfSSL_ERR_remove_state(unsigned long id)
{
    WOLFSSL_ENTER("wolfSSL_ERR_remove_state");
    (void)id;
    if (wc_ERR_remove_state() != 0) {
        WOLFSSL_MSG("Error with removing the state");
    }
}


WOLFSSL_BN_CTX* wolfSSL_BN_CTX_new(void)
{
    static int ctx;  /* wolfcrypt doesn't now need ctx */

    WOLFSSL_MSG("wolfSSL_BN_CTX_new");
    return (WOLFSSL_BN_CTX*)&ctx;

}

void wolfSSL_BN_CTX_init(WOLFSSL_BN_CTX* ctx)
{
    (void)ctx;
    WOLFSSL_MSG("wolfSSL_BN_CTX_init");
}


void wolfSSL_BN_CTX_free(WOLFSSL_BN_CTX* ctx)
{
    (void)ctx;
    WOLFSSL_MSG("wolfSSL_BN_CTX_free");
    /* do free since static ctx that does nothing */
}

/* WOLFSSL_SUCCESS on ok */
int wolfSSL_BN_sub(WOLFSSL_BIGNUM* r, const WOLFSSL_BIGNUM* a,
                  const WOLFSSL_BIGNUM* b)
{
    WOLFSSL_MSG("wolfSSL_BN_sub");

    if (r == NULL || a == NULL || b == NULL)
        return 0;

    if (mp_sub((mp_int*)a->internal,(mp_int*)b->internal,
               (mp_int*)r->internal) == MP_OKAY)
        return WOLFSSL_SUCCESS;

    WOLFSSL_MSG("wolfSSL_BN_sub mp_sub failed");
    return 0;
}

int wolfSSL_BN_mul(WOLFSSL_BIGNUM *r, WOLFSSL_BIGNUM *a, WOLFSSL_BIGNUM *b,
    WOLFSSL_BN_CTX *ctx)
{
    int ret = WOLFSSL_SUCCESS;

    (void)ctx;

    WOLFSSL_ENTER("wolfSSL_BN_mul");

    if (r == NULL || a == NULL || b == NULL || r->internal == NULL ||
        a->internal == NULL || b->internal == NULL) {
        ret = WOLFSSL_FAILURE;
    }

    if (ret == WOLFSSL_SUCCESS) {
        ret = mp_mul((mp_int*)a->internal, (mp_int*)b->internal,
                     (mp_int*)r->internal);
        if (ret == MP_OKAY) {
            ret = WOLFSSL_SUCCESS;
        }
        else {
            ret = WOLFSSL_FAILURE;
        }
    }

    WOLFSSL_LEAVE("wolfSSL_BN_mul", ret);

    return ret;
}

#ifndef WOLFSSL_SP_MATH
int wolfSSL_BN_div(WOLFSSL_BIGNUM* dv, WOLFSSL_BIGNUM* rem,
                   const WOLFSSL_BIGNUM* a, const WOLFSSL_BIGNUM* d,
                   WOLFSSL_BN_CTX* ctx)
{
    int ret = WOLFSSL_SUCCESS;

    (void)ctx;

    WOLFSSL_ENTER("wolfSSL_BN_div");

    if (dv == NULL || rem == NULL || a == NULL || d == NULL ||
        dv->internal == NULL || rem->internal == NULL || a->internal == NULL ||
        d->internal == NULL) {
        ret = WOLFSSL_FAILURE;
    }

    if (ret == WOLFSSL_SUCCESS) {
        ret = mp_div((mp_int*)a->internal, (mp_int*)d->internal,
                     (mp_int*)dv->internal, (mp_int*)rem->internal);
        if (ret == MP_OKAY) {
            ret = WOLFSSL_SUCCESS;
        }
        else {
            ret = WOLFSSL_FAILURE;
        }
    }

    WOLFSSL_LEAVE("wolfSSL_BN_div", ret);

    return ret;
}
#endif

#if !defined(NO_RSA) && defined(WOLFSSL_KEY_GEN) /* Needed to get mp_gcd. */
int wolfSSL_BN_gcd(WOLFSSL_BIGNUM* r, WOLFSSL_BIGNUM* a, WOLFSSL_BIGNUM* b,
                   WOLFSSL_BN_CTX* ctx)
{
    int ret = WOLFSSL_SUCCESS;

    (void)ctx;

    WOLFSSL_ENTER("wolfSSL_BN_gcd");

    if (r == NULL || a == NULL || b == NULL || r->internal == NULL ||
        a->internal == NULL || b->internal == NULL) {
        ret = WOLFSSL_FAILURE;
    }

    if (ret == WOLFSSL_SUCCESS) {
        ret = mp_gcd((mp_int*)a->internal, (mp_int*)b->internal,
                     (mp_int*)r->internal);
        if (ret == MP_OKAY) {
            ret = WOLFSSL_SUCCESS;
        }
        else {
            ret = WOLFSSL_FAILURE;
        }
    }

    WOLFSSL_LEAVE("wolfSSL_BN_gcd", ret);

    return ret;
}
#endif /* !NO_RSA && WOLFSSL_KEY_GEN */

/* WOLFSSL_SUCCESS on ok */
int wolfSSL_BN_mod(WOLFSSL_BIGNUM* r, const WOLFSSL_BIGNUM* a,
                  const WOLFSSL_BIGNUM* b, const WOLFSSL_BN_CTX* c)
{
    (void)c;
    WOLFSSL_MSG("wolfSSL_BN_mod");

    if (r == NULL || a == NULL || b == NULL)
        return 0;

    if (mp_mod((mp_int*)a->internal,(mp_int*)b->internal,
               (mp_int*)r->internal) == MP_OKAY)
        return WOLFSSL_SUCCESS;

    WOLFSSL_MSG("wolfSSL_BN_mod mp_mod failed");
    return 0;
}


/* r = (a^p) % m */
int wolfSSL_BN_mod_exp(WOLFSSL_BIGNUM *r, const WOLFSSL_BIGNUM *a,
      const WOLFSSL_BIGNUM *p, const WOLFSSL_BIGNUM *m, WOLFSSL_BN_CTX *ctx)
{
    int ret;

    WOLFSSL_ENTER("wolfSSL_BN_mod_exp");

    (void) ctx;
    if (r == NULL || a == NULL || p == NULL || m == NULL) {
        WOLFSSL_MSG("Bad Argument");
        return WOLFSSL_FAILURE;
    }

    if ((ret = mp_exptmod((mp_int*)a->internal,(mp_int*)p->internal,
               (mp_int*)m->internal, (mp_int*)r->internal)) == MP_OKAY) {
        return WOLFSSL_SUCCESS;
    }

    WOLFSSL_LEAVE("wolfSSL_BN_mod_exp", ret);
    (void)ret;

    return WOLFSSL_FAILURE;
}

/* r = (a * p) % m */
int wolfSSL_BN_mod_mul(WOLFSSL_BIGNUM *r, const WOLFSSL_BIGNUM *a,
        const WOLFSSL_BIGNUM *p, const WOLFSSL_BIGNUM *m, WOLFSSL_BN_CTX *ctx)
{
    int ret;

    WOLFSSL_ENTER("wolfSSL_BN_mod_mul");

    (void) ctx;
    if (r == NULL || a == NULL || p == NULL || m == NULL) {
        WOLFSSL_MSG("Bad Argument");
        return SSL_FAILURE;
    }

    if ((ret = mp_mulmod((mp_int*)a->internal,(mp_int*)p->internal,
               (mp_int*)m->internal, (mp_int*)r->internal)) == MP_OKAY) {
        return WOLFSSL_SUCCESS;
    }

    WOLFSSL_LEAVE("wolfSSL_BN_mod_mul", ret);
    (void)ret;

    return SSL_FAILURE;
}

const WOLFSSL_BIGNUM* wolfSSL_BN_value_one(void)
{
    WOLFSSL_MSG("wolfSSL_BN_value_one");

    if (bn_one == NULL) {
        bn_one = wolfSSL_BN_new();
        if (bn_one) {
            if (mp_set_int((mp_int*)bn_one->internal, 1) != MP_OKAY) {
                /* handle error by freeing BN and returning NULL */
                wolfSSL_BN_free(bn_one);
                bn_one = NULL;
            }
        }
    }

    return bn_one;
}

/* return compliant with OpenSSL
 *   size of BIGNUM in bytes, 0 if error */
int wolfSSL_BN_num_bytes(const WOLFSSL_BIGNUM* bn)
{
    WOLFSSL_ENTER("wolfSSL_BN_num_bytes");

    if (bn == NULL || bn->internal == NULL)
        return WOLFSSL_FAILURE;

    return mp_unsigned_bin_size((mp_int*)bn->internal);
}

/* return compliant with OpenSSL
 *   size of BIGNUM in bits, 0 if error */
int wolfSSL_BN_num_bits(const WOLFSSL_BIGNUM* bn)
{
    WOLFSSL_ENTER("wolfSSL_BN_num_bits");

    if (bn == NULL || bn->internal == NULL)
        return WOLFSSL_FAILURE;

    return mp_count_bits((mp_int*)bn->internal);
}

int wolfSSL_BN_is_negative(const WOLFSSL_BIGNUM* bn)
{
    if (bn == NULL)
        return WOLFSSL_FAILURE;

    return mp_isneg((mp_int*)bn->internal);
}

void wolfSSL_BN_zero(WOLFSSL_BIGNUM* bn)
{
    if (bn == NULL || bn->internal == NULL) {
        return;
    }

    mp_zero((mp_int*)bn->internal);
}

int wolfSSL_BN_one(WOLFSSL_BIGNUM* bn)
{
    int ret = WOLFSSL_SUCCESS;

    if (bn == NULL || bn->internal == NULL) {
        return WOLFSSL_FAILURE;
    }

    if (ret == WOLFSSL_SUCCESS) {
        ret = wolfSSL_BN_set_word(bn, 1);
    }

    return ret;
}

/* return compliant with OpenSSL
 *   1 if BIGNUM is zero, 0 else */
int wolfSSL_BN_is_zero(const WOLFSSL_BIGNUM* bn)
{
    WOLFSSL_MSG("wolfSSL_BN_is_zero");

    if (bn == NULL || bn->internal == NULL)
        return WOLFSSL_FAILURE;

    if (mp_iszero((mp_int*)bn->internal) == MP_YES)
        return WOLFSSL_SUCCESS;

    return WOLFSSL_FAILURE;
}

/* return compliant with OpenSSL
 *   1 if BIGNUM is one, 0 else */
int wolfSSL_BN_is_one(const WOLFSSL_BIGNUM* bn)
{
    WOLFSSL_MSG("wolfSSL_BN_is_one");

    if (bn == NULL || bn->internal == NULL)
        return WOLFSSL_FAILURE;

    if (mp_cmp_d((mp_int*)bn->internal, 1) == MP_EQ)
        return WOLFSSL_SUCCESS;

    return WOLFSSL_FAILURE;
}

/* return compliant with OpenSSL
 *   1 if BIGNUM is odd, 0 else */
int wolfSSL_BN_is_odd(const WOLFSSL_BIGNUM* bn)
{
    WOLFSSL_MSG("wolfSSL_BN_is_odd");

    if (bn == NULL || bn->internal == NULL)
        return WOLFSSL_FAILURE;

    if (mp_isodd((mp_int*)bn->internal) == MP_YES)
        return WOLFSSL_SUCCESS;

    return WOLFSSL_FAILURE;
}

/* return compliant with OpenSSL
 *   1 if BIGNUM is word, 0 else */
int wolfSSL_BN_is_word(const WOLFSSL_BIGNUM* bn, WOLFSSL_BN_ULONG w)
{
    WOLFSSL_MSG("wolfSSL_BN_is_word");

    if (bn == NULL || bn->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        return WOLFSSL_FAILURE;
    }

    if (w <= (WOLFSSL_BN_ULONG)MP_MASK) {
        if (mp_isword((mp_int*)bn->internal, (mp_digit)w) == MP_YES) {
            return WOLFSSL_SUCCESS;
        }
    } else {
        int ret;
        mp_int w_mp;
        if (mp_init(&w_mp) != MP_OKAY)
            return WOLFSSL_FAILURE;
        if (mp_set_int(&w_mp, w) != MP_OKAY)
            return WOLFSSL_FAILURE;
        ret = mp_cmp((mp_int *)bn->internal, &w_mp);
        mp_free(&w_mp);
        if (ret == MP_EQ)
            return WOLFSSL_SUCCESS;
    }

    return WOLFSSL_FAILURE;
}

/* return compliant with OpenSSL
 *   -1 if a < b, 0 if a == b and 1 if a > b
 */
int wolfSSL_BN_cmp(const WOLFSSL_BIGNUM* a, const WOLFSSL_BIGNUM* b)
{
    int ret;

    WOLFSSL_MSG("wolfSSL_BN_cmp");

    if (a == NULL || a->internal == NULL || b == NULL || b->internal == NULL)
        return WOLFSSL_FATAL_ERROR;

    ret = mp_cmp((mp_int*)a->internal, (mp_int*)b->internal);

    return (ret == MP_EQ ? 0 : (ret == MP_GT ? 1 : -1));
}

/* return compliant with OpenSSL
 *   length of BIGNUM in bytes, -1 if error */
int wolfSSL_BN_bn2bin(const WOLFSSL_BIGNUM* bn, unsigned char* r)
{
    WOLFSSL_MSG("wolfSSL_BN_bn2bin");

    if (bn == NULL || bn->internal == NULL) {
        WOLFSSL_MSG("NULL bn error");
        return WOLFSSL_FATAL_ERROR;
    }

    if (r == NULL)
        return mp_unsigned_bin_size((mp_int*)bn->internal);

    if (mp_to_unsigned_bin((mp_int*)bn->internal, r) != MP_OKAY) {
        WOLFSSL_MSG("mp_to_unsigned_bin error");
        return WOLFSSL_FATAL_ERROR;
    }

    return mp_unsigned_bin_size((mp_int*)bn->internal);
}


WOLFSSL_BIGNUM* wolfSSL_BN_bin2bn(const unsigned char* str, int len,
                            WOLFSSL_BIGNUM* ret)
{
    int weOwn = 0;

    WOLFSSL_MSG("wolfSSL_BN_bin2bn");

    /* if ret is null create a BN */
    if (ret == NULL) {
        ret = wolfSSL_BN_new();
        weOwn = 1;
        if (ret == NULL)
            return NULL;
    }

    /* check ret and ret->internal then read in value */
    if (ret && ret->internal) {
        if (mp_read_unsigned_bin((mp_int*)ret->internal, str, len) != 0) {
            WOLFSSL_MSG("mp_read_unsigned_bin failure");
            if (weOwn)
                wolfSSL_BN_free(ret);
            return NULL;
        }
    } else {
        /* This may be overly defensive */
        if (weOwn)
            wolfSSL_BN_free(ret);
        return NULL;
    }

    return ret;
}

/* return compliant with OpenSSL
 *   1 if success, 0 if error */
#ifndef NO_WOLFSSL_STUB
int wolfSSL_mask_bits(WOLFSSL_BIGNUM* bn, int n)
{
    (void)bn;
    (void)n;
    WOLFSSL_ENTER("wolfSSL_BN_mask_bits");
    WOLFSSL_STUB("BN_mask_bits");
    return SSL_FAILURE;
}
#endif

/* WOLFSSL_SUCCESS on ok */
int wolfSSL_BN_rand(WOLFSSL_BIGNUM* bn, int bits, int top, int bottom)
{
    int ret = WOLFSSL_SUCCESS;
    int len = (bits + 7) / 8;
    WC_RNG* rng = &globalRNG;
    byte* buff = NULL;

    WOLFSSL_ENTER("wolfSSL_BN_rand");

    if ((bn == NULL || bn->internal == NULL) || bits < 0 ||
        (bits == 0 && (bottom != 0 || top != -1)) || (bits == 1 && top > 0)) {
        WOLFSSL_MSG("Bad argument");
        ret = WOLFSSL_FAILURE;
    }

    if (ret == WOLFSSL_SUCCESS) {
        if (len == 0) {
            mp_zero((mp_int*)bn->internal);
        }
        else {
            buff = (byte*)XMALLOC(len, NULL, DYNAMIC_TYPE_TMP_BUFFER);
            if (buff == NULL) {
                WOLFSSL_MSG("Failed to allocate buffer.");
                XFREE(buff, NULL, DYNAMIC_TYPE_TMP_BUFFER);
                ret = WOLFSSL_FAILURE;
            }

            if (ret == WOLFSSL_SUCCESS && initGlobalRNG == 0 &&
                wolfSSL_RAND_Init() != WOLFSSL_SUCCESS) {
                WOLFSSL_MSG("Failed to use global RNG.");
                ret = WOLFSSL_FAILURE;
            }

            if (ret == WOLFSSL_SUCCESS &&
                wc_RNG_GenerateBlock(rng, buff, len) != 0) {
                WOLFSSL_MSG("wc_RNG_GenerateBlock failed");
                ret = WOLFSSL_FAILURE;
            }
            if (ret == WOLFSSL_SUCCESS &&
                mp_read_unsigned_bin((mp_int*)bn->internal,buff,len)
                != MP_OKAY) {
                    WOLFSSL_MSG("mp_read_unsigned_bin failed");
                    ret = WOLFSSL_FAILURE;
            }
            if (ret == WOLFSSL_SUCCESS) {
                /* Truncate to requested bit length. */
                mp_rshb((mp_int*)bn->internal, 8 - (bits % 8));

                if (top == 0) {
                    if (mp_set_bit((mp_int*)bn->internal, bits - 1)
                        != MP_OKAY) {
                        WOLFSSL_MSG("Failed to set top bit");
                        ret = WOLFSSL_FAILURE;
                    }
                }
                else if (top > 0) {
                    if (mp_set_bit((mp_int*)bn->internal, bits - 1)
                        != MP_OKAY ||
                        mp_set_bit((mp_int*)bn->internal, bits - 2)
                        != MP_OKAY) {
                        WOLFSSL_MSG("Failed to set top 2 bits");
                        ret = WOLFSSL_FAILURE;
                    }
                }
            }
            if (ret == WOLFSSL_SUCCESS && bottom &&
                mp_set_bit((mp_int*)bn->internal, 0) != MP_OKAY) {
                WOLFSSL_MSG("Failed to set 0th bit");
                ret = WOLFSSL_FAILURE;
            }

            if (buff != NULL) {
                XFREE(buff, NULL, DYNAMIC_TYPE_TMP_BUFFER);
            }
        }
    }

    WOLFSSL_LEAVE("wolfSSL_BN_rand", ret);

    return ret;
}

/**
 * N = length of range input var
 * Generate N-bit length numbers until generated number is less than range
 * @param r     Output number
 * @param range The upper limit of generated output
 * @return WOLFSSL_SUCCESS on success and WOLFSSL_FAILURE on failure
 */
int wolfSSL_BN_rand_range(WOLFSSL_BIGNUM *r, const WOLFSSL_BIGNUM *range)
{
    int n;
    int iter = 0;
    WOLFSSL_MSG("wolfSSL_BN_rand_range");

    if (r == NULL || range == NULL) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }

    n = wolfSSL_BN_num_bits(range);

    if (n <= 1) {
        wolfSSL_BN_zero(r);
    }
    else {
        do {
            if (iter >= 100) {
                WOLFSSL_MSG("wolfSSL_BN_rand_range too many iterations");
                return WOLFSSL_FAILURE;
            }
            iter++;
            if (wolfSSL_BN_pseudo_rand(r, n, -1, 0) == WOLFSSL_FAILURE) {
                WOLFSSL_MSG("wolfSSL_BN_rand error");
                return WOLFSSL_FAILURE;
            }
        } while(wolfSSL_BN_cmp(r, range) >= 0);
    }
    return WOLFSSL_SUCCESS;
}

/* WOLFSSL_SUCCESS on ok
 * code is same as wolfSSL_BN_rand except for how top and bottom is handled.
 * top -1 then leave most sig bit alone
 * top 0 then most sig is set to 1
 * top is 1 then first two most sig bits are 1
 *
 * bottom is hot then odd number */
int wolfSSL_BN_pseudo_rand(WOLFSSL_BIGNUM* bn, int bits, int top, int bottom)
{
    int           ret    = 0;
    int           len;
    int           initTmpRng = 0;
    WC_RNG*       rng    = NULL;
#ifdef WOLFSSL_SMALL_STACK
    WC_RNG*       tmpRNG = NULL;
    byte*         buff   = NULL;
#else
    WC_RNG        tmpRNG[1];
    byte          buff[1024];
#endif

    WOLFSSL_ENTER("wolfSSL_BN_pseudo_rand");

    if (bits <= 0) {
        return WOLFSSL_FAILURE;
    }

    len = bits / 8;
    if (bits % 8)
        len++;

    /* has to be a length of at least 1 since we set buf[0] and buf[len-1] */
    if (top == 1 || top == 0 || bottom == 1) {
        if (len < 1) {
            return WOLFSSL_FAILURE;
        }
    }

#ifdef WOLFSSL_SMALL_STACK
    buff   = (byte*)XMALLOC(1024,        NULL, DYNAMIC_TYPE_TMP_BUFFER);
    tmpRNG = (WC_RNG*) XMALLOC(sizeof(WC_RNG), NULL, DYNAMIC_TYPE_TMP_BUFFER);
    if (buff == NULL || tmpRNG == NULL) {
        XFREE(buff,   NULL, DYNAMIC_TYPE_TMP_BUFFER);
        XFREE(tmpRNG, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        return ret;
    }
#endif

    if (bn == NULL || bn->internal == NULL)
        WOLFSSL_MSG("Bad function arguments");
    else if (wc_InitRng(tmpRNG) == 0) {
        rng = tmpRNG;
        initTmpRng = 1;
    }
    else if (initGlobalRNG)
        rng = &globalRNG;

    if (rng) {
        if (wc_RNG_GenerateBlock(rng, buff, len) != 0)
            WOLFSSL_MSG("Bad wc_RNG_GenerateBlock");
        else {
            switch (top) {
                case -1:
                    break;

                case 0:
                    buff[0] |= 0x80;
                    break;

                case 1:
                    buff[0] |= 0x80 | 0x40;
                    break;
            }

            if (bottom == 1) {
                buff[len-1] |= 0x01;
            }

            if (mp_read_unsigned_bin((mp_int*)bn->internal,buff,len) != MP_OKAY)
                WOLFSSL_MSG("mp read bin failed");
            else
                ret = WOLFSSL_SUCCESS;
        }
    }

    if (initTmpRng)
        wc_FreeRng(tmpRNG);

#ifdef WOLFSSL_SMALL_STACK
    XFREE(buff,   NULL, DYNAMIC_TYPE_TMP_BUFFER);
    XFREE(tmpRNG, NULL, DYNAMIC_TYPE_TMP_BUFFER);
#endif

    return ret;
}

/* return code compliant with OpenSSL :
 *   1 if bit set, 0 else
 */
int wolfSSL_BN_is_bit_set(const WOLFSSL_BIGNUM* bn, int n)
{
    if (bn == NULL || bn->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        return WOLFSSL_FAILURE;
    }

    return mp_is_bit_set((mp_int*)bn->internal, (mp_digit)n);
}

/* return code compliant with OpenSSL :
 *   1 if success, 0 else
 */
int wolfSSL_BN_set_bit(WOLFSSL_BIGNUM* bn, int n)
{
    if (bn == NULL || bn->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        return WOLFSSL_FAILURE;
    }

    if (mp_set_bit((mp_int*)bn->internal, n) != MP_OKAY) {
        WOLFSSL_MSG("mp_set_bit error");
        return WOLFSSL_FAILURE;
    }

    return WOLFSSL_SUCCESS;
}


int wolfSSL_BN_clear_bit(WOLFSSL_BIGNUM* bn, int n)
{
    int ret = WOLFSSL_FAILURE;
#ifndef WOLFSSL_SMALL_STACK
    mp_int tmp[1];
#else
    mp_int* tmp = NULL;
#endif

    if (bn == NULL || bn->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        goto end;
    }
    if (mp_is_bit_set((mp_int*)bn->internal, n)) {
#ifdef WOLFSSL_SMALL_STACK
       tmp = (mp_int*)XMALLOC(sizeof(mp_int), NULL, DYNAMIC_TYPE_BIGINT);
       if (tmp == NULL) {
           goto end;
       }
#endif
        if (mp_init(tmp) != MP_OKAY) {
            goto end;
        }
        if (mp_set_bit(tmp, n) != MP_OKAY) {
            goto cleanup;
        }
        if (mp_sub((mp_int*)bn->internal, tmp, (mp_int*)bn->internal) != MP_OKAY) {
            goto cleanup;
        }
    } else {
        goto end;
    }

    ret = WOLFSSL_SUCCESS;
cleanup:
    mp_clear(tmp);

end:
#ifdef WOLFSSL_SMALL_STACK
    if (tmp)
        XFREE(tmp, NULL, DYNAMIC_TYPE_BIGINT);
#endif
    return ret;
}


/* WOLFSSL_SUCCESS on ok */
/* Note on use: this function expects str to be an even length. It is
 * converting pairs of bytes into 8-bit values. As an example, the RSA
 * public exponent is commonly 0x010001. To get it to convert, you need
 * to pass in the string "010001", it will fail if you use "10001". This
 * is an affect of how Base16_Decode() works.
 */
int wolfSSL_BN_hex2bn(WOLFSSL_BIGNUM** bn, const char* str)
{
    int     ret     = 0;
    word32  decSz   = 1024;
#ifdef WOLFSSL_SMALL_STACK
    byte*   decoded;
#else
    byte    decoded[1024];
#endif
    int     weOwn = 0;
    int     strLen;

    WOLFSSL_MSG("wolfSSL_BN_hex2bn");

#ifdef WOLFSSL_SMALL_STACK
    decoded = (byte*)XMALLOC(decSz, NULL, DYNAMIC_TYPE_DER);
    if (decoded == NULL)
        return ret;
#endif

    if (str == NULL || str[0] == '\0') {
        WOLFSSL_MSG("Bad function argument");
        ret = WOLFSSL_FAILURE;
    } else {
        strLen = (int)XSTRLEN(str);
        /* ignore trailing new lines */
        while (str[strLen-1] == '\n' && strLen > 0) strLen--;

        if (Base16_Decode((byte*)str, strLen, decoded, &decSz) < 0)
            WOLFSSL_MSG("Bad Base16_Decode error");
        else if (bn == NULL)
            ret = decSz;
        else {
            if (*bn == NULL) {
                *bn = wolfSSL_BN_new();
                if (*bn != NULL) {
                    weOwn = 1;
                }
            }

            if (*bn == NULL)
                WOLFSSL_MSG("BN new failed");
            else if (wolfSSL_BN_bin2bn(decoded, decSz, *bn) == NULL) {
                WOLFSSL_MSG("Bad bin2bn error");
                if (weOwn == 1) {
                    wolfSSL_BN_free(*bn); /* Free new BN */
                }
            }
            else
                ret = WOLFSSL_SUCCESS;
        }
    }

#ifdef WOLFSSL_SMALL_STACK
    XFREE(decoded, NULL, DYNAMIC_TYPE_DER);
#endif

    return ret;
}


WOLFSSL_BIGNUM* wolfSSL_BN_dup(const WOLFSSL_BIGNUM* bn)
{
    WOLFSSL_BIGNUM* ret;

    WOLFSSL_MSG("wolfSSL_BN_dup");

    if (bn == NULL || bn->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        return NULL;
    }

    ret = wolfSSL_BN_new();
    if (ret == NULL) {
        WOLFSSL_MSG("bn new error");
        return NULL;
    }

    if (mp_copy((mp_int*)bn->internal, (mp_int*)ret->internal) != MP_OKAY) {
        WOLFSSL_MSG("mp_copy error");
        wolfSSL_BN_free(ret);
        return NULL;
    }

    ret->neg = bn->neg;

    return ret;
}


WOLFSSL_BIGNUM* wolfSSL_BN_copy(WOLFSSL_BIGNUM* r, const WOLFSSL_BIGNUM* bn)
{
    WOLFSSL_MSG("wolfSSL_BN_copy");

    if (r == NULL || bn == NULL) {
        WOLFSSL_MSG("r or bn NULL error");
        return NULL;
    }

    if (mp_copy((mp_int*)bn->internal, (mp_int*)r->internal) != MP_OKAY) {
        WOLFSSL_MSG("mp_copy error");
        return NULL;
    }

    r->neg = bn->neg;

    return r;
}

/* return code compliant with OpenSSL :
 *   1 if success, 0 else
 */
int wolfSSL_BN_set_word(WOLFSSL_BIGNUM* bn, unsigned long w)
{
    WOLFSSL_MSG("wolfSSL_BN_set_word");

    if (bn == NULL) {
        WOLFSSL_MSG("bn NULL error");
        return WOLFSSL_FAILURE;
    }

    if (mp_set_int((mp_int*)bn->internal, w) != MP_OKAY) {
        WOLFSSL_MSG("mp_init_set_int error");
        return WOLFSSL_FAILURE;
    }

    return WOLFSSL_SUCCESS;
}

static WOLFSSL_BN_ULONG wolfSSL_BN_get_word_1(mp_int *mp) {
#if DIGIT_BIT >= (SIZEOF_LONG * CHAR_BIT)
    return (WOLFSSL_BN_ULONG)mp->dp[0];
#else
    WOLFSSL_BN_ULONG ret = 0UL;
    int digit_i;

    for (digit_i = 0; digit_i < mp->used; ++digit_i)
        ret |= ((WOLFSSL_BN_ULONG)mp->dp[digit_i]) << (DIGIT_BIT * digit_i);

    return ret;
#endif
}

/* Returns the big number as an unsigned long if possible.
 *
 * bn  big number structure to get value from
 *
 * Returns value or 0xFFFFFFFFL if bigger than unsigned long.
 */
WOLFSSL_BN_ULONG wolfSSL_BN_get_word(const WOLFSSL_BIGNUM* bn)
{
    WOLFSSL_MSG("wolfSSL_BN_get_word");

    if (bn == NULL) {
        WOLFSSL_MSG("Invalid argument");
        return 0;
    }

    if (wolfSSL_BN_num_bytes(bn) > (int)sizeof(unsigned long)) {
        WOLFSSL_MSG("bignum is larger than unsigned long");
        return 0xFFFFFFFFL;
    }

    return wolfSSL_BN_get_word_1((mp_int*)bn->internal);
}

/* return code compliant with OpenSSL :
 *   number length in decimal if success, 0 if error
 */
#ifndef NO_WOLFSSL_STUB
int wolfSSL_BN_dec2bn(WOLFSSL_BIGNUM** bn, const char* str)
{
    (void)bn;
    (void)str;

    WOLFSSL_MSG("wolfSSL_BN_dec2bn");
    WOLFSSL_STUB("BN_dec2bn");
    return SSL_FAILURE;
}
#endif

#if defined(WOLFSSL_KEY_GEN) || defined(HAVE_COMP_KEY)
char *wolfSSL_BN_bn2dec(const WOLFSSL_BIGNUM *bn)
{
    int len = 0;
    char *buf;

    WOLFSSL_MSG("wolfSSL_BN_bn2dec");

    if (bn == NULL || bn->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        return NULL;
    }

    if (mp_radix_size((mp_int*)bn->internal, MP_RADIX_DEC, &len) != MP_OKAY) {
        WOLFSSL_MSG("mp_radix_size failure");
        return NULL;
    }

    buf = (char*) XMALLOC(len, NULL, DYNAMIC_TYPE_OPENSSL);
    if (buf == NULL) {
        WOLFSSL_MSG("BN_bn2dec malloc buffer failure");
        return NULL;
    }

    if (mp_todecimal((mp_int*)bn->internal, buf) != MP_OKAY) {
        XFREE(buf, NULL, DYNAMIC_TYPE_OPENSSL);
        return NULL;
    }

    return buf;
}
#else
char* wolfSSL_BN_bn2dec(const WOLFSSL_BIGNUM* bn)
{
    (void)bn;

    WOLFSSL_MSG("wolfSSL_BN_bn2dec");

    return NULL;
}
#endif /* defined(WOLFSSL_KEY_GEN) || defined(HAVE_COMP_KEY) */

/* Internal function for adding/subtracting an unsigned long from a
 * WOLFSSL_BIGNUM. To add, pass "sub" as 0. To subtract, pass it as 1.
 * Returns 1 (WOLFSSL_SUCCESS) on success and 0 (WOLFSSL_FAILURE) on failure.
 */
static int wolfSSL_BN_add_word_int(WOLFSSL_BIGNUM *bn, WOLFSSL_BN_ULONG w,
                                   int sub)
{
    int ret = WOLFSSL_SUCCESS;
    int rc = 0;
#ifdef WOLFSSL_SMALL_STACK
    mp_int *w_mp = (mp_int *)XMALLOC(sizeof(*w_mp), NULL,
                                     DYNAMIC_TYPE_TMP_BUFFER);
    if (w_mp == NULL)
        return WOLFSSL_FAILURE;
#else
    mp_int w_mp[1];
#endif

    XMEMSET(w_mp, 0, sizeof(*w_mp));

    if (bn == NULL || bn->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        ret = WOLFSSL_FAILURE;
    }

    if (ret == WOLFSSL_SUCCESS) {
        if (w <= (WOLFSSL_BN_ULONG)MP_MASK) {
            if (sub == 1) {
                rc = mp_sub_d((mp_int*)bn->internal, (mp_digit)w,
                              (mp_int*)bn->internal);
            }
            else {
                rc = mp_add_d((mp_int*)bn->internal, (mp_digit)w,
                              (mp_int*)bn->internal);
            }
            if (rc != MP_OKAY) {
                WOLFSSL_MSG("mp_add/sub_d error");
                ret = WOLFSSL_FAILURE;
            }
        }
        else {
            if (mp_init(w_mp) != MP_OKAY) {
                ret = WOLFSSL_FAILURE;
            }
            if (ret == WOLFSSL_SUCCESS) {
                if (mp_set_int(w_mp, w) != MP_OKAY) {
                    ret = WOLFSSL_FAILURE;
                }
            }
            if (ret == WOLFSSL_SUCCESS) {
                if (sub == 1) {
                    rc = mp_sub((mp_int *)bn->internal, w_mp,
                                (mp_int *)bn->internal);
                }
                else {
                    rc = mp_add((mp_int *)bn->internal, w_mp,
                                (mp_int *)bn->internal);
                }
                if (rc != MP_OKAY) {
                    WOLFSSL_MSG("mp_add/sub error");
                    ret = WOLFSSL_FAILURE;
                }
            }
        }
    }

    mp_free(w_mp);

#ifdef WOLFSSL_SMALL_STACK
    XFREE(w_mp, NULL, DYNAMIC_TYPE_TMP_BUFFER);
#endif

    return ret;
}

/* return code compliant with OpenSSL :
 *   1 if success, 0 else
 */
int wolfSSL_BN_add_word(WOLFSSL_BIGNUM *bn, WOLFSSL_BN_ULONG w)
{
    int ret;

    WOLFSSL_ENTER("wolfSSL_BN_add_word");

    ret = wolfSSL_BN_add_word_int(bn, w, 0);

    WOLFSSL_LEAVE("wolfSSL_BN_add_word", ret);

    return ret;
}

/* return code compliant with OpenSSL :
 *   1 if success, 0 else
 */
int wolfSSL_BN_sub_word(WOLFSSL_BIGNUM* bn, WOLFSSL_BN_ULONG w)
{
    int ret;

    WOLFSSL_ENTER("wolfSSL_BN_sub_word");

    ret = wolfSSL_BN_add_word_int(bn, w, 1);

    WOLFSSL_LEAVE("wolfSSL_BN_sub_word", ret);

    return ret;
}

#ifndef WOLFSSL_SP_MATH
/* return code compliant with OpenSSL :
 *   1 if success, 0 else
 */
int wolfSSL_BN_lshift(WOLFSSL_BIGNUM *r, const WOLFSSL_BIGNUM *bn, int n)
{
    WOLFSSL_MSG("wolfSSL_BN_lshift");

    if (r == NULL || r->internal == NULL || bn == NULL || bn->internal == NULL){
        WOLFSSL_MSG("bn NULL error");
        return WOLFSSL_FAILURE;
    }

    if (mp_mul_2d((mp_int*)bn->internal, n, (mp_int*)r->internal) != MP_OKAY) {
        WOLFSSL_MSG("mp_mul_2d error");
        return WOLFSSL_FAILURE;
    }

    return WOLFSSL_SUCCESS;
}

/* return code compliant with OpenSSL :
 *   1 if success, 0 else
 */
int wolfSSL_BN_rshift(WOLFSSL_BIGNUM *r, const WOLFSSL_BIGNUM *bn, int n)
{
    WOLFSSL_MSG("wolfSSL_BN_rshift");

    if (r == NULL || r->internal == NULL || bn == NULL || bn->internal == NULL){
        WOLFSSL_MSG("bn NULL error");
        return WOLFSSL_FAILURE;
    }

    if (mp_div_2d((mp_int*)bn->internal, n,
                  (mp_int*)r->internal, NULL) != MP_OKAY) {
        WOLFSSL_MSG("mp_mul_2d error");
        return WOLFSSL_FAILURE;
    }

    return WOLFSSL_SUCCESS;
}
#endif

/* return code compliant with OpenSSL :
 *   1 if success, 0 else
 */
int wolfSSL_BN_add(WOLFSSL_BIGNUM *r, WOLFSSL_BIGNUM *a, WOLFSSL_BIGNUM *b)
{
    WOLFSSL_MSG("wolfSSL_BN_add");

    if (r == NULL || r->internal == NULL || a == NULL || a->internal == NULL ||
        b == NULL || b->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        return WOLFSSL_FAILURE;
    }

    if (mp_add((mp_int*)a->internal, (mp_int*)b->internal,
               (mp_int*)r->internal) != MP_OKAY) {
        WOLFSSL_MSG("mp_add_d error");
        return WOLFSSL_FAILURE;
    }

    return WOLFSSL_SUCCESS;
}

#ifndef WOLFSSL_SP_MATH
/* r = a + b (mod m) */
int wolfSSL_BN_mod_add(WOLFSSL_BIGNUM *r, const WOLFSSL_BIGNUM *a,
                       const WOLFSSL_BIGNUM *b, const WOLFSSL_BIGNUM *m,
                       WOLFSSL_BN_CTX *ctx)
{
    (void)ctx;
    WOLFSSL_MSG("wolfSSL_BN_add");

    if (r == NULL || r->internal == NULL ||
            a == NULL || a->internal == NULL ||
            b == NULL || b->internal == NULL ||
            m == NULL || m->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        return WOLFSSL_FAILURE;
    }

    if (mp_addmod((mp_int*)a->internal, (mp_int*)b->internal,
                  (mp_int*)m->internal, (mp_int*)r->internal) != MP_OKAY) {
        WOLFSSL_MSG("mp_add_d error");
        return WOLFSSL_FAILURE;
    }

    return WOLFSSL_SUCCESS;
}
#endif

#if defined(WOLFSSL_KEY_GEN) && (!defined(NO_RSA) || !defined(NO_DH) || !defined(NO_DSA))

int wolfSSL_BN_generate_prime_ex(WOLFSSL_BIGNUM* prime, int bits,
    int safe, const WOLFSSL_BIGNUM* add, const WOLFSSL_BIGNUM* rem,
    WOLFSSL_BN_GENCB* cb)
{
    int ret = WOLFSSL_SUCCESS;
#ifdef WOLFSSL_SMALL_STACK
    WC_RNG* rng = NULL;
#else
    WC_RNG rng[1];
#endif

    (void)cb;

    WOLFSSL_ENTER("wolfSSL_BN_generate_prime_ex");

    if (safe == 1 || add != NULL || rem != NULL) {
        /* These parameters aren't supported, yet. */
        ret = WOLFSSL_FAILURE;
    }

    if (prime == NULL || prime->internal == NULL) {
        ret = WOLFSSL_FAILURE;
    }

#ifdef WOLFSSL_SMALL_STACK
    if (ret == WOLFSSL_SUCCESS) {
        rng = (WC_RNG*)XMALLOC(sizeof(WC_RNG), NULL, DYNAMIC_TYPE_RNG);
        if (rng == NULL) {
            ret = WOLFSSL_FAILURE;
        }
    }
#endif
    if (ret == WOLFSSL_SUCCESS) {
        XMEMSET(rng, 0, sizeof(WC_RNG));
        if (wc_InitRng(rng) != 0) {
            ret = WOLFSSL_FAILURE;
        }
    }

    if (ret == WOLFSSL_SUCCESS) {
        if (mp_rand_prime((mp_int*)prime->internal, (bits + 7) / 8, rng, NULL)
                != MP_OKAY) {
            ret = WOLFSSL_FAILURE;
        }
    }

    wc_FreeRng(rng);
#ifdef WOLFSSL_SMALL_STACK
    if (rng != NULL)
        XFREE(rng, NULL, DYNAMIC_TYPE_RNG);
#endif

    WOLFSSL_LEAVE("wolfSSL_BN_generate_prime_ex", ret);

    return ret;
}

/* return code compliant with OpenSSL :
 *   1 if prime, 0 if not, -1 if error
 */
int wolfSSL_BN_is_prime_ex(const WOLFSSL_BIGNUM *bn, int nbchecks,
                           WOLFSSL_BN_CTX *ctx, WOLFSSL_BN_GENCB *cb)
{
    WC_RNG*        rng    = NULL;
#ifdef WOLFSSL_SMALL_STACK
    WC_RNG*        tmpRNG = NULL;
#else
    WC_RNG         tmpRNG[1];
#endif
    int            initTmpRng = 0;
    int            res = MP_NO;

    (void)ctx;
    (void)cb;

    WOLFSSL_MSG("wolfSSL_BN_is_prime_ex");

    if (bn == NULL || bn->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        return WOLFSSL_FATAL_ERROR;
    }

#ifdef WOLFSSL_SMALL_STACK
    tmpRNG = (WC_RNG*)XMALLOC(sizeof(WC_RNG), NULL, DYNAMIC_TYPE_RNG);
    if (tmpRNG == NULL)
        return WOLFSSL_FAILURE;
#endif
    if (wc_InitRng(tmpRNG) == 0) {
        rng = tmpRNG;
        initTmpRng = 1;
    }
    else {
        WOLFSSL_MSG("Bad RNG Init, trying global");
        if (initGlobalRNG == 0) {
            WOLFSSL_MSG("Global RNG no Init");
        }
        else
            rng = &globalRNG;
    }

    if (rng) {
        if (mp_prime_is_prime_ex((mp_int*)bn->internal,
                                 nbchecks, &res, rng) != MP_OKAY) {
            WOLFSSL_MSG("mp_prime_is_prime_ex error");
            res = MP_NO;
        }
    }

    if (initTmpRng)
        wc_FreeRng(tmpRNG);
#ifdef WOLFSSL_SMALL_STACK
    XFREE(tmpRNG, NULL, DYNAMIC_TYPE_RNG);
#endif

    if (res != MP_YES) {
        WOLFSSL_MSG("mp_prime_is_prime_ex not prime");
        return WOLFSSL_FAILURE;
    }

    return WOLFSSL_SUCCESS;
}

/* return code compliant with OpenSSL :
 *   (bn mod w) if success, -1 if error
 */
WOLFSSL_BN_ULONG wolfSSL_BN_mod_word(const WOLFSSL_BIGNUM *bn,
                                     WOLFSSL_BN_ULONG w)
{
    WOLFSSL_BN_ULONG ret = 0;

    WOLFSSL_MSG("wolfSSL_BN_mod_word");

    if (bn == NULL || bn->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        return (WOLFSSL_BN_ULONG)WOLFSSL_FATAL_ERROR;
    }

    if (w <= (WOLFSSL_BN_ULONG)MP_MASK) {
        mp_digit bn_ret;
        if (mp_mod_d((mp_int*)bn->internal, (mp_digit)w, &bn_ret) != MP_OKAY) {
            WOLFSSL_MSG("mp_add_d error");
            return (WOLFSSL_BN_ULONG)WOLFSSL_FATAL_ERROR;
        }
        ret = (WOLFSSL_BN_ULONG)bn_ret;
    } else {
        int mp_ret;
        mp_int w_mp, r_mp;
        if (mp_init(&w_mp) != MP_OKAY)
            return (unsigned long)WOLFSSL_FAILURE;
        if (mp_init(&r_mp) != MP_OKAY)
            return (unsigned long)WOLFSSL_FAILURE;
        if (mp_set_int(&w_mp, w) != MP_OKAY)
            return (unsigned long)WOLFSSL_FAILURE;
        mp_ret = mp_mod((mp_int *)bn->internal, &w_mp, &r_mp);
        ret = wolfSSL_BN_get_word_1(&r_mp);
        mp_free(&r_mp);
        mp_free(&w_mp);
        if (mp_ret != MP_OKAY) {
            WOLFSSL_MSG("mp_mod error");
            return (WOLFSSL_BN_ULONG)WOLFSSL_FAILURE;
        }
    }

    return ret;
}
#endif /* WOLFSSL_KEY_GEN && (!NO_RSA || !NO_DH || !NO_DSA) */

char *wolfSSL_BN_bn2hex(const WOLFSSL_BIGNUM *bn)
{
    int len = 0;
    char *buf;

    WOLFSSL_ENTER("wolfSSL_BN_bn2hex");

    if (bn == NULL || bn->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        return NULL;
    }

    if (mp_radix_size((mp_int*)bn->internal, MP_RADIX_HEX, &len) != MP_OKAY) {
        WOLFSSL_MSG("mp_radix_size failure");
        return NULL;
    }

    buf = (char*)XMALLOC(len, NULL, DYNAMIC_TYPE_OPENSSL);
    if (buf == NULL) {
        WOLFSSL_MSG("BN_bn2hex malloc buffer failure");
        return NULL;
    }

    if (mp_tohex((mp_int*)bn->internal, buf) != MP_OKAY) {
        XFREE(buf, NULL, DYNAMIC_TYPE_OPENSSL);
        return NULL;
    }

    return buf;
}

#if !defined(NO_FILESYSTEM) && defined(XFPRINTF)
/* return code compliant with OpenSSL :
 *   1 if success, 0 if error
 */
int wolfSSL_BN_print_fp(XFILE fp, const WOLFSSL_BIGNUM *bn)
{
    char *buf;
    int ret;

    WOLFSSL_ENTER("wolfSSL_BN_print_fp");

    if (fp == XBADFILE || bn == NULL || bn->internal == NULL) {
        WOLFSSL_MSG("bn NULL error");
        return WOLFSSL_FAILURE;
    }

    buf = wolfSSL_BN_bn2hex(bn);
    if (buf == NULL) {
        WOLFSSL_MSG("wolfSSL_BN_bn2hex failure");
        return WOLFSSL_FAILURE;
    }

    if (XFPRINTF(fp, "%s", buf) < 0)
        ret = WOLFSSL_FAILURE;
    else
        ret = WOLFSSL_SUCCESS;

    XFREE(buf, NULL, DYNAMIC_TYPE_OPENSSL);

    return ret;
}
#endif /* !NO_FILESYSTEM && XFPRINTF */


WOLFSSL_BIGNUM *wolfSSL_BN_CTX_get(WOLFSSL_BN_CTX *ctx)
{
    /* ctx is not used, return new Bignum */
    (void)ctx;

    WOLFSSL_ENTER("wolfSSL_BN_CTX_get");

    return wolfSSL_BN_new();
}

#ifndef NO_WOLFSSL_STUB
void wolfSSL_BN_CTX_start(WOLFSSL_BN_CTX *ctx)
{
    (void)ctx;

    WOLFSSL_ENTER("wolfSSL_BN_CTX_start");
    WOLFSSL_STUB("BN_CTX_start");
    WOLFSSL_MSG("wolfSSL_BN_CTX_start TBD");
}
#endif


WOLFSSL_BIGNUM *wolfSSL_BN_mod_inverse(WOLFSSL_BIGNUM *r,
                                       WOLFSSL_BIGNUM *a,
                                       const WOLFSSL_BIGNUM *n,
                                       WOLFSSL_BN_CTX *ctx)
{
    int dynamic = 0;

    /* ctx is not used */
    (void)ctx;

    WOLFSSL_ENTER("wolfSSL_BN_mod_inverse");

    /* check parameter */
    if (r == NULL) {
        r = wolfSSL_BN_new();
        if (r == NULL){
            WOLFSSL_MSG("WolfSSL_BN_new() failed");
            return NULL;
        }
        dynamic = 1;
    }

    if (a == NULL) {
        WOLFSSL_MSG("a NULL error");
        if (dynamic == 1) {
            wolfSSL_BN_free(r);
        }
        return NULL;
    }

    if (n == NULL) {
        WOLFSSL_MSG("n NULL error");
        if (dynamic == 1) {
            wolfSSL_BN_free(r);
        }
        return NULL;
    }

    /* Compute inverse of a modulo n and return r */
    if (mp_invmod((mp_int *)a->internal,(mp_int *)n->internal,
                  (mp_int*)r->internal) == MP_VAL){
        WOLFSSL_MSG("mp_invmod() error");
        if (dynamic == 1) {
            wolfSSL_BN_free(r);
        }
        return NULL;
    }

    return  r;
}
#endif  /* OPENSSL_EXTRA */
#if (defined(WOLFSSL_QT) || defined(OPENSSL_ALL) || defined(OPENSSL_EXTRA)) && \
    !defined(NO_ASN)
#ifndef NO_BIO
static int unprintable_char(char c)
{
    const unsigned char last_unprintable = 31;
    const unsigned char LF = 10;
    const unsigned char CR = 13;

    if (c <= last_unprintable && c != LF && c != CR) {
        return 1;
    }
    return 0;
}

int wolfSSL_ASN1_STRING_print(WOLFSSL_BIO *out, WOLFSSL_ASN1_STRING *str)
{
    int i;

    WOLFSSL_ENTER("wolfSSL_ASN1_STRING_print");
    if (out == NULL || str == NULL)
           return WOLFSSL_FAILURE;

    for (i=0; i < str->length; i++) {
        if (unprintable_char(str->data[i])) {
            str->data[i] = '.';
        }
    }

    if (wolfSSL_BIO_write(out, str->data, str->length) != str->length){
        return WOLFSSL_FAILURE;
    }

    return str->length;
}
#endif /* !NO_BIO */
#endif /* (WOLFSSL_QT || OPENSSL_ALL || OPENSSL_EXTRA) && !NO_ASN */

#if defined(OPENSSL_EXTRA)

const char *wolfSSL_ASN1_tag2str(int tag)
{
    static const char *const tag_label[31] = {
        "EOC", "BOOLEAN", "INTEGER", "BIT STRING", "OCTET STRING", "NULL",
        "OBJECT", "OBJECT DESCRIPTOR", "EXTERNAL", "REAL", "ENUMERATED",
        "<ASN1 11>", "UTF8STRING", "<ASN1 13>", "<ASN1 14>", "<ASN1 15>",
        "SEQUENCE", "SET", "NUMERICSTRING", "PRINTABLESTRING", "T61STRING",
        "VIDEOTEXTSTRING", "IA5STRING", "UTCTIME", "GENERALIZEDTIME",
        "GRAPHICSTRING", "VISIBLESTRING", "GENERALSTRING", "UNIVERSALSTRING",
        "<ASN1 29>", "BMPSTRING"
    };

    if ((tag == V_ASN1_NEG_INTEGER) || (tag == V_ASN1_NEG_ENUMERATED))
        tag &= ~0x100;
    if (tag < 0 || tag > 30)
        return "(unknown)";
    return tag_label[tag];
}

#ifndef NO_BIO
static int check_esc_char(char c, char *esc)
{
    char *ptr;

    ptr = esc;
    while(*ptr != 0){
        if (c == *ptr)
            return 1;
        ptr++;
    }
    return 0;
}

int wolfSSL_ASN1_STRING_print_ex(WOLFSSL_BIO *out, WOLFSSL_ASN1_STRING *str,
                                 unsigned long flags)
{
    size_t str_len = 0, type_len = 0;
    unsigned char *typebuf = NULL;
    const char *hash="#";

    WOLFSSL_ENTER("wolfSSL_ASN1_STRING_PRINT_ex");
    if (out == NULL || str == NULL)
        return WOLFSSL_FAILURE;

    /* add ASN1 type tag */
    if (flags & ASN1_STRFLGS_SHOW_TYPE){
        const char *tag = wolfSSL_ASN1_tag2str(str->type);
        /* colon len + tag len + null*/
        type_len = XSTRLEN(tag) + 2;
        typebuf = (unsigned char *)XMALLOC(type_len , NULL, DYNAMIC_TYPE_TMP_BUFFER);
        if (typebuf == NULL){
            WOLFSSL_MSG("memory alloc failed.");
            return WOLFSSL_FAILURE;
        }
        XMEMSET(typebuf, 0, type_len);
        if (XSNPRINTF((char*)typebuf, (size_t)type_len , "%s:", tag)
            >= (int)type_len)
        {
            WOLFSSL_MSG("Buffer overrun.");
            return WOLFSSL_FAILURE;
        }
        type_len--;
    }

    /* dump hex */
    if (flags & ASN1_STRFLGS_DUMP_ALL){
        char hex_tmp[4];
        char *str_ptr, *str_end;

        if (type_len > 0){
            if (wolfSSL_BIO_write(out, typebuf, (int)type_len) != (int)type_len){
                XFREE(typebuf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
                return WOLFSSL_FAILURE;
            }
            str_len += type_len;
        }
        if (wolfSSL_BIO_write(out, hash, 1) != 1){
            goto err_exit;
        }
        str_len++;
        if (flags & ASN1_STRFLGS_DUMP_DER){
            ByteToHexStr((byte)str->type, &hex_tmp[0]);
            ByteToHexStr((byte)str->length, &hex_tmp[2]);
            if (wolfSSL_BIO_write(out, hex_tmp, 4) != 4){
                goto err_exit;
            }
            str_len += 4;
            XMEMSET(hex_tmp, 0, 4);
        }

        str_ptr = str->data;
        str_end = str->data + str->length;
        while (str_ptr < str_end){
            ByteToHexStr((byte)*str_ptr, &hex_tmp[0]);
            if (wolfSSL_BIO_write(out, hex_tmp, 2) != 2){
                goto err_exit;
            }
            str_ptr++;
            str_len += 2;
        }
        if (type_len > 0)
            XFREE(typebuf, NULL, DYNAMIC_TYPE_TMP_BUFFER);

        return (int)str_len;
    }

    if (type_len > 0){
        if (wolfSSL_BIO_write(out, typebuf, (int)type_len) != (int)type_len){
            XFREE(typebuf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
            return WOLFSSL_FAILURE;
        }
        str_len += type_len;
    }

    if (flags & ASN1_STRFLGS_ESC_2253){
        char esc_ch[] = "+;<>\\";
        char* esc_ptr;

        esc_ptr = str->data;
        while (*esc_ptr != 0){
            if (check_esc_char(*esc_ptr, esc_ch)){
                if (wolfSSL_BIO_write(out,"\\", 1) != 1)
                    goto err_exit;
                str_len++;
            }
            if (wolfSSL_BIO_write(out, esc_ptr, 1) != 1)
                goto err_exit;
            str_len++;
            esc_ptr++;
        }
        if (type_len > 0)
            XFREE(typebuf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        return (int)str_len;
    }

    if (wolfSSL_BIO_write(out, str->data, str->length) != str->length){
        goto err_exit;
    }
    str_len += str->length;
    if (type_len > 0)
        XFREE(typebuf, NULL, DYNAMIC_TYPE_TMP_BUFFER);

    return (int)str_len;

err_exit:
    if (type_len > 0)
        XFREE(typebuf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    return WOLFSSL_FAILURE;
}
#endif /* !NO_BIO */

#if !defined(NO_ASN_TIME) && !defined(USER_TIME) && !defined(TIME_OVERRIDES)


WOLFSSL_ASN1_TIME* wolfSSL_ASN1_TIME_adj(WOLFSSL_ASN1_TIME *s, time_t t,
                                    int offset_day, long offset_sec)
{
    const time_t sec_per_day = 24*60*60;
    time_t t_adj = 0;
    time_t offset_day_sec = 0;
    char time_str[MAX_TIME_STRING_SZ];
    int time_get;

    WOLFSSL_ENTER("wolfSSL_ASN1_TIME_adj");

    if (s == NULL) {
        s = wolfSSL_ASN1_TIME_new();
        if (s == NULL) {
            return NULL;
        }
    }

    /* compute GMT time with offset */
    offset_day_sec = offset_day * sec_per_day;
    t_adj          = t + offset_day_sec + offset_sec;

    /* Get time string as either UTC or GeneralizedTime */
    time_get = GetFormattedTime(&t_adj, (byte*)time_str,
        (word32)sizeof(time_str));
    if (time_get <= 0) {
        wolfSSL_ASN1_TIME_free(s);
        return NULL;
    }

    if (wolfSSL_ASN1_TIME_set_string(s, time_str) != WOLFSSL_SUCCESS) {
        wolfSSL_ASN1_TIME_free(s);
        return NULL;
    }

    return s;
}
#endif /* !NO_ASN_TIME && !USER_TIME && !TIME_OVERRIDES */

#ifndef NO_ASN_TIME

WOLFSSL_ASN1_TIME* wolfSSL_ASN1_TIME_new(void)
{
    WOLFSSL_ASN1_TIME* ret = (WOLFSSL_ASN1_TIME*)
            XMALLOC(sizeof(WOLFSSL_ASN1_TIME), NULL, DYNAMIC_TYPE_OPENSSL);
    if (!ret)
        return NULL;
    XMEMSET(ret, 0, sizeof(WOLFSSL_ASN1_TIME));
    return ret;
}

void wolfSSL_ASN1_TIME_free(WOLFSSL_ASN1_TIME* t)
{
    if (t) {
        XFREE(t, NULL, DYNAMIC_TYPE_OPENSSL);
    }
}
/* not a compatibility function - length getter for opaque type */
int wolfSSL_ASN1_TIME_get_length(WOLFSSL_ASN1_TIME *t)
{
    WOLFSSL_ENTER("wolfSSL_ASN1_TIME_get_length");
    if (t == NULL)
        return WOLFSSL_FAILURE;
    return t->length;
}
/* not a compatibility function - data getter for opaque type */
unsigned char* wolfSSL_ASN1_TIME_get_data(WOLFSSL_ASN1_TIME *t)
{
    WOLFSSL_ENTER("wolfSSL_ASN1_TIME_get_data");
    if (t == NULL)
        return NULL;
    return t->data;
}

WOLFSSL_ASN1_TIME* wolfSSL_ASN1_TIME_to_generalizedtime(WOLFSSL_ASN1_TIME *t,
                                                        WOLFSSL_ASN1_TIME **out)
{
    int time_type = 0;
    WOLFSSL_ASN1_TIME *ret = NULL;

    WOLFSSL_ENTER("wolfSSL_ASN1_TIME_to_generalizedtime");
    if (t == NULL) {
        WOLFSSL_MSG("Invalid ASN_TIME value");
    } else {
        time_type = t->type;
        if (time_type != ASN_UTC_TIME && time_type != ASN_GENERALIZED_TIME){
            WOLFSSL_MSG("Invalid ASN_TIME type.");
        } else {
            if (out == NULL || *out == NULL) {
                ret = wolfSSL_ASN1_TIME_new();
                if (ret == NULL){
                    WOLFSSL_MSG("memory alloc failed.");
                }
            } else {
                ret = *out;
            }
        }
    }

    if (ret != NULL) {
        if (time_type == ASN_GENERALIZED_TIME){
            XMEMCPY(ret->data, t->data, ASN_GENERALIZED_TIME_SIZE);
        } else { /* ASN_UTC_TIME */
            /* convert UTC to generalized time */
            ret->type = ASN_GENERALIZED_TIME;
            ret->length = ASN_GENERALIZED_TIME_SIZE;
            if (t->data[0] >= '5') {
                ret->data[0] = '1'; ret->data[1] = '9';
            } else {
                ret->data[0] = '2'; ret->data[1] = '0';
            }
            XMEMCPY(&ret->data[2], t->data, ASN_UTC_TIME_SIZE);
        }
    }

    return ret;
}
#endif /* !NO_ASN_TIME */

#ifndef NO_ASN
int wolfSSL_i2c_ASN1_INTEGER(WOLFSSL_ASN1_INTEGER *a, unsigned char **pp)
{
    unsigned char *pptr = NULL;
    char pad = 0 ;
    unsigned char pad_val = 0;
    int ret_size = 0;
    unsigned char data1 = 0;
    unsigned char neg = 0;
    int i = 0;

    WOLFSSL_ENTER("wolfSSL_i2c_ASN1_INTEGER");
    if (a == NULL)
        return WOLFSSL_FAILURE;

    ret_size = a->intData[1];
    if (ret_size == 0)
        ret_size = 1;
    else{
        ret_size = (int)a->intData[1];
        neg = a->negative;
        data1 = a->intData[2];
        if (ret_size == 1 && data1 == 0)
            neg = 0;
        /* 0x80 or greater positive number in first byte */
        if (!neg && (data1 > 127)){
            pad = 1;
            pad_val = 0;
        } else if (neg){
            /* negative number */
            if (data1 > 128){
                pad = 1;
                pad_val = 0xff;
            } else if (data1 == 128){
                for (i = 3; i < a->intData[1] + 2; i++){
                    if (a->intData[i]){
                        pad = 1;
                        pad_val = 0xff;
                        break;
                    }
                }
            }
        }
        ret_size += (int)pad;
    }
    if (pp == NULL)
        return ret_size;

    pptr = *pp;
    if (pad)
        *(pptr++) = pad_val;
    if (a->intData[1] == 0)
        *(pptr++) = 0;
    else if (!neg){
        /* positive number */
        for (i=0; i < a->intData[1]; i++){
            *pptr = a->intData[i+2];
            pptr++;
        }
    } else {
        /* negative number */
        int str_len = 0;

        /* 0 padding from end of buffer */
        str_len = (int)a->intData[1];
        pptr += a->intData[1] - 1;
        while (!a->intData[str_len + 2] && str_len > 1){
            *(pptr--) = 0;
            str_len--;
        }
        /* 2's complement next octet */
        *(pptr--) = ((a->intData[str_len + 1]) ^ 0xff) + 1;
        str_len--;
        /* Complement any octets left */
        while (str_len > 0){
            *(pptr--) = a->intData[str_len + 1] ^ 0xff;
            str_len--;
        }
    }
    *pp += ret_size;
    return ret_size;
}
#endif /* !NO_ASN */
#endif /* OPENSSL_EXTRA */

#if defined(OPENSSL_EXTRA) || defined(OPENSSL_EXTRA_X509_SMALL)
/* when calling SetIndividualExternal, mpi should be cleared by caller if no
 * longer used. ie mp_free(mpi). This is to free data when fastmath is
 * disabled since a copy of mpi is made by this function and placed into bn.
 */
int SetIndividualExternal(WOLFSSL_BIGNUM** bn, mp_int* mpi)
{
    byte dynamic = 0;

#ifdef WOLFSSL_DEBUG_OPENSSL
    WOLFSSL_MSG("Entering SetIndividualExternal");
#endif

    if (mpi == NULL || bn == NULL) {
        WOLFSSL_MSG("mpi NULL error");
        return WOLFSSL_FATAL_ERROR;
    }

    if (*bn == NULL) {
        *bn = wolfSSL_BN_new();
        if (*bn == NULL) {
            WOLFSSL_MSG("SetIndividualExternal alloc failed");
            return WOLFSSL_FATAL_ERROR;
        }
        dynamic = 1;
    }

    if (mp_copy(mpi, (mp_int*)((*bn)->internal)) != MP_OKAY) {
        WOLFSSL_MSG("mp_copy error");
        if (dynamic == 1) {
            wolfSSL_BN_free(*bn);
        }
        return WOLFSSL_FATAL_ERROR;
    }

    return WOLFSSL_SUCCESS;
}


static void InitwolfSSL_BigNum(WOLFSSL_BIGNUM* bn)
{
    if (bn)
        XMEMSET(bn, 0, sizeof(WOLFSSL_BIGNUM));
}


WOLFSSL_BIGNUM* wolfSSL_BN_new(void)
{
    WOLFSSL_BIGNUM* external;
    mp_int*        mpi;

#ifdef WOLFSSL_DEBUG_OPENSSL
    WOLFSSL_MSG("wolfSSL_BN_new");
#endif

#if !defined(USE_FAST_MATH) || defined(HAVE_WOLF_BIGINT)
    mpi = (mp_int*) XMALLOC(sizeof(mp_int), NULL, DYNAMIC_TYPE_BIGINT);
    if (mpi == NULL) {
        WOLFSSL_MSG("wolfSSL_BN_new malloc mpi failure");
        return NULL;
    }
#endif

    external = (WOLFSSL_BIGNUM*) XMALLOC(sizeof(WOLFSSL_BIGNUM), NULL,
                                        DYNAMIC_TYPE_BIGINT);
    if (external == NULL) {
        WOLFSSL_MSG("wolfSSL_BN_new malloc WOLFSSL_BIGNUM failure");
#if !defined(USE_FAST_MATH) || defined(HAVE_WOLF_BIGINT)
        XFREE(mpi, NULL, DYNAMIC_TYPE_BIGINT);
#endif
        return NULL;
    }

#if defined(USE_FAST_MATH) && !defined(HAVE_WOLF_BIGINT)
    mpi = &external->fp;
#endif

    InitwolfSSL_BigNum(external);
    if (mp_init(mpi) != MP_OKAY) {
        wolfSSL_BN_free(external);
        return NULL;
    }
    external->internal = mpi;

    return external;
}


#if defined(USE_FAST_MATH) && !defined(HAVE_WOLF_BIGINT)
/* This function works without BN_free only with TFM */
void wolfSSL_BN_init(WOLFSSL_BIGNUM* bn)
{
    if(bn == NULL)return;
#ifdef WOLFSSL_DEBUG_OPENSSL
    WOLFSSL_MSG("wolfSSL_BN_init");
#endif
    InitwolfSSL_BigNum(bn);
    if (mp_init(&bn->fp) != MP_OKAY)
        return;
    bn->internal = (void *)&bn->fp;
}
#endif

void wolfSSL_BN_free(WOLFSSL_BIGNUM* bn)
{
#ifdef WOLFSSL_DEBUG_OPENSSL
    WOLFSSL_MSG("wolfSSL_BN_free");
#endif
    if (bn) {
        if (bn->internal) {
            mp_int* bni = (mp_int*)bn->internal;
            mp_free(bni);
#if !defined(USE_FAST_MATH) || defined(HAVE_WOLF_BIGINT)
            XFREE(bn->internal, NULL, DYNAMIC_TYPE_BIGINT);
#endif
            bn->internal = NULL;
        }
        XFREE(bn, NULL, DYNAMIC_TYPE_BIGINT);
        /* bn = NULL, don't try to access or double free it */
    }

}

void wolfSSL_BN_clear_free(WOLFSSL_BIGNUM* bn)
{
#ifdef WOLFSSL_DEBUG_OPENSSL
    WOLFSSL_MSG("wolfSSL_BN_clear_free");
#endif
    if (bn) {
        if (bn->internal) {
            mp_int* bni = (mp_int*)bn->internal;
            mp_forcezero(bni);
        }
        wolfSSL_BN_free(bn);
    }
}

void wolfSSL_BN_clear(WOLFSSL_BIGNUM* bn)
{
#ifdef WOLFSSL_DEBUG_OPENSSL
    WOLFSSL_MSG("wolfSSL_BN_clear");
#endif
    if (bn && bn->internal) {
        mp_forcezero((mp_int*)bn->internal);
    }
}
#endif /* OPENSSL_EXTRA || OPENSSL_EXTRA_X509_SMALL */

#ifdef OPENSSL_ALL

#if !defined(NO_BIO) && !defined(NO_PWDBASED) && defined(HAVE_PKCS8)
int wolfSSL_PEM_write_bio_PKCS8PrivateKey(WOLFSSL_BIO* bio,
                                          WOLFSSL_EVP_PKEY* pkey,
                                          const WOLFSSL_EVP_CIPHER* enc,
                                          char* passwd, int passwdSz,
                                          wc_pem_password_cb* cb, void* ctx)
{
    int ret = 0;
    char password[NAME_SZ];
    byte* key = NULL;
    word32 keySz;
    byte* pem = NULL;
    int pemSz;
    int type = PKCS8_PRIVATEKEY_TYPE;
    int algId;
    const byte* curveOid;
    word32 oidSz;
    int encAlgId = 0;

    if (bio == NULL || pkey == NULL)
        return -1;

    keySz = pkey->pkey_sz + 128;
    key = (byte*)XMALLOC(keySz, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    if (key == NULL)
        ret = MEMORY_E;

    if (ret == 0 && enc != NULL && passwd == NULL) {
        passwdSz = cb(password, sizeof(password), 1, ctx);
        if (passwdSz < 0)
            ret = WOLFSSL_FAILURE;
        passwd = password;
    }

    if (ret == 0 && enc != NULL) {
        WC_RNG rng;
        ret = wc_InitRng(&rng);
        if (ret == 0) {
        #ifndef NO_DES3
            if (enc == EVP_DES_CBC)
                encAlgId = DESb;
            else if (enc == EVP_DES_EDE3_CBC)
                encAlgId = DES3b;
            else
        #endif
        #if !defined(NO_AES) && defined(HAVE_AES_CBC)
            #ifdef WOLFSSL_AES_256
            if (enc == EVP_AES_256_CBC)
                encAlgId = AES256CBCb;
            else
            #endif
        #endif
                ret = -1;
            if (ret == 0) {
                ret = TraditionalEnc((byte*)pkey->pkey.ptr, pkey->pkey_sz, key,
                                       &keySz, passwd, passwdSz, PKCS5, PBES2,
                                       encAlgId, NULL, 0, WC_PKCS12_ITT_DEFAULT,
                                       &rng, NULL);
                if (ret > 0) {
                    keySz = ret;
                    ret = 0;
                }
            }
            wc_FreeRng(&rng);
        }
        type = PKCS8_ENC_PRIVATEKEY_TYPE;
    }
    if (ret == 0 && enc == NULL) {
        type = PKCS8_PRIVATEKEY_TYPE;
    #ifdef HAVE_ECC
        if (pkey->type == EVP_PKEY_EC) {
            algId = ECDSAk;
            ret = wc_ecc_get_oid(pkey->ecc->group->curve_oid, &curveOid,
                                                                        &oidSz);
        }
        else
    #endif
        {
            algId = RSAk;
            curveOid = NULL;
            oidSz = 0;
        }

    #ifdef HAVE_ECC
        if (ret >= 0)
    #endif
        {
            ret = wc_CreatePKCS8Key(key, &keySz, (byte*)pkey->pkey.ptr,
                                         pkey->pkey_sz, algId, curveOid, oidSz);
            keySz = ret;
        }
    }

    if (password == passwd)
        XMEMSET(password, 0, passwdSz);

    if (ret >= 0) {
        pemSz = 2 * keySz + 2 * 64;
        pem = (byte*)XMALLOC(pemSz, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        if (pem == NULL)
            ret = MEMORY_E;
    }

    if (ret >= 0)
        ret = wc_DerToPemEx(key, keySz, pem, pemSz, NULL, type);

    if (key != NULL)
        XFREE(key, NULL, DYNAMIC_TYPE_TMP_BUFFER);

    if (ret >= 0) {
        if (wolfSSL_BIO_write(bio, pem, ret) != ret)
            ret = -1;
    }

    if (pem != NULL)
        XFREE(pem, NULL, DYNAMIC_TYPE_TMP_BUFFER);

    return ret < 0 ? 0 : ret;

}

#if !defined(NO_FILESYSTEM) && !defined(NO_STDIO_FILESYSTEM)
int wolfSSL_PEM_write_PKCS8PrivateKey(XFILE f, WOLFSSL_EVP_PKEY* pkey,
    const WOLFSSL_EVP_CIPHER* enc, char* passwd, int passwdSz,
    wc_pem_password_cb* cb, void* ctx)
{
    int ret = WOLFSSL_SUCCESS;
    BIO *b;

    WOLFSSL_ENTER("wolfSSL_PEM_write_PKCS8PrivateKey");

    b = wolfSSL_BIO_new_fp(f, BIO_NOCLOSE);
    if (b == NULL) {
        ret = WOLFSSL_FAILURE;
    }
    if (ret == WOLFSSL_SUCCESS) {
        ret = wolfSSL_PEM_write_bio_PKCS8PrivateKey(b, pkey, enc, passwd,
                passwdSz, cb, ctx);
    }

    wolfSSL_BIO_free(b);

    return ret;
}
#endif /* !NO_FILESYSTEM && !NO_STDIO_FILESYSTEM */

static int bio_get_data(WOLFSSL_BIO* bio, byte** data)
{
    int ret = 0;
    byte* mem = NULL;

    ret = wolfSSL_BIO_get_len(bio);
    if (ret > 0) {
        mem = (byte*)XMALLOC(ret, bio->heap, DYNAMIC_TYPE_OPENSSL);
        if (mem == NULL) {
            WOLFSSL_MSG("Memory error");
            ret = MEMORY_E;
        }
        if (ret >= 0) {
            if ((ret = wolfSSL_BIO_read(bio, mem, ret)) <= 0) {
                XFREE(mem, bio->heap, DYNAMIC_TYPE_OPENSSL);
                ret = MEMORY_E;
                mem = NULL;
            }
        }
    }

    *data = mem;

    return ret;
}

/* DER data is PKCS#8 encrypted. */
WOLFSSL_EVP_PKEY* wolfSSL_d2i_PKCS8PrivateKey_bio(WOLFSSL_BIO* bio,
                                                  WOLFSSL_EVP_PKEY** pkey,
                                                  wc_pem_password_cb* cb,
                                                  void* ctx)
{
    int ret;
    byte* der;
    int len;
    byte* p;
    word32 algId;
    WOLFSSL_EVP_PKEY* key;

    if ((len = bio_get_data(bio, &der)) < 0)
        return NULL;

    if (cb != NULL) {
        char password[NAME_SZ];
        int passwordSz = cb(password, sizeof(password), PEM_PASS_READ, ctx);
        if (passwordSz < 0) {
            XFREE(der, bio->heap, DYNAMIC_TYPE_OPENSSL);
            return NULL;
        }
    #ifdef WOLFSSL_CHECK_MEM_ZERO
        wc_MemZero_Add("wolfSSL_d2i_PKCS8PrivateKey_bio password", password,
            passwordSz);
    #endif

        ret = ToTraditionalEnc(der, len, password, passwordSz, &algId);
        if (ret < 0) {
            XFREE(der, bio->heap, DYNAMIC_TYPE_OPENSSL);
            return NULL;
        }

        ForceZero(password, passwordSz);
    #ifdef WOLFSSL_CHECK_MEM_ZERO
        wc_MemZero_Check(password, passwordSz);
    #endif
    }

    p = der;
    key = wolfSSL_d2i_PrivateKey_EVP(pkey, &p, len);
    XFREE(der, bio->heap, DYNAMIC_TYPE_OPENSSL);
    return key;
}

#endif /* !NO_BIO && !NO_PWDBASED && HAVE_PKCS8 */

/* Detect which type of key it is before decoding. */
WOLFSSL_EVP_PKEY* wolfSSL_d2i_AutoPrivateKey(WOLFSSL_EVP_PKEY** pkey,
                                             const unsigned char** pp,
                                             long length)
{
    int ret;
    WOLFSSL_EVP_PKEY* key = NULL;
    const byte* der = *pp;
    word32 idx = 0;
    int len = 0;
    word32 end = 0;
    int cnt = 0;
    int type;
    word32 algId;
    word32 keyLen = (word32)length;

    /* Take off PKCS#8 wrapper if found. */
    if ((len = ToTraditionalInline_ex(der, &idx, keyLen, &algId)) >= 0) {
        der += idx;
        keyLen = len;
    }
    idx = 0;
    len = 0;

    /* Use the number of elements in the outer sequence to determine key type.
     */
    ret = GetSequence(der, &idx, &len, keyLen);
    if (ret >= 0) {
        end = idx + len;
        while (ret >= 0 && idx < end) {
            /* Skip type */
            idx++;
            /* Get length and skip over - keeping count */
            len = 0;
            ret = GetLength(der, &idx, &len, keyLen);
            if (ret >= 0) {
                if (idx + len > end)
                    ret = ASN_PARSE_E;
                else {
                    idx += len;
                    cnt++;
                }
            }
        }
    }

    if (ret >= 0) {
        /* ECC includes version, private[, curve][, public key] */
        if (cnt >= 2 && cnt <= 4)
            type = EVP_PKEY_EC;
        else
            type = EVP_PKEY_RSA;

        key = wolfSSL_d2i_PrivateKey(type, pkey, &der, keyLen);
        *pp = der;
    }

    return key;
}
#endif /* OPENSSL_ALL */

#ifdef WOLFSSL_STATIC_EPHEMERAL
int wolfSSL_StaticEphemeralKeyLoad(WOLFSSL* ssl, int keyAlgo, void* keyPtr)
{
    int ret;
    word32 idx = 0;
    DerBuffer* der = NULL;

    if (ssl == NULL || ssl->ctx == NULL || keyPtr == NULL) {
        return BAD_FUNC_ARG;
    }

#ifndef SINGLE_THREADED
    if (!ssl->ctx->staticKELockInit) {
        return BUFFER_E; /* no keys set */
    }
    ret = wc_LockMutex(&ssl->ctx->staticKELock);
    if (ret != 0) {
        return ret;
    }
#endif

    ret = BUFFER_E; /* set default error */
    switch (keyAlgo) {
    #ifndef NO_DH
        case WC_PK_TYPE_DH:
            if (ssl != NULL)
                der = ssl->staticKE.dhKey;
            if (der == NULL)
                der = ssl->ctx->staticKE.dhKey;
            if (der != NULL) {
                DhKey* key = (DhKey*)keyPtr;
                WOLFSSL_MSG("Using static DH key");
                ret = wc_DhKeyDecode(der->buffer, &idx, key, der->length);
            }
            break;
    #endif
    #ifdef HAVE_ECC
        case WC_PK_TYPE_ECDH:
            if (ssl != NULL)
                der = ssl->staticKE.ecKey;
            if (der == NULL)
                der = ssl->ctx->staticKE.ecKey;
            if (der != NULL) {
                ecc_key* key = (ecc_key*)keyPtr;
                WOLFSSL_MSG("Using static ECDH key");
                ret = wc_EccPrivateKeyDecode(der->buffer, &idx, key, der->length);
            }
            break;
    #endif
    #ifdef HAVE_CURVE25519
        case WC_PK_TYPE_CURVE25519:
            if (ssl != NULL)
                der = ssl->staticKE.x25519Key;
            if (der == NULL)
                der = ssl->ctx->staticKE.x25519Key;
            if (der != NULL) {
                curve25519_key* key = (curve25519_key*)keyPtr;
                WOLFSSL_MSG("Using static X25519 key");
                ret = wc_Curve25519PrivateKeyDecode(der->buffer, &idx, key,
                    der->length);
            }
            break;
    #endif
    #ifdef HAVE_CURVE448
        case WC_PK_TYPE_CURVE448:
            if (ssl != NULL)
                der = ssl->staticKE.x448Key;
            if (der == NULL)
                der = ssl->ctx->staticKE.x448Key;
            if (der != NULL) {
                curve448_key* key = (curve448_key*)keyPtr;
                WOLFSSL_MSG("Using static X448 key");
                ret = wc_Curve448PrivateKeyDecode(der->buffer, &idx, key,
                    der->length);
            }
            break;
    #endif
        default:
            /* not supported */
            ret = NOT_COMPILED_IN;
            break;
    }

#ifndef SINGLE_THREADED
    wc_UnLockMutex(&ssl->ctx->staticKELock);
#endif
    return ret;
}

static int SetStaticEphemeralKey(WOLFSSL_CTX* ctx,
    StaticKeyExchangeInfo_t* staticKE, int keyAlgo, const char* key,
    unsigned int keySz, int format, void* heap)
{
    int ret = 0;
    DerBuffer* der = NULL;
    byte* keyBuf = NULL;
#ifndef NO_FILESYSTEM
    const char* keyFile = NULL;
#endif

    /* allow empty key to free buffer */
    if (staticKE == NULL || (key == NULL && keySz > 0)) {
        return BAD_FUNC_ARG;
    }

    WOLFSSL_ENTER("SetStaticEphemeralKey");

    /* if just free'ing key then skip loading */
    if (key != NULL) {
    #ifndef NO_FILESYSTEM
        /* load file from filesystem */
        if (key != NULL && keySz == 0) {
            size_t keyBufSz = 0;
            keyFile = (const char*)key;
            ret = wc_FileLoad(keyFile, &keyBuf, &keyBufSz, heap);
            if (ret != 0) {
                return ret;
            }
            keySz = (unsigned int)keyBufSz;
        }
        else
    #endif
        {
            /* use as key buffer directly */
            keyBuf = (byte*)key;
        }

        if (format == WOLFSSL_FILETYPE_PEM) {
        #ifdef WOLFSSL_PEM_TO_DER
            int keyFormat = 0;
            ret = PemToDer(keyBuf, keySz, PRIVATEKEY_TYPE, &der,
                heap, NULL, &keyFormat);
            /* auto detect key type */
            if (ret == 0 && keyAlgo == WC_PK_TYPE_NONE) {
                if (keyFormat == ECDSAk)
                    keyAlgo = WC_PK_TYPE_ECDH;
                else if (keyFormat == X25519k)
                    keyAlgo = WC_PK_TYPE_CURVE25519;
                else
                    keyAlgo = WC_PK_TYPE_DH;
            }
        #else
            ret = NOT_COMPILED_IN;
        #endif
        }
        else {
            /* Detect PK type (if required) */
        #ifdef HAVE_ECC
            if (keyAlgo == WC_PK_TYPE_NONE) {
                word32 idx = 0;
                ecc_key eccKey;
                ret = wc_ecc_init_ex(&eccKey, heap, INVALID_DEVID);
                if (ret == 0) {
                    ret = wc_EccPrivateKeyDecode(keyBuf, &idx, &eccKey, keySz);
                    if (ret == 0)
                        keyAlgo = WC_PK_TYPE_ECDH;
                    wc_ecc_free(&eccKey);
                }
            }
        #endif
        #if !defined(NO_DH) && defined(WOLFSSL_DH_EXTRA)
            if (keyAlgo == WC_PK_TYPE_NONE) {
                word32 idx = 0;
                DhKey dhKey;
                ret = wc_InitDhKey_ex(&dhKey, heap, INVALID_DEVID);
                if (ret == 0) {
                    ret = wc_DhKeyDecode(keyBuf, &idx, &dhKey, keySz);
                    if (ret == 0)
                        keyAlgo = WC_PK_TYPE_DH;
                    wc_FreeDhKey(&dhKey);
                }
            }
        #endif
        #ifdef HAVE_CURVE25519
            if (keyAlgo == WC_PK_TYPE_NONE) {
                word32 idx = 0;
                curve25519_key x25519Key;
                ret = wc_curve25519_init_ex(&x25519Key, heap, INVALID_DEVID);
                if (ret == 0) {
                    ret = wc_Curve25519PrivateKeyDecode(keyBuf, &idx, &x25519Key,
                        keySz);
                    if (ret == 0)
                        keyAlgo = WC_PK_TYPE_CURVE25519;
                    wc_curve25519_free(&x25519Key);
                }
            }
        #endif
        #ifdef HAVE_CURVE448
            if (keyAlgo == WC_PK_TYPE_NONE) {
                word32 idx = 0;
                curve448_key x448Key;
                ret = wc_curve448_init(&x448Key);
                if (ret == 0) {
                    ret = wc_Curve448PrivateKeyDecode(keyBuf, &idx, &x448Key,
                        keySz);
                    if (ret == 0)
                        keyAlgo = WC_PK_TYPE_CURVE448;
                    wc_curve448_free(&x448Key);
                }
            }
        #endif

            if (keyAlgo != WC_PK_TYPE_NONE) {
                ret = AllocDer(&der, keySz, PRIVATEKEY_TYPE, heap);
                if (ret == 0) {
                    XMEMCPY(der->buffer, keyBuf, keySz);
                }
            }
        }
    }

#ifndef NO_FILESYSTEM
    /* done with keyFile buffer */
    if (keyFile && keyBuf) {
        XFREE(keyBuf, heap, DYNAMIC_TYPE_TMP_BUFFER);
    }
#endif

#ifndef SINGLE_THREADED
    if (ret == 0 && !ctx->staticKELockInit) {
        ret = wc_InitMutex(&ctx->staticKELock);
        if (ret == 0) {
            ctx->staticKELockInit = 1;
        }
    }
#endif
    if (ret == 0
    #ifndef SINGLE_THREADED
        && (ret = wc_LockMutex(&ctx->staticKELock)) == 0
    #endif
    ) {
        switch (keyAlgo) {
        #ifndef NO_DH
            case WC_PK_TYPE_DH:
                FreeDer(&staticKE->dhKey);
                staticKE->dhKey = der; der = NULL;
                break;
        #endif
        #ifdef HAVE_ECC
            case WC_PK_TYPE_ECDH:
                FreeDer(&staticKE->ecKey);
                staticKE->ecKey = der; der = NULL;
                break;
        #endif
        #ifdef HAVE_CURVE25519
            case WC_PK_TYPE_CURVE25519:
                FreeDer(&staticKE->x25519Key);
                staticKE->x25519Key = der; der = NULL;
                break;
        #endif
        #ifdef HAVE_CURVE448
            case WC_PK_TYPE_CURVE448:
                FreeDer(&staticKE->x448Key);
                staticKE->x448Key = der; der = NULL;
                break;
        #endif
            default:
                /* not supported */
                ret = NOT_COMPILED_IN;
                break;
        }

    #ifndef SINGLE_THREADED
        wc_UnLockMutex(&ctx->staticKELock);
    #endif
    }

    if (ret != 0) {
        FreeDer(&der);
    }

    (void)ctx; /* not used for single threaded */

    WOLFSSL_LEAVE("SetStaticEphemeralKey", ret);

    return ret;
}

int wolfSSL_CTX_set_ephemeral_key(WOLFSSL_CTX* ctx, int keyAlgo,
    const char* key, unsigned int keySz, int format)
{
    if (ctx == NULL) {
        return BAD_FUNC_ARG;
    }
    return SetStaticEphemeralKey(ctx, &ctx->staticKE, keyAlgo,
        key, keySz, format, ctx->heap);
}
int wolfSSL_set_ephemeral_key(WOLFSSL* ssl, int keyAlgo,
    const char* key, unsigned int keySz, int format)
{
    if (ssl == NULL || ssl->ctx == NULL) {
        return BAD_FUNC_ARG;
    }
    return SetStaticEphemeralKey(ssl->ctx, &ssl->staticKE, keyAlgo,
        key, keySz, format, ssl->heap);
}

static int GetStaticEphemeralKey(WOLFSSL_CTX* ctx, WOLFSSL* ssl,
    int keyAlgo, const unsigned char** key, unsigned int* keySz)
{
    int ret = 0;
    DerBuffer* der = NULL;

    if (key)   *key = NULL;
    if (keySz) *keySz = 0;

#ifndef SINGLE_THREADED
    if (ctx->staticKELockInit &&
        (ret = wc_LockMutex(&ctx->staticKELock)) != 0) {
        return ret;
    }
#endif

    switch (keyAlgo) {
    #ifndef NO_DH
        case WC_PK_TYPE_DH:
            if (ssl != NULL)
                der = ssl->staticKE.dhKey;
            if (der == NULL)
                der = ctx->staticKE.dhKey;
            break;
    #endif
    #ifdef HAVE_ECC
        case WC_PK_TYPE_ECDH:
            if (ssl != NULL)
                der = ssl->staticKE.ecKey;
            if (der == NULL)
                der = ctx->staticKE.ecKey;
            break;
    #endif
    #ifdef HAVE_CURVE25519
        case WC_PK_TYPE_CURVE25519:
            if (ssl != NULL)
                der = ssl->staticKE.x25519Key;
            if (der == NULL)
                der = ctx->staticKE.x25519Key;
            break;
    #endif
    #ifdef HAVE_CURVE448
        case WC_PK_TYPE_CURVE448:
            if (ssl != NULL)
                der = ssl->staticKE.x448Key;
            if (der == NULL)
                der = ctx->staticKE.x448Key;
            break;
    #endif
        default:
            /* not supported */
            ret = NOT_COMPILED_IN;
            break;
    }

    if (der) {
        if (key)
            *key = der->buffer;
        if (keySz)
            *keySz = der->length;
    }

#ifndef SINGLE_THREADED
    wc_UnLockMutex(&ctx->staticKELock);
#endif

    return ret;
}

/* returns pointer to currently loaded static ephemeral as ASN.1 */
/* this can be converted to PEM using wc_DerToPem */
int wolfSSL_CTX_get_ephemeral_key(WOLFSSL_CTX* ctx, int keyAlgo,
    const unsigned char** key, unsigned int* keySz)
{
    if (ctx == NULL) {
        return BAD_FUNC_ARG;
    }

    return GetStaticEphemeralKey(ctx, NULL, keyAlgo, key, keySz);
}
int wolfSSL_get_ephemeral_key(WOLFSSL* ssl, int keyAlgo,
    const unsigned char** key, unsigned int* keySz)
{
    if (ssl == NULL || ssl->ctx == NULL) {
        return BAD_FUNC_ARG;
    }

    return GetStaticEphemeralKey(ssl->ctx, ssl, keyAlgo, key, keySz);
}

#endif /* WOLFSSL_STATIC_EPHEMERAL */

#if defined(OPENSSL_EXTRA)
/* wolfSSL_THREADID_current is provided as a compat API with
 * CRYPTO_THREADID_current to register current thread id into given id object.
 * However, CRYPTO_THREADID_current API has been deprecated and no longer
 * exists in the OpenSSL 1.0.0 or later.This API only works as a stub
 * like as existing wolfSSL_THREADID_set_numeric.
 */
void wolfSSL_THREADID_current(WOLFSSL_CRYPTO_THREADID* id)
{
    (void)id;
    return;
}
/* wolfSSL_THREADID_hash is provided as a compatible API with
 * CRYPTO_THREADID_hash which returns a hash value calcurated from the
 * specified thread id. However, CRYPTO_THREADID_hash API has been
 * deprecated and no longer exists in the OpenSSL 1.0.0 or later.
 * This API only works as a stub to returns 0. This behavior is
 * equivalent to the latest OpenSSL CRYPTO_THREADID_hash.
 */
unsigned long wolfSSL_THREADID_hash(const WOLFSSL_CRYPTO_THREADID* id)
{
    (void)id;
    return 0UL;
}
/* wolfSSL_CTX_set_ecdh_auto is provided as compatible API with
 * SSL_CTX_set_ecdh_auto to enable auto ecdh curve selection functionality.
 * Since this functionality is enabled by default in wolfSSL,
 * this API exists as a stub.
 */
int wolfSSL_CTX_set_ecdh_auto(WOLFSSL_CTX* ctx, int onoff)
{
    (void)ctx;
    (void)onoff;
    return WOLFSSL_SUCCESS;
}

/**
 * set security level (wolfSSL doesn't support security level)
 * @param ctx  a pointer to WOLFSSL_EVP_PKEY_CTX structure
 * @param level security level
 */
void wolfSSL_CTX_set_security_level(WOLFSSL_CTX* ctx, int level)
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_security_level");
    (void)ctx;
    (void)level;
}
/**
 * get security level (wolfSSL doesn't support security level)
 * @param ctx  a pointer to WOLFSSL_EVP_PKEY_CTX structure
 * @return always 0(level 0)
 */
int wolfSSL_CTX_get_security_level(const WOLFSSL_CTX* ctx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_get_security_level");
    (void)ctx;
    return 0;
}


/**
 * Determine whether a WOLFSSL_SESSION object can be used for resumption
 * @param s  a pointer to WOLFSSL_SESSION structure
 * @return return 1 if session is resumable, otherwise 0.
 */
int wolfSSL_SESSION_is_resumable(const WOLFSSL_SESSION *s)
{
    s = ClientSessionToSession(s);
    if (s == NULL)
        return 0;

#ifdef HAVE_SESSION_TICKET
    if (s->ticketLen > 0)
        return 1;
#endif

    if (s->sessionIDSz > 0)
        return 1;

    return 0;
}

#if defined(OPENSSL_EXTRA) && defined(HAVE_SECRET_CALLBACK)
/*
 * This API accepts a user callback which puts key-log records into
 * a KEY LOGFILE. The callback is stored into a CTX and propagated to
 * each SSL object on its creation timing.
 */
void wolfSSL_CTX_set_keylog_callback(WOLFSSL_CTX* ctx, wolfSSL_CTX_keylog_cb_func cb)
{
    WOLFSSL_ENTER("wolfSSL_CTX_set_keylog_callback");
  /* stores the callback into WOLFSSL_CTX */
    if (ctx != NULL) {
        ctx->keyLogCb = cb;
    }
}
wolfSSL_CTX_keylog_cb_func wolfSSL_CTX_get_keylog_callback(
    const WOLFSSL_CTX* ctx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_get_keylog_callback");
    if (ctx != NULL)
        return ctx->keyLogCb;
    else
        return NULL;
}
#endif /* OPENSSL_EXTRA && HAVE_SECRET_CALLBACK */

#endif /* OPENSSL_EXTRA */

#ifndef NO_CERT
#define WOLFSSL_X509_INCLUDED
#include "src/x509.c"
#endif

/*******************************************************************************
 * START OF standard C library wrapping APIs
 ******************************************************************************/
#if defined(OPENSSL_ALL) || (defined(OPENSSL_EXTRA) && (defined(HAVE_STUNNEL) || \
                             defined(WOLFSSL_NGINX) || defined(HAVE_LIGHTY) || \
                             defined(WOLFSSL_HAPROXY) || defined(WOLFSSL_OPENSSH)))
#ifndef NO_WOLFSSL_STUB
int wolfSSL_CRYPTO_set_mem_ex_functions(void *(*m) (size_t, const char *, int),
                                void *(*r) (void *, size_t, const char *,
                                            int), void (*f) (void *))
{
    (void) m;
    (void) r;
    (void) f;
    WOLFSSL_ENTER("wolfSSL_CRYPTO_set_mem_ex_functions");
    WOLFSSL_STUB("CRYPTO_set_mem_ex_functions");

    return WOLFSSL_FAILURE;
}
#endif
#endif

#if defined(OPENSSL_EXTRA)

/**
 * free allocated memory resouce
 * @param str  a pointer to resource to be freed
 * @param file dummy argument
 * @param line dummy argument
 */
void wolfSSL_CRYPTO_free(void *str, const char *file, int line)
{
    (void)file;
    (void)line;
    XFREE(str, 0, DYNAMIC_TYPE_TMP_BUFFER);
}
/**
 * allocate memory with size of num
 * @param num  size of memory allocation to be malloced
 * @param file dummy argument
 * @param line dummy argument
 * @return a pointer to allocated memory on succssesful, otherwise NULL
 */
void *wolfSSL_CRYPTO_malloc(size_t num, const char *file, int line)
{
    (void)file;
    (void)line;
    return XMALLOC(num, 0, DYNAMIC_TYPE_TMP_BUFFER);
}

#endif

/*******************************************************************************
 * END OF standard C library wrapping APIs
 ******************************************************************************/

/*******************************************************************************
 * START OF EX_DATA APIs
 ******************************************************************************/
#if defined(OPENSSL_ALL) || (defined(OPENSSL_EXTRA) && (defined(HAVE_STUNNEL) || \
                             defined(WOLFSSL_NGINX) || defined(HAVE_LIGHTY) || \
                             defined(WOLFSSL_HAPROXY) || defined(WOLFSSL_OPENSSH)))
void wolfSSL_CRYPTO_cleanup_all_ex_data(void){
    WOLFSSL_ENTER("CRYPTO_cleanup_all_ex_data");
}
#endif

#ifdef HAVE_EX_DATA
void* wolfSSL_CRYPTO_get_ex_data(const WOLFSSL_CRYPTO_EX_DATA* ex_data, int idx)
{
    WOLFSSL_ENTER("wolfSSL_CTX_get_ex_data");
#ifdef MAX_EX_DATA
    if(ex_data && idx < MAX_EX_DATA && idx >= 0) {
        return ex_data->ex_data[idx];
    }
#else
    (void)ex_data;
    (void)idx;
#endif
    return NULL;
}

int wolfSSL_CRYPTO_set_ex_data(WOLFSSL_CRYPTO_EX_DATA* ex_data, int idx, void *data)
{
    WOLFSSL_ENTER("wolfSSL_CRYPTO_set_ex_data");
#ifdef MAX_EX_DATA
    if (ex_data && idx < MAX_EX_DATA && idx >= 0) {
#ifdef HAVE_EX_DATA_CLEANUP_HOOKS
        if (ex_data->ex_data_cleanup_routines[idx]) {
            if (ex_data->ex_data[idx])
                ex_data->ex_data_cleanup_routines[idx](ex_data->ex_data[idx]);
            ex_data->ex_data_cleanup_routines[idx] = NULL;
        }
#endif
        ex_data->ex_data[idx] = data;
        return WOLFSSL_SUCCESS;
    }
#else
    (void)ex_data;
    (void)idx;
    (void)data;
#endif
    return WOLFSSL_FAILURE;
}

#ifdef HAVE_EX_DATA_CLEANUP_HOOKS
int wolfSSL_CRYPTO_set_ex_data_with_cleanup(
    WOLFSSL_CRYPTO_EX_DATA* ex_data,
    int idx,
    void *data,
    wolfSSL_ex_data_cleanup_routine_t cleanup_routine)
{
    WOLFSSL_ENTER("wolfSSL_CRYPTO_set_ex_data_with_cleanup");
    if (ex_data && idx < MAX_EX_DATA && idx >= 0) {
        if (ex_data->ex_data_cleanup_routines[idx] && ex_data->ex_data[idx])
            ex_data->ex_data_cleanup_routines[idx](ex_data->ex_data[idx]);
        ex_data->ex_data[idx] = data;
        ex_data->ex_data_cleanup_routines[idx] = cleanup_routine;
        return WOLFSSL_SUCCESS;
    }
    return WOLFSSL_FAILURE;
}
#endif /* HAVE_EX_DATA_CLEANUP_HOOKS */

/**
 * Issues unique index for the class specified by class_index.
 * Other parameter except class_index are ignored.
 * Currently, following class_index are accepted:
 *  - WOLF_CRYPTO_EX_INDEX_SSL
 *  - WOLF_CRYPTO_EX_INDEX_SSL_CTX
 *  - WOLF_CRYPTO_EX_INDEX_X509
 * @param class_index index one of CRYPTO_EX_INDEX_xxx
 * @param argp  parameters to be saved
 * @param argl  parameters to be saved
 * @param new_func a pointer to WOLFSSL_CRYPTO_EX_new
 * @param dup_func a pointer to WOLFSSL_CRYPTO_EX_dup
 * @param free_func a pointer to WOLFSSL_CRYPTO_EX_free
 * @return index value grater or equal to zero on success, -1 on failure.
 */
int wolfSSL_CRYPTO_get_ex_new_index(int class_index, long argl, void *argp,
                                           WOLFSSL_CRYPTO_EX_new* new_func,
                                           WOLFSSL_CRYPTO_EX_dup* dup_func,
                                           WOLFSSL_CRYPTO_EX_free* free_func)
{
    WOLFSSL_ENTER("wolfSSL_CRYPTO_get_ex_new_index");

    WOLFSSL_CRYPTO_EX_DATA_IGNORE_PARAMS(argl, argp, new_func, dup_func,
                                         free_func);

    return wolfssl_get_ex_new_index(class_index);
}
#endif /* HAVE_EX_DATA */

/*******************************************************************************
 * END OF EX_DATA APIs
 ******************************************************************************/

/*******************************************************************************
 * START OF BUF_MEM API
 ******************************************************************************/

#if defined(OPENSSL_EXTRA)

/* Begin functions for openssl/buffer.h */
WOLFSSL_BUF_MEM* wolfSSL_BUF_MEM_new(void)
{
    WOLFSSL_BUF_MEM* buf;
    buf = (WOLFSSL_BUF_MEM*)XMALLOC(sizeof(WOLFSSL_BUF_MEM), NULL,
                                                        DYNAMIC_TYPE_OPENSSL);
    if (buf) {
        XMEMSET(buf, 0, sizeof(WOLFSSL_BUF_MEM));
    }
    return buf;
}

/* non-compat API returns length of buffer on success */
int wolfSSL_BUF_MEM_grow_ex(WOLFSSL_BUF_MEM* buf, size_t len,
        char zeroFill)
{

    int len_int = (int)len;
    int mx;
    char* tmp;

    /* verify provided arguments */
    if (buf == NULL || len_int < 0) {
        return 0; /* BAD_FUNC_ARG; */
    }

    /* check to see if fits in existing length */
    if (buf->length > len) {
        buf->length = len;
        return len_int;
    }

    /* check to see if fits in max buffer */
    if (buf->max >= len) {
        if (buf->data != NULL && zeroFill) {
            XMEMSET(&buf->data[buf->length], 0, len - buf->length);
        }
        buf->length = len;
        return len_int;
    }

    /* expand size, to handle growth */
    mx = (len_int + 3) / 3 * 4;

    /* use realloc */
    tmp = (char*)XREALLOC(buf->data, mx, NULL, DYNAMIC_TYPE_OPENSSL);
    if (tmp == NULL) {
        return 0; /* ERR_R_MALLOC_FAILURE; */
    }
    buf->data = tmp;

    buf->max = mx;
    if (zeroFill)
        XMEMSET(&buf->data[buf->length], 0, len - buf->length);
    buf->length = len;

    return len_int;

}

/* returns length of buffer on success */
int wolfSSL_BUF_MEM_grow(WOLFSSL_BUF_MEM* buf, size_t len)
{
    return wolfSSL_BUF_MEM_grow_ex(buf, len, 1);
}

/* non-compat API returns length of buffer on success */
int wolfSSL_BUF_MEM_resize(WOLFSSL_BUF_MEM* buf, size_t len)
{
    char* tmp;
    int mx;

    /* verify provided arguments */
    if (buf == NULL || len == 0 || (int)len <= 0) {
        return 0; /* BAD_FUNC_ARG; */
    }

    if (len == buf->length)
        return (int)len;

    if (len > buf->length)
        return wolfSSL_BUF_MEM_grow_ex(buf, len, 0);

    /* expand size, to handle growth */
    mx = ((int)len + 3) / 3 * 4;

    /* We want to shrink the internal buffer */
    tmp = (char*)XREALLOC(buf->data, mx, NULL, DYNAMIC_TYPE_OPENSSL);
    if (tmp == NULL)
        return 0;

    buf->data = tmp;
    buf->length = len;
    buf->max = mx;

    return (int)len;
}

void wolfSSL_BUF_MEM_free(WOLFSSL_BUF_MEM* buf)
{
    if (buf) {
        if (buf->data) {
            XFREE(buf->data, NULL, DYNAMIC_TYPE_OPENSSL);
            buf->data = NULL;
        }
        buf->max = 0;
        buf->length = 0;
        XFREE(buf, NULL, DYNAMIC_TYPE_OPENSSL);
    }
}
/* End Functions for openssl/buffer.h */

#endif /* OPENSSL_EXTRA */

/*******************************************************************************
 * END OF BUF_MEM API
 ******************************************************************************/

#define WOLFSSL_CONF_INCLUDED
#include <src/conf.c>

/*******************************************************************************
 * START OF RAND API
 ******************************************************************************/

#if defined(OPENSSL_EXTRA) && !defined(WOLFSSL_NO_OPENSSL_RAND_CB)
static int wolfSSL_RAND_InitMutex(void)
{
    if (gRandMethodsInit == 0) {
        if (wc_InitMutex(&gRandMethodMutex) != 0) {
            WOLFSSL_MSG("Bad Init Mutex rand methods");
            return BAD_MUTEX_E;
        }
        gRandMethodsInit = 1;
    }
    return 0;
}
#endif

#ifdef OPENSSL_EXTRA

/* Checks if the global RNG has been created. If not then one is created.
 *
 * Returns WOLFSSL_SUCCESS when no error is encountered.
 */
int wolfSSL_RAND_Init(void)
{
    int ret = WOLFSSL_FAILURE;
#ifdef HAVE_GLOBAL_RNG
    if (wc_LockMutex(&globalRNGMutex) == 0) {
        if (initGlobalRNG == 0) {
            ret = wc_InitRng(&globalRNG);
            if (ret == 0) {
                initGlobalRNG = 1;
                ret = WOLFSSL_SUCCESS;
            }
        }
        wc_UnLockMutex(&globalRNGMutex);
    }
#endif
    return ret;
}


/* WOLFSSL_SUCCESS on ok */
int wolfSSL_RAND_seed(const void* seed, int len)
{
#ifndef WOLFSSL_NO_OPENSSL_RAND_CB
    if (wolfSSL_RAND_InitMutex() == 0 && wc_LockMutex(&gRandMethodMutex) == 0) {
        if (gRandMethods && gRandMethods->seed) {
            int ret = gRandMethods->seed(seed, len);
            wc_UnLockMutex(&gRandMethodMutex);
            return ret;
        }
        wc_UnLockMutex(&gRandMethodMutex);
    }
#else
    (void)seed;
    (void)len;
#endif

    /* Make sure global shared RNG (globalRNG) is initialized */
    return wolfSSL_RAND_Init();
}


/* Returns the path for reading seed data from.
 * Uses the env variable $RANDFILE first if set, if not then used $HOME/.rnd
 *
 * Note uses stdlib by default unless XGETENV macro is overwritten
 *
 * fname buffer to hold path
 * len   length of fname buffer
 *
 * Returns a pointer to fname on success and NULL on failure
 */
const char* wolfSSL_RAND_file_name(char* fname, unsigned long len)
{
#ifndef NO_FILESYSTEM
    char* rt;
    char ap[] = "/.rnd";

    WOLFSSL_ENTER("wolfSSL_RAND_file_name");

    if (fname == NULL) {
        return NULL;
    }

    XMEMSET(fname, 0, len);
    /* if access to stdlib.h */
    if ((rt = XGETENV("RANDFILE")) != NULL) {
        if (len > XSTRLEN(rt)) {
            XMEMCPY(fname, rt, XSTRLEN(rt));
        }
        else {
            WOLFSSL_MSG("RANDFILE too large for buffer");
            rt = NULL;
        }
    }

    /* $RANDFILE was not set or is too large, check $HOME */
    if (rt == NULL) {
        WOLFSSL_MSG("Environment variable RANDFILE not set");
        if ((rt = XGETENV("HOME")) == NULL) {
            WOLFSSL_MSG("Environment variable HOME not set");
            return NULL;
        }

        if (len > XSTRLEN(rt) +  XSTRLEN(ap)) {
            fname[0] = '\0';
            XSTRNCAT(fname, rt, len);
            XSTRNCAT(fname, ap, len - XSTRLEN(rt));
            return fname;
        }
        else {
            WOLFSSL_MSG("HOME too large for buffer");
            return NULL;
        }
    }

    return fname;
#else
    /* no filesystem defined */
    WOLFSSL_ENTER("wolfSSL_RAND_file_name");
    WOLFSSL_MSG("No filesystem feature enabled, not compiled in");
    (void)fname;
    (void)len;
    return NULL;
#endif
}


/* Writes 1024 bytes from the RNG to the given file name.
 *
 * fname name of file to write to
 *
 * Returns the number of bytes written
 */
int wolfSSL_RAND_write_file(const char* fname)
{
    int bytes = 0;

    WOLFSSL_ENTER("RAND_write_file");

    if (fname == NULL) {
        return SSL_FAILURE;
    }

#ifndef NO_FILESYSTEM
    {
    #ifndef WOLFSSL_SMALL_STACK
        unsigned char buf[1024];
    #else
        unsigned char* buf = (unsigned char *)XMALLOC(1024, NULL,
                                                       DYNAMIC_TYPE_TMP_BUFFER);
        if (buf == NULL) {
            WOLFSSL_MSG("malloc failed");
            return SSL_FAILURE;
        }
    #endif
        bytes = 1024; /* default size of buf */

        if (initGlobalRNG == 0 && wolfSSL_RAND_Init() != WOLFSSL_SUCCESS) {
            WOLFSSL_MSG("No RNG to use");
        #ifdef WOLFSSL_SMALL_STACK
            XFREE(buf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        #endif
            return 0;
        }

        if (wc_RNG_GenerateBlock(&globalRNG, buf, bytes) != 0) {
            WOLFSSL_MSG("Error generating random buffer");
            bytes = 0;
        }
        else {
            XFILE f;

        #ifdef WOLFSSL_CHECK_MEM_ZERO
            wc_MemZero_Add("wolfSSL_RAND_write_file buf", buf, bytes);
        #endif

            f = XFOPEN(fname, "wb");
            if (f == XBADFILE) {
                WOLFSSL_MSG("Error opening the file");
                bytes = 0;
            }
            else {
                size_t bytes_written = XFWRITE(buf, 1, bytes, f);
                bytes = (int)bytes_written;
                XFCLOSE(f);
            }
        }
        ForceZero(buf, bytes);
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(buf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    #elif defined(WOLFSSL_CHECK_MEM_ZERO)
        wc_MemZero_Check(buf, sizeof(buf));
    #endif
    }
#endif

    return bytes;
}

#ifndef FREERTOS_TCP

/* These constant values are protocol values made by egd */
#if defined(USE_WOLFSSL_IO) && !defined(USE_WINDOWS_API) && !defined(HAVE_FIPS) && \
    defined(HAVE_HASHDRBG) && !defined(NETOS) && defined(HAVE_SYS_UN_H)
    #define WOLFSSL_EGD_NBLOCK 0x01
    #include <sys/un.h>
#endif

/* This collects entropy from the path nm and seeds the global PRNG with it.
 *
 * nm is the file path to the egd server
 *
 * Returns the number of bytes read.
 */
int wolfSSL_RAND_egd(const char* nm)
{
#ifdef WOLFSSL_EGD_NBLOCK
    struct sockaddr_un rem;
    int fd;
    int ret = WOLFSSL_SUCCESS;
    word32 bytes = 0;
    word32 idx   = 0;
#ifndef WOLFSSL_SMALL_STACK
    unsigned char buf[256];
#else
    unsigned char* buf;
    buf = (unsigned char*)XMALLOC(256, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    if (buf == NULL) {
        WOLFSSL_MSG("Not enough memory");
        return WOLFSSL_FATAL_ERROR;
    }
#endif

    XMEMSET(&rem, 0, sizeof(struct sockaddr_un));
    if (nm == NULL) {
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(buf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    #endif
        return WOLFSSL_FATAL_ERROR;
    }

    fd = socket(AF_UNIX, SOCK_STREAM, 0);
    if (fd < 0) {
        WOLFSSL_MSG("Error creating socket");
    #ifdef WOLFSSL_SMALL_STACK
        XFREE(buf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    #endif
        return WOLFSSL_FATAL_ERROR;
    }
    rem.sun_family = AF_UNIX;
    XSTRNCPY(rem.sun_path, nm, sizeof(rem.sun_path) - 1);
    rem.sun_path[sizeof(rem.sun_path)-1] = '\0';

    /* connect to egd server */
    if (connect(fd, (struct sockaddr*)&rem, sizeof(struct sockaddr_un)) == -1) {
        WOLFSSL_MSG("error connecting to egd server");
        ret = WOLFSSL_FATAL_ERROR;
    }

#ifdef WOLFSSL_CHECK_MEM_ZERO
    if (ret == WOLFSSL_SUCCESS) {
        wc_MemZero_Add("wolfSSL_RAND_egd buf", buf, 256);
    }
#endif
    while (ret == WOLFSSL_SUCCESS && bytes < 255 && idx + 2 < 256) {
        buf[idx]     = WOLFSSL_EGD_NBLOCK;
        buf[idx + 1] = 255 - bytes; /* request 255 bytes from server */
        ret = (int)write(fd, buf + idx, 2);
        if (ret != 2) {
            if (errno == EAGAIN) {
                ret = WOLFSSL_SUCCESS;
                continue;
            }
            WOLFSSL_MSG("error requesting entropy from egd server");
            ret = WOLFSSL_FATAL_ERROR;
            break;
        }

        /* attempting to read */
        buf[idx] = 0;
        ret = (int)read(fd, buf + idx, 256 - bytes);
        if (ret == 0) {
            WOLFSSL_MSG("error reading entropy from egd server");
            ret = WOLFSSL_FATAL_ERROR;
            break;
        }
        if (ret > 0 && buf[idx] > 0) {
            bytes += buf[idx]; /* egd stores amount sent in first byte */
            if (bytes + idx > 255 || buf[idx] > ret) {
                WOLFSSL_MSG("Buffer error");
                ret = WOLFSSL_FATAL_ERROR;
                break;
            }
            XMEMMOVE(buf + idx, buf + idx + 1, buf[idx]);
            idx = bytes;
            ret = WOLFSSL_SUCCESS;
            if (bytes >= 255) {
                break;
            }
        }
        else {
            if (errno == EAGAIN || errno == EINTR) {
                WOLFSSL_MSG("EGD would read");
                ret = WOLFSSL_SUCCESS; /* try again */
            }
            else if (buf[idx] == 0) {
                /* if egd returned 0 then there is no more entropy to be had.
                   Do not try more reads. */
                ret = WOLFSSL_SUCCESS;
                break;
            }
            else {
                WOLFSSL_MSG("Error with read");
                ret = WOLFSSL_FATAL_ERROR;
            }
        }
    }

    if (bytes > 0 && ret == WOLFSSL_SUCCESS) {
        /* call to check global RNG is created */
        if (wolfSSL_RAND_Init() != SSL_SUCCESS) {
            WOLFSSL_MSG("Error with initializing global RNG structure");
            ret = WOLFSSL_FATAL_ERROR;
        }
        else if (wc_RNG_DRBG_Reseed(&globalRNG, (const byte*) buf, bytes)
                != 0) {
            WOLFSSL_MSG("Error with reseeding DRBG structure");
            ret = WOLFSSL_FATAL_ERROR;
        }
        #ifdef SHOW_SECRETS
        else { /* print out entropy found only when no error occured */
            word32 i;
            printf("EGD Entropy = ");
            for (i = 0; i < bytes; i++) {
                printf("%02X", buf[i]);
            }
            printf("\n");
        }
        #endif
    }

    ForceZero(buf, bytes);
#ifdef WOLFSSL_SMALL_STACK
    XFREE(buf, NULL, DYNAMIC_TYPE_TMP_BUFFER);
#elif defined(WOLFSSL_CHECK_MEM_ZERO)
    wc_MemZero_Check(buf, 256);
#endif
    close(fd);

    if (ret == WOLFSSL_SUCCESS) {
        return bytes;
    }
    else {
        return ret;
    }
#else
    WOLFSSL_MSG("Type of socket needed is not available");
    WOLFSSL_MSG("\tor using mode where DRBG API is not available");
    (void)nm;

    return WOLFSSL_FATAL_ERROR;
#endif /* WOLFSSL_EGD_NBLOCK */
}

#endif /* !FREERTOS_TCP */

void wolfSSL_RAND_Cleanup(void)
{
#ifndef WOLFSSL_NO_OPENSSL_RAND_CB
    if (wolfSSL_RAND_InitMutex() == 0 && wc_LockMutex(&gRandMethodMutex) == 0) {
        if (gRandMethods && gRandMethods->cleanup)
            gRandMethods->cleanup();
        wc_UnLockMutex(&gRandMethodMutex);
    }

    if (wc_FreeMutex(&gRandMethodMutex) == 0)
        gRandMethodsInit = 0;
#endif
#ifdef HAVE_GLOBAL_RNG
    if (wc_LockMutex(&globalRNGMutex) == 0) {
        if (initGlobalRNG) {
            wc_FreeRng(&globalRNG);
            initGlobalRNG = 0;
        }
        wc_UnLockMutex(&globalRNGMutex);
    }
#endif
}

/* returns WOLFSSL_SUCCESS if the bytes generated are valid otherwise WOLFSSL_FAILURE */
int wolfSSL_RAND_pseudo_bytes(unsigned char* buf, int num)
{
    int ret;
    int hash;
    byte secret[DRBG_SEED_LEN]; /* secret length arbitraily choosen */

#ifndef WOLFSSL_NO_OPENSSL_RAND_CB
    if (wolfSSL_RAND_InitMutex() == 0 && wc_LockMutex(&gRandMethodMutex) == 0) {
        if (gRandMethods && gRandMethods->pseudorand) {
            ret = gRandMethods->pseudorand(buf, num);
            wc_UnLockMutex(&gRandMethodMutex);
            return ret;
        }
        wc_UnLockMutex(&gRandMethodMutex);
    }
#endif

#ifdef WOLFSSL_HAVE_PRF
    #ifndef NO_SHA256
    hash = WC_SHA256;
    #elif defined(WOLFSSL_SHA384)
    hash = WC_SHA384;
    #elif !defined(NO_SHA)
    hash = WC_SHA;
    #elif !defined(NO_MD5)
    hash = WC_MD5;
    #endif

    /* get secret value from source of entropy */
    ret = wolfSSL_RAND_bytes(secret, DRBG_SEED_LEN);

    /* uses input buffer to seed for pseudo random number generation, each
     * thread will potentially have different results this way */
    if (ret == WOLFSSL_SUCCESS) {
        PRIVATE_KEY_UNLOCK();
        ret = wc_PRF(buf, num, secret, DRBG_SEED_LEN, (const byte*)buf, num,
                hash, NULL, INVALID_DEVID);
        PRIVATE_KEY_LOCK();
        ret = (ret == 0) ? WOLFSSL_SUCCESS: WOLFSSL_FAILURE;
    }
#else
    /* fall back to just doing wolfSSL_RAND_bytes if PRF not avialbale */
    ret = wolfSSL_RAND_bytes(buf, num);
    (void)hash;
    (void)secret;
#endif
    return ret;
}

/* returns WOLFSSL_SUCCESS if the bytes generated are valid otherwise WOLFSSL_FAILURE */
int wolfSSL_RAND_bytes(unsigned char* buf, int num)
{
    int     ret = 0;
    WC_RNG* rng = NULL;
#ifdef WOLFSSL_SMALL_STACK
    WC_RNG* tmpRNG = NULL;
#else
    WC_RNG  tmpRNG[1];
#endif
    int initTmpRng = 0;
    int blockCount = 0;
#ifdef HAVE_GLOBAL_RNG
    int used_global = 0;
#endif

    WOLFSSL_ENTER("wolfSSL_RAND_bytes");
    /* sanity check */
    if (buf == NULL || num < 0)
        /* return code compliant with OpenSSL */
        return 0;

    /* if a RAND callback has been set try and use it */
#ifndef WOLFSSL_NO_OPENSSL_RAND_CB
    if (wolfSSL_RAND_InitMutex() == 0 && wc_LockMutex(&gRandMethodMutex) == 0) {
        if (gRandMethods && gRandMethods->bytes) {
            ret = gRandMethods->bytes(buf, num);
            wc_UnLockMutex(&gRandMethodMutex);
            return ret;
        }
        wc_UnLockMutex(&gRandMethodMutex);
    }
#endif
#ifdef HAVE_GLOBAL_RNG
    if (initGlobalRNG) {
        if (wc_LockMutex(&globalRNGMutex) != 0) {
            WOLFSSL_MSG("Bad Lock Mutex rng");
            return ret;
        }

        rng = &globalRNG;
        used_global = 1;
    }
    else
#endif
    {
    #ifdef WOLFSSL_SMALL_STACK
        tmpRNG = (WC_RNG*)XMALLOC(sizeof(WC_RNG), NULL, DYNAMIC_TYPE_RNG);
        if (tmpRNG == NULL)
            return ret;
    #endif
        if (wc_InitRng(tmpRNG) == 0) {
            rng = tmpRNG;
            initTmpRng = 1;
        }
    }
    if (rng) {
        /* handles size greater than RNG_MAX_BLOCK_LEN */
        blockCount = num / RNG_MAX_BLOCK_LEN;

        while (blockCount--) {
            ret = wc_RNG_GenerateBlock(rng, buf, RNG_MAX_BLOCK_LEN);
            if (ret != 0) {
                WOLFSSL_MSG("Bad wc_RNG_GenerateBlock");
                break;
            }
            num -= RNG_MAX_BLOCK_LEN;
            buf += RNG_MAX_BLOCK_LEN;
        }

        if (ret == 0 && num)
            ret = wc_RNG_GenerateBlock(rng, buf, num);

        if (ret != 0)
            WOLFSSL_MSG("Bad wc_RNG_GenerateBlock");
        else
            ret = WOLFSSL_SUCCESS;
    }

#ifdef HAVE_GLOBAL_RNG
    if (used_global == 1)
        wc_UnLockMutex(&globalRNGMutex);
#endif
    if (initTmpRng)
        wc_FreeRng(tmpRNG);
#ifdef WOLFSSL_SMALL_STACK
    if (tmpRNG)
        XFREE(tmpRNG, NULL, DYNAMIC_TYPE_RNG);
#endif

    return ret;
}


int wolfSSL_RAND_poll(void)
{
    byte  entropy[16];
    int  ret = 0;
    word32 entropy_sz = 16;

    WOLFSSL_ENTER("wolfSSL_RAND_poll");
    if (initGlobalRNG == 0){
        WOLFSSL_MSG("Global RNG no Init");
        return  WOLFSSL_FAILURE;
    }
    ret = wc_GenerateSeed(&globalRNG.seed, entropy, entropy_sz);
    if (ret != 0){
        WOLFSSL_MSG("Bad wc_RNG_GenerateBlock");
        ret = WOLFSSL_FAILURE;
    }else
        ret = WOLFSSL_SUCCESS;

    return ret;
}

    /* If a valid struct is provided with function pointers, will override
       RAND_seed, bytes, cleanup, add, pseudo_bytes and status.  If a NULL
       pointer is passed in, it will cancel any previous function overrides.

       Returns WOLFSSL_SUCCESS on success, WOLFSSL_FAILURE on failure. */
    int wolfSSL_RAND_set_rand_method(const WOLFSSL_RAND_METHOD *methods)
    {
    #ifndef WOLFSSL_NO_OPENSSL_RAND_CB
        if (wolfSSL_RAND_InitMutex() == 0 && wc_LockMutex(&gRandMethodMutex) == 0) {
            gRandMethods = methods;
            wc_UnLockMutex(&gRandMethodMutex);
            return WOLFSSL_SUCCESS;
        }
    #else
        (void)methods;
    #endif
        return WOLFSSL_FAILURE;
    }

    /* Returns WOLFSSL_SUCCESS if the RNG has been seeded with enough data */
    int wolfSSL_RAND_status(void)
    {
        int ret = WOLFSSL_SUCCESS;
    #ifndef WOLFSSL_NO_OPENSSL_RAND_CB
        if (wolfSSL_RAND_InitMutex() == 0 && wc_LockMutex(&gRandMethodMutex) == 0) {
            if (gRandMethods && gRandMethods->status)
                ret = gRandMethods->status();
            wc_UnLockMutex(&gRandMethodMutex);
        }
        else {
            ret = WOLFSSL_FAILURE;
        }
    #else
        /* wolfCrypt provides enough seed internally, so return success */
    #endif
        return ret;
    }

    void wolfSSL_RAND_add(const void* add, int len, double entropy)
    {
    #ifndef WOLFSSL_NO_OPENSSL_RAND_CB
        if (wolfSSL_RAND_InitMutex() == 0 && wc_LockMutex(&gRandMethodMutex) == 0) {
            if (gRandMethods && gRandMethods->add) {
                /* callback has return code, but RAND_add does not */
                (void)gRandMethods->add(add, len, entropy);
            }
            wc_UnLockMutex(&gRandMethodMutex);
        }
    #else
        /* wolfSSL seeds/adds internally, use explicit RNG if you want
           to take control */
        (void)add;
        (void)len;
        (void)entropy;
    #endif
    }

#endif /* OPENSSL_EXTRA */

/*******************************************************************************
 * END OF RAND API
 ******************************************************************************/

/*******************************************************************************
 * START OF EVP_CIPHER API
 ******************************************************************************/

#ifdef OPENSSL_EXTRA

    /* store for external read of iv, WOLFSSL_SUCCESS on success */
    int  wolfSSL_StoreExternalIV(WOLFSSL_EVP_CIPHER_CTX* ctx)
    {
        WOLFSSL_ENTER("wolfSSL_StoreExternalIV");

        if (ctx == NULL) {
            WOLFSSL_MSG("Bad function argument");
            return WOLFSSL_FATAL_ERROR;
        }

        switch (ctx->cipherType) {
#ifndef NO_AES
#if defined(HAVE_AES_CBC) || defined(WOLFSSL_AES_DIRECT)
            case AES_128_CBC_TYPE :
            case AES_192_CBC_TYPE :
            case AES_256_CBC_TYPE :
                WOLFSSL_MSG("AES CBC");
                XMEMCPY(ctx->iv, &ctx->cipher.aes.reg, ctx->ivSz);
                break;
#endif
#ifdef HAVE_AESGCM
            case AES_128_GCM_TYPE :
            case AES_192_GCM_TYPE :
            case AES_256_GCM_TYPE :
                WOLFSSL_MSG("AES GCM");
                XMEMCPY(ctx->iv, &ctx->cipher.aes.reg, ctx->ivSz);
                break;
#endif /* HAVE_AESGCM */
#ifdef HAVE_AESCCM
            case AES_128_CCM_TYPE :
            case AES_192_CCM_TYPE :
            case AES_256_CCM_TYPE :
                WOLFSSL_MSG("AES CCM");
                XMEMCPY(ctx->iv, &ctx->cipher.aes.reg, ctx->ivSz);
                break;
#endif /* HAVE_AESCCM */
#ifdef HAVE_AES_ECB
            case AES_128_ECB_TYPE :
            case AES_192_ECB_TYPE :
            case AES_256_ECB_TYPE :
                WOLFSSL_MSG("AES ECB");
                break;
#endif
#ifdef WOLFSSL_AES_COUNTER
            case AES_128_CTR_TYPE :
            case AES_192_CTR_TYPE :
            case AES_256_CTR_TYPE :
                WOLFSSL_MSG("AES CTR");
                XMEMCPY(ctx->iv, &ctx->cipher.aes.reg, AES_BLOCK_SIZE);
                break;
#endif /* WOLFSSL_AES_COUNTER */
#ifdef WOLFSSL_AES_CFB
#if !defined(HAVE_SELFTEST) && !defined(HAVE_FIPS)
            case AES_128_CFB1_TYPE:
            case AES_192_CFB1_TYPE:
            case AES_256_CFB1_TYPE:
                WOLFSSL_MSG("AES CFB1");
                break;
            case AES_128_CFB8_TYPE:
            case AES_192_CFB8_TYPE:
            case AES_256_CFB8_TYPE:
                WOLFSSL_MSG("AES CFB8");
                break;
#endif /* !HAVE_SELFTEST && !HAVE_FIPS */
            case AES_128_CFB128_TYPE:
            case AES_192_CFB128_TYPE:
            case AES_256_CFB128_TYPE:
                WOLFSSL_MSG("AES CFB128");
                break;
#endif /* WOLFSSL_AES_CFB */
#if defined(WOLFSSL_AES_OFB)
            case AES_128_OFB_TYPE:
            case AES_192_OFB_TYPE:
            case AES_256_OFB_TYPE:
                WOLFSSL_MSG("AES OFB");
                break;
#endif /* WOLFSSL_AES_OFB */
#ifdef WOLFSSL_AES_XTS
            case AES_128_XTS_TYPE:
            case AES_256_XTS_TYPE:
                WOLFSSL_MSG("AES XTS");
                break;
#endif /* WOLFSSL_AES_XTS */
#endif /* NO_AES */

#ifndef NO_DES3
            case DES_CBC_TYPE :
                WOLFSSL_MSG("DES CBC");
                XMEMCPY(ctx->iv, &ctx->cipher.des.reg, DES_BLOCK_SIZE);
                break;

            case DES_EDE3_CBC_TYPE :
                WOLFSSL_MSG("DES EDE3 CBC");
                XMEMCPY(ctx->iv, &ctx->cipher.des3.reg, DES_BLOCK_SIZE);
                break;
#endif
#ifdef WOLFSSL_DES_ECB
            case DES_ECB_TYPE :
                WOLFSSL_MSG("DES ECB");
                break;
            case DES_EDE3_ECB_TYPE :
                WOLFSSL_MSG("DES3 ECB");
                break;
#endif
            case ARC4_TYPE :
                WOLFSSL_MSG("ARC4");
                break;

#if defined(HAVE_CHACHA) && defined(HAVE_POLY1305)
            case CHACHA20_POLY1305_TYPE:
                break;
#endif

#ifdef HAVE_CHACHA
            case CHACHA20_TYPE:
                break;
#endif

            case NULL_CIPHER_TYPE :
                WOLFSSL_MSG("NULL");
                break;

            default: {
                WOLFSSL_MSG("bad type");
                return WOLFSSL_FATAL_ERROR;
            }
        }
        return WOLFSSL_SUCCESS;
    }

    /* set internal IV from external, WOLFSSL_SUCCESS on success */
    int  wolfSSL_SetInternalIV(WOLFSSL_EVP_CIPHER_CTX* ctx)
    {

        WOLFSSL_ENTER("wolfSSL_SetInternalIV");

        if (ctx == NULL) {
            WOLFSSL_MSG("Bad function argument");
            return WOLFSSL_FATAL_ERROR;
        }

        switch (ctx->cipherType) {

#ifndef NO_AES
#if defined(HAVE_AES_CBC) || defined(WOLFSSL_AES_DIRECT)
            case AES_128_CBC_TYPE :
            case AES_192_CBC_TYPE :
            case AES_256_CBC_TYPE :
                WOLFSSL_MSG("AES CBC");
                XMEMCPY(&ctx->cipher.aes.reg, ctx->iv, AES_BLOCK_SIZE);
                break;
#endif
#ifdef HAVE_AESGCM
            case AES_128_GCM_TYPE :
            case AES_192_GCM_TYPE :
            case AES_256_GCM_TYPE :
                WOLFSSL_MSG("AES GCM");
                XMEMCPY(&ctx->cipher.aes.reg, ctx->iv, AES_BLOCK_SIZE);
                break;
#endif
#ifdef HAVE_AES_ECB
            case AES_128_ECB_TYPE :
            case AES_192_ECB_TYPE :
            case AES_256_ECB_TYPE :
                WOLFSSL_MSG("AES ECB");
                break;
#endif
#ifdef WOLFSSL_AES_COUNTER
            case AES_128_CTR_TYPE :
            case AES_192_CTR_TYPE :
            case AES_256_CTR_TYPE :
                WOLFSSL_MSG("AES CTR");
                XMEMCPY(&ctx->cipher.aes.reg, ctx->iv, AES_BLOCK_SIZE);
                break;
#endif

#endif /* NO_AES */

#ifndef NO_DES3
            case DES_CBC_TYPE :
                WOLFSSL_MSG("DES CBC");
                XMEMCPY(&ctx->cipher.des.reg, ctx->iv, DES_BLOCK_SIZE);
                break;

            case DES_EDE3_CBC_TYPE :
                WOLFSSL_MSG("DES EDE3 CBC");
                XMEMCPY(&ctx->cipher.des3.reg, ctx->iv, DES_BLOCK_SIZE);
                break;
#endif
#ifdef WOLFSSL_DES_ECB
            case DES_ECB_TYPE :
                WOLFSSL_MSG("DES ECB");
                break;
            case DES_EDE3_ECB_TYPE :
                WOLFSSL_MSG("DES3 ECB");
                break;
#endif

            case ARC4_TYPE :
                WOLFSSL_MSG("ARC4");
                break;

#if defined(HAVE_CHACHA) && defined(HAVE_POLY1305)
            case CHACHA20_POLY1305_TYPE:
                break;
#endif

#ifdef HAVE_CHACHA
            case CHACHA20_TYPE:
                break;
#endif

            case NULL_CIPHER_TYPE :
                WOLFSSL_MSG("NULL");
                break;

            default: {
                WOLFSSL_MSG("bad type");
                return WOLFSSL_FATAL_ERROR;
            }
        }
        return WOLFSSL_SUCCESS;
    }

#ifndef NO_DES3

void wolfSSL_3des_iv(WOLFSSL_EVP_CIPHER_CTX* ctx, int doset,
                            unsigned char* iv, int len)
{
    (void)len;

    WOLFSSL_MSG("wolfSSL_3des_iv");

    if (ctx == NULL || iv == NULL) {
        WOLFSSL_MSG("Bad function argument");
        return;
    }

    if (doset)
        wc_Des3_SetIV(&ctx->cipher.des3, iv);  /* OpenSSL compat, no ret */
    else
        XMEMCPY(iv, &ctx->cipher.des3.reg, DES_BLOCK_SIZE);
}

#endif /* NO_DES3 */


#ifndef NO_AES

void wolfSSL_aes_ctr_iv(WOLFSSL_EVP_CIPHER_CTX* ctx, int doset,
                      unsigned char* iv, int len)
{
    (void)len;

    WOLFSSL_MSG("wolfSSL_aes_ctr_iv");

    if (ctx == NULL || iv == NULL) {
        WOLFSSL_MSG("Bad function argument");
        return;
    }

    if (doset)
       (void)wc_AesSetIV(&ctx->cipher.aes, iv);  /* OpenSSL compat, no ret */
    else
        XMEMCPY(iv, &ctx->cipher.aes.reg, AES_BLOCK_SIZE);
}

#endif /* NO_AES */

#endif /* OPENSSL_EXTRA */

/*******************************************************************************
 * END OF EVP_CIPHER API
 ******************************************************************************/

#ifndef NO_CERTS

#define WOLFSSL_X509_STORE_INCLUDED
#include <src/x509_str.c>

/*******************************************************************************
 * START OF PKCS7 APIs
 ******************************************************************************/
#ifdef HAVE_PKCS7

#ifdef OPENSSL_ALL
PKCS7* wolfSSL_PKCS7_new(void)
{
    WOLFSSL_PKCS7* pkcs7;
    int ret = 0;

    pkcs7 = (WOLFSSL_PKCS7*)XMALLOC(sizeof(WOLFSSL_PKCS7), NULL,
                                    DYNAMIC_TYPE_PKCS7);
    if (pkcs7 != NULL) {
        XMEMSET(pkcs7, 0, sizeof(WOLFSSL_PKCS7));
        ret = wc_PKCS7_Init(&pkcs7->pkcs7, NULL, INVALID_DEVID);
    }

    if (ret != 0 && pkcs7 != NULL) {
        XFREE(pkcs7, NULL, DYNAMIC_TYPE_PKCS7);
        pkcs7 = NULL;
    }

    return (PKCS7*)pkcs7;
}

/******************************************************************************
* wolfSSL_PKCS7_SIGNED_new - allocates PKCS7 and initialize it for a signed data
*
* RETURNS:
* returns pointer to the PKCS7 structure on success, otherwise returns NULL
*/
PKCS7_SIGNED* wolfSSL_PKCS7_SIGNED_new(void)
{
    byte signedData[]= { 0x2A, 0x86, 0x48, 0x86, 0xF7, 0x0D, 0x01, 0x07, 0x02};
    PKCS7* pkcs7 = NULL;

    if ((pkcs7 = wolfSSL_PKCS7_new()) == NULL)
        return NULL;
    pkcs7->contentOID = SIGNED_DATA;
    if ((wc_PKCS7_SetContentType(pkcs7, signedData, sizeof(signedData))) < 0) {
        if (pkcs7) {
            wolfSSL_PKCS7_free(pkcs7);
            return NULL;
        }
    }
    return pkcs7;
}

void wolfSSL_PKCS7_free(PKCS7* pkcs7)
{
    WOLFSSL_PKCS7* p7 = (WOLFSSL_PKCS7*)pkcs7;

    if (p7 != NULL) {
        if (p7->data != NULL)
            XFREE(p7->data, NULL, DYNAMIC_TYPE_PKCS7);
        wc_PKCS7_Free(&p7->pkcs7);
        if (p7->certs)
            wolfSSL_sk_pop_free(p7->certs, NULL);
        XFREE(p7, NULL, DYNAMIC_TYPE_PKCS7);
    }
}

void wolfSSL_PKCS7_SIGNED_free(PKCS7_SIGNED* p7)
{
    wolfSSL_PKCS7_free(p7);
    return;
}

/**
 * Convert DER/ASN.1 encoded signedData structure to internal PKCS7
 * structure. Note, does not support detached content.
 *
 * p7 - pointer to set to address of newly created PKCS7 structure on return
 * in - pointer to pointer of DER/ASN.1 data
 * len - length of input data, bytes
 *
 * Returns newly allocated and populated PKCS7 structure or NULL on error.
 */
PKCS7* wolfSSL_d2i_PKCS7(PKCS7** p7, const unsigned char** in, int len)
{
    return wolfSSL_d2i_PKCS7_ex(p7, in, len, NULL, 0);
}

/*****************************************************************************
* wolfSSL_d2i_PKCS7_ex - Converts the given unsigned char buffer of size len
* into a PKCS7 object.  Optionally, accepts a byte buffer of content which
* is stored as the PKCS7 object's content, to support detached signatures.
* @param content The content which is signed, in case the signature is
*                detached.  Ignored if NULL.
* @param contentSz The size of the passed in content.
*
* RETURNS:
* returns pointer to a PKCS7 structure on success, otherwise returns NULL
*/
PKCS7* wolfSSL_d2i_PKCS7_ex(PKCS7** p7, const unsigned char** in, int len,
        byte* content, word32 contentSz)
{
    WOLFSSL_PKCS7* pkcs7 = NULL;

    WOLFSSL_ENTER("wolfSSL_d2i_PKCS7_ex");

    if (in == NULL || *in == NULL || len < 0)
        return NULL;

    if ((pkcs7 = (WOLFSSL_PKCS7*)wolfSSL_PKCS7_new()) == NULL)
        return NULL;

    pkcs7->len = len;
    pkcs7->data = (byte*)XMALLOC(pkcs7->len, NULL, DYNAMIC_TYPE_PKCS7);
    if (pkcs7->data == NULL) {
        wolfSSL_PKCS7_free((PKCS7*)pkcs7);
        return NULL;
    }
    XMEMCPY(pkcs7->data, *in, pkcs7->len);

    if (content != NULL) {
        pkcs7->pkcs7.content = content;
        pkcs7->pkcs7.contentSz = contentSz;
    }
    if (wc_PKCS7_VerifySignedData(&pkcs7->pkcs7, pkcs7->data, pkcs7->len)
                                                                         != 0) {
        WOLFSSL_MSG("wc_PKCS7_VerifySignedData failed");
        wolfSSL_PKCS7_free((PKCS7*)pkcs7);
        return NULL;
    }

    if (p7 != NULL)
        *p7 = (PKCS7*)pkcs7;
    *in += pkcs7->len;
    return (PKCS7*)pkcs7;
}

/**
 * This API was added as a helper function for libest. It
 * extracts a stack of certificates from the pkcs7 object.
 * @param pkcs7 PKCS7 parameter object
 * @return WOLFSSL_STACK_OF(WOLFSSL_X509)*
 */
WOLFSSL_STACK* wolfSSL_PKCS7_to_stack(PKCS7* pkcs7)
{
    int i;
    WOLFSSL_PKCS7* p7 = (WOLFSSL_PKCS7*)pkcs7;
    WOLF_STACK_OF(WOLFSSL_X509)* ret = NULL;

    WOLFSSL_ENTER("wolfSSL_PKCS7_to_stack");

    if (!p7) {
        WOLFSSL_MSG("Bad parameter");
        return NULL;
    }

    if (p7->certs)
        return p7->certs;

    for (i = 0; i < MAX_PKCS7_CERTS && p7->pkcs7.cert[i]; i++) {
        WOLFSSL_X509* x509 = wolfSSL_X509_d2i(NULL, p7->pkcs7.cert[i],
            p7->pkcs7.certSz[i]);
        if (!ret)
            ret = wolfSSL_sk_X509_new_null();
        if (x509) {
            if (wolfSSL_sk_X509_push(ret, x509) != WOLFSSL_SUCCESS) {
                wolfSSL_X509_free(x509);
                WOLFSSL_MSG("wolfSSL_sk_X509_push error");
                goto error;
            }
        }
        else {
            WOLFSSL_MSG("wolfSSL_X509_d2i error");
            goto error;
        }
    }

    /* Save stack to free later */
    if (p7->certs)
        wolfSSL_sk_pop_free(p7->certs, NULL);
    p7->certs = ret;

    return ret;
error:
    if (ret) {
        wolfSSL_sk_pop_free(ret, NULL);
    }
    return NULL;
}

/**
 * Return stack of signers contained in PKCS7 cert.
 * Notes:
 * - Currently only PKCS#7 messages with a single signer cert is supported.
 * - Returned WOLFSSL_STACK must be freed by caller.
 *
 * pkcs7 - PKCS7 struct to retrieve signer certs from.
 * certs - currently unused
 * flags - flags to control function behavior.
 *
 * Return WOLFSSL_STACK of signers on success, NULL on error.
 */
WOLFSSL_STACK* wolfSSL_PKCS7_get0_signers(PKCS7* pkcs7, WOLFSSL_STACK* certs,
                                          int flags)
{
    WOLFSSL_X509* x509 = NULL;
    WOLFSSL_STACK* signers = NULL;
    WOLFSSL_PKCS7* p7 = (WOLFSSL_PKCS7*)pkcs7;

    if (p7 == NULL)
        return NULL;

    /* Only PKCS#7 messages with a single cert that is the verifying certificate
     * is supported.
     */
    if (flags & PKCS7_NOINTERN) {
        WOLFSSL_MSG("PKCS7_NOINTERN flag not supported");
        return NULL;
    }

    signers = wolfSSL_sk_X509_new_null();
    if (signers == NULL)
        return NULL;

    if (wolfSSL_d2i_X509(&x509, (const byte**)&p7->pkcs7.singleCert,
                         p7->pkcs7.singleCertSz) == NULL) {
        wolfSSL_sk_X509_pop_free(signers, NULL);
        return NULL;
    }

    if (wolfSSL_sk_X509_push(signers, x509) != WOLFSSL_SUCCESS) {
        wolfSSL_sk_X509_pop_free(signers, NULL);
        return NULL;
    }

    (void)certs;

    return signers;
}

#ifndef NO_BIO

PKCS7* wolfSSL_d2i_PKCS7_bio(WOLFSSL_BIO* bio, PKCS7** p7)
{
    WOLFSSL_PKCS7* pkcs7;
    int ret;

    WOLFSSL_ENTER("wolfSSL_d2i_PKCS7_bio");

    if (bio == NULL)
        return NULL;

    if ((pkcs7 = (WOLFSSL_PKCS7*)wolfSSL_PKCS7_new()) == NULL)
        return NULL;

    pkcs7->len = wolfSSL_BIO_get_len(bio);
    pkcs7->data = (byte*)XMALLOC(pkcs7->len, NULL, DYNAMIC_TYPE_PKCS7);
    if (pkcs7->data == NULL) {
        wolfSSL_PKCS7_free((PKCS7*)pkcs7);
        return NULL;
    }

    if ((ret = wolfSSL_BIO_read(bio, pkcs7->data, pkcs7->len)) <= 0) {
        wolfSSL_PKCS7_free((PKCS7*)pkcs7);
        return NULL;
    }
    /* pkcs7->len may change if using b64 for example */
    pkcs7->len = ret;

    if (wc_PKCS7_VerifySignedData(&pkcs7->pkcs7, pkcs7->data, pkcs7->len)
                                                                         != 0) {
        WOLFSSL_MSG("wc_PKCS7_VerifySignedData failed");
        wolfSSL_PKCS7_free((PKCS7*)pkcs7);
        return NULL;
    }

    if (p7 != NULL)
        *p7 = (PKCS7*)pkcs7;
    return (PKCS7*)pkcs7;
}

int wolfSSL_i2d_PKCS7(PKCS7 *p7, unsigned char **out)
{
    byte* output = NULL;
    int localBuf = 0;
    int len;
    WC_RNG rng;
    int ret = WOLFSSL_FAILURE;
    WOLFSSL_ENTER("wolfSSL_i2d_PKCS7");

    if (!out || !p7) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }

    if (!p7->rng) {
        if (wc_InitRng(&rng) != 0) {
            WOLFSSL_MSG("wc_InitRng error");
            return WOLFSSL_FAILURE;
        }
        p7->rng = &rng; // cppcheck-suppress autoVariables
    }

    if ((len = wc_PKCS7_EncodeSignedData(p7, NULL, 0)) < 0) {
        WOLFSSL_MSG("wc_PKCS7_EncodeSignedData error");
        goto cleanup;
    }

    if (*out == NULL) {
        output = (byte*)XMALLOC(len, NULL, DYNAMIC_TYPE_TMP_BUFFER);
        if (!output) {
            WOLFSSL_MSG("malloc error");
            goto cleanup;
        }
        localBuf = 1;
    }
    else {
        output = *out;
    }

    if ((len = wc_PKCS7_EncodeSignedData(p7, output, len)) < 0) {
        WOLFSSL_MSG("wc_PKCS7_EncodeSignedData error");
        goto cleanup;
    }

    ret = len;
cleanup:
    if (p7->rng == &rng) {
        wc_FreeRng(&rng);
        p7->rng = NULL;
    }
    if (ret == WOLFSSL_FAILURE && localBuf && output)
        XFREE(output, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    if (ret != WOLFSSL_FAILURE)
        *out = output;
    return ret;
}

int wolfSSL_i2d_PKCS7_bio(WOLFSSL_BIO *bio, PKCS7 *p7)
{
    byte* output = NULL;
    int len;
    int ret = WOLFSSL_FAILURE;
    WOLFSSL_ENTER("wolfSSL_i2d_PKCS7_bio");

    if (!bio || !p7) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }

    if ((len = wolfSSL_i2d_PKCS7(p7, &output)) == WOLFSSL_FAILURE) {
        WOLFSSL_MSG("wolfSSL_i2d_PKCS7 error");
        goto cleanup;
    }

    if (wolfSSL_BIO_write(bio, output, len) <= 0) {
        WOLFSSL_MSG("wolfSSL_BIO_write error");
        goto cleanup;
    }

    ret = WOLFSSL_SUCCESS;
cleanup:
    if (output)
        XFREE(output, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    return ret;
}

/**
 * Creates and returns a PKCS7 signedData structure.
 *
 * Inner content type is set to DATA to match OpenSSL behavior.
 *
 * signer   - certificate to sign bundle with
 * pkey     - private key matching signer
 * certs    - optional additional set of certificates to include
 * in       - input data to be signed
 * flags    - optional set of flags to control sign behavior
 *
 *    PKCS7_BINARY   - Do not translate input data to MIME canonical
 *                     format (\r\n line endings), thus preventing corruption of
 *                     binary content.
 *    PKCS7_TEXT     - Prepend MIME headers for text/plain to content.
 *    PKCS7_DETACHED - Set signature detached, omit content from output bundle.
 *    PKCS7_STREAM   - initialize PKCS7 struct for signing, do not read data.
 *
 * Flags not currently supported:
 *    PKCS7_NOCERTS  - Do not include the signer cert in the output bundle.
 *    PKCS7_PARTIAL  - Allow for PKCS7_sign() to be only partially set up,
 *                     then signers etc to be added separately before
 *                     calling PKCS7_final().
 *
 * Returns valid PKCS7 structure pointer, or NULL if an error occurred.
 */
PKCS7* wolfSSL_PKCS7_sign(WOLFSSL_X509* signer, WOLFSSL_EVP_PKEY* pkey,
        WOLFSSL_STACK* certs, WOLFSSL_BIO* in, int flags)
{
    int err = 0;
    WOLFSSL_PKCS7* p7 = NULL;
    WOLFSSL_STACK* cert = certs;

    WOLFSSL_ENTER("wolfSSL_PKCS7_sign");

    if (flags & PKCS7_NOCERTS) {
        WOLFSSL_MSG("PKCS7_NOCERTS flag not yet supported");
        err = 1;
    }

    if (flags & PKCS7_PARTIAL) {
        WOLFSSL_MSG("PKCS7_PARTIAL flag not yet supported");
        err = 1;
    }

    if ((err == 0) && (signer == NULL || signer->derCert == NULL ||
                       signer->derCert->length == 0)) {
        WOLFSSL_MSG("Bad function arg, signer is NULL or incomplete");
        err = 1;
    }

    if ((err == 0) && (pkey == NULL || pkey->pkey.ptr == NULL ||
                       pkey->pkey_sz <= 0)) {
        WOLFSSL_MSG("Bad function arg, pkey is NULL or incomplete");
        err = 1;
    }

    if ((err == 0) && (in == NULL) && !(flags & PKCS7_STREAM)) {
        WOLFSSL_MSG("input data required unless PKCS7_STREAM used");
        err = 1;
    }

    if ((err == 0) && ((p7 = (WOLFSSL_PKCS7*)wolfSSL_PKCS7_new()) == NULL)) {
        WOLFSSL_MSG("Error allocating new WOLFSSL_PKCS7");
        err = 1;
    }

    /* load signer certificate */
    if (err == 0) {
        if (wc_PKCS7_InitWithCert(&p7->pkcs7, signer->derCert->buffer,
                                  signer->derCert->length) != 0) {
            WOLFSSL_MSG("Failed to load signer certificate");
            err = 1;
        }
    }

    /* set signer private key, data types, defaults */
    if (err == 0) {
        p7->pkcs7.privateKey = (byte*)pkey->pkey.ptr;
        p7->pkcs7.privateKeySz = pkey->pkey_sz;
        p7->pkcs7.contentOID = DATA;  /* inner content default is DATA */
        p7->pkcs7.hashOID = SHA256h;  /* default to SHA-256 hash type */
        p7->type = SIGNED_DATA;       /* PKCS7_final switches on type */
    }

    /* add additional chain certs if provided */
    while (cert && (err == 0)) {
        if (cert->data.x509 != NULL && cert->data.x509->derCert != NULL) {
            if (wc_PKCS7_AddCertificate(&p7->pkcs7,
                                cert->data.x509->derCert->buffer,
                                cert->data.x509->derCert->length) != 0) {
                WOLFSSL_MSG("Error in wc_PKCS7_AddCertificate");
                err = 1;
            }
        }
        cert = cert->next;
    }

    if ((err == 0) && (flags & PKCS7_DETACHED)) {
        if (wc_PKCS7_SetDetached(&p7->pkcs7, 1) != 0) {
            WOLFSSL_MSG("Failed to set signature detached");
            err = 1;
        }
    }

    if ((err == 0) && (flags & PKCS7_STREAM)) {
        /* if streaming, return before finalizing */
        return (PKCS7*)p7;
    }

    if ((err == 0) && (wolfSSL_PKCS7_final((PKCS7*)p7, in, flags) != 1)) {
        WOLFSSL_MSG("Error calling wolfSSL_PKCS7_final");
        err = 1;
    }

    if ((err != 0) && (p7 != NULL)) {
        wolfSSL_PKCS7_free((PKCS7*)p7);
        p7 = NULL;
    }

    return (PKCS7*)p7;
}

#ifdef HAVE_SMIME

#ifndef MAX_MIME_LINE_LEN
    #define MAX_MIME_LINE_LEN 1024
#endif

/**
 * Copy input BIO to output BIO, but convert all line endings to CRLF (\r\n),
 * used by PKCS7_final().
 *
 * in  - input WOLFSSL_BIO to be converted
 * out - output WOLFSSL_BIO to hold copy of in, with line endings adjusted
 *
 * Return 0 on success, negative on error
 */
static int wolfSSL_BIO_to_MIME_crlf(WOLFSSL_BIO* in, WOLFSSL_BIO* out)
{
    int ret = 0;
    int lineLen = 0;
    word32 canonLineLen = 0;
    char* canonLine = NULL;
#ifdef WOLFSSL_SMALL_STACK
    char* line = NULL;
#else
    char line[MAX_MIME_LINE_LEN];
#endif

    if (in == NULL || out == NULL) {
        return BAD_FUNC_ARG;
    }

#ifdef WOLFSSL_SMALL_STACK
    line = (char*)XMALLOC(MAX_MIME_LINE_LEN, in->heap,
                          DYNAMIC_TYPE_TMP_BUFFER);
    if (line == NULL) {
        return MEMORY_E;
    }
#endif
    XMEMSET(line, 0, MAX_MIME_LINE_LEN);

    while ((lineLen = wolfSSL_BIO_gets(in, line, (int)sizeof(line))) > 0) {

        if (line[lineLen - 1] == '\r' || line[lineLen - 1] == '\n') {
            canonLineLen = (word32)lineLen;
            if ((canonLine = wc_MIME_single_canonicalize(
                                line, &canonLineLen)) == NULL) {
                ret = -1;
                break;
            }

            /* remove trailing null */
            if (canonLine[canonLineLen] == '\0') {
                canonLineLen--;
            }

            if (wolfSSL_BIO_write(out, canonLine, (int)canonLineLen) < 0) {
                ret = -1;
                break;
            }
            XFREE(canonLine, NULL, DYNAMIC_TYPE_PKCS7);
            canonLine = NULL;
        }
        else {
            /* no line ending in current line, write direct to out */
            if (wolfSSL_BIO_write(out, line, lineLen) < 0) {
                ret = -1;
                break;
            }
        }
    }

    if (canonLine != NULL) {
        XFREE(canonLine, NULL, DYNAMIC_TYPE_PKCS7);
    }
#ifdef WOLFSSL_SMALL_STACK
    XFREE(line, in->heap, DYNAMIC_TYPE_TMP_BUFFER);
#endif

    return ret;
}

#endif /* HAVE_SMIME */

/* Used by both PKCS7_final() and PKCS7_verify() */
static const char contTypeText[] = "Content-Type: text/plain\r\n\r\n";

/**
 * Finalize PKCS7 structure, currently supports signedData only.
 *
 * Does not generate final bundle (ie: signedData), but finalizes
 * the PKCS7 structure in preparation for a output function to be called next.
 *
 * pkcs7 - initialized PKCS7 structure, populated with signer, etc
 * in    - input data
 * flags - flags to control PKCS7 behavior. Other flags except those noted
 *         below are ignored:
 *
 *    PKCS7_BINARY - Do not translate input data to MIME canonical
 *                   format (\r\n line endings), thus preventing corruption of
 *                   binary content.
 *    PKCS7_TEXT   - Prepend MIME headers for text/plain to content.
 *
 * Returns 1 on success, 0 on error
 */
int wolfSSL_PKCS7_final(PKCS7* pkcs7, WOLFSSL_BIO* in, int flags)
{
    int ret = 1;
    int memSz = 0;
    unsigned char* mem = NULL;
    WOLFSSL_PKCS7* p7 = (WOLFSSL_PKCS7*)pkcs7;
    WOLFSSL_BIO* data = NULL;

    WOLFSSL_ENTER("wolfSSL_PKCS7_final");

    if (p7 == NULL || in == NULL) {
        WOLFSSL_MSG("Bad input args to PKCS7_final");
        ret = 0;
    }

    if (ret == 1) {
        if ((data = wolfSSL_BIO_new(wolfSSL_BIO_s_mem())) == NULL) {
            WOLFSSL_MSG("Error in wolfSSL_BIO_new");
            ret = 0;
        }
    }

    /* prepend Content-Type header if PKCS7_TEXT */
    if ((ret == 1) && (flags & PKCS7_TEXT)) {
        if (wolfSSL_BIO_write(data, contTypeText,
                              (int)XSTR_SIZEOF(contTypeText)) < 0) {
            WOLFSSL_MSG("Error prepending Content-Type header");
            ret = 0;
        }
    }

    /* convert line endings to CRLF if !PKCS7_BINARY */
    if (ret == 1) {
        if (flags & PKCS7_BINARY) {

            /* no CRLF conversion, direct copy content */
            if ((memSz = wolfSSL_BIO_get_len(in)) <= 0) {
                ret = 0;
            }
            if (ret == 1) {
                mem = (unsigned char*)XMALLOC(memSz, in->heap,
                                              DYNAMIC_TYPE_TMP_BUFFER);
                if (mem == NULL) {
                    WOLFSSL_MSG("Failed to allocate memory for input data");
                    ret = 0;
                }
            }

            if (ret == 1) {
                if (wolfSSL_BIO_read(in, mem, memSz) != memSz) {
                    WOLFSSL_MSG("Error reading from input BIO");
                    ret = 0;
                }
                else if (wolfSSL_BIO_write(data, mem, memSz) < 0) {
                    ret = 0;
                }
            }

            if (mem != NULL) {
                XFREE(mem, in->heap, DYNAMIC_TYPE_TMP_BUFFER);
            }
        }
        else {
    #ifdef HAVE_SMIME
            /* convert content line endings to CRLF */
            if (wolfSSL_BIO_to_MIME_crlf(in, data) != 0) {
                WOLFSSL_MSG("Error converting line endings to CRLF");
                ret = 0;
            }
            else {
                p7->pkcs7.contentCRLF = 1;
            }
    #else
            WOLFSSL_MSG("Without PKCS7_BINARY requires wolfSSL to be built "
                        "with HAVE_SMIME");
            ret = 0;
    #endif
        }
    }

    if ((ret == 1) && ((memSz = wolfSSL_BIO_get_mem_data(data, &mem)) < 0)) {
        WOLFSSL_MSG("Error in wolfSSL_BIO_get_mem_data");
        ret = 0;
    }

    if (ret == 1) {
        if (p7->data != NULL) {
            XFREE(p7->data, NULL, DYNAMIC_TYPE_PKCS7);
        }
        p7->data = (byte*)XMALLOC(memSz, NULL, DYNAMIC_TYPE_PKCS7);
        if (p7->data == NULL) {
            ret = 0;
        }
        else {
            XMEMCPY(p7->data, mem, memSz);
            p7->len = memSz;
        }
    }

    if (ret == 1) {
        p7->pkcs7.content = p7->data;
        p7->pkcs7.contentSz = p7->len;
    }

    if (data != NULL) {
        wolfSSL_BIO_free(data);
    }

    return ret;
}

int wolfSSL_PKCS7_verify(PKCS7* pkcs7, WOLFSSL_STACK* certs,
        WOLFSSL_X509_STORE* store, WOLFSSL_BIO* in, WOLFSSL_BIO* out, int flags)
{
    int i, ret = 0;
    unsigned char* mem = NULL;
    int memSz = 0;
    WOLFSSL_PKCS7* p7 = (WOLFSSL_PKCS7*)pkcs7;
    int contTypeLen;
    WOLFSSL_X509* signer = NULL;
    WOLFSSL_STACK* signers = NULL;

    WOLFSSL_ENTER("wolfSSL_PKCS7_verify");

    if (pkcs7 == NULL)
        return WOLFSSL_FAILURE;

    if (in != NULL) {
        if ((memSz = wolfSSL_BIO_get_mem_data(in, &mem)) < 0)
            return WOLFSSL_FAILURE;

        p7->pkcs7.content = mem;
        p7->pkcs7.contentSz = memSz;
    }

    /* certs is the list of certificates to find the cert with issuer/serial. */
    (void)certs;
    /* store is the certificate store to use to verify signer certificate
     * associated with the signers.
     */
    (void)store;

    ret = wc_PKCS7_VerifySignedData(&p7->pkcs7, p7->data, p7->len);
    if (ret != 0)
        return WOLFSSL_FAILURE;

    if ((flags & PKCS7_NOVERIFY) != PKCS7_NOVERIFY) {
        /* Verify signer certificates */
        if (store == NULL || store->cm == NULL) {
            WOLFSSL_MSG("No store or store certs, but PKCS7_NOVERIFY not set");
            return WOLFSSL_FAILURE;
        }

        signers = wolfSSL_PKCS7_get0_signers(pkcs7, certs, flags);
        if (signers == NULL) {
            WOLFSSL_MSG("No signers found to verify");
            return WOLFSSL_FAILURE;
        }
        for (i = 0; i < wolfSSL_sk_X509_num(signers); i++) {
            signer = wolfSSL_sk_X509_value(signers, i);

            if (wolfSSL_CertManagerVerifyBuffer(store->cm,
                        signer->derCert->buffer,
                        signer->derCert->length,
                        WOLFSSL_FILETYPE_ASN1) != WOLFSSL_SUCCESS) {
                WOLFSSL_MSG("Failed to verify signer certificate");
                wolfSSL_sk_X509_pop_free(signers, NULL);
                return WOLFSSL_FAILURE;
            }
        }
        wolfSSL_sk_X509_pop_free(signers, NULL);
    }

    if (flags & PKCS7_TEXT) {
        /* strip MIME header for text/plain, otherwise error */
        contTypeLen = XSTR_SIZEOF(contTypeText);
        if ((p7->pkcs7.contentSz < (word32)contTypeLen) ||
            (XMEMCMP(p7->pkcs7.content, contTypeText, contTypeLen) != 0)) {
            WOLFSSL_MSG("Error PKCS7 Content-Type not found with PKCS7_TEXT");
            return WOLFSSL_FAILURE;
        }
        p7->pkcs7.content += contTypeLen;
        p7->pkcs7.contentSz -= contTypeLen;
    }

    if (out != NULL) {
        wolfSSL_BIO_write(out, p7->pkcs7.content, p7->pkcs7.contentSz);
    }

    WOLFSSL_LEAVE("wolfSSL_PKCS7_verify", WOLFSSL_SUCCESS);

    return WOLFSSL_SUCCESS;
}

/**
 * This API was added as a helper function for libest. It
 * encodes a stack of certificates to pkcs7 format.
 * @param pkcs7 PKCS7 parameter object
 * @param certs WOLFSSL_STACK_OF(WOLFSSL_X509)*
 * @param out   Output bio
 * @return WOLFSSL_SUCCESS on success and WOLFSSL_FAILURE on failure
 */
int wolfSSL_PKCS7_encode_certs(PKCS7* pkcs7, WOLFSSL_STACK* certs,
        WOLFSSL_BIO* out)
{
    int ret;
    WOLFSSL_PKCS7* p7;
    WOLFSSL_ENTER("wolfSSL_PKCS7_encode_certs");

    if (!pkcs7 || !certs || !out) {
        WOLFSSL_MSG("Bad parameter");
        return WOLFSSL_FAILURE;
    }

    p7 = (WOLFSSL_PKCS7*)pkcs7;

    /* take ownership of certs */
    p7->certs = certs;

    if (pkcs7->certList) {
        WOLFSSL_MSG("wolfSSL_PKCS7_encode_certs called multiple times on same "
                    "struct");
        return WOLFSSL_FAILURE;
    }

    if (certs) {
        /* Save some of the values */
        int hashOID = pkcs7->hashOID;
        byte version = pkcs7->version;

        if (!certs->data.x509 || !certs->data.x509->derCert) {
            WOLFSSL_MSG("Missing cert");
            return WOLFSSL_FAILURE;
        }

        if (wc_PKCS7_InitWithCert(pkcs7, certs->data.x509->derCert->buffer,
                                      certs->data.x509->derCert->length) != 0) {
            WOLFSSL_MSG("wc_PKCS7_InitWithCert error");
            return WOLFSSL_FAILURE;
        }
        certs = certs->next;

        pkcs7->hashOID = hashOID;
        pkcs7->version = version;
    }

    /* Add the certs to the PKCS7 struct */
    while (certs) {
        if (!certs->data.x509 || !certs->data.x509->derCert) {
            WOLFSSL_MSG("Missing cert");
            return WOLFSSL_FAILURE;
        }
        if (wc_PKCS7_AddCertificate(pkcs7, certs->data.x509->derCert->buffer,
                                      certs->data.x509->derCert->length) != 0) {
            WOLFSSL_MSG("wc_PKCS7_AddCertificate error");
            return WOLFSSL_FAILURE;
        }
        certs = certs->next;
    }

    if (wc_PKCS7_SetSignerIdentifierType(pkcs7, DEGENERATE_SID) != 0) {
        WOLFSSL_MSG("wc_PKCS7_SetSignerIdentifierType error");
        return WOLFSSL_FAILURE;
    }

    ret = wolfSSL_i2d_PKCS7_bio(out, pkcs7);

    return ret;
}

/******************************************************************************
* wolfSSL_PEM_write_bio_PKCS7 - writes the PKCS7 data to BIO
*
* RETURNS:
* returns WOLFSSL_SUCCESS on success, otherwise returns WOLFSSL_FAILURE
*/
int wolfSSL_PEM_write_bio_PKCS7(WOLFSSL_BIO* bio, PKCS7* p7)
{
#ifdef WOLFSSL_SMALL_STACK
    byte* outputHead;
    byte* outputFoot;
#else
    byte outputHead[2048];
    byte outputFoot[2048];
#endif
    word32 outputHeadSz = 2048;
    word32 outputFootSz = 2048;
    word32 outputSz = 0;
    byte*  output = NULL;
    byte*  pem = NULL;
    int    pemSz = -1;
    enum wc_HashType hashType;
    byte hashBuf[WC_MAX_DIGEST_SIZE];
    word32 hashSz = -1;

    WOLFSSL_ENTER("wolfSSL_PEM_write_bio_PKCS7()");

    if (bio == NULL || p7 == NULL)
        return WOLFSSL_FAILURE;

#ifdef WOLFSSL_SMALL_STACK
    outputHead = (byte*)XMALLOC(outputHeadSz, bio->heap,
        DYNAMIC_TYPE_TMP_BUFFER);
    if (outputHead == NULL)
        return MEMORY_E;

    outputFoot = (byte*)XMALLOC(outputFootSz, bio->heap,
        DYNAMIC_TYPE_TMP_BUFFER);
    if (outputFoot == NULL)
        goto error;

#endif

    XMEMSET(hashBuf, 0, WC_MAX_DIGEST_SIZE);
    XMEMSET(outputHead, 0, outputHeadSz);
    XMEMSET(outputFoot, 0, outputFootSz);

    hashType = wc_OidGetHash(p7->hashOID);
    hashSz = wc_HashGetDigestSize(hashType);
    if (hashSz > WC_MAX_DIGEST_SIZE)
        return WOLFSSL_FAILURE;

    /* only SIGNED_DATA is supported */
    switch (p7->contentOID) {
        case SIGNED_DATA:
            break;
        default:
            WOLFSSL_MSG("Unknown PKCS#7 Type");
            return WOLFSSL_FAILURE;
    };

    if ((wc_PKCS7_EncodeSignedData_ex(p7, hashBuf, hashSz,
        outputHead, &outputHeadSz, outputFoot, &outputFootSz)) != 0)
        return WOLFSSL_FAILURE;

    outputSz = outputHeadSz + p7->contentSz + outputFootSz;
    output = (byte*)XMALLOC(outputSz, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);

    if (!output)
         return WOLFSSL_FAILURE;

    XMEMSET(output, 0, outputSz);
    outputSz = 0;
    XMEMCPY(&output[outputSz], outputHead, outputHeadSz);
    outputSz += outputHeadSz;
    XMEMCPY(&output[outputSz], p7->content, p7->contentSz);
    outputSz += p7->contentSz;
    XMEMCPY(&output[outputSz], outputFoot, outputFootSz);
    outputSz += outputFootSz;

    /* get PEM size */
    pemSz = wc_DerToPemEx(output, outputSz, NULL, 0, NULL, CERT_TYPE);
    if (pemSz < 0)
        goto error;

    pemSz++; /* for '\0'*/

    /* create PEM buffer and convert from DER to PEM*/
    if ((pem = (byte*)XMALLOC(pemSz, bio->heap, DYNAMIC_TYPE_TMP_BUFFER))
                                                                        == NULL)
        goto error;

    XMEMSET(pem, 0, pemSz);

    if (wc_DerToPemEx(output, outputSz, pem, pemSz, NULL, CERT_TYPE) < 0) {
        goto error;
    }
    if ((wolfSSL_BIO_write(bio, pem, pemSz) == pemSz)) {
        XFREE(output, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
        XFREE(pem, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
#ifdef WOLFSSL_SMALL_STACK
        XFREE(outputHead, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
        XFREE(outputFoot, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
#endif
        return WOLFSSL_SUCCESS;
    }

error:
#ifdef WOLFSSL_SMALL_STACK
    if (outputHead) {
        XFREE(outputHead, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
    }
    if (outputFoot) {
        XFREE(outputFoot, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
    }
#endif
    if (output) {
        XFREE(output, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
    }
    if (pem) {
        XFREE(pem, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
    }
    return WOLFSSL_FAILURE;
}

#ifdef HAVE_SMIME
/*****************************************************************************
* wolfSSL_SMIME_read_PKCS7 - Reads the given S/MIME message and parses it into
* a PKCS7 object. In case of a multipart message, stores the signed data in
* bcont.
*
* RETURNS:
* returns pointer to a PKCS7 structure on success, otherwise returns NULL
*/
PKCS7* wolfSSL_SMIME_read_PKCS7(WOLFSSL_BIO* in,
        WOLFSSL_BIO** bcont)
{
    MimeHdr* allHdrs = NULL;
    MimeHdr* curHdr = NULL;
    MimeParam* curParam = NULL;
    int inLen = 0;
    byte* bcontMem = NULL;
    int bcontMemSz = 0;
    int sectionLen = 0;
    int ret = -1;
    char* section = NULL;
    char* canonLine = NULL;
    char* canonSection = NULL;
    PKCS7* pkcs7 = NULL;
    word32 outLen = 0;
    word32 canonLineLen = 0;
    byte* out = NULL;
    byte* outHead = NULL;

    int canonPos = 0;
    int lineLen = 0;
    int remainLen = 0;
    byte isEnd = 0;
    size_t canonSize = 0;
    size_t boundLen = 0;
    char* boundary = NULL;

    static const char kContType[] = "Content-Type";
    static const char kCTE[] = "Content-Transfer-Encoding";
    static const char kMultSigned[] = "multipart/signed";
    static const char kAppPkcsSign[] = "application/pkcs7-signature";
    static const char kAppXPkcsSign[] = "application/x-pkcs7-signature";
    static const char kAppPkcs7Mime[] = "application/pkcs7-mime";
    static const char kAppXPkcs7Mime[] = "application/x-pkcs7-mime";

    WOLFSSL_ENTER("wolfSSL_SMIME_read_PKCS7");

    if (in == NULL || bcont == NULL) {
        goto error;
    }
    inLen = wolfSSL_BIO_get_len(in);
    if (inLen <= 0) {
        goto error;
    }
    remainLen = wolfSSL_BIO_get_len(in);
    if (remainLen <= 0) {
        goto error;
    }

    section = (char*)XMALLOC(remainLen+1, NULL, DYNAMIC_TYPE_PKCS7);
    if (section == NULL) {
        goto error;
    }
    lineLen = wolfSSL_BIO_gets(in, section, remainLen);
    if (lineLen <= 0) {
        goto error;
    }
    while (isEnd == 0 && remainLen > 0) {
        sectionLen += lineLen;
        remainLen -= lineLen;
        lineLen = wolfSSL_BIO_gets(in, &section[sectionLen], remainLen);
        if (lineLen <= 0) {
            goto error;
        }
        /* Line with just newline signals end of headers. */
        if ((lineLen==2 && !XSTRNCMP(&section[sectionLen],
                                     "\r\n", 2)) ||
            (lineLen==1 && (section[sectionLen] == '\r' ||
                            section[sectionLen] == '\n'))) {
            isEnd = 1;
        }
    }
    section[sectionLen] = '\0';
    ret = wc_MIME_parse_headers(section, sectionLen, &allHdrs);
    if (ret < 0) {
        WOLFSSL_MSG("Parsing MIME headers failed.");
        goto error;
    }
    isEnd = 0;
    section[0] = '\0';
    sectionLen = 0;

    curHdr = wc_MIME_find_header_name(kContType, allHdrs);
    if (curHdr && !XSTRNCMP(curHdr->body, kMultSigned,
                            XSTR_SIZEOF(kMultSigned))) {
        curParam = wc_MIME_find_param_attr("protocol", curHdr->params);
        if (curParam && (!XSTRNCMP(curParam->value, kAppPkcsSign,
                                   XSTR_SIZEOF(kAppPkcsSign)) ||
                         !XSTRNCMP(curParam->value, kAppXPkcsSign,
                                   XSTR_SIZEOF(kAppXPkcsSign)))) {
            curParam = wc_MIME_find_param_attr("boundary", curHdr->params);
            if (curParam == NULL) {
                goto error;
            }

            boundLen = XSTRLEN(curParam->value) + 2;
            boundary = (char*)XMALLOC(boundLen+1, NULL, DYNAMIC_TYPE_PKCS7);
            if (boundary == NULL) {
                goto error;
            }
            XMEMSET(boundary, 0, (word32)(boundLen+1));
            boundary[0] = boundary[1] = '-';
            XSTRNCPY(&boundary[2], curParam->value, boundLen-2);

            /* Parse up to first boundary, ignore everything here. */
            lineLen = wolfSSL_BIO_gets(in, section, remainLen);
            if (lineLen <= 0) {
                goto error;
            }
            while (XSTRNCMP(&section[sectionLen], boundary, boundLen) &&
                   remainLen > 0) {
                sectionLen += lineLen;
                remainLen -= lineLen;
                lineLen = wolfSSL_BIO_gets(in, &section[sectionLen],
                                           remainLen);
                if (lineLen <= 0) {
                    goto error;
                }
            }

            section[0] = '\0';
            sectionLen = 0;
            canonSize = remainLen + 1;
            canonSection = (char*)XMALLOC(canonSize, NULL,
                                          DYNAMIC_TYPE_PKCS7);
            if (canonSection == NULL) {
                goto error;
            }

            lineLen = wolfSSL_BIO_gets(in, section, remainLen);
            while (XSTRNCMP(&section[sectionLen], boundary, boundLen) &&
                            remainLen > 0) {
                canonLineLen = lineLen;
                canonLine = wc_MIME_single_canonicalize(&section[sectionLen],
                                                        &canonLineLen);
                if (canonLine == NULL) {
                    goto error;
                }
                /* If line endings were added, the initial length may be
                 * exceeded. */
                if ((canonPos + canonLineLen) >= canonSize) {
                    canonSize = canonPos + canonLineLen;
                    canonSection = (char*)XREALLOC(canonSection, canonSize,
                                                   NULL, DYNAMIC_TYPE_PKCS7);
                    if (canonSection == NULL) {
                        goto error;
                    }
                }
                XMEMCPY(&canonSection[canonPos], canonLine,
                        (int)canonLineLen - 1);
                canonPos += canonLineLen - 1;
                XFREE(canonLine, NULL, DYNAMIC_TYPE_PKCS7);
                canonLine = NULL;

                sectionLen += lineLen;
                remainLen -= lineLen;

                lineLen = wolfSSL_BIO_gets(in, &section[sectionLen],
                                           remainLen);
                if (lineLen <= 0) {
                    goto error;
                }
            }

            if (canonPos > 0) {
                canonPos--;
            }

            /* Strip the final trailing newline.  Support \r, \n or \r\n. */
            if (canonSection[canonPos] == '\n') {
                if (canonPos > 0) {
                    canonPos--;
                }
            }

            if (canonSection[canonPos] == '\r') {
                if (canonPos > 0) {
                    canonPos--;
                }
            }

            canonSection[canonPos+1] = '\0';

            *bcont = wolfSSL_BIO_new(wolfSSL_BIO_s_mem());
            ret = wolfSSL_BIO_write(*bcont, canonSection,
                                    canonPos + 1);
            if (ret != (canonPos+1)) {
                goto error;
            }
            if ((bcontMemSz = wolfSSL_BIO_get_mem_data(*bcont, &bcontMem))
                                                                          < 0) {
                goto error;
            }
            XFREE(canonSection, NULL, DYNAMIC_TYPE_PKCS7);
            canonSection = NULL;

            wc_MIME_free_hdrs(allHdrs);
            allHdrs = NULL;
            section[0] = '\0';
            sectionLen = 0;
            lineLen = wolfSSL_BIO_gets(in, section, remainLen);
            if (lineLen <= 0) {
                goto error;
            }
            while (isEnd == 0 && remainLen > 0) {
                sectionLen += lineLen;
                remainLen -= lineLen;
                lineLen = wolfSSL_BIO_gets(in, &section[sectionLen],
                                           remainLen);
                if (lineLen <= 0) {
                    goto error;
                }
                /* Line with just newline signals end of headers. */
                if ((lineLen==2 && !XSTRNCMP(&section[sectionLen],
                                             "\r\n", 2)) ||
                    (lineLen==1 && (section[sectionLen] == '\r' ||
                                    section[sectionLen] == '\n'))) {
                    isEnd = 1;
                }
            }
            section[sectionLen] = '\0';
            ret = wc_MIME_parse_headers(section, sectionLen, &allHdrs);
            if (ret < 0) {
                WOLFSSL_MSG("Parsing MIME headers failed.");
                goto error;
            }
            curHdr = wc_MIME_find_header_name(kContType, allHdrs);
            if (curHdr == NULL || (XSTRNCMP(curHdr->body, kAppPkcsSign,
                                   XSTR_SIZEOF(kAppPkcsSign)) &&
                                   XSTRNCMP(curHdr->body, kAppXPkcsSign,
                                   XSTR_SIZEOF(kAppXPkcsSign)))) {
                WOLFSSL_MSG("S/MIME headers not found inside "
                            "multipart message.\n");
                goto error;
            }

            section[0] = '\0';
            sectionLen = 0;
            lineLen = wolfSSL_BIO_gets(in, section, remainLen);
            while (XSTRNCMP(&section[sectionLen], boundary, boundLen) &&
                   remainLen > 0) {
                sectionLen += lineLen;
                remainLen -= lineLen;
                lineLen = wolfSSL_BIO_gets(in, &section[sectionLen],
                                           remainLen);
                if (lineLen <= 0) {
                    goto error;
                }
            }

            XFREE(boundary, NULL, DYNAMIC_TYPE_PKCS7);
            boundary = NULL;
        }
    }
    else if (curHdr && (!XSTRNCMP(curHdr->body, kAppPkcs7Mime,
                                  XSTR_SIZEOF(kAppPkcs7Mime)) ||
                        !XSTRNCMP(curHdr->body, kAppXPkcs7Mime,
                                  XSTR_SIZEOF(kAppXPkcs7Mime)))) {
        sectionLen = wolfSSL_BIO_get_len(in);
        if (sectionLen <= 0) {
            goto error;
        }
        ret = wolfSSL_BIO_read(in, section, sectionLen);
        if (ret < 0 || ret != sectionLen) {
            WOLFSSL_MSG("Error reading input BIO.");
            goto error;
        }
    }
    else {
        WOLFSSL_MSG("S/MIME headers not found.");
        goto error;
    }

    curHdr = wc_MIME_find_header_name(kCTE, allHdrs);
    if (curHdr == NULL) {
        WOLFSSL_MSG("Content-Transfer-Encoding header not found, "
                    "assuming base64 encoding.");
    }
    else if (XSTRNCMP(curHdr->body, "base64", XSTRLEN("base64"))) {
        WOLFSSL_MSG("S/MIME encodings other than base64 are not "
                    "currently supported.\n");
        goto error;
    }

    if (section == NULL || sectionLen <= 0) {
        goto error;
    }
    outLen = ((sectionLen*3+3)/4)+1;
    out = (byte*)XMALLOC(outLen*sizeof(byte), NULL, DYNAMIC_TYPE_PKCS7);
    outHead = out;
    if (outHead == NULL) {
        goto error;
    }
    /* Strip trailing newlines. */
    while ((sectionLen > 0) &&
           (section[sectionLen-1] == '\r' || section[sectionLen-1] == '\n')) {
        sectionLen--;
    }
    section[sectionLen] = '\0';
    ret = Base64_Decode((const byte*)section, sectionLen, out, &outLen);
    if (ret < 0) {
        WOLFSSL_MSG("Error base64 decoding S/MIME message.");
        goto error;
    }
    pkcs7 = wolfSSL_d2i_PKCS7_ex(NULL, (const unsigned char**)&out, outLen,
        bcontMem, bcontMemSz);

    wc_MIME_free_hdrs(allHdrs);
    XFREE(outHead, NULL, DYNAMIC_TYPE_PKCS7);
    XFREE(section, NULL, DYNAMIC_TYPE_PKCS7);

    return pkcs7;

error:
    wc_MIME_free_hdrs(allHdrs);
    XFREE(boundary, NULL, DYNAMIC_TYPE_PKCS7);
    XFREE(outHead, NULL, DYNAMIC_TYPE_PKCS7);
    XFREE(section, NULL, DYNAMIC_TYPE_PKCS7);
    if (canonSection != NULL)
        XFREE(canonSection, NULL, DYNAMIC_TYPE_PKCS7);
    if (bcont) {
        wolfSSL_BIO_free(*bcont);
        *bcont = NULL; /* reset 'bcount' pointer to NULL on failure */
    }

    return NULL;
}

/* Convert hash algo OID (from Hash_Sum in asn.h) to SMIME string equivalent.
 * Returns hash algorithm string or "unknown" if not found */
static const char* wolfSSL_SMIME_HashOIDToString(int hashOID)
{
    switch (hashOID) {
        case MD5h:
            return "md5";
        case SHAh:
            return "sha1";
        case SHA224h:
            return "sha-224";
        case SHA256h:
            return "sha-256";
        case SHA384h:
            return "sha-384";
        case SHA512h:
            return "sha-512";
        case SHA3_224h:
            return "sha3-224";
        case SHA3_384h:
            return "sha3-384";
        case SHA3_512h:
            return "sha3-512";
        default:
            break;
    }

    return "unknown";
}

/* Convert PKCS#7 type (from PKCS7_TYPES in pkcs7.h) to SMIME string.
 * RFC2633 only defines signed-data, enveloped-data, certs-only.
 * Returns string on success, NULL on unknown type. */
static const char* wolfSSL_SMIME_PKCS7TypeToString(int type)
{
    switch (type) {
        case SIGNED_DATA:
            return "signed-data";
        case ENVELOPED_DATA:
            return "enveloped-data";
        default:
            break;
    }

    return NULL;
}

/**
 * Convert PKCS7 structure to SMIME format, adding necessary headers.
 *
 * Handles generation of PKCS7 bundle (ie: signedData). PKCS7 structure
 * should be set up beforehand with PKCS7_sign/final/etc. Output is always
 * Base64 encoded.
 *
 * out   - output BIO for SMIME formatted data to be placed
 * pkcs7 - input PKCS7 structure, initialized and set up
 * in    - input content to be encoded into PKCS7
 * flags - flags to control behavior of PKCS7 generation
 *
 * Returns 1 on success, 0 or negative on failure
 */
int wolfSSL_SMIME_write_PKCS7(WOLFSSL_BIO* out, PKCS7* pkcs7, WOLFSSL_BIO* in,
                              int flags)
{
    int i;
    int ret = 1;
    WOLFSSL_PKCS7* p7 = (WOLFSSL_PKCS7*)pkcs7;
    byte* p7out = NULL;
    int len = 0;

    char boundary[33]; /* 32 chars + \0 */
    byte* sigBase64 = NULL;
    word32 sigBase64Len = 0;
    const char* p7TypeString = NULL;

    static const char alphanum[] = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ";

    if (out == NULL || p7 == NULL) {
        WOLFSSL_MSG("Bad function arguments");
        return 0;
    }

    if (in != NULL && (p7->pkcs7.content == NULL || p7->pkcs7.contentSz == 0 ||
                       p7->pkcs7.contentCRLF == 0)) {
        /* store and adjust content line endings for CRLF if needed */
        if (wolfSSL_PKCS7_final((PKCS7*)p7, in, flags) != 1) {
            ret = 0;
        }
    }

    if (ret > 0) {
        /* Generate signedData bundle, DER in output (dynamic) */
        if ((len = wolfSSL_i2d_PKCS7((PKCS7*)p7, &p7out)) == WOLFSSL_FAILURE) {
            WOLFSSL_MSG("Error in wolfSSL_i2d_PKCS7");
            ret = 0;
        }
    }

    /* Base64 encode signedData bundle */
    if (ret > 0) {
        if (Base64_Encode(p7out, len, NULL, &sigBase64Len) != LENGTH_ONLY_E) {
            ret = 0;
        }
        else {
            sigBase64 = (byte*)XMALLOC(sigBase64Len, NULL,
                                       DYNAMIC_TYPE_TMP_BUFFER);
            if (sigBase64 == NULL) {
                ret = 0;
            }
        }
    }

    if (ret > 0) {
        XMEMSET(sigBase64, 0, sigBase64Len);
        if (Base64_Encode(p7out, len, sigBase64, &sigBase64Len) < 0) {
            WOLFSSL_MSG("Error in Base64_Encode of signature");
            ret = 0;
        }
    }

    /* build up SMIME message */
    if (ret > 0) {
        if (flags & PKCS7_DETACHED) {

            /* generate random boundary */
            if (initGlobalRNG == 0 && wolfSSL_RAND_Init() != WOLFSSL_SUCCESS) {
                WOLFSSL_MSG("No RNG to use");
                ret = 0;
            }

            /* no need to generate random byte for null terminator (size-1) */
            if ((ret > 0) && (wc_RNG_GenerateBlock(&globalRNG, (byte*)boundary,
                                  sizeof(boundary) - 1 ) != 0)) {
                    WOLFSSL_MSG("Error in wc_RNG_GenerateBlock");
                    ret = 0;
            }

            if (ret > 0) {
                for (i = 0; i < (int)sizeof(boundary) - 1; i++) {
                    boundary[i] =
                        alphanum[boundary[i] % XSTR_SIZEOF(alphanum)];
                }
                boundary[sizeof(boundary)-1] = 0;
            }

            if (ret > 0) {
                /* S/MIME header beginning */
                ret = wolfSSL_BIO_printf(out,
                        "MIME-Version: 1.0\n"
                        "Content-Type: multipart/signed; "
                        "protocol=\"application/x-pkcs7-signature\"; "
                        "micalg=\"%s\"; "
                        "boundary=\"----%s\"\n\n"
                        "This is an S/MIME signed message\n\n"
                        "------%s\n",
                        wolfSSL_SMIME_HashOIDToString(p7->pkcs7.hashOID),
                        boundary, boundary);
            }

            if (ret > 0) {
                /* S/MIME content */
                ret = wolfSSL_BIO_write(out,
                        p7->pkcs7.content, p7->pkcs7.contentSz);
            }

            if (ret > 0) {
                /* S/SMIME header end boundary */
                ret = wolfSSL_BIO_printf(out,
                        "\n------%s\n", boundary);
            }

            if (ret > 0) {
                /* Signature and header */
                ret = wolfSSL_BIO_printf(out,
                        "Content-Type: application/x-pkcs7-signature; "
                        "name=\"smime.p7s\"\n"
                        "Content-Transfer-Encoding: base64\n"
                        "Content-Disposition: attachment; "
                        "filename=\"smime.p7s\"\n\n"
                        "%.*s\n" /* Base64 encoded signature */
                        "------%s--\n\n",
                        sigBase64Len, sigBase64,
                        boundary);
            }
        }
        else {
            p7TypeString = wolfSSL_SMIME_PKCS7TypeToString(p7->type);
            if (p7TypeString == NULL) {
                WOLFSSL_MSG("Unsupported PKCS7 SMIME type");
                ret = 0;
            }

            if (ret > 0) {
                /* not detached */
                ret = wolfSSL_BIO_printf(out,
                        "MIME-Version: 1.0\n"
                        "Content-Disposition: attachment; "
                        "filename=\"smime.p7m\"\n"
                        "Content-Type: application/x-pkcs7-mime; "
                        "smime-type=%s; name=\"smime.p7m\"\n"
                        "Content-Transfer-Encoding: base64\n\n"
                        "%.*s\n" /* signature */,
                        p7TypeString, sigBase64Len, sigBase64);
            }
        }
    }

    if (p7out != NULL) {
        XFREE(p7out, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    }
    if (sigBase64 != NULL) {
        XFREE(sigBase64, NULL, DYNAMIC_TYPE_TMP_BUFFER);
    }

    if (ret > 0) {
        return WOLFSSL_SUCCESS;
    }

    return WOLFSSL_FAILURE;
}

#endif /* HAVE_SMIME */
#endif /* !NO_BIO */
#endif /* OPENSSL_ALL */

#endif /* HAVE_PKCS7 */
/*******************************************************************************
 * END OF PKCS7 APIs
 ******************************************************************************/

/*******************************************************************************
 * START OF PKCS12 APIs
 ******************************************************************************/
#ifdef OPENSSL_EXTRA

/* no-op function. Was initially used for adding encryption algorithms available
 * for PKCS12 */
void wolfSSL_PKCS12_PBE_add(void)
{
    WOLFSSL_ENTER("wolfSSL_PKCS12_PBE_add");
}

#if !defined(NO_FILESYSTEM)
WOLFSSL_X509_PKCS12 *wolfSSL_d2i_PKCS12_fp(XFILE fp,
        WOLFSSL_X509_PKCS12 **pkcs12)
{
    WOLFSSL_ENTER("wolfSSL_d2i_PKCS12_fp");
    return (WOLFSSL_X509_PKCS12 *)wolfSSL_d2i_X509_fp_ex(fp, (void **)pkcs12,
        PKCS12_TYPE);
}
#endif /* !NO_FILESYSTEM */

#endif /* OPENSSL_EXTRA */

#if defined(HAVE_PKCS12)

#ifdef OPENSSL_EXTRA

#if !defined(NO_ASN) && !defined(NO_PWDBASED)

#ifndef NO_BIO
WC_PKCS12* wolfSSL_d2i_PKCS12_bio(WOLFSSL_BIO* bio, WC_PKCS12** pkcs12)
{
    WC_PKCS12* localPkcs12 = NULL;
    unsigned char* mem = NULL;
    long memSz;
    int ret = -1;

    WOLFSSL_ENTER("wolfSSL_d2i_PKCS12_bio");

    if (bio == NULL) {
        WOLFSSL_MSG("Bad Function Argument bio is NULL");
        return NULL;
    }

    memSz = wolfSSL_BIO_get_len(bio);
    if (memSz <= 0) {
        return NULL;
    }
    mem = (unsigned char*)XMALLOC(memSz, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
    if (mem == NULL) {
        return NULL;
    }

    if (mem != NULL) {
        localPkcs12 = wc_PKCS12_new();
        if (localPkcs12 == NULL) {
            WOLFSSL_MSG("Memory error");
        }
    }

    if (mem != NULL && localPkcs12 != NULL) {
        if (wolfSSL_BIO_read(bio, mem, (int)memSz) == memSz) {
            ret = wc_d2i_PKCS12(mem, (word32)memSz, localPkcs12);
            if (ret < 0) {
                WOLFSSL_MSG("Failed to get PKCS12 sequence");
            }
        }
        else {
            WOLFSSL_MSG("Failed to get data from bio struct");
        }
    }

    /* cleanup */
    if (mem != NULL)
        XFREE(mem, bio->heap, DYNAMIC_TYPE_TMP_BUFFER);
    if (ret < 0 && localPkcs12 != NULL) {
        wc_PKCS12_free(localPkcs12);
        localPkcs12 = NULL;
    }
    if (pkcs12 != NULL)
        *pkcs12 = localPkcs12;

    return localPkcs12;
}

/* Converts the PKCS12 to DER format and outputs it into bio.
 *
 * bio is the structure to hold output DER
 * pkcs12 structure to create DER from
 *
 * return 1 for success or 0 if an error occurs
 */
int wolfSSL_i2d_PKCS12_bio(WOLFSSL_BIO *bio, WC_PKCS12 *pkcs12)
{
    int ret = WOLFSSL_FAILURE;

    WOLFSSL_ENTER("wolfSSL_i2d_PKCS12_bio");

    if ((bio != NULL) && (pkcs12 != NULL)) {
        word32 certSz = 0;
        byte *certDer = NULL;

        certSz = wc_i2d_PKCS12(pkcs12, &certDer, NULL);
        if ((certSz > 0) && (certDer != NULL)) {
            if (wolfSSL_BIO_write(bio, certDer, certSz) == (int)certSz) {
                ret = WOLFSSL_SUCCESS;
            }
        }

        if (certDer != NULL) {
            XFREE(certDer, NULL, DYNAMIC_TYPE_PKCS);
        }
    }

    return ret;
}
#endif /* !NO_BIO */

/* Creates a new WC_PKCS12 structure
 *
 * pass  password to use
 * name  friendlyName to use
 * pkey  private key to go into PKCS12 bundle
 * cert  certificate to go into PKCS12 bundle
 * ca    extra certificates that can be added to bundle. Can be NULL
 * keyNID  type of encryption to use on the key (-1 means no encryption)
 * certNID type of encryption to use on the certificate
 * itt     number of iterations with encryption
 * macItt  number of iterations with mac creation
 * keyType flag for signature and/or encryption key
 *
 * returns a pointer to a new WC_PKCS12 structure on success and NULL on fail
 */
WC_PKCS12* wolfSSL_PKCS12_create(char* pass, char* name, WOLFSSL_EVP_PKEY* pkey,
        WOLFSSL_X509* cert, WOLF_STACK_OF(WOLFSSL_X509)* ca, int keyNID,
        int certNID, int itt, int macItt, int keyType)
{
    WC_PKCS12* pkcs12;
    WC_DerCertList* list = NULL;
    word32 passSz;
    byte* keyDer = NULL;
    word32 keyDerSz;
    byte* certDer;
    int certDerSz;

    WOLFSSL_ENTER("wolfSSL_PKCS12_create()");

    if (pass == NULL || pkey == NULL || cert == NULL) {
        WOLFSSL_LEAVE("wolfSSL_PKCS12_create()", BAD_FUNC_ARG);
        return NULL;
    }
    passSz = (word32)XSTRLEN(pass);

    keyDer = (byte*)pkey->pkey.ptr;
    keyDerSz = pkey->pkey_sz;

    certDer = (byte*)wolfSSL_X509_get_der(cert, &certDerSz);
    if (certDer == NULL) {
        return NULL;
    }

    if (ca != NULL) {
        WC_DerCertList* cur;
        unsigned long numCerts = ca->num;
        byte* curDer;
        int   curDerSz = 0;
        WOLFSSL_STACK* sk = ca;

        while (numCerts > 0 && sk != NULL) {
            cur = (WC_DerCertList*)XMALLOC(sizeof(WC_DerCertList), NULL,
                    DYNAMIC_TYPE_PKCS);
            if (cur == NULL) {
                wc_FreeCertList(list, NULL);
                return NULL;
            }

            curDer = (byte*)wolfSSL_X509_get_der(sk->data.x509, &curDerSz);
            if (curDer == NULL || curDerSz < 0) {
                XFREE(cur, NULL, DYNAMIC_TYPE_PKCS);
                wc_FreeCertList(list, NULL);
                return NULL;
            }

            cur->buffer = (byte*)XMALLOC(curDerSz, NULL, DYNAMIC_TYPE_PKCS);
            if (cur->buffer == NULL) {
                XFREE(cur, NULL, DYNAMIC_TYPE_PKCS);
                wc_FreeCertList(list, NULL);
                return NULL;
            }
            XMEMCPY(cur->buffer, curDer, curDerSz);
            cur->bufferSz = curDerSz;
            cur->next = list;
            list = cur;

            sk = sk->next;
            numCerts--;
        }
    }

    pkcs12 = wc_PKCS12_create(pass, passSz, name, keyDer, keyDerSz,
            certDer, certDerSz, list, keyNID, certNID, itt, macItt,
            keyType, NULL);

    if (ca != NULL) {
        wc_FreeCertList(list, NULL);
    }

    return pkcs12;
}


/* return WOLFSSL_SUCCESS on success, WOLFSSL_FAILURE on failure */
int wolfSSL_PKCS12_parse(WC_PKCS12* pkcs12, const char* psw,
          WOLFSSL_EVP_PKEY** pkey, WOLFSSL_X509** cert,
          WOLF_STACK_OF(WOLFSSL_X509)** ca)
{
    void* heap = NULL;
    int ret;
    byte* certData = NULL;
    word32 certDataSz;
    byte* pk = NULL;
    word32 pkSz;
    WC_DerCertList* certList = NULL;
#ifdef WOLFSSL_SMALL_STACK
    DecodedCert *DeCert;
#else
    DecodedCert DeCert[1];
#endif

    WOLFSSL_ENTER("wolfSSL_PKCS12_parse");

    /* make sure we init return args */
    if (pkey) *pkey = NULL;
    if (cert) *cert = NULL;
    if (ca)   *ca = NULL;

    if (pkcs12 == NULL || psw == NULL || pkey == NULL || cert == NULL) {
        WOLFSSL_MSG("Bad argument value");
        return WOLFSSL_FAILURE;
    }

    heap  = wc_PKCS12_GetHeap(pkcs12);

    if (ca == NULL) {
        ret = wc_PKCS12_parse(pkcs12, psw, &pk, &pkSz, &certData, &certDataSz,
            NULL);
    }
    else {
        ret = wc_PKCS12_parse(pkcs12, psw, &pk, &pkSz, &certData, &certDataSz,
            &certList);
    }
    if (ret < 0) {
        WOLFSSL_LEAVE("wolfSSL_PKCS12_parse", ret);
        return WOLFSSL_FAILURE;
    }

#ifdef WOLFSSL_SMALL_STACK
    DeCert = (DecodedCert *)XMALLOC(sizeof(*DeCert), heap,
                                    DYNAMIC_TYPE_DCERT);
    if (DeCert == NULL) {
        WOLFSSL_MSG("out of memory");
        return WOLFSSL_FAILURE;
    }
#endif

    /* Decode cert and place in X509 stack struct */
    if (certList != NULL) {
        WC_DerCertList* current = certList;

        *ca = (WOLF_STACK_OF(WOLFSSL_X509)*)XMALLOC(
            sizeof(WOLF_STACK_OF(WOLFSSL_X509)), heap, DYNAMIC_TYPE_X509);
        if (*ca == NULL) {
            if (pk != NULL) {
                XFREE(pk, heap, DYNAMIC_TYPE_PUBLIC_KEY);
            }
            if (certData != NULL) {
                XFREE(*cert, heap, DYNAMIC_TYPE_PKCS); *cert = NULL;
            }
            /* Free up WC_DerCertList and move on */
            while (current != NULL) {
                WC_DerCertList* next = current->next;

                XFREE(current->buffer, heap, DYNAMIC_TYPE_PKCS);
                XFREE(current, heap, DYNAMIC_TYPE_PKCS);
                current = next;
            }
            ret = WOLFSSL_FAILURE;
            goto out;
        }
        XMEMSET(*ca, 0, sizeof(WOLF_STACK_OF(WOLFSSL_X509)));

        /* add list of DER certs as X509's to stack */
        while (current != NULL) {
            WC_DerCertList*  toFree = current;
            WOLFSSL_X509* x509;

            x509 = (WOLFSSL_X509*)XMALLOC(sizeof(WOLFSSL_X509), heap,
                DYNAMIC_TYPE_X509);
            InitX509(x509, 1, heap);
            InitDecodedCert(DeCert, current->buffer, current->bufferSz, heap);
            if (ParseCertRelative(DeCert, CERT_TYPE, NO_VERIFY, NULL) != 0) {
                WOLFSSL_MSG("Issue with parsing certificate");
                FreeDecodedCert(DeCert);
                wolfSSL_X509_free(x509);
            }
            else {
                if (CopyDecodedToX509(x509, DeCert) != 0) {
                    WOLFSSL_MSG("Failed to copy decoded cert");
                    FreeDecodedCert(DeCert);
                    wolfSSL_X509_free(x509);
                    wolfSSL_sk_X509_pop_free(*ca, NULL); *ca = NULL;
                    if (pk != NULL) {
                        XFREE(pk, heap, DYNAMIC_TYPE_PUBLIC_KEY);
                    }
                    if (certData != NULL) {
                        XFREE(certData, heap, DYNAMIC_TYPE_PKCS);
                    }
                    /* Free up WC_DerCertList */
                    while (current != NULL) {
                        WC_DerCertList* next = current->next;

                        XFREE(current->buffer, heap, DYNAMIC_TYPE_PKCS);
                        XFREE(current, heap, DYNAMIC_TYPE_PKCS);
                        current = next;
                    }
                    ret = WOLFSSL_FAILURE;
                    goto out;
                }
                FreeDecodedCert(DeCert);

                if (wolfSSL_sk_X509_push(*ca, x509) != 1) {
                    WOLFSSL_MSG("Failed to push x509 onto stack");
                    wolfSSL_X509_free(x509);
                    wolfSSL_sk_X509_pop_free(*ca, NULL); *ca = NULL;
                    if (pk != NULL) {
                        XFREE(pk, heap, DYNAMIC_TYPE_PUBLIC_KEY);
                    }
                    if (certData != NULL) {
                        XFREE(certData, heap, DYNAMIC_TYPE_PKCS);
                    }

                    /* Free up WC_DerCertList */
                    while (current != NULL) {
                        WC_DerCertList* next = current->next;

                        XFREE(current->buffer, heap, DYNAMIC_TYPE_PKCS);
                        XFREE(current, heap, DYNAMIC_TYPE_PKCS);
                        current = next;
                    }
                    ret = WOLFSSL_FAILURE;
                    goto out;
                }
            }
            current = current->next;
            XFREE(toFree->buffer, heap, DYNAMIC_TYPE_PKCS);
            XFREE(toFree, heap, DYNAMIC_TYPE_PKCS);
        }
    }


    /* Decode cert and place in X509 struct */
    if (certData != NULL) {
        *cert = (WOLFSSL_X509*)XMALLOC(sizeof(WOLFSSL_X509), heap,
            DYNAMIC_TYPE_X509);
        if (*cert == NULL) {
            if (pk != NULL) {
                XFREE(pk, heap, DYNAMIC_TYPE_PUBLIC_KEY);
            }
            if (ca != NULL) {
                wolfSSL_sk_X509_pop_free(*ca, NULL); *ca = NULL;
            }
            XFREE(certData, heap, DYNAMIC_TYPE_PKCS);
            ret = WOLFSSL_FAILURE;
            goto out;
        }
        InitX509(*cert, 1, heap);
        InitDecodedCert(DeCert, certData, certDataSz, heap);
        if (ParseCertRelative(DeCert, CERT_TYPE, NO_VERIFY, NULL) != 0) {
            WOLFSSL_MSG("Issue with parsing certificate");
        }
        if (CopyDecodedToX509(*cert, DeCert) != 0) {
            WOLFSSL_MSG("Failed to copy decoded cert");
            FreeDecodedCert(DeCert);
            if (pk != NULL) {
                XFREE(pk, heap, DYNAMIC_TYPE_PUBLIC_KEY);
            }
            if (ca != NULL) {
                wolfSSL_sk_X509_pop_free(*ca, NULL); *ca = NULL;
            }
            wolfSSL_X509_free(*cert); *cert = NULL;
            ret = WOLFSSL_FAILURE;
            goto out;
        }
        FreeDecodedCert(DeCert);
        XFREE(certData, heap, DYNAMIC_TYPE_PKCS);
    }


    /* get key type */
    ret = BAD_STATE_E;
    if (pk != NULL) { /* decode key if present */
        *pkey = wolfSSL_EVP_PKEY_new_ex(heap);
        if (*pkey == NULL) {
            wolfSSL_X509_free(*cert); *cert = NULL;
            if (ca != NULL) {
                wolfSSL_sk_X509_pop_free(*ca, NULL); *ca = NULL;
            }
            XFREE(pk, heap, DYNAMIC_TYPE_PUBLIC_KEY);
            ret = WOLFSSL_FAILURE;
            goto out;
        }

    #ifndef NO_RSA
        {
            const unsigned char* pt = pk;
            if (wolfSSL_d2i_PrivateKey(EVP_PKEY_RSA, pkey, &pt, pkSz) !=
                    NULL) {
                ret = 0;
            }
        }
    #endif /* NO_RSA */

    #ifdef HAVE_ECC
        if (ret != 0) { /* if is in fail state check if ECC key */
            const unsigned char* pt = pk;
            if (wolfSSL_d2i_PrivateKey(EVP_PKEY_EC, pkey, &pt, pkSz) !=
                    NULL) {
                ret = 0;
            }
        }
    #endif /* HAVE_ECC */
        if (pk != NULL)
            XFREE(pk, heap, DYNAMIC_TYPE_PKCS);
        if (ret != 0) { /* if is in fail state and no PKEY then fail */
            wolfSSL_X509_free(*cert); *cert = NULL;
            if (ca != NULL) {
                wolfSSL_sk_X509_pop_free(*ca, NULL); *ca = NULL;
            }
            wolfSSL_EVP_PKEY_free(*pkey); *pkey = NULL;
            WOLFSSL_MSG("Bad PKCS12 key format");
            ret = WOLFSSL_FAILURE;
            goto out;
        }

        if (pkey != NULL && *pkey != NULL) {
            (*pkey)->save_type = 0;
        }
    }

    (void)ret;
    (void)ca;

    ret = WOLFSSL_SUCCESS;

out:

#ifdef WOLFSSL_SMALL_STACK
    XFREE(DeCert, heap, DYNAMIC_TYPE_DCERT);
#endif

    return ret;
}

int wolfSSL_PKCS12_verify_mac(WC_PKCS12 *pkcs12, const char *psw,
        int pswLen)
{
    WOLFSSL_ENTER("wolfSSL_PKCS12_verify_mac");

    if (!pkcs12) {
        return WOLFSSL_FAILURE;
    }

    return wc_PKCS12_verify_ex(pkcs12, (const byte*)psw, pswLen) == 0 ?
            WOLFSSL_SUCCESS : WOLFSSL_FAILURE;
}

#endif /* !NO_ASN && !NO_PWDBASED */

#endif /* OPENSSL_EXTRA */

#endif /* HAVE_PKCS12 */
/*******************************************************************************
 * END OF PKCS12 APIs
 ******************************************************************************/

#endif /* !NO_CERTS */


/*******************************************************************************
 * BEGIN OPENSSL FIPS DRBG APIs
 ******************************************************************************/
#if defined(OPENSSL_EXTRA) && !defined(WC_NO_RNG) && defined(HAVE_HASHDRBG)
int wolfSSL_FIPS_drbg_init(WOLFSSL_DRBG_CTX *ctx, int type, unsigned int flags)
{
    int ret = WOLFSSL_FAILURE;
    if (ctx != NULL) {
        XMEMSET(ctx, 0, sizeof(WOLFSSL_DRBG_CTX));
        ctx->type = type;
        ctx->xflags = flags;
        ctx->status = DRBG_STATUS_UNINITIALISED;
        ret = WOLFSSL_SUCCESS;
    }
    return ret;
}
WOLFSSL_DRBG_CTX* wolfSSL_FIPS_drbg_new(int type, unsigned int flags)
{
    int ret = WOLFSSL_FAILURE;
    WOLFSSL_DRBG_CTX* ctx = (WOLFSSL_DRBG_CTX*)XMALLOC(sizeof(WOLFSSL_DRBG_CTX),
        NULL, DYNAMIC_TYPE_OPENSSL);
    ret = wolfSSL_FIPS_drbg_init(ctx, type, flags);
    if (ret == WOLFSSL_SUCCESS && type != 0) {
        ret = wolfSSL_FIPS_drbg_instantiate(ctx, NULL, 0);
    }
    if (ret != WOLFSSL_SUCCESS) {
        WOLFSSL_ERROR(ret);
        wolfSSL_FIPS_drbg_free(ctx);
        ctx = NULL;
    }
    return ctx;
}
int wolfSSL_FIPS_drbg_instantiate(WOLFSSL_DRBG_CTX* ctx,
    const unsigned char* pers, size_t perslen)
{
    int ret = WOLFSSL_FAILURE;
    if (ctx != NULL && ctx->rng == NULL) {
    #if !defined(HAVE_SELFTEST) && (!defined(HAVE_FIPS) || \
        (defined(HAVE_FIPS) && FIPS_VERSION_GE(5,0)))
        ctx->rng = wc_rng_new((byte*)pers, (word32)perslen, NULL);
    #else
        ctx->rng = (WC_RNG*)XMALLOC(sizeof(WC_RNG), NULL, DYNAMIC_TYPE_RNG);
        if (ctx->rng != NULL) {
        #if defined(HAVE_FIPS) && FIPS_VERSION_GE(2,0)
            ret = wc_InitRngNonce(ctx->rng, (byte*)pers, (word32)perslen);
        #else
            ret = wc_InitRng(ctx->rng);
            (void)pers;
            (void)perslen;
        #endif
            if (ret != 0) {
                WOLFSSL_ERROR(ret);
                XFREE(ctx->rng, NULL, DYNAMIC_TYPE_RNG);
                ctx->rng = NULL;
            }
        }
    #endif
    }
    if (ctx != NULL && ctx->rng != NULL) {
        ctx->status = DRBG_STATUS_READY;
        ret = WOLFSSL_SUCCESS;
    }
    return ret;
}
int wolfSSL_FIPS_drbg_set_callbacks(WOLFSSL_DRBG_CTX* ctx,
    drbg_entropy_get entropy_get, drbg_entropy_clean entropy_clean,
    size_t entropy_blocklen,
    drbg_nonce_get none_get, drbg_nonce_clean nonce_clean)
{
    int ret = WOLFSSL_FAILURE;
    if (ctx != NULL) {
        ctx->entropy_get = entropy_get;
        ctx->entropy_clean = entropy_clean;
        ctx->entropy_blocklen = entropy_blocklen;
        ctx->none_get = none_get;
        ctx->nonce_clean = nonce_clean;
        ret = WOLFSSL_SUCCESS;
    }
    return ret;
}
void wolfSSL_FIPS_rand_add(const void* buf, int num, double entropy)
{
    /* not implemented */
    (void)buf;
    (void)num;
    (void)entropy;
}
int wolfSSL_FIPS_drbg_reseed(WOLFSSL_DRBG_CTX* ctx, const unsigned char* adin,
    size_t adinlen)
{
    int ret = WOLFSSL_FAILURE;
    if (ctx != NULL && ctx->rng != NULL) {
    #if !defined(HAVE_SELFTEST) && (!defined(HAVE_FIPS) || \
        (defined(HAVE_FIPS) && FIPS_VERSION_GE(2,0)))
        if (wc_RNG_DRBG_Reseed(ctx->rng, adin, (word32)adinlen) == 0) {
            ret = WOLFSSL_SUCCESS;
        }
    #else
        ret = WOLFSSL_SUCCESS;
        (void)adin;
        (void)adinlen;
    #endif
    }
    return ret;
}
int wolfSSL_FIPS_drbg_generate(WOLFSSL_DRBG_CTX* ctx, unsigned char* out,
    size_t outlen, int prediction_resistance, const unsigned char* adin,
    size_t adinlen)
{
    int ret = WOLFSSL_FAILURE;
    if (ctx != NULL && ctx->rng != NULL) {
        ret = wc_RNG_GenerateBlock(ctx->rng, out, (word32)outlen);
        if (ret == 0) {
            ret = WOLFSSL_SUCCESS;
        }
    }
    (void)prediction_resistance;
    (void)adin;
    (void)adinlen;
    return ret;
}
int wolfSSL_FIPS_drbg_uninstantiate(WOLFSSL_DRBG_CTX *ctx)
{
    if (ctx != NULL && ctx->rng != NULL) {
    #if !defined(HAVE_SELFTEST) && (!defined(HAVE_FIPS) || \
        (defined(HAVE_FIPS) && FIPS_VERSION_GE(5,0)))
        wc_rng_free(ctx->rng);
    #else
        wc_FreeRng(ctx->rng);
        XFREE(ctx->rng, NULL, DYNAMIC_TYPE_RNG);
    #endif
        ctx->rng = NULL;
        ctx->status = DRBG_STATUS_UNINITIALISED;
    }
    return WOLFSSL_SUCCESS;
}
void wolfSSL_FIPS_drbg_free(WOLFSSL_DRBG_CTX *ctx)
{
    if (ctx != NULL) {
        /* As saftey check if free'ing the default drbg, then mark global NULL.
         * Technically the user should not call free on the default drbg. */
        if (ctx == gDrbgDefCtx) {
            gDrbgDefCtx = NULL;
        }
        wolfSSL_FIPS_drbg_uninstantiate(ctx);
        XFREE(ctx, NULL, DYNAMIC_TYPE_OPENSSL);
    }
}
WOLFSSL_DRBG_CTX* wolfSSL_FIPS_get_default_drbg(void)
{
    if (gDrbgDefCtx == NULL) {
        gDrbgDefCtx = wolfSSL_FIPS_drbg_new(0, 0);
    }
    return gDrbgDefCtx;
}
void wolfSSL_FIPS_get_timevec(unsigned char* buf, unsigned long* pctr)
{
    /* not implemented */
    (void)buf;
    (void)pctr;
}
void* wolfSSL_FIPS_drbg_get_app_data(WOLFSSL_DRBG_CTX *ctx)
{
    if (ctx != NULL) {
        return ctx->app_data;
    }
    return NULL;
}
void wolfSSL_FIPS_drbg_set_app_data(WOLFSSL_DRBG_CTX *ctx, void *app_data)
{
    if (ctx != NULL) {
        ctx->app_data = app_data;
    }
}
#endif
/*******************************************************************************
 * END OF OPENSSL FIPS DRBG APIs
 ******************************************************************************/


#endif /* !WOLFCRYPT_ONLY */

/*******************************************************************************
 * START OF CRYPTO-ONLY APIs
 ******************************************************************************/

#if defined(OPENSSL_EXTRA) || defined(HAVE_LIGHTY) || \
    defined(WOLFSSL_MYSQL_COMPATIBLE) || defined(HAVE_STUNNEL) || \
    defined(WOLFSSL_NGINX) || defined(HAVE_POCO_LIB) || \
    defined(WOLFSSL_HAPROXY)

#ifndef NO_SHA
    /* One shot SHA1 hash of message.
     *
     * d  message to hash
     * n  size of d buffer
     * md buffer to hold digest. Should be SHA_DIGEST_SIZE.
     *
     * Note: if md is null then a static buffer of SHA_DIGEST_SIZE is used.
     *       When the static buffer is used this function is not thread safe.
     *
     * Returns a pointer to the message digest on success and NULL on failure.
     */
    unsigned char *wolfSSL_SHA1(const unsigned char *d, size_t n,
            unsigned char *md)
    {
        static byte dig[WC_SHA_DIGEST_SIZE];
        byte* ret = md;
        wc_Sha sha;

        WOLFSSL_ENTER("wolfSSL_SHA1");

        if (wc_InitSha_ex(&sha, NULL, INVALID_DEVID) != 0) {
            WOLFSSL_MSG("SHA1 Init failed");
            return NULL;
        }

        if (wc_ShaUpdate(&sha, (const byte*)d, (word32)n) != 0) {
            WOLFSSL_MSG("SHA1 Update failed");
            return NULL;
        }

        if (md == NULL) {
            WOLFSSL_MSG("STATIC BUFFER BEING USED. wolfSSL_SHA1 IS NOT "
                        "THREAD SAFE WHEN md == NULL");
            ret = dig;
        }
        if (wc_ShaFinal(&sha, ret) != 0) {
            WOLFSSL_MSG("SHA1 Final failed");
            wc_ShaFree(&sha);
            return NULL;
        }
        wc_ShaFree(&sha);

        return ret;
    }
#endif /* ! NO_SHA */

#ifdef WOLFSSL_SHA224
    /* One shot SHA224 hash of message.
     *
     * d  message to hash
     * n  size of d buffer
     * md buffer to hold digest. Should be WC_SHA224_DIGEST_SIZE.
     *
     * Note: if md is null then a static buffer of WC_SHA256_DIGEST_SIZE is used.
     *       When the static buffer is used this function is not thread safe.
     *
     * Returns a pointer to the message digest on success and NULL on failure.
     */
      unsigned char *wolfSSL_SHA224(const unsigned char *d, size_t n,
            unsigned char *md)
     {
        static byte dig[WC_SHA224_DIGEST_SIZE];
        byte* ret = md;
        wc_Sha256 sha;

        WOLFSSL_ENTER("wolfSSL_SHA224");

        if (wc_InitSha224_ex(&sha, NULL, INVALID_DEVID) != 0) {
            WOLFSSL_MSG("SHA224 Init failed");
            return NULL;
        }

        if (wc_Sha224Update(&sha, (const byte*)d, (word32)n) != 0) {
            WOLFSSL_MSG("SHA224 Update failed");
            return NULL;
        }

        if (md == NULL) {
            WOLFSSL_MSG("STATIC BUFFER BEING USED. wolfSSL_SHA224 IS NOT "
                        "THREAD SAFE WHEN md == NULL");
            ret = dig;
        }
        if (wc_Sha224Final(&sha, ret) != 0) {
            WOLFSSL_MSG("SHA224 Final failed");
            wc_Sha224Free(&sha);
            return NULL;
        }
        wc_Sha224Free(&sha);

        return ret;
    }
#endif

#ifndef NO_SHA256
    /* One shot SHA256 hash of message.
     *
     * d  message to hash
     * n  size of d buffer
     * md buffer to hold digest. Should be WC_SHA256_DIGEST_SIZE.
     *
     * Note: if md is null then a static buffer of WC_SHA256_DIGEST_SIZE is used.
     *       When the static buffer is used this function is not thread safe.
     *
     * Returns a pointer to the message digest on success and NULL on failure.
     */
    unsigned char *wolfSSL_SHA256(const unsigned char *d, size_t n,
            unsigned char *md)
    {
        static byte dig[WC_SHA256_DIGEST_SIZE];
        byte* ret = md;
        wc_Sha256 sha;

        WOLFSSL_ENTER("wolfSSL_SHA256");

        if (wc_InitSha256_ex(&sha, NULL, INVALID_DEVID) != 0) {
            WOLFSSL_MSG("SHA256 Init failed");
            return NULL;
        }

        if (wc_Sha256Update(&sha, (const byte*)d, (word32)n) != 0) {
            WOLFSSL_MSG("SHA256 Update failed");
            return NULL;
        }

        if (md == NULL) {
            WOLFSSL_MSG("STATIC BUFFER BEING USED. wolfSSL_SHA256 IS NOT "
                        "THREAD SAFE WHEN md == NULL");
            ret = dig;
        }
        if (wc_Sha256Final(&sha, ret) != 0) {
            WOLFSSL_MSG("SHA256 Final failed");
            wc_Sha256Free(&sha);
            return NULL;
        }
        wc_Sha256Free(&sha);

        return ret;
    }
#endif /* ! NO_SHA256 */

#ifdef WOLFSSL_SHA384
     /* One shot SHA384 hash of message.
      *
      * d  message to hash
      * n  size of d buffer
      * md buffer to hold digest. Should be WC_SHA256_DIGEST_SIZE.
      *
      * Note: if md is null then a static buffer of WC_SHA256_DIGEST_SIZE is used.
      *       When the static buffer is used this function is not thread safe.
      *
      * Returns a pointer to the message digest on success and NULL on failure.
      */
     unsigned char *wolfSSL_SHA384(const unsigned char *d, size_t n,
             unsigned char *md)
     {
         static byte dig[WC_SHA384_DIGEST_SIZE];
         byte* ret = md;
         wc_Sha384 sha;

         WOLFSSL_ENTER("wolfSSL_SHA384");

         if (wc_InitSha384_ex(&sha, NULL, INVALID_DEVID) != 0) {
             WOLFSSL_MSG("SHA384 Init failed");
             return NULL;
         }

         if (wc_Sha384Update(&sha, (const byte*)d, (word32)n) != 0) {
             WOLFSSL_MSG("SHA384 Update failed");
             return NULL;
         }

         if (md == NULL) {
             WOLFSSL_MSG("STATIC BUFFER BEING USED. wolfSSL_SHA384 IS NOT "
                         "THREAD SAFE WHEN md == NULL");
             ret = dig;
         }
         if (wc_Sha384Final(&sha, ret) != 0) {
             WOLFSSL_MSG("SHA384 Final failed");
             wc_Sha384Free(&sha);
             return NULL;
         }
         wc_Sha384Free(&sha);

         return ret;
     }
#endif /* WOLFSSL_SHA384  */

#if defined(WOLFSSL_SHA512)
     /* One shot SHA512 hash of message.
      *
      * d  message to hash
      * n  size of d buffer
      * md buffer to hold digest. Should be WC_SHA256_DIGEST_SIZE.
      *
      * Note: if md is null then a static buffer of WC_SHA256_DIGEST_SIZE is used.
      *       When the static buffer is used this function is not thread safe.
      *
      * Returns a pointer to the message digest on success and NULL on failure.
      */
     unsigned char *wolfSSL_SHA512(const unsigned char *d, size_t n,
             unsigned char *md)
     {
         static byte dig[WC_SHA512_DIGEST_SIZE];
         byte* ret = md;
         wc_Sha512 sha;

         WOLFSSL_ENTER("wolfSSL_SHA512");

         if (wc_InitSha512_ex(&sha, NULL, INVALID_DEVID) != 0) {
             WOLFSSL_MSG("SHA512 Init failed");
             return NULL;
         }

         if (wc_Sha512Update(&sha, (const byte*)d, (word32)n) != 0) {
             WOLFSSL_MSG("SHA512 Update failed");
             return NULL;
         }

         if (md == NULL) {
             WOLFSSL_MSG("STATIC BUFFER BEING USED. wolfSSL_SHA512 IS NOT "
                         "THREAD SAFE WHEN md == NULL");
             ret = dig;
         }
         if (wc_Sha512Final(&sha, ret) != 0) {
             WOLFSSL_MSG("SHA512 Final failed");
             wc_Sha512Free(&sha);
             return NULL;
         }
         wc_Sha512Free(&sha);

         return ret;
     }
#endif /* WOLFSSL_SHA512 */
#endif /* OPENSSL_EXTRA || HAVE_LIGHTY || WOLFSSL_MYSQL_COMPATIBLE ||
        * HAVE_STUNNEL || WOLFSSL_NGINX || HAVE_POCO_LIB || WOLFSSL_HAPROXY */

/*******************************************************************************
 * END OF CRYPTO-ONLY APIs
 ******************************************************************************/