/* benchmark.c * * Copyright (C) 2006-2022 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 */ /* wolfCrypt benchmark */ #ifdef HAVE_CONFIG_H #include #endif #ifndef WOLFSSL_USER_SETTINGS #include #endif #include #include #include #include #include #ifdef HAVE_PTHREAD #include #endif #if defined(HAVE_PTHREAD) || \ (!defined(NO_CRYPT_BENCHMARK) && !defined(NO_STDIO_FILESYSTEM) && \ !defined(NO_ERROR_STRINGS) && !defined(NO_MAIN_DRIVER) && \ !defined(BENCH_EMBEDDED)) #include #ifndef WOLFSSL_ZEPHYR #include #endif #endif /* Macro to disable benchmark */ #ifndef NO_CRYPT_BENCHMARK /* only for stack size check */ #ifdef HAVE_STACK_SIZE #include #include #elif defined(WOLFSSL_ASYNC_CRYPT) #ifndef WC_NO_ASYNC_THREADING #define WC_ENABLE_BENCH_THREADING #endif /* benchmark multi-threading - disable for FIPS self test */ #elif !defined(SINGLE_THREADED) && !defined(WC_NO_BENCH_THREADING) && \ defined(HAVE_PTHREAD) && !defined(HAVE_RENESAS_SYNC) #define WC_ENABLE_BENCH_THREADING #if defined(_POSIX_THREADS) typedef void* THREAD_RETURN; typedef pthread_t THREAD_TYPE; #define WOLFSSL_THREAD #if !defined(__MINGW32__) #define INFINITE (-1) #define WAIT_OBJECT_0 0L #endif #elif defined(WOLFSSL_MDK_ARM)|| defined(WOLFSSL_KEIL_TCP_NET) || defined(FREESCALE_MQX) typedef unsigned int THREAD_RETURN; typedef int THREAD_TYPE; #define WOLFSSL_THREAD #elif defined(WOLFSSL_TIRTOS) typedef void THREAD_RETURN; typedef Task_Handle THREAD_TYPE; #ifdef HAVE_STACK_SIZE #undef EXIT_TEST #define EXIT_TEST(ret) #endif #define WOLFSSL_THREAD #elif defined(WOLFSSL_ZEPHYR) typedef void THREAD_RETURN; typedef struct k_thread THREAD_TYPE; #ifdef HAVE_STACK_SIZE #undef EXIT_TEST #define EXIT_TEST(ret) #endif #define WOLFSSL_THREAD #elif defined(NETOS) typedef UINT THREAD_RETURN; typedef TX_THREAD THREAD_TYPE; #define WOLFSSL_THREAD #define INFINITE TX_WAIT_FOREVER #define WAIT_OBJECT_0 TX_NO_WAIT #else typedef unsigned int THREAD_RETURN; typedef intptr_t THREAD_TYPE; #define WOLFSSL_THREAD __stdcall #endif #endif #ifdef USE_FLAT_BENCHMARK_H #include "benchmark.h" #else #include "wolfcrypt/benchmark/benchmark.h" #endif /* printf mappings */ #ifdef FREESCALE_MQX #include /* see wc_port.h for fio.h and nio.h includes */ #elif defined(FREESCALE_KSDK_1_3) #include "fsl_debug_console.h" #include "fsl_os_abstraction.h" #undef printf #define printf PRINTF #elif defined(WOLFSSL_DEOS) #include #include #undef printf #define printf printx #elif defined(MICRIUM) #if (OS_VERSION < 50000) #include void BSP_Ser_Printf (CPU_CHAR* format, ...); #undef printf #define printf BSP_Ser_Printf #endif #elif defined(WOLFSSL_ZEPHYR) #include #define BENCH_EMBEDDED #define printf printfk static int printfk(const char *fmt, ...) { int ret; char line[150]; va_list ap; va_start(ap, fmt); ret = vsnprintf(line, sizeof(line), fmt, ap); line[sizeof(line)-1] = '\0'; printk("%s", line); va_end(ap); return ret; } #elif defined(WOLFSSL_TELIT_M2MB) #include #include #include #include "m2m_log.h" /* for M2M_LOG_INFO - not standard API */ /* remap printf */ #undef printf #define printf M2M_LOG_INFO /* OS requires occasional sleep() */ #ifndef TEST_SLEEP_MS #define TEST_SLEEP_MS 50 #endif #define TEST_SLEEP() m2mb_os_taskSleep(M2MB_OS_MS2TICKS(TEST_SLEEP_MS)) /* don't use file system for these tests, since ./certs dir isn't loaded */ #undef NO_FILESYSTEM #define NO_FILESYSTEM /* ANDROID_V454 (for android studio) displays information in a textview * and redirects printf to the textview output instead of using * __android_log_print() */ #elif defined(ANDROID) && !defined(ANDROID_V454) #ifdef XMALLOC_USER #include /* we're using malloc / free direct here */ #endif #ifndef STRING_USER #include #endif #include #define printf(...) \ __android_log_print(ANDROID_LOG_DEBUG, "[WOLFCRYPT]", __VA_ARGS__) #define fprintf(fp, ...) \ __android_log_print(ANDROID_LOG_DEBUG, "[WOLFCRYPT]", __VA_ARGS__) #else #if defined(XMALLOC_USER) || defined(FREESCALE_MQX) /* MQX classic needs for EXIT_FAILURE */ #include /* we're using malloc / free direct here */ #endif #ifndef STRING_USER #include #include #endif /* enable way for customer to override test/bench printf */ #ifdef XPRINTF #undef printf #define printf XPRINTF #elif defined(NETOS) #undef printf #define printf dc_log_printf #endif #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifndef NO_HMAC #include #endif #ifdef WOLFSSL_SIPHASH #include #endif #ifndef NO_PWDBASED #include #endif #ifdef HAVE_ECC #include #endif #ifdef HAVE_CURVE25519 #include #endif #ifdef HAVE_ED25519 #include #endif #ifdef HAVE_CURVE448 #include #endif #ifdef HAVE_ED448 #include #endif #ifdef WOLFCRYPT_HAVE_ECCSI #include #endif #ifdef WOLFCRYPT_HAVE_SAKKE #include #endif #ifdef HAVE_LIBOQS #include #include #endif #if defined(HAVE_PQC) #if defined(HAVE_FALCON) #include #endif #if defined(HAVE_DILITHIUM) #include #endif #if defined(HAVE_SPHINCS) #include #endif #endif #ifdef HAVE_PQM4 #include #define PQM4_PUBLIC_KEY_LENGTH CRYPTO_PUBLICKEYBYTES #define PQM4_PRIVATE_KEY_LENGTH CRYPTO_SECRETKEYBYTES #define PQM4_SHARED_SECRET_LENGTH CRYPTO_BYTES #define PQM4_CIPHERTEXT_LENGTH CRYPTO_CIPHERTEXTBYTES typedef char OQS_KEM; #endif #include #include #include #include #ifdef WOLF_CRYPTO_CB #include #ifdef HAVE_INTEL_QA_SYNC #include #endif #ifdef HAVE_CAVIUM_OCTEON_SYNC #include #endif #ifdef HAVE_RENESAS_SYNC #include #endif #endif #ifdef WOLFSSL_ASYNC_CRYPT #include #endif #ifdef HAVE_FIPS #include static void myFipsCb(int ok, int err, const char* hash) { printf("in my Fips callback, ok = %d, err = %d\n", ok, err); printf("message = %s\n", wc_GetErrorString(err)); printf("hash = %s\n", hash); if (err == IN_CORE_FIPS_E) { printf("In core integrity hash check failure, copy above hash\n"); printf("into verifyCore[] in fips_test.c and rebuild\n"); } } #endif #ifdef WOLFSSL_STATIC_MEMORY static WOLFSSL_HEAP_HINT* HEAP_HINT; #else #define HEAP_HINT NULL #endif /* WOLFSSL_STATIC_MEMORY */ #ifndef EXIT_FAILURE #define EXIT_FAILURE 1 #endif #undef LIBCALL_CHECK_RET #if defined(NO_STDIO_FILESYSTEM) || defined(NO_ERROR_STRINGS) || \ defined(NO_MAIN_DRIVER) || defined(BENCH_EMBEDDED) #define LIBCALL_CHECK_RET(...) __VA_ARGS__ #else #define LIBCALL_CHECK_RET(...) do { \ int _libcall_ret = (__VA_ARGS__); \ if (_libcall_ret < 0) { \ fprintf(stderr, "%s L%d error %d for \"%s\"\n", \ __FILE__, __LINE__, errno, #__VA_ARGS__); \ _exit(1); \ } \ } while(0) #endif #undef PTHREAD_CHECK_RET #define PTHREAD_CHECK_RET(...) do { \ int _pthread_ret = (__VA_ARGS__); \ if (_pthread_ret != 0) { \ errno = _pthread_ret; \ fprintf(stderr, "%s L%d error %d for \"%s\"\n", \ __FILE__, __LINE__, _pthread_ret, #__VA_ARGS__); \ _exit(1); \ } \ } while(0) /* optional macro to add sleep between tests */ #ifndef TEST_SLEEP /* stub the sleep macro */ #define TEST_SLEEP() #endif #define TEST_STRING "Everyone gets Friday off." #define TEST_STRING_SZ 25 /* Bit values for each algorithm that is able to be benchmarked. * Common grouping of algorithms also. * Each algorithm has a unique value for its type e.g. cipher. */ /* Cipher algorithms. */ #define BENCH_AES_CBC 0x00000001 #define BENCH_AES_GCM 0x00000002 #define BENCH_AES_ECB 0x00000004 #define BENCH_AES_XTS 0x00000008 #define BENCH_AES_CTR 0x00000010 #define BENCH_AES_CCM 0x00000020 #define BENCH_CAMELLIA 0x00000100 #define BENCH_ARC4 0x00000200 #define BENCH_CHACHA20 0x00001000 #define BENCH_CHACHA20_POLY1305 0x00002000 #define BENCH_DES 0x00004000 #define BENCH_AES_CFB 0x00010000 #define BENCH_AES_OFB 0x00020000 #define BENCH_AES_SIV 0x00040000 /* Digest algorithms. */ #define BENCH_MD5 0x00000001 #define BENCH_POLY1305 0x00000002 #define BENCH_SHA 0x00000004 #define BENCH_SHA224 0x00000010 #define BENCH_SHA256 0x00000020 #define BENCH_SHA384 0x00000040 #define BENCH_SHA512 0x00000080 #define BENCH_SHA2 (BENCH_SHA224 | BENCH_SHA256 | \ BENCH_SHA384 | BENCH_SHA512) #define BENCH_SHA3_224 0x00000100 #define BENCH_SHA3_256 0x00000200 #define BENCH_SHA3_384 0x00000400 #define BENCH_SHA3_512 0x00000800 #define BENCH_SHA3 (BENCH_SHA3_224 | BENCH_SHA3_256 | \ BENCH_SHA3_384 | BENCH_SHA3_512) #define BENCH_RIPEMD 0x00001000 #define BENCH_BLAKE2B 0x00002000 #define BENCH_BLAKE2S 0x00004000 /* MAC algorithms. */ #define BENCH_CMAC 0x00000001 #define BENCH_HMAC_MD5 0x00000002 #define BENCH_HMAC_SHA 0x00000004 #define BENCH_HMAC_SHA224 0x00000010 #define BENCH_HMAC_SHA256 0x00000020 #define BENCH_HMAC_SHA384 0x00000040 #define BENCH_HMAC_SHA512 0x00000080 #define BENCH_HMAC (BENCH_HMAC_MD5 | BENCH_HMAC_SHA | \ BENCH_HMAC_SHA224 | BENCH_HMAC_SHA256 | \ BENCH_HMAC_SHA384 | BENCH_HMAC_SHA512) #define BENCH_PBKDF2 0x00000100 #define BENCH_SIPHASH 0x00000200 /* Asymmetric algorithms. */ #define BENCH_RSA_KEYGEN 0x00000001 #define BENCH_RSA 0x00000002 #define BENCH_RSA_SZ 0x00000004 #define BENCH_DH 0x00000010 #define BENCH_ECC_MAKEKEY 0x00001000 #define BENCH_ECC 0x00002000 #define BENCH_ECC_ENCRYPT 0x00004000 #define BENCH_ECC_ALL 0x00008000 #define BENCH_CURVE25519_KEYGEN 0x00010000 #define BENCH_CURVE25519_KA 0x00020000 #define BENCH_ED25519_KEYGEN 0x00040000 #define BENCH_ED25519_SIGN 0x00080000 #define BENCH_CURVE448_KEYGEN 0x00100000 #define BENCH_CURVE448_KA 0x00200000 #define BENCH_ED448_KEYGEN 0x00400000 #define BENCH_ED448_SIGN 0x00800000 #define BENCH_ECC_P256 0x01000000 #define BENCH_ECC_P384 0x02000000 #define BENCH_ECC_P521 0x04000000 #define BENCH_ECCSI_KEYGEN 0x00000020 #define BENCH_ECCSI_PAIRGEN 0x00000040 #define BENCH_ECCSI_VALIDATE 0x00000080 #define BENCH_ECCSI 0x00000400 #define BENCH_SAKKE_KEYGEN 0x10000000 #define BENCH_SAKKE_RSKGEN 0x20000000 #define BENCH_SAKKE_VALIDATE 0x40000000 #define BENCH_SAKKE 0x80000000 /* Post-Quantum Asymmetric algorithms. */ #define BENCH_FALCON_LEVEL1_SIGN 0x00000001 #define BENCH_FALCON_LEVEL5_SIGN 0x00000002 #define BENCH_KYBER_LEVEL1_KEYGEN 0x00000004 #define BENCH_KYBER_LEVEL1_ENCAP 0x00000008 #define BENCH_KYBER_LEVEL3_KEYGEN 0x00000010 #define BENCH_KYBER_LEVEL3_ENCAP 0x00000020 #define BENCH_KYBER_LEVEL5_KEYGEN 0x00000040 #define BENCH_KYBER_LEVEL5_ENCAP 0x00000080 #define BENCH_KYBER90S_LEVEL1_KEYGEN 0x00000100 #define BENCH_KYBER90S_LEVEL1_ENCAP 0x00000200 #define BENCH_KYBER90S_LEVEL3_KEYGEN 0x00000400 #define BENCH_KYBER90S_LEVEL3_ENCAP 0x00000800 #define BENCH_KYBER90S_LEVEL5_KEYGEN 0x00001000 #define BENCH_KYBER90S_LEVEL5_ENCAP 0x00002000 #define BENCH_SABER_LEVEL1_KEYGEN 0x00004000 #define BENCH_SABER_LEVEL1_ENCAP 0x00008000 #define BENCH_SABER_LEVEL3_KEYGEN 0x00010000 #define BENCH_SABER_LEVEL3_ENCAP 0x00020000 #define BENCH_SABER_LEVEL5_KEYGEN 0x00040000 #define BENCH_SABER_LEVEL5_ENCAP 0x00080000 #define BENCH_NTRUHPS_LEVEL1_KEYGEN 0x00100000 #define BENCH_NTRUHPS_LEVEL1_ENCAP 0x00200000 #define BENCH_NTRUHPS_LEVEL3_KEYGEN 0x00400000 #define BENCH_NTRUHPS_LEVEL3_ENCAP 0x00800000 #define BENCH_NTRUHPS_LEVEL5_KEYGEN 0x01000000 #define BENCH_NTRUHPS_LEVEL5_ENCAP 0x02000000 #define BENCH_DILITHIUM_LEVEL2_SIGN 0x04000000 #define BENCH_DILITHIUM_LEVEL3_SIGN 0x08000000 #define BENCH_DILITHIUM_LEVEL5_SIGN 0x10000000 #define BENCH_DILITHIUM_AES_LEVEL2_SIGN 0x20000000 #define BENCH_DILITHIUM_AES_LEVEL3_SIGN 0x40000000 #define BENCH_DILITHIUM_AES_LEVEL5_SIGN 0x80000000 /* Post-Quantum Asymmetric algorithms. (Part 2) */ #define BENCH_SPHINCS_FAST_LEVEL1_SIGN 0x00000001 #define BENCH_SPHINCS_FAST_LEVEL3_SIGN 0x00000002 #define BENCH_SPHINCS_FAST_LEVEL5_SIGN 0x00000004 #define BENCH_SPHINCS_SMALL_LEVEL1_SIGN 0x00000008 #define BENCH_SPHINCS_SMALL_LEVEL3_SIGN 0x00000010 #define BENCH_SPHINCS_SMALL_LEVEL5_SIGN 0x00000020 /* Other */ #define BENCH_RNG 0x00000001 #define BENCH_SCRYPT 0x00000002 /* Benchmark all compiled in algorithms. * When 1, ignore other benchmark algorithm values. * 0, only benchmark algorithm values set. */ static int bench_all = 1; /* Cipher algorithms to benchmark. */ static int bench_cipher_algs = 0; /* Digest algorithms to benchmark. */ static int bench_digest_algs = 0; /* MAC algorithms to benchmark. */ static int bench_mac_algs = 0; /* Asymmetric algorithms to benchmark. */ static int bench_asym_algs = 0; /* Post-Quantum Asymmetric algorithms to benchmark. */ static int bench_pq_asym_algs = 0; /* Post-Quantum Asymmetric algorithms to benchmark. (Part 2)*/ static int bench_pq_asym_algs2 = 0; /* Other cryptographic algorithms to benchmark. */ static int bench_other_algs = 0; #if !defined(WOLFSSL_BENCHMARK_ALL) && !defined(NO_MAIN_DRIVER) /* The mapping of command line option to bit values. */ typedef struct bench_alg { /* Command line option string. */ const char* str; /* Bit values to set. */ word32 val; } bench_alg; #ifndef MAIN_NO_ARGS /* All recognized cipher algorithm choosing command line options. */ static const bench_alg bench_cipher_opt[] = { { "-cipher", 0xffffffff }, #ifdef HAVE_AES_CBC { "-aes-cbc", BENCH_AES_CBC }, #endif #ifdef HAVE_AESGCM { "-aes-gcm", BENCH_AES_GCM }, #endif #ifdef WOLFSSL_AES_DIRECT { "-aes-ecb", BENCH_AES_ECB }, #endif #ifdef WOLFSSL_AES_XTS { "-aes-xts", BENCH_AES_XTS }, #endif #ifdef WOLFSSL_AES_CFB { "-aes-cfb", BENCH_AES_CFB }, #endif #ifdef WOLFSSL_AES_OFB { "-aes-ofb", BENCH_AES_OFB }, #endif #ifdef WOLFSSL_AES_COUNTER { "-aes-ctr", BENCH_AES_CTR }, #endif #ifdef HAVE_AESCCM { "-aes-ccm", BENCH_AES_CCM }, #endif #ifdef WOLFSSL_AES_SIV { "-aes-siv", BENCH_AES_SIV }, #endif #ifdef HAVE_CAMELLIA { "-camellia", BENCH_CAMELLIA }, #endif #ifndef NO_RC4 { "-arc4", BENCH_ARC4 }, #endif #ifdef HAVE_CHACHA { "-chacha20", BENCH_CHACHA20 }, #endif #if defined(HAVE_CHACHA) && defined(HAVE_POLY1305) { "-chacha20-poly1305", BENCH_CHACHA20_POLY1305 }, #endif #ifndef NO_DES3 { "-des", BENCH_DES }, #endif { NULL, 0 } }; /* All recognized digest algorithm choosing command line options. */ static const bench_alg bench_digest_opt[] = { { "-digest", 0xffffffff }, #ifndef NO_MD5 { "-md5", BENCH_MD5 }, #endif #ifdef HAVE_POLY1305 { "-poly1305", BENCH_POLY1305 }, #endif #ifndef NO_SHA { "-sha", BENCH_SHA }, #endif #if defined(WOLFSSL_SHA224) || !defined(NO_SHA256) || defined(WOLFSSL_SHA384) \ || defined(WOLFSSL_SHA512) { "-sha2", BENCH_SHA2 }, #endif #ifdef WOLFSSL_SHA224 { "-sha224", BENCH_SHA224 }, #endif #ifndef NO_SHA256 { "-sha256", BENCH_SHA256 }, #endif #ifdef WOLFSSL_SHA384 { "-sha384", BENCH_SHA384 }, #endif #ifdef WOLFSSL_SHA512 { "-sha512", BENCH_SHA512 }, #endif #ifdef WOLFSSL_SHA3 { "-sha3", BENCH_SHA3 }, #ifndef WOLFSSL_NOSHA3_224 { "-sha3-224", BENCH_SHA3_224 }, #endif #ifndef WOLFSSL_NOSHA3_256 { "-sha3-256", BENCH_SHA3_256 }, #endif #ifndef WOLFSSL_NOSHA3_384 { "-sha3-384", BENCH_SHA3_384 }, #endif #ifndef WOLFSSL_NOSHA3_512 { "-sha3-512", BENCH_SHA3_512 }, #endif #endif #ifdef WOLFSSL_RIPEMD { "-ripemd", BENCH_RIPEMD }, #endif #ifdef HAVE_BLAKE2 { "-blake2b", BENCH_BLAKE2B }, #endif #ifdef HAVE_BLAKE2S { "-blake2s", BENCH_BLAKE2S }, #endif { NULL, 0 } }; /* All recognized MAC algorithm choosing command line options. */ static const bench_alg bench_mac_opt[] = { { "-mac", 0xffffffff }, #ifdef WOLFSSL_CMAC { "-cmac", BENCH_CMAC }, #endif #ifndef NO_HMAC { "-hmac", BENCH_HMAC }, #ifndef NO_MD5 { "-hmac-md5", BENCH_HMAC_MD5 }, #endif #ifndef NO_SHA { "-hmac-sha", BENCH_HMAC_SHA }, #endif #ifdef WOLFSSL_SHA224 { "-hmac-sha224", BENCH_HMAC_SHA224 }, #endif #ifndef NO_SHA256 { "-hmac-sha256", BENCH_HMAC_SHA256 }, #endif #ifdef WOLFSSL_SHA384 { "-hmac-sha384", BENCH_HMAC_SHA384 }, #endif #ifdef WOLFSSL_SHA512 { "-hmac-sha512", BENCH_HMAC_SHA512 }, #endif #ifndef NO_PWDBASED { "-pbkdf2", BENCH_PBKDF2 }, #endif #ifdef WOLFSSL_SIPHASH { "-siphash", BENCH_SIPHASH }, #endif #endif { NULL, 0 } }; /* All recognized asymmetric algorithm choosing command line options. */ static const bench_alg bench_asym_opt[] = { { "-asym", 0xffffffff }, #ifndef NO_RSA #ifdef WOLFSSL_KEY_GEN { "-rsa-kg", BENCH_RSA_KEYGEN }, #endif { "-rsa", BENCH_RSA }, { "-rsa-sz", BENCH_RSA_SZ }, #endif #ifndef NO_DH { "-dh", BENCH_DH }, #endif #ifdef HAVE_ECC { "-ecc-kg", BENCH_ECC_MAKEKEY }, { "-ecc", BENCH_ECC }, #ifdef HAVE_ECC_ENCRYPT { "-ecc-enc", BENCH_ECC_ENCRYPT }, #endif { "-ecc-all", BENCH_ECC_ALL }, #endif #ifdef HAVE_CURVE25519 { "-curve25519-kg", BENCH_CURVE25519_KEYGEN }, #ifdef HAVE_CURVE25519_SHARED_SECRET { "-x25519", BENCH_CURVE25519_KA }, #endif #endif #ifdef HAVE_ED25519 { "-ed25519-kg", BENCH_ED25519_KEYGEN }, { "-ed25519", BENCH_ED25519_SIGN }, #endif #ifdef HAVE_CURVE448 { "-curve448-kg", BENCH_CURVE448_KEYGEN }, #ifdef HAVE_CURVE448_SHARED_SECRET { "-x448", BENCH_CURVE448_KA }, #endif #endif #ifdef HAVE_ED448 { "-ed448-kg", BENCH_ED448_KEYGEN }, { "-ed448", BENCH_ED448_SIGN }, #endif #ifdef WOLFCRYPT_HAVE_ECCSI { "-eccsi-kg", BENCH_ECCSI_KEYGEN }, { "-eccsi-pair", BENCH_ECCSI_PAIRGEN }, { "-eccsi-val", BENCH_ECCSI_VALIDATE }, { "-eccsi", BENCH_ECCSI }, #endif #ifdef WOLFCRYPT_HAVE_SAKKE { "-sakke-kg", BENCH_SAKKE_KEYGEN }, { "-sakke-rsk", BENCH_SAKKE_RSKGEN }, { "-sakke-val", BENCH_SAKKE_VALIDATE }, { "-sakke", BENCH_SAKKE }, #endif { NULL, 0 } }; /* All recognized other cryptographic algorithm choosing command line options. */ static const bench_alg bench_other_opt[] = { { "-other", 0xffffffff }, #ifndef WC_NO_RNG { "-rng", BENCH_RNG }, #endif #ifdef HAVE_SCRYPT { "-scrypt", BENCH_SCRYPT }, #endif { NULL, 0} }; #endif /* MAIN_NO_ARGS */ #endif /* !WOLFSSL_BENCHMARK_ALL && !NO_MAIN_DRIVER */ #if defined(HAVE_PQC) /* The post-quantum-specific mapping of command line option to bit values and * OQS name. */ typedef struct bench_pq_alg { /* Command line option string. */ const char* str; /* Bit values to set. */ word32 val; const char* pqc_name; } bench_pq_alg; /* All recognized post-quantum asymmetric algorithm choosing command line * options. */ static const bench_pq_alg bench_pq_asym_opt[] = { { "-pq", 0xffffffff, NULL}, #ifdef HAVE_PQM4 { "-kyber_level1-kg", BENCH_KYBER_LEVEL1_KEYGEN, NULL }, { "-kyber_level1-ed", BENCH_KYBER_LEVEL1_ENCAP, NULL }, #endif #ifdef HAVE_LIBOQS { "-falcon_level1", BENCH_FALCON_LEVEL1_SIGN, OQS_SIG_alg_falcon_512 }, { "-falcon_level5", BENCH_FALCON_LEVEL5_SIGN, OQS_SIG_alg_falcon_1024 }, { "-dilithium_level2", BENCH_DILITHIUM_LEVEL2_SIGN, OQS_SIG_alg_dilithium_2 }, { "-dilithium_level3", BENCH_DILITHIUM_LEVEL3_SIGN, OQS_SIG_alg_dilithium_3 }, { "-dilithium_level5", BENCH_DILITHIUM_LEVEL5_SIGN, OQS_SIG_alg_dilithium_5 }, { "-dilithium_aes_level2", BENCH_DILITHIUM_AES_LEVEL2_SIGN, OQS_SIG_alg_dilithium_2_aes }, { "-dilithium_aes_level3", BENCH_DILITHIUM_AES_LEVEL3_SIGN, OQS_SIG_alg_dilithium_3_aes }, { "-dilithium_aes_level5", BENCH_DILITHIUM_AES_LEVEL5_SIGN, OQS_SIG_alg_dilithium_5_aes }, { "-kyber_level1-kg", BENCH_KYBER_LEVEL1_KEYGEN, OQS_KEM_alg_kyber_512 }, { "-kyber_level1-ed", BENCH_KYBER_LEVEL1_ENCAP, OQS_KEM_alg_kyber_512 }, { "-kyber_level3-kg", BENCH_KYBER_LEVEL3_KEYGEN, OQS_KEM_alg_kyber_768 }, { "-kyber_level3-ed", BENCH_KYBER_LEVEL3_ENCAP, OQS_KEM_alg_kyber_768 }, { "-kyber_level5-kg", BENCH_KYBER_LEVEL5_KEYGEN, OQS_KEM_alg_kyber_1024 }, { "-kyber_level5-ed", BENCH_KYBER_LEVEL5_ENCAP, OQS_KEM_alg_kyber_1024 }, { "-kyber90s_level1-kg", BENCH_KYBER90S_LEVEL1_KEYGEN, OQS_KEM_alg_kyber_512_90s }, { "-kyber90s_level1-ed", BENCH_KYBER90S_LEVEL1_ENCAP, OQS_KEM_alg_kyber_512_90s }, { "-kyber90s_level3-kg", BENCH_KYBER90S_LEVEL3_KEYGEN, OQS_KEM_alg_kyber_768_90s }, { "-kyber90s_level3-ed", BENCH_KYBER90S_LEVEL3_ENCAP, OQS_KEM_alg_kyber_768_90s }, { "-kyber90s_level5-kg", BENCH_KYBER90S_LEVEL5_KEYGEN, OQS_KEM_alg_kyber_1024_90s}, { "-kyber90s_level5-ed", BENCH_KYBER90S_LEVEL5_ENCAP, OQS_KEM_alg_kyber_1024_90s }, { "-saber_level1-kg", BENCH_SABER_LEVEL1_KEYGEN, OQS_KEM_alg_saber_lightsaber }, { "-saber_level1-ed", BENCH_SABER_LEVEL1_ENCAP, OQS_KEM_alg_saber_lightsaber }, { "-saber_level3-kg", BENCH_SABER_LEVEL3_KEYGEN, OQS_KEM_alg_saber_saber }, { "-saber_level3-ed", BENCH_SABER_LEVEL3_ENCAP, OQS_KEM_alg_saber_saber }, { "-saber_level5-kg", BENCH_SABER_LEVEL5_KEYGEN, OQS_KEM_alg_saber_firesaber }, { "-saber_level5-ed", BENCH_SABER_LEVEL5_ENCAP, OQS_KEM_alg_saber_firesaber }, { "-ntruHPS_level1-kg", BENCH_NTRUHPS_LEVEL1_KEYGEN, OQS_KEM_alg_ntru_hps2048509 }, { "-ntruHPS_level1-ed", BENCH_NTRUHPS_LEVEL1_ENCAP, OQS_KEM_alg_ntru_hps2048509 }, { "-ntruHPS_level3-kg", BENCH_NTRUHPS_LEVEL3_KEYGEN, OQS_KEM_alg_ntru_hps2048677 }, { "-ntruHPS_level3-ed", BENCH_NTRUHPS_LEVEL3_ENCAP, OQS_KEM_alg_ntru_hps2048677 }, { "-ntruHPS_level5-kg", BENCH_NTRUHPS_LEVEL5_KEYGEN, OQS_KEM_alg_ntru_hps4096821 }, { "-ntruHPS_level5-ed", BENCH_NTRUHPS_LEVEL5_ENCAP, OQS_KEM_alg_ntru_hps4096821 }, #endif /* HAVE_LIBOQS */ { NULL, 0, NULL } }; #ifdef HAVE_LIBOQS /* All recognized post-quantum asymmetric algorithm choosing command line * options. (Part 2) */ static const bench_pq_alg bench_pq_asym_opt2[] = { { "-pq", 0xffffffff, NULL}, { "-sphincs_fast_level1", BENCH_SPHINCS_FAST_LEVEL1_SIGN, OQS_SIG_alg_sphincs_shake256_128f_simple }, { "-sphincs_fast_level3", BENCH_SPHINCS_FAST_LEVEL3_SIGN, OQS_SIG_alg_sphincs_shake256_192f_simple }, { "-sphincs_fast_level5", BENCH_SPHINCS_FAST_LEVEL5_SIGN, OQS_SIG_alg_sphincs_shake256_256f_simple }, { "-sphincs_small_level1", BENCH_SPHINCS_SMALL_LEVEL1_SIGN, OQS_SIG_alg_sphincs_shake256_128s_simple }, { "-sphincs_small_level3", BENCH_SPHINCS_SMALL_LEVEL3_SIGN, OQS_SIG_alg_sphincs_shake256_192s_simple }, { "-sphincs_small_level5", BENCH_SPHINCS_SMALL_LEVEL5_SIGN, OQS_SIG_alg_sphincs_shake256_256s_simple }, { NULL, 0, NULL } }; #endif /* HAVE_LIBOQS */ #endif /* HAVE_PQC */ #ifdef HAVE_WNR const char* wnrConfigFile = "wnr-example.conf"; #endif #if defined(WOLFSSL_MDK_ARM) extern XFILE wolfSSL_fopen(const char *fname, const char *mode); #define fopen wolfSSL_fopen #endif static int lng_index = 0; #ifndef NO_MAIN_DRIVER #ifndef MAIN_NO_ARGS static const char* bench_Usage_msg1[][18] = { /* 0 English */ { "-? Help, print this usage\n 0: English, 1: Japanese\n", "-csv Print terminal output in csv format\n", "-base10 Display bytes as power of 10 (eg 1 kB = 1000 Bytes)\n", "-no_aad No additional authentication data passed.\n", "-dgst_full Full digest operation performed.\n", "-rsa_sign Measure RSA sign/verify instead of encrypt/decrypt.\n", " -rsa-sz\n Measure RSA performance.\n", "-ffhdhe2048 Measure DH using FFDHE 2048-bit parameters.\n", "-ffhdhe3072 Measure DH using FFDHE 3072-bit parameters.\n", "-p256 Measure ECC using P-256 curve.\n", "-p384 Measure ECC using P-384 curve.\n", "-p521 Measure ECC using P-521 curve.\n", "-ecc-all Bench all enabled ECC curves.\n", "- Algorithm to benchmark. Available algorithms include:\n", "-lng Display benchmark result by specified language.\n 0: English, 1: Japanese\n", " Size of block in bytes\n", "-threads Number of threads to run\n", "-print Show benchmark stats summary\n" }, #ifndef NO_MULTIBYTE_PRINT /* 1 Japanese */ { "-? ヘルプ, 使い方を表示します。\n 0: 英語、 1: 日本語\n", "-csv csv 形式で端末に出力します。\n", "-base10 バイトを10のべき乗で表示します。(例 1 kB = 1000 Bytes)\n", "-no_aad 追加の認証データを使用しません.\n", "-dgst_full フルの digest 暗号操作を実施します。\n", "-rsa_sign 暗号/復号化の代わりに RSA の署名/検証を測定します。\n", " -rsa-sz\n RSA の性能を測定します。\n", "-ffhdhe2048 Measure DH using FFDHE 2048-bit parameters.\n", "-ffhdhe3072 Measure DH using FFDHE 3072-bit parameters.\n", "-p256 Measure ECC using P-256 curve.\n", "-p384 Measure ECC using P-384 curve.\n", "-p521 Measure ECC using P-521 curve.\n", "-ecc-all Bench all enabled ECC curves.\n", "- アルゴリズムのベンチマークを実施します。\n 利用可能なアルゴリズムは下記を含みます:\n", "-lng 指定された言語でベンチマーク結果を表示します。\n 0: 英語、 1: 日本語\n", " ブロックサイズをバイト単位で指定します。\n", "-threads 実行するスレッド数\n", "-print ベンチマーク統計の要約を表示する\n" }, #endif }; #endif /* MAIN_NO_ARGS */ #endif static const char* bench_result_words1[][4] = { { "took", "seconds" , "Cycles per byte", NULL }, /* 0 English */ #ifndef NO_MULTIBYTE_PRINT { "を" , "秒で処理", "1バイトあたりのサイクル数", NULL }, /* 1 Japanese */ #endif }; #if !defined(NO_RSA) || \ defined(HAVE_ECC) || !defined(NO_DH) || defined(HAVE_ECC_ENCRYPT) || \ defined(HAVE_CURVE25519) || defined(HAVE_CURVE25519_SHARED_SECRET) || \ defined(HAVE_ED25519) || defined(HAVE_CURVE448) || \ defined(HAVE_CURVE448_SHARED_SECRET) || defined(HAVE_ED448) static const char* bench_desc_words[][14] = { /* 0 1 2 3 4 5 6 7 8 9 10 11 12 13 */ {"public", "private", "key gen", "agree" , "sign", "verify", "encryption", "decryption", "rsk gen", "encap", "derive", "valid", "pair gen", NULL}, /* 0 English */ #ifndef NO_MULTIBYTE_PRINT {"公開鍵", "秘密鍵" ,"鍵生成" , "鍵共有" , "署名", "検証" , "暗号化" , "復号化" , "rsk gen", "encap", "derive", "valid", "pair gen", NULL}, /* 1 Japanese */ #endif }; #endif #if defined(__GNUC__) && defined(__x86_64__) && !defined(NO_ASM) && !defined(WOLFSSL_SGX) #define HAVE_GET_CYCLES static WC_INLINE word64 get_intel_cycles(void); static THREAD_LS_T word64 total_cycles; #define INIT_CYCLE_COUNTER #define BEGIN_INTEL_CYCLES total_cycles = get_intel_cycles(); #define END_INTEL_CYCLES total_cycles = get_intel_cycles() - total_cycles; /* s == size in bytes that 1 count represents, normally BENCH_SIZE */ #define SHOW_INTEL_CYCLES(b, n, s) \ (void)XSNPRINTF((b) + XSTRLEN(b), (n) - XSTRLEN(b), " %s = %6.2f\n", \ bench_result_words1[lng_index][2], \ count == 0 ? 0 : (float)total_cycles / ((word64)count*(s))) #define SHOW_INTEL_CYCLES_CSV(b, n, s) \ (void)XSNPRINTF((b) + XSTRLEN(b), (n) - XSTRLEN(b), "%.2f,\n", \ count == 0 ? 0 : (float)total_cycles / ((word64)count*(s))) #elif defined(LINUX_CYCLE_COUNT) #include #include #include static THREAD_LS_T word64 begin_cycles; static THREAD_LS_T word64 total_cycles; static THREAD_LS_T int cycles = -1; static THREAD_LS_T struct perf_event_attr atr; #define INIT_CYCLE_COUNTER do { \ atr.type = PERF_TYPE_HARDWARE; \ atr.config = PERF_COUNT_HW_CPU_CYCLES; \ cycles = (int)syscall(__NR_perf_event_open, &atr, 0, -1, -1, 0); \ } while (0); #define BEGIN_INTEL_CYCLES read(cycles, &begin_cycles, sizeof(begin_cycles)); #define END_INTEL_CYCLES do { \ read(cycles, &total_cycles, sizeof(total_cycles)); \ total_cycles = total_cycles - begin_cycles; \ } while (0); /* s == size in bytes that 1 count represents, normally BENCH_SIZE */ #define SHOW_INTEL_CYCLES(b, n, s) \ (void)XSNPRINTF(b + XSTRLEN(b), n - XSTRLEN(b), " %s = %6.2f\n", \ bench_result_words1[lng_index][2], \ (float)total_cycles / (count*s)) #define SHOW_INTEL_CYCLES_CSV(b, n, s) \ (void)XSNPRINTF(b + XSTRLEN(b), n - XSTRLEN(b), "%.2f,\n", \ (float)total_cycles / (count*s)) #elif defined(SYNERGY_CYCLE_COUNT) #include "hal_data.h" static THREAD_LS_T word64 begin_cycles; static THREAD_LS_T word64 total_cycles; #define INIT_CYCLE_COUNTER #define BEGIN_INTEL_CYCLES begin_cycles = DWT->CYCCNT = 0; #define END_INTEL_CYCLES total_cycles = DWT->CYCCNT - begin_cycles; /* s == size in bytes that 1 count represents, normally BENCH_SIZE */ #define SHOW_INTEL_CYCLES(b, n, s) \ (void)XSNPRINTF(b + XSTRLEN(b), n - XSTRLEN(b), " %s = %6.2f\n", \ bench_result_words1[lng_index][2], \ (float)total_cycles / (count*s)) #define SHOW_INTEL_CYCLES_CSV(b, n, s) \ (void)XSNPRINTF(b + XSTRLEN(b), n - XSTRLEN(b), "%.2f,\n", \ (float)total_cycles / (count*s)) #else #define INIT_CYCLE_COUNTER #define BEGIN_INTEL_CYCLES #define END_INTEL_CYCLES #define SHOW_INTEL_CYCLES(b, n, s) b[XSTRLEN(b)] = '\n' #define SHOW_INTEL_CYCLES_CSV(b, n, s) b[XSTRLEN(b)] = '\n' #endif /* determine benchmark buffer to use (if NO_FILESYSTEM) */ #if !defined(USE_CERT_BUFFERS_1024) && !defined(USE_CERT_BUFFERS_2048) && \ !defined(USE_CERT_BUFFERS_3072) #define USE_CERT_BUFFERS_2048 /* default to 2048 */ #endif #if defined(USE_CERT_BUFFERS_1024) || defined(USE_CERT_BUFFERS_2048) || \ defined(USE_CERT_BUFFERS_3072) || !defined(NO_DH) /* include test cert and key buffers for use with NO_FILESYSTEM */ #include #endif #if defined(HAVE_BLAKE2) || defined(HAVE_BLAKE2S) #include #endif #ifdef _MSC_VER /* 4996 warning to use MS extensions e.g., strcpy_s instead of strncpy */ #pragma warning(disable: 4996) #endif #ifdef WOLFSSL_CURRTIME_REMAP #define current_time WOLFSSL_CURRTIME_REMAP #elif !defined(HAVE_STACK_SIZE) double current_time(int reset); #endif #if defined(DEBUG_WOLFSSL) && !defined(HAVE_VALGRIND) && \ !defined(HAVE_STACK_SIZE) #ifdef __cplusplus extern "C" { #endif WOLFSSL_API int wolfSSL_Debugging_ON(void); WOLFSSL_API void wolfSSL_Debugging_OFF(void); #ifdef __cplusplus } /* extern "C" */ #endif #endif #if (!defined(NO_RSA) && !defined(WOLFSSL_RSA_VERIFY_ONLY) && !defined(WC_NO_RNG)) \ || !defined(NO_DH) || defined(WOLFSSL_KEY_GEN) || defined(HAVE_ECC) \ || defined(HAVE_CURVE25519) || defined(HAVE_ED25519) \ || defined(HAVE_CURVE448) || defined(HAVE_ED448) #define HAVE_LOCAL_RNG static THREAD_LS_T WC_RNG gRng; #define GLOBAL_RNG &gRng #else #define GLOBAL_RNG NULL #endif #if defined(HAVE_ED25519) || defined(HAVE_CURVE25519) || \ defined(HAVE_CURVE448) || defined(HAVE_ED448) || \ defined(HAVE_ECC) || !defined(NO_DH) || \ !defined(NO_RSA) || defined(HAVE_SCRYPT) #define BENCH_ASYM #endif #if defined(BENCH_ASYM) #if defined(HAVE_ECC) || !defined(NO_RSA) || !defined(NO_DH) || \ defined(HAVE_CURVE25519) || defined(HAVE_ED25519) || \ defined(HAVE_CURVE448) || defined(HAVE_ED448) static const char* bench_result_words2[][5] = { { "ops took", "sec" , "avg" , "ops/sec", NULL }, /* 0 English */ #ifndef NO_MULTIBYTE_PRINT { "回処理を", "秒で実施", "平均", "処理/秒", NULL }, /* 1 Japanese */ #endif }; #endif #endif #ifdef WOLFSSL_CAAM #include #ifdef WOLFSSL_SECO_CAAM #define SECO_MAX_UPDATES 10000 #define SECO_BENCHMARK_NONCE 0x7777 #define SECO_KEY_STORE_ID 1 #endif static THREAD_LS_T int devId = WOLFSSL_CAAM_DEVID; #else static THREAD_LS_T int devId = INVALID_DEVID; #endif /* Asynchronous helper macros */ #ifdef WC_ENABLE_BENCH_THREADING typedef struct ThreadData { pthread_t thread_id; } ThreadData; static ThreadData* g_threadData; static volatile int g_threadCount; #endif #ifdef WOLFSSL_ASYNC_CRYPT static WOLF_EVENT_QUEUE eventQueue; #define BENCH_ASYNC_GET_DEV(obj) (&(obj)->asyncDev) #define BENCH_ASYNC_GET_NAME(useDeviceID) (useDeviceID) ? "HW" : "SW" #define BENCH_MAX_PENDING (WOLF_ASYNC_MAX_PENDING) static int bench_async_check(int* ret, WC_ASYNC_DEV* asyncDev, int callAgain, int* times, int limit, int* pending) { int allowNext = 0; /* this state can be set from a different thread */ WOLF_EVENT_STATE state = asyncDev->event.state; /* if algo doesn't require calling again then use this flow */ if (state == WOLF_EVENT_STATE_DONE) { if (callAgain) { /* needs called again, so allow it and handle completion in bench_async_handle */ allowNext = 1; } else { *ret = asyncDev->event.ret; asyncDev->event.state = WOLF_EVENT_STATE_READY; (*times)++; if (*pending > 0) /* to support case where async blocks */ (*pending)--; if ((*times + *pending) < limit) allowNext = 1; } } /* if slot is available and we haven't reached limit, start another */ else if (state == WOLF_EVENT_STATE_READY && (*times + *pending) < limit) { allowNext = 1; } return allowNext; } static int bench_async_handle(int* ret, WC_ASYNC_DEV* asyncDev, int callAgain, int* times, int* pending) { WOLF_EVENT_STATE state = asyncDev->event.state; if (*ret == WC_PENDING_E) { if (state == WOLF_EVENT_STATE_DONE) { *ret = asyncDev->event.ret; asyncDev->event.state = WOLF_EVENT_STATE_READY; (*times)++; (*pending)--; } else { (*pending)++; *ret = wc_AsyncHandle(asyncDev, &eventQueue, callAgain ? WC_ASYNC_FLAG_CALL_AGAIN : WC_ASYNC_FLAG_NONE); } } else if (*ret >= 0) { *ret = asyncDev->event.ret; asyncDev->event.state = WOLF_EVENT_STATE_READY; (*times)++; if (*pending > 0) /* to support case where async blocks */ (*pending)--; } return (*ret >= 0) ? 1 : 0; } static WC_INLINE int bench_async_poll(int* pending) { int ret, asyncDone = 0; ret = wolfAsync_EventQueuePoll(&eventQueue, NULL, NULL, 0, WOLF_POLL_FLAG_CHECK_HW, &asyncDone); if (ret != 0) { printf("Async poll failed %d\n", ret); return ret; } if (asyncDone == 0) { #ifndef WC_NO_ASYNC_THREADING /* give time to other threads */ wc_AsyncThreadYield(); #endif } (void)pending; return asyncDone; } #else #define BENCH_MAX_PENDING (1) #define BENCH_ASYNC_GET_NAME(useDeviceID) "" #define BENCH_ASYNC_GET_DEV(obj) NULL static WC_INLINE int bench_async_check(int* ret, void* asyncDev, int callAgain, int* times, int limit, int* pending) { (void)ret; (void)asyncDev; (void)callAgain; (void)times; (void)limit; (void)pending; return 1; } static WC_INLINE int bench_async_handle(int* ret, void* asyncDev, int callAgain, int* times, int* pending) { (void)asyncDev; (void)callAgain; (void)pending; if (*ret >= 0) { /* operation completed */ (*times)++; return 1; } return 0; } #define bench_async_poll(p) #endif /* WOLFSSL_ASYNC_CRYPT */ /* maximum runtime for each benchmark */ #ifndef BENCH_MIN_RUNTIME_SEC #define BENCH_MIN_RUNTIME_SEC 1.0f #endif #if defined(HAVE_AESGCM) || defined(HAVE_AESCCM) #if !defined(AES_AUTH_ADD_SZ) && \ defined(STM32_CRYPTO) && !defined(STM32_AESGCM_PARTIAL) /* For STM32 use multiple of 4 to leverage crypto hardware */ #define AES_AUTH_ADD_SZ 16 #endif #ifndef AES_AUTH_ADD_SZ #define AES_AUTH_ADD_SZ 13 #endif #define AES_AUTH_TAG_SZ 16 #define BENCH_CIPHER_ADD AES_AUTH_TAG_SZ static word32 aesAuthAddSz = AES_AUTH_ADD_SZ; #endif #ifndef BENCH_CIPHER_ADD #define BENCH_CIPHER_ADD 0 #endif /* use kB instead of mB for embedded benchmarking */ #ifdef BENCH_EMBEDDED enum BenchmarkBounds { scryptCnt = 1, ntimes = 2, genTimes = BENCH_MAX_PENDING, agreeTimes = 2 }; static int numBlocks = 25; /* how many kB to test (en/de)cryption */ static word32 bench_size = (1024ul); #else enum BenchmarkBounds { scryptCnt = 10, ntimes = 100, genTimes = BENCH_MAX_PENDING, /* must be at least BENCH_MAX_PENDING */ agreeTimes = 100 }; static int numBlocks = 5; /* how many megs to test (en/de)cryption */ static word32 bench_size = (1024*1024UL); #endif static int base2 = 1; static int digest_stream = 1; #ifndef NO_RSA /* Don't measure RSA sign/verify by default */ static int rsa_sign_verify = 0; #endif #ifndef NO_DH /* Use the FFDHE parameters */ static int use_ffdhe = 0; #endif /* Don't print out in CSV format by default */ static int csv_format = 0; #ifdef BENCH_ASYM static int csv_header_count = 0; #endif /* for compatibility */ #define BENCH_SIZE bench_size /* globals for cipher tests */ static THREAD_LS_T byte* bench_plain = NULL; static THREAD_LS_T byte* bench_cipher = NULL; static const XGEN_ALIGN byte bench_key_buf[] = { 0x01,0x23,0x45,0x67,0x89,0xab,0xcd,0xef, 0xfe,0xde,0xba,0x98,0x76,0x54,0x32,0x10, 0x89,0xab,0xcd,0xef,0x01,0x23,0x45,0x67, 0x01,0x23,0x45,0x67,0x89,0xab,0xcd,0xef, 0xf0,0xf1,0xf2,0xf3,0xf4,0xf5,0xf6,0xf7, 0xf8,0xf9,0xfa,0xfb,0xfc,0xfd,0xfe,0xff, 0x00,0x01,0x02,0x03,0x04,0x05,0x06,0x07, 0x08,0x09,0x0a,0x0b,0x0c,0x0d,0x0e,0x0f, }; static const XGEN_ALIGN byte bench_iv_buf[] = { 0x12,0x34,0x56,0x78,0x90,0xab,0xcd,0xef, 0x01,0x01,0x01,0x01,0x01,0x01,0x01,0x01, 0x11,0x21,0x31,0x41,0x51,0x61,0x71,0x81 }; static THREAD_LS_T byte* bench_key = NULL; static THREAD_LS_T byte* bench_iv = NULL; #ifdef WOLFSSL_STATIC_MEMORY #ifdef BENCH_EMBEDDED static byte gBenchMemory[50000]; #else static byte gBenchMemory[400000]; #endif #endif /* This code handles cases with systems where static (non cost) ram variables aren't properly initialized with data */ static int gBenchStaticInit = 0; static void benchmark_static_init(void) { if (gBenchStaticInit == 0) { gBenchStaticInit = 1; /* Init static variables */ bench_all = 1; #ifdef BENCH_EMBEDDED numBlocks = 25; /* how many kB to test (en/de)cryption */ bench_size = (1024ul); #else numBlocks = 5; /* how many megs to test (en/de)cryption */ bench_size = (1024*1024UL); #endif #if defined(HAVE_AESGCM) || defined(HAVE_AESCCM) aesAuthAddSz = AES_AUTH_ADD_SZ; #endif base2 = 1; digest_stream = 1; } } /******************************************************************************/ /* Begin Stats Functions */ /******************************************************************************/ typedef enum bench_stat_type { BENCH_STAT_ASYM, BENCH_STAT_SYM, BENCH_STAT_IGNORE, } bench_stat_type_t; #ifdef WC_ENABLE_BENCH_THREADING static int gPrintStats = 0; static pthread_mutex_t bench_lock = PTHREAD_MUTEX_INITIALIZER; #ifndef BENCH_MAX_NAME_SZ #define BENCH_MAX_NAME_SZ 24 #endif typedef struct bench_stats { struct bench_stats* next; struct bench_stats* prev; char algo[BENCH_MAX_NAME_SZ+1]; /* may not be static, so make copy */ const char* desc; double perfsec; int strength; int useDeviceID; int finishCount; bench_stat_type_t type; int lastRet; const char* perftype; } bench_stats_t; static bench_stats_t* bench_stats_head; static bench_stats_t* bench_stats_tail; static bench_stats_t* bench_stats_add(bench_stat_type_t type, const char* algo, int strength, const char* desc, int useDeviceID, double perfsec, const char* perftype, int ret) { bench_stats_t* bstat = NULL; /* protect bench_stats_head and bench_stats_tail access */ PTHREAD_CHECK_RET(pthread_mutex_lock(&bench_lock)); if (algo != NULL) { /* locate existing in list */ for (bstat = bench_stats_head; bstat != NULL; bstat = bstat->next) { /* match based on algo, strength and desc */ if (XSTRNCMP(bstat->algo, algo, BENCH_MAX_NAME_SZ) == 0 && bstat->strength == strength && bstat->desc == desc && bstat->useDeviceID == useDeviceID) { break; } } } if (bstat == NULL) { /* allocate new and put on list */ bstat = (bench_stats_t*)XMALLOC(sizeof(bench_stats_t), NULL, DYNAMIC_TYPE_INFO); if (bstat) { XMEMSET(bstat, 0, sizeof(bench_stats_t)); /* add to list */ bstat->next = NULL; if (bench_stats_tail == NULL) { bench_stats_head = bstat; } else { bench_stats_tail->next = bstat; bstat->prev = bench_stats_tail; } bench_stats_tail = bstat; /* add to the end either way */ } } if (bstat) { bstat->type = type; if (algo != NULL) XSTRNCPY(bstat->algo, algo, BENCH_MAX_NAME_SZ); bstat->strength = strength; bstat->desc = desc; bstat->useDeviceID = useDeviceID; bstat->perfsec += perfsec; bstat->finishCount++; bstat->perftype = perftype; if (bstat->lastRet > ret) bstat->lastRet = ret; /* track last error */ } PTHREAD_CHECK_RET(pthread_mutex_unlock(&bench_lock)); return bstat; } void bench_stats_print(void) { bench_stats_t* bstat; /* protect bench_stats_head and bench_stats_tail access */ PTHREAD_CHECK_RET(pthread_mutex_lock(&bench_lock)); for (bstat = bench_stats_head; bstat != NULL; ) { if (bstat->type == BENCH_STAT_SYM) { printf("%-16s%s %8.3f %s/s\n", bstat->desc, BENCH_ASYNC_GET_NAME(bstat->useDeviceID), bstat->perfsec, base2 ? "MB" : "mB"); } else { printf("%-5s %4d %-9s %s %.3f ops/sec\n", bstat->algo, bstat->strength, bstat->desc, BENCH_ASYNC_GET_NAME(bstat->useDeviceID), bstat->perfsec); } bstat = bstat->next; } PTHREAD_CHECK_RET(pthread_mutex_unlock(&bench_lock)); } #else /* !WC_ENABLE_BENCH_THREADING */ typedef struct bench_stats { const char* algo; const char* desc; double perfsec; const char* perftype; int strength; bench_stat_type_t type; int ret; } bench_stats_t; /* 16 threads and 8 different operations. */ #define MAX_BENCH_STATS (16 * 8) static bench_stats_t gStats[MAX_BENCH_STATS]; static int gStatsCount; static bench_stats_t* bench_stats_add(bench_stat_type_t type, const char* algo, int strength, const char* desc, int useDeviceID, double perfsec, const char* perftype, int ret) { bench_stats_t* bstat = NULL; if (gStatsCount >= MAX_BENCH_STATS) return bstat; bstat = &gStats[gStatsCount++]; bstat->algo = algo; bstat->desc = desc; bstat->perfsec = perfsec; bstat->perftype = perftype; bstat->strength = strength; bstat->type = type; bstat->ret = ret; (void)useDeviceID; return bstat; } void bench_stats_print(void) { int i; bench_stats_t* bstat; for (i=0; itype == BENCH_STAT_SYM) { printf("%-16s %8.3f %s/s\n", bstat->desc, bstat->perfsec, base2 ? "MB" : "mB"); } else if (bstat->type == BENCH_STAT_ASYM) { printf("%-5s %4d %-9s %.3f ops/sec\n", bstat->algo, bstat->strength, bstat->desc, bstat->perfsec); } } } #endif /* WC_ENABLE_BENCH_THREADING */ static WC_INLINE void bench_stats_init(void) { #if defined(WOLFSSL_ASYNC_CRYPT) && !defined(WC_NO_ASYNC_THREADING) bench_stats_head = NULL; bench_stats_tail = NULL; #endif INIT_CYCLE_COUNTER } static WC_INLINE void bench_stats_start(int* count, double* start) { *count = 0; *start = current_time(1); BEGIN_INTEL_CYCLES } static WC_INLINE int bench_stats_sym_check(double start) { return ((current_time(0) - start) < BENCH_MIN_RUNTIME_SEC); } /* countSz is number of bytes that 1 count represents. Normally bench_size, * except for AES direct that operates on AES_BLOCK_SIZE blocks */ static void bench_stats_sym_finish(const char* desc, int useDeviceID, int count, int countSz, double start, int ret) { double total, persec = 0, blocks = (double)count; const char* blockType; char msg[128] = {0}; const char** word = bench_result_words1[lng_index]; END_INTEL_CYCLES total = current_time(0) - start; /* calculate actual bytes */ blocks *= countSz; if (base2) { /* determine if we should show as KB or MB */ if (blocks > (1024UL * 1024UL)) { blocks /= (1024UL * 1024UL); blockType = "MB"; } else if (blocks > 1024) { blocks /= 1024; /* make KB */ blockType = "KB"; } else { blockType = "bytes"; } } else { /* determine if we should show as kB or mB */ if (blocks > (1000UL * 1000UL)) { blocks /= (1000UL * 1000UL); blockType = "mB"; } else if (blocks > 1000) { blocks /= 1000; /* make kB */ blockType = "kB"; } else { blockType = "bytes"; } } /* calculate blocks per second */ if (total > 0) { persec = (1 / total) * blocks; } /* format and print to terminal */ if (csv_format == 1) { (void)XSNPRINTF(msg, sizeof(msg), "%s,%.3f,", desc, persec); SHOW_INTEL_CYCLES_CSV(msg, sizeof(msg), countSz); } else { (void)XSNPRINTF(msg, sizeof(msg), "%-16s%s %5.0f %s %s %5.3f %s, %8.3f %s/s", desc, BENCH_ASYNC_GET_NAME(useDeviceID), blocks, blockType, word[0], total, word[1], persec, blockType); SHOW_INTEL_CYCLES(msg, sizeof(msg), countSz); } printf("%s", msg); /* show errors */ if (ret < 0) { printf("Benchmark %s failed: %d\n", desc, ret); } /* Add to thread stats */ bench_stats_add(BENCH_STAT_SYM, desc, 0, desc, useDeviceID, persec, blockType, ret); (void)useDeviceID; (void)ret; TEST_SLEEP(); } #ifdef BENCH_ASYM #if defined(HAVE_ECC) || !defined(NO_RSA) || !defined(NO_DH) || \ defined(HAVE_CURVE25519) || defined(HAVE_ED25519) || \ defined(HAVE_CURVE448) || defined(HAVE_ED448) static void bench_stats_asym_finish(const char* algo, int strength, const char* desc, int useDeviceID, int count, double start, int ret) { double total, each = 0, opsSec, milliEach; const char **word = bench_result_words2[lng_index]; const char* kOpsSec = "Ops/Sec"; char msg[128] = {0}; total = current_time(0) - start; if (count > 0) each = total / count; /* per second */ opsSec = count / total; /* ops second */ milliEach = each * 1000; /* milliseconds */ /* format and print to terminal */ if (csv_format == 1) { /* only print out header once */ if (csv_header_count == 1) { printf("\nAsymmetric Ciphers:\n\n"); printf("Algorithm,avg ms,ops/sec,\n"); csv_header_count++; } (void)XSNPRINTF(msg, sizeof(msg), "%s %d %s,%.3f,%.3f,\n", algo, strength, desc, milliEach, opsSec); } else { (void)XSNPRINTF(msg, sizeof(msg), "%-6s %5d %-9s %s %6d %s %5.3f %s, %s %5.3f ms," " %.3f %s\n", algo, strength, desc, BENCH_ASYNC_GET_NAME(useDeviceID), count, word[0], total, word[1], word[2], milliEach, opsSec, word[3]); } printf("%s", msg); /* show errors */ if (ret < 0) { printf("Benchmark %s %s %d failed: %d\n", algo, desc, strength, ret); } /* Add to thread stats */ bench_stats_add(BENCH_STAT_ASYM, algo, strength, desc, useDeviceID, opsSec, kOpsSec, ret); (void)useDeviceID; (void)ret; TEST_SLEEP(); } #endif #if defined(HAVE_PQC) static void bench_stats_pq_asym_finish(const char* algo, int useDeviceID, int count, double start, int ret) { double total, each = 0, opsSec, milliEach; const char **word = bench_result_words2[lng_index]; const char* kOpsSec = "Ops/Sec"; char msg[128] = {0}; total = current_time(0) - start; if (count > 0) each = total / count; /* per second */ opsSec = count / total; /* ops second */ milliEach = each * 1000; /* milliseconds */ /* format and print to terminal */ if (csv_format == 1) { /* only print out header once */ if (csv_header_count == 1) { printf("\nPost Quantum Asymmetric Ciphers:\n\n"); printf("Algorithm,avg ms,ops/sec,\n"); csv_header_count++; } (void)XSNPRINTF(msg, sizeof(msg), "%s %.3f,%.3f,\n", algo, milliEach, opsSec); } else { (void)XSNPRINTF(msg, sizeof(msg), "%-18s %s %6d %s %5.3f %s, %s %5.3f ms," " %.3f %s\n", algo, BENCH_ASYNC_GET_NAME(useDeviceID), count, word[0], total, word[1], word[2], milliEach, opsSec, word[3]); } printf("%s", msg); /* show errors */ if (ret < 0) { printf("Benchmark %s failed: %d\n", algo, ret); } /* Add to thread stats */ bench_stats_add(BENCH_STAT_ASYM, algo, 0, "", useDeviceID, opsSec, kOpsSec, ret); (void)useDeviceID; (void)ret; TEST_SLEEP(); } #endif #endif /* BENCH_ASYM */ static WC_INLINE void bench_stats_free(void) { #if defined(WOLFSSL_ASYNC_CRYPT) && !defined(WC_NO_ASYNC_THREADING) bench_stats_t* bstat; for (bstat = bench_stats_head; bstat != NULL; ) { bench_stats_t* next = bstat->next; XFREE(bstat, NULL, DYNAMIC_TYPE_INFO); bstat = next; } bench_stats_head = NULL; bench_stats_tail = NULL; #endif } /******************************************************************************/ /* End Stats Functions */ /******************************************************************************/ static void* benchmarks_do(void* args) { int bench_buf_size; #ifdef WOLFSSL_ASYNC_CRYPT #ifndef WC_NO_ASYNC_THREADING ThreadData* threadData = (ThreadData*)args; if (wolfAsync_DevOpenThread(&devId, &threadData->thread_id) < 0) #else if (wolfAsync_DevOpen(&devId) < 0) #endif { printf("Async device open failed\nRunning without async\n"); } #endif /* WOLFSSL_ASYNC_CRYPT */ (void)args; #ifdef WOLFSSL_ASYNC_CRYPT if (wolfEventQueue_Init(&eventQueue) != 0) { printf("Async event queue init failure!\n"); } #endif #ifdef WOLF_CRYPTO_CB #ifdef HAVE_INTEL_QA_SYNC devId = wc_CryptoCb_InitIntelQa(); if (devId == INVALID_DEVID) { printf("Couldn't init the Intel QA\n"); } #endif #ifdef HAVE_CAVIUM_OCTEON_SYNC devId = wc_CryptoCb_InitOcteon(); if (devId == INVALID_DEVID) { printf("Couldn't get the Octeon device ID\n"); } #endif #ifdef HAVE_RENESAS_SYNC devId = wc_CryptoCb_CryptInitRenesasCmn(NULL, &guser_PKCbInfo); if (devId == INVALID_DEVID) { printf("Couldn't get the Renesas device ID\n"); } #endif #endif #if defined(HAVE_LOCAL_RNG) { int rngRet; #ifndef HAVE_FIPS rngRet = wc_InitRng_ex(&gRng, HEAP_HINT, devId); #else rngRet = wc_InitRng(&gRng); #endif if (rngRet < 0) { printf("InitRNG failed\n"); return NULL; } } #endif /* setup bench plain, cipher, key and iv globals */ /* make sure bench buffer is multiple of 16 (AES block size) */ bench_buf_size = (int)bench_size + BENCH_CIPHER_ADD; if (bench_buf_size % 16) bench_buf_size += 16 - (bench_buf_size % 16); #ifdef WOLFSSL_AFALG_XILINX_AES bench_plain = (byte*)aligned_alloc(64, (size_t)bench_buf_size + 16); bench_cipher = (byte*)aligned_alloc(64, (size_t)bench_buf_size + 16); #else bench_plain = (byte*)XMALLOC((size_t)bench_buf_size + 16, HEAP_HINT, DYNAMIC_TYPE_WOLF_BIGINT); bench_cipher = (byte*)XMALLOC((size_t)bench_buf_size + 16, HEAP_HINT, DYNAMIC_TYPE_WOLF_BIGINT); #endif if (bench_plain == NULL || bench_cipher == NULL) { XFREE(bench_plain, HEAP_HINT, DYNAMIC_TYPE_WOLF_BIGINT); XFREE(bench_cipher, HEAP_HINT, DYNAMIC_TYPE_WOLF_BIGINT); bench_plain = bench_cipher = NULL; printf("Benchmark block buffer alloc failed!\n"); goto exit; } XMEMSET(bench_plain, 0, (size_t)bench_buf_size); XMEMSET(bench_cipher, 0, (size_t)bench_buf_size); #if defined(WOLFSSL_ASYNC_CRYPT) || defined(HAVE_INTEL_QA_SYNC) bench_key = (byte*)XMALLOC(sizeof(bench_key_buf), HEAP_HINT, DYNAMIC_TYPE_WOLF_BIGINT); bench_iv = (byte*)XMALLOC(sizeof(bench_iv_buf), HEAP_HINT, DYNAMIC_TYPE_WOLF_BIGINT); if (bench_key == NULL || bench_iv == NULL) { XFREE(bench_key, HEAP_HINT, DYNAMIC_TYPE_WOLF_BIGINT); XFREE(bench_iv, HEAP_HINT, DYNAMIC_TYPE_WOLF_BIGINT); bench_key = bench_iv = NULL; printf("Benchmark cipher buffer alloc failed!\n"); goto exit; } XMEMCPY(bench_key, bench_key_buf, sizeof(bench_key_buf)); XMEMCPY(bench_iv, bench_iv_buf, sizeof(bench_iv_buf)); #else bench_key = (byte*)bench_key_buf; bench_iv = (byte*)bench_iv_buf; #endif #ifndef WC_NO_RNG if (bench_all || (bench_other_algs & BENCH_RNG)) bench_rng(); #endif /* WC_NO_RNG */ #ifndef NO_AES #ifdef HAVE_AES_CBC if (bench_all || (bench_cipher_algs & BENCH_AES_CBC)) { #ifndef NO_SW_BENCH bench_aescbc(0); #endif #if ((defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_3DES)) || \ defined(HAVE_INTEL_QA_SYNC) || defined(HAVE_CAVIUM_OCTEON_SYNC) || \ defined(HAVE_RENESAS_SYNC) || defined(WOLFSSL_CAAM)) && \ !defined(NO_HW_BENCH) bench_aescbc(1); #endif } #endif #ifdef HAVE_AESGCM if (bench_all || (bench_cipher_algs & BENCH_AES_GCM)) { #ifndef NO_SW_BENCH bench_aesgcm(0); #endif #if ((defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_3DES)) || \ defined(HAVE_INTEL_QA_SYNC) || defined(HAVE_CAVIUM_OCTEON_SYNC) || \ defined(HAVE_RENESAS_SYNC) || defined(WOLFSSL_CAAM)) && \ !defined(NO_HW_BENCH) bench_aesgcm(1); #endif bench_gmac(); } #endif #ifdef HAVE_AES_ECB if (bench_all || (bench_cipher_algs & BENCH_AES_ECB)) { #ifndef NO_SW_BENCH bench_aesecb(0); #endif #if ((defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_AES)) || \ defined(WOLFSSL_CAAM)) && !defined(NO_HW_BENCH) bench_aesecb(1); #endif } #endif #ifdef WOLFSSL_AES_XTS if (bench_all || (bench_cipher_algs & BENCH_AES_XTS)) bench_aesxts(); #endif #ifdef WOLFSSL_AES_CFB if (bench_all || (bench_cipher_algs & BENCH_AES_CFB)) bench_aescfb(); #endif #ifdef WOLFSSL_AES_OFB if (bench_all || (bench_cipher_algs & BENCH_AES_OFB)) bench_aesofb(); #endif #ifdef WOLFSSL_AES_COUNTER if (bench_all || (bench_cipher_algs & BENCH_AES_CTR)) bench_aesctr(); #endif #ifdef HAVE_AESCCM if (bench_all || (bench_cipher_algs & BENCH_AES_CCM)) bench_aesccm(); #endif #ifdef WOLFSSL_AES_SIV if (bench_all || (bench_cipher_algs & BENCH_AES_SIV)) bench_aessiv(); #endif #endif /* !NO_AES */ #ifdef HAVE_CAMELLIA if (bench_all || (bench_cipher_algs & BENCH_CAMELLIA)) bench_camellia(); #endif #ifndef NO_RC4 if (bench_all || (bench_cipher_algs & BENCH_ARC4)) { #ifndef NO_SW_BENCH bench_arc4(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_ARC4) && \ !defined(NO_HW_BENCH) bench_arc4(1); #endif } #endif #ifdef HAVE_CHACHA if (bench_all || (bench_cipher_algs & BENCH_CHACHA20)) bench_chacha(); #endif #if defined(HAVE_CHACHA) && defined(HAVE_POLY1305) if (bench_all || (bench_cipher_algs & BENCH_CHACHA20_POLY1305)) bench_chacha20_poly1305_aead(); #endif #ifndef NO_DES3 if (bench_all || (bench_cipher_algs & BENCH_DES)) { #ifndef NO_SW_BENCH bench_des(0); #endif #if ((defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_3DES)) || \ defined(HAVE_INTEL_QA_SYNC) || defined(HAVE_CAVIUM_OCTEON_SYNC)) && \ !defined(NO_HW_BENCH) bench_des(1); #endif } #endif #ifndef NO_MD5 if (bench_all || (bench_digest_algs & BENCH_MD5)) { #ifndef NO_SW_BENCH bench_md5(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_MD5) && \ !defined(NO_HW_BENCH) bench_md5(1); #endif } #endif #ifdef HAVE_POLY1305 if (bench_all || (bench_digest_algs & BENCH_POLY1305)) bench_poly1305(); #endif #ifndef NO_SHA if (bench_all || (bench_digest_algs & BENCH_SHA)) { #ifndef NO_SW_BENCH bench_sha(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA) && \ !defined(NO_HW_BENCH) bench_sha(1); #endif } #endif #ifdef WOLFSSL_SHA224 if (bench_all || (bench_digest_algs & BENCH_SHA224)) { #ifndef NO_SW_BENCH bench_sha224(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA224) && \ !defined(NO_HW_BENCH) bench_sha224(1); #endif } #endif #ifndef NO_SHA256 if (bench_all || (bench_digest_algs & BENCH_SHA256)) { #ifndef NO_SW_BENCH bench_sha256(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA256) && \ !defined(NO_HW_BENCH) bench_sha256(1); #endif } #endif #ifdef WOLFSSL_SHA384 if (bench_all || (bench_digest_algs & BENCH_SHA384)) { #ifndef NO_SW_BENCH bench_sha384(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA384) && \ !defined(NO_HW_BENCH) bench_sha384(1); #endif } #endif #ifdef WOLFSSL_SHA512 if (bench_all || (bench_digest_algs & BENCH_SHA512)) { #ifndef NO_SW_BENCH bench_sha512(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA512) && \ !defined(NO_HW_BENCH) bench_sha512(1); #endif } #endif #ifdef WOLFSSL_SHA3 #ifndef WOLFSSL_NOSHA3_224 if (bench_all || (bench_digest_algs & BENCH_SHA3_224)) { #ifndef NO_SW_BENCH bench_sha3_224(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA3) && \ !defined(NO_HW_BENCH) bench_sha3_224(1); #endif } #endif /* WOLFSSL_NOSHA3_224 */ #ifndef WOLFSSL_NOSHA3_256 if (bench_all || (bench_digest_algs & BENCH_SHA3_256)) { #ifndef NO_SW_BENCH bench_sha3_256(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA3) && \ !defined(NO_HW_BENCH) bench_sha3_256(1); #endif } #endif /* WOLFSSL_NOSHA3_256 */ #ifndef WOLFSSL_NOSHA3_384 if (bench_all || (bench_digest_algs & BENCH_SHA3_384)) { #ifndef NO_SW_BENCH bench_sha3_384(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA3) && \ !defined(NO_HW_BENCH) bench_sha3_384(1); #endif } #endif /* WOLFSSL_NOSHA3_384 */ #ifndef WOLFSSL_NOSHA3_512 if (bench_all || (bench_digest_algs & BENCH_SHA3_512)) { #ifndef NO_SW_BENCH bench_sha3_512(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_SHA3) && \ !defined(NO_HW_BENCH) bench_sha3_512(1); #endif } #endif /* WOLFSSL_NOSHA3_512 */ #endif #ifdef WOLFSSL_RIPEMD if (bench_all || (bench_digest_algs & BENCH_RIPEMD)) bench_ripemd(); #endif #ifdef HAVE_BLAKE2 if (bench_all || (bench_digest_algs & BENCH_BLAKE2B)) bench_blake2b(); #endif #ifdef HAVE_BLAKE2S if (bench_all || (bench_digest_algs & BENCH_BLAKE2S)) bench_blake2s(); #endif #ifdef WOLFSSL_CMAC if (bench_all || (bench_mac_algs & BENCH_CMAC)) bench_cmac(); #endif #ifndef NO_HMAC #ifndef NO_MD5 if (bench_all || (bench_mac_algs & BENCH_HMAC_MD5)) { #ifndef NO_SW_BENCH bench_hmac_md5(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_HMAC) && \ defined(WC_ASYNC_ENABLE_MD5) && !defined(NO_HW_BENCH) bench_hmac_md5(1); #endif } #endif #ifndef NO_SHA if (bench_all || (bench_mac_algs & BENCH_HMAC_SHA)) { #ifndef NO_SW_BENCH bench_hmac_sha(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_HMAC) && \ defined(WC_ASYNC_ENABLE_SHA) && !defined(NO_HW_BENCH) bench_hmac_sha(1); #endif } #endif #ifdef WOLFSSL_SHA224 if (bench_all || (bench_mac_algs & BENCH_HMAC_SHA224)) { #ifndef NO_SW_BENCH bench_hmac_sha224(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_HMAC) && \ defined(WC_ASYNC_ENABLE_SHA224) && !defined(NO_HW_BENCH) bench_hmac_sha224(1); #endif } #endif #ifndef NO_SHA256 if (bench_all || (bench_mac_algs & BENCH_HMAC_SHA256)) { #ifndef NO_SW_BENCH bench_hmac_sha256(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_HMAC) && \ defined(WC_ASYNC_ENABLE_SHA256) && !defined(NO_HW_BENCH) bench_hmac_sha256(1); #endif } #endif #ifdef WOLFSSL_SHA384 if (bench_all || (bench_mac_algs & BENCH_HMAC_SHA384)) { #ifndef NO_SW_BENCH bench_hmac_sha384(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_HMAC) && \ defined(WC_ASYNC_ENABLE_SHA384) && !defined(NO_HW_BENCH) bench_hmac_sha384(1); #endif } #endif #ifdef WOLFSSL_SHA512 if (bench_all || (bench_mac_algs & BENCH_HMAC_SHA512)) { #ifndef NO_SW_BENCH bench_hmac_sha512(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_HMAC) && \ defined(WC_ASYNC_ENABLE_SHA512) && !defined(NO_HW_BENCH) bench_hmac_sha512(1); #endif } #endif #ifndef NO_PWDBASED if (bench_all || (bench_mac_algs & BENCH_PBKDF2)) { bench_pbkdf2(); } #endif #ifdef WOLFSSL_SIPHASH if (bench_all || (bench_mac_algs & BENCH_SIPHASH)) { bench_siphash(); } #endif #endif /* NO_HMAC */ #ifdef HAVE_SCRYPT if (bench_all || (bench_other_algs & BENCH_SCRYPT)) bench_scrypt(); #endif #ifndef NO_RSA #ifdef WOLFSSL_KEY_GEN if (bench_all || (bench_asym_algs & BENCH_RSA_KEYGEN)) { #ifndef NO_SW_BENCH if (((word32)bench_asym_algs == 0xFFFFFFFFU) || (bench_asym_algs & BENCH_RSA_SZ) == 0) { bench_rsaKeyGen(0); } else { bench_rsaKeyGen_size(0, bench_size); } #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_RSA_KEYGEN) \ && !defined(NO_HW_BENCH) if (bench_asym_algs & BENCH_RSA_SZ) { bench_rsaKeyGen_size(1, bench_size); } else { bench_rsaKeyGen(1); } #endif } #endif if (bench_all || (bench_asym_algs & BENCH_RSA)) { #ifndef NO_SW_BENCH bench_rsa(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_RSA) && \ !defined(NO_HW_BENCH) bench_rsa(1); #endif } #ifdef WOLFSSL_KEY_GEN if (bench_asym_algs & BENCH_RSA_SZ) { #ifndef NO_SW_BENCH bench_rsa_key(0, bench_size); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_RSA) && \ !defined(NO_HW_BENCH) bench_rsa_key(1, bench_size); #endif } #endif #endif #ifndef NO_DH if (bench_all || (bench_asym_algs & BENCH_DH)) { #ifndef NO_SW_BENCH bench_dh(0); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_DH) && \ !defined(NO_HW_BENCH) bench_dh(1); #endif } #endif #ifdef HAVE_ECC if (bench_all || (bench_asym_algs & BENCH_ECC_MAKEKEY) || (bench_asym_algs & BENCH_ECC) || (bench_asym_algs & BENCH_ECC_ALL) || (bench_asym_algs & BENCH_ECC_ENCRYPT)) { if (bench_asym_algs & BENCH_ECC_ALL) { #if defined(HAVE_FIPS) || defined(HAVE_SELFTEST) printf("not supported in FIPS mode (no ending enum value)\n"); #else int curveId = (int)ECC_SECP192R1; /* set make key and encrypt */ bench_asym_algs |= BENCH_ECC_MAKEKEY | BENCH_ECC | BENCH_ECC_ENCRYPT; if (csv_format != 1) { printf("\nECC Benchmarks:\n"); } do { #ifdef WOLFCRYPT_HAVE_SAKKE /* SAKKE is not useable with ECDH/ECDSA. Run separate test. */ if (curveId == ECC_SAKKE_1) { curveId++; continue; } #endif if (wc_ecc_get_curve_size_from_id(curveId) != ECC_BAD_ARG_E) { bench_ecc_curve(curveId); if (csv_format != 1) { printf("\n"); } } curveId++; } while (curveId != (int)ECC_CURVE_MAX); #endif } else if (bench_asym_algs & BENCH_ECC_P256) { bench_ecc_curve((int)ECC_SECP256R1); } else if (bench_asym_algs & BENCH_ECC_P384) { bench_ecc_curve((int)ECC_SECP384R1); } else if (bench_asym_algs & BENCH_ECC_P521) { bench_ecc_curve((int)ECC_SECP521R1); } else { #ifndef NO_ECC256 bench_ecc_curve((int)ECC_SECP256R1); #endif #ifdef HAVE_ECC_BRAINPOOL bench_ecc_curve((int)ECC_BRAINPOOLP256R1); #endif } } #endif #ifdef HAVE_CURVE25519 if (bench_all || (bench_asym_algs & BENCH_CURVE25519_KEYGEN)) bench_curve25519KeyGen(); #ifdef HAVE_CURVE25519_SHARED_SECRET if (bench_all || (bench_asym_algs & BENCH_CURVE25519_KA)) bench_curve25519KeyAgree(); #endif #endif #ifdef HAVE_ED25519 if (bench_all || (bench_asym_algs & BENCH_ED25519_KEYGEN)) bench_ed25519KeyGen(); if (bench_all || (bench_asym_algs & BENCH_ED25519_SIGN)) bench_ed25519KeySign(); #endif #ifdef HAVE_CURVE448 if (bench_all || (bench_asym_algs & BENCH_CURVE448_KEYGEN)) bench_curve448KeyGen(); #ifdef HAVE_CURVE448_SHARED_SECRET if (bench_all || (bench_asym_algs & BENCH_CURVE448_KA)) bench_curve448KeyAgree(); #endif #endif #ifdef HAVE_ED448 if (bench_all || (bench_asym_algs & BENCH_ED448_KEYGEN)) bench_ed448KeyGen(); if (bench_all || (bench_asym_algs & BENCH_ED448_SIGN)) bench_ed448KeySign(); #endif #ifdef WOLFCRYPT_HAVE_ECCSI #ifdef WOLFCRYPT_ECCSI_KMS if (bench_all || (bench_asym_algs & BENCH_ECCSI_KEYGEN)) { bench_eccsiKeyGen(); } if (bench_all || (bench_asym_algs & BENCH_ECCSI_PAIRGEN)) { bench_eccsiPairGen(); } #endif #ifdef WOLFCRYPT_ECCSI_CLIENT if (bench_all || (bench_asym_algs & BENCH_ECCSI_VALIDATE)) { bench_eccsiValidate(); } if (bench_all || (bench_asym_algs & BENCH_ECCSI)) { bench_eccsi(); } #endif #endif #if defined(HAVE_PQC) if (bench_all || (bench_pq_asym_algs & BENCH_KYBER_LEVEL1_KEYGEN)) bench_pqcKemKeygen(BENCH_KYBER_LEVEL1_KEYGEN); if (bench_all || (bench_pq_asym_algs & BENCH_KYBER_LEVEL1_ENCAP)) bench_pqcKemEncapDecap(BENCH_KYBER_LEVEL1_ENCAP); #endif #if defined(HAVE_LIBOQS) if (bench_all || (bench_pq_asym_algs & BENCH_KYBER_LEVEL3_KEYGEN)) bench_pqcKemKeygen(BENCH_KYBER_LEVEL3_KEYGEN); if (bench_all || (bench_pq_asym_algs & BENCH_KYBER_LEVEL3_ENCAP)) bench_pqcKemEncapDecap(BENCH_KYBER_LEVEL3_ENCAP); if (bench_all || (bench_pq_asym_algs & BENCH_KYBER_LEVEL5_KEYGEN)) bench_pqcKemKeygen(BENCH_KYBER_LEVEL5_KEYGEN); if (bench_all || (bench_pq_asym_algs & BENCH_KYBER_LEVEL5_ENCAP)) bench_pqcKemEncapDecap(BENCH_KYBER_LEVEL5_ENCAP); if (bench_all || (bench_pq_asym_algs & BENCH_KYBER90S_LEVEL1_KEYGEN)) bench_pqcKemKeygen(BENCH_KYBER90S_LEVEL1_KEYGEN); if (bench_all || (bench_pq_asym_algs & BENCH_KYBER90S_LEVEL1_ENCAP)) bench_pqcKemEncapDecap(BENCH_KYBER90S_LEVEL1_ENCAP); if (bench_all || (bench_pq_asym_algs & BENCH_KYBER90S_LEVEL3_KEYGEN)) bench_pqcKemKeygen(BENCH_KYBER90S_LEVEL3_KEYGEN); if (bench_all || (bench_pq_asym_algs & BENCH_KYBER90S_LEVEL3_ENCAP)) bench_pqcKemEncapDecap(BENCH_KYBER90S_LEVEL3_ENCAP); if (bench_all || (bench_pq_asym_algs & BENCH_KYBER90S_LEVEL5_KEYGEN)) bench_pqcKemKeygen(BENCH_KYBER90S_LEVEL5_KEYGEN); if (bench_all || (bench_pq_asym_algs & BENCH_KYBER90S_LEVEL5_ENCAP)) bench_pqcKemEncapDecap(BENCH_KYBER90S_LEVEL5_ENCAP); if (bench_all || (bench_pq_asym_algs & BENCH_SABER_LEVEL1_KEYGEN)) bench_pqcKemKeygen(BENCH_SABER_LEVEL1_KEYGEN); if (bench_all || (bench_pq_asym_algs & BENCH_SABER_LEVEL1_ENCAP)) bench_pqcKemEncapDecap(BENCH_SABER_LEVEL1_ENCAP); if (bench_all || (bench_pq_asym_algs & BENCH_SABER_LEVEL3_KEYGEN)) bench_pqcKemKeygen(BENCH_SABER_LEVEL3_KEYGEN); if (bench_all || (bench_pq_asym_algs & BENCH_SABER_LEVEL3_ENCAP)) bench_pqcKemEncapDecap(BENCH_SABER_LEVEL3_ENCAP); if (bench_all || (bench_pq_asym_algs & BENCH_SABER_LEVEL5_KEYGEN)) bench_pqcKemKeygen(BENCH_SABER_LEVEL5_KEYGEN); if (bench_all || (bench_pq_asym_algs & BENCH_SABER_LEVEL5_ENCAP)) bench_pqcKemEncapDecap(BENCH_SABER_LEVEL5_ENCAP); if (bench_all || (bench_pq_asym_algs & BENCH_NTRUHPS_LEVEL1_KEYGEN)) bench_pqcKemKeygen(BENCH_NTRUHPS_LEVEL1_KEYGEN); if (bench_all || (bench_pq_asym_algs & BENCH_NTRUHPS_LEVEL1_ENCAP)) bench_pqcKemEncapDecap(BENCH_NTRUHPS_LEVEL1_ENCAP); if (bench_all || (bench_pq_asym_algs & BENCH_NTRUHPS_LEVEL3_KEYGEN)) bench_pqcKemKeygen(BENCH_NTRUHPS_LEVEL3_KEYGEN); if (bench_all || (bench_pq_asym_algs & BENCH_NTRUHPS_LEVEL3_ENCAP)) bench_pqcKemEncapDecap(BENCH_NTRUHPS_LEVEL3_ENCAP); if (bench_all || (bench_pq_asym_algs & BENCH_NTRUHPS_LEVEL5_KEYGEN)) bench_pqcKemKeygen(BENCH_NTRUHPS_LEVEL5_KEYGEN); if (bench_all || (bench_pq_asym_algs & BENCH_NTRUHPS_LEVEL5_ENCAP)) bench_pqcKemEncapDecap(BENCH_NTRUHPS_LEVEL5_ENCAP); #ifdef HAVE_FALCON if (bench_all || (bench_pq_asym_algs & BENCH_FALCON_LEVEL1_SIGN)) bench_falconKeySign(1); if (bench_all || (bench_pq_asym_algs & BENCH_FALCON_LEVEL5_SIGN)) bench_falconKeySign(5); #endif #ifdef HAVE_DILITHIUM if (bench_all || (bench_pq_asym_algs & BENCH_DILITHIUM_LEVEL2_SIGN)) bench_dilithiumKeySign(2, SHAKE_VARIANT); if (bench_all || (bench_pq_asym_algs & BENCH_DILITHIUM_LEVEL3_SIGN)) bench_dilithiumKeySign(3, SHAKE_VARIANT); if (bench_all || (bench_pq_asym_algs & BENCH_DILITHIUM_LEVEL5_SIGN)) bench_dilithiumKeySign(5, SHAKE_VARIANT); if (bench_all || (bench_pq_asym_algs & BENCH_DILITHIUM_AES_LEVEL2_SIGN)) bench_dilithiumKeySign(2, AES_VARIANT); if (bench_all || (bench_pq_asym_algs & BENCH_DILITHIUM_AES_LEVEL3_SIGN)) bench_dilithiumKeySign(3, AES_VARIANT); if (bench_all || (bench_pq_asym_algs & BENCH_DILITHIUM_AES_LEVEL5_SIGN)) bench_dilithiumKeySign(5, AES_VARIANT); #endif #ifdef HAVE_SPHINCS if (bench_all || (bench_pq_asym_algs2 & BENCH_SPHINCS_FAST_LEVEL1_SIGN)) bench_sphincsKeySign(1, FAST_VARIANT); if (bench_all || (bench_pq_asym_algs2 & BENCH_SPHINCS_FAST_LEVEL3_SIGN)) bench_sphincsKeySign(3, FAST_VARIANT); if (bench_all || (bench_pq_asym_algs2 & BENCH_SPHINCS_FAST_LEVEL5_SIGN)) bench_sphincsKeySign(5, FAST_VARIANT); if (bench_all || (bench_pq_asym_algs2 & BENCH_SPHINCS_SMALL_LEVEL1_SIGN)) bench_sphincsKeySign(1, SMALL_VARIANT); if (bench_all || (bench_pq_asym_algs2 & BENCH_SPHINCS_SMALL_LEVEL3_SIGN)) bench_sphincsKeySign(3, SMALL_VARIANT); if (bench_all || (bench_pq_asym_algs2 & BENCH_SPHINCS_SMALL_LEVEL5_SIGN)) bench_sphincsKeySign(5, SMALL_VARIANT); #endif #endif /* HAVE_LIBOQS */ #ifdef WOLFCRYPT_HAVE_SAKKE #ifdef WOLFCRYPT_SAKKE_KMS if (bench_all || (bench_asym_algs & BENCH_SAKKE_KEYGEN)) { bench_sakkeKeyGen(); } if (bench_all || (bench_asym_algs & BENCH_SAKKE_RSKGEN)) { bench_sakkeRskGen(); } #endif #ifdef WOLFCRYPT_SAKKE_CLIENT if (bench_all || (bench_asym_algs & BENCH_SAKKE_VALIDATE)) { bench_sakkeValidate(); } if (bench_all || (bench_asym_algs & BENCH_SAKKE)) { bench_sakke(); } #endif #endif exit: /* free benchmark buffers */ XFREE(bench_plain, HEAP_HINT, DYNAMIC_TYPE_WOLF_BIGINT); XFREE(bench_cipher, HEAP_HINT, DYNAMIC_TYPE_WOLF_BIGINT); #ifdef WOLFSSL_ASYNC_CRYPT XFREE(bench_key, HEAP_HINT, DYNAMIC_TYPE_WOLF_BIGINT); XFREE(bench_iv, HEAP_HINT, DYNAMIC_TYPE_WOLF_BIGINT); #endif #if defined(HAVE_LOCAL_RNG) wc_FreeRng(&gRng); #endif /* cleanup the thread if fixed point cache is enabled and have thread local */ #if defined(HAVE_THREAD_LS) && defined(HAVE_ECC) && defined(FP_ECC) wc_ecc_fp_free(); #endif (void)bench_cipher_algs; (void)bench_digest_algs; (void)bench_mac_algs; (void)bench_asym_algs; (void)bench_other_algs; (void)bench_pq_asym_algs; (void)bench_pq_asym_algs2; return NULL; } int benchmark_init(void) { int ret = 0; benchmark_static_init(); #ifdef WOLFSSL_STATIC_MEMORY ret = wc_LoadStaticMemory(&HEAP_HINT, gBenchMemory, sizeof(gBenchMemory), WOLFMEM_GENERAL, 1); if (ret != 0) { printf("unable to load static memory %d\n", ret); } #endif /* WOLFSSL_STATIC_MEMORY */ if ((ret = wolfCrypt_Init()) != 0) { printf("wolfCrypt_Init failed %d\n", ret); return EXIT_FAILURE; } #ifdef WOLFSSL_SECO_CAAM if (devId == WOLFSSL_SECO_DEVID && wc_SECO_OpenHSM(SECO_KEY_STORE_ID, SECO_BENCHMARK_NONCE, SECO_MAX_UPDATES, CAAM_KEYSTORE_CREATE) != 0) { printf("unable to open HSM\n"); wolfCrypt_Cleanup(); return EXIT_FAILURE; } #endif #ifdef WC_RNG_SEED_CB wc_SetSeed_Cb(wc_GenerateSeed); #endif bench_stats_init(); #if defined(DEBUG_WOLFSSL) && !defined(HAVE_VALGRIND) wolfSSL_Debugging_ON(); #endif if (csv_format == 1) { printf("wolfCrypt Benchmark (block bytes %d, min %.1f sec each)\n", (int)BENCH_SIZE, BENCH_MIN_RUNTIME_SEC); printf("This format allows you to easily copy the output to a csv file."); printf("\n\nSymmetric Ciphers:\n\n"); printf("Algorithm,MB/s,Cycles per byte,\n"); } else { printf("wolfCrypt Benchmark (block bytes %d, min %.1f sec each)\n", (int)BENCH_SIZE, BENCH_MIN_RUNTIME_SEC); } #ifdef HAVE_WNR ret = wc_InitNetRandom(wnrConfigFile, NULL, 5000); if (ret != 0) { printf("Whitewood netRandom config init failed %d\n", ret); } #endif /* HAVE_WNR */ return ret; } int benchmark_free(void) { int ret; #ifdef WC_ENABLE_BENCH_THREADING if (gPrintStats || devId != INVALID_DEVID) { bench_stats_print(); } #endif bench_stats_free(); #ifdef WOLF_CRYPTO_CB #ifdef HAVE_INTEL_QA_SYNC wc_CryptoCb_CleanupIntelQa(&devId); #endif #ifdef HAVE_CAVIUM_OCTEON_SYNC wc_CryptoCb_CleanupOcteon(&devId); #endif #ifdef HAVE_RENESAS_SYNC wc_CryptoCb_CleanupRenesasCmn(&devId); #endif #endif #ifdef WOLFSSL_ASYNC_CRYPT /* free event queue */ wolfEventQueue_Free(&eventQueue); /* close device */ wolfAsync_DevClose(&devId); #endif #ifdef HAVE_WNR ret = wc_FreeNetRandom(); if (ret < 0) { printf("Failed to free netRandom context %d\n", ret); } #endif #ifdef WOLFSSL_SECO_CAAM if (devId == WOLFSSL_SECO_DEVID && wc_SECO_CloseHSM() != 0) { printf("Error closing down the key store\n"); } #endif if ((ret = wolfCrypt_Cleanup()) != 0) { printf("error %d with wolfCrypt_Cleanup\n", ret); } return ret; } #if defined(WC_ENABLE_BENCH_THREADING) && !defined(WOLFSSL_ASYNC_CRYPT) static THREAD_RETURN WOLFSSL_THREAD run_bench(void* args) { benchmark_test(args); EXIT_TEST(0); } static int benchmark_test_threaded(void* args) { int i; printf("Threads: %d\n", g_threadCount); g_threadData = (ThreadData*)XMALLOC(sizeof(ThreadData) * g_threadCount, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); if (g_threadData == NULL) { printf("Thread data alloc failed!\n"); return EXIT_FAILURE; } for (i = 0; i < g_threadCount; i++) { PTHREAD_CHECK_RET(pthread_create(&g_threadData[i].thread_id, NULL, run_bench, args)); } for (i = 0; i < g_threadCount; i++) { PTHREAD_CHECK_RET(pthread_join(g_threadData[i].thread_id, 0)); } printf("\n"); bench_stats_print(); return 0; } #endif /* so embedded projects can pull in tests on their own */ #ifdef HAVE_STACK_SIZE THREAD_RETURN WOLFSSL_THREAD benchmark_test(void* args) #else int benchmark_test(void *args) #endif { int ret; (void)args; #ifdef HAVE_FIPS wolfCrypt_SetCb_fips(myFipsCb); #endif ret = benchmark_init(); if (ret != 0) EXIT_TEST(ret); #if defined(WOLFSSL_ASYNC_CRYPT) && !defined(WC_NO_ASYNC_THREADING) { int i; if (g_threadCount == 0) { #ifdef WC_ASYNC_BENCH_THREAD_COUNT g_threadCount = WC_ASYNC_BENCH_THREAD_COUNT; #else g_threadCount = wc_AsyncGetNumberOfCpus(); if (g_threadCount > 0) { g_threadCount /= 2; /* use physical core count */ } #endif } if (g_threadCount <= 0) { g_threadCount = 1; } printf("CPUs: %d\n", g_threadCount); g_threadData = (ThreadData*)XMALLOC(sizeof(ThreadData) * g_threadCount, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); if (g_threadData == NULL) { printf("Thread data alloc failed!\n"); EXIT_TEST(EXIT_FAILURE); } /* Create threads */ for (i = 0; i < g_threadCount; i++) { ret = wc_AsyncThreadCreate(&g_threadData[i].thread_id, benchmarks_do, &g_threadData[i]); if (ret != 0) { printf("Error creating benchmark thread %d\n", ret); EXIT_TEST(EXIT_FAILURE); } } /* Start threads */ for (i = 0; i < g_threadCount; i++) { wc_AsyncThreadJoin(&g_threadData[i].thread_id); } XFREE(g_threadData, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); } #else benchmarks_do(NULL); #endif printf("Benchmark complete\n"); ret = benchmark_free(); EXIT_TEST(ret); } #ifndef WC_NO_RNG void bench_rng(void) { int ret, i, count; double start; long pos, len, remain; WC_RNG myrng; #ifndef HAVE_FIPS ret = wc_InitRng_ex(&myrng, HEAP_HINT, devId); #else ret = wc_InitRng(&myrng); #endif if (ret < 0) { printf("InitRNG failed %d\n", ret); return; } bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { /* Split request to handle large RNG request */ pos = 0; remain = (int)BENCH_SIZE; while (remain > 0) { len = remain; if (len > RNG_MAX_BLOCK_LEN) len = RNG_MAX_BLOCK_LEN; ret = wc_RNG_GenerateBlock(&myrng, &bench_plain[pos], (word32)len); if (ret < 0) goto exit_rng; remain -= len; pos += len; } } count += i; } while (bench_stats_sym_check(start)); exit_rng: bench_stats_sym_finish("RNG", 0, count, bench_size, start, ret); wc_FreeRng(&myrng); } #endif /* WC_NO_RNG */ #ifndef NO_AES #ifdef HAVE_AES_CBC static void bench_aescbc_internal(int useDeviceID, const byte* key, word32 keySz, const byte* iv, const char* encLabel, const char* decLabel) { int ret = 0, i, count = 0, times, pending = 0; Aes enc[BENCH_MAX_PENDING]; double start; /* clear for done cleanup */ XMEMSET(enc, 0, sizeof(enc)); /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if ((ret = wc_AesInit(&enc[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID)) != 0) { printf("AesInit failed, ret = %d\n", ret); goto exit; } ret = wc_AesSetKey(&enc[i], key, keySz, iv, AES_ENCRYPTION); if (ret != 0) { printf("AesSetKey failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, numBlocks, &pending)) { ret = wc_AesCbcEncrypt(&enc[i], bench_plain, bench_cipher, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, &pending)) { goto exit_aes_enc; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_aes_enc: bench_stats_sym_finish(encLabel, useDeviceID, count, bench_size, start, ret); if (ret < 0) { goto exit; } #ifdef HAVE_AES_DECRYPT /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { ret = wc_AesSetKey(&enc[i], key, keySz, iv, AES_DECRYPTION); if (ret != 0) { printf("AesSetKey failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, numBlocks, &pending)) { ret = wc_AesCbcDecrypt(&enc[i], bench_cipher, bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, &pending)) { goto exit_aes_dec; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_aes_dec: bench_stats_sym_finish(decLabel, useDeviceID, count, bench_size, start, ret); #endif /* HAVE_AES_DECRYPT */ (void)decLabel; exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_AesFree(&enc[i]); } } void bench_aescbc(int useDeviceID) { #ifdef WOLFSSL_AES_128 bench_aescbc_internal(useDeviceID, bench_key, 16, bench_iv, "AES-128-CBC-enc", "AES-128-CBC-dec"); #endif #ifdef WOLFSSL_AES_192 bench_aescbc_internal(useDeviceID, bench_key, 24, bench_iv, "AES-192-CBC-enc", "AES-192-CBC-dec"); #endif #ifdef WOLFSSL_AES_256 bench_aescbc_internal(useDeviceID, bench_key, 32, bench_iv, "AES-256-CBC-enc", "AES-256-CBC-dec"); #endif } #endif /* HAVE_AES_CBC */ #ifdef HAVE_AESGCM static void bench_aesgcm_internal(int useDeviceID, const byte* key, word32 keySz, const byte* iv, word32 ivSz, const char* encLabel, const char* decLabel) { int ret = 0, i, count = 0, times, pending = 0; Aes enc[BENCH_MAX_PENDING]; #ifdef HAVE_AES_DECRYPT Aes dec[BENCH_MAX_PENDING]; #endif double start; WC_DECLARE_VAR(bench_additional, byte, AES_AUTH_ADD_SZ, HEAP_HINT); WC_DECLARE_VAR(bench_tag, byte, AES_AUTH_TAG_SZ, HEAP_HINT); #ifdef WC_DECLARE_VAR_IS_HEAP_ALLOC if (bench_additional == NULL || bench_tag == NULL) { printf("bench_aesgcm_internal malloc failed\n"); goto exit; } #endif /* clear for done cleanup */ XMEMSET(enc, 0, sizeof(enc)); #ifdef HAVE_AES_DECRYPT XMEMSET(dec, 0, sizeof(dec)); #endif #ifdef WOLFSSL_ASYNC_CRYPT if (bench_additional) #endif XMEMSET(bench_additional, 0, AES_AUTH_ADD_SZ); #ifdef WOLFSSL_ASYNC_CRYPT if (bench_tag) #endif XMEMSET(bench_tag, 0, AES_AUTH_TAG_SZ); /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if ((ret = wc_AesInit(&enc[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID)) != 0) { printf("AesInit failed, ret = %d\n", ret); goto exit; } ret = wc_AesGcmSetKey(&enc[i], key, keySz); if (ret != 0) { printf("AesGcmSetKey failed, ret = %d\n", ret); goto exit; } } /* GCM uses same routine in backend for both encrypt and decrypt */ bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, numBlocks, &pending)) { #ifndef BENCHMARK_AESGCM_STREAM ret = wc_AesGcmEncrypt(&enc[i], bench_cipher, bench_plain, BENCH_SIZE, iv, ivSz, bench_tag, AES_AUTH_TAG_SZ, bench_additional, aesAuthAddSz); #else ret = wc_AesGcmEncryptInit(&enc[i], NULL, 0, iv, ivSz); if (ret == 0) { ret = wc_AesGcmEncryptUpdate(&enc[i], bench_cipher, bench_plain, BENCH_SIZE, bench_additional, aesAuthAddSz); } if (ret == 0) { ret = wc_AesGcmEncryptFinal(&enc[i], bench_tag, AES_AUTH_TAG_SZ); } #endif if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, &pending)) { goto exit_aes_gcm; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_aes_gcm: bench_stats_sym_finish(encLabel, useDeviceID, count, bench_size, start, ret); #ifdef HAVE_AES_DECRYPT /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if ((ret = wc_AesInit(&dec[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID)) != 0) { printf("AesInit failed, ret = %d\n", ret); goto exit; } ret = wc_AesGcmSetKey(&dec[i], key, keySz); if (ret != 0) { printf("AesGcmSetKey failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&dec[i]), 0, ×, numBlocks, &pending)) { #ifndef BENCHMARK_AESGCM_STREAM ret = wc_AesGcmDecrypt(&dec[i], bench_plain, bench_cipher, BENCH_SIZE, iv, ivSz, bench_tag, AES_AUTH_TAG_SZ, bench_additional, aesAuthAddSz); #else ret = wc_AesGcmDecryptInit(&enc[i], NULL, 0, iv, ivSz); if (ret == 0) { ret = wc_AesGcmDecryptUpdate(&enc[i], bench_plain, bench_cipher, BENCH_SIZE, bench_additional, aesAuthAddSz); } if (ret == 0) { ret = wc_AesGcmDecryptFinal(&enc[i], bench_tag, AES_AUTH_TAG_SZ); } #endif if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&dec[i]), 0, ×, &pending)) { goto exit_aes_gcm_dec; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_aes_gcm_dec: bench_stats_sym_finish(decLabel, useDeviceID, count, bench_size, start, ret); #endif /* HAVE_AES_DECRYPT */ (void)decLabel; exit: if (ret < 0) { printf("bench_aesgcm failed: %d\n", ret); } #ifdef HAVE_AES_DECRYPT for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_AesFree(&dec[i]); } #endif for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_AesFree(&enc[i]); } WC_FREE_VAR(bench_additional, HEAP_HINT); WC_FREE_VAR(bench_tag, HEAP_HINT); } void bench_aesgcm(int useDeviceID) { #if defined(WOLFSSL_AES_128) && !defined(WOLFSSL_AFALG_XILINX_AES) \ && !defined(WOLFSSL_XILINX_CRYPT) bench_aesgcm_internal(useDeviceID, bench_key, 16, bench_iv, 12, "AES-128-GCM-enc", "AES-128-GCM-dec"); #endif #if defined(WOLFSSL_AES_192) && !defined(WOLFSSL_AFALG_XILINX_AES) \ && !defined(WOLFSSL_XILINX_CRYPT) bench_aesgcm_internal(useDeviceID, bench_key, 24, bench_iv, 12, "AES-192-GCM-enc", "AES-192-GCM-dec"); #endif #ifdef WOLFSSL_AES_256 bench_aesgcm_internal(useDeviceID, bench_key, 32, bench_iv, 12, "AES-256-GCM-enc", "AES-256-GCM-dec"); #endif } /* GMAC */ void bench_gmac(void) { int ret, count = 0; Gmac gmac; double start; byte tag[AES_AUTH_TAG_SZ]; /* determine GCM GHASH method */ #ifdef GCM_SMALL const char* gmacStr = "GMAC Small"; #elif defined(GCM_TABLE) const char* gmacStr = "GMAC Table"; #elif defined(GCM_TABLE_4BIT) const char* gmacStr = "GMAC Table 4-bit"; #elif defined(GCM_WORD32) const char* gmacStr = "GMAC Word32"; #else const char* gmacStr = "GMAC Default"; #endif /* init keys */ XMEMSET(bench_plain, 0, bench_size); XMEMSET(tag, 0, sizeof(tag)); XMEMSET(&gmac, 0, sizeof(Gmac)); /* clear context */ (void)wc_AesInit((Aes*)&gmac, HEAP_HINT, INVALID_DEVID); wc_GmacSetKey(&gmac, bench_key, 16); bench_stats_start(&count, &start); do { ret = wc_GmacUpdate(&gmac, bench_iv, 12, bench_plain, bench_size, tag, sizeof(tag)); count++; } while (bench_stats_sym_check(start)); wc_AesFree((Aes*)&gmac); bench_stats_sym_finish(gmacStr, 0, count, bench_size, start, ret); } #endif /* HAVE_AESGCM */ #ifdef HAVE_AES_ECB static void bench_aesecb_internal(int useDeviceID, const byte* key, word32 keySz, const char* encLabel, const char* decLabel) { int ret = 0, i, count = 0, times, pending = 0; Aes enc[BENCH_MAX_PENDING]; double start; /* clear for done cleanup */ XMEMSET(enc, 0, sizeof(enc)); /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if ((ret = wc_AesInit(&enc[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID)) != 0) { printf("AesInit failed, ret = %d\n", ret); goto exit; } ret = wc_AesSetKey(&enc[i], key, keySz, bench_iv, AES_ENCRYPTION); if (ret != 0) { printf("AesSetKey failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, numBlocks, &pending)) { #ifdef HAVE_FIPS wc_AesEncryptDirect(&enc[i], bench_cipher, bench_plain); #else wc_AesEcbEncrypt(&enc[i], bench_cipher, bench_plain, AES_BLOCK_SIZE); #endif ret = 0; if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, &pending)) { goto exit_aes_enc; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_aes_enc: bench_stats_sym_finish(encLabel, useDeviceID, count, AES_BLOCK_SIZE, start, ret); #ifdef HAVE_AES_DECRYPT /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { ret = wc_AesSetKey(&enc[i], key, keySz, bench_iv, AES_DECRYPTION); if (ret != 0) { printf("AesSetKey failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, numBlocks, &pending)) { #ifdef HAVE_FIPS wc_AesDecryptDirect(&enc[i], bench_plain, bench_cipher); #else wc_AesEcbDecrypt(&enc[i], bench_plain, bench_cipher, AES_BLOCK_SIZE); #endif ret = 0; if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, &pending)) { goto exit_aes_dec; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_aes_dec: bench_stats_sym_finish(decLabel, useDeviceID, count, AES_BLOCK_SIZE, start, ret); #endif /* HAVE_AES_DECRYPT */ exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_AesFree(&enc[i]); } } void bench_aesecb(int useDeviceID) { #ifdef WOLFSSL_AES_128 bench_aesecb_internal(useDeviceID, bench_key, 16, "AES-128-ECB-enc", "AES-128-ECB-dec"); #endif #ifdef WOLFSSL_AES_192 bench_aesecb_internal(useDeviceID, bench_key, 24, "AES-192-ECB-enc", "AES-192-ECB-dec"); #endif #ifdef WOLFSSL_AES_256 bench_aesecb_internal(useDeviceID, bench_key, 32, "AES-256-ECB-enc", "AES-256-ECB-dec"); #endif } #endif /* HAVE_AES_ECB */ #ifdef WOLFSSL_AES_CFB static void bench_aescfb_internal(const byte* key, word32 keySz, const byte* iv, const char* label) { Aes enc; double start; int i, ret, count; ret = wc_AesSetKey(&enc, key, keySz, iv, AES_ENCRYPTION); if (ret != 0) { printf("AesSetKey failed, ret = %d\n", ret); return; } bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { if((ret = wc_AesCfbEncrypt(&enc, bench_plain, bench_cipher, BENCH_SIZE)) != 0) { printf("wc_AesCfbEncrypt failed, ret = %d\n", ret); return; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish(label, 0, count, bench_size, start, ret); } void bench_aescfb(void) { #ifdef WOLFSSL_AES_128 bench_aescfb_internal(bench_key, 16, bench_iv, "AES-128-CFB"); #endif #ifdef WOLFSSL_AES_192 bench_aescfb_internal(bench_key, 24, bench_iv, "AES-192-CFB"); #endif #ifdef WOLFSSL_AES_256 bench_aescfb_internal(bench_key, 32, bench_iv, "AES-256-CFB"); #endif } #endif /* WOLFSSL_AES_CFB */ #ifdef WOLFSSL_AES_OFB static void bench_aesofb_internal(const byte* key, word32 keySz, const byte* iv, const char* label) { Aes enc; double start; int i, ret, count; ret = wc_AesSetKey(&enc, key, keySz, iv, AES_ENCRYPTION); if (ret != 0) { printf("AesSetKey failed, ret = %d\n", ret); return; } bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { if((ret = wc_AesOfbEncrypt(&enc, bench_plain, bench_cipher, BENCH_SIZE)) != 0) { printf("wc_AesCfbEncrypt failed, ret = %d\n", ret); return; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish(label, 0, count, bench_size, start, ret); } void bench_aesofb(void) { #ifdef WOLFSSL_AES_128 bench_aesofb_internal(bench_key, 16, bench_iv, "AES-128-OFB"); #endif #ifdef WOLFSSL_AES_192 bench_aesofb_internal(bench_key, 24, bench_iv, "AES-192-OFB"); #endif #ifdef WOLFSSL_AES_256 bench_aesofb_internal(bench_key, 32, bench_iv, "AES-256-OFB"); #endif } #endif /* WOLFSSL_AES_CFB */ #ifdef WOLFSSL_AES_XTS void bench_aesxts(void) { XtsAes aes; double start; int i, count, ret; static unsigned char k1[] = { 0xa1, 0xb9, 0x0c, 0xba, 0x3f, 0x06, 0xac, 0x35, 0x3b, 0x2c, 0x34, 0x38, 0x76, 0x08, 0x17, 0x62, 0x09, 0x09, 0x23, 0x02, 0x6e, 0x91, 0x77, 0x18, 0x15, 0xf2, 0x9d, 0xab, 0x01, 0x93, 0x2f, 0x2f }; static unsigned char i1[] = { 0x4f, 0xae, 0xf7, 0x11, 0x7c, 0xda, 0x59, 0xc6, 0x6e, 0x4b, 0x92, 0x01, 0x3e, 0x76, 0x8a, 0xd5 }; ret = wc_AesXtsSetKey(&aes, k1, sizeof(k1), AES_ENCRYPTION, HEAP_HINT, devId); if (ret != 0) { printf("wc_AesXtsSetKey failed, ret = %d\n", ret); return; } bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { if ((ret = wc_AesXtsEncrypt(&aes, bench_cipher, bench_plain, BENCH_SIZE, i1, sizeof(i1))) != 0) { printf("wc_AesXtsEncrypt failed, ret = %d\n", ret); return; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish("AES-XTS-enc", 0, count, bench_size, start, ret); wc_AesXtsFree(&aes); /* decryption benchmark */ ret = wc_AesXtsSetKey(&aes, k1, sizeof(k1), AES_DECRYPTION, HEAP_HINT, devId); if (ret != 0) { printf("wc_AesXtsSetKey failed, ret = %d\n", ret); return; } bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { if ((ret = wc_AesXtsDecrypt(&aes, bench_plain, bench_cipher, BENCH_SIZE, i1, sizeof(i1))) != 0) { printf("wc_AesXtsDecrypt failed, ret = %d\n", ret); return; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish("AES-XTS-dec", 0, count, bench_size, start, ret); wc_AesXtsFree(&aes); } #endif /* WOLFSSL_AES_XTS */ #ifdef WOLFSSL_AES_COUNTER static void bench_aesctr_internal(const byte* key, word32 keySz, const byte* iv, const char* label) { Aes enc; double start; int i, count, ret = 0; wc_AesSetKeyDirect(&enc, key, keySz, iv, AES_ENCRYPTION); bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { if((ret = wc_AesCtrEncrypt(&enc, bench_plain, bench_cipher, BENCH_SIZE)) != 0) { printf("wc_AesCtrEncrypt failed, ret = %d\n", ret); return; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish(label, 0, count, bench_size, start, ret); } void bench_aesctr(void) { #ifdef WOLFSSL_AES_128 bench_aesctr_internal(bench_key, 16, bench_iv, "AES-128-CTR"); #endif #ifdef WOLFSSL_AES_192 bench_aesctr_internal(bench_key, 24, bench_iv, "AES-192-CTR"); #endif #ifdef WOLFSSL_AES_256 bench_aesctr_internal(bench_key, 32, bench_iv, "AES-256-CTR"); #endif } #endif /* WOLFSSL_AES_COUNTER */ #ifdef HAVE_AESCCM void bench_aesccm(void) { Aes enc; double start; int ret, i, count; WC_DECLARE_VAR(bench_additional, byte, AES_AUTH_ADD_SZ, HEAP_HINT); WC_DECLARE_VAR(bench_tag, byte, AES_AUTH_TAG_SZ, HEAP_HINT); #ifdef WC_DECLARE_VAR_IS_HEAP_ALLOC if (bench_additional == NULL || bench_tag == NULL) { printf("bench_aesccm malloc failed\n"); goto exit; } #endif XMEMSET(bench_tag, 0, AES_AUTH_TAG_SZ); XMEMSET(bench_additional, 0, AES_AUTH_ADD_SZ); if ((ret = wc_AesInit(&enc, HEAP_HINT, devId)) != 0) { printf("wc_AesInit failed, ret = %d\n", ret); goto exit; } if ((ret = wc_AesCcmSetKey(&enc, bench_key, 16)) != 0) { printf("wc_AesCcmSetKey failed, ret = %d\n", ret); goto exit; } bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret |= wc_AesCcmEncrypt(&enc, bench_cipher, bench_plain, BENCH_SIZE, bench_iv, 12, bench_tag, AES_AUTH_TAG_SZ, bench_additional, aesAuthAddSz); } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish("AES-CCM-Enc", 0, count, bench_size, start, ret); if (ret != 0) { printf("wc_AesCcmEncrypt failed, ret = %d\n", ret); goto exit; } bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret |= wc_AesCcmDecrypt(&enc, bench_plain, bench_cipher, BENCH_SIZE, bench_iv, 12, bench_tag, AES_AUTH_TAG_SZ, bench_additional, aesAuthAddSz); } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish("AES-CCM-Dec", 0, count, bench_size, start, ret); if (ret != 0) { printf("wc_AesCcmEncrypt failed, ret = %d\n", ret); goto exit; } exit: WC_FREE_VAR(bench_additional, HEAP_HINT); WC_FREE_VAR(bench_tag, HEAP_HINT); } #endif /* HAVE_AESCCM */ #ifdef WOLFSSL_AES_SIV static void bench_aessiv_internal(const byte* key, word32 keySz, const char* encLabel, const char* decLabel) { int i; int ret = 0; byte assoc[AES_BLOCK_SIZE]; byte nonce[AES_BLOCK_SIZE]; byte siv[AES_BLOCK_SIZE]; int count = 0; double start; bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_AesSivEncrypt(key, keySz, assoc, AES_BLOCK_SIZE, nonce, AES_BLOCK_SIZE, bench_plain, bench_size, siv, bench_cipher); if (ret != 0) { printf("wc_AesSivEncrypt failed (%d)\n", ret); return; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish(encLabel, 0, count, bench_size, start, ret); bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_AesSivDecrypt(key, keySz, assoc, AES_BLOCK_SIZE, nonce, AES_BLOCK_SIZE, bench_cipher, bench_size, siv, bench_plain); if (ret != 0) { printf("wc_AesSivDecrypt failed (%d)\n", ret); return; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish(decLabel, 0, count, bench_size, start, ret); } void bench_aessiv(void) { bench_aessiv_internal(bench_key, 32, "AES-256-SIV-enc", "AES-256-SIV-dec"); bench_aessiv_internal(bench_key, 48, "AES-384-SIV-enc", "AES-384-SIV-dec"); bench_aessiv_internal(bench_key, 64, "AES-512-SIV-enc", "AES-512-SIV-dec"); } #endif /* WOLFSSL_AES_SIV */ #endif /* !NO_AES */ #ifdef HAVE_POLY1305 void bench_poly1305(void) { Poly1305 enc; byte mac[16]; double start; int ret = 0, i, count; if (digest_stream) { ret = wc_Poly1305SetKey(&enc, bench_key, 32); if (ret != 0) { printf("Poly1305SetKey failed, ret = %d\n", ret); return; } bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_Poly1305Update(&enc, bench_plain, BENCH_SIZE); if (ret != 0) { printf("Poly1305Update failed: %d\n", ret); break; } } wc_Poly1305Final(&enc, mac); count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish("POLY1305", 0, count, bench_size, start, ret); } else { bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_Poly1305SetKey(&enc, bench_key, 32); if (ret != 0) { printf("Poly1305SetKey failed, ret = %d\n", ret); return; } ret = wc_Poly1305Update(&enc, bench_plain, BENCH_SIZE); if (ret != 0) { printf("Poly1305Update failed: %d\n", ret); break; } wc_Poly1305Final(&enc, mac); } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish("POLY1305", 0, count, bench_size, start, ret); } } #endif /* HAVE_POLY1305 */ #ifdef HAVE_CAMELLIA void bench_camellia(void) { Camellia cam; double start; int ret, i, count; ret = wc_CamelliaSetKey(&cam, bench_key, 16, bench_iv); if (ret != 0) { printf("CamelliaSetKey failed, ret = %d\n", ret); return; } bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_CamelliaCbcEncrypt(&cam, bench_cipher, bench_plain, BENCH_SIZE); if (ret < 0) { printf("CamelliaCbcEncrypt failed: %d\n", ret); return; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish("Camellia", 0, count, bench_size, start, ret); } #endif #ifndef NO_DES3 void bench_des(int useDeviceID) { int ret = 0, i, count = 0, times, pending = 0; Des3 enc[BENCH_MAX_PENDING]; double start; /* clear for done cleanup */ XMEMSET(enc, 0, sizeof(enc)); /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if ((ret = wc_Des3Init(&enc[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID)) != 0) { printf("Des3Init failed, ret = %d\n", ret); goto exit; } ret = wc_Des3_SetKey(&enc[i], bench_key, bench_iv, DES_ENCRYPTION); if (ret != 0) { printf("Des3_SetKey failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, numBlocks, &pending)) { ret = wc_Des3_CbcEncrypt(&enc[i], bench_cipher, bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, &pending)) { goto exit_3des; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_3des: bench_stats_sym_finish("3DES", useDeviceID, count, bench_size, start, ret); exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_Des3Free(&enc[i]); } } #endif /* !NO_DES3 */ #ifndef NO_RC4 void bench_arc4(int useDeviceID) { int ret = 0, i, count = 0, times, pending = 0; Arc4 enc[BENCH_MAX_PENDING]; double start; /* clear for done cleanup */ XMEMSET(enc, 0, sizeof(enc)); /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if ((ret = wc_Arc4Init(&enc[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID)) != 0) { printf("Arc4Init failed, ret = %d\n", ret); goto exit; } ret = wc_Arc4SetKey(&enc[i], bench_key, 16); if (ret != 0) { printf("Arc4SetKey failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, numBlocks, &pending)) { ret = wc_Arc4Process(&enc[i], bench_cipher, bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&enc[i]), 0, ×, &pending)) { goto exit_arc4; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_arc4: bench_stats_sym_finish("ARC4", useDeviceID, count, bench_size, start, ret); exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_Arc4Free(&enc[i]); } } #endif /* !NO_RC4 */ #ifdef HAVE_CHACHA void bench_chacha(void) { ChaCha enc; double start; int i, count; wc_Chacha_SetKey(&enc, bench_key, 16); bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { wc_Chacha_SetIV(&enc, bench_iv, 0); wc_Chacha_Process(&enc, bench_cipher, bench_plain, BENCH_SIZE); } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish("CHACHA", 0, count, bench_size, start, 0); } #endif /* HAVE_CHACHA*/ #if defined(HAVE_CHACHA) && defined(HAVE_POLY1305) void bench_chacha20_poly1305_aead(void) { double start; int ret = 0, i, count; byte authTag[CHACHA20_POLY1305_AEAD_AUTHTAG_SIZE]; XMEMSET(authTag, 0, sizeof(authTag)); bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_ChaCha20Poly1305_Encrypt(bench_key, bench_iv, NULL, 0, bench_plain, BENCH_SIZE, bench_cipher, authTag); if (ret < 0) { printf("wc_ChaCha20Poly1305_Encrypt error: %d\n", ret); break; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish("CHA-POLY", 0, count, bench_size, start, ret); } #endif /* HAVE_CHACHA && HAVE_POLY1305 */ #ifndef NO_MD5 void bench_md5(int useDeviceID) { wc_Md5 hash[BENCH_MAX_PENDING]; double start; int ret = 0, i, count = 0, times, pending = 0; WC_DECLARE_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_MD5_DIGEST_SIZE, HEAP_HINT); WC_INIT_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_MD5_DIGEST_SIZE, HEAP_HINT); /* clear for done cleanup */ XMEMSET(hash, 0, sizeof(hash)); if (digest_stream) { /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { ret = wc_InitMd5_ex(&hash[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID); if (ret != 0) { printf("InitMd5_ex failed, ret = %d\n", ret); goto exit; } #ifdef WOLFSSL_PIC32MZ_HASH wc_Md5SizeSet(&hash[i], numBlocks * BENCH_SIZE); #endif } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Md5Update(&hash[i], bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_md5; } } } /* for i */ } /* for times */ count += times; times = 0; do { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Md5Final(&hash[i], digest[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_md5; } } } /* for i */ } while (pending > 0); } while (bench_stats_sym_check(start)); } else { bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks; times++) { ret = wc_InitMd5_ex(hash, HEAP_HINT, INVALID_DEVID); if (ret == 0) ret = wc_Md5Update(hash, bench_plain, BENCH_SIZE); if (ret == 0) ret = wc_Md5Final(hash, digest[0]); if (ret != 0) goto exit_md5; } /* for times */ count += times; } while (bench_stats_sym_check(start)); } exit_md5: bench_stats_sym_finish("MD5", useDeviceID, count, bench_size, start, ret); exit: #ifdef WOLFSSL_ASYNC_CRYPT for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_Md5Free(&hash[i]); } #endif WC_FREE_ARRAY(digest, BENCH_MAX_PENDING, HEAP_HINT); } #endif /* !NO_MD5 */ #ifndef NO_SHA void bench_sha(int useDeviceID) { wc_Sha hash[BENCH_MAX_PENDING]; double start; int ret = 0, i, count = 0, times, pending = 0; WC_DECLARE_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA_DIGEST_SIZE, HEAP_HINT); WC_INIT_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA_DIGEST_SIZE, HEAP_HINT); /* clear for done cleanup */ XMEMSET(hash, 0, sizeof(hash)); if (digest_stream) { /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { ret = wc_InitSha_ex(&hash[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID); if (ret != 0) { printf("InitSha failed, ret = %d\n", ret); goto exit; } #ifdef WOLFSSL_PIC32MZ_HASH wc_ShaSizeSet(&hash[i], numBlocks * BENCH_SIZE); #endif } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_ShaUpdate(&hash[i], bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha; } } } /* for i */ } /* for times */ count += times; times = 0; do { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_ShaFinal(&hash[i], digest[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha; } } } /* for i */ } while (pending > 0); } while (bench_stats_sym_check(start)); } else { bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks; times++) { ret = wc_InitSha_ex(hash, HEAP_HINT, INVALID_DEVID); if (ret == 0) ret = wc_ShaUpdate(hash, bench_plain, BENCH_SIZE); if (ret == 0) ret = wc_ShaFinal(hash, digest[0]); if (ret != 0) goto exit_sha; } /* for times */ count += times; } while (bench_stats_sym_check(start)); } exit_sha: bench_stats_sym_finish("SHA", useDeviceID, count, bench_size, start, ret); exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_ShaFree(&hash[i]); } WC_FREE_ARRAY(digest, BENCH_MAX_PENDING, HEAP_HINT); } #endif /* NO_SHA */ #ifdef WOLFSSL_SHA224 void bench_sha224(int useDeviceID) { wc_Sha224 hash[BENCH_MAX_PENDING]; double start; int ret = 0, i, count = 0, times, pending = 0; WC_DECLARE_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA224_DIGEST_SIZE, HEAP_HINT); WC_INIT_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA224_DIGEST_SIZE, HEAP_HINT); /* clear for done cleanup */ XMEMSET(hash, 0, sizeof(hash)); if (digest_stream) { /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { ret = wc_InitSha224_ex(&hash[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID); if (ret != 0) { printf("InitSha224_ex failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha224Update(&hash[i], bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha224; } } } /* for i */ } /* for times */ count += times; times = 0; do { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha224Final(&hash[i], digest[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha224; } } } /* for i */ } while (pending > 0); } while (bench_stats_sym_check(start)); } else { bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks; times++) { ret = wc_InitSha224_ex(hash, HEAP_HINT, INVALID_DEVID); if (ret == 0) ret = wc_Sha224Update(hash, bench_plain, BENCH_SIZE); if (ret == 0) ret = wc_Sha224Final(hash, digest[0]); if (ret != 0) goto exit_sha224; } /* for times */ count += times; } while (bench_stats_sym_check(start)); } exit_sha224: bench_stats_sym_finish("SHA-224", useDeviceID, count, bench_size, start, ret); exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_Sha224Free(&hash[i]); } WC_FREE_ARRAY(digest, BENCH_MAX_PENDING, HEAP_HINT); } #endif #ifndef NO_SHA256 void bench_sha256(int useDeviceID) { wc_Sha256 hash[BENCH_MAX_PENDING]; double start; int ret = 0, i, count = 0, times, pending = 0; WC_DECLARE_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA256_DIGEST_SIZE, HEAP_HINT); WC_INIT_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA256_DIGEST_SIZE, HEAP_HINT); /* clear for done cleanup */ XMEMSET(hash, 0, sizeof(hash)); if (digest_stream) { /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { ret = wc_InitSha256_ex(&hash[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID); if (ret != 0) { printf("InitSha256_ex failed, ret = %d\n", ret); goto exit; } #ifdef WOLFSSL_PIC32MZ_HASH wc_Sha256SizeSet(&hash[i], numBlocks * BENCH_SIZE); #endif } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha256Update(&hash[i], bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha256; } } } /* for i */ } /* for times */ count += times; times = 0; do { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha256Final(&hash[i], digest[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha256; } } } /* for i */ } while (pending > 0); } while (bench_stats_sym_check(start)); } else { bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks; times++) { ret = wc_InitSha256_ex(hash, HEAP_HINT, INVALID_DEVID); if (ret == 0) ret = wc_Sha256Update(hash, bench_plain, BENCH_SIZE); if (ret == 0) ret = wc_Sha256Final(hash, digest[0]); if (ret != 0) goto exit_sha256; } /* for times */ count += times; } while (bench_stats_sym_check(start)); } exit_sha256: bench_stats_sym_finish("SHA-256", useDeviceID, count, bench_size, start, ret); exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_Sha256Free(&hash[i]); } WC_FREE_ARRAY(digest, BENCH_MAX_PENDING, HEAP_HINT); } #endif #ifdef WOLFSSL_SHA384 void bench_sha384(int useDeviceID) { wc_Sha384 hash[BENCH_MAX_PENDING]; double start; int ret = 0, i, count = 0, times, pending = 0; WC_DECLARE_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA384_DIGEST_SIZE, HEAP_HINT); WC_INIT_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA384_DIGEST_SIZE, HEAP_HINT); /* clear for done cleanup */ XMEMSET(hash, 0, sizeof(hash)); if (digest_stream) { /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { ret = wc_InitSha384_ex(&hash[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID); if (ret != 0) { printf("InitSha384_ex failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha384Update(&hash[i], bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha384; } } } /* for i */ } /* for times */ count += times; times = 0; do { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha384Final(&hash[i], digest[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha384; } } } /* for i */ } while (pending > 0); } while (bench_stats_sym_check(start)); } else { bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks; times++) { ret = wc_InitSha384_ex(hash, HEAP_HINT, INVALID_DEVID); if (ret == 0) ret = wc_Sha384Update(hash, bench_plain, BENCH_SIZE); if (ret == 0) ret = wc_Sha384Final(hash, digest[0]); if (ret != 0) goto exit_sha384; } /* for times */ count += times; } while (bench_stats_sym_check(start)); } exit_sha384: bench_stats_sym_finish("SHA-384", useDeviceID, count, bench_size, start, ret); exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_Sha384Free(&hash[i]); } WC_FREE_ARRAY(digest, BENCH_MAX_PENDING, HEAP_HINT); } #endif #ifdef WOLFSSL_SHA512 void bench_sha512(int useDeviceID) { wc_Sha512 hash[BENCH_MAX_PENDING]; double start; int ret = 0, i, count = 0, times, pending = 0; WC_DECLARE_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA512_DIGEST_SIZE, HEAP_HINT); WC_INIT_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA512_DIGEST_SIZE, HEAP_HINT); /* clear for done cleanup */ XMEMSET(hash, 0, sizeof(hash)); if (digest_stream) { /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { ret = wc_InitSha512_ex(&hash[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID); if (ret != 0) { printf("InitSha512_ex failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha512Update(&hash[i], bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha512; } } } /* for i */ } /* for times */ count += times; times = 0; do { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha512Final(&hash[i], digest[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha512; } } } /* for i */ } while (pending > 0); } while (bench_stats_sym_check(start)); } else { bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks; times++) { ret = wc_InitSha512_ex(hash, HEAP_HINT, INVALID_DEVID); if (ret == 0) ret = wc_Sha512Update(hash, bench_plain, BENCH_SIZE); if (ret == 0) ret = wc_Sha512Final(hash, digest[0]); if (ret != 0) goto exit_sha512; } /* for times */ count += times; } while (bench_stats_sym_check(start)); } exit_sha512: bench_stats_sym_finish("SHA-512", useDeviceID, count, bench_size, start, ret); exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_Sha512Free(&hash[i]); } WC_FREE_ARRAY(digest, BENCH_MAX_PENDING, HEAP_HINT); } #endif #ifdef WOLFSSL_SHA3 #ifndef WOLFSSL_NOSHA3_224 void bench_sha3_224(int useDeviceID) { wc_Sha3 hash[BENCH_MAX_PENDING]; double start; int ret = 0, i, count = 0, times, pending = 0; WC_DECLARE_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA3_224_DIGEST_SIZE, HEAP_HINT); WC_INIT_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA3_224_DIGEST_SIZE, HEAP_HINT); /* clear for done cleanup */ XMEMSET(hash, 0, sizeof(hash)); if (digest_stream) { /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { ret = wc_InitSha3_224(&hash[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID); if (ret != 0) { printf("InitSha3_224 failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha3_224_Update(&hash[i], bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha3_224; } } } /* for i */ } /* for times */ count += times; times = 0; do { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha3_224_Final(&hash[i], digest[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha3_224; } } } /* for i */ } while (pending > 0); } while (bench_stats_sym_check(start)); } else { bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks; times++) { ret = wc_InitSha3_224(hash, HEAP_HINT, INVALID_DEVID); if (ret == 0) ret = wc_Sha3_224_Update(hash, bench_plain, BENCH_SIZE); if (ret == 0) ret = wc_Sha3_224_Final(hash, digest[0]); if (ret != 0) goto exit_sha3_224; } /* for times */ count += times; } while (bench_stats_sym_check(start)); } exit_sha3_224: bench_stats_sym_finish("SHA3-224", useDeviceID, count, bench_size, start, ret); exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_Sha3_224_Free(&hash[i]); } WC_FREE_ARRAY(digest, BENCH_MAX_PENDING, HEAP_HINT); } #endif /* WOLFSSL_NOSHA3_224 */ #ifndef WOLFSSL_NOSHA3_256 void bench_sha3_256(int useDeviceID) { wc_Sha3 hash[BENCH_MAX_PENDING]; double start; int ret = 0, i, count = 0, times, pending = 0; WC_DECLARE_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA3_256_DIGEST_SIZE, HEAP_HINT); WC_INIT_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA3_256_DIGEST_SIZE, HEAP_HINT); /* clear for done cleanup */ XMEMSET(hash, 0, sizeof(hash)); if (digest_stream) { /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { ret = wc_InitSha3_256(&hash[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID); if (ret != 0) { printf("InitSha3_256 failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha3_256_Update(&hash[i], bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha3_256; } } } /* for i */ } /* for times */ count += times; times = 0; do { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha3_256_Final(&hash[i], digest[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha3_256; } } } /* for i */ } while (pending > 0); } while (bench_stats_sym_check(start)); } else { bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks; times++) { ret = wc_InitSha3_256(hash, HEAP_HINT, INVALID_DEVID); if (ret == 0) ret = wc_Sha3_256_Update(hash, bench_plain, BENCH_SIZE); if (ret == 0) ret = wc_Sha3_256_Final(hash, digest[0]); if (ret != 0) goto exit_sha3_256; } /* for times */ count += times; } while (bench_stats_sym_check(start)); } exit_sha3_256: bench_stats_sym_finish("SHA3-256", useDeviceID, count, bench_size, start, ret); exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_Sha3_256_Free(&hash[i]); } WC_FREE_ARRAY(digest, BENCH_MAX_PENDING, HEAP_HINT); } #endif /* WOLFSSL_NOSHA3_256 */ #ifndef WOLFSSL_NOSHA3_384 void bench_sha3_384(int useDeviceID) { wc_Sha3 hash[BENCH_MAX_PENDING]; double start; int ret = 0, i, count = 0, times, pending = 0; WC_DECLARE_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA3_384_DIGEST_SIZE, HEAP_HINT); WC_INIT_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA3_384_DIGEST_SIZE, HEAP_HINT); /* clear for done cleanup */ XMEMSET(hash, 0, sizeof(hash)); if (digest_stream) { /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { ret = wc_InitSha3_384(&hash[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID); if (ret != 0) { printf("InitSha3_384 failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha3_384_Update(&hash[i], bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha3_384; } } } /* for i */ } /* for times */ count += times; times = 0; do { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha3_384_Final(&hash[i], digest[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha3_384; } } } /* for i */ } while (pending > 0); } while (bench_stats_sym_check(start)); } else { bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks; times++) { ret = wc_InitSha3_384(hash, HEAP_HINT, INVALID_DEVID); if (ret == 0) ret = wc_Sha3_384_Update(hash, bench_plain, BENCH_SIZE); if (ret == 0) ret = wc_Sha3_384_Final(hash, digest[0]); if (ret != 0) goto exit_sha3_384; } /* for times */ count += times; } while (bench_stats_sym_check(start)); } exit_sha3_384: bench_stats_sym_finish("SHA3-384", useDeviceID, count, bench_size, start, ret); exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_Sha3_384_Free(&hash[i]); } WC_FREE_ARRAY(digest, BENCH_MAX_PENDING, HEAP_HINT); } #endif /* WOLFSSL_NOSHA3_384 */ #ifndef WOLFSSL_NOSHA3_512 void bench_sha3_512(int useDeviceID) { wc_Sha3 hash[BENCH_MAX_PENDING]; double start; int ret = 0, i, count = 0, times, pending = 0; WC_DECLARE_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA3_512_DIGEST_SIZE, HEAP_HINT); WC_INIT_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_SHA3_512_DIGEST_SIZE, HEAP_HINT); /* clear for done cleanup */ XMEMSET(hash, 0, sizeof(hash)); if (digest_stream) { /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { ret = wc_InitSha3_512(&hash[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID); if (ret != 0) { printf("InitSha3_512 failed, ret = %d\n", ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha3_512_Update(&hash[i], bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha3_512; } } } /* for i */ } /* for times */ count += times; times = 0; do { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, numBlocks, &pending)) { ret = wc_Sha3_512_Final(&hash[i], digest[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hash[i]), 0, ×, &pending)) { goto exit_sha3_512; } } } /* for i */ } while (pending > 0); } while (bench_stats_sym_check(start)); } else { bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks; times++) { ret = wc_InitSha3_512(hash, HEAP_HINT, INVALID_DEVID); if (ret == 0) ret = wc_Sha3_512_Update(hash, bench_plain, BENCH_SIZE); if (ret == 0) ret = wc_Sha3_512_Final(hash, digest[0]); if (ret != 0) goto exit_sha3_512; } /* for times */ count += times; } while (bench_stats_sym_check(start)); } exit_sha3_512: bench_stats_sym_finish("SHA3-512", useDeviceID, count, bench_size, start, ret); exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_Sha3_512_Free(&hash[i]); } WC_FREE_ARRAY(digest, BENCH_MAX_PENDING, HEAP_HINT); } #endif /* WOLFSSL_NOSHA3_512 */ #endif #ifdef WOLFSSL_RIPEMD int bench_ripemd(void) { RipeMd hash; byte digest[RIPEMD_DIGEST_SIZE]; double start; int i, count, ret = 0; if (digest_stream) { ret = wc_InitRipeMd(&hash); if (ret != 0) { return ret; } bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_RipeMdUpdate(&hash, bench_plain, BENCH_SIZE); if (ret != 0) { return ret; } } ret = wc_RipeMdFinal(&hash, digest); if (ret != 0) { return ret; } count += i; } while (bench_stats_sym_check(start)); } else { bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_InitRipeMd(&hash); if (ret != 0) { return ret; } ret = wc_RipeMdUpdate(&hash, bench_plain, BENCH_SIZE); if (ret != 0) { return ret; } ret = wc_RipeMdFinal(&hash, digest); if (ret != 0) { return ret; } } count += i; } while (bench_stats_sym_check(start)); } bench_stats_sym_finish("RIPEMD", 0, count, bench_size, start, ret); return 0; } #endif #ifdef HAVE_BLAKE2 void bench_blake2b(void) { Blake2b b2b; byte digest[64]; double start; int ret = 0, i, count; if (digest_stream) { ret = wc_InitBlake2b(&b2b, 64); if (ret != 0) { printf("InitBlake2b failed, ret = %d\n", ret); return; } bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_Blake2bUpdate(&b2b, bench_plain, BENCH_SIZE); if (ret != 0) { printf("Blake2bUpdate failed, ret = %d\n", ret); return; } } ret = wc_Blake2bFinal(&b2b, digest, 64); if (ret != 0) { printf("Blake2bFinal failed, ret = %d\n", ret); return; } count += i; } while (bench_stats_sym_check(start)); } else { bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_InitBlake2b(&b2b, 64); if (ret != 0) { printf("InitBlake2b failed, ret = %d\n", ret); return; } ret = wc_Blake2bUpdate(&b2b, bench_plain, BENCH_SIZE); if (ret != 0) { printf("Blake2bUpdate failed, ret = %d\n", ret); return; } ret = wc_Blake2bFinal(&b2b, digest, 64); if (ret != 0) { printf("Blake2bFinal failed, ret = %d\n", ret); return; } } count += i; } while (bench_stats_sym_check(start)); } bench_stats_sym_finish("BLAKE2b", 0, count, bench_size, start, ret); } #endif #if defined(HAVE_BLAKE2S) void bench_blake2s(void) { Blake2s b2s; byte digest[32]; double start; int ret = 0, i, count; if (digest_stream) { ret = wc_InitBlake2s(&b2s, 32); if (ret != 0) { printf("InitBlake2s failed, ret = %d\n", ret); return; } bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_Blake2sUpdate(&b2s, bench_plain, BENCH_SIZE); if (ret != 0) { printf("Blake2sUpdate failed, ret = %d\n", ret); return; } } ret = wc_Blake2sFinal(&b2s, digest, 32); if (ret != 0) { printf("Blake2sFinal failed, ret = %d\n", ret); return; } count += i; } while (bench_stats_sym_check(start)); } else { bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_InitBlake2s(&b2s, 32); if (ret != 0) { printf("InitBlake2b failed, ret = %d\n", ret); return; } ret = wc_Blake2sUpdate(&b2s, bench_plain, BENCH_SIZE); if (ret != 0) { printf("Blake2bUpdate failed, ret = %d\n", ret); return; } ret = wc_Blake2sFinal(&b2s, digest, 32); if (ret != 0) { printf("Blake2sFinal failed, ret = %d\n", ret); return; } } count += i; } while (bench_stats_sym_check(start)); } bench_stats_sym_finish("BLAKE2s", 0, count, bench_size, start, ret); } #endif #ifdef WOLFSSL_CMAC static void bench_cmac_helper(int keySz, const char* outMsg) { Cmac cmac; byte digest[AES_BLOCK_SIZE]; word32 digestSz = sizeof(digest); double start; int ret, i, count; #ifdef WOLFSSL_SECO_CAAM unsigned int keyID; int keyGroup = 1; /* group one was chosen arbitrarily */ int keyInfo = CAAM_KEY_TRANSIENT; int keyType = CAAM_KEYTYPE_AES128; byte pubKey[AES_256_KEY_SIZE]; if (keySz == AES_256_KEY_SIZE) { keyType = CAAM_KEYTYPE_AES256; } if (wc_SECO_GenerateKey(CAAM_GENERATE_KEY, keyGroup, pubKey, 0, keyType, keyInfo, &keyID) != 0) { printf("Error generating key in hsm\n"); return; } #endif bench_stats_start(&count, &start); do { #ifdef HAVE_FIPS ret = wc_InitCmac(&cmac, bench_key, keySz, WC_CMAC_AES, NULL); #else ret = wc_InitCmac_ex(&cmac, bench_key, keySz, WC_CMAC_AES, NULL, HEAP_HINT, devId); #endif if (ret != 0) { printf("InitCmac failed, ret = %d\n", ret); return; } #ifdef WOLFSSL_SECO_CAAM wc_SECO_CMACSetKeyID(&cmac, keyID); #endif for (i = 0; i < numBlocks; i++) { ret = wc_CmacUpdate(&cmac, bench_plain, BENCH_SIZE); if (ret != 0) { printf("CmacUpdate failed, ret = %d\n", ret); return; } } /* Note: final force zero's the Cmac struct */ ret = wc_CmacFinal(&cmac, digest, &digestSz); if (ret != 0) { printf("CmacFinal failed, ret = %d\n", ret); return; } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish(outMsg, 0, count, bench_size, start, ret); } void bench_cmac(void) { #ifdef WOLFSSL_AES_128 bench_cmac_helper(16, "AES-128-CMAC"); #endif #ifdef WOLFSSL_AES_256 bench_cmac_helper(32, "AES-256-CMAC"); #endif } #endif /* WOLFSSL_CMAC */ #ifdef HAVE_SCRYPT void bench_scrypt(void) { byte derived[64]; double start; int ret, i, count; bench_stats_start(&count, &start); do { for (i = 0; i < scryptCnt; i++) { ret = wc_scrypt(derived, (byte*)"pleaseletmein", 13, (byte*)"SodiumChloride", 14, 14, 8, 1, sizeof(derived)); if (ret != 0) { printf("scrypt failed, ret = %d\n", ret); goto exit; } } count += i; } while (bench_stats_sym_check(start)); exit: bench_stats_asym_finish("scrypt", 17, "", 0, count, start, ret); } #endif /* HAVE_SCRYPT */ #ifndef NO_HMAC static void bench_hmac(int useDeviceID, int type, int digestSz, byte* key, word32 keySz, const char* label) { Hmac hmac[BENCH_MAX_PENDING]; double start; int ret = 0, i, count = 0, times, pending = 0; #ifdef WOLFSSL_ASYNC_CRYPT WC_DECLARE_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_MAX_DIGEST_SIZE, HEAP_HINT); WC_INIT_ARRAY(digest, byte, BENCH_MAX_PENDING, WC_MAX_DIGEST_SIZE, HEAP_HINT); #else byte digest[BENCH_MAX_PENDING][WC_MAX_DIGEST_SIZE]; #endif (void)digestSz; /* clear for done cleanup */ XMEMSET(hmac, 0, sizeof(hmac)); /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { ret = wc_HmacInit(&hmac[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID); if (ret != 0) { printf("wc_HmacInit failed for %s, ret = %d\n", label, ret); goto exit; } ret = wc_HmacSetKey(&hmac[i], type, key, keySz); if (ret != 0) { printf("wc_HmacSetKey failed for %s, ret = %d\n", label, ret); goto exit; } } bench_stats_start(&count, &start); do { for (times = 0; times < numBlocks || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hmac[i]), 0, ×, numBlocks, &pending)) { ret = wc_HmacUpdate(&hmac[i], bench_plain, BENCH_SIZE); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hmac[i]), 0, ×, &pending)) { goto exit_hmac; } } } /* for i */ } /* for times */ count += times; times = 0; do { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&hmac[i]), 0, ×, numBlocks, &pending)) { ret = wc_HmacFinal(&hmac[i], digest[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&hmac[i]), 0, ×, &pending)) { goto exit_hmac; } } } /* for i */ } while (pending > 0); } while (bench_stats_sym_check(start)); exit_hmac: bench_stats_sym_finish(label, useDeviceID, count, bench_size, start, ret); exit: for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_HmacFree(&hmac[i]); } #ifdef WOLFSSL_ASYNC_CRYPT WC_FREE_ARRAY(digest, BENCH_MAX_PENDING, HEAP_HINT); #endif } #ifndef NO_MD5 void bench_hmac_md5(int useDeviceID) { byte key[] = { 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b }; bench_hmac(useDeviceID, WC_MD5, WC_MD5_DIGEST_SIZE, key, sizeof(key), "HMAC-MD5"); } #endif /* NO_MD5 */ #ifndef NO_SHA void bench_hmac_sha(int useDeviceID) { byte key[] = { 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b }; bench_hmac(useDeviceID, WC_SHA, WC_SHA_DIGEST_SIZE, key, sizeof(key), "HMAC-SHA"); } #endif /* NO_SHA */ #ifdef WOLFSSL_SHA224 void bench_hmac_sha224(int useDeviceID) { byte key[] = { 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b }; bench_hmac(useDeviceID, WC_SHA224, WC_SHA224_DIGEST_SIZE, key, sizeof(key), "HMAC-SHA224"); } #endif /* WOLFSSL_SHA224 */ #ifndef NO_SHA256 void bench_hmac_sha256(int useDeviceID) { byte key[] = { 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b }; bench_hmac(useDeviceID, WC_SHA256, WC_SHA256_DIGEST_SIZE, key, sizeof(key), "HMAC-SHA256"); } #endif /* NO_SHA256 */ #ifdef WOLFSSL_SHA384 void bench_hmac_sha384(int useDeviceID) { byte key[] = { 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b }; bench_hmac(useDeviceID, WC_SHA384, WC_SHA384_DIGEST_SIZE, key, sizeof(key), "HMAC-SHA384"); } #endif /* WOLFSSL_SHA384 */ #ifdef WOLFSSL_SHA512 void bench_hmac_sha512(int useDeviceID) { byte key[] = { 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b }; bench_hmac(useDeviceID, WC_SHA512, WC_SHA512_DIGEST_SIZE, key, sizeof(key), "HMAC-SHA512"); } #endif /* WOLFSSL_SHA512 */ #ifndef NO_PWDBASED void bench_pbkdf2(void) { double start; int ret = 0, count = 0; const char* passwd32 = "passwordpasswordpasswordpassword"; const byte salt32[] = { 0x78, 0x57, 0x8E, 0x5a, 0x5d, 0x63, 0xcb, 0x06, 0x78, 0x57, 0x8E, 0x5a, 0x5d, 0x63, 0xcb, 0x06, 0x78, 0x57, 0x8E, 0x5a, 0x5d, 0x63, 0xcb, 0x06, 0x78, 0x57, 0x8E, 0x5a, 0x5d, 0x63, 0xcb, 0x06 }; byte derived[32]; bench_stats_start(&count, &start); do { ret = wc_PBKDF2(derived, (const byte*)passwd32, (int)XSTRLEN(passwd32), salt32, (int)sizeof(salt32), 1000, 32, WC_SHA256); count++; } while (bench_stats_sym_check(start)); bench_stats_sym_finish("PBKDF2", 32, count, 32, start, ret); } #endif /* !NO_PWDBASED */ #endif /* NO_HMAC */ #ifdef WOLFSSL_SIPHASH void bench_siphash(void) { double start; int ret = 0, count; const char* passwd16 = "passwordpassword"; byte out[16]; int i; bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_SipHash((const byte*)passwd16, bench_plain, BENCH_SIZE, out, 8); } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish("SipHash-8", 1, count, BENCH_SIZE, start, ret); bench_stats_start(&count, &start); do { for (i = 0; i < numBlocks; i++) { ret = wc_SipHash((const byte*)passwd16, bench_plain, BENCH_SIZE, out, 16); } count += i; } while (bench_stats_sym_check(start)); bench_stats_sym_finish("SipHash-16", 1, count, BENCH_SIZE, start, ret); } #endif #ifndef NO_RSA #if defined(WOLFSSL_KEY_GEN) static void bench_rsaKeyGen_helper(int useDeviceID, int keySz) { RsaKey genKey[BENCH_MAX_PENDING]; double start; int ret = 0, i, count = 0, times, pending = 0; const long rsa_e_val = WC_RSA_EXPONENT; const char**desc = bench_desc_words[lng_index]; /* clear for done cleanup */ XMEMSET(genKey, 0, sizeof(genKey)); bench_stats_start(&count, &start); do { /* while free pending slots in queue, submit ops */ for (times = 0; times < genTimes || pending > 0; ) { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&genKey[i]), 0, ×, genTimes, &pending)) { wc_FreeRsaKey(&genKey[i]); ret = wc_InitRsaKey_ex(&genKey[i], HEAP_HINT, devId); if (ret < 0) { goto exit; } ret = wc_MakeRsaKey(&genKey[i], keySz, rsa_e_val, &gRng); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&genKey[i]), 0, ×, &pending)) { goto exit; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit: bench_stats_asym_finish("RSA", keySz, desc[2], useDeviceID, count, start, ret); /* cleanup */ for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_FreeRsaKey(&genKey[i]); } } void bench_rsaKeyGen(int useDeviceID) { int k, keySz; #if !defined(WOLFSSL_SP_MATH) || defined(WOLFSSL_SP_MATH_ALL) const int keySizes[2] = {1024, 2048}; #else const int keySizes[1] = {2048}; #endif for (k = 0; k < (int)(sizeof(keySizes)/sizeof(int)); k++) { keySz = keySizes[k]; bench_rsaKeyGen_helper(useDeviceID, keySz); } } void bench_rsaKeyGen_size(int useDeviceID, int keySz) { bench_rsaKeyGen_helper(useDeviceID, keySz); } #endif /* WOLFSSL_KEY_GEN */ #if !defined(USE_CERT_BUFFERS_1024) && !defined(USE_CERT_BUFFERS_2048) && \ !defined(USE_CERT_BUFFERS_3072) #if defined(WOLFSSL_MDK_SHELL) static char *certRSAname = "certs/rsa2048.der"; /* set by shell command */ static void set_Bench_RSA_File(char * cert) { certRSAname = cert ; } #elif defined(FREESCALE_MQX) static char *certRSAname = "a:\\certs\\rsa2048.der"; #else static const char *certRSAname = "certs/rsa2048.der"; #endif #endif #define RSA_BUF_SIZE 384 /* for up to 3072 bit */ #if defined(WOLFSSL_RSA_VERIFY_INLINE) || defined(WOLFSSL_RSA_PUBLIC_ONLY) #if defined(USE_CERT_BUFFERS_2048) static unsigned char rsa_2048_sig[] = { 0x8c, 0x9e, 0x37, 0xbf, 0xc3, 0xa6, 0xba, 0x1c, 0x53, 0x22, 0x40, 0x4b, 0x8b, 0x0d, 0x3c, 0x0e, 0x2e, 0x8c, 0x31, 0x2c, 0x47, 0xbf, 0x03, 0x48, 0x18, 0x46, 0x73, 0x8d, 0xd7, 0xdd, 0x17, 0x64, 0x0d, 0x7f, 0xdc, 0x74, 0xed, 0x80, 0xc3, 0xe8, 0x9a, 0x18, 0x33, 0xd4, 0xe6, 0xc5, 0xe1, 0x54, 0x75, 0xd1, 0xbb, 0x40, 0xde, 0xa8, 0xb9, 0x1b, 0x14, 0xe8, 0xc1, 0x39, 0xeb, 0xa0, 0x69, 0x8a, 0xc6, 0x9b, 0xef, 0x53, 0xb5, 0x23, 0x2b, 0x78, 0x06, 0x43, 0x37, 0x11, 0x81, 0x84, 0x73, 0x33, 0x33, 0xfe, 0xf7, 0x5d, 0x2b, 0x84, 0xd6, 0x83, 0xd6, 0xdd, 0x55, 0x33, 0xef, 0xd1, 0xf7, 0x12, 0xb0, 0xc2, 0x0e, 0xb1, 0x78, 0xd4, 0xa8, 0xa3, 0x25, 0xeb, 0xed, 0x9a, 0xb3, 0xee, 0xc3, 0x7e, 0xce, 0x13, 0x18, 0x86, 0x31, 0xe1, 0xef, 0x01, 0x0f, 0x6e, 0x67, 0x24, 0x74, 0xbd, 0x0b, 0x7f, 0xa9, 0xca, 0x6f, 0xaa, 0x83, 0x28, 0x90, 0x40, 0xf1, 0xb5, 0x10, 0x0e, 0x26, 0x03, 0x05, 0x5d, 0x87, 0xb4, 0xe0, 0x4c, 0x98, 0xd8, 0xc6, 0x42, 0x89, 0x77, 0xeb, 0xb6, 0xd4, 0xe6, 0x26, 0xf3, 0x31, 0x25, 0xde, 0x28, 0x38, 0x58, 0xe8, 0x2c, 0xf4, 0x56, 0x7c, 0xb6, 0xfd, 0x99, 0xb0, 0xb0, 0xf4, 0x83, 0xb6, 0x74, 0xa9, 0x5b, 0x9f, 0xe8, 0xe9, 0xf1, 0xa1, 0x2a, 0xbd, 0xf6, 0x83, 0x28, 0x09, 0xda, 0xa6, 0xd6, 0xcd, 0x61, 0x60, 0xf7, 0x13, 0x4e, 0x46, 0x57, 0x38, 0x1e, 0x11, 0x92, 0x6b, 0x6b, 0xcf, 0xd3, 0xf4, 0x8b, 0x66, 0x03, 0x25, 0xa3, 0x7a, 0x2f, 0xce, 0xc1, 0x85, 0xa5, 0x48, 0x91, 0x8a, 0xb3, 0x4f, 0x5d, 0x98, 0xb1, 0x69, 0x58, 0x47, 0x69, 0x0c, 0x52, 0xdc, 0x42, 0x4c, 0xef, 0xe8, 0xd4, 0x4d, 0x6a, 0x33, 0x7d, 0x9e, 0xd2, 0x51, 0xe6, 0x41, 0xbf, 0x4f, 0xa2 }; #elif defined(USE_CERT_BUFFERS_3072) static unsigned char rsa_3072_sig[] = { 0x1a, 0xd6, 0x0d, 0xfd, 0xe3, 0x41, 0x95, 0x76, 0x27, 0x16, 0x7d, 0xc7, 0x94, 0x16, 0xca, 0xa8, 0x26, 0x08, 0xbe, 0x78, 0x87, 0x72, 0x4c, 0xd9, 0xa7, 0xfc, 0x33, 0x77, 0x2d, 0x53, 0x07, 0xb5, 0x8c, 0xce, 0x48, 0x17, 0x9b, 0xff, 0x9f, 0x9b, 0x17, 0xc4, 0xbb, 0x72, 0xed, 0xdb, 0xa0, 0x34, 0x69, 0x5b, 0xc7, 0x4e, 0xbf, 0xec, 0x13, 0xc5, 0x98, 0x71, 0x9a, 0x4e, 0x18, 0x0e, 0xcb, 0xe7, 0xc6, 0xd5, 0x21, 0x31, 0x7c, 0x0d, 0xae, 0x14, 0x2b, 0x87, 0x4f, 0x77, 0x95, 0x2e, 0x26, 0xe2, 0x83, 0xfe, 0x49, 0x1e, 0x87, 0x19, 0x4a, 0x63, 0x73, 0x75, 0xf1, 0xf5, 0x71, 0xd2, 0xce, 0xd4, 0x39, 0x2b, 0xd9, 0xe0, 0x76, 0x70, 0xc8, 0xf8, 0xed, 0xdf, 0x90, 0x57, 0x17, 0xb9, 0x16, 0xf6, 0xe9, 0x49, 0x48, 0xce, 0x5a, 0x8b, 0xe4, 0x84, 0x7c, 0xf3, 0x31, 0x68, 0x97, 0x45, 0x68, 0x38, 0x50, 0x3a, 0x70, 0xbd, 0xb3, 0xd3, 0xd2, 0xe0, 0x56, 0x5b, 0xc2, 0x0c, 0x2c, 0x10, 0x70, 0x7b, 0xd4, 0x99, 0xf9, 0x38, 0x31, 0xb1, 0x86, 0xa0, 0x07, 0xf1, 0xf6, 0x53, 0xb0, 0x44, 0x82, 0x40, 0xd2, 0xab, 0x0e, 0x71, 0x5d, 0xe1, 0xea, 0x3a, 0x77, 0xc9, 0xef, 0xfe, 0x54, 0x65, 0xa3, 0x49, 0xfd, 0xa5, 0x33, 0xaa, 0x16, 0x1a, 0x38, 0xe7, 0xaa, 0xb7, 0x13, 0xb2, 0x3b, 0xc7, 0x00, 0x87, 0x12, 0xfe, 0xfd, 0xf4, 0x55, 0x6d, 0x1d, 0x4a, 0x0e, 0xad, 0xd0, 0x4c, 0x55, 0x91, 0x60, 0xd9, 0xef, 0x74, 0x69, 0x22, 0x8c, 0x51, 0x65, 0xc2, 0x04, 0xac, 0xd3, 0x8d, 0xf7, 0x35, 0x29, 0x13, 0x6d, 0x61, 0x7c, 0x39, 0x2f, 0x41, 0x4c, 0xdf, 0x38, 0xfd, 0x1a, 0x7d, 0x42, 0xa7, 0x6f, 0x3f, 0x3d, 0x9b, 0xd1, 0x97, 0xab, 0xc0, 0xa7, 0x28, 0x1c, 0xc0, 0x02, 0x26, 0xeb, 0xce, 0xf9, 0xe1, 0x34, 0x45, 0xaf, 0xbf, 0x8d, 0xb8, 0xe0, 0xff, 0xd9, 0x6f, 0x77, 0xf3, 0xf7, 0xed, 0x6a, 0xbb, 0x03, 0x52, 0xfb, 0x38, 0xfc, 0xea, 0x9f, 0xc9, 0x98, 0xed, 0x21, 0x45, 0xaf, 0x43, 0x2b, 0x64, 0x96, 0x82, 0x30, 0xe9, 0xb4, 0x36, 0x89, 0x77, 0x07, 0x4a, 0xc6, 0x1f, 0x38, 0x7a, 0xee, 0xb6, 0x86, 0xf6, 0x2f, 0x03, 0xec, 0xa2, 0xe5, 0x48, 0xe5, 0x5a, 0xf5, 0x1c, 0xd2, 0xd9, 0xd8, 0x2d, 0x9d, 0x06, 0x07, 0xc9, 0x8b, 0x5d, 0xe0, 0x0f, 0x5e, 0x0c, 0x53, 0x27, 0xff, 0x23, 0xee, 0xca, 0x5e, 0x4d, 0xf1, 0x95, 0x77, 0x78, 0x1f, 0xf2, 0x44, 0x5b, 0x7d, 0x01, 0x49, 0x61, 0x6f, 0x6d, 0xbf, 0xf5, 0x19, 0x06, 0x39, 0xe9, 0xe9, 0x29, 0xde, 0x47, 0x5e, 0x2e, 0x1f, 0x68, 0xf4, 0x32, 0x5e, 0xe9, 0xd0, 0xa7, 0xb4, 0x2a, 0x45, 0xdf, 0x15, 0x7d, 0x0d, 0x5b, 0xef, 0xc6, 0x23, 0xac }; #else #error Not Supported Yet! #endif #endif /* WOLFSSL_RSA_VERIFY_INLINE || WOLFSSL_RSA_PUBLIC_ONLY */ static void bench_rsa_helper(int useDeviceID, RsaKey rsaKey[BENCH_MAX_PENDING], int rsaKeySz) { int ret = 0, i, times, count = 0, pending = 0; word32 idx = 0; #ifndef WOLFSSL_RSA_VERIFY_ONLY const char* messageStr = TEST_STRING; const int len = (int)TEST_STRING_SZ; #endif double start = 0.0F; const char**desc = bench_desc_words[lng_index]; #ifndef WOLFSSL_RSA_VERIFY_ONLY WC_DECLARE_VAR(message, byte, TEST_STRING_SZ, HEAP_HINT); #endif WC_DECLARE_ARRAY_DYNAMIC_DEC(enc, byte, BENCH_MAX_PENDING, rsaKeySz, HEAP_HINT); #if !defined(WOLFSSL_RSA_VERIFY_INLINE) && !defined(WOLFSSL_RSA_PUBLIC_ONLY) WC_DECLARE_ARRAY_DYNAMIC_DEC(out, byte, BENCH_MAX_PENDING, rsaKeySz, HEAP_HINT); #else byte* out[BENCH_MAX_PENDING]; #endif WC_DECLARE_ARRAY_DYNAMIC_EXE(enc, byte, BENCH_MAX_PENDING, rsaKeySz, HEAP_HINT); #if !defined(WOLFSSL_RSA_VERIFY_INLINE) && !defined(WOLFSSL_RSA_PUBLIC_ONLY) WC_DECLARE_ARRAY_DYNAMIC_EXE(out, byte, BENCH_MAX_PENDING, rsaKeySz, HEAP_HINT); if (out[0] == NULL) { ret = MEMORY_E; goto exit; } #endif if (enc[0] == NULL) { ret = MEMORY_E; goto exit; } #ifdef WC_DECLARE_VAR_IS_HEAP_ALLOC if (message == NULL) { ret = MEMORY_E; goto exit; } #endif #ifndef WOLFSSL_RSA_VERIFY_ONLY XMEMCPY(message, messageStr, len); #endif if (!rsa_sign_verify) { #ifndef WOLFSSL_RSA_VERIFY_ONLY /* begin public RSA */ bench_stats_start(&count, &start); do { for (times = 0; times < ntimes || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&rsaKey[i]), 1, ×, ntimes, &pending)) { ret = wc_RsaPublicEncrypt(message, (word32)len, enc[i], rsaKeySz/8, &rsaKey[i], GLOBAL_RNG); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV( &rsaKey[i]), 1, ×, &pending)) { goto exit_rsa_verify; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_rsa_verify: bench_stats_asym_finish("RSA", rsaKeySz, desc[0], useDeviceID, count, start, ret); #endif /* !WOLFSSL_RSA_VERIFY_ONLY */ #ifndef WOLFSSL_RSA_PUBLIC_ONLY if (ret < 0) { goto exit; } /* capture resulting encrypt length */ idx = (word32)(rsaKeySz/8); /* begin private async RSA */ bench_stats_start(&count, &start); do { for (times = 0; times < ntimes || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&rsaKey[i]), 1, ×, ntimes, &pending)) { ret = wc_RsaPrivateDecrypt(enc[i], idx, out[i], rsaKeySz/8, &rsaKey[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&rsaKey[i]), 1, ×, &pending)) { goto exit_rsa_pub; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_rsa_pub: bench_stats_asym_finish("RSA", rsaKeySz, desc[1], useDeviceID, count, start, ret); #endif /* !WOLFSSL_RSA_PUBLIC_ONLY */ } else { #if !defined(WOLFSSL_RSA_PUBLIC_ONLY) && !defined(WOLFSSL_RSA_VERIFY_ONLY) /* begin RSA sign */ bench_stats_start(&count, &start); do { for (times = 0; times < ntimes || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&rsaKey[i]), 1, ×, ntimes, &pending)) { ret = wc_RsaSSL_Sign(message, len, enc[i], rsaKeySz/8, &rsaKey[i], &gRng); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&rsaKey[i]), 1, ×, &pending)) { goto exit_rsa_sign; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_rsa_sign: bench_stats_asym_finish("RSA", rsaKeySz, desc[4], useDeviceID, count, start, ret); if (ret < 0) { goto exit; } #endif /* !WOLFSSL_RSA_PUBLIC_ONLY && !WOLFSSL_RSA_VERIFY_ONLY */ /* capture resulting encrypt length */ idx = rsaKeySz/8; /* begin RSA verify */ bench_stats_start(&count, &start); do { for (times = 0; times < ntimes || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&rsaKey[i]), 1, ×, ntimes, &pending)) { #if !defined(WOLFSSL_RSA_VERIFY_INLINE) && \ !defined(WOLFSSL_RSA_PUBLIC_ONLY) ret = wc_RsaSSL_Verify(enc[i], idx, out[i], rsaKeySz/8, &rsaKey[i]); #elif defined(USE_CERT_BUFFERS_2048) XMEMCPY(enc[i], rsa_2048_sig, sizeof(rsa_2048_sig)); idx = sizeof(rsa_2048_sig); out[i] = NULL; ret = wc_RsaSSL_VerifyInline(enc[i], idx, &out[i], &rsaKey[i]); if (ret > 0) ret = 0; #elif defined(USE_CERT_BUFFERS_3072) XMEMCPY(enc[i], rsa_3072_sig, sizeof(rsa_3072_sig)); idx = sizeof(rsa_3072_sig); out[i] = NULL; ret = wc_RsaSSL_VerifyInline(enc[i], idx, &out[i], &rsaKey[i]); if (ret > 0) ret = 0; #endif if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&rsaKey[i]), 1, ×, &pending)) { goto exit_rsa_verifyinline; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_rsa_verifyinline: bench_stats_asym_finish("RSA", rsaKeySz, desc[5], useDeviceID, count, start, ret); } exit: WC_FREE_ARRAY_DYNAMIC(enc, BENCH_MAX_PENDING, HEAP_HINT); #if !defined(WOLFSSL_RSA_VERIFY_INLINE) && !defined(WOLFSSL_RSA_PUBLIC_ONLY) WC_FREE_ARRAY_DYNAMIC(out, BENCH_MAX_PENDING, HEAP_HINT); #endif WC_FREE_VAR(message, HEAP_HINT); } void bench_rsa(int useDeviceID) { int i; RsaKey rsaKey[BENCH_MAX_PENDING]; int ret = 0; int rsaKeySz = 0; const byte* tmp; size_t bytes; #if !defined(WOLFSSL_RSA_PUBLIC_ONLY) && !defined(WOLFSSL_RSA_VERIFY_ONLY) word32 idx; #endif #ifdef USE_CERT_BUFFERS_1024 tmp = rsa_key_der_1024; bytes = (size_t)sizeof_rsa_key_der_1024; rsaKeySz = 1024; #elif defined(USE_CERT_BUFFERS_2048) tmp = rsa_key_der_2048; bytes = (size_t)sizeof_rsa_key_der_2048; rsaKeySz = 2048; #elif defined(USE_CERT_BUFFERS_3072) tmp = rsa_key_der_3072; bytes = (size_t)sizeof_rsa_key_der_3072; rsaKeySz = 3072; #else #error "need a cert buffer size" #endif /* USE_CERT_BUFFERS */ /* clear for done cleanup */ XMEMSET(rsaKey, 0, sizeof(rsaKey)); /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { /* setup an async context for each key */ ret = wc_InitRsaKey_ex(&rsaKey[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID); if (ret < 0) { goto exit_bench_rsa; } #if !defined(WOLFSSL_RSA_PUBLIC_ONLY) && !defined(WOLFSSL_RSA_VERIFY_ONLY) #ifdef WC_RSA_BLINDING ret = wc_RsaSetRNG(&rsaKey[i], &gRng); if (ret != 0) goto exit_bench_rsa; #endif #endif #if !defined(WOLFSSL_RSA_PUBLIC_ONLY) && !defined(WOLFSSL_RSA_VERIFY_ONLY) /* decode the private key */ idx = 0; if ((ret = wc_RsaPrivateKeyDecode(tmp, &idx, &rsaKey[i], (word32)bytes)) != 0) { printf("wc_RsaPrivateKeyDecode failed! %d\n", ret); goto exit_bench_rsa; } #elif defined(WOLFSSL_PUBLIC_MP) /* get offset to public portion of the RSA key */ #ifdef USE_CERT_BUFFERS_1024 bytes = 11; #elif defined(USE_CERT_BUFFERS_2048) || defined(USE_CERT_BUFFERS_3072) bytes = 12; #endif ret = mp_read_unsigned_bin(&rsaKey[i].n, &tmp[bytes], rsaKeySz/8); if (ret != 0) { printf("wc_RsaPrivateKeyDecode failed! %d\n", ret); goto exit_bench_rsa; } ret = mp_set_int(&rsaKey[i].e, WC_RSA_EXPONENT); if (ret != 0) { printf("wc_RsaPrivateKeyDecode failed! %d\n", ret); goto exit_bench_rsa; } #else /* Note: To benchmark public only define WOLFSSL_PUBLIC_MP */ rsaKeySz = 0; #endif } if (rsaKeySz > 0) { bench_rsa_helper(useDeviceID, rsaKey, rsaKeySz); } (void)bytes; (void)tmp; exit_bench_rsa: /* cleanup */ for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_FreeRsaKey(&rsaKey[i]); } } #ifdef WOLFSSL_KEY_GEN /* bench any size of RSA key */ void bench_rsa_key(int useDeviceID, int rsaKeySz) { int ret = 0, i, pending = 0; RsaKey rsaKey[BENCH_MAX_PENDING]; int isPending[BENCH_MAX_PENDING]; long exp = 65537L; /* clear for done cleanup */ XMEMSET(rsaKey, 0, sizeof(rsaKey)); XMEMSET(isPending, 0, sizeof(isPending)); /* init keys */ do { pending = 0; for (i = 0; i < BENCH_MAX_PENDING; i++) { if (!isPending[i]) { /* if making the key is pending then just call * wc_MakeRsaKey again */ /* setup an async context for each key */ if (wc_InitRsaKey_ex(&rsaKey[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID) < 0) { goto exit_bench_rsa_key; } #ifdef WC_RSA_BLINDING ret = wc_RsaSetRNG(&rsaKey[i], &gRng); if (ret != 0) goto exit_bench_rsa_key; #endif } /* create the RSA key */ ret = wc_MakeRsaKey(&rsaKey[i], rsaKeySz, exp, &gRng); if (ret == WC_PENDING_E) { isPending[i] = 1; pending = 1; } else if (ret != 0) { printf("wc_MakeRsaKey failed! %d\n", ret); goto exit_bench_rsa_key; } } /* for i */ } while (pending > 0); bench_rsa_helper(useDeviceID, rsaKey, rsaKeySz); exit_bench_rsa_key: /* cleanup */ for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_FreeRsaKey(&rsaKey[i]); } } #endif /* WOLFSSL_KEY_GEN */ #endif /* !NO_RSA */ #ifndef NO_DH #if !defined(USE_CERT_BUFFERS_1024) && !defined(USE_CERT_BUFFERS_2048) && \ !defined(USE_CERT_BUFFERS_3072) #if defined(WOLFSSL_MDK_SHELL) static char *certDHname = "certs/dh2048.der"; /* set by shell command */ void set_Bench_DH_File(char * cert) { certDHname = cert ; } #elif defined(FREESCALE_MQX) static char *certDHname = "a:\\certs\\dh2048.der"; #elif defined(NO_ASN) /* do nothing, but don't need a file */ #else static const char *certDHname = "certs/dh2048.der"; #endif #endif #ifdef HAVE_FFDHE_4096 #define BENCH_DH_KEY_SIZE 512 /* for 4096 bit */ #else #define BENCH_DH_KEY_SIZE 384 /* for 3072 bit */ #endif #define BENCH_DH_PRIV_SIZE (BENCH_DH_KEY_SIZE/8) void bench_dh(int useDeviceID) { int ret = 0, i; int count = 0, times, pending = 0; const byte* tmp = NULL; double start = 0.0F; DhKey dhKey[BENCH_MAX_PENDING]; int dhKeySz = BENCH_DH_KEY_SIZE * 8; /* used in printf */ const char**desc = bench_desc_words[lng_index]; #ifndef NO_ASN size_t bytes = 0; word32 idx; #endif word32 pubSz[BENCH_MAX_PENDING]; word32 privSz[BENCH_MAX_PENDING]; word32 pubSz2 = BENCH_DH_KEY_SIZE; word32 privSz2 = BENCH_DH_PRIV_SIZE; word32 agreeSz[BENCH_MAX_PENDING]; #if defined(HAVE_FFDHE_2048) || defined(HAVE_FFDHE_3072) #ifdef HAVE_PUBLIC_FFDHE const DhParams *params = NULL; #else int paramName = 0; #endif #endif WC_DECLARE_ARRAY(pub, byte, BENCH_MAX_PENDING, BENCH_DH_KEY_SIZE, HEAP_HINT); WC_DECLARE_VAR(pub2, byte, BENCH_DH_KEY_SIZE, HEAP_HINT); WC_DECLARE_ARRAY(agree, byte, BENCH_MAX_PENDING, BENCH_DH_KEY_SIZE, HEAP_HINT); WC_DECLARE_ARRAY(priv, byte, BENCH_MAX_PENDING, BENCH_DH_PRIV_SIZE, HEAP_HINT); WC_DECLARE_VAR(priv2, byte, BENCH_DH_PRIV_SIZE, HEAP_HINT); WC_INIT_ARRAY(pub, byte, BENCH_MAX_PENDING, BENCH_DH_KEY_SIZE, HEAP_HINT); WC_INIT_ARRAY(agree, byte, BENCH_MAX_PENDING, BENCH_DH_KEY_SIZE, HEAP_HINT); WC_INIT_ARRAY(priv, byte, BENCH_MAX_PENDING, BENCH_DH_PRIV_SIZE, HEAP_HINT); #ifdef WC_DECLARE_VAR_IS_HEAP_ALLOC if (pub[0] == NULL || pub2 == NULL || agree[0] == NULL || priv[0] == NULL || priv2 == NULL) { ret = MEMORY_E; goto exit; } #endif (void)tmp; if (!use_ffdhe) { #if defined(NO_ASN) dhKeySz = 1024; /* do nothing, but don't use default FILE */ #elif defined(USE_CERT_BUFFERS_1024) tmp = dh_key_der_1024; bytes = (size_t)sizeof_dh_key_der_1024; dhKeySz = 1024; #elif defined(USE_CERT_BUFFERS_2048) tmp = dh_key_der_2048; bytes = (size_t)sizeof_dh_key_der_2048; dhKeySz = 2048; #elif defined(USE_CERT_BUFFERS_3072) tmp = dh_key_der_3072; bytes = (size_t)sizeof_dh_key_der_3072; dhKeySz = 3072; #else #error "need to define a cert buffer size" #endif /* USE_CERT_BUFFERS */ } #ifdef HAVE_FFDHE_2048 else if (use_ffdhe == 2048) { #ifdef HAVE_PUBLIC_FFDHE params = wc_Dh_ffdhe2048_Get(); #else paramName = WC_FFDHE_2048; #endif dhKeySz = 2048; } #endif #ifdef HAVE_FFDHE_3072 else if (use_ffdhe == 3072) { #ifdef HAVE_PUBLIC_FFDHE params = wc_Dh_ffdhe3072_Get(); #else paramName = WC_FFDHE_3072; #endif dhKeySz = 3072; } #endif #ifdef HAVE_FFDHE_4096 else if (use_ffdhe == 4096) { #ifdef HAVE_PUBLIC_FFDHE params = wc_Dh_ffdhe4096_Get(); #else paramName = WC_FFDHE_4096; #endif dhKeySz = 4096; } #endif /* clear for done cleanup */ XMEMSET(dhKey, 0, sizeof(dhKey)); /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { /* setup an async context for each key */ ret = wc_InitDhKey_ex(&dhKey[i], HEAP_HINT, useDeviceID ? devId : INVALID_DEVID); if (ret != 0) goto exit; /* setup key */ if (!use_ffdhe) { #ifdef NO_ASN ret = wc_DhSetKey(&dhKey[i], dh_p, sizeof(dh_p), dh_g, sizeof(dh_g)); #else idx = 0; ret = wc_DhKeyDecode(tmp, &idx, &dhKey[i], (word32)bytes); #endif } #if defined(HAVE_FFDHE_2048) || defined(HAVE_FFDHE_3072) #ifdef HAVE_PUBLIC_FFDHE else if (params != NULL) { ret = wc_DhSetKey(&dhKey[i], params->p, params->p_len, params->g, params->g_len); } #else else if (paramName != 0) { ret = wc_DhSetNamedKey(&dhKey[i], paramName); } #endif #endif if (ret != 0) { printf("DhKeyDecode failed %d, can't benchmark\n", ret); goto exit; } } /* Key Gen */ bench_stats_start(&count, &start); PRIVATE_KEY_UNLOCK(); do { /* while free pending slots in queue, submit ops */ for (times = 0; times < genTimes || pending > 0; ) { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&dhKey[i]), 0, ×, genTimes, &pending)) { privSz[i] = BENCH_DH_PRIV_SIZE; pubSz[i] = BENCH_DH_KEY_SIZE; ret = wc_DhGenerateKeyPair(&dhKey[i], &gRng, priv[i], &privSz[i], pub[i], &pubSz[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&dhKey[i]), 0, ×, &pending)) { goto exit_dh_gen; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); PRIVATE_KEY_LOCK(); exit_dh_gen: bench_stats_asym_finish("DH", dhKeySz, desc[2], useDeviceID, count, start, ret); if (ret < 0) { goto exit; } /* Generate key to use as other public */ PRIVATE_KEY_UNLOCK(); ret = wc_DhGenerateKeyPair(&dhKey[0], &gRng, priv2, &privSz2, pub2, &pubSz2); PRIVATE_KEY_LOCK(); #ifdef WOLFSSL_ASYNC_CRYPT ret = wc_AsyncWait(ret, &dhKey[0].asyncDev, WC_ASYNC_FLAG_NONE); #endif /* Key Agree */ bench_stats_start(&count, &start); PRIVATE_KEY_UNLOCK(); do { for (times = 0; times < agreeTimes || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&dhKey[i]), 0, ×, agreeTimes, &pending)) { ret = wc_DhAgree(&dhKey[i], agree[i], &agreeSz[i], priv[i], privSz[i], pub2, pubSz2); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&dhKey[i]), 0, ×, &pending)) { goto exit; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); PRIVATE_KEY_LOCK(); exit: bench_stats_asym_finish("DH", dhKeySz, desc[3], useDeviceID, count, start, ret); /* cleanup */ for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_FreeDhKey(&dhKey[i]); } WC_FREE_ARRAY(pub, BENCH_MAX_PENDING, HEAP_HINT); WC_FREE_VAR(pub2, HEAP_HINT); WC_FREE_ARRAY(priv, BENCH_MAX_PENDING, HEAP_HINT); WC_FREE_VAR(priv2, HEAP_HINT); WC_FREE_ARRAY(agree, BENCH_MAX_PENDING, HEAP_HINT); } #endif /* !NO_DH */ #ifdef HAVE_ECC /* +8 for 'ECDSA [%s]' and null terminator */ #define BENCH_ECC_NAME_SZ (ECC_MAXNAME + 8) /* run all benchmarks on a curve */ void bench_ecc_curve(int curveId) { if (bench_all || (bench_asym_algs & BENCH_ECC_MAKEKEY)) { #ifndef NO_SW_BENCH bench_eccMakeKey(0, curveId); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_ECC) && \ !defined(NO_HW_BENCH) bench_eccMakeKey(1, curveId); #endif } if (bench_all || (bench_asym_algs & BENCH_ECC)) { #ifndef NO_SW_BENCH bench_ecc(0, curveId); #endif #if defined(WOLFSSL_ASYNC_CRYPT) && defined(WC_ASYNC_ENABLE_ECC) && \ !defined(NO_HW_BENCH) bench_ecc(1, curveId); #endif } #ifdef HAVE_ECC_ENCRYPT if (bench_all || (bench_asym_algs & BENCH_ECC_ENCRYPT)) bench_eccEncrypt(curveId); #endif } void bench_eccMakeKey(int useDeviceID, int curveId) { int ret = 0, i, times, count, pending = 0; int deviceID; int keySize; ecc_key genKey[BENCH_MAX_PENDING]; char name[BENCH_ECC_NAME_SZ]; double start; const char**desc = bench_desc_words[lng_index]; #ifdef WOLFSSL_ASYNC_CRYPT deviceID = useDeviceID ? devId : INVALID_DEVID; #else deviceID = devId; #endif keySize = wc_ecc_get_curve_size_from_id(curveId); /* clear for done cleanup */ XMEMSET(&genKey, 0, sizeof(genKey)); /* ECC Make Key */ bench_stats_start(&count, &start); do { /* while free pending slots in queue, submit ops */ for (times = 0; times < agreeTimes || pending > 0; ) { bench_async_poll(&pending); for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&genKey[i]), 0, ×, agreeTimes, &pending)) { wc_ecc_free(&genKey[i]); ret = wc_ecc_init_ex(&genKey[i], HEAP_HINT, deviceID); if (ret < 0) { goto exit; } ret = wc_ecc_make_key_ex(&gRng, keySize, &genKey[i], curveId); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&genKey[i]), 0, ×, &pending)) { goto exit; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit: (void)XSNPRINTF(name, BENCH_ECC_NAME_SZ, "ECC [%15s]", wc_ecc_get_name(curveId)); bench_stats_asym_finish(name, keySize * 8, desc[2], useDeviceID, count, start, ret); /* cleanup */ for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_ecc_free(&genKey[i]); } } void bench_ecc(int useDeviceID, int curveId) { int ret = 0, i, times, count, pending = 0; int deviceID; int keySize; char name[BENCH_ECC_NAME_SZ]; ecc_key genKey[BENCH_MAX_PENDING]; #ifdef HAVE_ECC_DHE ecc_key genKey2[BENCH_MAX_PENDING]; #endif #if !defined(NO_ASN) && defined(HAVE_ECC_SIGN) #ifdef HAVE_ECC_VERIFY int verify[BENCH_MAX_PENDING]; #endif #endif word32 x[BENCH_MAX_PENDING]; double start = 0; const char**desc = bench_desc_words[lng_index]; #ifdef HAVE_ECC_DHE WC_DECLARE_ARRAY(shared, byte, BENCH_MAX_PENDING, MAX_ECC_BYTES, HEAP_HINT); #endif #if !defined(NO_ASN) && defined(HAVE_ECC_SIGN) WC_DECLARE_ARRAY(sig, byte, BENCH_MAX_PENDING, ECC_MAX_SIG_SIZE, HEAP_HINT); WC_DECLARE_ARRAY(digest, byte, BENCH_MAX_PENDING, MAX_ECC_BYTES, HEAP_HINT); #endif #ifdef HAVE_ECC_DHE WC_INIT_ARRAY(shared, byte, BENCH_MAX_PENDING, MAX_ECC_BYTES, HEAP_HINT); #endif #if !defined(NO_ASN) && defined(HAVE_ECC_SIGN) WC_INIT_ARRAY(sig, byte, BENCH_MAX_PENDING, ECC_MAX_SIG_SIZE, HEAP_HINT); WC_INIT_ARRAY(digest, byte, BENCH_MAX_PENDING, MAX_ECC_BYTES, HEAP_HINT); #endif #ifdef WOLFSSL_ASYNC_CRYPT deviceID = useDeviceID ? devId : INVALID_DEVID; #else deviceID = devId; #endif /* clear for done cleanup */ XMEMSET(&genKey, 0, sizeof(genKey)); #ifdef HAVE_ECC_DHE XMEMSET(&genKey2, 0, sizeof(genKey2)); #endif keySize = wc_ecc_get_curve_size_from_id(curveId); /* init keys */ for (i = 0; i < BENCH_MAX_PENDING; i++) { /* setup an context for each key */ if ((ret = wc_ecc_init_ex(&genKey[i], HEAP_HINT, deviceID)) < 0) { goto exit; } ret = wc_ecc_make_key_ex(&gRng, keySize, &genKey[i], curveId); #ifdef WOLFSSL_ASYNC_CRYPT ret = wc_AsyncWait(ret, &genKey[i].asyncDev, WC_ASYNC_FLAG_NONE); #endif if (ret < 0) { goto exit; } #ifdef HAVE_ECC_DHE if ((ret = wc_ecc_init_ex(&genKey2[i], HEAP_HINT, deviceID)) < 0) { goto exit; } if ((ret = wc_ecc_make_key_ex(&gRng, keySize, &genKey2[i], curveId)) > 0) { goto exit; } #endif } #ifdef HAVE_ECC_DHE #if defined(ECC_TIMING_RESISTANT) && (!defined(HAVE_FIPS) || \ (!defined(HAVE_FIPS_VERSION) || (HAVE_FIPS_VERSION != 2))) && \ !defined(HAVE_SELFTEST) for (i = 0; i < BENCH_MAX_PENDING; i++) { (void)wc_ecc_set_rng(&genKey[i], &gRng); } #endif /* ECC Shared Secret */ bench_stats_start(&count, &start); PRIVATE_KEY_UNLOCK(); do { for (times = 0; times < agreeTimes || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&genKey[i]), 1, ×, agreeTimes, &pending)) { x[i] = (word32)keySize; ret = wc_ecc_shared_secret(&genKey[i], &genKey2[i], shared[i], &x[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&genKey[i]), 1, ×, &pending)) { goto exit_ecdhe; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); PRIVATE_KEY_UNLOCK(); exit_ecdhe: (void)XSNPRINTF(name, BENCH_ECC_NAME_SZ, "ECDHE [%15s]", wc_ecc_get_name(curveId)); bench_stats_asym_finish(name, keySize * 8, desc[3], useDeviceID, count, start, ret); if (ret < 0) { goto exit; } #endif /* HAVE_ECC_DHE */ #if !defined(NO_ASN) && defined(HAVE_ECC_SIGN) /* Init digest to sign */ for (i = 0; i < BENCH_MAX_PENDING; i++) { for (count = 0; count < keySize; count++) { digest[i][count] = (byte)count; } } /* ECC Sign */ bench_stats_start(&count, &start); do { for (times = 0; times < agreeTimes || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&genKey[i]), 1, ×, agreeTimes, &pending)) { if (genKey[i].state == 0) x[i] = ECC_MAX_SIG_SIZE; ret = wc_ecc_sign_hash(digest[i], (word32)keySize, sig[i], &x[i], &gRng, &genKey[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&genKey[i]), 1, ×, &pending)) { goto exit_ecdsa_sign; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_ecdsa_sign: (void)XSNPRINTF(name, BENCH_ECC_NAME_SZ, "ECDSA [%15s]", wc_ecc_get_name(curveId)); bench_stats_asym_finish(name, keySize * 8, desc[4], useDeviceID, count, start, ret); if (ret < 0) { goto exit; } #ifdef HAVE_ECC_VERIFY /* ECC Verify */ bench_stats_start(&count, &start); do { for (times = 0; times < agreeTimes || pending > 0; ) { bench_async_poll(&pending); /* while free pending slots in queue, submit ops */ for (i = 0; i < BENCH_MAX_PENDING; i++) { if (bench_async_check(&ret, BENCH_ASYNC_GET_DEV(&genKey[i]), 1, ×, agreeTimes, &pending)) { if (genKey[i].state == 0) verify[i] = 0; ret = wc_ecc_verify_hash(sig[i], x[i], digest[i], (word32)keySize, &verify[i], &genKey[i]); if (!bench_async_handle(&ret, BENCH_ASYNC_GET_DEV(&genKey[i]), 1, ×, &pending)) { goto exit_ecdsa_verify; } } } /* for i */ } /* for times */ count += times; } while (bench_stats_sym_check(start)); exit_ecdsa_verify: (void)XSNPRINTF(name, BENCH_ECC_NAME_SZ, "ECDSA [%15s]", wc_ecc_get_name(curveId)); bench_stats_asym_finish(name, keySize * 8, desc[5], useDeviceID, count, start, ret); #endif /* HAVE_ECC_VERIFY */ #endif /* !NO_ASN && HAVE_ECC_SIGN */ exit: /* cleanup */ for (i = 0; i < BENCH_MAX_PENDING; i++) { wc_ecc_free(&genKey[i]); #ifdef HAVE_ECC_DHE wc_ecc_free(&genKey2[i]); #endif } #ifdef HAVE_ECC_DHE WC_FREE_ARRAY(shared, BENCH_MAX_PENDING, HEAP_HINT); #endif #if !defined(NO_ASN) && defined(HAVE_ECC_SIGN) WC_FREE_ARRAY(sig, BENCH_MAX_PENDING, HEAP_HINT); WC_FREE_ARRAY(digest, BENCH_MAX_PENDING, HEAP_HINT); #endif (void)useDeviceID; (void)pending; (void)x; (void)count; (void)times; (void)desc; (void)start; (void)name; } #ifdef HAVE_ECC_ENCRYPT void bench_eccEncrypt(int curveId) { ecc_key userA, userB; int keySize; byte msg[48]; byte out[sizeof(msg) + WC_SHA256_DIGEST_SIZE + (MAX_ECC_BITS+3)/4 + 2]; word32 outSz = sizeof(out); word32 bench_plainSz = BENCH_SIZE; int ret, i, count; double start; const char**desc = bench_desc_words[lng_index]; char name[BENCH_ECC_NAME_SZ]; keySize = wc_ecc_get_curve_size_from_id(curveId); ret = wc_ecc_init_ex(&userA, HEAP_HINT, devId); if (ret != 0) { printf("wc_ecc_encrypt make key A failed: %d\n", ret); return; } ret = wc_ecc_init_ex(&userB, HEAP_HINT, devId); if (ret != 0) { printf("wc_ecc_encrypt make key B failed: %d\n", ret); wc_ecc_free(&userA); return; } #if defined(ECC_TIMING_RESISTANT) && (!defined(HAVE_FIPS) || \ (!defined(HAVE_FIPS_VERSION) || (HAVE_FIPS_VERSION != 2))) && \ !defined(HAVE_SELFTEST) ret = wc_ecc_set_rng(&userA, &gRng); if (ret != 0) { goto exit; } ret = wc_ecc_set_rng(&userB, &gRng); if (ret != 0) { goto exit; } #endif ret = wc_ecc_make_key_ex(&gRng, keySize, &userA, curveId); #ifdef WOLFSSL_ASYNC_CRYPT ret = wc_AsyncWait(ret, &userA.asyncDev, WC_ASYNC_FLAG_NONE); #endif if (ret != 0) goto exit; ret = wc_ecc_make_key_ex(&gRng, keySize, &userB, curveId); #ifdef WOLFSSL_ASYNC_CRYPT ret = wc_AsyncWait(ret, &userB.asyncDev, WC_ASYNC_FLAG_NONE); #endif if (ret != 0) goto exit; for (i = 0; i < (int)sizeof(msg); i++) msg[i] = i; bench_stats_start(&count, &start); do { for (i = 0; i < ntimes; i++) { /* encrypt msg to B */ ret = wc_ecc_encrypt(&userA, &userB, msg, sizeof(msg), out, &outSz, NULL); if (ret != 0) { printf("wc_ecc_encrypt failed! %d\n", ret); goto exit_enc; } } count += i; } while (bench_stats_sym_check(start)); exit_enc: (void)XSNPRINTF(name, BENCH_ECC_NAME_SZ, "ECC [%15s]", wc_ecc_get_name(curveId)); bench_stats_asym_finish(name, keySize * 8, desc[6], 0, count, start, ret); bench_stats_start(&count, &start); do { for (i = 0; i < ntimes; i++) { /* decrypt msg from A */ ret = wc_ecc_decrypt(&userB, &userA, out, outSz, bench_plain, &bench_plainSz, NULL); if (ret != 0) { printf("wc_ecc_decrypt failed! %d\n", ret); goto exit_dec; } } count += i; } while (bench_stats_sym_check(start)); exit_dec: bench_stats_asym_finish(name, keySize * 8, desc[7], 0, count, start, ret); exit: /* cleanup */ wc_ecc_free(&userB); wc_ecc_free(&userA); } #endif #endif /* HAVE_ECC */ #ifdef HAVE_CURVE25519 void bench_curve25519KeyGen(void) { curve25519_key genKey; double start; int ret = 0, i, count; const char**desc = bench_desc_words[lng_index]; /* Key Gen */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { ret = wc_curve25519_make_key(&gRng, 32, &genKey); wc_curve25519_free(&genKey); if (ret != 0) { printf("wc_curve25519_make_key failed: %d\n", ret); break; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("CURVE", 25519, desc[2], 0, count, start, ret); } #ifdef HAVE_CURVE25519_SHARED_SECRET void bench_curve25519KeyAgree(void) { curve25519_key genKey, genKey2; double start; int ret, i, count; byte shared[32]; const char**desc = bench_desc_words[lng_index]; word32 x = 0; wc_curve25519_init_ex(&genKey, HEAP_HINT, devId); wc_curve25519_init_ex(&genKey2, HEAP_HINT, devId); ret = wc_curve25519_make_key(&gRng, 32, &genKey); if (ret != 0) { printf("curve25519_make_key failed\n"); return; } ret = wc_curve25519_make_key(&gRng, 32, &genKey2); if (ret != 0) { printf("curve25519_make_key failed: %d\n", ret); wc_curve25519_free(&genKey); return; } /* Shared secret */ bench_stats_start(&count, &start); do { for (i = 0; i < agreeTimes; i++) { x = sizeof(shared); ret = wc_curve25519_shared_secret(&genKey, &genKey2, shared, &x); if (ret != 0) { printf("curve25519_shared_secret failed: %d\n", ret); goto exit; } } count += i; } while (bench_stats_sym_check(start)); exit: bench_stats_asym_finish("CURVE", 25519, desc[3], 0, count, start, ret); wc_curve25519_free(&genKey2); wc_curve25519_free(&genKey); } #endif /* HAVE_CURVE25519_SHARED_SECRET */ #endif /* HAVE_CURVE25519 */ #ifdef HAVE_ED25519 void bench_ed25519KeyGen(void) { ed25519_key genKey; double start; int i, count; const char**desc = bench_desc_words[lng_index]; /* Key Gen */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { wc_ed25519_init(&genKey); (void)wc_ed25519_make_key(&gRng, 32, &genKey); wc_ed25519_free(&genKey); } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("ED", 25519, desc[2], 0, count, start, 0); } void bench_ed25519KeySign(void) { int ret; ed25519_key genKey; #ifdef HAVE_ED25519_SIGN double start; int i, count; byte sig[ED25519_SIG_SIZE]; byte msg[512]; word32 x = 0; const char**desc = bench_desc_words[lng_index]; #endif wc_ed25519_init(&genKey); ret = wc_ed25519_make_key(&gRng, ED25519_KEY_SIZE, &genKey); if (ret != 0) { printf("ed25519_make_key failed\n"); return; } #ifdef HAVE_ED25519_SIGN /* make dummy msg */ for (i = 0; i < (int)sizeof(msg); i++) msg[i] = (byte)i; bench_stats_start(&count, &start); do { for (i = 0; i < agreeTimes; i++) { x = sizeof(sig); ret = wc_ed25519_sign_msg(msg, sizeof(msg), sig, &x, &genKey); if (ret != 0) { printf("ed25519_sign_msg failed\n"); goto exit_ed_sign; } } count += i; } while (bench_stats_sym_check(start)); exit_ed_sign: bench_stats_asym_finish("ED", 25519, desc[4], 0, count, start, ret); #ifdef HAVE_ED25519_VERIFY bench_stats_start(&count, &start); do { for (i = 0; i < agreeTimes; i++) { int verify = 0; ret = wc_ed25519_verify_msg(sig, x, msg, sizeof(msg), &verify, &genKey); if (ret != 0 || verify != 1) { printf("ed25519_verify_msg failed\n"); goto exit_ed_verify; } } count += i; } while (bench_stats_sym_check(start)); exit_ed_verify: bench_stats_asym_finish("ED", 25519, desc[5], 0, count, start, ret); #endif /* HAVE_ED25519_VERIFY */ #endif /* HAVE_ED25519_SIGN */ wc_ed25519_free(&genKey); } #endif /* HAVE_ED25519 */ #ifdef HAVE_CURVE448 void bench_curve448KeyGen(void) { curve448_key genKey; double start; int ret = 0, i, count; const char**desc = bench_desc_words[lng_index]; /* Key Gen */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { ret = wc_curve448_make_key(&gRng, 56, &genKey); wc_curve448_free(&genKey); if (ret != 0) { printf("wc_curve448_make_key failed: %d\n", ret); break; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("CURVE", 448, desc[2], 0, count, start, ret); } #ifdef HAVE_CURVE448_SHARED_SECRET void bench_curve448KeyAgree(void) { curve448_key genKey, genKey2; double start; int ret, i, count; byte shared[56]; const char**desc = bench_desc_words[lng_index]; word32 x = 0; wc_curve448_init(&genKey); wc_curve448_init(&genKey2); ret = wc_curve448_make_key(&gRng, 56, &genKey); if (ret != 0) { printf("curve448_make_key failed\n"); return; } ret = wc_curve448_make_key(&gRng, 56, &genKey2); if (ret != 0) { printf("curve448_make_key failed: %d\n", ret); wc_curve448_free(&genKey); return; } /* Shared secret */ bench_stats_start(&count, &start); do { for (i = 0; i < agreeTimes; i++) { x = sizeof(shared); ret = wc_curve448_shared_secret(&genKey, &genKey2, shared, &x); if (ret != 0) { printf("curve448_shared_secret failed: %d\n", ret); goto exit; } } count += i; } while (bench_stats_sym_check(start)); exit: bench_stats_asym_finish("CURVE", 448, desc[3], 0, count, start, ret); wc_curve448_free(&genKey2); wc_curve448_free(&genKey); } #endif /* HAVE_CURVE448_SHARED_SECRET */ #endif /* HAVE_CURVE448 */ #ifdef HAVE_ED448 void bench_ed448KeyGen(void) { ed448_key genKey; double start; int i, count; const char**desc = bench_desc_words[lng_index]; /* Key Gen */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { wc_ed448_init(&genKey); (void)wc_ed448_make_key(&gRng, ED448_KEY_SIZE, &genKey); wc_ed448_free(&genKey); } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("ED", 448, desc[2], 0, count, start, 0); } void bench_ed448KeySign(void) { int ret; ed448_key genKey; #ifdef HAVE_ED448_SIGN double start; int i, count; byte sig[ED448_SIG_SIZE]; byte msg[512]; word32 x = 0; const char**desc = bench_desc_words[lng_index]; #endif wc_ed448_init(&genKey); ret = wc_ed448_make_key(&gRng, ED448_KEY_SIZE, &genKey); if (ret != 0) { printf("ed448_make_key failed\n"); return; } #ifdef HAVE_ED448_SIGN /* make dummy msg */ for (i = 0; i < (int)sizeof(msg); i++) msg[i] = (byte)i; bench_stats_start(&count, &start); do { for (i = 0; i < agreeTimes; i++) { x = sizeof(sig); ret = wc_ed448_sign_msg(msg, sizeof(msg), sig, &x, &genKey, NULL, 0); if (ret != 0) { printf("ed448_sign_msg failed\n"); goto exit_ed_sign; } } count += i; } while (bench_stats_sym_check(start)); exit_ed_sign: bench_stats_asym_finish("ED", 448, desc[4], 0, count, start, ret); #ifdef HAVE_ED448_VERIFY bench_stats_start(&count, &start); do { for (i = 0; i < agreeTimes; i++) { int verify = 0; ret = wc_ed448_verify_msg(sig, x, msg, sizeof(msg), &verify, &genKey, NULL, 0); if (ret != 0 || verify != 1) { printf("ed448_verify_msg failed\n"); goto exit_ed_verify; } } count += i; } while (bench_stats_sym_check(start)); exit_ed_verify: bench_stats_asym_finish("ED", 448, desc[5], 0, count, start, ret); #endif /* HAVE_ED448_VERIFY */ #endif /* HAVE_ED448_SIGN */ wc_ed448_free(&genKey); } #endif /* HAVE_ED448 */ #ifdef WOLFCRYPT_HAVE_ECCSI #ifdef WOLFCRYPT_ECCSI_KMS void bench_eccsiKeyGen(void) { EccsiKey genKey; double start; int i, count; const char**desc = bench_desc_words[lng_index]; int ret; /* Key Gen */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { wc_InitEccsiKey(&genKey, NULL, INVALID_DEVID); ret = wc_MakeEccsiKey(&genKey, &gRng); if (ret != 0) { printf("wc_MakeEccsiKey failed: %d\n", ret); break; } wc_FreeEccsiKey(&genKey); } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("ECCSI", 256, desc[2], 0, count, start, 0); } void bench_eccsiPairGen(void) { EccsiKey genKey; double start; int i, count; const char**desc = bench_desc_words[lng_index]; mp_int ssk; ecc_point* pvt; byte id[] = { 0x01, 0x23, 0x34, 0x45 }; int ret; (void)mp_init(&ssk); pvt = wc_ecc_new_point(); wc_InitEccsiKey(&genKey, NULL, INVALID_DEVID); (void)wc_MakeEccsiKey(&genKey, &gRng); /* RSK Gen */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { ret = wc_MakeEccsiPair(&genKey, &gRng, WC_HASH_TYPE_SHA256, id, sizeof(id), &ssk, pvt); if (ret != 0) { printf("wc_MakeEccsiPair failed: %d\n", ret); break; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("ECCSI", 256, desc[12], 0, count, start, 0); wc_FreeEccsiKey(&genKey); wc_ecc_del_point(pvt); mp_free(&ssk); } #endif #ifdef WOLFCRYPT_ECCSI_CLIENT void bench_eccsiValidate(void) { EccsiKey genKey; double start; int i, count; const char**desc = bench_desc_words[lng_index]; mp_int ssk; ecc_point* pvt; byte id[] = { 0x01, 0x23, 0x34, 0x45 }; int valid; int ret; (void)mp_init(&ssk); pvt = wc_ecc_new_point(); wc_InitEccsiKey(&genKey, NULL, INVALID_DEVID); (void)wc_MakeEccsiKey(&genKey, &gRng); (void)wc_MakeEccsiPair(&genKey, &gRng, WC_HASH_TYPE_SHA256, id, sizeof(id), &ssk, pvt); /* Validation of RSK */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { ret = wc_ValidateEccsiPair(&genKey, WC_HASH_TYPE_SHA256, id, sizeof(id), &ssk, pvt, &valid); if (ret != 0 || !valid) { printf("wc_ValidateEccsiPair failed: %d (valid=%d))\n", ret, valid); break; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("ECCSI", 256, desc[11], 0, count, start, 0); wc_FreeEccsiKey(&genKey); wc_ecc_del_point(pvt); mp_free(&ssk); } void bench_eccsi(void) { EccsiKey genKey; double start; int i, count; const char**desc = bench_desc_words[lng_index]; mp_int ssk; ecc_point* pvt; byte id[] = { 0x01, 0x23, 0x34, 0x45 }; byte msg[] = { 0x01, 0x23, 0x34, 0x45 }; byte hash[WC_SHA256_DIGEST_SIZE]; byte hashSz = (byte)sizeof(hash); byte sig[257]; word32 sigSz = sizeof(sig); int ret; int verified; (void)mp_init(&ssk); pvt = wc_ecc_new_point(); (void)wc_InitEccsiKey(&genKey, NULL, INVALID_DEVID); (void)wc_MakeEccsiKey(&genKey, &gRng); (void)wc_MakeEccsiPair(&genKey, &gRng, WC_HASH_TYPE_SHA256, id, sizeof(id), &ssk, pvt); (void)wc_HashEccsiId(&genKey, WC_HASH_TYPE_SHA256, id, sizeof(id), pvt, hash, &hashSz); (void)wc_SetEccsiHash(&genKey, hash, hashSz); (void)wc_SetEccsiPair(&genKey, &ssk, pvt); /* Encapsulate */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { ret = wc_SignEccsiHash(&genKey, &gRng, WC_HASH_TYPE_SHA256, msg, sizeof(msg), sig, &sigSz); if (ret != 0) { printf("wc_SignEccsiHash failed: %d\n", ret); break; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("ECCSI", 256, desc[4], 0, count, start, 0); /* Derive */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { ret = wc_VerifyEccsiHash(&genKey, WC_HASH_TYPE_SHA256, msg, sizeof(msg), sig, sigSz, &verified); if (ret != 0 || !verified) { printf("wc_VerifyEccsiHash failed: %d (verified: %d)\n", ret, verified); break; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("ECCSI", 256, desc[5], 0, count, start, 0); wc_FreeEccsiKey(&genKey); wc_ecc_del_point(pvt); } #endif /* WOLFCRYPT_ECCSI_CLIENT */ #endif /* WOLFCRYPT_HAVE_ECCSI */ #ifdef WOLFCRYPT_HAVE_SAKKE #ifdef WOLFCRYPT_SAKKE_KMS void bench_sakkeKeyGen(void) { SakkeKey genKey; double start; int i, count; const char**desc = bench_desc_words[lng_index]; int ret; /* Key Gen */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { wc_InitSakkeKey_ex(&genKey, 128, ECC_SAKKE_1, NULL, INVALID_DEVID); ret = wc_MakeSakkeKey(&genKey, &gRng); if (ret != 0) { printf("wc_MakeSakkeKey failed: %d\n", ret); break; } wc_FreeSakkeKey(&genKey); } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("SAKKE", 1024, desc[2], 0, count, start, 0); } void bench_sakkeRskGen(void) { SakkeKey genKey; double start; int i, count; const char**desc = bench_desc_words[lng_index]; ecc_point* rsk; byte id[] = { 0x01, 0x23, 0x34, 0x45 }; int ret; rsk = wc_ecc_new_point(); wc_InitSakkeKey_ex(&genKey, 128, ECC_SAKKE_1, NULL, INVALID_DEVID); (void)wc_MakeSakkeKey(&genKey, &gRng); /* RSK Gen */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { ret = wc_MakeSakkeRsk(&genKey, id, sizeof(id), rsk); if (ret != 0) { printf("wc_MakeSakkeRsk failed: %d\n", ret); break; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("SAKKE", 1024, desc[8], 0, count, start, 0); wc_FreeSakkeKey(&genKey); wc_ecc_del_point(rsk); } #endif #ifdef WOLFCRYPT_SAKKE_CLIENT void bench_sakkeValidate(void) { SakkeKey genKey; double start; int i, count; const char**desc = bench_desc_words[lng_index]; ecc_point* rsk; byte id[] = { 0x01, 0x23, 0x34, 0x45 }; int valid; int ret; rsk = wc_ecc_new_point(); (void)wc_InitSakkeKey_ex(&genKey, 128, ECC_SAKKE_1, NULL, INVALID_DEVID); (void)wc_MakeSakkeKey(&genKey, &gRng); (void)wc_MakeSakkeRsk(&genKey, id, sizeof(id), rsk); (void)wc_ValidateSakkeRsk(&genKey, id, sizeof(id), rsk, &valid); /* Validation of RSK */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { ret = wc_ValidateSakkeRsk(&genKey, id, sizeof(id), rsk, &valid); if (ret != 0 || !valid) { printf("wc_ValidateSakkeRsk failed: %d (valid=%d))\n", ret, valid); break; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("SAKKE", 1024, desc[11], 0, count, start, 0); wc_FreeSakkeKey(&genKey); wc_ecc_del_point(rsk); } void bench_sakke(void) { SakkeKey genKey; double start; int i, count; const char**desc = bench_desc_words[lng_index]; ecc_point* rsk; byte id[] = { 0x01, 0x23, 0x34, 0x45 }; byte ssv[] = { 0x01, 0x23, 0x34, 0x45 }; byte derSSV[sizeof(ssv)]; byte auth[257]; word16 authSz = sizeof(auth); int ret = 0; byte* table = NULL; word32 len = 0; byte* iTable = NULL; word32 iTableLen = 0; rsk = wc_ecc_new_point(); (void)wc_InitSakkeKey_ex(&genKey, 128, ECC_SAKKE_1, NULL, INVALID_DEVID); (void)wc_MakeSakkeKey(&genKey, &gRng); (void)wc_MakeSakkeRsk(&genKey, id, sizeof(id), rsk); (void)wc_SetSakkeRsk(&genKey, rsk, NULL, 0); (void)wc_SetSakkeIdentity(&genKey, id, sizeof(id)); /* Encapsulate */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { ret = wc_MakeSakkeEncapsulatedSSV(&genKey, WC_HASH_TYPE_SHA256, ssv, sizeof(ssv), auth, &authSz); if (ret != 0) { printf("wc_MakeSakkeEncapsulatedSSV failed: %d\n", ret); break; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("SAKKE", 1024, desc[9], 0, count, start, 0); /* Derive */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { XMEMCPY(derSSV, ssv, sizeof(ssv)); ret = wc_DeriveSakkeSSV(&genKey, WC_HASH_TYPE_SHA256, derSSV, sizeof(derSSV), auth, authSz); if (ret != 0) { printf("wc_DeriveSakkeSSV failed: %d\n", ret); break; } } if (ret != 0) break; count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("SAKKE", 1024, desc[10], 0, count, start, 0); /* Calculate Point I and generate table. */ (void)wc_MakeSakkePointI(&genKey, id, sizeof(id)); iTableLen = 0; (void)wc_GenerateSakkePointITable(&genKey, NULL, &iTableLen); if (iTableLen != 0) { iTable = (byte*)XMALLOC(iTableLen, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); (void)wc_GenerateSakkePointITable(&genKey, iTable, &iTableLen); } /* Encapsulate with Point I table */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { ret = wc_MakeSakkeEncapsulatedSSV(&genKey, WC_HASH_TYPE_SHA256, ssv, sizeof(ssv), auth, &authSz); if (ret != 0) { printf("wc_MakeSakkeEncapsulatedSSV failed: %d\n", ret); break; } } count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("SAKKE", 1024, desc[9], 0, count, start, 0); (void)wc_SetSakkeRsk(&genKey, rsk, table, len); /* Derive with Point I table */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { XMEMCPY(derSSV, ssv, sizeof(ssv)); ret = wc_DeriveSakkeSSV(&genKey, WC_HASH_TYPE_SHA256, derSSV, sizeof(derSSV), auth, authSz); if (ret != 0) { printf("wc_DeriveSakkeSSV failed: %d\n", ret); break; } } if (ret != 0) break; count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("SAKKE", 1024, desc[10], 0, count, start, 0); len = 0; (void)wc_GenerateSakkeRskTable(&genKey, rsk, NULL, &len); if (len > 0) { table = (byte*)XMALLOC(len, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); (void)wc_GenerateSakkeRskTable(&genKey, rsk, table, &len); } (void)wc_SetSakkeRsk(&genKey, rsk, table, len); /* Derive with Point I table and RSK table */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { XMEMCPY(derSSV, ssv, sizeof(ssv)); ret = wc_DeriveSakkeSSV(&genKey, WC_HASH_TYPE_SHA256, derSSV, sizeof(derSSV), auth, authSz); if (ret != 0) { printf("wc_DeriveSakkeSSV failed: %d\n", ret); break; } } if (ret != 0) break; count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("SAKKE", 1024, desc[10], 0, count, start, 0); wc_ClearSakkePointITable(&genKey); /* Derive with RSK table */ bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { XMEMCPY(derSSV, ssv, sizeof(ssv)); ret = wc_DeriveSakkeSSV(&genKey, WC_HASH_TYPE_SHA256, derSSV, sizeof(derSSV), auth, authSz); if (ret != 0) { printf("wc_DeriveSakkeSSV failed: %d\n", ret); break; } } if (ret != 0) break; count += i; } while (bench_stats_sym_check(start)); bench_stats_asym_finish("SAKKE", 1024, desc[10], 0, count, start, 0); wc_FreeSakkeKey(&genKey); wc_ecc_del_point(rsk); } #endif /* WOLFCRYPT_SAKKE_CLIENT */ #endif /* WOLFCRYPT_HAVE_SAKKE */ #if defined(HAVE_PQC) static void bench_pqcKemInit(word32 alg, byte **priv_key, byte **pub_key, const char **wolf_name, OQS_KEM **kem) { int i; const char *pqc_name = NULL; *pub_key = NULL; *priv_key = NULL; for (i=0; bench_pq_asym_opt[i].str != NULL; i++) { if (alg == bench_pq_asym_opt[i].val) { #ifdef HAVE_LIBOQS pqc_name = bench_pq_asym_opt[i].pqc_name; #endif *wolf_name = bench_pq_asym_opt[i].str; break; } } #ifdef HAVE_LIBOQS if (pqc_name == NULL) { printf("Bad OQS Alg specified\n"); return; } *kem = OQS_KEM_new(pqc_name); if (*kem == NULL) { printf("OQS_KEM_new() failed\n"); return; } *pub_key = (byte*)XMALLOC((*kem)->length_public_key, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); *priv_key = (byte*)XMALLOC((*kem)->length_secret_key, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); #endif #ifdef HAVE_PQM4 *pub_key = (byte*)XMALLOC(PQM4_PUBLIC_KEY_LENGTH, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); *priv_key = (byte*)XMALLOC(PQM4_PRIVATE_KEY_LENGTH, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); (void)pqc_name; #endif } void bench_pqcKemKeygen(word32 alg) { const char *wolf_name = NULL; OQS_KEM* kem = NULL; double start; int i, count, ret; byte *priv_key; byte *pub_key; bench_pqcKemInit(alg, &priv_key, &pub_key, &wolf_name, &kem); if (wolf_name == NULL || pub_key == NULL || #ifdef HAVE_LIBOQS kem == NULL || #endif priv_key == NULL) { printf("bench_pqcKemInit() failed\n"); goto exit; } bench_stats_start(&count, &start); do { for (i = 0; i < genTimes; i++) { #ifdef HAVE_LIBOQS ret = OQS_KEM_keypair(kem, pub_key, priv_key); if (ret != OQS_SUCCESS) { printf("OQS_KEM_keypair() failed: %d\n", ret); goto exit; } #endif #ifdef HAVE_PQM4 ret = crypto_kem_keypair(pub_key, priv_key); if (ret != 0) { printf("crypto_kem_keypair() failed: %d\n", ret); goto exit; } #endif } count += i; } while (bench_stats_sym_check(start)); /* + 1 gets rid of the leading dash (-) */ bench_stats_pq_asym_finish(wolf_name + 1, 0, count, start, 0); exit: XFREE(priv_key, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); XFREE(pub_key, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); #ifdef HAVE_LIBOQS OQS_KEM_free(kem); #endif } void bench_pqcKemEncapDecap(word32 alg) { const char *wolf_name = NULL; OQS_KEM* kem = NULL; double start; int i, count, ret; byte *priv_key; byte *pub_key; byte *ciphertext = NULL; byte *shared_secret = NULL; bench_pqcKemInit(alg, &priv_key, &pub_key, &wolf_name, &kem); if (wolf_name == NULL || pub_key == NULL || #ifdef HAVE_LIBOQS kem == NULL || #endif priv_key == NULL) { printf("bench_pqcKemInit() failed\n"); goto exit; } #ifdef HAVE_LIBOQS ret = OQS_KEM_keypair(kem, pub_key, priv_key); if (ret != OQS_SUCCESS) { printf("OQS_KEM_keypair() failed: %d\n", ret); goto exit; } shared_secret = (byte*)XMALLOC(kem->length_shared_secret, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); ciphertext = (byte*)XMALLOC(kem->length_ciphertext, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); #endif #ifdef HAVE_PQM4 ret = crypto_kem_keypair(pub_key, priv_key); if (ret != 0) { printf("crypto_kem_keypair() failed: %d\n", ret); goto exit; } shared_secret = (byte*)XMALLOC(PQM4_SHARED_SECRET_LENGTH, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); ciphertext = (byte*)XMALLOC(PQM4_CIPHERTEXT_LENGTH, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); #endif if (shared_secret == NULL || ciphertext == NULL) { printf("XMALLOC() failed\n"); goto exit; } #ifdef HAVE_LIBOQS if (ret == OQS_SUCCESS) #endif #ifdef HAVE_PQM4 if (ret == 0) #endif { bench_stats_start(&count, &start); do { for (i = 0; i < agreeTimes; i++) { #ifdef HAVE_LIBOQS ret = OQS_KEM_encaps(kem, ciphertext, shared_secret, pub_key); if (ret != OQS_SUCCESS) { printf("OQS_KEM_encaps() failed: %d\n", ret); goto exit; } ret = OQS_KEM_decaps(kem, shared_secret, ciphertext, priv_key); if (ret != OQS_SUCCESS) { printf("OQS_KEM_decaps() failed: %d\n", ret); goto exit; } #endif #ifdef HAVE_PQM4 ret = crypto_kem_enc(ciphertext, shared_secret, pub_key); if (ret != 0){ printf("crypto_kem_enc() failed: %d\n", ret); goto exit; } ret = crypto_kem_dec(shared_secret, ciphertext, priv_key); if (ret != 0){ printf("crypto_kem_dec() failed: %d\n", ret); goto exit; } #endif } count += i; } while (bench_stats_sym_check(start)); /* + 1 gets rid of the leading dash (-) */ bench_stats_pq_asym_finish(wolf_name + 1, 0, count, start, ret); } exit: XFREE(ciphertext, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); XFREE(shared_secret, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); XFREE(priv_key, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); XFREE(pub_key, HEAP_HINT, DYNAMIC_TYPE_TMP_BUFFER); #ifdef HAVE_LIBOQS OQS_KEM_free(kem); #endif } #ifdef HAVE_FALCON void bench_falconKeySign(byte level) { int ret = 0; falcon_key key; double start; int i, count; byte sig[FALCON_MAX_SIG_SIZE]; byte msg[512]; word32 x = 0; const char**desc = bench_desc_words[lng_index]; ret = wc_falcon_init(&key); if (ret != 0) { printf("wc_falcon_init failed %d\n", ret); return; } ret = wc_falcon_set_level(&key, level); if (ret != 0) { printf("wc_falcon_set_level failed %d\n", ret); } if (ret == 0) { if (level == 1) { ret = wc_falcon_import_private_key(bench_falcon_level1_key, sizeof_bench_falcon_level1_key, NULL, 0, &key); } else { ret = wc_falcon_import_private_key(bench_falcon_level5_key, sizeof_bench_falcon_level5_key, NULL, 0, &key); } if (ret != 0) { printf("wc_falcon_import_private_key failed %d\n", ret); } } /* make dummy msg */ for (i = 0; i < (int)sizeof(msg); i++) { msg[i] = (byte)i; } bench_stats_start(&count, &start); do { for (i = 0; i < agreeTimes; i++) { if (ret == 0) { if (level == 1) { x = FALCON_LEVEL1_SIG_SIZE; } else { x = FALCON_LEVEL5_SIG_SIZE; } ret = wc_falcon_sign_msg(msg, sizeof(msg), sig, &x, &key); if (ret != 0) { printf("wc_falcon_sign_msg failed\n"); } } } count += i; } while (bench_stats_sym_check(start)); if (ret == 0) { bench_stats_asym_finish("FALCON", level, desc[4], 0, count, start, ret); } bench_stats_start(&count, &start); do { for (i = 0; i < agreeTimes; i++) { if (ret == 0) { int verify = 0; ret = wc_falcon_verify_msg(sig, x, msg, sizeof(msg), &verify, &key); if (ret != 0 || verify != 1) { printf("wc_falcon_verify_msg failed %d, verify %d\n", ret, verify); ret = -1; } } } count += i; } while (bench_stats_sym_check(start)); if (ret == 0) { bench_stats_asym_finish("FALCON", level, desc[5], 0, count, start, ret); } wc_falcon_free(&key); } #endif /* HAVE_FALCON */ #ifdef HAVE_DILITHIUM void bench_dilithiumKeySign(byte level, byte sym) { int ret = 0; dilithium_key key; double start; int i, count; byte sig[DILITHIUM_MAX_SIG_SIZE]; byte msg[512]; word32 x = 0; const char**desc = bench_desc_words[lng_index]; ret = wc_dilithium_init(&key); if (ret != 0) { printf("wc_dilithium_init failed %d\n", ret); return; } ret = wc_dilithium_set_level_and_sym(&key, level, sym); if (ret != 0) { printf("wc_dilithium_set_level_and_sym() failed %d\n", ret); } if (ret == 0) { ret = -1; if ((level == 2) && (sym == SHAKE_VARIANT)) { ret = wc_dilithium_import_private_key(bench_dilithium_level2_key, sizeof_bench_dilithium_level2_key, NULL, 0, &key); } else if ((level == 3) && (sym == SHAKE_VARIANT)) { ret = wc_dilithium_import_private_key(bench_dilithium_level3_key, sizeof_bench_dilithium_level3_key, NULL, 0, &key); } else if ((level == 5) && (sym == SHAKE_VARIANT)) { ret = wc_dilithium_import_private_key(bench_dilithium_level5_key, sizeof_bench_dilithium_level5_key, NULL, 0, &key); } else if ((level == 2) && (sym == AES_VARIANT)) { ret = wc_dilithium_import_private_key( bench_dilithium_aes_level2_key, sizeof_bench_dilithium_level2_key, NULL, 0, &key); } else if ((level == 3) && (sym == AES_VARIANT)) { ret = wc_dilithium_import_private_key( bench_dilithium_aes_level3_key, sizeof_bench_dilithium_level3_key, NULL, 0, &key); } else if ((level == 5) && (sym == AES_VARIANT)) { ret = wc_dilithium_import_private_key( bench_dilithium_aes_level5_key, sizeof_bench_dilithium_level5_key, NULL, 0, &key); } if (ret != 0) { printf("wc_dilithium_import_private_key failed %d\n", ret); } } /* make dummy msg */ for (i = 0; i < (int)sizeof(msg); i++) { msg[i] = (byte)i; } bench_stats_start(&count, &start); do { for (i = 0; i < agreeTimes; i++) { if (ret == 0) { if (level == 2) { x = DILITHIUM_LEVEL2_SIG_SIZE; } else if (level == 3) { x = DILITHIUM_LEVEL3_SIG_SIZE; } else { x = DILITHIUM_LEVEL5_SIG_SIZE; } ret = wc_dilithium_sign_msg(msg, sizeof(msg), sig, &x, &key); if (ret != 0) { printf("wc_dilithium_sign_msg failed\n"); } } } count += i; } while (bench_stats_sym_check(start)); if (ret == 0) { if (sym == SHAKE_VARIANT) { bench_stats_asym_finish("DILITHIUM", level, desc[4], 0, count, start, ret); } else { bench_stats_asym_finish("DILITHIUM-AES", level, desc[4], 0, count, start, ret); } } bench_stats_start(&count, &start); do { for (i = 0; i < agreeTimes; i++) { if (ret == 0) { int verify = 0; ret = wc_dilithium_verify_msg(sig, x, msg, sizeof(msg), &verify, &key); if (ret != 0 || verify != 1) { printf("wc_dilithium_verify_msg failed %d, verify %d\n", ret, verify); ret = -1; } } } count += i; } while (bench_stats_sym_check(start)); if (ret == 0) { if (sym == SHAKE_VARIANT) { bench_stats_asym_finish("DILITHIUM", level, desc[5], 0, count, start, ret); } else { bench_stats_asym_finish("DILITHIUM-AES", level, desc[5], 0, count, start, ret); } } wc_dilithium_free(&key); } #endif /* HAVE_DILITHIUM */ #ifdef HAVE_SPHINCS void bench_sphincsKeySign(byte level, byte optim) { int ret = 0; sphincs_key key; double start; int i, count; byte sig[SPHINCS_MAX_SIG_SIZE]; byte msg[512]; word32 x = 0; const char**desc = bench_desc_words[lng_index]; ret = wc_sphincs_init(&key); if (ret != 0) { printf("wc_sphincs_init failed %d\n", ret); return; } ret = wc_sphincs_set_level_and_optim(&key, level, optim); if (ret != 0) { printf("wc_sphincs_set_level_and_optim() failed %d\n", ret); } if (ret == 0) { ret = -1; if ((level == 1) && (optim == FAST_VARIANT)) { ret = wc_sphincs_import_private_key(bench_sphincs_fast_level1_key, sizeof_bench_sphincs_fast_level1_key, NULL, 0, &key); } else if ((level == 3) && (optim == FAST_VARIANT)) { ret = wc_sphincs_import_private_key(bench_sphincs_fast_level3_key, sizeof_bench_sphincs_fast_level3_key, NULL, 0, &key); } else if ((level == 5) && (optim == FAST_VARIANT)) { ret = wc_sphincs_import_private_key(bench_sphincs_fast_level5_key, sizeof_bench_sphincs_fast_level5_key, NULL, 0, &key); } else if ((level == 1) && (optim == SMALL_VARIANT)) { ret = wc_sphincs_import_private_key( bench_sphincs_small_level1_key, sizeof_bench_sphincs_small_level1_key, NULL, 0, &key); } else if ((level == 3) && (optim == SMALL_VARIANT)) { ret = wc_sphincs_import_private_key( bench_sphincs_small_level3_key, sizeof_bench_sphincs_small_level3_key, NULL, 0, &key); } else if ((level == 5) && (optim == SMALL_VARIANT)) { ret = wc_sphincs_import_private_key( bench_sphincs_small_level5_key, sizeof_bench_sphincs_small_level5_key, NULL, 0, &key); } if (ret != 0) { printf("wc_sphincs_import_private_key failed %d\n", ret); } } /* make dummy msg */ for (i = 0; i < (int)sizeof(msg); i++) { msg[i] = (byte)i; } bench_stats_start(&count, &start); do { for (i = 0; i < agreeTimes; i++) { if (ret == 0) { if ((level == 1) && (optim == FAST_VARIANT)) { x = SPHINCS_FAST_LEVEL1_SIG_SIZE; } else if ((level == 3) && (optim == FAST_VARIANT)) { x = SPHINCS_FAST_LEVEL3_SIG_SIZE; } else if ((level == 5) && (optim == FAST_VARIANT)) { x = SPHINCS_FAST_LEVEL5_SIG_SIZE; } else if ((level == 1) && (optim == SMALL_VARIANT)) { x = SPHINCS_SMALL_LEVEL1_SIG_SIZE; } else if ((level == 3) && (optim == SMALL_VARIANT)) { x = SPHINCS_SMALL_LEVEL3_SIG_SIZE; } else if ((level == 5) && (optim == SMALL_VARIANT)) { x = SPHINCS_SMALL_LEVEL5_SIG_SIZE; } ret = wc_sphincs_sign_msg(msg, sizeof(msg), sig, &x, &key); if (ret != 0) { printf("wc_sphincs_sign_msg failed\n"); } } } count += i; } while (bench_stats_sym_check(start)); if (ret == 0) { if (optim == FAST_VARIANT) { bench_stats_asym_finish("SPHINCS-FAST", level, desc[4], 0, count, start, ret); } else { bench_stats_asym_finish("SPHINCS-SMALL", level, desc[4], 0, count, start, ret); } } bench_stats_start(&count, &start); do { for (i = 0; i < agreeTimes; i++) { if (ret == 0) { int verify = 0; ret = wc_sphincs_verify_msg(sig, x, msg, sizeof(msg), &verify, &key); if (ret != 0 || verify != 1) { printf("wc_sphincs_verify_msg failed %d, verify %d\n", ret, verify); ret = -1; } } } count += i; } while (bench_stats_sym_check(start)); if (ret == 0) { if (optim == FAST_VARIANT) { bench_stats_asym_finish("SPHINCS-FAST", level, desc[5], 0, count, start, ret); } else { bench_stats_asym_finish("SPHINCS-SMALL", level, desc[5], 0, count, start, ret); } } wc_sphincs_free(&key); } #endif /* HAVE_SPHINCS */ #endif /* HAVE_PQC */ #ifndef HAVE_STACK_SIZE #if defined(_WIN32) && !defined(INTIME_RTOS) #define WIN32_LEAN_AND_MEAN #include double current_time(int reset) { static int init = 0; static LARGE_INTEGER freq; LARGE_INTEGER count; (void)reset; if (!init) { QueryPerformanceFrequency(&freq); init = 1; } QueryPerformanceCounter(&count); return (double)count.QuadPart / freq.QuadPart; } #elif defined MICROCHIP_PIC32 #if defined(WOLFSSL_MICROCHIP_PIC32MZ) #define CLOCK 80000000.0 #else #define CLOCK 40000000.0 #endif extern void WriteCoreTimer(word32 t); extern word32 ReadCoreTimer(void); double current_time(int reset) { unsigned int ns; if (reset) { WriteCoreTimer(0); } /* get timer in ns */ ns = ReadCoreTimer(); /* return seconds as a double */ return ( ns / CLOCK * 2.0); } #elif defined(WOLFSSL_IAR_ARM_TIME) || defined (WOLFSSL_MDK_ARM) || \ defined(WOLFSSL_USER_CURRTIME) || defined(WOLFSSL_CURRTIME_REMAP) /* declared above at line 239 */ /* extern double current_time(int reset); */ #elif defined(FREERTOS) #include "task.h" #if defined(WOLFSSL_ESPIDF) /* proto type definition */ int construct_argv(); extern char* __argv[22]; #endif double current_time(int reset) { portTickType tickCount; (void) reset; /* tick count == ms, if configTICK_RATE_HZ is set to 1000 */ tickCount = xTaskGetTickCount(); return (double)tickCount / 1000; } #elif defined (WOLFSSL_TIRTOS) extern double current_time(int reset); #elif defined(FREESCALE_MQX) double current_time(int reset) { TIME_STRUCT tv; _time_get(&tv); return (double)tv.SECONDS + (double)tv.MILLISECONDS / 1000; } #elif defined(FREESCALE_KSDK_BM) double current_time(int reset) { return (double)OSA_TimeGetMsec() / 1000; } #elif defined(WOLFSSL_EMBOS) #include "RTOS.h" double current_time(int reset) { double time_now; double current_s = OS_GetTime() / 1000.0; double current_us = OS_GetTime_us() / 1000000.0; time_now = (double)( current_s + current_us); (void) reset; return time_now; } #elif defined(WOLFSSL_SGX) double current_time(int reset); #elif defined(WOLFSSL_DEOS) double current_time(int reset) { const uint32_t systemTickTimeInHz = 1000000 / systemTickInMicroseconds(); const volatile uint32_t *systemTickPtr = systemTickPointer(); (void)reset; return (double) *systemTickPtr/systemTickTimeInHz; } #elif defined(MICRIUM) double current_time(int reset) { #if (OS_VERSION < 50000) CPU_ERR err; (void)reset; return (double) CPU_TS_Get32()/CPU_TS_TmrFreqGet(&err); #else RTOS_ERR err; double ret = 0; OS_TICK tick = OSTimeGet(&err); OS_RATE_HZ rate = OSTimeTickRateHzGet(&err); (void)reset; if (RTOS_ERR_CODE_GET(err) == RTOS_ERR_NONE) { ret = ((double)tick)/rate; } return ret; #endif } #elif defined(WOLFSSL_ZEPHYR) #include double current_time(int reset) { (void)reset; #if defined(CONFIG_ARCH_POSIX) k_cpu_idle(); #endif return (double)k_uptime_get() / 1000; } #elif defined(WOLFSSL_NETBURNER) #include #include #include double current_time(int reset) { DWORD ticks = TimeTick; /* ticks since system start */ (void)reset; return (double) ticks/TICKS_PER_SECOND; } #elif defined(THREADX) #include "tx_api.h" double current_time(int reset) { (void)reset; return (double) tx_time_get() / TX_TIMER_TICKS_PER_SECOND; } #elif defined(WOLFSSL_XILINX) #ifndef XPAR_CPU_CORTEXA53_0_TIMESTAMP_CLK_FREQ #define XPAR_CPU_CORTEXA53_0_TIMESTAMP_CLK_FREQ 50000000 #endif #ifndef COUNTS_PER_SECOND #define COUNTS_PER_SECOND XPAR_CPU_CORTEXA53_0_TIMESTAMP_CLK_FREQ #endif double current_time(int reset) { double timer; uint64_t cntPct = 0; asm volatile("mrs %0, CNTPCT_EL0" : "=r" (cntPct)); /* Convert to milliseconds */ timer = (double)(cntPct / (COUNTS_PER_SECOND / 1000)); /* Convert to seconds.millisecond */ timer /= 1000; return timer; } #else #include double current_time(int reset) { struct timeval tv; (void)reset; LIBCALL_CHECK_RET(gettimeofday(&tv, 0)); return (double)tv.tv_sec + (double)tv.tv_usec / 1000000; } #endif /* _WIN32 */ #endif /* !HAVE_STACK_SIZE */ #if defined(HAVE_GET_CYCLES) static WC_INLINE word64 get_intel_cycles(void) { unsigned int lo_c, hi_c; __asm__ __volatile__ ( "cpuid\n\t" "rdtsc" : "=a"(lo_c), "=d"(hi_c) /* out */ : "a"(0) /* in */ : "%ebx", "%ecx"); /* clobber */ return ((word64)lo_c) | (((word64)hi_c) << 32); } #endif /* HAVE_GET_CYCLES */ void benchmark_configure(int block_size) { /* must be greater than 0 */ if (block_size > 0) { numBlocks = numBlocks * bench_size / block_size; bench_size = (word32)block_size; } } #ifndef NO_MAIN_DRIVER #ifndef MAIN_NO_ARGS #ifndef WOLFSSL_BENCHMARK_ALL /* Display the algorithm string and keep to 80 characters per line. * * str Algorithm string to print. * line Length of line used so far. */ static void print_alg(const char* str, int* line) { int optLen; optLen = (int)XSTRLEN(str) + 1; if (optLen + *line > 80) { printf("\n "); *line = 13; } *line += optLen; printf(" %s", str); } #endif /* Display the usage options of the benchmark program. */ static void Usage(void) { #ifndef WOLFSSL_BENCHMARK_ALL int i; int line; #endif printf("benchmark\n"); printf("%s", bench_Usage_msg1[lng_index][0]); /* option -? */ printf("%s", bench_Usage_msg1[lng_index][1]); /* option -csv */ printf("%s", bench_Usage_msg1[lng_index][2]); /* option -base10 */ #if defined(HAVE_AESGCM) || defined(HAVE_AESCCM) printf("%s", bench_Usage_msg1[lng_index][3]); /* option -no_add */ #endif printf("%s", bench_Usage_msg1[lng_index][4]); /* option -dgst_full */ #ifndef NO_RSA printf("%s", bench_Usage_msg1[lng_index][5]); /* option -ras_sign */ #ifdef WOLFSSL_KEY_GEN printf("%s", bench_Usage_msg1[lng_index][6]); /* option -rsa-sz */ #endif #endif #if !defined(NO_DH) && defined(HAVE_FFDHE_2048) printf("%s", bench_Usage_msg1[lng_index][7]); /* option -ffdhe2048 */ #endif #if !defined(NO_DH) && defined(HAVE_FFDHE_3072) printf("%s", bench_Usage_msg1[lng_index][8]); /* option -ffdhe3072 */ #endif #if defined(HAVE_ECC) && !defined(NO_ECC256) printf("%s", bench_Usage_msg1[lng_index][9]); /* option -p256 */ #endif #if defined(HAVE_ECC) && defined(HAVE_ECC384) printf("%s", bench_Usage_msg1[lng_index][10]); /* option -p384 */ #endif #if defined(HAVE_ECC) && defined(HAVE_ECC521) printf("%s", bench_Usage_msg1[lng_index][11]); /* option -p521 */ #endif #if defined(HAVE_ECC) printf("%s", bench_Usage_msg1[lng_index][12]); /* option -ecc-all */ #endif #ifndef WOLFSSL_BENCHMARK_ALL printf("%s", bench_Usage_msg1[lng_index][13]); /* option - */ printf(" "); line = 13; for (i=0; bench_cipher_opt[i].str != NULL; i++) print_alg(bench_cipher_opt[i].str + 1, &line); printf("\n "); line = 13; for (i=0; bench_digest_opt[i].str != NULL; i++) print_alg(bench_digest_opt[i].str + 1, &line); printf("\n "); line = 13; for (i=0; bench_mac_opt[i].str != NULL; i++) print_alg(bench_mac_opt[i].str + 1, &line); printf("\n "); line = 13; for (i=0; bench_asym_opt[i].str != NULL; i++) print_alg(bench_asym_opt[i].str + 1, &line); printf("\n "); line = 13; for (i=0; bench_other_opt[i].str != NULL; i++) print_alg(bench_other_opt[i].str + 1, &line); printf("\n "); #if defined(HAVE_PQC) line = 13; for (i=0; bench_pq_asym_opt[i].str != NULL; i++) print_alg(bench_pq_asym_opt[i].str + 1, &line); #if defined(HAVE_LIBOQS) for (i=0; bench_pq_asym_opt2[i].str != NULL; i++) print_alg(bench_pq_asym_opt2[i].str + 1, &line); printf("\n"); #endif /* HAVE_LIBOQS */ #endif /* HAVE_PQC */ #endif /* !WOLFSSL_BENCHMARK_ALL */ printf("%s", bench_Usage_msg1[lng_index][14]); /* option -lng */ printf("%s", bench_Usage_msg1[lng_index][15]); /* option */ #ifdef WC_ENABLE_BENCH_THREADING printf("%s", bench_Usage_msg1[lng_index][16]); /* option -threads */ #endif printf("%s", bench_Usage_msg1[lng_index][17]); /* option -print */ } /* Match the command line argument with the string. * * arg Command line argument. * str String to check for. * return 1 if the command line argument matches the string, 0 otherwise. */ static int string_matches(const char* arg, const char* str) { int len = (int)XSTRLEN(str) + 1; return XSTRNCMP(arg, str, len) == 0; } #endif /* MAIN_NO_ARGS */ #if defined(WOLFSSL_ESPIDF) || defined(_WIN32_WCE) int wolf_benchmark_task( ) #elif defined(MAIN_NO_ARGS) int main() #else int main(int argc, char** argv) #endif { int ret = 0; #ifndef MAIN_NO_ARGS int optMatched; #ifdef WOLFSSL_ESPIDF int argc = construct_argv(); char** argv = (char**)__argv; #endif #ifndef WOLFSSL_BENCHMARK_ALL int i; #endif #endif benchmark_static_init(); printf("------------------------------------------------------------------------------\n"); printf(" wolfSSL version %s\n", LIBWOLFSSL_VERSION_STRING); printf("------------------------------------------------------------------------------\n"); #ifndef MAIN_NO_ARGS while (argc > 1) { if (string_matches(argv[1], "-?")) { if(--argc>1){ lng_index = XATOI((++argv)[1]); if(lng_index<0||lng_index>1) { lng_index = 0; } } Usage(); return 0; } else if (string_matches(argv[1], "-lng")) { argc--; argv++; if(argc>1) { lng_index = XATOI(argv[1]); if(lng_index<0||lng_index>1){ printf("invalid number(%d) is specified. [ :0-1]\n", lng_index); lng_index = 0; } } } else if (string_matches(argv[1], "-base10")) base2 = 0; #if defined(HAVE_AESGCM) || defined(HAVE_AESCCM) else if (string_matches(argv[1], "-no_aad")) aesAuthAddSz = 0; #endif else if (string_matches(argv[1], "-dgst_full")) digest_stream = 0; #ifndef NO_RSA else if (string_matches(argv[1], "-rsa_sign")) rsa_sign_verify = 1; #endif #if !defined(NO_DH) && defined(HAVE_FFDHE_2048) else if (string_matches(argv[1], "-ffdhe2048")) use_ffdhe = 2048; #endif #if !defined(NO_DH) && defined(HAVE_FFDHE_3072) else if (string_matches(argv[1], "-ffdhe3072")) use_ffdhe = 3072; #endif #if !defined(NO_DH) && defined(HAVE_FFDHE_4096) else if (string_matches(argv[1], "-ffdhe4096")) use_ffdhe = 4096; #endif #if defined(HAVE_ECC) && !defined(NO_ECC256) else if (string_matches(argv[1], "-p256")) bench_asym_algs |= BENCH_ECC_P256; #endif #if defined(HAVE_ECC) && defined(HAVE_ECC384) else if (string_matches(argv[1], "-p384")) bench_asym_algs |= BENCH_ECC_P384; #endif #if defined(HAVE_ECC) && defined(HAVE_ECC521) else if (string_matches(argv[1], "-p521")) bench_asym_algs |= BENCH_ECC_P521; #endif #ifdef BENCH_ASYM else if (string_matches(argv[1], "-csv")) { csv_format = 1; csv_header_count = 1; } #endif #ifdef WC_ENABLE_BENCH_THREADING else if (string_matches(argv[1], "-threads")) { argc--; argv++; if (argc > 1) { g_threadCount = XATOI(argv[1]); if (g_threadCount < 1 || lng_index > 128){ printf("invalid number(%d) is specified. [ :1-128]\n", g_threadCount); g_threadCount = 0; } } } else if (string_matches(argv[1], "-print")) { gPrintStats = 1; } #endif else if (argv[1][0] == '-') { optMatched = 0; #ifndef WOLFSSL_BENCHMARK_ALL /* Check known algorithm choosing command line options. */ /* Known cipher algorithms */ for (i=0; !optMatched && bench_cipher_opt[i].str != NULL; i++) { if (string_matches(argv[1], bench_cipher_opt[i].str)) { bench_cipher_algs |= bench_cipher_opt[i].val; bench_all = 0; optMatched = 1; } } /* Known digest algorithms */ for (i=0; !optMatched && bench_digest_opt[i].str != NULL; i++) { if (string_matches(argv[1], bench_digest_opt[i].str)) { bench_digest_algs |= bench_digest_opt[i].val; bench_all = 0; optMatched = 1; } } /* Known MAC algorithms */ for (i=0; !optMatched && bench_mac_opt[i].str != NULL; i++) { if (string_matches(argv[1], bench_mac_opt[i].str)) { bench_mac_algs |= bench_mac_opt[i].val; bench_all = 0; optMatched = 1; } } /* Known asymmetric algorithms */ for (i=0; !optMatched && bench_asym_opt[i].str != NULL; i++) { if (string_matches(argv[1], bench_asym_opt[i].str)) { bench_asym_algs |= bench_asym_opt[i].val; bench_all = 0; optMatched = 1; } } #if defined(HAVE_PQC) /* Known asymmetric post-quantum algorithms */ for (i=0; !optMatched && bench_pq_asym_opt[i].str != NULL; i++) { if (string_matches(argv[1], bench_pq_asym_opt[i].str)) { bench_pq_asym_algs |= bench_pq_asym_opt[i].val; bench_all = 0; optMatched = 1; } } #if defined(HAVE_LIBOQS) /* Both bench_pq_asym_opt and bench_pq_asym_opt2 are looking for * -pq, so we need to reset optMatched in case it was set to 1 just * above. */ optMatched = 0; for (i=0; !optMatched && bench_pq_asym_opt2[i].str != NULL; i++) { if (string_matches(argv[1], bench_pq_asym_opt2[i].str)) { bench_pq_asym_algs2 |= bench_pq_asym_opt2[i].val; bench_all = 0; optMatched = 1; } } #endif /* HAVE_LIBOQS*/ #endif /* HAVE_PQC */ /* Other known cryptographic algorithms */ for (i=0; !optMatched && bench_other_opt[i].str != NULL; i++) { if (string_matches(argv[1], bench_other_opt[i].str)) { bench_other_algs |= bench_other_opt[i].val; bench_all = 0; optMatched = 1; } } #endif if (!optMatched) { printf("Option not recognized: %s\n", argv[1]); Usage(); return 1; } } else { /* parse for block size */ benchmark_configure(XATOI(argv[1])); } argc--; argv++; } #endif /* MAIN_NO_ARGS */ #if defined(WC_ENABLE_BENCH_THREADING) && !defined(WOLFSSL_ASYNC_CRYPT) if (g_threadCount > 1) { ret = benchmark_test_threaded(NULL); } else #endif { #ifdef HAVE_STACK_SIZE ret = StackSizeCheck(NULL, benchmark_test); #else ret = benchmark_test(NULL); #endif } return ret; } #endif /* !NO_MAIN_DRIVER */ #else #ifndef NO_MAIN_DRIVER int main(void) { return 0; } #endif #endif /* !NO_CRYPT_BENCHMARK */