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- /*
- * Copyright 2015-2018 The OpenSSL Project Authors. All Rights Reserved.
- *
- * Licensed under the OpenSSL license (the "License"). You may not use
- * this file except in compliance with the License. You can obtain a copy
- * in the file LICENSE in the source distribution or at
- * https://www.openssl.org/source/license.html
- */
- #include <stdlib.h>
- #include <string.h>
- #include <openssl/crypto.h>
- #include "internal/poly1305.h"
- #include "poly1305_local.h"
- size_t Poly1305_ctx_size ()
- {
- return sizeof(struct poly1305_context);
- }
- /* pick 32-bit unsigned integer in little endian order */
- static unsigned int U8TOU32(const unsigned char *p)
- {
- return (((unsigned int)(p[0] & 0xff)) |
- ((unsigned int)(p[1] & 0xff) << 8) |
- ((unsigned int)(p[2] & 0xff) << 16) |
- ((unsigned int)(p[3] & 0xff) << 24));
- }
- /*
- * Implementations can be classified by amount of significant bits in
- * words making up the multi-precision value, or in other words radix
- * or base of numerical representation, e.g. base 2^64, base 2^32,
- * base 2^26. Complementary characteristic is how wide is the result of
- * multiplication of pair of digits, e.g. it would take 128 bits to
- * accommodate multiplication result in base 2^64 case. These are used
- * interchangeably. To describe implementation that is. But interface
- * is designed to isolate this so that low-level primitives implemented
- * in assembly can be self-contained/self-coherent.
- */
- #ifndef POLY1305_ASM
- /*
- * Even though there is __int128 reference implementation targeting
- * 64-bit platforms provided below, it's not obvious that it's optimal
- * choice for every one of them. Depending on instruction set overall
- * amount of instructions can be comparable to one in __int64
- * implementation. Amount of multiplication instructions would be lower,
- * but not necessarily overall. And in out-of-order execution context,
- * it is the latter that can be crucial...
- *
- * On related note. Poly1305 author, D. J. Bernstein, discusses and
- * provides floating-point implementations of the algorithm in question.
- * It made a lot of sense by the time of introduction, because most
- * then-modern processors didn't have pipelined integer multiplier.
- * [Not to mention that some had non-constant timing for integer
- * multiplications.] Floating-point instructions on the other hand could
- * be issued every cycle, which allowed to achieve better performance.
- * Nowadays, with SIMD and/or out-or-order execution, shared or
- * even emulated FPU, it's more complicated, and floating-point
- * implementation is not necessarily optimal choice in every situation,
- * rather contrary...
- *
- * <appro@openssl.org>
- */
- typedef unsigned int u32;
- /*
- * poly1305_blocks processes a multiple of POLY1305_BLOCK_SIZE blocks
- * of |inp| no longer than |len|. Behaviour for |len| not divisible by
- * block size is unspecified in general case, even though in reference
- * implementation the trailing chunk is simply ignored. Per algorithm
- * specification, every input block, complete or last partial, is to be
- * padded with a bit past most significant byte. The latter kind is then
- * padded with zeros till block size. This last partial block padding
- * is caller(*)'s responsibility, and because of this the last partial
- * block is always processed with separate call with |len| set to
- * POLY1305_BLOCK_SIZE and |padbit| to 0. In all other cases |padbit|
- * should be set to 1 to perform implicit padding with 128th bit.
- * poly1305_blocks does not actually check for this constraint though,
- * it's caller(*)'s responsibility to comply.
- *
- * (*) In the context "caller" is not application code, but higher
- * level Poly1305_* from this very module, so that quirks are
- * handled locally.
- */
- static void
- poly1305_blocks(void *ctx, const unsigned char *inp, size_t len, u32 padbit);
- /*
- * Type-agnostic "rip-off" from constant_time_locl.h
- */
- # define CONSTANT_TIME_CARRY(a,b) ( \
- (a ^ ((a ^ b) | ((a - b) ^ b))) >> (sizeof(a) * 8 - 1) \
- )
- # if (defined(__SIZEOF_INT128__) && __SIZEOF_INT128__==16) && \
- (defined(__SIZEOF_LONG__) && __SIZEOF_LONG__==8)
- typedef unsigned long u64;
- typedef __uint128_t u128;
- typedef struct {
- u64 h[3];
- u64 r[2];
- } poly1305_internal;
- /* pick 32-bit unsigned integer in little endian order */
- static u64 U8TOU64(const unsigned char *p)
- {
- return (((u64)(p[0] & 0xff)) |
- ((u64)(p[1] & 0xff) << 8) |
- ((u64)(p[2] & 0xff) << 16) |
- ((u64)(p[3] & 0xff) << 24) |
- ((u64)(p[4] & 0xff) << 32) |
- ((u64)(p[5] & 0xff) << 40) |
- ((u64)(p[6] & 0xff) << 48) |
- ((u64)(p[7] & 0xff) << 56));
- }
- /* store a 32-bit unsigned integer in little endian */
- static void U64TO8(unsigned char *p, u64 v)
- {
- p[0] = (unsigned char)((v) & 0xff);
- p[1] = (unsigned char)((v >> 8) & 0xff);
- p[2] = (unsigned char)((v >> 16) & 0xff);
- p[3] = (unsigned char)((v >> 24) & 0xff);
- p[4] = (unsigned char)((v >> 32) & 0xff);
- p[5] = (unsigned char)((v >> 40) & 0xff);
- p[6] = (unsigned char)((v >> 48) & 0xff);
- p[7] = (unsigned char)((v >> 56) & 0xff);
- }
- static void poly1305_init(void *ctx, const unsigned char key[16])
- {
- poly1305_internal *st = (poly1305_internal *) ctx;
- /* h = 0 */
- st->h[0] = 0;
- st->h[1] = 0;
- st->h[2] = 0;
- /* r &= 0xffffffc0ffffffc0ffffffc0fffffff */
- st->r[0] = U8TOU64(&key[0]) & 0x0ffffffc0fffffff;
- st->r[1] = U8TOU64(&key[8]) & 0x0ffffffc0ffffffc;
- }
- static void
- poly1305_blocks(void *ctx, const unsigned char *inp, size_t len, u32 padbit)
- {
- poly1305_internal *st = (poly1305_internal *)ctx;
- u64 r0, r1;
- u64 s1;
- u64 h0, h1, h2, c;
- u128 d0, d1;
- r0 = st->r[0];
- r1 = st->r[1];
- s1 = r1 + (r1 >> 2);
- h0 = st->h[0];
- h1 = st->h[1];
- h2 = st->h[2];
- while (len >= POLY1305_BLOCK_SIZE) {
- /* h += m[i] */
- h0 = (u64)(d0 = (u128)h0 + U8TOU64(inp + 0));
- h1 = (u64)(d1 = (u128)h1 + (d0 >> 64) + U8TOU64(inp + 8));
- /*
- * padbit can be zero only when original len was
- * POLY1306_BLOCK_SIZE, but we don't check
- */
- h2 += (u64)(d1 >> 64) + padbit;
- /* h *= r "%" p, where "%" stands for "partial remainder" */
- d0 = ((u128)h0 * r0) +
- ((u128)h1 * s1);
- d1 = ((u128)h0 * r1) +
- ((u128)h1 * r0) +
- (h2 * s1);
- h2 = (h2 * r0);
- /* last reduction step: */
- /* a) h2:h0 = h2<<128 + d1<<64 + d0 */
- h0 = (u64)d0;
- h1 = (u64)(d1 += d0 >> 64);
- h2 += (u64)(d1 >> 64);
- /* b) (h2:h0 += (h2:h0>>130) * 5) %= 2^130 */
- c = (h2 >> 2) + (h2 & ~3UL);
- h2 &= 3;
- h0 += c;
- h1 += (c = CONSTANT_TIME_CARRY(h0,c));
- h2 += CONSTANT_TIME_CARRY(h1,c);
- /*
- * Occasional overflows to 3rd bit of h2 are taken care of
- * "naturally". If after this point we end up at the top of
- * this loop, then the overflow bit will be accounted for
- * in next iteration. If we end up in poly1305_emit, then
- * comparison to modulus below will still count as "carry
- * into 131st bit", so that properly reduced value will be
- * picked in conditional move.
- */
- inp += POLY1305_BLOCK_SIZE;
- len -= POLY1305_BLOCK_SIZE;
- }
- st->h[0] = h0;
- st->h[1] = h1;
- st->h[2] = h2;
- }
- static void poly1305_emit(void *ctx, unsigned char mac[16],
- const u32 nonce[4])
- {
- poly1305_internal *st = (poly1305_internal *) ctx;
- u64 h0, h1, h2;
- u64 g0, g1, g2;
- u128 t;
- u64 mask;
- h0 = st->h[0];
- h1 = st->h[1];
- h2 = st->h[2];
- /* compare to modulus by computing h + -p */
- g0 = (u64)(t = (u128)h0 + 5);
- g1 = (u64)(t = (u128)h1 + (t >> 64));
- g2 = h2 + (u64)(t >> 64);
- /* if there was carry into 131st bit, h1:h0 = g1:g0 */
- mask = 0 - (g2 >> 2);
- g0 &= mask;
- g1 &= mask;
- mask = ~mask;
- h0 = (h0 & mask) | g0;
- h1 = (h1 & mask) | g1;
- /* mac = (h + nonce) % (2^128) */
- h0 = (u64)(t = (u128)h0 + nonce[0] + ((u64)nonce[1]<<32));
- h1 = (u64)(t = (u128)h1 + nonce[2] + ((u64)nonce[3]<<32) + (t >> 64));
- U64TO8(mac + 0, h0);
- U64TO8(mac + 8, h1);
- }
- # else
- # if defined(_WIN32) && !defined(__MINGW32__)
- typedef unsigned __int64 u64;
- # elif defined(__arch64__)
- typedef unsigned long u64;
- # else
- typedef unsigned long long u64;
- # endif
- typedef struct {
- u32 h[5];
- u32 r[4];
- } poly1305_internal;
- /* store a 32-bit unsigned integer in little endian */
- static void U32TO8(unsigned char *p, unsigned int v)
- {
- p[0] = (unsigned char)((v) & 0xff);
- p[1] = (unsigned char)((v >> 8) & 0xff);
- p[2] = (unsigned char)((v >> 16) & 0xff);
- p[3] = (unsigned char)((v >> 24) & 0xff);
- }
- static void poly1305_init(void *ctx, const unsigned char key[16])
- {
- poly1305_internal *st = (poly1305_internal *) ctx;
- /* h = 0 */
- st->h[0] = 0;
- st->h[1] = 0;
- st->h[2] = 0;
- st->h[3] = 0;
- st->h[4] = 0;
- /* r &= 0xffffffc0ffffffc0ffffffc0fffffff */
- st->r[0] = U8TOU32(&key[0]) & 0x0fffffff;
- st->r[1] = U8TOU32(&key[4]) & 0x0ffffffc;
- st->r[2] = U8TOU32(&key[8]) & 0x0ffffffc;
- st->r[3] = U8TOU32(&key[12]) & 0x0ffffffc;
- }
- static void
- poly1305_blocks(void *ctx, const unsigned char *inp, size_t len, u32 padbit)
- {
- poly1305_internal *st = (poly1305_internal *)ctx;
- u32 r0, r1, r2, r3;
- u32 s1, s2, s3;
- u32 h0, h1, h2, h3, h4, c;
- u64 d0, d1, d2, d3;
- r0 = st->r[0];
- r1 = st->r[1];
- r2 = st->r[2];
- r3 = st->r[3];
- s1 = r1 + (r1 >> 2);
- s2 = r2 + (r2 >> 2);
- s3 = r3 + (r3 >> 2);
- h0 = st->h[0];
- h1 = st->h[1];
- h2 = st->h[2];
- h3 = st->h[3];
- h4 = st->h[4];
- while (len >= POLY1305_BLOCK_SIZE) {
- /* h += m[i] */
- h0 = (u32)(d0 = (u64)h0 + U8TOU32(inp + 0));
- h1 = (u32)(d1 = (u64)h1 + (d0 >> 32) + U8TOU32(inp + 4));
- h2 = (u32)(d2 = (u64)h2 + (d1 >> 32) + U8TOU32(inp + 8));
- h3 = (u32)(d3 = (u64)h3 + (d2 >> 32) + U8TOU32(inp + 12));
- h4 += (u32)(d3 >> 32) + padbit;
- /* h *= r "%" p, where "%" stands for "partial remainder" */
- d0 = ((u64)h0 * r0) +
- ((u64)h1 * s3) +
- ((u64)h2 * s2) +
- ((u64)h3 * s1);
- d1 = ((u64)h0 * r1) +
- ((u64)h1 * r0) +
- ((u64)h2 * s3) +
- ((u64)h3 * s2) +
- (h4 * s1);
- d2 = ((u64)h0 * r2) +
- ((u64)h1 * r1) +
- ((u64)h2 * r0) +
- ((u64)h3 * s3) +
- (h4 * s2);
- d3 = ((u64)h0 * r3) +
- ((u64)h1 * r2) +
- ((u64)h2 * r1) +
- ((u64)h3 * r0) +
- (h4 * s3);
- h4 = (h4 * r0);
- /* last reduction step: */
- /* a) h4:h0 = h4<<128 + d3<<96 + d2<<64 + d1<<32 + d0 */
- h0 = (u32)d0;
- h1 = (u32)(d1 += d0 >> 32);
- h2 = (u32)(d2 += d1 >> 32);
- h3 = (u32)(d3 += d2 >> 32);
- h4 += (u32)(d3 >> 32);
- /* b) (h4:h0 += (h4:h0>>130) * 5) %= 2^130 */
- c = (h4 >> 2) + (h4 & ~3U);
- h4 &= 3;
- h0 += c;
- h1 += (c = CONSTANT_TIME_CARRY(h0,c));
- h2 += (c = CONSTANT_TIME_CARRY(h1,c));
- h3 += (c = CONSTANT_TIME_CARRY(h2,c));
- h4 += CONSTANT_TIME_CARRY(h3,c);
- /*
- * Occasional overflows to 3rd bit of h4 are taken care of
- * "naturally". If after this point we end up at the top of
- * this loop, then the overflow bit will be accounted for
- * in next iteration. If we end up in poly1305_emit, then
- * comparison to modulus below will still count as "carry
- * into 131st bit", so that properly reduced value will be
- * picked in conditional move.
- */
- inp += POLY1305_BLOCK_SIZE;
- len -= POLY1305_BLOCK_SIZE;
- }
- st->h[0] = h0;
- st->h[1] = h1;
- st->h[2] = h2;
- st->h[3] = h3;
- st->h[4] = h4;
- }
- static void poly1305_emit(void *ctx, unsigned char mac[16],
- const u32 nonce[4])
- {
- poly1305_internal *st = (poly1305_internal *) ctx;
- u32 h0, h1, h2, h3, h4;
- u32 g0, g1, g2, g3, g4;
- u64 t;
- u32 mask;
- h0 = st->h[0];
- h1 = st->h[1];
- h2 = st->h[2];
- h3 = st->h[3];
- h4 = st->h[4];
- /* compare to modulus by computing h + -p */
- g0 = (u32)(t = (u64)h0 + 5);
- g1 = (u32)(t = (u64)h1 + (t >> 32));
- g2 = (u32)(t = (u64)h2 + (t >> 32));
- g3 = (u32)(t = (u64)h3 + (t >> 32));
- g4 = h4 + (u32)(t >> 32);
- /* if there was carry into 131st bit, h3:h0 = g3:g0 */
- mask = 0 - (g4 >> 2);
- g0 &= mask;
- g1 &= mask;
- g2 &= mask;
- g3 &= mask;
- mask = ~mask;
- h0 = (h0 & mask) | g0;
- h1 = (h1 & mask) | g1;
- h2 = (h2 & mask) | g2;
- h3 = (h3 & mask) | g3;
- /* mac = (h + nonce) % (2^128) */
- h0 = (u32)(t = (u64)h0 + nonce[0]);
- h1 = (u32)(t = (u64)h1 + (t >> 32) + nonce[1]);
- h2 = (u32)(t = (u64)h2 + (t >> 32) + nonce[2]);
- h3 = (u32)(t = (u64)h3 + (t >> 32) + nonce[3]);
- U32TO8(mac + 0, h0);
- U32TO8(mac + 4, h1);
- U32TO8(mac + 8, h2);
- U32TO8(mac + 12, h3);
- }
- # endif
- #else
- int poly1305_init(void *ctx, const unsigned char key[16], void *func);
- void poly1305_blocks(void *ctx, const unsigned char *inp, size_t len,
- unsigned int padbit);
- void poly1305_emit(void *ctx, unsigned char mac[16],
- const unsigned int nonce[4]);
- #endif
- void Poly1305_Init(POLY1305 *ctx, const unsigned char key[32])
- {
- ctx->nonce[0] = U8TOU32(&key[16]);
- ctx->nonce[1] = U8TOU32(&key[20]);
- ctx->nonce[2] = U8TOU32(&key[24]);
- ctx->nonce[3] = U8TOU32(&key[28]);
- #ifndef POLY1305_ASM
- poly1305_init(ctx->opaque, key);
- #else
- /*
- * Unlike reference poly1305_init assembly counterpart is expected
- * to return a value: non-zero if it initializes ctx->func, and zero
- * otherwise. Latter is to simplify assembly in cases when there no
- * multiple code paths to switch between.
- */
- if (!poly1305_init(ctx->opaque, key, &ctx->func)) {
- ctx->func.blocks = poly1305_blocks;
- ctx->func.emit = poly1305_emit;
- }
- #endif
- ctx->num = 0;
- }
- #ifdef POLY1305_ASM
- /*
- * This "eclipses" poly1305_blocks and poly1305_emit, but it's
- * conscious choice imposed by -Wshadow compiler warnings.
- */
- # define poly1305_blocks (*poly1305_blocks_p)
- # define poly1305_emit (*poly1305_emit_p)
- #endif
- void Poly1305_Update(POLY1305 *ctx, const unsigned char *inp, size_t len)
- {
- #ifdef POLY1305_ASM
- /*
- * As documented, poly1305_blocks is never called with input
- * longer than single block and padbit argument set to 0. This
- * property is fluently used in assembly modules to optimize
- * padbit handling on loop boundary.
- */
- poly1305_blocks_f poly1305_blocks_p = ctx->func.blocks;
- #endif
- size_t rem, num;
- if ((num = ctx->num)) {
- rem = POLY1305_BLOCK_SIZE - num;
- if (len >= rem) {
- memcpy(ctx->data + num, inp, rem);
- poly1305_blocks(ctx->opaque, ctx->data, POLY1305_BLOCK_SIZE, 1);
- inp += rem;
- len -= rem;
- } else {
- /* Still not enough data to process a block. */
- memcpy(ctx->data + num, inp, len);
- ctx->num = num + len;
- return;
- }
- }
- rem = len % POLY1305_BLOCK_SIZE;
- len -= rem;
- if (len >= POLY1305_BLOCK_SIZE) {
- poly1305_blocks(ctx->opaque, inp, len, 1);
- inp += len;
- }
- if (rem)
- memcpy(ctx->data, inp, rem);
- ctx->num = rem;
- }
- void Poly1305_Final(POLY1305 *ctx, unsigned char mac[16])
- {
- #ifdef POLY1305_ASM
- poly1305_blocks_f poly1305_blocks_p = ctx->func.blocks;
- poly1305_emit_f poly1305_emit_p = ctx->func.emit;
- #endif
- size_t num;
- if ((num = ctx->num)) {
- ctx->data[num++] = 1; /* pad bit */
- while (num < POLY1305_BLOCK_SIZE)
- ctx->data[num++] = 0;
- poly1305_blocks(ctx->opaque, ctx->data, POLY1305_BLOCK_SIZE, 0);
- }
- poly1305_emit(ctx->opaque, mac, ctx->nonce);
- /* zero out the state */
- OPENSSL_cleanse(ctx, sizeof(*ctx));
- }
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