boringssl/crypto/fipsmodule/modes/gcm.c
David Benjamin 73535ab252 Fix undefined block128_f, etc., casts.
This one is a little thorny. All the various block cipher modes
functions and callbacks take a void *key. This allows them to be used
with multiple kinds of block ciphers.

However, the implementations of those callbacks are the normal typed
functions, like AES_encrypt. Those take AES_KEY *key. While, at the ABI
level, this is perfectly fine, C considers this undefined behavior.

If we wish to preserve this genericness, we could either instantiate
multiple versions of these mode functions or create wrappers of
AES_encrypt, etc., that take void *key.

The former means more code and is tedious without C++ templates (maybe
someday...). The latter would not be difficult for a compiler to
optimize out. C mistakenly allowed comparing function pointers for
equality, which means a compiler cannot replace pointers to wrapper
functions with the real thing. (That said, the performance-sensitive
bits already act in chunks, e.g. ctr128_f, so the function call overhead
shouldn't matter.)

But our only 128-bit block cipher is AES anyway, so I just switched
things to use AES_KEY throughout. AES is doing fine, and hopefully we
would have the sense not to pair a hypothetical future block cipher with
so many modes!

Change-Id: Ied3e843f0e3042a439f09e655b29847ade9d4c7d
Reviewed-on: https://boringssl-review.googlesource.com/32107
Reviewed-by: Adam Langley <agl@google.com>
2018-10-01 17:35:02 +00:00

1073 lines
28 KiB
C

/* ====================================================================
* Copyright (c) 2008 The OpenSSL Project. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
*
* 3. All advertising materials mentioning features or use of this
* software must display the following acknowledgment:
* "This product includes software developed by the OpenSSL Project
* for use in the OpenSSL Toolkit. (http://www.openssl.org/)"
*
* 4. The names "OpenSSL Toolkit" and "OpenSSL Project" must not be used to
* endorse or promote products derived from this software without
* prior written permission. For written permission, please contact
* openssl-core@openssl.org.
*
* 5. Products derived from this software may not be called "OpenSSL"
* nor may "OpenSSL" appear in their names without prior written
* permission of the OpenSSL Project.
*
* 6. Redistributions of any form whatsoever must retain the following
* acknowledgment:
* "This product includes software developed by the OpenSSL Project
* for use in the OpenSSL Toolkit (http://www.openssl.org/)"
*
* THIS SOFTWARE IS PROVIDED BY THE OpenSSL PROJECT ``AS IS'' AND ANY
* EXPRESSED OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE OpenSSL PROJECT OR
* ITS CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
* STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED
* OF THE POSSIBILITY OF SUCH DAMAGE.
* ==================================================================== */
#include <openssl/base.h>
#include <assert.h>
#include <string.h>
#include <openssl/mem.h>
#include <openssl/cpu.h>
#include "internal.h"
#include "../../internal.h"
#if !defined(OPENSSL_NO_ASM) && \
(defined(OPENSSL_X86) || defined(OPENSSL_X86_64) || \
defined(OPENSSL_ARM) || defined(OPENSSL_AARCH64) || \
defined(OPENSSL_PPC64LE))
#define GHASH_ASM
#endif
#define PACK(s) ((size_t)(s) << (sizeof(size_t) * 8 - 16))
#define REDUCE1BIT(V) \
do { \
if (sizeof(size_t) == 8) { \
uint64_t T = UINT64_C(0xe100000000000000) & (0 - ((V).lo & 1)); \
(V).lo = ((V).hi << 63) | ((V).lo >> 1); \
(V).hi = ((V).hi >> 1) ^ T; \
} else { \
uint32_t T = 0xe1000000U & (0 - (uint32_t)((V).lo & 1)); \
(V).lo = ((V).hi << 63) | ((V).lo >> 1); \
(V).hi = ((V).hi >> 1) ^ ((uint64_t)T << 32); \
} \
} while (0)
// kSizeTWithoutLower4Bits is a mask that can be used to zero the lower four
// bits of a |size_t|.
static const size_t kSizeTWithoutLower4Bits = (size_t) -16;
static void gcm_init_4bit(u128 Htable[16], uint64_t H[2]) {
u128 V;
Htable[0].hi = 0;
Htable[0].lo = 0;
V.hi = H[0];
V.lo = H[1];
Htable[8] = V;
REDUCE1BIT(V);
Htable[4] = V;
REDUCE1BIT(V);
Htable[2] = V;
REDUCE1BIT(V);
Htable[1] = V;
Htable[3].hi = V.hi ^ Htable[2].hi, Htable[3].lo = V.lo ^ Htable[2].lo;
V = Htable[4];
Htable[5].hi = V.hi ^ Htable[1].hi, Htable[5].lo = V.lo ^ Htable[1].lo;
Htable[6].hi = V.hi ^ Htable[2].hi, Htable[6].lo = V.lo ^ Htable[2].lo;
Htable[7].hi = V.hi ^ Htable[3].hi, Htable[7].lo = V.lo ^ Htable[3].lo;
V = Htable[8];
Htable[9].hi = V.hi ^ Htable[1].hi, Htable[9].lo = V.lo ^ Htable[1].lo;
Htable[10].hi = V.hi ^ Htable[2].hi, Htable[10].lo = V.lo ^ Htable[2].lo;
Htable[11].hi = V.hi ^ Htable[3].hi, Htable[11].lo = V.lo ^ Htable[3].lo;
Htable[12].hi = V.hi ^ Htable[4].hi, Htable[12].lo = V.lo ^ Htable[4].lo;
Htable[13].hi = V.hi ^ Htable[5].hi, Htable[13].lo = V.lo ^ Htable[5].lo;
Htable[14].hi = V.hi ^ Htable[6].hi, Htable[14].lo = V.lo ^ Htable[6].lo;
Htable[15].hi = V.hi ^ Htable[7].hi, Htable[15].lo = V.lo ^ Htable[7].lo;
#if defined(GHASH_ASM) && defined(OPENSSL_ARM)
for (int j = 0; j < 16; ++j) {
V = Htable[j];
Htable[j].hi = V.lo;
Htable[j].lo = V.hi;
}
#endif
}
#if !defined(GHASH_ASM) || defined(OPENSSL_AARCH64) || defined(OPENSSL_PPC64LE)
static const size_t rem_4bit[16] = {
PACK(0x0000), PACK(0x1C20), PACK(0x3840), PACK(0x2460),
PACK(0x7080), PACK(0x6CA0), PACK(0x48C0), PACK(0x54E0),
PACK(0xE100), PACK(0xFD20), PACK(0xD940), PACK(0xC560),
PACK(0x9180), PACK(0x8DA0), PACK(0xA9C0), PACK(0xB5E0)};
static void gcm_gmult_4bit(uint64_t Xi[2], const u128 Htable[16]) {
u128 Z;
int cnt = 15;
size_t rem, nlo, nhi;
nlo = ((const uint8_t *)Xi)[15];
nhi = nlo >> 4;
nlo &= 0xf;
Z.hi = Htable[nlo].hi;
Z.lo = Htable[nlo].lo;
while (1) {
rem = (size_t)Z.lo & 0xf;
Z.lo = (Z.hi << 60) | (Z.lo >> 4);
Z.hi = (Z.hi >> 4);
if (sizeof(size_t) == 8) {
Z.hi ^= rem_4bit[rem];
} else {
Z.hi ^= (uint64_t)rem_4bit[rem] << 32;
}
Z.hi ^= Htable[nhi].hi;
Z.lo ^= Htable[nhi].lo;
if (--cnt < 0) {
break;
}
nlo = ((const uint8_t *)Xi)[cnt];
nhi = nlo >> 4;
nlo &= 0xf;
rem = (size_t)Z.lo & 0xf;
Z.lo = (Z.hi << 60) | (Z.lo >> 4);
Z.hi = (Z.hi >> 4);
if (sizeof(size_t) == 8) {
Z.hi ^= rem_4bit[rem];
} else {
Z.hi ^= (uint64_t)rem_4bit[rem] << 32;
}
Z.hi ^= Htable[nlo].hi;
Z.lo ^= Htable[nlo].lo;
}
Xi[0] = CRYPTO_bswap8(Z.hi);
Xi[1] = CRYPTO_bswap8(Z.lo);
}
// Streamed gcm_mult_4bit, see CRYPTO_gcm128_[en|de]crypt for
// details... Compiler-generated code doesn't seem to give any
// performance improvement, at least not on x86[_64]. It's here
// mostly as reference and a placeholder for possible future
// non-trivial optimization[s]...
static void gcm_ghash_4bit(uint64_t Xi[2], const u128 Htable[16],
const uint8_t *inp, size_t len) {
u128 Z;
int cnt;
size_t rem, nlo, nhi;
do {
cnt = 15;
nlo = ((const uint8_t *)Xi)[15];
nlo ^= inp[15];
nhi = nlo >> 4;
nlo &= 0xf;
Z.hi = Htable[nlo].hi;
Z.lo = Htable[nlo].lo;
while (1) {
rem = (size_t)Z.lo & 0xf;
Z.lo = (Z.hi << 60) | (Z.lo >> 4);
Z.hi = (Z.hi >> 4);
if (sizeof(size_t) == 8) {
Z.hi ^= rem_4bit[rem];
} else {
Z.hi ^= (uint64_t)rem_4bit[rem] << 32;
}
Z.hi ^= Htable[nhi].hi;
Z.lo ^= Htable[nhi].lo;
if (--cnt < 0) {
break;
}
nlo = ((const uint8_t *)Xi)[cnt];
nlo ^= inp[cnt];
nhi = nlo >> 4;
nlo &= 0xf;
rem = (size_t)Z.lo & 0xf;
Z.lo = (Z.hi << 60) | (Z.lo >> 4);
Z.hi = (Z.hi >> 4);
if (sizeof(size_t) == 8) {
Z.hi ^= rem_4bit[rem];
} else {
Z.hi ^= (uint64_t)rem_4bit[rem] << 32;
}
Z.hi ^= Htable[nlo].hi;
Z.lo ^= Htable[nlo].lo;
}
Xi[0] = CRYPTO_bswap8(Z.hi);
Xi[1] = CRYPTO_bswap8(Z.lo);
} while (inp += 16, len -= 16);
}
#else // GHASH_ASM
void gcm_gmult_4bit(uint64_t Xi[2], const u128 Htable[16]);
void gcm_ghash_4bit(uint64_t Xi[2], const u128 Htable[16], const uint8_t *inp,
size_t len);
#endif
#define GCM_MUL(ctx, Xi) gcm_gmult_4bit((ctx)->Xi.u, (ctx)->gcm_key.Htable)
#if defined(GHASH_ASM)
#define GHASH(ctx, in, len) \
gcm_ghash_4bit((ctx)->Xi.u, (ctx)->gcm_key.Htable, in, len)
// GHASH_CHUNK is "stride parameter" missioned to mitigate cache
// trashing effect. In other words idea is to hash data while it's
// still in L1 cache after encryption pass...
#define GHASH_CHUNK (3 * 1024)
#endif
#if defined(GHASH_ASM)
#if defined(OPENSSL_X86) || defined(OPENSSL_X86_64)
#define GCM_FUNCREF_4BIT
void gcm_init_clmul(u128 Htable[16], const uint64_t Xi[2]);
void gcm_gmult_clmul(uint64_t Xi[2], const u128 Htable[16]);
void gcm_ghash_clmul(uint64_t Xi[2], const u128 Htable[16], const uint8_t *inp,
size_t len);
#if defined(OPENSSL_X86_64)
#define GHASH_ASM_X86_64
void gcm_init_avx(u128 Htable[16], const uint64_t Xi[2]);
void gcm_gmult_avx(uint64_t Xi[2], const u128 Htable[16]);
void gcm_ghash_avx(uint64_t Xi[2], const u128 Htable[16], const uint8_t *in,
size_t len);
#define AESNI_GCM
size_t aesni_gcm_encrypt(const uint8_t *in, uint8_t *out, size_t len,
const AES_KEY *key, uint8_t ivec[16], uint64_t *Xi);
size_t aesni_gcm_decrypt(const uint8_t *in, uint8_t *out, size_t len,
const AES_KEY *key, uint8_t ivec[16], uint64_t *Xi);
#endif
#if defined(OPENSSL_X86)
#define GHASH_ASM_X86
void gcm_gmult_4bit_mmx(uint64_t Xi[2], const u128 Htable[16]);
void gcm_ghash_4bit_mmx(uint64_t Xi[2], const u128 Htable[16], const uint8_t *inp,
size_t len);
#endif
#elif defined(OPENSSL_ARM) || defined(OPENSSL_AARCH64)
#include <openssl/arm_arch.h>
#if __ARM_ARCH__ >= 7
#define GHASH_ASM_ARM
#define GCM_FUNCREF_4BIT
static int pmull_capable(void) {
return CRYPTO_is_ARMv8_PMULL_capable();
}
void gcm_init_v8(u128 Htable[16], const uint64_t Xi[2]);
void gcm_gmult_v8(uint64_t Xi[2], const u128 Htable[16]);
void gcm_ghash_v8(uint64_t Xi[2], const u128 Htable[16], const uint8_t *inp,
size_t len);
#if defined(OPENSSL_ARM)
// 32-bit ARM also has support for doing GCM with NEON instructions.
static int neon_capable(void) {
return CRYPTO_is_NEON_capable();
}
void gcm_init_neon(u128 Htable[16], const uint64_t Xi[2]);
void gcm_gmult_neon(uint64_t Xi[2], const u128 Htable[16]);
void gcm_ghash_neon(uint64_t Xi[2], const u128 Htable[16], const uint8_t *inp,
size_t len);
#else
// AArch64 only has the ARMv8 versions of functions.
static int neon_capable(void) {
return 0;
}
static void gcm_init_neon(u128 Htable[16], const uint64_t Xi[2]) {
abort();
}
static void gcm_gmult_neon(uint64_t Xi[2], const u128 Htable[16]) {
abort();
}
static void gcm_ghash_neon(uint64_t Xi[2], const u128 Htable[16],
const uint8_t *inp, size_t len) {
abort();
}
#endif
#endif
#elif defined(OPENSSL_PPC64LE)
#define GHASH_ASM_PPC64LE
#define GCM_FUNCREF_4BIT
void gcm_init_p8(u128 Htable[16], const uint64_t Xi[2]);
void gcm_gmult_p8(uint64_t Xi[2], const u128 Htable[16]);
void gcm_ghash_p8(uint64_t Xi[2], const u128 Htable[16], const uint8_t *inp,
size_t len);
#endif
#endif
#ifdef GCM_FUNCREF_4BIT
#undef GCM_MUL
#define GCM_MUL(ctx, Xi) (*gcm_gmult_p)((ctx)->Xi.u, (ctx)->gcm_key.Htable)
#ifdef GHASH
#undef GHASH
#define GHASH(ctx, in, len) \
(*gcm_ghash_p)((ctx)->Xi.u, (ctx)->gcm_key.Htable, in, len)
#endif
#endif
void CRYPTO_ghash_init(gmult_func *out_mult, ghash_func *out_hash,
u128 *out_key, u128 out_table[16],
int *out_is_avx,
const uint8_t *gcm_key) {
*out_is_avx = 0;
union {
uint64_t u[2];
uint8_t c[16];
} H;
OPENSSL_memcpy(H.c, gcm_key, 16);
// H is stored in host byte order
H.u[0] = CRYPTO_bswap8(H.u[0]);
H.u[1] = CRYPTO_bswap8(H.u[1]);
OPENSSL_memcpy(out_key, H.c, 16);
#if defined(GHASH_ASM_X86_64)
if (crypto_gcm_clmul_enabled()) {
if (((OPENSSL_ia32cap_get()[1] >> 22) & 0x41) == 0x41) { // AVX+MOVBE
gcm_init_avx(out_table, H.u);
*out_mult = gcm_gmult_avx;
*out_hash = gcm_ghash_avx;
*out_is_avx = 1;
return;
}
gcm_init_clmul(out_table, H.u);
*out_mult = gcm_gmult_clmul;
*out_hash = gcm_ghash_clmul;
return;
}
#elif defined(GHASH_ASM_X86)
if (crypto_gcm_clmul_enabled()) {
gcm_init_clmul(out_table, H.u);
*out_mult = gcm_gmult_clmul;
*out_hash = gcm_ghash_clmul;
return;
}
#elif defined(GHASH_ASM_ARM)
if (pmull_capable()) {
gcm_init_v8(out_table, H.u);
*out_mult = gcm_gmult_v8;
*out_hash = gcm_ghash_v8;
return;
}
if (neon_capable()) {
gcm_init_neon(out_table, H.u);
*out_mult = gcm_gmult_neon;
*out_hash = gcm_ghash_neon;
return;
}
#elif defined(GHASH_ASM_PPC64LE)
if (CRYPTO_is_PPC64LE_vcrypto_capable()) {
gcm_init_p8(out_table, H.u);
*out_mult = gcm_gmult_p8;
*out_hash = gcm_ghash_p8;
return;
}
#endif
gcm_init_4bit(out_table, H.u);
#if defined(GHASH_ASM_X86)
*out_mult = gcm_gmult_4bit_mmx;
*out_hash = gcm_ghash_4bit_mmx;
#else
*out_mult = gcm_gmult_4bit;
*out_hash = gcm_ghash_4bit;
#endif
}
void CRYPTO_gcm128_init_key(GCM128_KEY *gcm_key, const AES_KEY *aes_key,
block128_f block, int block_is_hwaes) {
OPENSSL_memset(gcm_key, 0, sizeof(*gcm_key));
gcm_key->block = block;
uint8_t ghash_key[16];
OPENSSL_memset(ghash_key, 0, sizeof(ghash_key));
(*block)(ghash_key, ghash_key, aes_key);
int is_avx;
CRYPTO_ghash_init(&gcm_key->gmult, &gcm_key->ghash, &gcm_key->H,
gcm_key->Htable, &is_avx, ghash_key);
gcm_key->use_aesni_gcm_crypt = (is_avx && block_is_hwaes) ? 1 : 0;
}
void CRYPTO_gcm128_setiv(GCM128_CONTEXT *ctx, const AES_KEY *key,
const uint8_t *iv, size_t len) {
unsigned int ctr;
#ifdef GCM_FUNCREF_4BIT
void (*gcm_gmult_p)(uint64_t Xi[2], const u128 Htable[16]) =
ctx->gcm_key.gmult;
#endif
ctx->Yi.u[0] = 0;
ctx->Yi.u[1] = 0;
ctx->Xi.u[0] = 0;
ctx->Xi.u[1] = 0;
ctx->len.u[0] = 0; // AAD length
ctx->len.u[1] = 0; // message length
ctx->ares = 0;
ctx->mres = 0;
if (len == 12) {
OPENSSL_memcpy(ctx->Yi.c, iv, 12);
ctx->Yi.c[15] = 1;
ctr = 1;
} else {
uint64_t len0 = len;
while (len >= 16) {
for (size_t i = 0; i < 16; ++i) {
ctx->Yi.c[i] ^= iv[i];
}
GCM_MUL(ctx, Yi);
iv += 16;
len -= 16;
}
if (len) {
for (size_t i = 0; i < len; ++i) {
ctx->Yi.c[i] ^= iv[i];
}
GCM_MUL(ctx, Yi);
}
len0 <<= 3;
ctx->Yi.u[1] ^= CRYPTO_bswap8(len0);
GCM_MUL(ctx, Yi);
ctr = CRYPTO_bswap4(ctx->Yi.d[3]);
}
(*ctx->gcm_key.block)(ctx->Yi.c, ctx->EK0.c, key);
++ctr;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
}
int CRYPTO_gcm128_aad(GCM128_CONTEXT *ctx, const uint8_t *aad, size_t len) {
unsigned int n;
uint64_t alen = ctx->len.u[0];
#ifdef GCM_FUNCREF_4BIT
void (*gcm_gmult_p)(uint64_t Xi[2], const u128 Htable[16]) =
ctx->gcm_key.gmult;
#ifdef GHASH
void (*gcm_ghash_p)(uint64_t Xi[2], const u128 Htable[16], const uint8_t *inp,
size_t len) = ctx->gcm_key.ghash;
#endif
#endif
if (ctx->len.u[1]) {
return 0;
}
alen += len;
if (alen > (UINT64_C(1) << 61) || (sizeof(len) == 8 && alen < len)) {
return 0;
}
ctx->len.u[0] = alen;
n = ctx->ares;
if (n) {
while (n && len) {
ctx->Xi.c[n] ^= *(aad++);
--len;
n = (n + 1) % 16;
}
if (n == 0) {
GCM_MUL(ctx, Xi);
} else {
ctx->ares = n;
return 1;
}
}
// Process a whole number of blocks.
#ifdef GHASH
size_t len_blocks = len & kSizeTWithoutLower4Bits;
if (len_blocks != 0) {
GHASH(ctx, aad, len_blocks);
aad += len_blocks;
len -= len_blocks;
}
#else
while (len >= 16) {
for (size_t i = 0; i < 16; ++i) {
ctx->Xi.c[i] ^= aad[i];
}
GCM_MUL(ctx, Xi);
aad += 16;
len -= 16;
}
#endif
// Process the remainder.
if (len != 0) {
n = (unsigned int)len;
for (size_t i = 0; i < len; ++i) {
ctx->Xi.c[i] ^= aad[i];
}
}
ctx->ares = n;
return 1;
}
int CRYPTO_gcm128_encrypt(GCM128_CONTEXT *ctx, const AES_KEY *key,
const uint8_t *in, uint8_t *out, size_t len) {
unsigned int n, ctr;
uint64_t mlen = ctx->len.u[1];
block128_f block = ctx->gcm_key.block;
#ifdef GCM_FUNCREF_4BIT
void (*gcm_gmult_p)(uint64_t Xi[2], const u128 Htable[16]) =
ctx->gcm_key.gmult;
#ifdef GHASH
void (*gcm_ghash_p)(uint64_t Xi[2], const u128 Htable[16], const uint8_t *inp,
size_t len) = ctx->gcm_key.ghash;
#endif
#endif
mlen += len;
if (mlen > ((UINT64_C(1) << 36) - 32) ||
(sizeof(len) == 8 && mlen < len)) {
return 0;
}
ctx->len.u[1] = mlen;
if (ctx->ares) {
// First call to encrypt finalizes GHASH(AAD)
GCM_MUL(ctx, Xi);
ctx->ares = 0;
}
ctr = CRYPTO_bswap4(ctx->Yi.d[3]);
n = ctx->mres;
if (n) {
while (n && len) {
ctx->Xi.c[n] ^= *(out++) = *(in++) ^ ctx->EKi.c[n];
--len;
n = (n + 1) % 16;
}
if (n == 0) {
GCM_MUL(ctx, Xi);
} else {
ctx->mres = n;
return 1;
}
}
if (STRICT_ALIGNMENT &&
((uintptr_t)in | (uintptr_t)out) % sizeof(size_t) != 0) {
for (size_t i = 0; i < len; ++i) {
if (n == 0) {
(*block)(ctx->Yi.c, ctx->EKi.c, key);
++ctr;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
}
ctx->Xi.c[n] ^= out[i] = in[i] ^ ctx->EKi.c[n];
n = (n + 1) % 16;
if (n == 0) {
GCM_MUL(ctx, Xi);
}
}
ctx->mres = n;
return 1;
}
#if defined(GHASH) && defined(GHASH_CHUNK)
while (len >= GHASH_CHUNK) {
size_t j = GHASH_CHUNK;
while (j) {
(*block)(ctx->Yi.c, ctx->EKi.c, key);
++ctr;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
for (size_t i = 0; i < 16; i += sizeof(size_t)) {
store_word_le(out + i,
load_word_le(in + i) ^ ctx->EKi.t[i / sizeof(size_t)]);
}
out += 16;
in += 16;
j -= 16;
}
GHASH(ctx, out - GHASH_CHUNK, GHASH_CHUNK);
len -= GHASH_CHUNK;
}
size_t len_blocks = len & kSizeTWithoutLower4Bits;
if (len_blocks != 0) {
while (len >= 16) {
(*block)(ctx->Yi.c, ctx->EKi.c, key);
++ctr;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
for (size_t i = 0; i < 16; i += sizeof(size_t)) {
store_word_le(out + i,
load_word_le(in + i) ^ ctx->EKi.t[i / sizeof(size_t)]);
}
out += 16;
in += 16;
len -= 16;
}
GHASH(ctx, out - len_blocks, len_blocks);
}
#else
while (len >= 16) {
(*block)(ctx->Yi.c, ctx->EKi.c, key);
++ctr;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
for (size_t i = 0; i < 16; i += sizeof(size_t)) {
size_t tmp = load_word_le(in + i) ^ ctx->EKi.t[i / sizeof(size_t)];
store_word_le(out + i, tmp);
ctx->Xi.t[i / sizeof(size_t)] ^= tmp;
}
GCM_MUL(ctx, Xi);
out += 16;
in += 16;
len -= 16;
}
#endif
if (len) {
(*block)(ctx->Yi.c, ctx->EKi.c, key);
++ctr;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
while (len--) {
ctx->Xi.c[n] ^= out[n] = in[n] ^ ctx->EKi.c[n];
++n;
}
}
ctx->mres = n;
return 1;
}
int CRYPTO_gcm128_decrypt(GCM128_CONTEXT *ctx, const AES_KEY *key,
const unsigned char *in, unsigned char *out,
size_t len) {
unsigned int n, ctr;
uint64_t mlen = ctx->len.u[1];
block128_f block = ctx->gcm_key.block;
#ifdef GCM_FUNCREF_4BIT
void (*gcm_gmult_p)(uint64_t Xi[2], const u128 Htable[16]) =
ctx->gcm_key.gmult;
#ifdef GHASH
void (*gcm_ghash_p)(uint64_t Xi[2], const u128 Htable[16], const uint8_t *inp,
size_t len) = ctx->gcm_key.ghash;
#endif
#endif
mlen += len;
if (mlen > ((UINT64_C(1) << 36) - 32) ||
(sizeof(len) == 8 && mlen < len)) {
return 0;
}
ctx->len.u[1] = mlen;
if (ctx->ares) {
// First call to decrypt finalizes GHASH(AAD)
GCM_MUL(ctx, Xi);
ctx->ares = 0;
}
ctr = CRYPTO_bswap4(ctx->Yi.d[3]);
n = ctx->mres;
if (n) {
while (n && len) {
uint8_t c = *(in++);
*(out++) = c ^ ctx->EKi.c[n];
ctx->Xi.c[n] ^= c;
--len;
n = (n + 1) % 16;
}
if (n == 0) {
GCM_MUL(ctx, Xi);
} else {
ctx->mres = n;
return 1;
}
}
if (STRICT_ALIGNMENT &&
((uintptr_t)in | (uintptr_t)out) % sizeof(size_t) != 0) {
for (size_t i = 0; i < len; ++i) {
uint8_t c;
if (n == 0) {
(*block)(ctx->Yi.c, ctx->EKi.c, key);
++ctr;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
}
c = in[i];
out[i] = c ^ ctx->EKi.c[n];
ctx->Xi.c[n] ^= c;
n = (n + 1) % 16;
if (n == 0) {
GCM_MUL(ctx, Xi);
}
}
ctx->mres = n;
return 1;
}
#if defined(GHASH) && defined(GHASH_CHUNK)
while (len >= GHASH_CHUNK) {
size_t j = GHASH_CHUNK;
GHASH(ctx, in, GHASH_CHUNK);
while (j) {
(*block)(ctx->Yi.c, ctx->EKi.c, key);
++ctr;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
for (size_t i = 0; i < 16; i += sizeof(size_t)) {
store_word_le(out + i,
load_word_le(in + i) ^ ctx->EKi.t[i / sizeof(size_t)]);
}
out += 16;
in += 16;
j -= 16;
}
len -= GHASH_CHUNK;
}
size_t len_blocks = len & kSizeTWithoutLower4Bits;
if (len_blocks != 0) {
GHASH(ctx, in, len_blocks);
while (len >= 16) {
(*block)(ctx->Yi.c, ctx->EKi.c, key);
++ctr;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
for (size_t i = 0; i < 16; i += sizeof(size_t)) {
store_word_le(out + i,
load_word_le(in + i) ^ ctx->EKi.t[i / sizeof(size_t)]);
}
out += 16;
in += 16;
len -= 16;
}
}
#else
while (len >= 16) {
(*block)(ctx->Yi.c, ctx->EKi.c, key);
++ctr;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
for (size_t i = 0; i < 16; i += sizeof(size_t)) {
size_t c = load_word_le(in + i);
store_word_le(out + i, c ^ ctx->EKi.t[i / sizeof(size_t)]);
ctx->Xi.t[i / sizeof(size_t)] ^= c;
}
GCM_MUL(ctx, Xi);
out += 16;
in += 16;
len -= 16;
}
#endif
if (len) {
(*block)(ctx->Yi.c, ctx->EKi.c, key);
++ctr;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
while (len--) {
uint8_t c = in[n];
ctx->Xi.c[n] ^= c;
out[n] = c ^ ctx->EKi.c[n];
++n;
}
}
ctx->mres = n;
return 1;
}
int CRYPTO_gcm128_encrypt_ctr32(GCM128_CONTEXT *ctx, const AES_KEY *key,
const uint8_t *in, uint8_t *out, size_t len,
ctr128_f stream) {
unsigned int n, ctr;
uint64_t mlen = ctx->len.u[1];
#ifdef GCM_FUNCREF_4BIT
void (*gcm_gmult_p)(uint64_t Xi[2], const u128 Htable[16]) =
ctx->gcm_key.gmult;
#ifdef GHASH
void (*gcm_ghash_p)(uint64_t Xi[2], const u128 Htable[16], const uint8_t *inp,
size_t len) = ctx->gcm_key.ghash;
#endif
#endif
mlen += len;
if (mlen > ((UINT64_C(1) << 36) - 32) ||
(sizeof(len) == 8 && mlen < len)) {
return 0;
}
ctx->len.u[1] = mlen;
if (ctx->ares) {
// First call to encrypt finalizes GHASH(AAD)
GCM_MUL(ctx, Xi);
ctx->ares = 0;
}
n = ctx->mres;
if (n) {
while (n && len) {
ctx->Xi.c[n] ^= *(out++) = *(in++) ^ ctx->EKi.c[n];
--len;
n = (n + 1) % 16;
}
if (n == 0) {
GCM_MUL(ctx, Xi);
} else {
ctx->mres = n;
return 1;
}
}
#if defined(AESNI_GCM)
if (ctx->gcm_key.use_aesni_gcm_crypt) {
// |aesni_gcm_encrypt| may not process all the input given to it. It may
// not process *any* of its input if it is deemed too small.
size_t bulk = aesni_gcm_encrypt(in, out, len, key, ctx->Yi.c, ctx->Xi.u);
in += bulk;
out += bulk;
len -= bulk;
}
#endif
ctr = CRYPTO_bswap4(ctx->Yi.d[3]);
#if defined(GHASH)
while (len >= GHASH_CHUNK) {
(*stream)(in, out, GHASH_CHUNK / 16, key, ctx->Yi.c);
ctr += GHASH_CHUNK / 16;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
GHASH(ctx, out, GHASH_CHUNK);
out += GHASH_CHUNK;
in += GHASH_CHUNK;
len -= GHASH_CHUNK;
}
#endif
size_t i = len & kSizeTWithoutLower4Bits;
if (i != 0) {
size_t j = i / 16;
(*stream)(in, out, j, key, ctx->Yi.c);
ctr += (unsigned int)j;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
in += i;
len -= i;
#if defined(GHASH)
GHASH(ctx, out, i);
out += i;
#else
while (j--) {
for (i = 0; i < 16; ++i) {
ctx->Xi.c[i] ^= out[i];
}
GCM_MUL(ctx, Xi);
out += 16;
}
#endif
}
if (len) {
(*ctx->gcm_key.block)(ctx->Yi.c, ctx->EKi.c, key);
++ctr;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
while (len--) {
ctx->Xi.c[n] ^= out[n] = in[n] ^ ctx->EKi.c[n];
++n;
}
}
ctx->mres = n;
return 1;
}
int CRYPTO_gcm128_decrypt_ctr32(GCM128_CONTEXT *ctx, const AES_KEY *key,
const uint8_t *in, uint8_t *out, size_t len,
ctr128_f stream) {
unsigned int n, ctr;
uint64_t mlen = ctx->len.u[1];
#ifdef GCM_FUNCREF_4BIT
void (*gcm_gmult_p)(uint64_t Xi[2], const u128 Htable[16]) =
ctx->gcm_key.gmult;
#ifdef GHASH
void (*gcm_ghash_p)(uint64_t Xi[2], const u128 Htable[16], const uint8_t *inp,
size_t len) = ctx->gcm_key.ghash;
#endif
#endif
mlen += len;
if (mlen > ((UINT64_C(1) << 36) - 32) ||
(sizeof(len) == 8 && mlen < len)) {
return 0;
}
ctx->len.u[1] = mlen;
if (ctx->ares) {
// First call to decrypt finalizes GHASH(AAD)
GCM_MUL(ctx, Xi);
ctx->ares = 0;
}
n = ctx->mres;
if (n) {
while (n && len) {
uint8_t c = *(in++);
*(out++) = c ^ ctx->EKi.c[n];
ctx->Xi.c[n] ^= c;
--len;
n = (n + 1) % 16;
}
if (n == 0) {
GCM_MUL(ctx, Xi);
} else {
ctx->mres = n;
return 1;
}
}
#if defined(AESNI_GCM)
if (ctx->gcm_key.use_aesni_gcm_crypt) {
// |aesni_gcm_decrypt| may not process all the input given to it. It may
// not process *any* of its input if it is deemed too small.
size_t bulk = aesni_gcm_decrypt(in, out, len, key, ctx->Yi.c, ctx->Xi.u);
in += bulk;
out += bulk;
len -= bulk;
}
#endif
ctr = CRYPTO_bswap4(ctx->Yi.d[3]);
#if defined(GHASH)
while (len >= GHASH_CHUNK) {
GHASH(ctx, in, GHASH_CHUNK);
(*stream)(in, out, GHASH_CHUNK / 16, key, ctx->Yi.c);
ctr += GHASH_CHUNK / 16;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
out += GHASH_CHUNK;
in += GHASH_CHUNK;
len -= GHASH_CHUNK;
}
#endif
size_t i = len & kSizeTWithoutLower4Bits;
if (i != 0) {
size_t j = i / 16;
#if defined(GHASH)
GHASH(ctx, in, i);
#else
while (j--) {
size_t k;
for (k = 0; k < 16; ++k) {
ctx->Xi.c[k] ^= in[k];
}
GCM_MUL(ctx, Xi);
in += 16;
}
j = i / 16;
in -= i;
#endif
(*stream)(in, out, j, key, ctx->Yi.c);
ctr += (unsigned int)j;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
out += i;
in += i;
len -= i;
}
if (len) {
(*ctx->gcm_key.block)(ctx->Yi.c, ctx->EKi.c, key);
++ctr;
ctx->Yi.d[3] = CRYPTO_bswap4(ctr);
while (len--) {
uint8_t c = in[n];
ctx->Xi.c[n] ^= c;
out[n] = c ^ ctx->EKi.c[n];
++n;
}
}
ctx->mres = n;
return 1;
}
int CRYPTO_gcm128_finish(GCM128_CONTEXT *ctx, const uint8_t *tag, size_t len) {
uint64_t alen = ctx->len.u[0] << 3;
uint64_t clen = ctx->len.u[1] << 3;
#ifdef GCM_FUNCREF_4BIT
void (*gcm_gmult_p)(uint64_t Xi[2], const u128 Htable[16]) =
ctx->gcm_key.gmult;
#endif
if (ctx->mres || ctx->ares) {
GCM_MUL(ctx, Xi);
}
alen = CRYPTO_bswap8(alen);
clen = CRYPTO_bswap8(clen);
ctx->Xi.u[0] ^= alen;
ctx->Xi.u[1] ^= clen;
GCM_MUL(ctx, Xi);
ctx->Xi.u[0] ^= ctx->EK0.u[0];
ctx->Xi.u[1] ^= ctx->EK0.u[1];
if (tag && len <= sizeof(ctx->Xi)) {
return CRYPTO_memcmp(ctx->Xi.c, tag, len) == 0;
} else {
return 0;
}
}
void CRYPTO_gcm128_tag(GCM128_CONTEXT *ctx, unsigned char *tag, size_t len) {
CRYPTO_gcm128_finish(ctx, NULL, 0);
OPENSSL_memcpy(tag, ctx->Xi.c,
len <= sizeof(ctx->Xi.c) ? len : sizeof(ctx->Xi.c));
}
#if defined(OPENSSL_X86) || defined(OPENSSL_X86_64)
int crypto_gcm_clmul_enabled(void) {
#ifdef GHASH_ASM
const uint32_t *ia32cap = OPENSSL_ia32cap_get();
return (ia32cap[0] & (1 << 24)) && // check FXSR bit
(ia32cap[1] & (1 << 1)); // check PCLMULQDQ bit
#else
return 0;
#endif
}
#endif