boringssl/crypto/rand/rand.c

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/* Copyright (c) 2014, Google Inc.
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
* SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION
* OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
* CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */
#include <openssl/rand.h>
#include <limits.h>
#include <string.h>
#include <openssl/mem.h>
#include "internal.h"
#include "../internal.h"
/* It's assumed that the operating system always has an unfailing source of
* entropy which is accessed via |CRYPTO_sysrand|. (If the operating system
* entropy source fails, it's up to |CRYPTO_sysrand| to abort the processwe
* don't try to handle it.)
*
* In addition, the hardware may provide a low-latency RNG. Intel's rdrand
* instruction is the canonical example of this. When a hardware RNG is
* available we don't need to worry about an RNG failure arising from fork()ing
* the process or moving a VM, so we can keep thread-local RNG state and XOR
* the hardware entropy in.
*
* (We assume that the OS entropy is safe from fork()ing and VM duplication.
* This might be a bit of a leap of faith, esp on Windows, but there's nothing
* that we can do about it.) */
/* rand_thread_state contains the per-thread state for the RNG. This is only
* used if the system has support for a hardware RNG. */
struct rand_thread_state {
uint8_t key[32];
uint64_t calls_used;
size_t bytes_used;
uint8_t partial_block[64];
unsigned partial_block_used;
};
/* kMaxCallsPerRefresh is the maximum number of |RAND_bytes| calls that we'll
* serve before reading a new key from the operating system. This only applies
* if we have a hardware RNG. */
static const unsigned kMaxCallsPerRefresh = 1024;
/* kMaxBytesPerRefresh is the maximum number of bytes that we'll return from
* |RAND_bytes| before reading a new key from the operating system. This only
* applies if we have a hardware RNG. */
static const uint64_t kMaxBytesPerRefresh = 1024 * 1024;
/* rand_thread_state_free frees a |rand_thread_state|. This is called when a
* thread exits. */
static void rand_thread_state_free(void *state) {
if (state == NULL) {
return;
}
OPENSSL_cleanse(state, sizeof(struct rand_thread_state));
OPENSSL_free(state);
}
extern void CRYPTO_chacha_20(uint8_t *out, const uint8_t *in, size_t in_len,
const uint8_t key[32], const uint8_t nonce[8],
size_t counter);
int RAND_bytes(uint8_t *buf, size_t len) {
if (len == 0) {
return 1;
}
Handle RDRAND failures. I mistakenly believed that only RDSEED could fail. However, the Intel manuals state that RDRAND can fail too. I can't actually observe it failing, even with all cores running RDRAND in a tight loop. In any case, the ChaCha20 masking means that it wouldn't be a big deal anyway. Still, this change tests the carry flag after RDRAND and the code falls back to |CRYPTO_sysrand| if RDRAND has a hiccup. (The Intel manuals suggest[1] calling RDRAND in a loop, ten times, before considering it to have failed. But a single failure appears to be such a rare event that the complexity in the asm code doesn't seem worth it.) This change also adds an asm function to fill a buffer with random data. Otherwise the overhead of calling |CRYPTO_rdrand|, and bouncing the data in and out of memory starts to add up. Thanks to W. Mark Kubacki, who may have reported this. (There's some confusion in the bug report.) Before: Did 6148000 RNG (16 bytes) operations in 1000080us: 98.4 MB/s Did 649000 RNG (256 bytes) operations in 1000281us: 166.1 MB/s Did 22000 RNG (8192 bytes) operations in 1033538us: 174.4 MB/s After: Did 6573000 RNG (16 bytes) operations in 1000002us: 105.2 MB/s Did 693000 RNG (256 bytes) operations in 1000127us: 177.4 MB/s Did 24000 RNG (8192 bytes) operations in 1028466us: 191.2 MB/s [1] Intel Reference Manual, section 7.3.17.1. Change-Id: Iba7f82e844ebacef535472a31f2dd749aad1190a Reviewed-on: https://boringssl-review.googlesource.com/5180 Reviewed-by: Adam Langley <agl@google.com>
2015-06-19 19:06:28 +01:00
if (!CRYPTO_have_hwrand() ||
!CRYPTO_hwrand(buf, len)) {
/* Without a hardware RNG to save us from address-space duplication, the OS
* entropy is used directly. */
CRYPTO_sysrand(buf, len);
return 1;
}
struct rand_thread_state *state =
CRYPTO_get_thread_local(OPENSSL_THREAD_LOCAL_RAND);
if (state == NULL) {
state = OPENSSL_malloc(sizeof(struct rand_thread_state));
if (state == NULL ||
!CRYPTO_set_thread_local(OPENSSL_THREAD_LOCAL_RAND, state,
rand_thread_state_free)) {
CRYPTO_sysrand(buf, len);
return 1;
}
memset(state->partial_block, 0, sizeof(state->partial_block));
state->calls_used = kMaxCallsPerRefresh;
}
if (state->calls_used >= kMaxCallsPerRefresh ||
state->bytes_used >= kMaxBytesPerRefresh) {
CRYPTO_sysrand(state->key, sizeof(state->key));
state->calls_used = 0;
state->bytes_used = 0;
state->partial_block_used = sizeof(state->partial_block);
}
if (len >= sizeof(state->partial_block)) {
size_t remaining = len;
while (remaining > 0) {
// kMaxBytesPerCall is only 2GB, while ChaCha can handle 256GB. But this
// is sufficient and easier on 32-bit.
static const size_t kMaxBytesPerCall = 0x80000000;
size_t todo = remaining;
if (todo > kMaxBytesPerCall) {
todo = kMaxBytesPerCall;
}
CRYPTO_chacha_20(buf, buf, todo, state->key,
(uint8_t *)&state->calls_used, 0);
buf += todo;
remaining -= todo;
state->calls_used++;
}
} else {
if (sizeof(state->partial_block) - state->partial_block_used < len) {
CRYPTO_chacha_20(state->partial_block, state->partial_block,
sizeof(state->partial_block), state->key,
(uint8_t *)&state->calls_used, 0);
state->partial_block_used = 0;
}
unsigned i;
for (i = 0; i < len; i++) {
buf[i] ^= state->partial_block[state->partial_block_used++];
}
state->calls_used++;
}
state->bytes_used += len;
return 1;
}
int RAND_pseudo_bytes(uint8_t *buf, size_t len) {
return RAND_bytes(buf, len);
}
void RAND_seed(const void *buf, int num) {}
int RAND_load_file(const char *path, long num) {
if (num < 0) { /* read the "whole file" */
return 1;
} else if (num <= INT_MAX) {
return (int) num;
} else {
return INT_MAX;
}
}
void RAND_add(const void *buf, int num, double entropy) {}
int RAND_egd(const char *path) {
return 255;
}
int RAND_poll(void) {
return 1;
}
int RAND_status(void) {
return 1;
}
static const struct rand_meth_st kSSLeayMethod = {NULL, NULL, NULL,
NULL, NULL, NULL};
RAND_METHOD *RAND_SSLeay(void) {
return (RAND_METHOD*) &kSSLeayMethod;
}
void RAND_set_rand_method(RAND_METHOD *method) {}