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/*
* Copyright Amazon.com, Inc. or its affiliates. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License").
* You may not use this file except in compliance with the License.
* A copy of the License is located at
*
* http://aws.amazon.com/apache2.0
*
* or in the "license" file accompanying this file. This file is distributed
* on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either
* express or implied. See the License for the specific language governing
* permissions and limitations under the License.
*/
#include <openssl/engine.h>
#include <openssl/rand.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <sys/param.h>
#include <unistd.h>
#include <pthread.h>
#include <limits.h>
#include <fcntl.h>
#include <string.h>
#include <stdint.h>
#include <stdlib.h>
#include <errno.h>
#include <time.h>
#if defined(S2N_CPUID_AVAILABLE)
#include <cpuid.h>
#endif
#include "api/s2n.h"
#include "crypto/s2n_drbg.h"
#include "error/s2n_errno.h"
#include "stuffer/s2n_stuffer.h"
#include "utils/s2n_fork_detection.h"
#include "utils/s2n_result.h"
#include "utils/s2n_safety.h"
#include "utils/s2n_random.h"
#include "utils/s2n_mem.h"
#define ENTROPY_SOURCE "/dev/urandom"
/* See https://en.wikipedia.org/wiki/CPUID */
#define RDRAND_ECX_FLAG 0x40000000
/* One second in nanoseconds */
#define ONE_S INT64_C(1000000000)
/* Placeholder value for an uninitialized entropy file descriptor */
#define UNINITIALIZED_ENTROPY_FD -1
static int entropy_fd = UNINITIALIZED_ENTROPY_FD;
struct s2n_rand_state {
uint64_t cached_fork_generation_number;
struct s2n_drbg public_drbg;
struct s2n_drbg private_drbg;
bool drbgs_initialized;
};
static __thread struct s2n_rand_state s2n_per_thread_rand_state = {
.cached_fork_generation_number = 0,
.public_drbg = {0},
.private_drbg = {0},
.drbgs_initialized = false
};
static int s2n_rand_init_impl(void);
static int s2n_rand_cleanup_impl(void);
static int s2n_rand_urandom_impl(void *ptr, uint32_t size);
static int s2n_rand_rdrand_impl(void *ptr, uint32_t size);
static s2n_rand_init_callback s2n_rand_init_cb = s2n_rand_init_impl;
static s2n_rand_cleanup_callback s2n_rand_cleanup_cb = s2n_rand_cleanup_impl;
static s2n_rand_seed_callback s2n_rand_seed_cb = s2n_rand_urandom_impl;
static s2n_rand_mix_callback s2n_rand_mix_cb = s2n_rand_urandom_impl;
/* non-static for SAW proof */
bool s2n_cpu_supports_rdrand() {
#if defined(S2N_CPUID_AVAILABLE)
uint32_t eax, ebx, ecx, edx;
if (!__get_cpuid(1, &eax, &ebx, &ecx, &edx)) {
return false;
}
if (ecx & RDRAND_ECX_FLAG) {
return true;
}
#endif
return false;
}
int s2n_rand_set_callbacks(s2n_rand_init_callback rand_init_callback,
s2n_rand_cleanup_callback rand_cleanup_callback,
s2n_rand_seed_callback rand_seed_callback,
s2n_rand_mix_callback rand_mix_callback)
{
POSIX_ENSURE_REF(rand_init_callback);
POSIX_ENSURE_REF(rand_cleanup_callback);
POSIX_ENSURE_REF(rand_seed_callback);
POSIX_ENSURE_REF(rand_mix_callback);
s2n_rand_init_cb = rand_init_callback;
s2n_rand_cleanup_cb = rand_cleanup_callback;
s2n_rand_seed_cb = rand_seed_callback;
s2n_rand_mix_cb = rand_mix_callback;
return S2N_SUCCESS;
}
S2N_RESULT s2n_get_seed_entropy(struct s2n_blob *blob)
{
RESULT_ENSURE_REF(blob);
RESULT_GUARD_POSIX(s2n_rand_seed_cb(blob->data, blob->size));
return S2N_RESULT_OK;
}
S2N_RESULT s2n_get_mix_entropy(struct s2n_blob *blob)
{
RESULT_ENSURE_REF(blob);
RESULT_GUARD_POSIX(s2n_rand_mix_cb(blob->data, blob->size));
return S2N_RESULT_OK;
}
static S2N_RESULT s2n_init_drbgs(void)
{
uint8_t s2n_public_drbg[] = "s2n public drbg";
uint8_t s2n_private_drbg[] = "s2n private drbg";
struct s2n_blob public = { .data = s2n_public_drbg, .size = sizeof(s2n_public_drbg) };
struct s2n_blob private = { .data = s2n_private_drbg, .size = sizeof(s2n_private_drbg) };
RESULT_GUARD(s2n_drbg_instantiate(&s2n_per_thread_rand_state.public_drbg, &public, S2N_AES_128_CTR_NO_DF_PR));
RESULT_GUARD(s2n_drbg_instantiate(&s2n_per_thread_rand_state.private_drbg, &private, S2N_AES_256_CTR_NO_DF_PR));
s2n_per_thread_rand_state.drbgs_initialized = true;
return S2N_RESULT_OK;
}
static S2N_RESULT s2n_ensure_initialized_drbgs(void)
{
if (s2n_per_thread_rand_state.drbgs_initialized == false) {
RESULT_GUARD(s2n_init_drbgs());
/* Then cache the fork generation number. We just initialized the drbg
* states with new entropy and forking is not an external event.
*/
uint64_t returned_fork_generation_number = 0;
RESULT_GUARD(s2n_get_fork_generation_number(&returned_fork_generation_number));
s2n_per_thread_rand_state.cached_fork_generation_number = returned_fork_generation_number;
}
return S2N_RESULT_OK;
}
/* s2n_ensure_uniqueness() implements defenses against uniqueness
* breaking events that might cause duplicated drbg states. Currently, only
* implements fork detection.
*/
static S2N_RESULT s2n_ensure_uniqueness(void)
{
uint64_t returned_fork_generation_number = 0;
RESULT_GUARD(s2n_get_fork_generation_number(&returned_fork_generation_number));
if (returned_fork_generation_number != s2n_per_thread_rand_state.cached_fork_generation_number) {
/* This assumes that s2n_rand_cleanup_thread() doesn't mutate any other
* state than the drbg states and it resets the drbg initialization
* boolean to false. s2n_ensure_initialized_drbgs() will cache the new
* fork generation number in the per thread state.
*/
RESULT_GUARD(s2n_rand_cleanup_thread());
RESULT_GUARD(s2n_ensure_initialized_drbgs());
}
return S2N_RESULT_OK;
}
static S2N_RESULT s2n_get_random_data(struct s2n_blob *out_blob,
struct s2n_drbg *drbg_state)
{
RESULT_GUARD(s2n_ensure_initialized_drbgs());
RESULT_GUARD(s2n_ensure_uniqueness());
uint32_t offset = 0;
uint32_t remaining = out_blob->size;
while(remaining) {
struct s2n_blob slice = { 0 };
RESULT_GUARD_POSIX(s2n_blob_slice(out_blob, &slice, offset, MIN(remaining, S2N_DRBG_GENERATE_LIMIT)));
RESULT_GUARD(s2n_drbg_generate(drbg_state, &slice));
remaining -= slice.size;
offset += slice.size;
}
return S2N_RESULT_OK;
}
S2N_RESULT s2n_get_public_random_data(struct s2n_blob *blob)
{
RESULT_GUARD(s2n_get_random_data(blob, &s2n_per_thread_rand_state.public_drbg));
return S2N_RESULT_OK;
}
S2N_RESULT s2n_get_private_random_data(struct s2n_blob *blob)
{
RESULT_GUARD(s2n_get_random_data(blob, &s2n_per_thread_rand_state.private_drbg));
return S2N_RESULT_OK;
}
S2N_RESULT s2n_get_public_random_bytes_used(uint64_t *bytes_used)
{
RESULT_GUARD(s2n_drbg_bytes_used(&s2n_per_thread_rand_state.public_drbg, bytes_used));
return S2N_RESULT_OK;
}
S2N_RESULT s2n_get_private_random_bytes_used(uint64_t *bytes_used)
{
RESULT_GUARD(s2n_drbg_bytes_used(&s2n_per_thread_rand_state.private_drbg, bytes_used));
return S2N_RESULT_OK;
}
static int s2n_rand_urandom_impl(void *ptr, uint32_t size)
{
POSIX_ENSURE(entropy_fd != UNINITIALIZED_ENTROPY_FD, S2N_ERR_NOT_INITIALIZED);
uint8_t *data = ptr;
uint32_t n = size;
struct timespec sleep_time = {.tv_sec = 0, .tv_nsec = 0 };
long backoff = 1;
while (n) {
errno = 0;
int r = read(entropy_fd, data, n);
if (r <= 0) {
/*
* A non-blocking read() on /dev/urandom should "never" fail,
* except for EINTR. If it does, briefly pause and use
* exponential backoff to avoid creating a tight spinning loop.
*
* iteration delay
* --------- -----------------
* 1 10 nsec
* 2 100 nsec
* 3 1,000 nsec
* 4 10,000 nsec
* 5 100,000 nsec
* 6 1,000,000 nsec
* 7 10,000,000 nsec
* 8 99,999,999 nsec
* 9 99,999,999 nsec
* ...
*/
if (errno != EINTR) {
backoff = MIN(backoff * 10, ONE_S - 1);
sleep_time.tv_nsec = backoff;
do {
r = nanosleep(&sleep_time, &sleep_time);
}
while (r != 0);
}
continue;
}
data += r;
n -= r;
}
return S2N_SUCCESS;
}
/*
* Return a random number in the range [0, bound)
*/
S2N_RESULT s2n_public_random(int64_t bound, uint64_t *output)
{
uint64_t r;
RESULT_ENSURE_GT(bound, 0);
while (1) {
struct s2n_blob blob = {.data = (void *)&r, sizeof(r) };
RESULT_GUARD(s2n_get_public_random_data(&blob));
/* Imagine an int was one byte and UINT_MAX was 256. If the
* caller asked for s2n_random(129, ...) we'd end up in
* trouble. Each number in the range 0...127 would be twice
* as likely as 128. That's because r == 0 % 129 -> 0, and
* r == 129 % 129 -> 0, but only r == 128 returns 128,
* r == 257 is out of range.
*
* To de-bias the dice, we discard values of r that are higher
* that the highest multiple of 'bound' an int can support. If
* bound is a uint, then in the worst case we discard 50% - 1 r's.
* But since 'bound' is an int and INT_MAX is <= UINT_MAX / 2,
* in the worst case we discard 25% - 1 r's.
*/
if (r < (UINT64_MAX - (UINT64_MAX % bound))) {
*output = r % bound;
return S2N_RESULT_OK;
}
}
}
#if S2N_LIBCRYPTO_SUPPORTS_CUSTOM_RAND
#define S2N_RAND_ENGINE_ID "s2n_rand"
int s2n_openssl_compat_rand(unsigned char *buf, int num)
{
struct s2n_blob out = {.data = buf,.size = num };
if (s2n_result_is_error(s2n_get_private_random_data(&out))) {
return 0;
}
return 1;
}
int s2n_openssl_compat_status(void)
{
return 1;
}
int s2n_openssl_compat_init(ENGINE * unused)
{
return 1;
}
RAND_METHOD s2n_openssl_rand_method = {
.seed = NULL,
.bytes = s2n_openssl_compat_rand,
.cleanup = NULL,
.add = NULL,
.pseudorand = s2n_openssl_compat_rand,
.status = s2n_openssl_compat_status
};
#endif
static int s2n_rand_init_impl(void)
{
OPEN:
entropy_fd = open(ENTROPY_SOURCE, O_RDONLY);
if (entropy_fd == -1) {
if (errno == EINTR) {
goto OPEN;
}
POSIX_BAIL(S2N_ERR_OPEN_RANDOM);
}
if (s2n_cpu_supports_rdrand()) {
s2n_rand_mix_cb = s2n_rand_rdrand_impl;
}
return S2N_SUCCESS;
}
S2N_RESULT s2n_rand_init(void)
{
RESULT_GUARD_POSIX(s2n_rand_init_cb());
RESULT_GUARD(s2n_ensure_initialized_drbgs());
#if S2N_LIBCRYPTO_SUPPORTS_CUSTOM_RAND
/* Create an engine */
ENGINE *e = ENGINE_new();
RESULT_ENSURE(e != NULL, S2N_ERR_OPEN_RANDOM);
RESULT_GUARD_OSSL(ENGINE_set_id(e, S2N_RAND_ENGINE_ID), S2N_ERR_OPEN_RANDOM);
RESULT_GUARD_OSSL(ENGINE_set_name(e, "s2n entropy generator"), S2N_ERR_OPEN_RANDOM);
RESULT_GUARD_OSSL(ENGINE_set_flags(e, ENGINE_FLAGS_NO_REGISTER_ALL), S2N_ERR_OPEN_RANDOM);
RESULT_GUARD_OSSL(ENGINE_set_init_function(e, s2n_openssl_compat_init), S2N_ERR_OPEN_RANDOM);
RESULT_GUARD_OSSL(ENGINE_set_RAND(e, &s2n_openssl_rand_method), S2N_ERR_OPEN_RANDOM);
RESULT_GUARD_OSSL(ENGINE_add(e), S2N_ERR_OPEN_RANDOM);
RESULT_GUARD_OSSL(ENGINE_free(e) , S2N_ERR_OPEN_RANDOM);
/* Use that engine for rand() */
e = ENGINE_by_id(S2N_RAND_ENGINE_ID);
RESULT_ENSURE(e != NULL, S2N_ERR_OPEN_RANDOM);
RESULT_GUARD_OSSL(ENGINE_init(e), S2N_ERR_OPEN_RANDOM);
RESULT_GUARD_OSSL(ENGINE_set_default(e, ENGINE_METHOD_RAND), S2N_ERR_OPEN_RANDOM);
RESULT_GUARD_OSSL(ENGINE_free(e), S2N_ERR_OPEN_RANDOM);
#endif
return S2N_RESULT_OK;
}
static int s2n_rand_cleanup_impl(void)
{
POSIX_ENSURE(entropy_fd != UNINITIALIZED_ENTROPY_FD, S2N_ERR_NOT_INITIALIZED);
POSIX_GUARD(close(entropy_fd));
entropy_fd = UNINITIALIZED_ENTROPY_FD;
return S2N_SUCCESS;
}
S2N_RESULT s2n_rand_cleanup(void)
{
RESULT_GUARD_POSIX(s2n_rand_cleanup_cb());
#if S2N_LIBCRYPTO_SUPPORTS_CUSTOM_RAND
/* Cleanup our rand ENGINE in libcrypto */
ENGINE *rand_engine = ENGINE_by_id(S2N_RAND_ENGINE_ID);
if (rand_engine) {
ENGINE_remove(rand_engine);
ENGINE_finish(rand_engine);
ENGINE_free(rand_engine);
ENGINE_cleanup();
RAND_set_rand_engine(NULL);
RAND_set_rand_method(NULL);
}
#endif
s2n_rand_init_cb = s2n_rand_init_impl;
s2n_rand_cleanup_cb = s2n_rand_cleanup_impl;
s2n_rand_seed_cb = s2n_rand_urandom_impl;
s2n_rand_mix_cb = s2n_rand_urandom_impl;
return S2N_RESULT_OK;
}
S2N_RESULT s2n_rand_cleanup_thread(void)
{
/* Currently, it is only safe for this function to mutate the drbg states
* in the per thread rand state. See s2n_ensure_uniqueness().
*/
RESULT_GUARD(s2n_drbg_wipe(&s2n_per_thread_rand_state.private_drbg));
RESULT_GUARD(s2n_drbg_wipe(&s2n_per_thread_rand_state.public_drbg));
s2n_per_thread_rand_state.drbgs_initialized = false;
return S2N_RESULT_OK;
}
/* This must only be used for unit tests. Any real use is dangerous and will be
* overwritten in s2n_ensure_uniqueness() if it is forked. This was added to
* support known answer tests that use OpenSSL and s2n_get_private_random_data
* directly.
*/
S2N_RESULT s2n_set_private_drbg_for_test(struct s2n_drbg drbg)
{
RESULT_ENSURE(s2n_in_unit_test(), S2N_ERR_NOT_IN_UNIT_TEST);
RESULT_GUARD(s2n_drbg_wipe(&s2n_per_thread_rand_state.private_drbg));
s2n_per_thread_rand_state.private_drbg = drbg;
return S2N_RESULT_OK;
}
/*
* volatile is important to prevent the compiler from
* re-ordering or optimizing the use of RDRAND.
*/
static int s2n_rand_rdrand_impl(void *data, uint32_t size)
{
#if defined(__x86_64__) || defined(__i386__)
struct s2n_blob out = { .data = data, .size = size };
int space_remaining = 0;
struct s2n_stuffer stuffer = {0};
union {
uint64_t u64;
#if defined(__i386__)
struct {
/* since we check first that we're on intel, we can safely assume little endian. */
uint32_t u_low;
uint32_t u_high;
} i386_fields;
#endif /* defined(__i386__) */
uint8_t u8[8];
} output;
POSIX_GUARD(s2n_stuffer_init(&stuffer, &out));
while ((space_remaining = s2n_stuffer_space_remaining(&stuffer))) {
unsigned char success = 0;
output.u64 = 0;
for (int tries = 0; tries < 10; tries++) {
#if defined(__i386__)
/* execute the rdrand instruction, store the result in a general purpose register (it's assigned to
* output.i386_fields.u_low). Check the carry bit, which will be set on success. Then clober the register and reset
* the carry bit. Due to needing to support an ancient assembler we use the opcode syntax.
* the %b1 is to force compilers to use c1 instead of ecx.
* Here's a description of how the opcode is encoded:
* 0x0fc7 (rdrand)
* 0xf0 (store the result in eax).
*/
unsigned char success_high = 0, success_low = 0;
__asm__ __volatile__(".byte 0x0f, 0xc7, 0xf0;\n" "setc %b1;\n": "=a"(output.i386_fields.u_low), "=qm"(success_low)
:
:"cc");
__asm__ __volatile__(".byte 0x0f, 0xc7, 0xf0;\n" "setc %b1;\n": "=a"(output.i386_fields.u_high), "=qm"(success_high)
:
:"cc");
/* cppcheck-suppress knownConditionTrueFalse */
success = success_high & success_low;
/* Treat either all 1 or all 0 bits in either the high or low order
* bits as failure */
if (output.i386_fields.u_low == 0 ||
output.i386_fields.u_low == UINT32_MAX ||
output.i386_fields.u_high == 0 ||
output.i386_fields.u_high == UINT32_MAX) {
success = 0;
}
#else
/* execute the rdrand instruction, store the result in a general purpose register (it's assigned to
* output.u64). Check the carry bit, which will be set on success. Then clober the carry bit.
* Due to needing to support an ancient assembler we use the opcode syntax.
* the %b1 is to force compilers to use c1 instead of ecx.
* Here's a description of how the opcode is encoded:
* 0x48 (pick a 64-bit register it does more too, but that's all that matters there)
* 0x0fc7 (rdrand)
* 0xf0 (store the result in rax). */
__asm__ __volatile__(".byte 0x48, 0x0f, 0xc7, 0xf0;\n" "setc %b1;\n": "=a"(output.u64), "=qm"(success)
:
:"cc");
#endif /* defined(__i386__) */
/* Some AMD CPUs will find that RDRAND "sticks" on all 1s but still reports success.
* Some other very old CPUs use all 0s as an error condition while still reporting success.
* If we encounter either of these suspicious values (a 1/2^63 chance) we'll treat them as
* a failure and generate a new value.
*
* In the future we could add CPUID checks to detect processors with these known bugs,
* however it does not appear worth it. The entropy loss is negligible and the
* corresponding likelihood that a healthy CPU generates either of these values is also
* negligible (1/2^63). Finally, adding processor specific logic would greatly
* increase the complexity and would cause us to "miss" any unknown processors with
* similar bugs. */
if (output.u64 == UINT64_MAX ||
output.u64 == 0) {
success = 0;
}
if (success) {
break;
}
}
POSIX_ENSURE(success, S2N_ERR_RDRAND_FAILED);
int data_to_fill = MIN(sizeof(output), space_remaining);
POSIX_GUARD(s2n_stuffer_write_bytes(&stuffer, output.u8, data_to_fill));
}
return S2N_SUCCESS;
#else
POSIX_BAIL(S2N_ERR_UNSUPPORTED_CPU);
#endif
}
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