/* 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 #include #include #include #if defined(BORINGSSL_FIPS) #include #endif #include #include #include #include "internal.h" #include "../../internal.h" #include "../delocate.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 process—we // 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 use it // as an additional-data input to CTR-DRBG. // // (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.) // kReseedInterval is the number of generate calls made to CTR-DRBG before // reseeding. static const unsigned kReseedInterval = 4096; // CRNGT_BLOCK_SIZE is the number of bytes in a “block” for the purposes of the // continuous random number generator test in FIPS 140-2, section 4.9.2. #define CRNGT_BLOCK_SIZE 16 // rand_thread_state contains the per-thread state for the RNG. struct rand_thread_state { CTR_DRBG_STATE drbg; // calls is the number of generate calls made on |drbg| since it was last // (re)seeded. This is bound by |kReseedInterval|. unsigned calls; // last_block_valid is non-zero iff |last_block| contains data from // |CRYPTO_sysrand|. int last_block_valid; #if defined(BORINGSSL_FIPS) // last_block contains the previous block from |CRYPTO_sysrand|. uint8_t last_block[CRNGT_BLOCK_SIZE]; // next and prev form a NULL-terminated, double-linked list of all states in // a process. struct rand_thread_state *next, *prev; #endif }; #if defined(BORINGSSL_FIPS) // thread_states_list is the head of a linked-list of all |rand_thread_state| // objects in the process, one per thread. This is needed because FIPS requires // that they be zeroed on process exit, but thread-local destructors aren't // called when the whole process is exiting. DEFINE_BSS_GET(struct rand_thread_state *, thread_states_list); DEFINE_STATIC_MUTEX(thread_states_list_lock); static void rand_thread_state_clear_all(void) __attribute__((destructor)); static void rand_thread_state_clear_all(void) { CRYPTO_STATIC_MUTEX_lock_write(thread_states_list_lock_bss_get()); for (struct rand_thread_state *cur = *thread_states_list_bss_get(); cur != NULL; cur = cur->next) { CTR_DRBG_clear(&cur->drbg); } // |thread_states_list_lock is deliberately left locked so that any threads // that are still running will hang if they try to call |RAND_bytes|. } #endif // rand_thread_state_free frees a |rand_thread_state|. This is called when a // thread exits. static void rand_thread_state_free(void *state_in) { struct rand_thread_state *state = state_in; if (state_in == NULL) { return; } #if defined(BORINGSSL_FIPS) CRYPTO_STATIC_MUTEX_lock_write(thread_states_list_lock_bss_get()); if (state->prev != NULL) { state->prev->next = state->next; } else { *thread_states_list_bss_get() = state->next; } if (state->next != NULL) { state->next->prev = state->prev; } CRYPTO_STATIC_MUTEX_unlock_write(thread_states_list_lock_bss_get()); CTR_DRBG_clear(&state->drbg); #endif OPENSSL_free(state); } #if defined(OPENSSL_X86_64) && !defined(OPENSSL_NO_ASM) && \ !defined(BORINGSSL_UNSAFE_DETERMINISTIC_MODE) static int hwrand(uint8_t *buf, const size_t len) { if (!have_rdrand()) { return 0; } const size_t len_multiple8 = len & ~7; if (!CRYPTO_rdrand_multiple8_buf(buf, len_multiple8)) { return 0; } const size_t remainder = len - len_multiple8; if (remainder != 0) { assert(remainder < 8); uint8_t rand_buf[8]; if (!CRYPTO_rdrand(rand_buf)) { return 0; } OPENSSL_memcpy(buf + len_multiple8, rand_buf, remainder); } #if defined(BORINGSSL_FIPS_BREAK_CRNG) // This breaks the "continuous random number generator test" defined in FIPS // 140-2, section 4.9.2, and implemented in rand_get_seed(). OPENSSL_memset(buf, 0, len); #endif return 1; } #else static int hwrand(uint8_t *buf, size_t len) { return 0; } #endif #if defined(BORINGSSL_FIPS) static void rand_get_seed(struct rand_thread_state *state, uint8_t seed[CTR_DRBG_ENTROPY_LEN]) { if (!state->last_block_valid) { if (!hwrand(state->last_block, sizeof(state->last_block))) { CRYPTO_sysrand(state->last_block, sizeof(state->last_block)); } state->last_block_valid = 1; } // We overread from /dev/urandom or RDRAND by a factor of 10 and XOR to // whiten. #define FIPS_OVERREAD 10 uint8_t entropy[CTR_DRBG_ENTROPY_LEN * FIPS_OVERREAD]; if (!hwrand(entropy, sizeof(entropy))) { CRYPTO_sysrand(entropy, sizeof(entropy)); } // See FIPS 140-2, section 4.9.2. This is the “continuous random number // generator test” which causes the program to randomly abort. Hopefully the // rate of failure is small enough not to be a problem in practice. if (CRYPTO_memcmp(state->last_block, entropy, CRNGT_BLOCK_SIZE) == 0) { fprintf(stderr, "CRNGT failed.\n"); BORINGSSL_FIPS_abort(); } for (size_t i = CRNGT_BLOCK_SIZE; i < sizeof(entropy); i += CRNGT_BLOCK_SIZE) { if (CRYPTO_memcmp(entropy + i - CRNGT_BLOCK_SIZE, entropy + i, CRNGT_BLOCK_SIZE) == 0) { fprintf(stderr, "CRNGT failed.\n"); BORINGSSL_FIPS_abort(); } } OPENSSL_memcpy(state->last_block, entropy + sizeof(entropy) - CRNGT_BLOCK_SIZE, CRNGT_BLOCK_SIZE); OPENSSL_memcpy(seed, entropy, CTR_DRBG_ENTROPY_LEN); for (size_t i = 1; i < FIPS_OVERREAD; i++) { for (size_t j = 0; j < CTR_DRBG_ENTROPY_LEN; j++) { seed[j] ^= entropy[CTR_DRBG_ENTROPY_LEN * i + j]; } } } #else static void rand_get_seed(struct rand_thread_state *state, uint8_t seed[CTR_DRBG_ENTROPY_LEN]) { // If not in FIPS mode, we don't overread from the system entropy source and // we don't depend only on the hardware RDRAND. CRYPTO_sysrand(seed, CTR_DRBG_ENTROPY_LEN); } #endif void RAND_bytes_with_additional_data(uint8_t *out, size_t out_len, const uint8_t user_additional_data[32]) { if (out_len == 0) { return; } // Additional data is mixed into every CTR-DRBG call to protect, as best we // can, against forks & VM clones. We do not over-read this information and // don't reseed with it so, from the point of view of FIPS, this doesn't // provide “prediction resistance”. But, in practice, it does. uint8_t additional_data[32]; if (!hwrand(additional_data, sizeof(additional_data))) { // Without a hardware RNG to save us from address-space duplication, the OS // entropy is used. This can be expensive (one read per |RAND_bytes| call) // and so can be disabled by applications that we have ensured don't fork // and aren't at risk of VM cloning. if (!rand_fork_unsafe_buffering_enabled()) { CRYPTO_sysrand(additional_data, sizeof(additional_data)); } else { OPENSSL_memset(additional_data, 0, sizeof(additional_data)); } } for (size_t i = 0; i < sizeof(additional_data); i++) { additional_data[i] ^= user_additional_data[i]; } struct rand_thread_state stack_state; 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)) { // If the system is out of memory, use an ephemeral state on the // stack. state = &stack_state; } state->last_block_valid = 0; uint8_t seed[CTR_DRBG_ENTROPY_LEN]; rand_get_seed(state, seed); if (!CTR_DRBG_init(&state->drbg, seed, NULL, 0)) { abort(); } state->calls = 0; #if defined(BORINGSSL_FIPS) if (state != &stack_state) { CRYPTO_STATIC_MUTEX_lock_write(thread_states_list_lock_bss_get()); struct rand_thread_state **states_list = thread_states_list_bss_get(); state->next = *states_list; if (state->next != NULL) { state->next->prev = state; } state->prev = NULL; *states_list = state; CRYPTO_STATIC_MUTEX_unlock_write(thread_states_list_lock_bss_get()); } #endif } if (state->calls >= kReseedInterval) { uint8_t seed[CTR_DRBG_ENTROPY_LEN]; rand_get_seed(state, seed); #if defined(BORINGSSL_FIPS) // Take a read lock around accesses to |state->drbg|. This is needed to // avoid returning bad entropy if we race with // |rand_thread_state_clear_all|. // // This lock must be taken after any calls to |CRYPTO_sysrand| to avoid a // bug on ppc64le. glibc may implement pthread locks by wrapping user code // in a hardware transaction, but, on some older versions of glibc and the // kernel, syscalls made with |syscall| did not abort the transaction. CRYPTO_STATIC_MUTEX_lock_read(thread_states_list_lock_bss_get()); #endif if (!CTR_DRBG_reseed(&state->drbg, seed, NULL, 0)) { abort(); } state->calls = 0; } else { #if defined(BORINGSSL_FIPS) CRYPTO_STATIC_MUTEX_lock_read(thread_states_list_lock_bss_get()); #endif } int first_call = 1; while (out_len > 0) { size_t todo = out_len; if (todo > CTR_DRBG_MAX_GENERATE_LENGTH) { todo = CTR_DRBG_MAX_GENERATE_LENGTH; } if (!CTR_DRBG_generate(&state->drbg, out, todo, additional_data, first_call ? sizeof(additional_data) : 0)) { abort(); } out += todo; out_len -= todo; // Though we only check before entering the loop, this cannot add enough to // overflow a |size_t|. state->calls++; first_call = 0; } if (state == &stack_state) { CTR_DRBG_clear(&state->drbg); } #if defined(BORINGSSL_FIPS) CRYPTO_STATIC_MUTEX_unlock_read(thread_states_list_lock_bss_get()); #endif } int RAND_bytes(uint8_t *out, size_t out_len) { static const uint8_t kZeroAdditionalData[32] = {0}; RAND_bytes_with_additional_data(out, out_len, kZeroAdditionalData); return 1; } int RAND_pseudo_bytes(uint8_t *buf, size_t len) { return RAND_bytes(buf, len); }