/* * Copyright 1995-2023 The OpenSSL Project Authors. All Rights Reserved. * * Licensed under the Apache License 2.0 (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 #include #include "internal/cryptlib.h" #include #include "crypto/rand.h" #include #include "internal/thread_once.h" #include "crypto/rand_pool.h" /* * Allocate memory and initialize a new random pool */ RAND_POOL *ossl_rand_pool_new(int entropy_requested, int secure, size_t min_len, size_t max_len) { RAND_POOL *pool = OPENSSL_zalloc(sizeof(*pool)); size_t min_alloc_size = RAND_POOL_MIN_ALLOCATION(secure); if (pool == NULL) return NULL; pool->min_len = min_len; pool->max_len = (max_len > RAND_POOL_MAX_LENGTH) ? RAND_POOL_MAX_LENGTH : max_len; pool->alloc_len = min_len < min_alloc_size ? min_alloc_size : min_len; if (pool->alloc_len > pool->max_len) pool->alloc_len = pool->max_len; if (secure) pool->buffer = OPENSSL_secure_zalloc(pool->alloc_len); else pool->buffer = OPENSSL_zalloc(pool->alloc_len); if (pool->buffer == NULL) goto err; pool->entropy_requested = entropy_requested; pool->secure = secure; return pool; err: OPENSSL_free(pool); return NULL; } /* * Attach new random pool to the given buffer * * This function is intended to be used only for feeding random data * provided by RAND_add() and RAND_seed() into the DRBG. */ RAND_POOL *ossl_rand_pool_attach(const unsigned char *buffer, size_t len, size_t entropy) { RAND_POOL *pool = OPENSSL_zalloc(sizeof(*pool)); if (pool == NULL) return NULL; /* * The const needs to be cast away, but attached buffers will not be * modified (in contrary to allocated buffers which are zeroed and * freed in the end). */ pool->buffer = (unsigned char *) buffer; pool->len = len; pool->attached = 1; pool->min_len = pool->max_len = pool->alloc_len = pool->len; pool->entropy = entropy; return pool; } /* * Free |pool|, securely erasing its buffer. */ void ossl_rand_pool_free(RAND_POOL *pool) { if (pool == NULL) return; /* * Although it would be advisable from a cryptographical viewpoint, * we are not allowed to clear attached buffers, since they are passed * to ossl_rand_pool_attach() as `const unsigned char*`. * (see corresponding comment in ossl_rand_pool_attach()). */ if (!pool->attached) { if (pool->secure) OPENSSL_secure_clear_free(pool->buffer, pool->alloc_len); else OPENSSL_clear_free(pool->buffer, pool->alloc_len); } OPENSSL_free(pool); } /* * Return the |pool|'s buffer to the caller (readonly). */ const unsigned char *ossl_rand_pool_buffer(RAND_POOL *pool) { return pool->buffer; } /* * Return the |pool|'s entropy to the caller. */ size_t ossl_rand_pool_entropy(RAND_POOL *pool) { return pool->entropy; } /* * Return the |pool|'s buffer length to the caller. */ size_t ossl_rand_pool_length(RAND_POOL *pool) { return pool->len; } /* * Detach the |pool| buffer and return it to the caller. * It's the responsibility of the caller to free the buffer * using OPENSSL_secure_clear_free() or to re-attach it * again to the pool using ossl_rand_pool_reattach(). */ unsigned char *ossl_rand_pool_detach(RAND_POOL *pool) { unsigned char *ret = pool->buffer; pool->buffer = NULL; pool->entropy = 0; return ret; } /* * Re-attach the |pool| buffer. It is only allowed to pass * the |buffer| which was previously detached from the same pool. */ void ossl_rand_pool_reattach(RAND_POOL *pool, unsigned char *buffer) { pool->buffer = buffer; OPENSSL_cleanse(pool->buffer, pool->len); pool->len = 0; } /* * If |entropy_factor| bits contain 1 bit of entropy, how many bytes does one * need to obtain at least |bits| bits of entropy? */ #define ENTROPY_TO_BYTES(bits, entropy_factor) \ (((bits) * (entropy_factor) + 7) / 8) /* * Checks whether the |pool|'s entropy is available to the caller. * This is the case when entropy count and buffer length are high enough. * Returns * * |entropy| if the entropy count and buffer size is large enough * 0 otherwise */ size_t ossl_rand_pool_entropy_available(RAND_POOL *pool) { if (pool->entropy < pool->entropy_requested) return 0; if (pool->len < pool->min_len) return 0; return pool->entropy; } /* * Returns the (remaining) amount of entropy needed to fill * the random pool. */ size_t ossl_rand_pool_entropy_needed(RAND_POOL *pool) { if (pool->entropy < pool->entropy_requested) return pool->entropy_requested - pool->entropy; return 0; } /* Increase the allocation size -- not usable for an attached pool */ static int rand_pool_grow(RAND_POOL *pool, size_t len) { if (len > pool->alloc_len - pool->len) { unsigned char *p; const size_t limit = pool->max_len / 2; size_t newlen = pool->alloc_len; if (pool->attached || len > pool->max_len - pool->len) { ERR_raise(ERR_LIB_RAND, ERR_R_INTERNAL_ERROR); return 0; } do newlen = newlen < limit ? newlen * 2 : pool->max_len; while (len > newlen - pool->len); if (pool->secure) p = OPENSSL_secure_zalloc(newlen); else p = OPENSSL_zalloc(newlen); if (p == NULL) return 0; memcpy(p, pool->buffer, pool->len); if (pool->secure) OPENSSL_secure_clear_free(pool->buffer, pool->alloc_len); else OPENSSL_clear_free(pool->buffer, pool->alloc_len); pool->buffer = p; pool->alloc_len = newlen; } return 1; } /* * Returns the number of bytes needed to fill the pool, assuming * the input has 1 / |entropy_factor| entropy bits per data bit. * In case of an error, 0 is returned. */ size_t ossl_rand_pool_bytes_needed(RAND_POOL *pool, unsigned int entropy_factor) { size_t bytes_needed; size_t entropy_needed = ossl_rand_pool_entropy_needed(pool); if (entropy_factor < 1) { ERR_raise(ERR_LIB_RAND, RAND_R_ARGUMENT_OUT_OF_RANGE); return 0; } bytes_needed = ENTROPY_TO_BYTES(entropy_needed, entropy_factor); if (bytes_needed > pool->max_len - pool->len) { /* not enough space left */ ERR_raise_data(ERR_LIB_RAND, RAND_R_RANDOM_POOL_OVERFLOW, "entropy_factor=%u, entropy_needed=%zu, bytes_needed=%zu," "pool->max_len=%zu, pool->len=%zu", entropy_factor, entropy_needed, bytes_needed, pool->max_len, pool->len); return 0; } if (pool->len < pool->min_len && bytes_needed < pool->min_len - pool->len) /* to meet the min_len requirement */ bytes_needed = pool->min_len - pool->len; /* * Make sure the buffer is large enough for the requested amount * of data. This guarantees that existing code patterns where * ossl_rand_pool_add_begin, ossl_rand_pool_add_end or ossl_rand_pool_add * are used to collect entropy data without any error handling * whatsoever, continue to be valid. * Furthermore if the allocation here fails once, make sure that * we don't fall back to a less secure or even blocking random source, * as that could happen by the existing code patterns. * This is not a concern for additional data, therefore that * is not needed if rand_pool_grow fails in other places. */ if (!rand_pool_grow(pool, bytes_needed)) { /* persistent error for this pool */ pool->max_len = pool->len = 0; return 0; } return bytes_needed; } /* Returns the remaining number of bytes available */ size_t ossl_rand_pool_bytes_remaining(RAND_POOL *pool) { return pool->max_len - pool->len; } /* * Add random bytes to the random pool. * * It is expected that the |buffer| contains |len| bytes of * random input which contains at least |entropy| bits of * randomness. * * Returns 1 if the added amount is adequate, otherwise 0 */ int ossl_rand_pool_add(RAND_POOL *pool, const unsigned char *buffer, size_t len, size_t entropy) { if (len > pool->max_len - pool->len) { ERR_raise(ERR_LIB_RAND, RAND_R_ENTROPY_INPUT_TOO_LONG); return 0; } if (pool->buffer == NULL) { ERR_raise(ERR_LIB_RAND, ERR_R_INTERNAL_ERROR); return 0; } if (len > 0) { /* * This is to protect us from accidentally passing the buffer * returned from ossl_rand_pool_add_begin. * The check for alloc_len makes sure we do not compare the * address of the end of the allocated memory to something * different, since that comparison would have an * indeterminate result. */ if (pool->alloc_len > pool->len && pool->buffer + pool->len == buffer) { ERR_raise(ERR_LIB_RAND, ERR_R_INTERNAL_ERROR); return 0; } /* * We have that only for cases when a pool is used to collect * additional data. * For entropy data, as long as the allocation request stays within * the limits given by ossl_rand_pool_bytes_needed this rand_pool_grow * below is guaranteed to succeed, thus no allocation happens. */ if (!rand_pool_grow(pool, len)) return 0; memcpy(pool->buffer + pool->len, buffer, len); pool->len += len; pool->entropy += entropy; } return 1; } /* * Start to add random bytes to the random pool in-place. * * Reserves the next |len| bytes for adding random bytes in-place * and returns a pointer to the buffer. * The caller is allowed to copy up to |len| bytes into the buffer. * If |len| == 0 this is considered a no-op and a NULL pointer * is returned without producing an error message. * * After updating the buffer, ossl_rand_pool_add_end() needs to be called * to finish the update operation (see next comment). */ unsigned char *ossl_rand_pool_add_begin(RAND_POOL *pool, size_t len) { if (len == 0) return NULL; if (len > pool->max_len - pool->len) { ERR_raise(ERR_LIB_RAND, RAND_R_RANDOM_POOL_OVERFLOW); return NULL; } if (pool->buffer == NULL) { ERR_raise(ERR_LIB_RAND, ERR_R_INTERNAL_ERROR); return NULL; } /* * As long as the allocation request stays within the limits given * by ossl_rand_pool_bytes_needed this rand_pool_grow below is guaranteed * to succeed, thus no allocation happens. * We have that only for cases when a pool is used to collect * additional data. Then the buffer might need to grow here, * and of course the caller is responsible to check the return * value of this function. */ if (!rand_pool_grow(pool, len)) return NULL; return pool->buffer + pool->len; } /* * Finish to add random bytes to the random pool in-place. * * Finishes an in-place update of the random pool started by * ossl_rand_pool_add_begin() (see previous comment). * It is expected that |len| bytes of random input have been added * to the buffer which contain at least |entropy| bits of randomness. * It is allowed to add less bytes than originally reserved. */ int ossl_rand_pool_add_end(RAND_POOL *pool, size_t len, size_t entropy) { if (len > pool->alloc_len - pool->len) { ERR_raise(ERR_LIB_RAND, RAND_R_RANDOM_POOL_OVERFLOW); return 0; } if (len > 0) { pool->len += len; pool->entropy += entropy; } return 1; }