/src/openssl/crypto/evp/evp_rand.c

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/*
 * Copyright 2020-2023 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 <stdio.h>
#include <stdlib.h>
#include <openssl/evp.h>
#include <openssl/rand.h>
#include <openssl/core.h>
#include <openssl/core_names.h>
#include <openssl/crypto.h>
#include "internal/cryptlib.h"
#include "internal/numbers.h"
#include "internal/provider.h"
#include "internal/core.h"
#include "crypto/evp.h"
#include "evp_local.h"

struct evp_rand_st {
    OSSL_PROVIDER *prov;
    int name_id;
    char *type_name;
    const char *description;
    CRYPTO_REF_COUNT refcnt;

    const OSSL_DISPATCH *dispatch;
    OSSL_FUNC_rand_newctx_fn *newctx;
    OSSL_FUNC_rand_freectx_fn *freectx;
    OSSL_FUNC_rand_instantiate_fn *instantiate;
    OSSL_FUNC_rand_uninstantiate_fn *uninstantiate;
    OSSL_FUNC_rand_generate_fn *generate;
    OSSL_FUNC_rand_reseed_fn *reseed;
    OSSL_FUNC_rand_nonce_fn *nonce;
    OSSL_FUNC_rand_enable_locking_fn *enable_locking;
    OSSL_FUNC_rand_lock_fn *lock;
    OSSL_FUNC_rand_unlock_fn *unlock;
    OSSL_FUNC_rand_gettable_params_fn *gettable_params;
    OSSL_FUNC_rand_gettable_ctx_params_fn *gettable_ctx_params;
    OSSL_FUNC_rand_settable_ctx_params_fn *settable_ctx_params;
    OSSL_FUNC_rand_get_params_fn *get_params;
    OSSL_FUNC_rand_get_ctx_params_fn *get_ctx_params;
    OSSL_FUNC_rand_set_ctx_params_fn *set_ctx_params;
    OSSL_FUNC_rand_verify_zeroization_fn *verify_zeroization;
    OSSL_FUNC_rand_get_seed_fn *get_seed;
    OSSL_FUNC_rand_clear_seed_fn *clear_seed;
} /* EVP_RAND */ ;

static int evp_rand_up_ref(void *vrand)
{
    EVP_RAND *rand = (EVP_RAND *)vrand;
    int ref = 0;

    if (rand != NULL)
        return CRYPTO_UP_REF(&rand->refcnt, &ref);
    return 1;
}

static void evp_rand_free(void *vrand)
{
    EVP_RAND *rand = (EVP_RAND *)vrand;
    int ref = 0;

    if (rand == NULL)
        return;
    CRYPTO_DOWN_REF(&rand->refcnt, &ref);
    if (ref > 0)
        return;
    OPENSSL_free(rand->type_name);
    ossl_provider_free(rand->prov);
    CRYPTO_FREE_REF(&rand->refcnt);
    OPENSSL_free(rand);
}

static void *evp_rand_new(void)
{
    EVP_RAND *rand = OPENSSL_zalloc(sizeof(*rand));

    if (rand == NULL)
        return NULL;

    if (!CRYPTO_NEW_REF(&rand->refcnt, 1)) {
        OPENSSL_free(rand);
        return NULL;
    }
    return rand;
}

/* Enable locking of the underlying DRBG/RAND if available */
int EVP_RAND_enable_locking(EVP_RAND_CTX *rand)
{
    if (rand->meth->enable_locking != NULL)
        return rand->meth->enable_locking(rand->algctx);
    ERR_raise(ERR_LIB_EVP, EVP_R_LOCKING_NOT_SUPPORTED);
    return 0;
}

/* Lock the underlying DRBG/RAND if available */
static int evp_rand_lock(EVP_RAND_CTX *rand)
{
    if (rand->meth->lock != NULL)
        return rand->meth->lock(rand->algctx);
    return 1;
}

/* Unlock the underlying DRBG/RAND if available */
static void evp_rand_unlock(EVP_RAND_CTX *rand)
{
    if (rand->meth->unlock != NULL)
        rand->meth->unlock(rand->algctx);
}

static void *evp_rand_from_algorithm(int name_id,
                                     const OSSL_ALGORITHM *algodef,
                                     OSSL_PROVIDER *prov)
{
    const OSSL_DISPATCH *fns = algodef->implementation;
    EVP_RAND *rand = NULL;
    int fnrandcnt = 0, fnctxcnt = 0, fnlockcnt = 0, fnenablelockcnt = 0;
#ifdef FIPS_MODULE
    int fnzeroizecnt = 0;
#endif

    if ((rand = evp_rand_new()) == NULL) {
        ERR_raise(ERR_LIB_EVP, ERR_R_EVP_LIB);
        return NULL;
    }
    rand->name_id = name_id;
    if ((rand->type_name = ossl_algorithm_get1_first_name(algodef)) == NULL) {
        evp_rand_free(rand);
        return NULL;
    }
    rand->description = algodef->algorithm_description;
    rand->dispatch = fns;
    for (; fns->function_id != 0; fns++) {
        switch (fns->function_id) {
        case OSSL_FUNC_RAND_NEWCTX:
            if (rand->newctx != NULL)
                break;
            rand->newctx = OSSL_FUNC_rand_newctx(fns);
            fnctxcnt++;
            break;
        case OSSL_FUNC_RAND_FREECTX:
            if (rand->freectx != NULL)
                break;
            rand->freectx = OSSL_FUNC_rand_freectx(fns);
            fnctxcnt++;
            break;
        case OSSL_FUNC_RAND_INSTANTIATE:
            if (rand->instantiate != NULL)
                break;
            rand->instantiate = OSSL_FUNC_rand_instantiate(fns);
            fnrandcnt++;
            break;
        case OSSL_FUNC_RAND_UNINSTANTIATE:
             if (rand->uninstantiate != NULL)
                break;
            rand->uninstantiate = OSSL_FUNC_rand_uninstantiate(fns);
            fnrandcnt++;
            break;
        case OSSL_FUNC_RAND_GENERATE:
            if (rand->generate != NULL)
                break;
            rand->generate = OSSL_FUNC_rand_generate(fns);
            fnrandcnt++;
            break;
        case OSSL_FUNC_RAND_RESEED:
            if (rand->reseed != NULL)
                break;
            rand->reseed = OSSL_FUNC_rand_reseed(fns);
            break;
        case OSSL_FUNC_RAND_NONCE:
            if (rand->nonce != NULL)
                break;
            rand->nonce = OSSL_FUNC_rand_nonce(fns);
            break;
        case OSSL_FUNC_RAND_ENABLE_LOCKING:
            if (rand->enable_locking != NULL)
                break;
            rand->enable_locking = OSSL_FUNC_rand_enable_locking(fns);
            fnenablelockcnt++;
            break;
        case OSSL_FUNC_RAND_LOCK:
            if (rand->lock != NULL)
                break;
            rand->lock = OSSL_FUNC_rand_lock(fns);
            fnlockcnt++;
            break;
        case OSSL_FUNC_RAND_UNLOCK:
            if (rand->unlock != NULL)
                break;
            rand->unlock = OSSL_FUNC_rand_unlock(fns);
            fnlockcnt++;
            break;
        case OSSL_FUNC_RAND_GETTABLE_PARAMS:
            if (rand->gettable_params != NULL)
                break;
            rand->gettable_params =
                OSSL_FUNC_rand_gettable_params(fns);
            break;
        case OSSL_FUNC_RAND_GETTABLE_CTX_PARAMS:
            if (rand->gettable_ctx_params != NULL)
                break;
            rand->gettable_ctx_params =
                OSSL_FUNC_rand_gettable_ctx_params(fns);
            break;
        case OSSL_FUNC_RAND_SETTABLE_CTX_PARAMS:
            if (rand->settable_ctx_params != NULL)
                break;
            rand->settable_ctx_params =
                OSSL_FUNC_rand_settable_ctx_params(fns);
            break;
        case OSSL_FUNC_RAND_GET_PARAMS:
            if (rand->get_params != NULL)
                break;
            rand->get_params = OSSL_FUNC_rand_get_params(fns);
            break;
        case OSSL_FUNC_RAND_GET_CTX_PARAMS:
            if (rand->get_ctx_params != NULL)
                break;
            rand->get_ctx_params = OSSL_FUNC_rand_get_ctx_params(fns);
            fnctxcnt++;
            break;
        case OSSL_FUNC_RAND_SET_CTX_PARAMS:
            if (rand->set_ctx_params != NULL)
                break;
            rand->set_ctx_params = OSSL_FUNC_rand_set_ctx_params(fns);
            break;
        case OSSL_FUNC_RAND_VERIFY_ZEROIZATION:
            if (rand->verify_zeroization != NULL)
                break;
            rand->verify_zeroization = OSSL_FUNC_rand_verify_zeroization(fns);
#ifdef FIPS_MODULE
            fnzeroizecnt++;
#endif
            break;
        case OSSL_FUNC_RAND_GET_SEED:
            if (rand->get_seed != NULL)
                break;
            rand->get_seed = OSSL_FUNC_rand_get_seed(fns);
            break;
        case OSSL_FUNC_RAND_CLEAR_SEED:
            if (rand->clear_seed != NULL)
                break;
            rand->clear_seed = OSSL_FUNC_rand_clear_seed(fns);
            break;
        }
    }
    /*
     * In order to be a consistent set of functions we must have at least
     * a complete set of "rand" functions and a complete set of context
     * management functions.  In FIPS mode, we also require the zeroization
     * verification function.
     *
     * In addition, if locking can be enabled, we need a complete set of
     * locking functions.
     */
    if (fnrandcnt != 3
            || fnctxcnt != 3
            || (fnenablelockcnt != 0 && fnenablelockcnt != 1)
            || (fnlockcnt != 0 && fnlockcnt != 2)
#ifdef FIPS_MODULE
            || fnzeroizecnt != 1
#endif
       ) {
        evp_rand_free(rand);
        ERR_raise(ERR_LIB_EVP, EVP_R_INVALID_PROVIDER_FUNCTIONS);
        return NULL;
    }

    if (prov != NULL && !ossl_provider_up_ref(prov)) {
        evp_rand_free(rand);
        ERR_raise(ERR_LIB_EVP, ERR_R_INTERNAL_ERROR);
        return NULL;
    }
    rand->prov = prov;

    return rand;
}

EVP_RAND *EVP_RAND_fetch(OSSL_LIB_CTX *libctx, const char *algorithm,
                         const char *properties)
{
    return evp_generic_fetch(libctx, OSSL_OP_RAND, algorithm, properties,
                             evp_rand_from_algorithm, evp_rand_up_ref,
                             evp_rand_free);
}

int EVP_RAND_up_ref(EVP_RAND *rand)
{
    return evp_rand_up_ref(rand);
}

void EVP_RAND_free(EVP_RAND *rand)
{
    evp_rand_free(rand);
}

int evp_rand_get_number(const EVP_RAND *rand)
{
    return rand->name_id;
}

const char *EVP_RAND_get0_name(const EVP_RAND *rand)
{
    return rand->type_name;
}

const char *EVP_RAND_get0_description(const EVP_RAND *rand)
{
    return rand->description;
}

int EVP_RAND_is_a(const EVP_RAND *rand, const char *name)
{
    return rand != NULL && evp_is_a(rand->prov, rand->name_id, NULL, name);
}

const OSSL_PROVIDER *EVP_RAND_get0_provider(const EVP_RAND *rand)
{
    return rand->prov;
}

int EVP_RAND_get_params(EVP_RAND *rand, OSSL_PARAM params[])
{
    if (rand->get_params != NULL)
        return rand->get_params(params);
    return 1;
}

int EVP_RAND_CTX_up_ref(EVP_RAND_CTX *ctx)
{
    int ref = 0;

    return CRYPTO_UP_REF(&ctx->refcnt, &ref);
}

EVP_RAND_CTX *EVP_RAND_CTX_new(EVP_RAND *rand, EVP_RAND_CTX *parent)
{
    EVP_RAND_CTX *ctx;
    void *parent_ctx = NULL;
    const OSSL_DISPATCH *parent_dispatch = NULL;

    if (rand == NULL) {
        ERR_raise(ERR_LIB_EVP, EVP_R_INVALID_NULL_ALGORITHM);
        return NULL;
    }

    ctx = OPENSSL_zalloc(sizeof(*ctx));
    if (ctx == NULL)
        return NULL;
    if (!CRYPTO_NEW_REF(&ctx->refcnt, 1)) {
        OPENSSL_free(ctx);
        return NULL;
    }
    if (parent != NULL) {
        if (!EVP_RAND_CTX_up_ref(parent)) {
            ERR_raise(ERR_LIB_EVP, ERR_R_INTERNAL_ERROR);
            CRYPTO_FREE_REF(&ctx->refcnt);
            OPENSSL_free(ctx);
            return NULL;
        }
        parent_ctx = parent->algctx;
        parent_dispatch = parent->meth->dispatch;
    }
    if ((ctx->algctx = rand->newctx(ossl_provider_ctx(rand->prov), parent_ctx,
                                    parent_dispatch)) == NULL
            || !EVP_RAND_up_ref(rand)) {
        ERR_raise(ERR_LIB_EVP, ERR_R_EVP_LIB);
        rand->freectx(ctx->algctx);
        CRYPTO_FREE_REF(&ctx->refcnt);
        OPENSSL_free(ctx);
        EVP_RAND_CTX_free(parent);
        return NULL;
    }
    ctx->meth = rand;
    ctx->parent = parent;
    return ctx;
}

void EVP_RAND_CTX_free(EVP_RAND_CTX *ctx)
{
    int ref = 0;
    EVP_RAND_CTX *parent;

    if (ctx == NULL)
        return;

    CRYPTO_DOWN_REF(&ctx->refcnt, &ref);
    if (ref > 0)
        return;
    parent = ctx->parent;
    ctx->meth->freectx(ctx->algctx);
    ctx->algctx = NULL;
    EVP_RAND_free(ctx->meth);
    CRYPTO_FREE_REF(&ctx->refcnt);
    OPENSSL_free(ctx);
    EVP_RAND_CTX_free(parent);
}

EVP_RAND *EVP_RAND_CTX_get0_rand(EVP_RAND_CTX *ctx)
{
    return ctx->meth;
}

static int evp_rand_get_ctx_params_locked(EVP_RAND_CTX *ctx,
                                          OSSL_PARAM params[])
{
    return ctx->meth->get_ctx_params(ctx->algctx, params);
}

int EVP_RAND_CTX_get_params(EVP_RAND_CTX *ctx, OSSL_PARAM params[])
{
    int res;

    if (!evp_rand_lock(ctx))
        return 0;
    res = evp_rand_get_ctx_params_locked(ctx, params);
    evp_rand_unlock(ctx);
    return res;
}

static int evp_rand_set_ctx_params_locked(EVP_RAND_CTX *ctx,
                                          const OSSL_PARAM params[])
{
    if (ctx->meth->set_ctx_params != NULL)
        return ctx->meth->set_ctx_params(ctx->algctx, params);
    return 1;
}

int EVP_RAND_CTX_set_params(EVP_RAND_CTX *ctx, const OSSL_PARAM params[])
{
    int res;

    if (!evp_rand_lock(ctx))
        return 0;
    res = evp_rand_set_ctx_params_locked(ctx, params);
    evp_rand_unlock(ctx);
    return res;
}

const OSSL_PARAM *EVP_RAND_gettable_params(const EVP_RAND *rand)
{
    if (rand->gettable_params == NULL)
        return NULL;
    return rand->gettable_params(ossl_provider_ctx(EVP_RAND_get0_provider(rand)));
}

const OSSL_PARAM *EVP_RAND_gettable_ctx_params(const EVP_RAND *rand)
{
    void *provctx;

    if (rand->gettable_ctx_params == NULL)
        return NULL;
    provctx = ossl_provider_ctx(EVP_RAND_get0_provider(rand));
    return rand->gettable_ctx_params(NULL, provctx);
}

const OSSL_PARAM *EVP_RAND_settable_ctx_params(const EVP_RAND *rand)
{
    void *provctx;

    if (rand->settable_ctx_params == NULL)
        return NULL;
    provctx = ossl_provider_ctx(EVP_RAND_get0_provider(rand));
    return rand->settable_ctx_params(NULL, provctx);
}

const OSSL_PARAM *EVP_RAND_CTX_gettable_params(EVP_RAND_CTX *ctx)
{
    void *provctx;

    if (ctx->meth->gettable_ctx_params == NULL)
        return NULL;
    provctx = ossl_provider_ctx(EVP_RAND_get0_provider(ctx->meth));
    return ctx->meth->gettable_ctx_params(ctx->algctx, provctx);
}

const OSSL_PARAM *EVP_RAND_CTX_settable_params(EVP_RAND_CTX *ctx)
{
    void *provctx;

    if (ctx->meth->settable_ctx_params == NULL)
        return NULL;
    provctx = ossl_provider_ctx(EVP_RAND_get0_provider(ctx->meth));
    return ctx->meth->settable_ctx_params(ctx->algctx, provctx);
}

void EVP_RAND_do_all_provided(OSSL_LIB_CTX *libctx,
                              void (*fn)(EVP_RAND *rand, void *arg),
                              void *arg)
{
    evp_generic_do_all(libctx, OSSL_OP_RAND,
                       (void (*)(void *, void *))fn, arg,
                       evp_rand_from_algorithm, evp_rand_up_ref,
                       evp_rand_free);
}

int EVP_RAND_names_do_all(const EVP_RAND *rand,
                          void (*fn)(const char *name, void *data),
                          void *data)
{
    if (rand->prov != NULL)
        return evp_names_do_all(rand->prov, rand->name_id, fn, data);

    return 1;
}

static int evp_rand_instantiate_locked
    (EVP_RAND_CTX *ctx, unsigned int strength, int prediction_resistance,
     const unsigned char *pstr, size_t pstr_len, const OSSL_PARAM params[])
{
    return ctx->meth->instantiate(ctx->algctx, strength, prediction_resistance,
                                  pstr, pstr_len, params);
}

int EVP_RAND_instantiate(EVP_RAND_CTX *ctx, unsigned int strength,
                         int prediction_resistance,
                         const unsigned char *pstr, size_t pstr_len,
                         const OSSL_PARAM params[])
{
    int res;

    if (!evp_rand_lock(ctx))
        return 0;
    res = evp_rand_instantiate_locked(ctx, strength, prediction_resistance,
                                      pstr, pstr_len, params);
    evp_rand_unlock(ctx);
    return res;
}

static int evp_rand_uninstantiate_locked(EVP_RAND_CTX *ctx)
{
    return ctx->meth->uninstantiate(ctx->algctx);
}

int EVP_RAND_uninstantiate(EVP_RAND_CTX *ctx)
{
    int res;

    if (!evp_rand_lock(ctx))
        return 0;
    res = evp_rand_uninstantiate_locked(ctx);
    evp_rand_unlock(ctx);
    return res;
}

static int evp_rand_generate_locked(EVP_RAND_CTX *ctx, unsigned char *out,
                                    size_t outlen, unsigned int strength,
                                    int prediction_resistance,
                                    const unsigned char *addin,
                                    size_t addin_len)
{
    size_t chunk, max_request = 0;
    OSSL_PARAM params[2] = { OSSL_PARAM_END, OSSL_PARAM_END };

    params[0] = OSSL_PARAM_construct_size_t(OSSL_RAND_PARAM_MAX_REQUEST,
                                            &max_request);
    if (!evp_rand_get_ctx_params_locked(ctx, params)
            || max_request == 0) {
        ERR_raise(ERR_LIB_EVP, EVP_R_UNABLE_TO_GET_MAXIMUM_REQUEST_SIZE);
        return 0;
    }
    for (; outlen > 0; outlen -= chunk, out += chunk) {
        chunk = outlen > max_request ? max_request : outlen;
        if (!ctx->meth->generate(ctx->algctx, out, chunk, strength,
                                 prediction_resistance, addin, addin_len)) {
            ERR_raise(ERR_LIB_EVP, EVP_R_GENERATE_ERROR);
            return 0;
        }
        /*
         * Prediction resistance is only relevant the first time around,
         * subsequently, the DRBG has already been properly reseeded.
         */
        prediction_resistance = 0;
    }
    return 1;
}

int EVP_RAND_generate(EVP_RAND_CTX *ctx, unsigned char *out, size_t outlen,
                      unsigned int strength, int prediction_resistance,
                      const unsigned char *addin, size_t addin_len)
{
    int res;

    if (!evp_rand_lock(ctx))
        return 0;
    res = evp_rand_generate_locked(ctx, out, outlen, strength,
                                   prediction_resistance, addin, addin_len);
    evp_rand_unlock(ctx);
    return res;
}

static int evp_rand_reseed_locked(EVP_RAND_CTX *ctx, int prediction_resistance,
                                  const unsigned char *ent, size_t ent_len,
                                  const unsigned char *addin, size_t addin_len)
{
    if (ctx->meth->reseed != NULL)
        return ctx->meth->reseed(ctx->algctx, prediction_resistance,
                                 ent, ent_len, addin, addin_len);
    return 1;
}

int EVP_RAND_reseed(EVP_RAND_CTX *ctx, int prediction_resistance,
                    const unsigned char *ent, size_t ent_len,
                    const unsigned char *addin, size_t addin_len)
{
    int res;

    if (!evp_rand_lock(ctx))
        return 0;
    res = evp_rand_reseed_locked(ctx, prediction_resistance,
                                 ent, ent_len, addin, addin_len);
    evp_rand_unlock(ctx);
    return res;
}

static unsigned int evp_rand_strength_locked(EVP_RAND_CTX *ctx)
{
    OSSL_PARAM params[2] = { OSSL_PARAM_END, OSSL_PARAM_END };
    unsigned int strength = 0;

    params[0] = OSSL_PARAM_construct_uint(OSSL_RAND_PARAM_STRENGTH, &strength);
    if (!evp_rand_get_ctx_params_locked(ctx, params))
        return 0;
    return strength;
}

unsigned int EVP_RAND_get_strength(EVP_RAND_CTX *ctx)
{
    unsigned int res;

    if (!evp_rand_lock(ctx))
        return 0;
    res = evp_rand_strength_locked(ctx);
    evp_rand_unlock(ctx);
    return res;
}

static int evp_rand_nonce_locked(EVP_RAND_CTX *ctx, unsigned char *out,
                                 size_t outlen)
{
    unsigned int str = evp_rand_strength_locked(ctx);

    if (ctx->meth->nonce != NULL)
        return ctx->meth->nonce(ctx->algctx, out, str, outlen, outlen) > 0;
    return evp_rand_generate_locked(ctx, out, outlen, str, 0, NULL, 0);
}

int EVP_RAND_nonce(EVP_RAND_CTX *ctx, unsigned char *out, size_t outlen)
{
    int res;

    if (ctx == NULL || out == NULL || outlen == 0) {
        ERR_raise(ERR_LIB_EVP, ERR_R_PASSED_NULL_PARAMETER);
        return 0;
    }

    if (!evp_rand_lock(ctx))
        return 0;
    res = evp_rand_nonce_locked(ctx, out, outlen);
    evp_rand_unlock(ctx);
    return res;
}

int EVP_RAND_get_state(EVP_RAND_CTX *ctx)
{
    OSSL_PARAM params[2] = { OSSL_PARAM_END, OSSL_PARAM_END };
    int state;

    params[0] = OSSL_PARAM_construct_int(OSSL_RAND_PARAM_STATE, &state);
    if (!EVP_RAND_CTX_get_params(ctx, params))
        state = EVP_RAND_STATE_ERROR;
    return state;
}

static int evp_rand_verify_zeroization_locked(EVP_RAND_CTX *ctx)
{
    if (ctx->meth->verify_zeroization != NULL)
        return ctx->meth->verify_zeroization(ctx->algctx);
    return 0;
}

int EVP_RAND_verify_zeroization(EVP_RAND_CTX *ctx)
{
    int res;

    if (!evp_rand_lock(ctx))
        return 0;
    res = evp_rand_verify_zeroization_locked(ctx);
    evp_rand_unlock(ctx);
    return res;
}

int evp_rand_can_seed(EVP_RAND_CTX *ctx)
{
    return ctx->meth->get_seed != NULL;
}

static size_t evp_rand_get_seed_locked(EVP_RAND_CTX *ctx,
                                       unsigned char **buffer,
                                       int entropy,
                                       size_t min_len, size_t max_len,
                                       int prediction_resistance,
                                       const unsigned char *adin,
                                       size_t adin_len)
{
    if (ctx->meth->get_seed != NULL)
        return ctx->meth->get_seed(ctx->algctx, buffer,
                                   entropy, min_len, max_len,
                                   prediction_resistance,
                                   adin, adin_len);
    return 0;
}

size_t evp_rand_get_seed(EVP_RAND_CTX *ctx,
                         unsigned char **buffer,
                         int entropy, size_t min_len, size_t max_len,
                         int prediction_resistance,
                         const unsigned char *adin, size_t adin_len)
{
    int res;

    if (!evp_rand_lock(ctx))
        return 0;
    res = evp_rand_get_seed_locked(ctx,
                                   buffer,
                                   entropy, min_len, max_len,
                                   prediction_resistance,
                                   adin, adin_len);
    evp_rand_unlock(ctx);
    return res;
}

static void evp_rand_clear_seed_locked(EVP_RAND_CTX *ctx,
                                       unsigned char *buffer, size_t b_len)
{
    if (ctx->meth->clear_seed != NULL)
        ctx->meth->clear_seed(ctx->algctx, buffer, b_len);
}

void evp_rand_clear_seed(EVP_RAND_CTX *ctx,
                         unsigned char *buffer, size_t b_len)
{
    if (!evp_rand_lock(ctx))
        return;
    evp_rand_clear_seed_locked(ctx, buffer, b_len);
    evp_rand_unlock(ctx);
}

Coverage Report

Created: 2025-06-13 06:57

Line	Count	Source (jump to first uncovered line)
1		/*
2		* Copyright 2020-2023 The OpenSSL Project Authors. All Rights Reserved.
3		*
4		* Licensed under the Apache License 2.0 (the "License"). You may not use
5		* this file except in compliance with the License. You can obtain a copy
6		* in the file LICENSE in the source distribution or at
7		* https://www.openssl.org/source/license.html
8		*/
9
10		#include <stdio.h>
11		#include <stdlib.h>
12		#include <openssl/evp.h>
13		#include <openssl/rand.h>
14		#include <openssl/core.h>
15		#include <openssl/core_names.h>
16		#include <openssl/crypto.h>
17		#include "internal/cryptlib.h"
18		#include "internal/numbers.h"
19		#include "internal/provider.h"
20		#include "internal/core.h"
21		#include "crypto/evp.h"
22		#include "evp_local.h"
23
24		struct evp_rand_st {
25		OSSL_PROVIDER *prov;
26		int name_id;
27		char *type_name;
28		const char *description;
29		CRYPTO_REF_COUNT refcnt;
30
31		const OSSL_DISPATCH *dispatch;
32		OSSL_FUNC_rand_newctx_fn *newctx;
33		OSSL_FUNC_rand_freectx_fn *freectx;
34		OSSL_FUNC_rand_instantiate_fn *instantiate;
35		OSSL_FUNC_rand_uninstantiate_fn *uninstantiate;
36		OSSL_FUNC_rand_generate_fn *generate;
37		OSSL_FUNC_rand_reseed_fn *reseed;
38		OSSL_FUNC_rand_nonce_fn *nonce;
39		OSSL_FUNC_rand_enable_locking_fn *enable_locking;
40		OSSL_FUNC_rand_lock_fn *lock;
41		OSSL_FUNC_rand_unlock_fn *unlock;
42		OSSL_FUNC_rand_gettable_params_fn *gettable_params;
43		OSSL_FUNC_rand_gettable_ctx_params_fn *gettable_ctx_params;
44		OSSL_FUNC_rand_settable_ctx_params_fn *settable_ctx_params;
45		OSSL_FUNC_rand_get_params_fn *get_params;
46		OSSL_FUNC_rand_get_ctx_params_fn *get_ctx_params;
47		OSSL_FUNC_rand_set_ctx_params_fn *set_ctx_params;
48		OSSL_FUNC_rand_verify_zeroization_fn *verify_zeroization;
49		OSSL_FUNC_rand_get_seed_fn *get_seed;
50		OSSL_FUNC_rand_clear_seed_fn *clear_seed;
51		} /* EVP_RAND */ ;
52
53		static int evp_rand_up_ref(void *vrand)
54	14	{
55	14	EVP_RAND rand = (EVP_RAND )vrand;
56	14	int ref = 0;
57
58	14	if (rand != NULL)
59	14	return CRYPTO_UP_REF(&rand->refcnt, &ref);
60	0	return 1;
61	14	}
62
63		static void evp_rand_free(void *vrand)
64	20	{
65	20	EVP_RAND rand = (EVP_RAND )vrand;
66	20	int ref = 0;
67
68	20	if (rand == NULL)
69	0	return;
70	20	CRYPTO_DOWN_REF(&rand->refcnt, &ref);
71	20	if (ref > 0)
72	14	return;
73	6	OPENSSL_free(rand->type_name);
74	6	ossl_provider_free(rand->prov);
75	6	CRYPTO_FREE_REF(&rand->refcnt);
76	6	OPENSSL_free(rand);
77	6	}
78
79		static void *evp_rand_new(void)
80	6	{
81	6	EVP_RAND rand = OPENSSL_zalloc(sizeof(rand));
82
83	6	if (rand == NULL)
84	0	return NULL;
85
86	6	if (!CRYPTO_NEW_REF(&rand->refcnt, 1)) {
87	0	OPENSSL_free(rand);
88	0	return NULL;
89	0	}
90	6	return rand;
91	6	}
92
93		/* Enable locking of the underlying DRBG/RAND if available */
94		int EVP_RAND_enable_locking(EVP_RAND_CTX *rand)
95	1	{
96	1	if (rand->meth->enable_locking != NULL)
97	1	return rand->meth->enable_locking(rand->algctx);
98	1	ERR_raise(ERR_LIB_EVP, EVP_R_LOCKING_NOT_SUPPORTED);
99	0	return 0;
100	1	}
101
102		/* Lock the underlying DRBG/RAND if available */
103		static int evp_rand_lock(EVP_RAND_CTX *rand)
104	37.7k	{
105	37.7k	if (rand->meth->lock != NULL)
106	1	return rand->meth->lock(rand->algctx);
107	37.7k	return 1;
108	37.7k	}
109
110		/* Unlock the underlying DRBG/RAND if available */
111		static void evp_rand_unlock(EVP_RAND_CTX *rand)
112	37.7k	{
113	37.7k	if (rand->meth->unlock != NULL)
114	1	rand->meth->unlock(rand->algctx);
115	37.7k	}
116
117		static void *evp_rand_from_algorithm(int name_id,
118		const OSSL_ALGORITHM *algodef,
119		OSSL_PROVIDER *prov)
120	6	{
121	6	const OSSL_DISPATCH *fns = algodef->implementation;
122	6	EVP_RAND *rand = NULL;
123	6	int fnrandcnt = 0, fnctxcnt = 0, fnlockcnt = 0, fnenablelockcnt = 0;
124		#ifdef FIPS_MODULE
125		int fnzeroizecnt = 0;
126		#endif
127
128	6	if ((rand = evp_rand_new()) == NULL) {
129	0	ERR_raise(ERR_LIB_EVP, ERR_R_EVP_LIB);
130	0	return NULL;
131	0	}
132	6	rand->name_id = name_id;
133	6	if ((rand->type_name = ossl_algorithm_get1_first_name(algodef)) == NULL) {
134	0	evp_rand_free(rand);
135	0	return NULL;
136	0	}
137	6	rand->description = algodef->algorithm_description;
138	6	rand->dispatch = fns;
139	92	for (; fns->function_id != 0; fns++) {
140	86	switch (fns->function_id) {
141	6	case OSSL_FUNC_RAND_NEWCTX:
142	6	if (rand->newctx != NULL)
143	0	break;
144	6	rand->newctx = OSSL_FUNC_rand_newctx(fns);
145	6	fnctxcnt++;
146	6	break;
147	6	case OSSL_FUNC_RAND_FREECTX:
148	6	if (rand->freectx != NULL)
149	0	break;
150	6	rand->freectx = OSSL_FUNC_rand_freectx(fns);
151	6	fnctxcnt++;
152	6	break;
153	6	case OSSL_FUNC_RAND_INSTANTIATE:
154	6	if (rand->instantiate != NULL)
155	0	break;
156	6	rand->instantiate = OSSL_FUNC_rand_instantiate(fns);
157	6	fnrandcnt++;
158	6	break;
159	6	case OSSL_FUNC_RAND_UNINSTANTIATE:
160	6	if (rand->uninstantiate != NULL)
161	0	break;
162	6	rand->uninstantiate = OSSL_FUNC_rand_uninstantiate(fns);
163	6	fnrandcnt++;
164	6	break;
165	6	case OSSL_FUNC_RAND_GENERATE:
166	6	if (rand->generate != NULL)
167	0	break;
168	6	rand->generate = OSSL_FUNC_rand_generate(fns);
169	6	fnrandcnt++;
170	6	break;
171	5	case OSSL_FUNC_RAND_RESEED:
172	5	if (rand->reseed != NULL)
173	0	break;
174	5	rand->reseed = OSSL_FUNC_rand_reseed(fns);
175	5	break;
176	1	case OSSL_FUNC_RAND_NONCE:
177	1	if (rand->nonce != NULL)
178	0	break;
179	1	rand->nonce = OSSL_FUNC_rand_nonce(fns);
180	1	break;
181	6	case OSSL_FUNC_RAND_ENABLE_LOCKING:
182	6	if (rand->enable_locking != NULL)
183	0	break;
184	6	rand->enable_locking = OSSL_FUNC_rand_enable_locking(fns);
185	6	fnenablelockcnt++;
186	6	break;
187	5	case OSSL_FUNC_RAND_LOCK:
188	5	if (rand->lock != NULL)
189	0	break;
190	5	rand->lock = OSSL_FUNC_rand_lock(fns);
191	5	fnlockcnt++;
192	5	break;
193	5	case OSSL_FUNC_RAND_UNLOCK:
194	5	if (rand->unlock != NULL)
195	0	break;
196	5	rand->unlock = OSSL_FUNC_rand_unlock(fns);
197	5	fnlockcnt++;
198	5	break;
199	0	case OSSL_FUNC_RAND_GETTABLE_PARAMS:
200	0	if (rand->gettable_params != NULL)
201	0	break;
202	0	rand->gettable_params =
203	0	OSSL_FUNC_rand_gettable_params(fns);
204	0	break;
205	6	case OSSL_FUNC_RAND_GETTABLE_CTX_PARAMS:
206	6	if (rand->gettable_ctx_params != NULL)
207	0	break;
208	6	rand->gettable_ctx_params =
209	6	OSSL_FUNC_rand_gettable_ctx_params(fns);
210	6	break;
211	4	case OSSL_FUNC_RAND_SETTABLE_CTX_PARAMS:
212	4	if (rand->settable_ctx_params != NULL)
213	0	break;
214	4	rand->settable_ctx_params =
215	4	OSSL_FUNC_rand_settable_ctx_params(fns);
216	4	break;
217	0	case OSSL_FUNC_RAND_GET_PARAMS:
218	0	if (rand->get_params != NULL)
219	0	break;
220	0	rand->get_params = OSSL_FUNC_rand_get_params(fns);
221	0	break;
222	6	case OSSL_FUNC_RAND_GET_CTX_PARAMS:
223	6	if (rand->get_ctx_params != NULL)
224	0	break;
225	6	rand->get_ctx_params = OSSL_FUNC_rand_get_ctx_params(fns);
226	6	fnctxcnt++;
227	6	break;
228	4	case OSSL_FUNC_RAND_SET_CTX_PARAMS:
229	4	if (rand->set_ctx_params != NULL)
230	0	break;
231	4	rand->set_ctx_params = OSSL_FUNC_rand_set_ctx_params(fns);
232	4	break;
233	5	case OSSL_FUNC_RAND_VERIFY_ZEROIZATION:
234	5	if (rand->verify_zeroization != NULL)
235	0	break;
236	5	rand->verify_zeroization = OSSL_FUNC_rand_verify_zeroization(fns);
237		#ifdef FIPS_MODULE
238		fnzeroizecnt++;
239		#endif
240	5	break;
241	5	case OSSL_FUNC_RAND_GET_SEED:
242	5	if (rand->get_seed != NULL)
243	0	break;
244	5	rand->get_seed = OSSL_FUNC_rand_get_seed(fns);
245	5	break;
246	4	case OSSL_FUNC_RAND_CLEAR_SEED:
247	4	if (rand->clear_seed != NULL)
248	0	break;
249	4	rand->clear_seed = OSSL_FUNC_rand_clear_seed(fns);
250	4	break;
251	86	}
252	86	}
253		/*
254		* In order to be a consistent set of functions we must have at least
255		* a complete set of "rand" functions and a complete set of context
256		* management functions. In FIPS mode, we also require the zeroization
257		* verification function.
258		*
259		* In addition, if locking can be enabled, we need a complete set of
260		* locking functions.
261		*/
262	6	if (fnrandcnt != 3
263	6	\|\| fnctxcnt != 3
264	6	\|\| (fnenablelockcnt != 0 && fnenablelockcnt != 1)
265	6	\|\| (fnlockcnt != 0 && fnlockcnt != 2)
266		#ifdef FIPS_MODULE
267		\|\| fnzeroizecnt != 1
268		#endif
269	6	) {
270	0	evp_rand_free(rand);
271	0	ERR_raise(ERR_LIB_EVP, EVP_R_INVALID_PROVIDER_FUNCTIONS);
272	0	return NULL;
273	0	}
274
275	6	if (prov != NULL && !ossl_provider_up_ref(prov)) {
276	0	evp_rand_free(rand);
277	0	ERR_raise(ERR_LIB_EVP, ERR_R_INTERNAL_ERROR);
278	0	return NULL;
279	0	}
280	6	rand->prov = prov;
281
282	6	return rand;
283	6	}
284
285		EVP_RAND EVP_RAND_fetch(OSSL_LIB_CTX libctx, const char *algorithm,
286		const char *properties)
287	3	{
288	3	return evp_generic_fetch(libctx, OSSL_OP_RAND, algorithm, properties,
289	3	evp_rand_from_algorithm, evp_rand_up_ref,
290	3	evp_rand_free);
291	3	}
292
293		int EVP_RAND_up_ref(EVP_RAND *rand)
294	3	{
295	3	return evp_rand_up_ref(rand);
296	3	}
297
298		void EVP_RAND_free(EVP_RAND *rand)
299	6	{
300	6	evp_rand_free(rand);
301	6	}
302
303		int evp_rand_get_number(const EVP_RAND *rand)
304	0	{
305	0	return rand->name_id;
306	0	}
307
308		const char EVP_RAND_get0_name(const EVP_RAND rand)
309	0	{
310	0	return rand->type_name;
311	0	}
312
313		const char EVP_RAND_get0_description(const EVP_RAND rand)
314	0	{
315	0	return rand->description;
316	0	}
317
318		int EVP_RAND_is_a(const EVP_RAND rand, const char name)
319	0	{
320	0	return rand != NULL && evp_is_a(rand->prov, rand->name_id, NULL, name);
321	0	}
322
323		const OSSL_PROVIDER EVP_RAND_get0_provider(const EVP_RAND rand)
324	2	{
325	2	return rand->prov;
326	2	}
327
328		int EVP_RAND_get_params(EVP_RAND *rand, OSSL_PARAM params[])
329	0	{
330	0	if (rand->get_params != NULL)
331	0	return rand->get_params(params);
332	0	return 1;
333	0	}
334
335		int EVP_RAND_CTX_up_ref(EVP_RAND_CTX *ctx)
336	2	{
337	2	int ref = 0;
338
339	2	return CRYPTO_UP_REF(&ctx->refcnt, &ref);
340	2	}
341
342		EVP_RAND_CTX EVP_RAND_CTX_new(EVP_RAND rand, EVP_RAND_CTX *parent)
343	3	{
344	3	EVP_RAND_CTX *ctx;
345	3	void *parent_ctx = NULL;
346	3	const OSSL_DISPATCH *parent_dispatch = NULL;
347
348	3	if (rand == NULL) {
349	0	ERR_raise(ERR_LIB_EVP, EVP_R_INVALID_NULL_ALGORITHM);
350	0	return NULL;
351	0	}
352
353	3	ctx = OPENSSL_zalloc(sizeof(*ctx));
354	3	if (ctx == NULL)
355	0	return NULL;
356	3	if (!CRYPTO_NEW_REF(&ctx->refcnt, 1)) {
357	0	OPENSSL_free(ctx);
358	0	return NULL;
359	0	}
360	3	if (parent != NULL) {
361	2	if (!EVP_RAND_CTX_up_ref(parent)) {
362	0	ERR_raise(ERR_LIB_EVP, ERR_R_INTERNAL_ERROR);
363	0	CRYPTO_FREE_REF(&ctx->refcnt);
364	0	OPENSSL_free(ctx);
365	0	return NULL;
366	0	}
367	2	parent_ctx = parent->algctx;
368	2	parent_dispatch = parent->meth->dispatch;
369	2	}
370	3	if ((ctx->algctx = rand->newctx(ossl_provider_ctx(rand->prov), parent_ctx,
371	3	parent_dispatch)) == NULL
372	3	\|\| !EVP_RAND_up_ref(rand)) {
373	0	ERR_raise(ERR_LIB_EVP, ERR_R_EVP_LIB);
374	0	rand->freectx(ctx->algctx);
375	0	CRYPTO_FREE_REF(&ctx->refcnt);
376	0	OPENSSL_free(ctx);
377	0	EVP_RAND_CTX_free(parent);
378	0	return NULL;
379	0	}
380	3	ctx->meth = rand;
381	3	ctx->parent = parent;
382	3	return ctx;
383	3	}
384
385		void EVP_RAND_CTX_free(EVP_RAND_CTX *ctx)
386	9	{
387	9	int ref = 0;
388	9	EVP_RAND_CTX *parent;
389
390	9	if (ctx == NULL)
391	4	return;
392
393	5	CRYPTO_DOWN_REF(&ctx->refcnt, &ref);
394	5	if (ref > 0)
395	2	return;
396	3	parent = ctx->parent;
397	3	ctx->meth->freectx(ctx->algctx);
398	3	ctx->algctx = NULL;
399	3	EVP_RAND_free(ctx->meth);
400	3	CRYPTO_FREE_REF(&ctx->refcnt);
401	3	OPENSSL_free(ctx);
402	3	EVP_RAND_CTX_free(parent);
403	3	}
404
405		EVP_RAND EVP_RAND_CTX_get0_rand(EVP_RAND_CTX ctx)
406	0	{
407	0	return ctx->meth;
408	0	}
409
410		static int evp_rand_get_ctx_params_locked(EVP_RAND_CTX *ctx,
411		OSSL_PARAM params[])
412	37.7k	{
413	37.7k	return ctx->meth->get_ctx_params(ctx->algctx, params);
414	37.7k	}
415
416		int EVP_RAND_CTX_get_params(EVP_RAND_CTX *ctx, OSSL_PARAM params[])
417	0	{
418	0	int res;
419
420	0	if (!evp_rand_lock(ctx))
421	0	return 0;
422	0	res = evp_rand_get_ctx_params_locked(ctx, params);
423	0	evp_rand_unlock(ctx);
424	0	return res;
425	0	}
426
427		static int evp_rand_set_ctx_params_locked(EVP_RAND_CTX *ctx,
428		const OSSL_PARAM params[])
429	0	{
430	0	if (ctx->meth->set_ctx_params != NULL)
431	0	return ctx->meth->set_ctx_params(ctx->algctx, params);
432	0	return 1;
433	0	}
434
435		int EVP_RAND_CTX_set_params(EVP_RAND_CTX *ctx, const OSSL_PARAM params[])
436	0	{
437	0	int res;
438
439	0	if (!evp_rand_lock(ctx))
440	0	return 0;
441	0	res = evp_rand_set_ctx_params_locked(ctx, params);
442	0	evp_rand_unlock(ctx);
443	0	return res;
444	0	}
445
446		const OSSL_PARAM EVP_RAND_gettable_params(const EVP_RAND rand)
447	0	{
448	0	if (rand->gettable_params == NULL)
449	0	return NULL;
450	0	return rand->gettable_params(ossl_provider_ctx(EVP_RAND_get0_provider(rand)));
451	0	}
452
453		const OSSL_PARAM EVP_RAND_gettable_ctx_params(const EVP_RAND rand)
454	0	{
455	0	void *provctx;
456
457	0	if (rand->gettable_ctx_params == NULL)
458	0	return NULL;
459	0	provctx = ossl_provider_ctx(EVP_RAND_get0_provider(rand));
460	0	return rand->gettable_ctx_params(NULL, provctx);
461	0	}
462
463		const OSSL_PARAM EVP_RAND_settable_ctx_params(const EVP_RAND rand)
464	0	{
465	0	void *provctx;
466
467	0	if (rand->settable_ctx_params == NULL)
468	0	return NULL;
469	0	provctx = ossl_provider_ctx(EVP_RAND_get0_provider(rand));
470	0	return rand->settable_ctx_params(NULL, provctx);
471	0	}
472
473		const OSSL_PARAM EVP_RAND_CTX_gettable_params(EVP_RAND_CTX ctx)
474	0	{
475	0	void *provctx;
476
477	0	if (ctx->meth->gettable_ctx_params == NULL)
478	0	return NULL;
479	0	provctx = ossl_provider_ctx(EVP_RAND_get0_provider(ctx->meth));
480	0	return ctx->meth->gettable_ctx_params(ctx->algctx, provctx);
481	0	}
482
483		const OSSL_PARAM EVP_RAND_CTX_settable_params(EVP_RAND_CTX ctx)
484	2	{
485	2	void *provctx;
486
487	2	if (ctx->meth->settable_ctx_params == NULL)
488	2	return NULL;
489	0	provctx = ossl_provider_ctx(EVP_RAND_get0_provider(ctx->meth));
490	0	return ctx->meth->settable_ctx_params(ctx->algctx, provctx);
491	2	}
492
493		void EVP_RAND_do_all_provided(OSSL_LIB_CTX *libctx,
494		void (fn)(EVP_RAND rand, void *arg),
495		void *arg)
496	0	{
497	0	evp_generic_do_all(libctx, OSSL_OP_RAND,
498	0	(void ()(void , void *))fn, arg,
499	0	evp_rand_from_algorithm, evp_rand_up_ref,
500	0	evp_rand_free);
501	0	}
502
503		int EVP_RAND_names_do_all(const EVP_RAND *rand,
504		void (fn)(const char name, void *data),
505		void *data)
506	0	{
507	0	if (rand->prov != NULL)
508	0	return evp_names_do_all(rand->prov, rand->name_id, fn, data);
509
510	0	return 1;
511	0	}
512
513		static int evp_rand_instantiate_locked
514		(EVP_RAND_CTX *ctx, unsigned int strength, int prediction_resistance,
515		const unsigned char *pstr, size_t pstr_len, const OSSL_PARAM params[])
516	3	{
517	3	return ctx->meth->instantiate(ctx->algctx, strength, prediction_resistance,
518	3	pstr, pstr_len, params);
519	3	}
520
521		int EVP_RAND_instantiate(EVP_RAND_CTX *ctx, unsigned int strength,
522		int prediction_resistance,
523		const unsigned char *pstr, size_t pstr_len,
524		const OSSL_PARAM params[])
525	3	{
526	3	int res;
527
528	3	if (!evp_rand_lock(ctx))
529	0	return 0;
530	3	res = evp_rand_instantiate_locked(ctx, strength, prediction_resistance,
531	3	pstr, pstr_len, params);
532	3	evp_rand_unlock(ctx);
533	3	return res;
534	3	}
535
536		static int evp_rand_uninstantiate_locked(EVP_RAND_CTX *ctx)
537	0	{
538	0	return ctx->meth->uninstantiate(ctx->algctx);
539	0	}
540
541		int EVP_RAND_uninstantiate(EVP_RAND_CTX *ctx)
542	0	{
543	0	int res;
544
545	0	if (!evp_rand_lock(ctx))
546	0	return 0;
547	0	res = evp_rand_uninstantiate_locked(ctx);
548	0	evp_rand_unlock(ctx);
549	0	return res;
550	0	}
551
552		static int evp_rand_generate_locked(EVP_RAND_CTX ctx, unsigned char out,
553		size_t outlen, unsigned int strength,
554		int prediction_resistance,
555		const unsigned char *addin,
556		size_t addin_len)
557	37.7k	{
558	37.7k	size_t chunk, max_request = 0;
559	37.7k	OSSL_PARAM params[2] = { OSSL_PARAM_END, OSSL_PARAM_END };
560
561	37.7k	params[0] = OSSL_PARAM_construct_size_t(OSSL_RAND_PARAM_MAX_REQUEST,
562	37.7k	&max_request);
563	37.7k	if (!evp_rand_get_ctx_params_locked(ctx, params)
564	37.7k	\|\| max_request == 0) {
565	0	ERR_raise(ERR_LIB_EVP, EVP_R_UNABLE_TO_GET_MAXIMUM_REQUEST_SIZE);
566	0	return 0;
567	0	}
568	75.5k	for (; outlen > 0; outlen -= chunk, out += chunk) {
569	37.7k	chunk = outlen > max_request ? max_request : outlen;
570	37.7k	if (!ctx->meth->generate(ctx->algctx, out, chunk, strength,
571	37.7k	prediction_resistance, addin, addin_len)) {
572	0	ERR_raise(ERR_LIB_EVP, EVP_R_GENERATE_ERROR);
573	0	return 0;
574	0	}
575		/*
576		* Prediction resistance is only relevant the first time around,
577		* subsequently, the DRBG has already been properly reseeded.
578		*/
579	37.7k	prediction_resistance = 0;
580	37.7k	}
581	37.7k	return 1;
582	37.7k	}
583
584		int EVP_RAND_generate(EVP_RAND_CTX ctx, unsigned char out, size_t outlen,
585		unsigned int strength, int prediction_resistance,
586		const unsigned char *addin, size_t addin_len)
587	37.7k	{
588	37.7k	int res;
589
590	37.7k	if (!evp_rand_lock(ctx))
591	0	return 0;
592	37.7k	res = evp_rand_generate_locked(ctx, out, outlen, strength,
593	37.7k	prediction_resistance, addin, addin_len);
594	37.7k	evp_rand_unlock(ctx);
595	37.7k	return res;
596	37.7k	}
597
598		static int evp_rand_reseed_locked(EVP_RAND_CTX *ctx, int prediction_resistance,
599		const unsigned char *ent, size_t ent_len,
600		const unsigned char *addin, size_t addin_len)
601	0	{
602	0	if (ctx->meth->reseed != NULL)
603	0	return ctx->meth->reseed(ctx->algctx, prediction_resistance,
604	0	ent, ent_len, addin, addin_len);
605	0	return 1;
606	0	}
607
608		int EVP_RAND_reseed(EVP_RAND_CTX *ctx, int prediction_resistance,
609		const unsigned char *ent, size_t ent_len,
610		const unsigned char *addin, size_t addin_len)
611	0	{
612	0	int res;
613
614	0	if (!evp_rand_lock(ctx))
615	0	return 0;
616	0	res = evp_rand_reseed_locked(ctx, prediction_resistance,
617	0	ent, ent_len, addin, addin_len);
618	0	evp_rand_unlock(ctx);
619	0	return res;
620	0	}
621
622		static unsigned int evp_rand_strength_locked(EVP_RAND_CTX *ctx)
623	0	{
624	0	OSSL_PARAM params[2] = { OSSL_PARAM_END, OSSL_PARAM_END };
625	0	unsigned int strength = 0;
626
627	0	params[0] = OSSL_PARAM_construct_uint(OSSL_RAND_PARAM_STRENGTH, &strength);
628	0	if (!evp_rand_get_ctx_params_locked(ctx, params))
629	0	return 0;
630	0	return strength;
631	0	}
632
633		unsigned int EVP_RAND_get_strength(EVP_RAND_CTX *ctx)
634	0	{
635	0	unsigned int res;
636
637	0	if (!evp_rand_lock(ctx))
638	0	return 0;
639	0	res = evp_rand_strength_locked(ctx);
640	0	evp_rand_unlock(ctx);
641	0	return res;
642	0	}
643
644		static int evp_rand_nonce_locked(EVP_RAND_CTX ctx, unsigned char out,
645		size_t outlen)
646	0	{
647	0	unsigned int str = evp_rand_strength_locked(ctx);
648
649	0	if (ctx->meth->nonce != NULL)
650	0	return ctx->meth->nonce(ctx->algctx, out, str, outlen, outlen) > 0;
651	0	return evp_rand_generate_locked(ctx, out, outlen, str, 0, NULL, 0);
652	0	}
653
654		int EVP_RAND_nonce(EVP_RAND_CTX ctx, unsigned char out, size_t outlen)
655	0	{
656	0	int res;
657
658	0	if (ctx == NULL \|\| out == NULL \|\| outlen == 0) {
659	0	ERR_raise(ERR_LIB_EVP, ERR_R_PASSED_NULL_PARAMETER);
660	0	return 0;
661	0	}
662
663	0	if (!evp_rand_lock(ctx))
664	0	return 0;
665	0	res = evp_rand_nonce_locked(ctx, out, outlen);
666	0	evp_rand_unlock(ctx);
667	0	return res;
668	0	}
669
670		int EVP_RAND_get_state(EVP_RAND_CTX *ctx)
671	0	{
672	0	OSSL_PARAM params[2] = { OSSL_PARAM_END, OSSL_PARAM_END };
673	0	int state;
674
675	0	params[0] = OSSL_PARAM_construct_int(OSSL_RAND_PARAM_STATE, &state);
676	0	if (!EVP_RAND_CTX_get_params(ctx, params))
677	0	state = EVP_RAND_STATE_ERROR;
678	0	return state;
679	0	}
680
681		static int evp_rand_verify_zeroization_locked(EVP_RAND_CTX *ctx)
682	0	{
683	0	if (ctx->meth->verify_zeroization != NULL)
684	0	return ctx->meth->verify_zeroization(ctx->algctx);
685	0	return 0;
686	0	}
687
688		int EVP_RAND_verify_zeroization(EVP_RAND_CTX *ctx)
689	0	{
690	0	int res;
691
692	0	if (!evp_rand_lock(ctx))
693	0	return 0;
694	0	res = evp_rand_verify_zeroization_locked(ctx);
695	0	evp_rand_unlock(ctx);
696	0	return res;
697	0	}
698
699		int evp_rand_can_seed(EVP_RAND_CTX *ctx)
700	0	{
701	0	return ctx->meth->get_seed != NULL;
702	0	}
703
704		static size_t evp_rand_get_seed_locked(EVP_RAND_CTX *ctx,
705		unsigned char **buffer,
706		int entropy,
707		size_t min_len, size_t max_len,
708		int prediction_resistance,
709		const unsigned char *adin,
710		size_t adin_len)
711	0	{
712	0	if (ctx->meth->get_seed != NULL)
713	0	return ctx->meth->get_seed(ctx->algctx, buffer,
714	0	entropy, min_len, max_len,
715	0	prediction_resistance,
716	0	adin, adin_len);
717	0	return 0;
718	0	}
719
720		size_t evp_rand_get_seed(EVP_RAND_CTX *ctx,
721		unsigned char **buffer,
722		int entropy, size_t min_len, size_t max_len,
723		int prediction_resistance,
724		const unsigned char *adin, size_t adin_len)
725	0	{
726	0	int res;
727
728	0	if (!evp_rand_lock(ctx))
729	0	return 0;
730	0	res = evp_rand_get_seed_locked(ctx,
731	0	buffer,
732	0	entropy, min_len, max_len,
733	0	prediction_resistance,
734	0	adin, adin_len);
735	0	evp_rand_unlock(ctx);
736	0	return res;
737	0	}
738
739		static void evp_rand_clear_seed_locked(EVP_RAND_CTX *ctx,
740		unsigned char *buffer, size_t b_len)
741	0	{
742	0	if (ctx->meth->clear_seed != NULL)
743	0	ctx->meth->clear_seed(ctx->algctx, buffer, b_len);
744	0	}
745
746		void evp_rand_clear_seed(EVP_RAND_CTX *ctx,
747		unsigned char *buffer, size_t b_len)
748	0	{
749	0	if (!evp_rand_lock(ctx))
750	0	return;
751	0	evp_rand_clear_seed_locked(ctx, buffer, b_len);
752	0	evp_rand_unlock(ctx);
753	0	}