/*

 * Copyright 2019-2023 The OpenSSL Project Authors. All Rights Reserved.

 * Copyright (c) 2019, Oracle and/or its affiliates.  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 <string.h>

#include <stdio.h>

#include <stdarg.h>

#include <openssl/crypto.h>

#include "internal/core.h"

#include "internal/property.h"

#include "internal/provider.h"

#include "internal/tsan_assist.h"

#include "crypto/ctype.h"

#include <openssl/lhash.h>

#include <openssl/rand.h>

#include "internal/thread_once.h"

#include "crypto/lhash.h"

#include "crypto/sparse_array.h"

#include "property_local.h"

#include "crypto/context.h"

/*

 * The number of elements in the query cache before we initiate a flush.

 * If reducing this, also ensure the stochastic test in test/property_test.c

 * isn't likely to fail.

 */

#define IMPL_CACHE_FLUSH_THRESHOLD  500

typedef struct {

    void *method;

    int (*up_ref)(void *);

    void (*free)(void *);

} METHOD;

typedef struct {

    const OSSL_PROVIDER *provider;

    OSSL_PROPERTY_LIST *properties;

    METHOD method;

} IMPLEMENTATION;

DEFINE_STACK_OF(IMPLEMENTATION)

typedef struct {

    const OSSL_PROVIDER *provider;

    const char *query;

    METHOD method;

    char body[1];

} QUERY;

DEFINE_LHASH_OF_EX(QUERY);

typedef struct {

    int nid;

    STACK_OF(IMPLEMENTATION) *impls;

    LHASH_OF(QUERY) *cache;

} ALGORITHM;

struct ossl_method_store_st {

    OSSL_LIB_CTX *ctx;

    SPARSE_ARRAY_OF(ALGORITHM) *algs;

    /*

     * Lock to protect the |algs| array from concurrent writing, when

     * individual implementations or queries are inserted.  This is used

     * by the appropriate functions here.

     */

    CRYPTO_RWLOCK *lock;

    /*

     * Lock to reserve the whole store.  This is used when fetching a set

     * of algorithms, via these functions, found in crypto/core_fetch.c:

     * ossl_method_construct_reserve_store()

     * ossl_method_construct_unreserve_store()

     */

    CRYPTO_RWLOCK *biglock;

    /* query cache specific values */

    /* Count of the query cache entries for all algs */

    size_t cache_nelem;

    /* Flag: 1 if query cache entries for all algs need flushing */

    int cache_need_flush;

};

typedef struct {

    LHASH_OF(QUERY) *cache;

    size_t nelem;

    uint32_t seed;

    unsigned char using_global_seed;

} IMPL_CACHE_FLUSH;

DEFINE_SPARSE_ARRAY_OF(ALGORITHM);

typedef struct ossl_global_properties_st {

    OSSL_PROPERTY_LIST *list;

#ifndef FIPS_MODULE

    unsigned int no_mirrored : 1;

#endif

} OSSL_GLOBAL_PROPERTIES;

static void ossl_method_cache_flush_alg(OSSL_METHOD_STORE *store,

                                        ALGORITHM *alg);

static void ossl_method_cache_flush(OSSL_METHOD_STORE *store, int nid);

/* Global properties are stored per library context */

void ossl_ctx_global_properties_free(void *vglobp)

{

    OSSL_GLOBAL_PROPERTIES *globp = vglobp;

    if (globp != NULL) {

        ossl_property_free(globp->list);

        OPENSSL_free(globp);

    }

}

void *ossl_ctx_global_properties_new(OSSL_LIB_CTX *ctx)

{

    return OPENSSL_zalloc(sizeof(OSSL_GLOBAL_PROPERTIES));

}

OSSL_PROPERTY_LIST **ossl_ctx_global_properties(OSSL_LIB_CTX *libctx,

                                                ossl_unused int loadconfig)

{

    OSSL_GLOBAL_PROPERTIES *globp;

#if !defined(FIPS_MODULE) && !defined(OPENSSL_NO_AUTOLOAD_CONFIG)

    if (loadconfig && !OPENSSL_init_crypto(OPENSSL_INIT_LOAD_CONFIG, NULL))

        return NULL;

#endif

    globp = ossl_lib_ctx_get_data(libctx, OSSL_LIB_CTX_GLOBAL_PROPERTIES);

    return globp != NULL ? &globp->list : NULL;

}

#ifndef FIPS_MODULE

int ossl_global_properties_no_mirrored(OSSL_LIB_CTX *libctx)

{

    OSSL_GLOBAL_PROPERTIES *globp

        = ossl_lib_ctx_get_data(libctx, OSSL_LIB_CTX_GLOBAL_PROPERTIES);

    return globp != NULL && globp->no_mirrored ? 1 : 0;

}

void ossl_global_properties_stop_mirroring(OSSL_LIB_CTX *libctx)

{

    OSSL_GLOBAL_PROPERTIES *globp

        = ossl_lib_ctx_get_data(libctx, OSSL_LIB_CTX_GLOBAL_PROPERTIES);

    if (globp != NULL)

        globp->no_mirrored = 1;

}

#endif

static int ossl_method_up_ref(METHOD *method)

{

    return (*method->up_ref)(method->method);

}

static void ossl_method_free(METHOD *method)

{

    (*method->free)(method->method);

}

static __owur int ossl_property_read_lock(OSSL_METHOD_STORE *p)

{

    return p != NULL ? CRYPTO_THREAD_read_lock(p->lock) : 0;

}

static __owur int ossl_property_write_lock(OSSL_METHOD_STORE *p)

{

    return p != NULL ? CRYPTO_THREAD_write_lock(p->lock) : 0;

}

static int ossl_property_unlock(OSSL_METHOD_STORE *p)

{

    return p != 0 ? CRYPTO_THREAD_unlock(p->lock) : 0;

}

static unsigned long query_hash(const QUERY *a)

{

    return OPENSSL_LH_strhash(a->query);

}

static int query_cmp(const QUERY *a, const QUERY *b)

{

    int res = strcmp(a->query, b->query);

    if (res == 0 && a->provider != NULL && b->provider != NULL)

        res = b->provider > a->provider ? 1

            : b->provider < a->provider ? -1

            : 0;

    return res;

}

static void impl_free(IMPLEMENTATION *impl)

{

    if (impl != NULL) {

        ossl_method_free(&impl->method);

        OPENSSL_free(impl);

    }

}

static void impl_cache_free(QUERY *elem)

{

    if (elem != NULL) {

        ossl_method_free(&elem->method);

        OPENSSL_free(elem);

    }

}

static void impl_cache_flush_alg(ossl_uintmax_t idx, ALGORITHM *alg)

{

    lh_QUERY_doall(alg->cache, &impl_cache_free);

    lh_QUERY_flush(alg->cache);

}

static void alg_cleanup(ossl_uintmax_t idx, ALGORITHM *a, void *arg)

{

    OSSL_METHOD_STORE *store = arg;

    if (a != NULL) {

        sk_IMPLEMENTATION_pop_free(a->impls, &impl_free);

        lh_QUERY_doall(a->cache, &impl_cache_free);

        lh_QUERY_free(a->cache);

        OPENSSL_free(a);

    }

    if (store != NULL)

        ossl_sa_ALGORITHM_set(store->algs, idx, NULL);

}

/*

 * The OSSL_LIB_CTX param here allows access to underlying property data needed

 * for computation

 */

OSSL_METHOD_STORE *ossl_method_store_new(OSSL_LIB_CTX *ctx)

{

    OSSL_METHOD_STORE *res;

    res = OPENSSL_zalloc(sizeof(*res));

    if (res != NULL) {

        res->ctx = ctx;

        if ((res->algs = ossl_sa_ALGORITHM_new()) == NULL

            || (res->lock = CRYPTO_THREAD_lock_new()) == NULL

            || (res->biglock = CRYPTO_THREAD_lock_new()) == NULL) {

            ossl_method_store_free(res);

            return NULL;

        }

    }

    return res;

}

void ossl_method_store_free(OSSL_METHOD_STORE *store)

{

    if (store != NULL) {

        if (store->algs != NULL)

            ossl_sa_ALGORITHM_doall_arg(store->algs, &alg_cleanup, store);

        ossl_sa_ALGORITHM_free(store->algs);

        CRYPTO_THREAD_lock_free(store->lock);

        CRYPTO_THREAD_lock_free(store->biglock);

        OPENSSL_free(store);

    }

}

int ossl_method_lock_store(OSSL_METHOD_STORE *store)

{

    return store != NULL ? CRYPTO_THREAD_write_lock(store->biglock) : 0;

}

int ossl_method_unlock_store(OSSL_METHOD_STORE *store)

{

    return store != NULL ? CRYPTO_THREAD_unlock(store->biglock) : 0;

}

static ALGORITHM *ossl_method_store_retrieve(OSSL_METHOD_STORE *store, int nid)

{

    return ossl_sa_ALGORITHM_get(store->algs, nid);

}

static int ossl_method_store_insert(OSSL_METHOD_STORE *store, ALGORITHM *alg)

{

    return ossl_sa_ALGORITHM_set(store->algs, alg->nid, alg);

}

int ossl_method_store_add(OSSL_METHOD_STORE *store, const OSSL_PROVIDER *prov,

                          int nid, const char *properties, void *method,

                          int (*method_up_ref)(void *),

                          void (*method_destruct)(void *))

{

    ALGORITHM *alg = NULL;

    IMPLEMENTATION *impl;

    int ret = 0;

    int i;

    if (nid <= 0 || method == NULL || store == NULL)

        return 0;

    if (properties == NULL)

        properties = "";

    if (!ossl_assert(prov != NULL))

        return 0;

    /* Create new entry */

    impl = OPENSSL_malloc(sizeof(*impl));

    if (impl == NULL)

        return 0;

    impl->method.method = method;

    impl->method.up_ref = method_up_ref;

    impl->method.free = method_destruct;

    if (!ossl_method_up_ref(&impl->method)) {

        OPENSSL_free(impl);

        return 0;

    }

    impl->provider = prov;

    /* Insert into the hash table if required */

    if (!ossl_property_write_lock(store)) {

        OPENSSL_free(impl);

        return 0;

    }

    ossl_method_cache_flush(store, nid);

    if ((impl->properties = ossl_prop_defn_get(store->ctx, properties)) == NULL) {

        impl->properties = ossl_parse_property(store->ctx, properties);

        if (impl->properties == NULL)

            goto err;

        if (!ossl_prop_defn_set(store->ctx, properties, &impl->properties)) {

            ossl_property_free(impl->properties);

            impl->properties = NULL;

            goto err;

        }

    }

    alg = ossl_method_store_retrieve(store, nid);

    if (alg == NULL) {

        if ((alg = OPENSSL_zalloc(sizeof(*alg))) == NULL

                || (alg->impls = sk_IMPLEMENTATION_new_null()) == NULL

                || (alg->cache = lh_QUERY_new(&query_hash, &query_cmp)) == NULL)

            goto err;

        alg->nid = nid;

        if (!ossl_method_store_insert(store, alg))

            goto err;

    }

    /* Push onto stack if there isn't one there already */

    for (i = 0; i < sk_IMPLEMENTATION_num(alg->impls); i++) {

        const IMPLEMENTATION *tmpimpl = sk_IMPLEMENTATION_value(alg->impls, i);

        if (tmpimpl->provider == impl->provider

            && tmpimpl->properties == impl->properties)

            break;

    }

    if (i == sk_IMPLEMENTATION_num(alg->impls)

        && sk_IMPLEMENTATION_push(alg->impls, impl))

        ret = 1;

    ossl_property_unlock(store);

    if (ret == 0)

        impl_free(impl);

    return ret;

err:

    ossl_property_unlock(store);

    alg_cleanup(0, alg, NULL);

    impl_free(impl);

    return 0;

}

int ossl_method_store_remove(OSSL_METHOD_STORE *store, int nid,

                             const void *method)

{

    ALGORITHM *alg = NULL;

    int i;

    if (nid <= 0 || method == NULL || store == NULL)

        return 0;

    if (!ossl_property_write_lock(store))

        return 0;

    ossl_method_cache_flush(store, nid);

    alg = ossl_method_store_retrieve(store, nid);

    if (alg == NULL) {

        ossl_property_unlock(store);

        return 0;

    }

    /*

     * A sorting find then a delete could be faster but these stacks should be

     * relatively small, so we avoid the overhead.  Sorting could also surprise

     * users when result orderings change (even though they are not guaranteed).

     */

    for (i = 0; i < sk_IMPLEMENTATION_num(alg->impls); i++) {

        IMPLEMENTATION *impl = sk_IMPLEMENTATION_value(alg->impls, i);

        if (impl->method.method == method) {

            impl_free(impl);

            (void)sk_IMPLEMENTATION_delete(alg->impls, i);

            ossl_property_unlock(store);

            return 1;

        }

    }

    ossl_property_unlock(store);

    return 0;

}

struct alg_cleanup_by_provider_data_st {

    OSSL_METHOD_STORE *store;

    const OSSL_PROVIDER *prov;

};

static void

alg_cleanup_by_provider(ossl_uintmax_t idx, ALGORITHM *alg, void *arg)

{

    struct alg_cleanup_by_provider_data_st *data = arg;

    int i, count;

    /*

     * We walk the stack backwards, to avoid having to deal with stack shifts

     * caused by deletion

     */

    for (count = 0, i = sk_IMPLEMENTATION_num(alg->impls); i-- > 0;) {

        IMPLEMENTATION *impl = sk_IMPLEMENTATION_value(alg->impls, i);

        if (impl->provider == data->prov) {

            impl_free(impl);

            (void)sk_IMPLEMENTATION_delete(alg->impls, i);

            count++;

        }

    }

    /*

     * If we removed any implementation, we also clear the whole associated

     * cache, 'cause that's the sensible thing to do.

     * There's no point flushing the cache entries where we didn't remove

     * any implementation, though.

     */

    if (count > 0)

        ossl_method_cache_flush_alg(data->store, alg);

}

int ossl_method_store_remove_all_provided(OSSL_METHOD_STORE *store,

                                          const OSSL_PROVIDER *prov)

{

    struct alg_cleanup_by_provider_data_st data;

    if (!ossl_property_write_lock(store))

        return 0;

    data.prov = prov;

    data.store = store;

    ossl_sa_ALGORITHM_doall_arg(store->algs, &alg_cleanup_by_provider, &data);

    ossl_property_unlock(store);

    return 1;

}

static void alg_do_one(ALGORITHM *alg, IMPLEMENTATION *impl,

                       void (*fn)(int id, void *method, void *fnarg),

                       void *fnarg)

{

    fn(alg->nid, impl->method.method, fnarg);

}

struct alg_do_each_data_st {

    void (*fn)(int id, void *method, void *fnarg);

    void *fnarg;

};

static void alg_do_each(ossl_uintmax_t idx, ALGORITHM *alg, void *arg)

{

    struct alg_do_each_data_st *data = arg;

    int i, end = sk_IMPLEMENTATION_num(alg->impls);

    for (i = 0; i < end; i++) {

        IMPLEMENTATION *impl = sk_IMPLEMENTATION_value(alg->impls, i);

        alg_do_one(alg, impl, data->fn, data->fnarg);

    }

}

void ossl_method_store_do_all(OSSL_METHOD_STORE *store,

                              void (*fn)(int id, void *method, void *fnarg),

                              void *fnarg)

{

    struct alg_do_each_data_st data;

    data.fn = fn;

    data.fnarg = fnarg;

    if (store != NULL)

        ossl_sa_ALGORITHM_doall_arg(store->algs, alg_do_each, &data);

}

int ossl_method_store_fetch(OSSL_METHOD_STORE *store,

                            int nid, const char *prop_query,

                            const OSSL_PROVIDER **prov_rw, void **method)

{

    OSSL_PROPERTY_LIST **plp;

    ALGORITHM *alg;

    IMPLEMENTATION *impl, *best_impl = NULL;

    OSSL_PROPERTY_LIST *pq = NULL, *p2 = NULL;

    const OSSL_PROVIDER *prov = prov_rw != NULL ? *prov_rw : NULL;

    int ret = 0;

    int j, best = -1, score, optional;

    if (nid <= 0 || method == NULL || store == NULL)

        return 0;

#if !defined(FIPS_MODULE) && !defined(OPENSSL_NO_AUTOLOAD_CONFIG)

    if (ossl_lib_ctx_is_default(store->ctx)

            && !OPENSSL_init_crypto(OPENSSL_INIT_LOAD_CONFIG, NULL))

        return 0;

#endif

    /* This only needs to be a read lock, because the query won't create anything */

    if (!ossl_property_read_lock(store))

        return 0;

    alg = ossl_method_store_retrieve(store, nid);

    if (alg == NULL) {

        ossl_property_unlock(store);

        return 0;

    }

    if (prop_query != NULL)

        p2 = pq = ossl_parse_query(store->ctx, prop_query, 0);

    plp = ossl_ctx_global_properties(store->ctx, 0);

    if (plp != NULL && *plp != NULL) {

        if (pq == NULL) {

            pq = *plp;

        } else {

            p2 = ossl_property_merge(pq, *plp);

            ossl_property_free(pq);

            if (p2 == NULL)

                goto fin;

            pq = p2;

        }

    }

    if (pq == NULL) {

        for (j = 0; j < sk_IMPLEMENTATION_num(alg->impls); j++) {

            if ((impl = sk_IMPLEMENTATION_value(alg->impls, j)) != NULL

                && (prov == NULL || impl->provider == prov)) {

                best_impl = impl;

                ret = 1;

                break;

            }

        }

        goto fin;

    }

    optional = ossl_property_has_optional(pq);

    for (j = 0; j < sk_IMPLEMENTATION_num(alg->impls); j++) {

        if ((impl = sk_IMPLEMENTATION_value(alg->impls, j)) != NULL

            && (prov == NULL || impl->provider == prov)) {

            score = ossl_property_match_count(pq, impl->properties);

            if (score > best) {

                best_impl = impl;

                best = score;

                ret = 1;

                if (!optional)

                    goto fin;

            }

        }

    }

fin:

    if (ret && ossl_method_up_ref(&best_impl->method)) {

        *method = best_impl->method.method;

        if (prov_rw != NULL)

            *prov_rw = best_impl->provider;

    } else {

        ret = 0;

    }

    ossl_property_unlock(store);

    ossl_property_free(p2);

    return ret;

}

static void ossl_method_cache_flush_alg(OSSL_METHOD_STORE *store,

                                        ALGORITHM *alg)

{

    store->cache_nelem -= lh_QUERY_num_items(alg->cache);

    impl_cache_flush_alg(0, alg);

}

static void ossl_method_cache_flush(OSSL_METHOD_STORE *store, int nid)

{

    ALGORITHM *alg = ossl_method_store_retrieve(store, nid);

    if (alg != NULL)

        ossl_method_cache_flush_alg(store, alg);

}

int ossl_method_store_cache_flush_all(OSSL_METHOD_STORE *store)

{

    if (!ossl_property_write_lock(store))

        return 0;

    ossl_sa_ALGORITHM_doall(store->algs, &impl_cache_flush_alg);

    store->cache_nelem = 0;

    ossl_property_unlock(store);

    return 1;

}

IMPLEMENT_LHASH_DOALL_ARG(QUERY, IMPL_CACHE_FLUSH);

/*

 * Flush an element from the query cache (perhaps).

 *

 * In order to avoid taking a write lock or using atomic operations

 * to keep accurate least recently used (LRU) or least frequently used

 * (LFU) information, the procedure used here is to stochastically

 * flush approximately half the cache.

 *

 * This procedure isn't ideal, LRU or LFU would be better.  However,

 * in normal operation, reaching a full cache would be unexpected.

 * It means that no steady state of algorithm queries has been reached.

 * That is, it is most likely an attack of some form.  A suboptimal clearance

 * strategy that doesn't degrade performance of the normal case is

 * preferable to a more refined approach that imposes a performance

 * impact.

 */

static void impl_cache_flush_cache(QUERY *c, IMPL_CACHE_FLUSH *state)

{

    uint32_t n;

    /*

     * Implement the 32 bit xorshift as suggested by George Marsaglia in:

     *      https://doi.org/10.18637/jss.v008.i14

     *

     * This is a very fast PRNG so there is no need to extract bits one at a

     * time and use the entire value each time.

     */

    n = state->seed;

    n ^= n << 13;

    n ^= n >> 17;

    n ^= n << 5;

    state->seed = n;

    if ((n & 1) != 0)

        impl_cache_free(lh_QUERY_delete(state->cache, c));

    else

        state->nelem++;

}

static void impl_cache_flush_one_alg(ossl_uintmax_t idx, ALGORITHM *alg,

                                     void *v)

{

    IMPL_CACHE_FLUSH *state = (IMPL_CACHE_FLUSH *)v;

    state->cache = alg->cache;

    lh_QUERY_doall_IMPL_CACHE_FLUSH(state->cache, &impl_cache_flush_cache,

                                    state);

}

static void ossl_method_cache_flush_some(OSSL_METHOD_STORE *store)

{

    IMPL_CACHE_FLUSH state;

    static TSAN_QUALIFIER uint32_t global_seed = 1;

    state.nelem = 0;

    state.using_global_seed = 0;

    if ((state.seed = OPENSSL_rdtsc()) == 0) {

        /* If there is no timer available, seed another way */

        state.using_global_seed = 1;

        state.seed = tsan_load(&global_seed);

    }

    store->cache_need_flush = 0;

    ossl_sa_ALGORITHM_doall_arg(store->algs, &impl_cache_flush_one_alg, &state);

    store->cache_nelem = state.nelem;

    /* Without a timer, update the global seed */

    if (state.using_global_seed)

        tsan_add(&global_seed, state.seed);

}

int ossl_method_store_cache_get(OSSL_METHOD_STORE *store, OSSL_PROVIDER *prov,

                                int nid, const char *prop_query, void **method)

{

    ALGORITHM *alg;

    QUERY elem, *r;

    int res = 0;

    if (nid <= 0 || store == NULL || prop_query == NULL)

        return 0;

    if (!ossl_property_read_lock(store))

        return 0;

    alg = ossl_method_store_retrieve(store, nid);

    if (alg == NULL)

        goto err;

    elem.query = prop_query;

    elem.provider = prov;

    r = lh_QUERY_retrieve(alg->cache, &elem);

    if (r == NULL)

        goto err;

    if (ossl_method_up_ref(&r->method)) {

        *method = r->method.method;

        res = 1;

    }

err:

    ossl_property_unlock(store);

    return res;

}

int ossl_method_store_cache_set(OSSL_METHOD_STORE *store, OSSL_PROVIDER *prov,

                                int nid, const char *prop_query, void *method,

                                int (*method_up_ref)(void *),

                                void (*method_destruct)(void *))

{

    QUERY elem, *old, *p = NULL;

    ALGORITHM *alg;

    size_t len;

    int res = 1;

    if (nid <= 0 || store == NULL || prop_query == NULL)

        return 0;

    if (!ossl_assert(prov != NULL))

        return 0;

    if (!ossl_property_write_lock(store))

        return 0;

    if (store->cache_need_flush)

        ossl_method_cache_flush_some(store);

    alg = ossl_method_store_retrieve(store, nid);

    if (alg == NULL)

        goto err;

    if (method == NULL) {

        elem.query = prop_query;

        elem.provider = prov;

        if ((old = lh_QUERY_delete(alg->cache, &elem)) != NULL) {

            impl_cache_free(old);

            store->cache_nelem--;

        }

        goto end;

    }

    p = OPENSSL_malloc(sizeof(*p) + (len = strlen(prop_query)));

    if (p != NULL) {

        p->query = p->body;

        p->provider = prov;

        p->method.method = method;

        p->method.up_ref = method_up_ref;

        p->method.free = method_destruct;

        if (!ossl_method_up_ref(&p->method))

            goto err;

        memcpy((char *)p->query, prop_query, len + 1);

        if ((old = lh_QUERY_insert(alg->cache, p)) != NULL) {

            impl_cache_free(old);

            goto end;

        }

        if (!lh_QUERY_error(alg->cache)) {

            if (++store->cache_nelem >= IMPL_CACHE_FLUSH_THRESHOLD)

                store->cache_need_flush = 1;

            goto end;

        }

        ossl_method_free(&p->method);

    }

err:

    res = 0;

    OPENSSL_free(p);

end:

    ossl_property_unlock(store);

    return res;

}