/* * Copyright (C) 2013-2014 Tobias Brunner * Copyright (C) 2008 Martin Willi * Copyright (C) 2016 Andreas Steffen * HSR Hochschule fuer Technik Rapperswil * * This program is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation; either version 2 of the License, or (at your * option) any later version. See . * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * for more details. */ #include "crypto_factory.h" #include #include #include #include #include const char *default_plugin_name = "default"; typedef struct entry_t entry_t; struct entry_t { /** * algorithm */ u_int algo; /** * plugin that registered this algorithm */ const char *plugin_name; /** * benchmarked speed */ u_int speed; /** * constructor */ union { crypter_constructor_t create_crypter; aead_constructor_t create_aead; signer_constructor_t create_signer; hasher_constructor_t create_hasher; prf_constructor_t create_prf; xof_constructor_t create_xof; rng_constructor_t create_rng; nonce_gen_constructor_t create_nonce_gen; dh_constructor_t create_dh; void *create; }; }; typedef struct private_crypto_factory_t private_crypto_factory_t; /** * private data of crypto_factory */ struct private_crypto_factory_t { /** * public functions */ crypto_factory_t public; /** * registered crypters, as entry_t */ linked_list_t *crypters; /** * registered aead transforms, as entry_t */ linked_list_t *aeads; /** * registered signers, as entry_t */ linked_list_t *signers; /** * registered hashers, as entry_t */ linked_list_t *hashers; /** * registered prfs, as entry_t */ linked_list_t *prfs; /** * registered xofs, as entry_t */ linked_list_t *xofs; /** * registered rngs, as entry_t */ linked_list_t *rngs; /** * registered nonce generators, as entry_t */ linked_list_t *nonce_gens; /** * registered diffie hellman, as entry_t */ linked_list_t *dhs; /** * test manager to test crypto algorithms */ crypto_tester_t *tester; /** * whether to test algorithms during registration */ bool test_on_add; /** * whether to test algorithms on each crypto primitive construction */ bool test_on_create; /** * run algorithm benchmark during registration */ bool bench; /** * Number of failed test vectors during "add". */ u_int test_failures; /** * rwlock to lock access to modules */ rwlock_t *lock; }; METHOD(crypto_factory_t, create_crypter, crypter_t*, private_crypto_factory_t *this, encryption_algorithm_t algo, size_t key_size) { enumerator_t *enumerator; entry_t *entry; crypter_t *crypter = NULL; this->lock->read_lock(this->lock); enumerator = this->crypters->create_enumerator(this->crypters); while (enumerator->enumerate(enumerator, &entry)) { if (entry->algo == algo) { if (this->test_on_create && !this->tester->test_crypter(this->tester, algo, key_size, entry->create_crypter, NULL, default_plugin_name)) { continue; } crypter = entry->create_crypter(algo, key_size); if (crypter) { break; } } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); return crypter; } METHOD(crypto_factory_t, create_aead, aead_t*, private_crypto_factory_t *this, encryption_algorithm_t algo, size_t key_size, size_t salt_size) { enumerator_t *enumerator; entry_t *entry; aead_t *aead = NULL; this->lock->read_lock(this->lock); enumerator = this->aeads->create_enumerator(this->aeads); while (enumerator->enumerate(enumerator, &entry)) { if (entry->algo == algo) { if (this->test_on_create && !this->tester->test_aead(this->tester, algo, key_size, salt_size, entry->create_aead, NULL, default_plugin_name)) { continue; } aead = entry->create_aead(algo, key_size, salt_size); if (aead) { break; } } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); return aead; } METHOD(crypto_factory_t, create_signer, signer_t*, private_crypto_factory_t *this, integrity_algorithm_t algo) { enumerator_t *enumerator; entry_t *entry; signer_t *signer = NULL; this->lock->read_lock(this->lock); enumerator = this->signers->create_enumerator(this->signers); while (enumerator->enumerate(enumerator, &entry)) { if (entry->algo == algo) { if (this->test_on_create && !this->tester->test_signer(this->tester, algo, entry->create_signer, NULL, default_plugin_name)) { continue; } signer = entry->create_signer(algo); if (signer) { break; } } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); return signer; } METHOD(crypto_factory_t, create_hasher, hasher_t*, private_crypto_factory_t *this, hash_algorithm_t algo) { enumerator_t *enumerator; entry_t *entry; hasher_t *hasher = NULL; this->lock->read_lock(this->lock); enumerator = this->hashers->create_enumerator(this->hashers); while (enumerator->enumerate(enumerator, &entry)) { if (entry->algo == algo) { if (this->test_on_create && !this->tester->test_hasher(this->tester, algo, entry->create_hasher, NULL, default_plugin_name)) { continue; } hasher = entry->create_hasher(entry->algo); if (hasher) { break; } } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); return hasher; } METHOD(crypto_factory_t, create_prf, prf_t*, private_crypto_factory_t *this, pseudo_random_function_t algo) { enumerator_t *enumerator; entry_t *entry; prf_t *prf = NULL; this->lock->read_lock(this->lock); enumerator = this->prfs->create_enumerator(this->prfs); while (enumerator->enumerate(enumerator, &entry)) { if (entry->algo == algo) { if (this->test_on_create && !this->tester->test_prf(this->tester, algo, entry->create_prf, NULL, default_plugin_name)) { continue; } prf = entry->create_prf(algo); if (prf) { break; } } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); return prf; } METHOD(crypto_factory_t, create_xof, xof_t*, private_crypto_factory_t *this, ext_out_function_t algo) { enumerator_t *enumerator; entry_t *entry; xof_t *xof = NULL; this->lock->read_lock(this->lock); enumerator = this->xofs->create_enumerator(this->xofs); while (enumerator->enumerate(enumerator, &entry)) { if (entry->algo == algo) { if (this->test_on_create && !this->tester->test_xof(this->tester, algo, entry->create_xof, NULL, default_plugin_name)) { continue; } xof = entry->create_xof(algo); if (xof) { break; } } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); return xof; } METHOD(crypto_factory_t, create_rng, rng_t*, private_crypto_factory_t *this, rng_quality_t quality) { enumerator_t *enumerator; entry_t *entry; rng_t *rng = NULL; this->lock->read_lock(this->lock); enumerator = this->rngs->create_enumerator(this->rngs); while (enumerator->enumerate(enumerator, &entry)) { /* find the best matching quality, but at least as good as requested */ if (entry->algo >= quality) { if (this->test_on_create && !this->tester->test_rng(this->tester, quality, entry->create_rng, NULL, default_plugin_name)) { continue; } rng = entry->create_rng(quality); if (rng) { break; } } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); return rng; } METHOD(crypto_factory_t, create_nonce_gen, nonce_gen_t*, private_crypto_factory_t *this) { enumerator_t *enumerator; entry_t *entry; nonce_gen_t *nonce_gen = NULL; this->lock->read_lock(this->lock); enumerator = this->nonce_gens->create_enumerator(this->nonce_gens); while (enumerator->enumerate(enumerator, &entry)) { nonce_gen = entry->create_nonce_gen(); if (nonce_gen) { break; } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); return nonce_gen; } METHOD(crypto_factory_t, create_dh, diffie_hellman_t*, private_crypto_factory_t *this, diffie_hellman_group_t group, ...) { enumerator_t *enumerator; entry_t *entry; va_list args; chunk_t g = chunk_empty, p = chunk_empty; diffie_hellman_t *diffie_hellman = NULL; if (group == MODP_CUSTOM) { va_start(args, group); g = va_arg(args, chunk_t); p = va_arg(args, chunk_t); va_end(args); } this->lock->read_lock(this->lock); enumerator = this->dhs->create_enumerator(this->dhs); while (enumerator->enumerate(enumerator, &entry)) { if (entry->algo == group) { if (this->test_on_create && group != MODP_CUSTOM && !this->tester->test_dh(this->tester, group, entry->create_dh, NULL, default_plugin_name)) { continue; } diffie_hellman = entry->create_dh(group, g, p); if (diffie_hellman) { break; } } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); return diffie_hellman; } /** * Insert an algorithm entry to a list * * Entries maintain the order in which algorithms were added, unless they were * benchmarked and speed is provided, which then is used to order entries of * the same algorithm. * An exception are RNG entries, which are sorted by algorithm identifier. */ static void add_entry(private_crypto_factory_t *this, linked_list_t *list, int algo, const char *plugin_name, u_int speed, void *create) { enumerator_t *enumerator; entry_t *entry, *current; bool sort = (list == this->rngs), found = FALSE; INIT(entry, .algo = algo, .plugin_name = plugin_name, .speed = speed, ); entry->create = create; this->lock->write_lock(this->lock); enumerator = list->create_enumerator(list); while (enumerator->enumerate(enumerator, ¤t)) { if (sort && current->algo > algo) { break; } else if (current->algo == algo) { if (speed > current->speed) { break; } found = TRUE; } else if (found) { break; } } list->insert_before(list, enumerator, entry); enumerator->destroy(enumerator); this->lock->unlock(this->lock); } METHOD(crypto_factory_t, add_crypter, bool, private_crypto_factory_t *this, encryption_algorithm_t algo, size_t key_size, const char *plugin_name, crypter_constructor_t create) { u_int speed = 0; if (!this->test_on_add || this->tester->test_crypter(this->tester, algo, key_size, create, this->bench ? &speed : NULL, plugin_name)) { add_entry(this, this->crypters, algo, plugin_name, speed, create); return TRUE; } this->test_failures++; return FALSE; } METHOD(crypto_factory_t, remove_crypter, void, private_crypto_factory_t *this, crypter_constructor_t create) { entry_t *entry; enumerator_t *enumerator; this->lock->write_lock(this->lock); enumerator = this->crypters->create_enumerator(this->crypters); while (enumerator->enumerate(enumerator, &entry)) { if (entry->create_crypter == create) { this->crypters->remove_at(this->crypters, enumerator); free(entry); } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); } METHOD(crypto_factory_t, add_aead, bool, private_crypto_factory_t *this, encryption_algorithm_t algo, size_t key_size, const char *plugin_name, aead_constructor_t create) { u_int speed = 0; if (!this->test_on_add || this->tester->test_aead(this->tester, algo, key_size, 0, create, this->bench ? &speed : NULL, plugin_name)) { add_entry(this, this->aeads, algo, plugin_name, speed, create); return TRUE; } this->test_failures++; return FALSE; } METHOD(crypto_factory_t, remove_aead, void, private_crypto_factory_t *this, aead_constructor_t create) { entry_t *entry; enumerator_t *enumerator; this->lock->write_lock(this->lock); enumerator = this->aeads->create_enumerator(this->aeads); while (enumerator->enumerate(enumerator, &entry)) { if (entry->create_aead == create) { this->aeads->remove_at(this->aeads, enumerator); free(entry); } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); } METHOD(crypto_factory_t, add_signer, bool, private_crypto_factory_t *this, integrity_algorithm_t algo, const char *plugin_name, signer_constructor_t create) { u_int speed = 0; if (!this->test_on_add || this->tester->test_signer(this->tester, algo, create, this->bench ? &speed : NULL, plugin_name)) { add_entry(this, this->signers, algo, plugin_name, speed, create); return TRUE; } this->test_failures++; return FALSE; } METHOD(crypto_factory_t, remove_signer, void, private_crypto_factory_t *this, signer_constructor_t create) { entry_t *entry; enumerator_t *enumerator; this->lock->write_lock(this->lock); enumerator = this->signers->create_enumerator(this->signers); while (enumerator->enumerate(enumerator, &entry)) { if (entry->create_signer == create) { this->signers->remove_at(this->signers, enumerator); free(entry); } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); } METHOD(crypto_factory_t, add_hasher, bool, private_crypto_factory_t *this, hash_algorithm_t algo, const char *plugin_name, hasher_constructor_t create) { u_int speed = 0; if (!this->test_on_add || this->tester->test_hasher(this->tester, algo, create, this->bench ? &speed : NULL, plugin_name)) { add_entry(this, this->hashers, algo, plugin_name, speed, create); return TRUE; } this->test_failures++; return FALSE; } METHOD(crypto_factory_t, remove_hasher, void, private_crypto_factory_t *this, hasher_constructor_t create) { entry_t *entry; enumerator_t *enumerator; this->lock->write_lock(this->lock); enumerator = this->hashers->create_enumerator(this->hashers); while (enumerator->enumerate(enumerator, &entry)) { if (entry->create_hasher == create) { this->hashers->remove_at(this->hashers, enumerator); free(entry); } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); } METHOD(crypto_factory_t, add_prf, bool, private_crypto_factory_t *this, pseudo_random_function_t algo, const char *plugin_name, prf_constructor_t create) { u_int speed = 0; if (!this->test_on_add || this->tester->test_prf(this->tester, algo, create, this->bench ? &speed : NULL, plugin_name)) { add_entry(this, this->prfs, algo, plugin_name, speed, create); return TRUE; } this->test_failures++; return FALSE; } METHOD(crypto_factory_t, remove_prf, void, private_crypto_factory_t *this, prf_constructor_t create) { entry_t *entry; enumerator_t *enumerator; this->lock->write_lock(this->lock); enumerator = this->prfs->create_enumerator(this->prfs); while (enumerator->enumerate(enumerator, &entry)) { if (entry->create_prf == create) { this->prfs->remove_at(this->prfs, enumerator); free(entry); } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); } METHOD(crypto_factory_t, add_xof, bool, private_crypto_factory_t *this, ext_out_function_t algo, const char *plugin_name, xof_constructor_t create) { u_int speed = 0; if (!this->test_on_add || this->tester->test_xof(this->tester, algo, create, this->bench ? &speed : NULL, plugin_name)) { add_entry(this, this->xofs, algo, plugin_name, speed, create); return TRUE; } this->test_failures++; return FALSE; } METHOD(crypto_factory_t, remove_xof, void, private_crypto_factory_t *this, xof_constructor_t create) { entry_t *entry; enumerator_t *enumerator; this->lock->write_lock(this->lock); enumerator = this->xofs->create_enumerator(this->xofs); while (enumerator->enumerate(enumerator, &entry)) { if (entry->create_xof == create) { this->xofs->remove_at(this->xofs, enumerator); free(entry); } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); } METHOD(crypto_factory_t, add_rng, bool, private_crypto_factory_t *this, rng_quality_t quality, const char *plugin_name, rng_constructor_t create) { u_int speed = 0; if (!this->test_on_add || this->tester->test_rng(this->tester, quality, create, this->bench ? &speed : NULL, plugin_name)) { add_entry(this, this->rngs, quality, plugin_name, speed, create); return TRUE; } this->test_failures++; return FALSE; } METHOD(crypto_factory_t, remove_rng, void, private_crypto_factory_t *this, rng_constructor_t create) { entry_t *entry; enumerator_t *enumerator; this->lock->write_lock(this->lock); enumerator = this->rngs->create_enumerator(this->rngs); while (enumerator->enumerate(enumerator, &entry)) { if (entry->create_rng == create) { this->rngs->remove_at(this->rngs, enumerator); free(entry); } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); } METHOD(crypto_factory_t, add_nonce_gen, bool, private_crypto_factory_t *this, const char *plugin_name, nonce_gen_constructor_t create) { add_entry(this, this->nonce_gens, 0, plugin_name, 0, create); return TRUE; } METHOD(crypto_factory_t, remove_nonce_gen, void, private_crypto_factory_t *this, nonce_gen_constructor_t create) { entry_t *entry; enumerator_t *enumerator; this->lock->write_lock(this->lock); enumerator = this->nonce_gens->create_enumerator(this->nonce_gens); while (enumerator->enumerate(enumerator, &entry)) { if (entry->create_nonce_gen == create) { this->nonce_gens->remove_at(this->nonce_gens, enumerator); free(entry); } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); } METHOD(crypto_factory_t, add_dh, bool, private_crypto_factory_t *this, diffie_hellman_group_t group, const char *plugin_name, dh_constructor_t create) { u_int speed = 0; if (!this->test_on_add || this->tester->test_dh(this->tester, group, create, this->bench ? &speed : NULL, plugin_name)) { add_entry(this, this->dhs, group, plugin_name, 0, create); return TRUE; } this->test_failures++; return FALSE; } METHOD(crypto_factory_t, remove_dh, void, private_crypto_factory_t *this, dh_constructor_t create) { entry_t *entry; enumerator_t *enumerator; this->lock->write_lock(this->lock); enumerator = this->dhs->create_enumerator(this->dhs); while (enumerator->enumerate(enumerator, &entry)) { if (entry->create_dh == create) { this->dhs->remove_at(this->dhs, enumerator); free(entry); } } enumerator->destroy(enumerator); this->lock->unlock(this->lock); } /** * match algorithms of an entry? */ static bool entry_match(entry_t *a, entry_t *b) { return a->algo == b->algo; } /** * check for uniqueness of an entry */ static bool unique_check(linked_list_t *list, entry_t **in, entry_t **out) { if (list->find_first(list, (void*)entry_match, NULL, *in) == SUCCESS) { return FALSE; } *out = *in; list->insert_last(list, *in); return TRUE; } /** * create an enumerator over entry->algo in list with locking and unique check */ static enumerator_t *create_enumerator(private_crypto_factory_t *this, linked_list_t *list, void *filter) { this->lock->read_lock(this->lock); return enumerator_create_filter( enumerator_create_filter( list->create_enumerator(list), (void*)unique_check, linked_list_create(), (void*)list->destroy), filter, this->lock, (void*)this->lock->unlock); } /** * Filter function to enumerate algorithm, not entry */ static bool crypter_filter(void *n, entry_t **entry, encryption_algorithm_t *algo, void *i2, const char **plugin_name) { *algo = (*entry)->algo; *plugin_name = (*entry)->plugin_name; return TRUE; } METHOD(crypto_factory_t, create_crypter_enumerator, enumerator_t*, private_crypto_factory_t *this) { return create_enumerator(this, this->crypters, crypter_filter); } METHOD(crypto_factory_t, create_aead_enumerator, enumerator_t*, private_crypto_factory_t *this) { return create_enumerator(this, this->aeads, crypter_filter); } /** * Filter function to enumerate algorithm, not entry */ static bool signer_filter(void *n, entry_t **entry, integrity_algorithm_t *algo, void *i2, const char **plugin_name) { *algo = (*entry)->algo; *plugin_name = (*entry)->plugin_name; return TRUE; } METHOD(crypto_factory_t, create_signer_enumerator, enumerator_t*, private_crypto_factory_t *this) { return create_enumerator(this, this->signers, signer_filter); } /** * Filter function to enumerate algorithm, not entry */ static bool hasher_filter(void *n, entry_t **entry, hash_algorithm_t *algo, void *i2, const char **plugin_name) { *algo = (*entry)->algo; *plugin_name = (*entry)->plugin_name; return TRUE; } METHOD(crypto_factory_t, create_hasher_enumerator, enumerator_t*, private_crypto_factory_t *this) { return create_enumerator(this, this->hashers, hasher_filter); } /** * Filter function to enumerate algorithm, not entry */ static bool prf_filter(void *n, entry_t **entry, pseudo_random_function_t *algo, void *i2, const char **plugin_name) { *algo = (*entry)->algo; *plugin_name = (*entry)->plugin_name; return TRUE; } METHOD(crypto_factory_t, create_prf_enumerator, enumerator_t*, private_crypto_factory_t *this) { return create_enumerator(this, this->prfs, prf_filter); } /** * Filter function to enumerate algorithm, not entry */ static bool xof_filter(void *n, entry_t **entry, ext_out_function_t *algo, void *i2, const char **plugin_name) { *algo = (*entry)->algo; *plugin_name = (*entry)->plugin_name; return TRUE; } METHOD(crypto_factory_t, create_xof_enumerator, enumerator_t*, private_crypto_factory_t *this) { return create_enumerator(this, this->xofs, xof_filter); } /** * Filter function to enumerate group, not entry */ static bool dh_filter(void *n, entry_t **entry, diffie_hellman_group_t *group, void *i2, const char **plugin_name) { *group = (*entry)->algo; *plugin_name = (*entry)->plugin_name; return TRUE; } METHOD(crypto_factory_t, create_dh_enumerator, enumerator_t*, private_crypto_factory_t *this) { return create_enumerator(this, this->dhs, dh_filter); } /** * Filter function to enumerate strength, not entry */ static bool rng_filter(void *n, entry_t **entry, rng_quality_t *quality, void *i2, const char **plugin_name) { *quality = (*entry)->algo; *plugin_name = (*entry)->plugin_name; return TRUE; } METHOD(crypto_factory_t, create_rng_enumerator, enumerator_t*, private_crypto_factory_t *this) { return create_enumerator(this, this->rngs, rng_filter); } /** * Filter function to enumerate plugin name, not entry */ static bool nonce_gen_filter(void *n, entry_t **entry, const char **plugin_name) { *plugin_name = (*entry)->plugin_name; return TRUE; } METHOD(crypto_factory_t, create_nonce_gen_enumerator, enumerator_t*, private_crypto_factory_t *this) { return create_enumerator(this, this->nonce_gens, nonce_gen_filter); } METHOD(crypto_factory_t, add_test_vector, void, private_crypto_factory_t *this, transform_type_t type, void *vector) { switch (type) { case ENCRYPTION_ALGORITHM: return this->tester->add_crypter_vector(this->tester, vector); case AEAD_ALGORITHM: return this->tester->add_aead_vector(this->tester, vector); case INTEGRITY_ALGORITHM: return this->tester->add_signer_vector(this->tester, vector); case HASH_ALGORITHM: return this->tester->add_hasher_vector(this->tester, vector); case PSEUDO_RANDOM_FUNCTION: return this->tester->add_prf_vector(this->tester, vector); case EXTENDED_OUTPUT_FUNCTION: return this->tester->add_xof_vector(this->tester, vector); case RANDOM_NUMBER_GENERATOR: return this->tester->add_rng_vector(this->tester, vector); case DIFFIE_HELLMAN_GROUP: return this->tester->add_dh_vector(this->tester, vector); default: DBG1(DBG_LIB, "%N test vectors not supported, ignored", transform_type_names, type); } } /** * Private enumerator for create_verify_enumerator() */ typedef struct { enumerator_t public; enumerator_t *inner; transform_type_t type; crypto_tester_t *tester; rwlock_t *lock; } verify_enumerator_t; METHOD(enumerator_t, verify_enumerate, bool, verify_enumerator_t *this, u_int *alg, const char **plugin, bool *valid) { entry_t *entry; if (!this->inner->enumerate(this->inner, &entry)) { return FALSE; } switch (this->type) { case ENCRYPTION_ALGORITHM: *valid = this->tester->test_crypter(this->tester, entry->algo, 0, entry->create_crypter, NULL, entry->plugin_name); break; case AEAD_ALGORITHM: *valid = this->tester->test_aead(this->tester, entry->algo, 0, 0, entry->create_aead, NULL, entry->plugin_name); break; case INTEGRITY_ALGORITHM: *valid = this->tester->test_signer(this->tester, entry->algo, entry->create_signer, NULL, entry->plugin_name); break; case HASH_ALGORITHM: *valid = this->tester->test_hasher(this->tester, entry->algo, entry->create_hasher, NULL, entry->plugin_name); break; case PSEUDO_RANDOM_FUNCTION: *valid = this->tester->test_prf(this->tester, entry->algo, entry->create_prf, NULL, entry->plugin_name); break; case EXTENDED_OUTPUT_FUNCTION: *valid = this->tester->test_xof(this->tester, entry->algo, entry->create_xof, NULL, entry->plugin_name); break; case RANDOM_NUMBER_GENERATOR: *valid = this->tester->test_rng(this->tester, entry->algo, entry->create_rng, NULL, entry->plugin_name); break; case DIFFIE_HELLMAN_GROUP: *valid = this->tester->test_dh(this->tester, entry->algo, entry->create_dh, NULL, entry->plugin_name); break; default: return FALSE; } *plugin = entry->plugin_name; *alg = entry->algo; return TRUE; } METHOD(enumerator_t, verify_destroy, void, verify_enumerator_t *this) { this->inner->destroy(this->inner); this->lock->unlock(this->lock); free(this); } METHOD(crypto_factory_t, create_verify_enumerator, enumerator_t*, private_crypto_factory_t *this, transform_type_t type) { verify_enumerator_t *enumerator; enumerator_t *inner; this->lock->read_lock(this->lock); switch (type) { case ENCRYPTION_ALGORITHM: inner = this->crypters->create_enumerator(this->crypters); break; case AEAD_ALGORITHM: inner = this->aeads->create_enumerator(this->aeads); break; case INTEGRITY_ALGORITHM: inner = this->signers->create_enumerator(this->signers); break; case HASH_ALGORITHM: inner = this->hashers->create_enumerator(this->hashers); break; case PSEUDO_RANDOM_FUNCTION: inner = this->prfs->create_enumerator(this->prfs); break; case EXTENDED_OUTPUT_FUNCTION: inner = this->xofs->create_enumerator(this->xofs); break; case RANDOM_NUMBER_GENERATOR: inner = this->rngs->create_enumerator(this->rngs); break; case DIFFIE_HELLMAN_GROUP: inner = this->dhs->create_enumerator(this->dhs); break; default: this->lock->unlock(this->lock); return enumerator_create_empty(); } INIT(enumerator, .public = { .enumerate = (void*)_verify_enumerate, .destroy = _verify_destroy, }, .inner = inner, .type = type, .tester = this->tester, .lock = this->lock, ); return &enumerator->public; } METHOD(crypto_factory_t, destroy, void, private_crypto_factory_t *this) { this->crypters->destroy(this->crypters); this->aeads->destroy(this->aeads); this->signers->destroy(this->signers); this->hashers->destroy(this->hashers); this->prfs->destroy(this->prfs); this->xofs->destroy(this->xofs); this->rngs->destroy(this->rngs); this->nonce_gens->destroy(this->nonce_gens); this->dhs->destroy(this->dhs); this->tester->destroy(this->tester); this->lock->destroy(this->lock); free(this); } /* * see header file */ crypto_factory_t *crypto_factory_create() { private_crypto_factory_t *this; INIT(this, .public = { .create_crypter = _create_crypter, .create_aead = _create_aead, .create_signer = _create_signer, .create_hasher = _create_hasher, .create_prf = _create_prf, .create_xof = _create_xof, .create_rng = _create_rng, .create_nonce_gen = _create_nonce_gen, .create_dh = _create_dh, .add_crypter = _add_crypter, .remove_crypter = _remove_crypter, .add_aead = _add_aead, .remove_aead = _remove_aead, .add_signer = _add_signer, .remove_signer = _remove_signer, .add_hasher = _add_hasher, .remove_hasher = _remove_hasher, .add_prf = _add_prf, .remove_prf = _remove_prf, .add_xof = _add_xof, .remove_xof = _remove_xof, .add_rng = _add_rng, .remove_rng = _remove_rng, .add_nonce_gen = _add_nonce_gen, .remove_nonce_gen = _remove_nonce_gen, .add_dh = _add_dh, .remove_dh = _remove_dh, .create_crypter_enumerator = _create_crypter_enumerator, .create_aead_enumerator = _create_aead_enumerator, .create_signer_enumerator = _create_signer_enumerator, .create_hasher_enumerator = _create_hasher_enumerator, .create_prf_enumerator = _create_prf_enumerator, .create_xof_enumerator = _create_xof_enumerator, .create_dh_enumerator = _create_dh_enumerator, .create_rng_enumerator = _create_rng_enumerator, .create_nonce_gen_enumerator = _create_nonce_gen_enumerator, .add_test_vector = _add_test_vector, .create_verify_enumerator = _create_verify_enumerator, .destroy = _destroy, }, .crypters = linked_list_create(), .aeads = linked_list_create(), .signers = linked_list_create(), .hashers = linked_list_create(), .prfs = linked_list_create(), .xofs = linked_list_create(), .rngs = linked_list_create(), .nonce_gens = linked_list_create(), .dhs = linked_list_create(), .lock = rwlock_create(RWLOCK_TYPE_DEFAULT), .tester = crypto_tester_create(), .test_on_add = lib->settings->get_bool(lib->settings, "%s.crypto_test.on_add", FALSE, lib->ns), .test_on_create = lib->settings->get_bool(lib->settings, "%s.crypto_test.on_create", FALSE, lib->ns), .bench = lib->settings->get_bool(lib->settings, "%s.crypto_test.bench", FALSE, lib->ns), ); return &this->public; }