/* * Copyright (C) 2011 Tobias Brunner * 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 "keymat_v1.h" #include #include #include #include typedef struct private_keymat_v1_t private_keymat_v1_t; /** * Max. number of IVs/QMs to track. */ #define MAX_EXCHANGES_DEFAULT 3 /** * Data stored for IVs */ typedef struct { /** message ID */ uint32_t mid; /** current IV */ chunk_t iv; /** last block of encrypted message */ chunk_t last_block; } iv_data_t; /** * Private data of an keymat_t object. */ struct private_keymat_v1_t { /** * Public keymat_v1_t interface. */ keymat_v1_t public; /** * IKE_SA Role, initiator or responder */ bool initiator; /** * General purpose PRF */ prf_t *prf; /** * PRF to create Phase 1 HASH payloads */ prf_t *prf_auth; /** * Crypter wrapped in an aead_t interface */ aead_t *aead; /** * Hasher used for IV generation (and other things like e.g. NAT-T) */ hasher_t *hasher; /** * Key used for authentication during main mode */ chunk_t skeyid; /** * Key to derive key material from for non-ISAKMP SAs, rekeying */ chunk_t skeyid_d; /** * Key used for authentication after main mode */ chunk_t skeyid_a; /** * Phase 1 IV */ iv_data_t phase1_iv; /** * Keep track of IVs for exchanges after phase 1. We store only a limited * number of IVs in an MRU sort of way. Stores iv_data_t objects. */ linked_list_t *ivs; /** * Keep track of Nonces during Quick Mode exchanges. Only a limited number * of QMs are tracked at the same time. Stores qm_data_t objects. */ linked_list_t *qms; /** * Max. number of IVs/Quick Modes to track. */ int max_exchanges; }; /** * Destroy an iv_data_t object. */ static void iv_data_destroy(iv_data_t *this) { chunk_free(&this->last_block); chunk_free(&this->iv); free(this); } /** * Data stored for Quick Mode exchanges */ typedef struct { /** message ID */ uint32_t mid; /** Ni_b (Nonce from first message) */ chunk_t n_i; /** Nr_b (Nonce from second message) */ chunk_t n_r; } qm_data_t; /** * Destroy a qm_data_t object. */ static void qm_data_destroy(qm_data_t *this) { chunk_free(&this->n_i); chunk_free(&this->n_r); free(this); } /** * Constants used in key derivation. */ static const chunk_t octet_0 = chunk_from_chars(0x00); static const chunk_t octet_1 = chunk_from_chars(0x01); static const chunk_t octet_2 = chunk_from_chars(0x02); /** * Simple aead_t implementation without support for authentication. */ typedef struct { /** implements aead_t interface */ aead_t aead; /** crypter to be used */ crypter_t *crypter; } private_aead_t; METHOD(aead_t, encrypt, bool, private_aead_t *this, chunk_t plain, chunk_t assoc, chunk_t iv, chunk_t *encrypted) { return this->crypter->encrypt(this->crypter, plain, iv, encrypted); } METHOD(aead_t, decrypt, bool, private_aead_t *this, chunk_t encrypted, chunk_t assoc, chunk_t iv, chunk_t *plain) { return this->crypter->decrypt(this->crypter, encrypted, iv, plain); } METHOD(aead_t, get_block_size, size_t, private_aead_t *this) { return this->crypter->get_block_size(this->crypter); } METHOD(aead_t, get_icv_size, size_t, private_aead_t *this) { return 0; } METHOD(aead_t, get_iv_size, size_t, private_aead_t *this) { /* in order to create the messages properly we return 0 here */ return 0; } METHOD(aead_t, get_iv_gen, iv_gen_t*, private_aead_t *this) { /* IVs are retrieved via keymat_v1.get_iv() */ return NULL; } METHOD(aead_t, get_key_size, size_t, private_aead_t *this) { return this->crypter->get_key_size(this->crypter); } METHOD(aead_t, set_key, bool, private_aead_t *this, chunk_t key) { return this->crypter->set_key(this->crypter, key); } METHOD(aead_t, aead_destroy, void, private_aead_t *this) { this->crypter->destroy(this->crypter); free(this); } /** * Expand SKEYID_e according to Appendix B in RFC 2409. * TODO-IKEv1: verify keys (e.g. for weak keys, see Appendix B) */ static bool expand_skeyid_e(chunk_t skeyid_e, size_t key_size, prf_t *prf, chunk_t *ka) { size_t block_size; chunk_t seed; int i; if (skeyid_e.len >= key_size) { /* no expansion required, reduce to key_size */ skeyid_e.len = key_size; *ka = skeyid_e; return TRUE; } block_size = prf->get_block_size(prf); *ka = chunk_alloc((key_size / block_size + 1) * block_size); ka->len = key_size; /* Ka = K1 | K2 | ..., K1 = prf(SKEYID_e, 0), K2 = prf(SKEYID_e, K1) ... */ if (!prf->set_key(prf, skeyid_e)) { chunk_clear(ka); chunk_clear(&skeyid_e); return FALSE; } seed = octet_0; for (i = 0; i < key_size; i += block_size) { if (!prf->get_bytes(prf, seed, ka->ptr + i)) { chunk_clear(ka); chunk_clear(&skeyid_e); return FALSE; } seed = chunk_create(ka->ptr + i, block_size); } chunk_clear(&skeyid_e); return TRUE; } /** * Create a simple implementation of the aead_t interface which only encrypts * or decrypts data. */ static aead_t *create_aead(proposal_t *proposal, prf_t *prf, chunk_t skeyid_e) { private_aead_t *this; uint16_t alg, key_size; crypter_t *crypter; chunk_t ka; if (!proposal->get_algorithm(proposal, ENCRYPTION_ALGORITHM, &alg, &key_size)) { DBG1(DBG_IKE, "no %N selected", transform_type_names, ENCRYPTION_ALGORITHM); return NULL; } crypter = lib->crypto->create_crypter(lib->crypto, alg, key_size / 8); if (!crypter) { DBG1(DBG_IKE, "%N %N (key size %d) not supported!", transform_type_names, ENCRYPTION_ALGORITHM, encryption_algorithm_names, alg, key_size); return NULL; } key_size = crypter->get_key_size(crypter); if (!expand_skeyid_e(skeyid_e, crypter->get_key_size(crypter), prf, &ka)) { return NULL; } DBG4(DBG_IKE, "encryption key Ka %B", &ka); if (!crypter->set_key(crypter, ka)) { chunk_clear(&ka); return NULL; } chunk_clear(&ka); INIT(this, .aead = { .encrypt = _encrypt, .decrypt = _decrypt, .get_block_size = _get_block_size, .get_icv_size = _get_icv_size, .get_iv_size = _get_iv_size, .get_iv_gen = _get_iv_gen, .get_key_size = _get_key_size, .set_key = _set_key, .destroy = _aead_destroy, }, .crypter = crypter, ); return &this->aead; } /** * Converts integrity algorithm to PRF algorithm */ static uint16_t auth_to_prf(uint16_t alg) { switch (alg) { case AUTH_HMAC_SHA1_96: return PRF_HMAC_SHA1; case AUTH_HMAC_SHA2_256_128: return PRF_HMAC_SHA2_256; case AUTH_HMAC_SHA2_384_192: return PRF_HMAC_SHA2_384; case AUTH_HMAC_SHA2_512_256: return PRF_HMAC_SHA2_512; case AUTH_HMAC_MD5_96: return PRF_HMAC_MD5; case AUTH_AES_XCBC_96: return PRF_AES128_XCBC; default: return PRF_UNDEFINED; } } /** * Converts integrity algorithm to hash algorithm */ static uint16_t auth_to_hash(uint16_t alg) { switch (alg) { case AUTH_HMAC_SHA1_96: return HASH_SHA1; case AUTH_HMAC_SHA2_256_128: return HASH_SHA256; case AUTH_HMAC_SHA2_384_192: return HASH_SHA384; case AUTH_HMAC_SHA2_512_256: return HASH_SHA512; case AUTH_HMAC_MD5_96: return HASH_MD5; default: return HASH_UNKNOWN; } } /** * Adjust the key length for PRF algorithms that expect a fixed key length. */ static void adjust_keylen(uint16_t alg, chunk_t *key) { switch (alg) { case PRF_AES128_XCBC: /* while rfc4434 defines variable keys for AES-XCBC, rfc3664 does * not and therefore fixed key semantics apply to XCBC for key * derivation. */ key->len = min(key->len, 16); break; default: /* all other algorithms use variable key length */ break; } } METHOD(keymat_v1_t, derive_ike_keys, bool, private_keymat_v1_t *this, proposal_t *proposal, diffie_hellman_t *dh, chunk_t dh_other, chunk_t nonce_i, chunk_t nonce_r, ike_sa_id_t *id, auth_method_t auth, shared_key_t *shared_key) { chunk_t g_xy, g_xi, g_xr, dh_me, spi_i, spi_r, nonces, data, skeyid_e; chunk_t skeyid; uint16_t alg; spi_i = chunk_alloca(sizeof(uint64_t)); spi_r = chunk_alloca(sizeof(uint64_t)); if (!proposal->get_algorithm(proposal, PSEUDO_RANDOM_FUNCTION, &alg, NULL)) { /* no PRF negotiated, use HMAC version of integrity algorithm instead */ if (!proposal->get_algorithm(proposal, INTEGRITY_ALGORITHM, &alg, NULL) || (alg = auth_to_prf(alg)) == PRF_UNDEFINED) { DBG1(DBG_IKE, "no %N selected", transform_type_names, PSEUDO_RANDOM_FUNCTION); return FALSE; } } this->prf = lib->crypto->create_prf(lib->crypto, alg); if (!this->prf) { DBG1(DBG_IKE, "%N %N not supported!", transform_type_names, PSEUDO_RANDOM_FUNCTION, pseudo_random_function_names, alg); return FALSE; } if (this->prf->get_block_size(this->prf) < this->prf->get_key_size(this->prf)) { /* TODO-IKEv1: support PRF output expansion (RFC 2409, Appendix B) */ DBG1(DBG_IKE, "expansion of %N %N output not supported!", transform_type_names, PSEUDO_RANDOM_FUNCTION, pseudo_random_function_names, alg); return FALSE; } if (!dh->get_shared_secret(dh, &g_xy)) { return FALSE; } DBG4(DBG_IKE, "shared Diffie Hellman secret %B", &g_xy); *((uint64_t*)spi_i.ptr) = id->get_initiator_spi(id); *((uint64_t*)spi_r.ptr) = id->get_responder_spi(id); nonces = chunk_cata("cc", nonce_i, nonce_r); switch (auth) { case AUTH_PSK: case AUTH_XAUTH_INIT_PSK: case AUTH_XAUTH_RESP_PSK: { /* SKEYID = prf(pre-shared-key, Ni_b | Nr_b) */ chunk_t psk; if (!shared_key) { chunk_clear(&g_xy); return FALSE; } psk = shared_key->get_key(shared_key); adjust_keylen(alg, &psk); if (!this->prf->set_key(this->prf, psk) || !this->prf->allocate_bytes(this->prf, nonces, &skeyid)) { chunk_clear(&g_xy); return FALSE; } break; } case AUTH_RSA: case AUTH_ECDSA_256: case AUTH_ECDSA_384: case AUTH_ECDSA_521: case AUTH_XAUTH_INIT_RSA: case AUTH_XAUTH_RESP_RSA: case AUTH_HYBRID_INIT_RSA: case AUTH_HYBRID_RESP_RSA: { if (!this->prf->set_key(this->prf, nonces) || !this->prf->allocate_bytes(this->prf, g_xy, &skeyid)) { chunk_clear(&g_xy); return FALSE; } break; } default: /* TODO-IKEv1: implement key derivation for other schemes */ /* authentication class not supported */ chunk_clear(&g_xy); return FALSE; } adjust_keylen(alg, &skeyid); DBG4(DBG_IKE, "SKEYID %B", &skeyid); /* SKEYID_d = prf(SKEYID, g^xy | CKY-I | CKY-R | 0) */ data = chunk_cat("cccc", g_xy, spi_i, spi_r, octet_0); if (!this->prf->set_key(this->prf, skeyid) || !this->prf->allocate_bytes(this->prf, data, &this->skeyid_d)) { chunk_clear(&g_xy); chunk_clear(&data); return FALSE; } chunk_clear(&data); DBG4(DBG_IKE, "SKEYID_d %B", &this->skeyid_d); /* SKEYID_a = prf(SKEYID, SKEYID_d | g^xy | CKY-I | CKY-R | 1) */ data = chunk_cat("ccccc", this->skeyid_d, g_xy, spi_i, spi_r, octet_1); if (!this->prf->allocate_bytes(this->prf, data, &this->skeyid_a)) { chunk_clear(&g_xy); chunk_clear(&data); return FALSE; } chunk_clear(&data); DBG4(DBG_IKE, "SKEYID_a %B", &this->skeyid_a); /* SKEYID_e = prf(SKEYID, SKEYID_a | g^xy | CKY-I | CKY-R | 2) */ data = chunk_cat("ccccc", this->skeyid_a, g_xy, spi_i, spi_r, octet_2); if (!this->prf->allocate_bytes(this->prf, data, &skeyid_e)) { chunk_clear(&g_xy); chunk_clear(&data); return FALSE; } chunk_clear(&data); DBG4(DBG_IKE, "SKEYID_e %B", &skeyid_e); chunk_clear(&g_xy); switch (auth) { case AUTH_ECDSA_256: alg = PRF_HMAC_SHA2_256; break; case AUTH_ECDSA_384: alg = PRF_HMAC_SHA2_384; break; case AUTH_ECDSA_521: alg = PRF_HMAC_SHA2_512; break; default: /* use proposal algorithm */ break; } this->prf_auth = lib->crypto->create_prf(lib->crypto, alg); if (!this->prf_auth) { DBG1(DBG_IKE, "%N %N not supported!", transform_type_names, PSEUDO_RANDOM_FUNCTION, pseudo_random_function_names, alg); chunk_clear(&skeyid); return FALSE; } if (!this->prf_auth->set_key(this->prf_auth, skeyid)) { chunk_clear(&skeyid); return FALSE; } chunk_clear(&skeyid); this->aead = create_aead(proposal, this->prf, skeyid_e); if (!this->aead) { return FALSE; } if (!this->hasher && !this->public.create_hasher(&this->public, proposal)) { return FALSE; } if (!dh->get_my_public_value(dh, &dh_me)) { return FALSE; } g_xi = this->initiator ? dh_me : dh_other; g_xr = this->initiator ? dh_other : dh_me; /* initial IV = hash(g^xi | g^xr) */ data = chunk_cata("cc", g_xi, g_xr); chunk_free(&dh_me); if (!this->hasher->allocate_hash(this->hasher, data, &this->phase1_iv.iv)) { return FALSE; } if (this->phase1_iv.iv.len > this->aead->get_block_size(this->aead)) { this->phase1_iv.iv.len = this->aead->get_block_size(this->aead); } DBG4(DBG_IKE, "initial IV %B", &this->phase1_iv.iv); return TRUE; } METHOD(keymat_v1_t, derive_child_keys, bool, private_keymat_v1_t *this, proposal_t *proposal, diffie_hellman_t *dh, uint32_t spi_i, uint32_t spi_r, chunk_t nonce_i, chunk_t nonce_r, chunk_t *encr_i, chunk_t *integ_i, chunk_t *encr_r, chunk_t *integ_r) { uint16_t enc_alg, int_alg, enc_size = 0, int_size = 0; uint8_t protocol; prf_plus_t *prf_plus; chunk_t seed, secret = chunk_empty; bool success = FALSE; if (proposal->get_algorithm(proposal, ENCRYPTION_ALGORITHM, &enc_alg, &enc_size)) { DBG2(DBG_CHD, " using %N for encryption", encryption_algorithm_names, enc_alg); if (!enc_size) { enc_size = keymat_get_keylen_encr(enc_alg); } if (enc_alg != ENCR_NULL && !enc_size) { DBG1(DBG_CHD, "no keylength defined for %N", encryption_algorithm_names, enc_alg); return FALSE; } /* to bytes */ enc_size /= 8; /* CCM/GCM/CTR/GMAC needs additional bytes */ switch (enc_alg) { case ENCR_AES_CCM_ICV8: case ENCR_AES_CCM_ICV12: case ENCR_AES_CCM_ICV16: case ENCR_CAMELLIA_CCM_ICV8: case ENCR_CAMELLIA_CCM_ICV12: case ENCR_CAMELLIA_CCM_ICV16: enc_size += 3; break; case ENCR_AES_GCM_ICV8: case ENCR_AES_GCM_ICV12: case ENCR_AES_GCM_ICV16: case ENCR_AES_CTR: case ENCR_NULL_AUTH_AES_GMAC: enc_size += 4; break; default: break; } } if (proposal->get_algorithm(proposal, INTEGRITY_ALGORITHM, &int_alg, &int_size)) { DBG2(DBG_CHD, " using %N for integrity", integrity_algorithm_names, int_alg); if (!int_size) { int_size = keymat_get_keylen_integ(int_alg); } if (!int_size) { DBG1(DBG_CHD, "no keylength defined for %N", integrity_algorithm_names, int_alg); return FALSE; } /* to bytes */ int_size /= 8; } /* KEYMAT = prf+(SKEYID_d, [ g(qm)^xy | ] protocol | SPI | Ni_b | Nr_b) */ if (!this->prf->set_key(this->prf, this->skeyid_d)) { return FALSE; } protocol = proposal->get_protocol(proposal); if (dh) { if (!dh->get_shared_secret(dh, &secret)) { return FALSE; } DBG4(DBG_CHD, "DH secret %B", &secret); } *encr_r = *integ_r = *encr_i = *integ_i = chunk_empty; seed = chunk_cata("ccccc", secret, chunk_from_thing(protocol), chunk_from_thing(spi_r), nonce_i, nonce_r); DBG4(DBG_CHD, "initiator SA seed %B", &seed); prf_plus = prf_plus_create(this->prf, FALSE, seed); if (!prf_plus || !prf_plus->allocate_bytes(prf_plus, enc_size, encr_i) || !prf_plus->allocate_bytes(prf_plus, int_size, integ_i)) { goto failure; } seed = chunk_cata("ccccc", secret, chunk_from_thing(protocol), chunk_from_thing(spi_i), nonce_i, nonce_r); DBG4(DBG_CHD, "responder SA seed %B", &seed); prf_plus->destroy(prf_plus); prf_plus = prf_plus_create(this->prf, FALSE, seed); if (!prf_plus || !prf_plus->allocate_bytes(prf_plus, enc_size, encr_r) || !prf_plus->allocate_bytes(prf_plus, int_size, integ_r)) { goto failure; } if (enc_size) { DBG4(DBG_CHD, "encryption initiator key %B", encr_i); DBG4(DBG_CHD, "encryption responder key %B", encr_r); } if (int_size) { DBG4(DBG_CHD, "integrity initiator key %B", integ_i); DBG4(DBG_CHD, "integrity responder key %B", integ_r); } success = TRUE; failure: if (!success) { chunk_clear(encr_i); chunk_clear(integ_i); chunk_clear(encr_r); chunk_clear(integ_r); } DESTROY_IF(prf_plus); chunk_clear(&secret); return success; } METHOD(keymat_v1_t, create_hasher, bool, private_keymat_v1_t *this, proposal_t *proposal) { uint16_t alg; if (!proposal->get_algorithm(proposal, INTEGRITY_ALGORITHM, &alg, NULL) || (alg = auth_to_hash(alg)) == HASH_UNKNOWN) { DBG1(DBG_IKE, "no %N selected", transform_type_names, HASH_ALGORITHM); return FALSE; } this->hasher = lib->crypto->create_hasher(lib->crypto, alg); if (!this->hasher) { DBG1(DBG_IKE, "%N %N not supported!", transform_type_names, HASH_ALGORITHM, hash_algorithm_names, alg); return FALSE; } return TRUE; } METHOD(keymat_v1_t, get_hasher, hasher_t*, private_keymat_v1_t *this) { return this->hasher; } METHOD(keymat_v1_t, get_hash, bool, private_keymat_v1_t *this, bool initiator, chunk_t dh, chunk_t dh_other, ike_sa_id_t *ike_sa_id, chunk_t sa_i, chunk_t id, chunk_t *hash) { chunk_t data; uint64_t spi, spi_other; /* HASH_I = prf(SKEYID, g^xi | g^xr | CKY-I | CKY-R | SAi_b | IDii_b ) * HASH_R = prf(SKEYID, g^xr | g^xi | CKY-R | CKY-I | SAi_b | IDir_b ) */ if (initiator) { spi = ike_sa_id->get_initiator_spi(ike_sa_id); spi_other = ike_sa_id->get_responder_spi(ike_sa_id); } else { spi_other = ike_sa_id->get_initiator_spi(ike_sa_id); spi = ike_sa_id->get_responder_spi(ike_sa_id); } data = chunk_cat("cccccc", dh, dh_other, chunk_from_thing(spi), chunk_from_thing(spi_other), sa_i, id); DBG3(DBG_IKE, "HASH_%c data %B", initiator ? 'I' : 'R', &data); if (!this->prf_auth->allocate_bytes(this->prf_auth, data, hash)) { free(data.ptr); return FALSE; } DBG3(DBG_IKE, "HASH_%c %B", initiator ? 'I' : 'R', hash); free(data.ptr); return TRUE; } /** * Get the nonce value found in the given message. * Returns FALSE if none is found. */ static bool get_nonce(message_t *message, chunk_t *n) { nonce_payload_t *nonce; nonce = (nonce_payload_t*)message->get_payload(message, PLV1_NONCE); if (nonce) { *n = nonce->get_nonce(nonce); return TRUE; } return FALSE; } /** * Generate the message data in order to generate the hashes. */ static chunk_t get_message_data(message_t *message, generator_t *generator) { payload_t *payload, *next; enumerator_t *enumerator; uint32_t *lenpos; if (message->is_encoded(message)) { /* inbound, although the message is generated, we cannot access the * cleartext message data, so generate it anyway */ enumerator = message->create_payload_enumerator(message); while (enumerator->enumerate(enumerator, &payload)) { if (payload->get_type(payload) == PLV1_HASH) { continue; } generator->generate_payload(generator, payload); } enumerator->destroy(enumerator); } else { /* outbound, generate the payloads (there is no HASH payload yet) */ enumerator = message->create_payload_enumerator(message); if (enumerator->enumerate(enumerator, &payload)) { while (enumerator->enumerate(enumerator, &next)) { payload->set_next_type(payload, next->get_type(next)); generator->generate_payload(generator, payload); payload = next; } payload->set_next_type(payload, PL_NONE); generator->generate_payload(generator, payload); } enumerator->destroy(enumerator); } return generator->get_chunk(generator, &lenpos); } /** * Try to find data about a Quick Mode with the given message ID, * if none is found, state is generated. */ static qm_data_t *lookup_quick_mode(private_keymat_v1_t *this, uint32_t mid) { enumerator_t *enumerator; qm_data_t *qm, *found = NULL; enumerator = this->qms->create_enumerator(this->qms); while (enumerator->enumerate(enumerator, &qm)) { if (qm->mid == mid) { /* state gets moved to the front of the list */ this->qms->remove_at(this->qms, enumerator); found = qm; break; } } enumerator->destroy(enumerator); if (!found) { INIT(found, .mid = mid, ); } this->qms->insert_first(this->qms, found); /* remove least recently used state if maximum reached */ if (this->qms->get_count(this->qms) > this->max_exchanges && this->qms->remove_last(this->qms, (void**)&qm) == SUCCESS) { qm_data_destroy(qm); } return found; } METHOD(keymat_v1_t, get_hash_phase2, bool, private_keymat_v1_t *this, message_t *message, chunk_t *hash) { uint32_t mid, mid_n; chunk_t data = chunk_empty; bool add_message = TRUE; char *name = "Hash"; if (!this->prf) { /* no keys derived yet */ return FALSE; } mid = message->get_message_id(message); mid_n = htonl(mid); /* Hashes are simple for most exchanges in Phase 2: * Hash = prf(SKEYID_a, M-ID | Complete message after HASH payload) * For Quick Mode there are three hashes: * Hash(1) = same as above * Hash(2) = prf(SKEYID_a, M-ID | Ni_b | Message after HASH payload) * Hash(3) = prf(SKEYID_a, 0 | M-ID | Ni_b | Nr_b) * So, for Quick Mode we keep track of the nonce values. */ switch (message->get_exchange_type(message)) { case QUICK_MODE: { qm_data_t *qm = lookup_quick_mode(this, mid); if (!qm->n_i.ptr) { /* Hash(1) = prf(SKEYID_a, M-ID | Message after HASH payload) */ name = "Hash(1)"; if (!get_nonce(message, &qm->n_i)) { return FALSE; } data = chunk_from_thing(mid_n); } else if (!qm->n_r.ptr) { /* Hash(2) = prf(SKEYID_a, M-ID | Ni_b | Message after HASH) */ name = "Hash(2)"; if (!get_nonce(message, &qm->n_r)) { return FALSE; } data = chunk_cata("cc", chunk_from_thing(mid_n), qm->n_i); } else { /* Hash(3) = prf(SKEYID_a, 0 | M-ID | Ni_b | Nr_b) */ name = "Hash(3)"; data = chunk_cata("cccc", octet_0, chunk_from_thing(mid_n), qm->n_i, qm->n_r); add_message = FALSE; /* we don't need the state anymore */ this->qms->remove(this->qms, qm, NULL); qm_data_destroy(qm); } break; } case TRANSACTION: case INFORMATIONAL_V1: /* Hash = prf(SKEYID_a, M-ID | Message after HASH payload) */ data = chunk_from_thing(mid_n); break; default: return FALSE; } if (!this->prf->set_key(this->prf, this->skeyid_a)) { return FALSE; } if (add_message) { generator_t *generator; chunk_t msg; generator = generator_create_no_dbg(); msg = get_message_data(message, generator); if (!this->prf->allocate_bytes(this->prf, data, NULL) || !this->prf->allocate_bytes(this->prf, msg, hash)) { generator->destroy(generator); return FALSE; } generator->destroy(generator); } else { if (!this->prf->allocate_bytes(this->prf, data, hash)) { return FALSE; } } DBG3(DBG_IKE, "%s %B", name, hash); return TRUE; } /** * Generate an IV */ static bool generate_iv(private_keymat_v1_t *this, iv_data_t *iv) { if (iv->mid == 0 || iv->iv.ptr) { /* use last block of previous encrypted message */ chunk_free(&iv->iv); iv->iv = iv->last_block; iv->last_block = chunk_empty; } else { /* initial phase 2 IV = hash(last_phase1_block | mid) */ uint32_t net;; chunk_t data; net = htonl(iv->mid); data = chunk_cata("cc", this->phase1_iv.iv, chunk_from_thing(net)); if (!this->hasher->allocate_hash(this->hasher, data, &iv->iv)) { return FALSE; } if (iv->iv.len > this->aead->get_block_size(this->aead)) { iv->iv.len = this->aead->get_block_size(this->aead); } } DBG4(DBG_IKE, "next IV for MID %u %B", iv->mid, &iv->iv); return TRUE; } /** * Try to find an IV for the given message ID, if not found, generate it. */ static iv_data_t *lookup_iv(private_keymat_v1_t *this, uint32_t mid) { enumerator_t *enumerator; iv_data_t *iv, *found = NULL; if (mid == 0) { return &this->phase1_iv; } enumerator = this->ivs->create_enumerator(this->ivs); while (enumerator->enumerate(enumerator, &iv)) { if (iv->mid == mid) { /* IV gets moved to the front of the list */ this->ivs->remove_at(this->ivs, enumerator); found = iv; break; } } enumerator->destroy(enumerator); if (!found) { INIT(found, .mid = mid, ); if (!generate_iv(this, found)) { iv_data_destroy(found); return NULL; } } this->ivs->insert_first(this->ivs, found); /* remove least recently used IV if maximum reached */ if (this->ivs->get_count(this->ivs) > this->max_exchanges && this->ivs->remove_last(this->ivs, (void**)&iv) == SUCCESS) { iv_data_destroy(iv); } return found; } METHOD(keymat_v1_t, get_iv, bool, private_keymat_v1_t *this, uint32_t mid, chunk_t *out) { iv_data_t *iv; iv = lookup_iv(this, mid); if (iv) { *out = iv->iv; return TRUE; } return FALSE; } METHOD(keymat_v1_t, update_iv, bool, private_keymat_v1_t *this, uint32_t mid, chunk_t last_block) { iv_data_t *iv = lookup_iv(this, mid); if (iv) { /* update last block */ chunk_free(&iv->last_block); iv->last_block = chunk_clone(last_block); return TRUE; } return FALSE; } METHOD(keymat_v1_t, confirm_iv, bool, private_keymat_v1_t *this, uint32_t mid) { iv_data_t *iv = lookup_iv(this, mid); if (iv) { return generate_iv(this, iv); } return FALSE; } METHOD(keymat_t, get_version, ike_version_t, private_keymat_v1_t *this) { return IKEV1; } METHOD(keymat_t, create_dh, diffie_hellman_t*, private_keymat_v1_t *this, diffie_hellman_group_t group) { return lib->crypto->create_dh(lib->crypto, group); } METHOD(keymat_t, create_nonce_gen, nonce_gen_t*, private_keymat_v1_t *this) { return lib->crypto->create_nonce_gen(lib->crypto); } METHOD(keymat_t, get_aead, aead_t*, private_keymat_v1_t *this, bool in) { return this->aead; } METHOD(keymat_t, destroy, void, private_keymat_v1_t *this) { DESTROY_IF(this->prf); DESTROY_IF(this->prf_auth); DESTROY_IF(this->aead); DESTROY_IF(this->hasher); chunk_clear(&this->skeyid_d); chunk_clear(&this->skeyid_a); chunk_free(&this->phase1_iv.iv); chunk_free(&this->phase1_iv.last_block); this->ivs->destroy_function(this->ivs, (void*)iv_data_destroy); this->qms->destroy_function(this->qms, (void*)qm_data_destroy); free(this); } /** * See header */ keymat_v1_t *keymat_v1_create(bool initiator) { private_keymat_v1_t *this; INIT(this, .public = { .keymat = { .get_version = _get_version, .create_dh = _create_dh, .create_nonce_gen = _create_nonce_gen, .get_aead = _get_aead, .destroy = _destroy, }, .derive_ike_keys = _derive_ike_keys, .derive_child_keys = _derive_child_keys, .create_hasher = _create_hasher, .get_hasher = _get_hasher, .get_hash = _get_hash, .get_hash_phase2 = _get_hash_phase2, .get_iv = _get_iv, .update_iv = _update_iv, .confirm_iv = _confirm_iv, }, .ivs = linked_list_create(), .qms = linked_list_create(), .initiator = initiator, .max_exchanges = lib->settings->get_int(lib->settings, "%s.max_ikev1_exchanges", MAX_EXCHANGES_DEFAULT, lib->ns), ); return &this->public; }