/* * Copyright (C) 2010 Martin Willi * Copyright (C) 2010 revosec AG * * 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 "tls_server.h" #include #include #include typedef struct private_tls_server_t private_tls_server_t; typedef enum { STATE_INIT, STATE_HELLO_RECEIVED, STATE_HELLO_SENT, STATE_CERT_SENT, STATE_KEY_EXCHANGE_SENT, STATE_CERTREQ_SENT, STATE_HELLO_DONE, STATE_CERT_RECEIVED, STATE_KEY_EXCHANGE_RECEIVED, STATE_CERT_VERIFY_RECEIVED, STATE_CIPHERSPEC_CHANGED_IN, STATE_FINISHED_RECEIVED, STATE_CIPHERSPEC_CHANGED_OUT, STATE_FINISHED_SENT, } server_state_t; /** * Private data of an tls_server_t object. */ struct private_tls_server_t { /** * Public tls_server_t interface. */ tls_server_t public; /** * TLS stack */ tls_t *tls; /** * TLS crypto context */ tls_crypto_t *crypto; /** * TLS alert handler */ tls_alert_t *alert; /** * Server identity */ identification_t *server; /** * Peer identity, NULL for no client authentication */ identification_t *peer; /** * State we are in */ server_state_t state; /** * Hello random data selected by client */ char client_random[32]; /** * Hello random data selected by server */ char server_random[32]; /** * Auth helper for peer authentication */ auth_cfg_t *peer_auth; /** * Auth helper for server authentication */ auth_cfg_t *server_auth; /** * Peer private key */ private_key_t *private; /** * DHE exchange */ diffie_hellman_t *dh; /** * Selected TLS cipher suite */ tls_cipher_suite_t suite; /** * Offered TLS version of the client */ tls_version_t client_version; /** * Hash and signature algorithms supported by peer */ chunk_t hashsig; /** * Elliptic curves supported by peer */ chunk_t curves; /** * Did we receive the curves from the client? */ bool curves_received; }; /** * Find a cipher suite and a server key */ static bool select_suite_and_key(private_tls_server_t *this, tls_cipher_suite_t *suites, int count) { private_key_t *key; key_type_t type; key = lib->credmgr->get_private(lib->credmgr, KEY_ANY, this->server, this->server_auth); if (!key) { DBG1(DBG_TLS, "no usable TLS server certificate found for '%Y'", this->server); return FALSE; } this->suite = this->crypto->select_cipher_suite(this->crypto, suites, count, key->get_type(key)); if (!this->suite) { /* no match for this key, try to find another type */ if (key->get_type(key) == KEY_ECDSA) { type = KEY_RSA; } else { type = KEY_ECDSA; } key->destroy(key); this->suite = this->crypto->select_cipher_suite(this->crypto, suites, count, type); if (!this->suite) { DBG1(DBG_TLS, "received cipher suites inacceptable"); return FALSE; } this->server_auth->destroy(this->server_auth); this->server_auth = auth_cfg_create(); key = lib->credmgr->get_private(lib->credmgr, type, this->server, this->server_auth); if (!key) { DBG1(DBG_TLS, "received cipher suites inacceptable"); return FALSE; } } this->private = key; return TRUE; } /** * Process client hello message */ static status_t process_client_hello(private_tls_server_t *this, bio_reader_t *reader) { u_int16_t version, extension; chunk_t random, session, ciphers, compression, ext = chunk_empty; bio_reader_t *extensions; tls_cipher_suite_t *suites; int count, i; this->crypto->append_handshake(this->crypto, TLS_CLIENT_HELLO, reader->peek(reader)); if (!reader->read_uint16(reader, &version) || !reader->read_data(reader, sizeof(this->client_random), &random) || !reader->read_data8(reader, &session) || !reader->read_data16(reader, &ciphers) || !reader->read_data8(reader, &compression) || (reader->remaining(reader) && !reader->read_data16(reader, &ext))) { DBG1(DBG_TLS, "received invalid ClientHello"); this->alert->add(this->alert, TLS_FATAL, TLS_DECODE_ERROR); return NEED_MORE; } if (ext.len) { extensions = bio_reader_create(ext); while (extensions->remaining(extensions)) { if (!extensions->read_uint16(extensions, &extension) || !extensions->read_data16(extensions, &ext)) { DBG1(DBG_TLS, "received invalid ClientHello Extensions"); this->alert->add(this->alert, TLS_FATAL, TLS_DECODE_ERROR); extensions->destroy(extensions); return NEED_MORE; } DBG2(DBG_TLS, "received TLS '%N' extension", tls_extension_names, extension); DBG3(DBG_TLS, "%B", &ext); switch (extension) { case TLS_EXT_SIGNATURE_ALGORITHMS: this->hashsig = chunk_clone(ext); break; case TLS_EXT_ELLIPTIC_CURVES: this->curves_received = TRUE; this->curves = chunk_clone(ext); break; default: break; } } extensions->destroy(extensions); } memcpy(this->client_random, random.ptr, sizeof(this->client_random)); if (!this->tls->set_version(this->tls, version)) { DBG1(DBG_TLS, "negotiated version %N not supported", tls_version_names, version); this->alert->add(this->alert, TLS_FATAL, TLS_PROTOCOL_VERSION); return NEED_MORE; } count = ciphers.len / sizeof(u_int16_t); suites = alloca(count * sizeof(tls_cipher_suite_t)); DBG2(DBG_TLS, "received %d TLS cipher suites:", count); for (i = 0; i < count; i++) { suites[i] = untoh16(&ciphers.ptr[i * sizeof(u_int16_t)]); DBG2(DBG_TLS, " %N", tls_cipher_suite_names, suites[i]); } if (!select_suite_and_key(this, suites, count)) { this->alert->add(this->alert, TLS_FATAL, TLS_HANDSHAKE_FAILURE); return NEED_MORE; } DBG1(DBG_TLS, "negotiated TLS version %N with suite %N", tls_version_names, this->tls->get_version(this->tls), tls_cipher_suite_names, this->suite); this->client_version = version; this->state = STATE_HELLO_RECEIVED; return NEED_MORE; } /** * Process certificate */ static status_t process_certificate(private_tls_server_t *this, bio_reader_t *reader) { certificate_t *cert; bio_reader_t *certs; chunk_t data; bool first = TRUE; this->crypto->append_handshake(this->crypto, TLS_CERTIFICATE, reader->peek(reader)); if (!reader->read_data24(reader, &data)) { DBG1(DBG_TLS, "certificate message header invalid"); this->alert->add(this->alert, TLS_FATAL, TLS_DECODE_ERROR); return NEED_MORE; } certs = bio_reader_create(data); while (certs->remaining(certs)) { if (!certs->read_data24(certs, &data)) { DBG1(DBG_TLS, "certificate message invalid"); this->alert->add(this->alert, TLS_FATAL, TLS_DECODE_ERROR); certs->destroy(certs); return NEED_MORE; } cert = lib->creds->create(lib->creds, CRED_CERTIFICATE, CERT_X509, BUILD_BLOB_ASN1_DER, data, BUILD_END); if (cert) { if (first) { this->peer_auth->add(this->peer_auth, AUTH_HELPER_SUBJECT_CERT, cert); DBG1(DBG_TLS, "received TLS peer certificate '%Y'", cert->get_subject(cert)); first = FALSE; } else { DBG1(DBG_TLS, "received TLS intermediate certificate '%Y'", cert->get_subject(cert)); this->peer_auth->add(this->peer_auth, AUTH_HELPER_IM_CERT, cert); } } else { DBG1(DBG_TLS, "parsing TLS certificate failed, skipped"); this->alert->add(this->alert, TLS_WARNING, TLS_BAD_CERTIFICATE); } } certs->destroy(certs); this->state = STATE_CERT_RECEIVED; return NEED_MORE; } /** * Process Client Key Exchange, using premaster encryption */ static status_t process_key_exchange_encrypted(private_tls_server_t *this, bio_reader_t *reader) { chunk_t encrypted, decrypted; char premaster[48]; rng_t *rng; this->crypto->append_handshake(this->crypto, TLS_CLIENT_KEY_EXCHANGE, reader->peek(reader)); if (!reader->read_data16(reader, &encrypted)) { DBG1(DBG_TLS, "received invalid Client Key Exchange"); this->alert->add(this->alert, TLS_FATAL, TLS_DECODE_ERROR); return NEED_MORE; } htoun16(premaster, this->client_version); /* pre-randomize premaster for failure cases */ rng = lib->crypto->create_rng(lib->crypto, RNG_WEAK); if (!rng) { DBG1(DBG_TLS, "creating RNG failed"); this->alert->add(this->alert, TLS_FATAL, TLS_INTERNAL_ERROR); return NEED_MORE; } rng->get_bytes(rng, sizeof(premaster) - 2, premaster + 2); rng->destroy(rng); if (this->private && this->private->decrypt(this->private, ENCRYPT_RSA_PKCS1, encrypted, &decrypted)) { if (decrypted.len == sizeof(premaster) && untoh16(decrypted.ptr) == this->client_version) { memcpy(premaster + 2, decrypted.ptr + 2, sizeof(premaster) - 2); } else { DBG1(DBG_TLS, "decrypted premaster has invalid length/version"); } chunk_clear(&decrypted); } else { DBG1(DBG_TLS, "decrypting Client Key Exchange failed"); } this->crypto->derive_secrets(this->crypto, chunk_from_thing(premaster), chunk_from_thing(this->client_random), chunk_from_thing(this->server_random)); this->state = STATE_KEY_EXCHANGE_RECEIVED; return NEED_MORE; } /** * Process client key exchange, using DHE exchange */ static status_t process_key_exchange_dhe(private_tls_server_t *this, bio_reader_t *reader) { chunk_t premaster, pub; bool ec; this->crypto->append_handshake(this->crypto, TLS_CLIENT_KEY_EXCHANGE, reader->peek(reader)); ec = diffie_hellman_group_is_ec(this->dh->get_dh_group(this->dh)); if ((ec && !reader->read_data8(reader, &pub)) || (!ec && (!reader->read_data16(reader, &pub) || pub.len == 0))) { DBG1(DBG_TLS, "received invalid Client Key Exchange"); this->alert->add(this->alert, TLS_FATAL, TLS_DECODE_ERROR); return NEED_MORE; } if (ec) { if (pub.ptr[0] != TLS_ANSI_UNCOMPRESSED) { DBG1(DBG_TLS, "DH point format '%N' not supported", tls_ansi_point_format_names, pub.ptr[0]); this->alert->add(this->alert, TLS_FATAL, TLS_INTERNAL_ERROR); return NEED_MORE; } pub = chunk_skip(pub, 1); } this->dh->set_other_public_value(this->dh, pub); if (this->dh->get_shared_secret(this->dh, &premaster) != SUCCESS) { DBG1(DBG_TLS, "calculating premaster from DH failed"); this->alert->add(this->alert, TLS_FATAL, TLS_INTERNAL_ERROR); return NEED_MORE; } this->crypto->derive_secrets(this->crypto, premaster, chunk_from_thing(this->client_random), chunk_from_thing(this->server_random)); chunk_clear(&premaster); this->state = STATE_KEY_EXCHANGE_RECEIVED; return NEED_MORE; } /** * Process Client Key Exchange */ static status_t process_key_exchange(private_tls_server_t *this, bio_reader_t *reader) { if (this->dh) { return process_key_exchange_dhe(this, reader); } return process_key_exchange_encrypted(this, reader); } /** * Process Certificate verify */ static status_t process_cert_verify(private_tls_server_t *this, bio_reader_t *reader) { bool verified = FALSE; enumerator_t *enumerator; public_key_t *public; auth_cfg_t *auth; bio_reader_t *sig; enumerator = lib->credmgr->create_public_enumerator(lib->credmgr, KEY_ANY, this->peer, this->peer_auth); while (enumerator->enumerate(enumerator, &public, &auth)) { sig = bio_reader_create(reader->peek(reader)); verified = this->crypto->verify_handshake(this->crypto, public, sig); sig->destroy(sig); if (verified) { break; } DBG1(DBG_TLS, "signature verification failed, trying another key"); } enumerator->destroy(enumerator); if (!verified) { DBG1(DBG_TLS, "no trusted certificate found for '%Y' to verify TLS peer", this->peer); this->alert->add(this->alert, TLS_FATAL, TLS_CERTIFICATE_UNKNOWN); return NEED_MORE; } this->crypto->append_handshake(this->crypto, TLS_CERTIFICATE_VERIFY, reader->peek(reader)); this->state = STATE_CERT_VERIFY_RECEIVED; return NEED_MORE; } /** * Process finished message */ static status_t process_finished(private_tls_server_t *this, bio_reader_t *reader) { chunk_t received; char buf[12]; if (!reader->read_data(reader, sizeof(buf), &received)) { DBG1(DBG_TLS, "received client finished too short"); this->alert->add(this->alert, TLS_FATAL, TLS_DECODE_ERROR); return NEED_MORE; } if (!this->crypto->calculate_finished(this->crypto, "client finished", buf)) { DBG1(DBG_TLS, "calculating client finished failed"); this->alert->add(this->alert, TLS_FATAL, TLS_INTERNAL_ERROR); return NEED_MORE; } if (!chunk_equals(received, chunk_from_thing(buf))) { DBG1(DBG_TLS, "received client finished invalid"); this->alert->add(this->alert, TLS_FATAL, TLS_DECRYPT_ERROR); return NEED_MORE; } this->crypto->append_handshake(this->crypto, TLS_FINISHED, received); this->state = STATE_FINISHED_RECEIVED; return NEED_MORE; } METHOD(tls_handshake_t, process, status_t, private_tls_server_t *this, tls_handshake_type_t type, bio_reader_t *reader) { tls_handshake_type_t expected; switch (this->state) { case STATE_INIT: if (type == TLS_CLIENT_HELLO) { return process_client_hello(this, reader); } expected = TLS_CLIENT_HELLO; break; case STATE_HELLO_DONE: if (type == TLS_CERTIFICATE) { return process_certificate(this, reader); } if (this->peer) { expected = TLS_CERTIFICATE; break; } /* otherwise fall through to next state */ case STATE_CERT_RECEIVED: if (type == TLS_CLIENT_KEY_EXCHANGE) { return process_key_exchange(this, reader); } expected = TLS_CLIENT_KEY_EXCHANGE; break; case STATE_KEY_EXCHANGE_RECEIVED: if (type == TLS_CERTIFICATE_VERIFY) { return process_cert_verify(this, reader); } if (this->peer) { expected = TLS_CERTIFICATE_VERIFY; break; } else { return INVALID_STATE; } case STATE_CIPHERSPEC_CHANGED_IN: if (type == TLS_FINISHED) { return process_finished(this, reader); } expected = TLS_FINISHED; break; default: DBG1(DBG_TLS, "TLS %N not expected in current state", tls_handshake_type_names, type); this->alert->add(this->alert, TLS_FATAL, TLS_UNEXPECTED_MESSAGE); return NEED_MORE; } DBG1(DBG_TLS, "TLS %N expected, but received %N", tls_handshake_type_names, expected, tls_handshake_type_names, type); this->alert->add(this->alert, TLS_FATAL, TLS_UNEXPECTED_MESSAGE); return NEED_MORE; } /** * Send ServerHello message */ static status_t send_server_hello(private_tls_server_t *this, tls_handshake_type_t *type, bio_writer_t *writer) { tls_version_t version; rng_t *rng; htoun32(&this->server_random, time(NULL)); rng = lib->crypto->create_rng(lib->crypto, RNG_WEAK); if (!rng) { DBG1(DBG_TLS, "no suitable RNG found to generate server random"); this->alert->add(this->alert, TLS_FATAL, TLS_INTERNAL_ERROR); return FAILED; } rng->get_bytes(rng, sizeof(this->server_random) - 4, this->server_random + 4); rng->destroy(rng); /* TLS version */ version = this->tls->get_version(this->tls); writer->write_uint16(writer, version); writer->write_data(writer, chunk_from_thing(this->server_random)); /* session identifier => none, we don't support session resumption */ writer->write_data8(writer, chunk_empty); /* add selected TLS cipher suite */ writer->write_uint16(writer, this->suite); /* NULL compression only */ writer->write_uint8(writer, 0); *type = TLS_SERVER_HELLO; this->state = STATE_HELLO_SENT; this->crypto->append_handshake(this->crypto, *type, writer->get_buf(writer)); return NEED_MORE; } /** * Send Certificate */ static status_t send_certificate(private_tls_server_t *this, tls_handshake_type_t *type, bio_writer_t *writer) { enumerator_t *enumerator; certificate_t *cert; auth_rule_t rule; bio_writer_t *certs; chunk_t data; /* generate certificate payload */ certs = bio_writer_create(256); cert = this->server_auth->get(this->server_auth, AUTH_RULE_SUBJECT_CERT); if (cert) { if (cert->get_encoding(cert, CERT_ASN1_DER, &data)) { DBG1(DBG_TLS, "sending TLS server certificate '%Y'", cert->get_subject(cert)); certs->write_data24(certs, data); free(data.ptr); } } enumerator = this->server_auth->create_enumerator(this->server_auth); while (enumerator->enumerate(enumerator, &rule, &cert)) { if (rule == AUTH_RULE_IM_CERT) { if (cert->get_encoding(cert, CERT_ASN1_DER, &data)) { DBG1(DBG_TLS, "sending TLS intermediate certificate '%Y'", cert->get_subject(cert)); certs->write_data24(certs, data); free(data.ptr); } } } enumerator->destroy(enumerator); writer->write_data24(writer, certs->get_buf(certs)); certs->destroy(certs); *type = TLS_CERTIFICATE; this->state = STATE_CERT_SENT; this->crypto->append_handshake(this->crypto, *type, writer->get_buf(writer)); return NEED_MORE; } /** * Send Certificate Request */ static status_t send_certificate_request(private_tls_server_t *this, tls_handshake_type_t *type, bio_writer_t *writer) { bio_writer_t *authorities, *supported; enumerator_t *enumerator; certificate_t *cert; x509_t *x509; identification_t *id; supported = bio_writer_create(4); /* we propose both RSA and ECDSA */ supported->write_uint8(supported, TLS_RSA_SIGN); supported->write_uint8(supported, TLS_ECDSA_SIGN); writer->write_data8(writer, supported->get_buf(supported)); supported->destroy(supported); if (this->tls->get_version(this->tls) >= TLS_1_2) { this->crypto->get_signature_algorithms(this->crypto, writer); } authorities = bio_writer_create(64); enumerator = lib->credmgr->create_cert_enumerator(lib->credmgr, CERT_X509, KEY_RSA, NULL, TRUE); while (enumerator->enumerate(enumerator, &cert)) { x509 = (x509_t*)cert; if (x509->get_flags(x509) & X509_CA) { id = cert->get_subject(cert); DBG1(DBG_TLS, "sending TLS cert request for '%Y'", id); authorities->write_data16(authorities, id->get_encoding(id)); } } enumerator->destroy(enumerator); writer->write_data16(writer, authorities->get_buf(authorities)); authorities->destroy(authorities); *type = TLS_CERTIFICATE_REQUEST; this->state = STATE_CERTREQ_SENT; this->crypto->append_handshake(this->crypto, *type, writer->get_buf(writer)); return NEED_MORE; } /** * Get the TLS curve of a given EC DH group */ static tls_named_curve_t ec_group_to_curve(private_tls_server_t *this, diffie_hellman_group_t group) { diffie_hellman_group_t current; tls_named_curve_t curve; enumerator_t *enumerator; enumerator = this->crypto->create_ec_enumerator(this->crypto); while (enumerator->enumerate(enumerator, ¤t, &curve)) { if (current == group) { enumerator->destroy(enumerator); return curve; } } enumerator->destroy(enumerator); return 0; } /** * Check if the peer supports a given TLS curve */ bool peer_supports_curve(private_tls_server_t *this, tls_named_curve_t curve) { bio_reader_t *reader; u_int16_t current; if (!this->curves_received) { /* none received, assume yes */ return TRUE; } reader = bio_reader_create(this->curves); while (reader->remaining(reader) && reader->read_uint16(reader, ¤t)) { if (current == curve) { reader->destroy(reader); return TRUE; } } reader->destroy(reader); return FALSE; } /** * Try to find a curve supported by both, client and server */ static bool find_supported_curve(private_tls_server_t *this, tls_named_curve_t *curve) { tls_named_curve_t current; enumerator_t *enumerator; enumerator = this->crypto->create_ec_enumerator(this->crypto); while (enumerator->enumerate(enumerator, NULL, ¤t)) { if (peer_supports_curve(this, current)) { *curve = current; enumerator->destroy(enumerator); return TRUE; } } enumerator->destroy(enumerator); return FALSE; } /** * Send Server key Exchange */ static status_t send_server_key_exchange(private_tls_server_t *this, tls_handshake_type_t *type, bio_writer_t *writer, diffie_hellman_group_t group) { diffie_hellman_params_t *params = NULL; tls_named_curve_t curve; chunk_t chunk; if (diffie_hellman_group_is_ec(group)) { curve = ec_group_to_curve(this, group); if (!curve || (!peer_supports_curve(this, curve) && !find_supported_curve(this, &curve))) { DBG1(DBG_TLS, "no EC group supported by client and server"); this->alert->add(this->alert, TLS_FATAL, TLS_HANDSHAKE_FAILURE); return NEED_MORE; } DBG2(DBG_TLS, "selected ECDH group %N", tls_named_curve_names, curve); writer->write_uint8(writer, TLS_ECC_NAMED_CURVE); writer->write_uint16(writer, curve); } else { params = diffie_hellman_get_params(group); if (!params) { DBG1(DBG_TLS, "no parameters found for DH group %N", diffie_hellman_group_names, group); this->alert->add(this->alert, TLS_FATAL, TLS_INTERNAL_ERROR); return NEED_MORE; } DBG2(DBG_TLS, "selected DH group %N", diffie_hellman_group_names, group); writer->write_data16(writer, params->prime); writer->write_data16(writer, params->generator); } this->dh = lib->crypto->create_dh(lib->crypto, group); if (!this->dh) { DBG1(DBG_TLS, "DH group %N not supported", diffie_hellman_group_names, group); this->alert->add(this->alert, TLS_FATAL, TLS_INTERNAL_ERROR); return NEED_MORE; } this->dh->get_my_public_value(this->dh, &chunk); if (params) { writer->write_data16(writer, chunk); } else { /* ECP uses 8bit length header only, but a point format */ writer->write_uint8(writer, chunk.len + 1); writer->write_uint8(writer, TLS_ANSI_UNCOMPRESSED); writer->write_data(writer, chunk); } free(chunk.ptr); chunk = chunk_cat("ccc", chunk_from_thing(this->client_random), chunk_from_thing(this->server_random), writer->get_buf(writer)); if (!this->private || !this->crypto->sign(this->crypto, this->private, writer, chunk, this->hashsig)) { DBG1(DBG_TLS, "signing DH parameters failed"); this->alert->add(this->alert, TLS_FATAL, TLS_INTERNAL_ERROR); free(chunk.ptr); return NEED_MORE; } free(chunk.ptr); *type = TLS_SERVER_KEY_EXCHANGE; this->state = STATE_KEY_EXCHANGE_SENT; this->crypto->append_handshake(this->crypto, *type, writer->get_buf(writer)); return NEED_MORE; } /** * Send Hello Done */ static status_t send_hello_done(private_tls_server_t *this, tls_handshake_type_t *type, bio_writer_t *writer) { *type = TLS_SERVER_HELLO_DONE; this->state = STATE_HELLO_DONE; this->crypto->append_handshake(this->crypto, *type, writer->get_buf(writer)); return NEED_MORE; } /** * Send Finished */ static status_t send_finished(private_tls_server_t *this, tls_handshake_type_t *type, bio_writer_t *writer) { char buf[12]; if (!this->crypto->calculate_finished(this->crypto, "server finished", buf)) { DBG1(DBG_TLS, "calculating server finished data failed"); this->alert->add(this->alert, TLS_FATAL, TLS_INTERNAL_ERROR); return FAILED; } writer->write_data(writer, chunk_from_thing(buf)); *type = TLS_FINISHED; this->state = STATE_FINISHED_SENT; this->crypto->derive_eap_msk(this->crypto, chunk_from_thing(this->client_random), chunk_from_thing(this->server_random)); return NEED_MORE; } METHOD(tls_handshake_t, build, status_t, private_tls_server_t *this, tls_handshake_type_t *type, bio_writer_t *writer) { diffie_hellman_group_t group; switch (this->state) { case STATE_HELLO_RECEIVED: return send_server_hello(this, type, writer); case STATE_HELLO_SENT: return send_certificate(this, type, writer); case STATE_CERT_SENT: group = this->crypto->get_dh_group(this->crypto); if (group) { return send_server_key_exchange(this, type, writer, group); } /* otherwise fall through to next state */ case STATE_KEY_EXCHANGE_SENT: if (this->peer) { return send_certificate_request(this, type, writer); } /* otherwise fall through to next state */ case STATE_CERTREQ_SENT: return send_hello_done(this, type, writer); case STATE_CIPHERSPEC_CHANGED_OUT: return send_finished(this, type, writer); case STATE_FINISHED_SENT: return INVALID_STATE; default: return INVALID_STATE; } } METHOD(tls_handshake_t, cipherspec_changed, bool, private_tls_server_t *this, bool inbound) { if (inbound) { if (this->peer) { return this->state == STATE_CERT_VERIFY_RECEIVED; } return this->state == STATE_KEY_EXCHANGE_RECEIVED; } else { return this->state == STATE_FINISHED_RECEIVED; } return FALSE; } METHOD(tls_handshake_t, change_cipherspec, void, private_tls_server_t *this, bool inbound) { this->crypto->change_cipher(this->crypto, inbound); if (inbound) { this->state = STATE_CIPHERSPEC_CHANGED_IN; } else { this->state = STATE_CIPHERSPEC_CHANGED_OUT; } } METHOD(tls_handshake_t, finished, bool, private_tls_server_t *this) { return this->state == STATE_FINISHED_SENT; } METHOD(tls_handshake_t, destroy, void, private_tls_server_t *this) { DESTROY_IF(this->private); DESTROY_IF(this->dh); this->peer_auth->destroy(this->peer_auth); this->server_auth->destroy(this->server_auth); free(this->hashsig.ptr); free(this->curves.ptr); free(this); } /** * See header */ tls_server_t *tls_server_create(tls_t *tls, tls_crypto_t *crypto, tls_alert_t *alert, identification_t *server, identification_t *peer) { private_tls_server_t *this; INIT(this, .public = { .handshake = { .process = _process, .build = _build, .cipherspec_changed = _cipherspec_changed, .change_cipherspec = _change_cipherspec, .finished = _finished, .destroy = _destroy, }, }, .tls = tls, .crypto = crypto, .alert = alert, .server = server, .peer = peer, .state = STATE_INIT, .peer_auth = auth_cfg_create(), .server_auth = auth_cfg_create(), ); return &this->public; }