// Copyright 1995-2016 The OpenSSL Project Authors. All Rights Reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // https://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include #include #include #include #include "../crypto/internal.h" #include "internal.h" BSSL_NAMESPACE_BEGIN static void tls_on_handshake_complete(SSL *ssl) { // The handshake should have released its final message. assert(!ssl->s3->has_message); // During the handshake, |hs_buf| is retained. Release if it there is no // excess in it. There should not be any excess because the handshake logic // rejects unprocessed data after each Finished message. Note this means we do // not allow a TLS 1.2 HelloRequest to be packed into the same record as // Finished. (Schannel also rejects this.) assert(!ssl->s3->hs_buf || ssl->s3->hs_buf->length == 0); if (ssl->s3->hs_buf && ssl->s3->hs_buf->length == 0) { ssl->s3->hs_buf.reset(); } } static bool tls_set_read_state(SSL *ssl, ssl_encryption_level_t level, UniquePtr aead_ctx, Span traffic_secret) { // Cipher changes are forbidden if the current epoch has leftover data. if (tls_has_unprocessed_handshake_data(ssl)) { OPENSSL_PUT_ERROR(SSL, SSL_R_EXCESS_HANDSHAKE_DATA); ssl_send_alert(ssl, SSL3_AL_FATAL, SSL_AD_UNEXPECTED_MESSAGE); return false; } if (SSL_is_quic(ssl)) { if ((ssl->s3->hs == nullptr || !ssl->s3->hs->hints_requested) && !ssl->quic_method->set_read_secret(ssl, level, aead_ctx->cipher(), traffic_secret.data(), traffic_secret.size())) { return false; } // QUIC only uses |ssl| for handshake messages, which never use early data // keys, so we return without installing anything. This avoids needing to // have two secrets active at once in 0-RTT. if (level == ssl_encryption_early_data) { return true; } ssl->s3->quic_read_level = level; } ssl->s3->read_sequence = 0; ssl->s3->aead_read_ctx = std::move(aead_ctx); return true; } static bool tls_set_write_state(SSL *ssl, ssl_encryption_level_t level, UniquePtr aead_ctx, Span traffic_secret) { if (!tls_flush_pending_hs_data(ssl)) { return false; } if (SSL_is_quic(ssl)) { if ((ssl->s3->hs == nullptr || !ssl->s3->hs->hints_requested) && !ssl->quic_method->set_write_secret(ssl, level, aead_ctx->cipher(), traffic_secret.data(), traffic_secret.size())) { return false; } // QUIC only uses |ssl| for handshake messages, which never use early data // keys, so we return without installing anything. This avoids needing to // have two secrets active at once in 0-RTT. if (level == ssl_encryption_early_data) { return true; } ssl->s3->quic_write_level = level; } ssl->s3->write_sequence = 0; ssl->s3->aead_write_ctx = std::move(aead_ctx); return true; } static void tls_finish_flight(SSL *ssl) { // We don't track whether a flight is complete in TLS and instead always flush // every queued message in |tls_flush|, whether the flight is complete or not. } static void tls_schedule_ack(SSL *ssl) { // TLS does not use ACKs. } static const SSL_PROTOCOL_METHOD kTLSProtocolMethod = { false /* is_dtls */, tls_new, tls_free, tls_get_message, tls_next_message, tls_has_unprocessed_handshake_data, tls_open_handshake, tls_open_change_cipher_spec, tls_open_app_data, tls_write_app_data, tls_dispatch_alert, tls_init_message, tls_finish_message, tls_add_message, tls_add_change_cipher_spec, tls_finish_flight, tls_schedule_ack, tls_flush, tls_on_handshake_complete, tls_set_read_state, tls_set_write_state, }; static bool ssl_noop_x509_check_client_CA_names( STACK_OF(CRYPTO_BUFFER) *names) { return true; } static void ssl_noop_x509_clear(CERT *cert) {} static void ssl_noop_x509_free(CERT *cert) {} static void ssl_noop_x509_dup(CERT *new_cert, const CERT *cert) {} static void ssl_noop_x509_flush_cached_leaf(CERT *cert) {} static void ssl_noop_x509_flush_cached_chain(CERT *cert) {} static bool ssl_noop_x509_session_cache_objects(SSL_SESSION *sess) { return true; } static bool ssl_noop_x509_session_dup(SSL_SESSION *new_session, const SSL_SESSION *session) { return true; } static void ssl_noop_x509_session_clear(SSL_SESSION *session) {} static bool ssl_noop_x509_session_verify_cert_chain(SSL_SESSION *session, SSL_HANDSHAKE *hs, uint8_t *out_alert) { return false; } static void ssl_noop_x509_hs_flush_cached_ca_names(SSL_HANDSHAKE *hs) {} static bool ssl_noop_x509_ssl_new(SSL_HANDSHAKE *hs) { return true; } static void ssl_noop_x509_ssl_config_free(SSL_CONFIG *cfg) {} static void ssl_noop_x509_ssl_flush_cached_client_CA(SSL_CONFIG *cfg) {} static bool ssl_noop_x509_ssl_auto_chain_if_needed(SSL_HANDSHAKE *hs) { return true; } static bool ssl_noop_x509_ssl_ctx_new(SSL_CTX *ctx) { return true; } static void ssl_noop_x509_ssl_ctx_free(SSL_CTX *ctx) {} static void ssl_noop_x509_ssl_ctx_flush_cached_client_CA(SSL_CTX *ctx) {} const SSL_X509_METHOD ssl_noop_x509_method = { ssl_noop_x509_check_client_CA_names, ssl_noop_x509_clear, ssl_noop_x509_free, ssl_noop_x509_dup, ssl_noop_x509_flush_cached_chain, ssl_noop_x509_flush_cached_leaf, ssl_noop_x509_session_cache_objects, ssl_noop_x509_session_dup, ssl_noop_x509_session_clear, ssl_noop_x509_session_verify_cert_chain, ssl_noop_x509_hs_flush_cached_ca_names, ssl_noop_x509_ssl_new, ssl_noop_x509_ssl_config_free, ssl_noop_x509_ssl_flush_cached_client_CA, ssl_noop_x509_ssl_auto_chain_if_needed, ssl_noop_x509_ssl_ctx_new, ssl_noop_x509_ssl_ctx_free, ssl_noop_x509_ssl_ctx_flush_cached_client_CA, }; BSSL_NAMESPACE_END using namespace bssl; const SSL_METHOD *TLS_method(void) { static const SSL_METHOD kMethod = { 0, &kTLSProtocolMethod, &ssl_crypto_x509_method, }; return &kMethod; } const SSL_METHOD *SSLv23_method(void) { return TLS_method(); } const SSL_METHOD *TLS_with_buffers_method(void) { static const SSL_METHOD kMethod = { 0, &kTLSProtocolMethod, &ssl_noop_x509_method, }; return &kMethod; } // Legacy version-locked methods. const SSL_METHOD *TLSv1_2_method(void) { static const SSL_METHOD kMethod = { TLS1_2_VERSION, &kTLSProtocolMethod, &ssl_crypto_x509_method, }; return &kMethod; } const SSL_METHOD *TLSv1_1_method(void) { static const SSL_METHOD kMethod = { TLS1_1_VERSION, &kTLSProtocolMethod, &ssl_crypto_x509_method, }; return &kMethod; } const SSL_METHOD *TLSv1_method(void) { static const SSL_METHOD kMethod = { TLS1_VERSION, &kTLSProtocolMethod, &ssl_crypto_x509_method, }; return &kMethod; } // Legacy side-specific methods. const SSL_METHOD *TLSv1_2_server_method(void) { return TLSv1_2_method(); } const SSL_METHOD *TLSv1_1_server_method(void) { return TLSv1_1_method(); } const SSL_METHOD *TLSv1_server_method(void) { return TLSv1_method(); } const SSL_METHOD *TLSv1_2_client_method(void) { return TLSv1_2_method(); } const SSL_METHOD *TLSv1_1_client_method(void) { return TLSv1_1_method(); } const SSL_METHOD *TLSv1_client_method(void) { return TLSv1_method(); } const SSL_METHOD *SSLv23_server_method(void) { return SSLv23_method(); } const SSL_METHOD *SSLv23_client_method(void) { return SSLv23_method(); } const SSL_METHOD *TLS_server_method(void) { return TLS_method(); } const SSL_METHOD *TLS_client_method(void) { return TLS_method(); }