// Copyright 2016 The BoringSSL Authors // // 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 #include #include #include #include #include #include #include #include #include #include "../crypto/fipsmodule/tls/internal.h" #include "../crypto/internal.h" #include "internal.h" BSSL_NAMESPACE_BEGIN static bool init_key_schedule(SSL_HANDSHAKE *hs, SSLTranscript *transcript, uint16_t version, const SSL_CIPHER *cipher) { if (!transcript->InitHash(version, cipher)) { return false; } // Initialize the secret to the zero key. hs->secret.clear(); hs->secret.Resize(transcript->DigestLen()); return true; } static bool hkdf_extract_to_secret(SSL_HANDSHAKE *hs, const SSLTranscript &transcript, Span in) { size_t len; if (!HKDF_extract(hs->secret.data(), &len, transcript.Digest(), in.data(), in.size(), hs->secret.data(), hs->secret.size())) { return false; } assert(len == hs->secret.size()); return true; } bool tls13_init_key_schedule(SSL_HANDSHAKE *hs, Span psk) { if (!init_key_schedule(hs, &hs->transcript, ssl_protocol_version(hs->ssl), hs->new_cipher)) { return false; } // Handback includes the whole handshake transcript, so we cannot free the // transcript buffer in the handback case. if (!hs->handback) { hs->transcript.FreeBuffer(); } return hkdf_extract_to_secret(hs, hs->transcript, psk); } bool tls13_init_early_key_schedule(SSL_HANDSHAKE *hs, const SSL_SESSION *session) { assert(!hs->ssl->server); // When offering ECH, early data is associated with ClientHelloInner, not // ClientHelloOuter. SSLTranscript *transcript = hs->selected_ech_config ? &hs->inner_transcript : &hs->transcript; return init_key_schedule(hs, transcript, ssl_session_protocol_version(session), session->cipher) && hkdf_extract_to_secret(hs, *transcript, session->secret); } static bool hkdf_expand_label_with_prefix(Span out, const EVP_MD *digest, Span secret, std::string_view label_prefix, std::string_view label, Span hash) { // This is a copy of CRYPTO_tls13_hkdf_expand_label, but modified to take an // arbitrary prefix for the label instead of using the hardcoded "tls13 " // prefix. CBB cbb, child; uint8_t *hkdf_label = NULL; size_t hkdf_label_len; CBB_zero(&cbb); if (!CBB_init(&cbb, 2 + 1 + label_prefix.size() + label.size() + 1 + hash.size()) || !CBB_add_u16(&cbb, out.size()) || !CBB_add_u8_length_prefixed(&cbb, &child) || !CBB_add_bytes(&child, reinterpret_cast(label_prefix.data()), label_prefix.size()) || !CBB_add_bytes(&child, reinterpret_cast(label.data()), label.size()) || !CBB_add_u8_length_prefixed(&cbb, &child) || !CBB_add_bytes(&child, hash.data(), hash.size()) || !CBB_finish(&cbb, &hkdf_label, &hkdf_label_len)) { CBB_cleanup(&cbb); return false; } const int ret = HKDF_expand(out.data(), out.size(), digest, secret.data(), secret.size(), hkdf_label, hkdf_label_len); OPENSSL_free(hkdf_label); return ret == 1; } static bool hkdf_expand_label(Span out, const EVP_MD *digest, Span secret, std::string_view label, Span hash, bool is_dtls) { if (is_dtls) { return hkdf_expand_label_with_prefix(out, digest, secret, "dtls13", label, hash); } return CRYPTO_tls13_hkdf_expand_label( out.data(), out.size(), digest, secret.data(), secret.size(), reinterpret_cast(label.data()), label.size(), hash.data(), hash.size()) == 1; } static const char kTLS13LabelDerived[] = "derived"; bool tls13_advance_key_schedule(SSL_HANDSHAKE *hs, Span in) { uint8_t derive_context[EVP_MAX_MD_SIZE]; unsigned derive_context_len; return EVP_Digest(nullptr, 0, derive_context, &derive_context_len, hs->transcript.Digest(), nullptr) && hkdf_expand_label(Span(hs->secret), hs->transcript.Digest(), hs->secret, kTLS13LabelDerived, Span(derive_context, derive_context_len), SSL_is_dtls(hs->ssl)) && hkdf_extract_to_secret(hs, hs->transcript, in); } // derive_secret_with_transcript derives a secret of length // |transcript.DigestLen()| and writes the result in |out| with the given label, // the current base secret, and the state of |transcript|. It returns true on // success and false on error. static bool derive_secret_with_transcript( const SSL_HANDSHAKE *hs, InplaceVector *out, const SSLTranscript &transcript, std::string_view label) { uint8_t context_hash[EVP_MAX_MD_SIZE]; size_t context_hash_len; if (!transcript.GetHash(context_hash, &context_hash_len)) { return false; } out->ResizeForOverwrite(transcript.DigestLen()); return hkdf_expand_label(Span(*out), transcript.Digest(), hs->secret, label, Span(context_hash, context_hash_len), SSL_is_dtls(hs->ssl)); } static bool derive_secret(SSL_HANDSHAKE *hs, InplaceVector *out, std::string_view label) { return derive_secret_with_transcript(hs, out, hs->transcript, label); } bool tls13_set_traffic_key(SSL *ssl, enum ssl_encryption_level_t level, enum evp_aead_direction_t direction, const SSL_SESSION *session, Span traffic_secret) { uint16_t version = ssl_session_protocol_version(session); const EVP_MD *digest = ssl_session_get_digest(session); bool is_dtls = SSL_is_dtls(ssl); UniquePtr traffic_aead; if (SSL_is_quic(ssl)) { // Install a placeholder SSLAEADContext so that SSL accessors work. The // encryption itself will be handled by the SSL_QUIC_METHOD. traffic_aead = SSLAEADContext::CreatePlaceholderForQUIC(session->cipher); } else { // Look up cipher suite properties. const EVP_AEAD *aead; size_t discard; if (!ssl_cipher_get_evp_aead(&aead, &discard, &discard, session->cipher, version)) { return false; } // Derive the key and IV. uint8_t key_buf[EVP_AEAD_MAX_KEY_LENGTH], iv_buf[EVP_AEAD_MAX_NONCE_LENGTH]; auto key = Span(key_buf).first(EVP_AEAD_key_length(aead)); auto iv = Span(iv_buf).first(EVP_AEAD_nonce_length(aead)); if (!hkdf_expand_label(key, digest, traffic_secret, "key", {}, is_dtls) || !hkdf_expand_label(iv, digest, traffic_secret, "iv", {}, is_dtls)) { return false; } traffic_aead = SSLAEADContext::Create(direction, session->ssl_version, session->cipher, key, {}, iv); } if (!traffic_aead) { return false; } if (direction == evp_aead_open) { if (!ssl->method->set_read_state(ssl, level, std::move(traffic_aead), traffic_secret)) { return false; } ssl->s3->read_traffic_secret.CopyFrom(traffic_secret); } else { if (!ssl->method->set_write_state(ssl, level, std::move(traffic_aead), traffic_secret)) { return false; } ssl->s3->write_traffic_secret.CopyFrom(traffic_secret); } return true; } namespace { class AESRecordNumberEncrypter : public RecordNumberEncrypter { public: bool SetKey(Span key) override { return AES_set_encrypt_key(key.data(), key.size() * 8, &key_) == 0; } bool GenerateMask(Span out, Span sample) override { if (sample.size() < AES_BLOCK_SIZE || out.size() > AES_BLOCK_SIZE) { return false; } uint8_t mask[AES_BLOCK_SIZE]; AES_encrypt(sample.data(), mask, &key_); OPENSSL_memcpy(out.data(), mask, out.size()); return true; } private: AES_KEY key_; }; class AES128RecordNumberEncrypter : public AESRecordNumberEncrypter { public: size_t KeySize() override { return 16; } }; class AES256RecordNumberEncrypter : public AESRecordNumberEncrypter { public: size_t KeySize() override { return 32; } }; class ChaChaRecordNumberEncrypter : public RecordNumberEncrypter { public: size_t KeySize() override { return kKeySize; } bool SetKey(Span key) override { if (key.size() != kKeySize) { return false; } OPENSSL_memcpy(key_, key.data(), key.size()); return true; } bool GenerateMask(Span out, Span sample) override { // RFC 9147 section 4.2.3 uses the first 4 bytes of the sample as the // counter and the next 12 bytes as the nonce. If we have less than 4+12=16 // bytes in the sample, then we'll read past the end of the |sample| buffer. // The counter is interpreted as little-endian per RFC 8439. if (sample.size() < 16) { return false; } uint32_t counter = CRYPTO_load_u32_le(sample.data()); Span nonce = sample.subspan(4); OPENSSL_memset(out.data(), 0, out.size()); CRYPTO_chacha_20(out.data(), out.data(), out.size(), key_, nonce.data(), counter); return true; } private: static constexpr size_t kKeySize = 32; uint8_t key_[kKeySize]; }; class NullRecordNumberEncrypter : public RecordNumberEncrypter { public: size_t KeySize() override { return 0; } bool SetKey(Span key) override { return true; } bool GenerateMask(Span out, Span sample) override { OPENSSL_memset(out.data(), 0, out.size()); return true; } }; } // namespace UniquePtr RecordNumberEncrypter::Create( const SSL_CIPHER *cipher, Span traffic_secret) { const EVP_MD *digest = ssl_get_handshake_digest(TLS1_3_VERSION, cipher); UniquePtr ret; if (CRYPTO_fuzzer_mode_enabled()) { ret = MakeUnique(); } else if (cipher->algorithm_enc == SSL_AES128GCM) { ret = MakeUnique(); } else if (cipher->algorithm_enc == SSL_AES256GCM) { ret = MakeUnique(); } else if (cipher->algorithm_enc == SSL_CHACHA20POLY1305) { ret = MakeUnique(); } else { OPENSSL_PUT_ERROR(SSL, ERR_R_INTERNAL_ERROR); } if (ret == nullptr) { return nullptr; } uint8_t rne_key_buf[RecordNumberEncrypter::kMaxKeySize]; auto rne_key = Span(rne_key_buf).first(ret->KeySize()); if (!hkdf_expand_label(rne_key, digest, traffic_secret, "sn", {}, /*is_dtls=*/true) || !ret->SetKey(rne_key)) { return nullptr; } return ret; } static const char kTLS13LabelExporter[] = "exp master"; static const char kTLS13LabelClientEarlyTraffic[] = "c e traffic"; static const char kTLS13LabelClientHandshakeTraffic[] = "c hs traffic"; static const char kTLS13LabelServerHandshakeTraffic[] = "s hs traffic"; static const char kTLS13LabelClientApplicationTraffic[] = "c ap traffic"; static const char kTLS13LabelServerApplicationTraffic[] = "s ap traffic"; bool tls13_derive_early_secret(SSL_HANDSHAKE *hs) { SSL *const ssl = hs->ssl; // When offering ECH on the client, early data is associated with // ClientHelloInner, not ClientHelloOuter. const SSLTranscript &transcript = (!ssl->server && hs->selected_ech_config) ? hs->inner_transcript : hs->transcript; if (!derive_secret_with_transcript(hs, &hs->early_traffic_secret, transcript, kTLS13LabelClientEarlyTraffic) || !ssl_log_secret(ssl, "CLIENT_EARLY_TRAFFIC_SECRET", hs->early_traffic_secret)) { return false; } return true; } bool tls13_derive_handshake_secrets(SSL_HANDSHAKE *hs) { SSL *const ssl = hs->ssl; if (!derive_secret(hs, &hs->client_handshake_secret, kTLS13LabelClientHandshakeTraffic) || !ssl_log_secret(ssl, "CLIENT_HANDSHAKE_TRAFFIC_SECRET", hs->client_handshake_secret) || !derive_secret(hs, &hs->server_handshake_secret, kTLS13LabelServerHandshakeTraffic) || !ssl_log_secret(ssl, "SERVER_HANDSHAKE_TRAFFIC_SECRET", hs->server_handshake_secret)) { return false; } return true; } bool tls13_derive_application_secrets(SSL_HANDSHAKE *hs) { SSL *const ssl = hs->ssl; if (!derive_secret(hs, &hs->client_traffic_secret_0, kTLS13LabelClientApplicationTraffic) || !ssl_log_secret(ssl, "CLIENT_TRAFFIC_SECRET_0", hs->client_traffic_secret_0) || !derive_secret(hs, &hs->server_traffic_secret_0, kTLS13LabelServerApplicationTraffic) || !ssl_log_secret(ssl, "SERVER_TRAFFIC_SECRET_0", hs->server_traffic_secret_0) || !derive_secret(hs, &ssl->s3->exporter_secret, kTLS13LabelExporter) || !ssl_log_secret(ssl, "EXPORTER_SECRET", ssl->s3->exporter_secret)) { return false; } return true; } static const char kTLS13LabelApplicationTraffic[] = "traffic upd"; bool tls13_rotate_traffic_key(SSL *ssl, enum evp_aead_direction_t direction) { Span secret = direction == evp_aead_open ? Span(ssl->s3->read_traffic_secret) : Span(ssl->s3->write_traffic_secret); const SSL_SESSION *session = SSL_get_session(ssl); const EVP_MD *digest = ssl_session_get_digest(session); return hkdf_expand_label(secret, digest, secret, kTLS13LabelApplicationTraffic, {}, SSL_is_dtls(ssl)) && tls13_set_traffic_key(ssl, ssl_encryption_application, direction, session, secret); } static const char kTLS13LabelResumption[] = "res master"; bool tls13_derive_resumption_secret(SSL_HANDSHAKE *hs) { return derive_secret(hs, &hs->new_session->secret, kTLS13LabelResumption); } static const char kTLS13LabelFinished[] = "finished"; // tls13_verify_data sets |out| to be the HMAC of |context| using a derived // Finished key for both Finished messages and the PSK binder. |out| must have // space available for |EVP_MAX_MD_SIZE| bytes. static bool tls13_verify_data(uint8_t *out, size_t *out_len, const EVP_MD *digest, uint16_t version, Span secret, Span context, bool is_dtls) { uint8_t key_buf[EVP_MAX_MD_SIZE]; auto key = Span(key_buf, EVP_MD_size(digest)); unsigned len; if (!hkdf_expand_label(key, digest, secret, kTLS13LabelFinished, {}, is_dtls) || HMAC(digest, key.data(), key.size(), context.data(), context.size(), out, &len) == nullptr) { return false; } *out_len = len; return true; } bool tls13_finished_mac(SSL_HANDSHAKE *hs, uint8_t *out, size_t *out_len, bool is_server) { Span traffic_secret = is_server ? hs->server_handshake_secret : hs->client_handshake_secret; uint8_t context_hash[EVP_MAX_MD_SIZE]; size_t context_hash_len; if (!hs->transcript.GetHash(context_hash, &context_hash_len) || !tls13_verify_data(out, out_len, hs->transcript.Digest(), hs->ssl->s3->version, traffic_secret, Span(context_hash, context_hash_len), SSL_is_dtls(hs->ssl))) { return false; } return true; } static const char kTLS13LabelResumptionPSK[] = "resumption"; bool tls13_derive_session_psk(SSL_SESSION *session, Span nonce, bool is_dtls) { const EVP_MD *digest = ssl_session_get_digest(session); // The session initially stores the resumption_master_secret, which we // override with the PSK. assert(session->secret.size() == EVP_MD_size(digest)); return hkdf_expand_label(Span(session->secret), digest, session->secret, kTLS13LabelResumptionPSK, nonce, is_dtls); } static const char kTLS13LabelExportKeying[] = "exporter"; bool tls13_export_keying_material(const SSL *ssl, Span out, Span secret, std::string_view label, Span context) { if (secret.empty()) { assert(0); OPENSSL_PUT_ERROR(SSL, ERR_R_INTERNAL_ERROR); return false; } const EVP_MD *digest = ssl_session_get_digest(SSL_get_session(ssl)); uint8_t hash_buf[EVP_MAX_MD_SIZE]; uint8_t export_context_buf[EVP_MAX_MD_SIZE]; unsigned hash_len; unsigned export_context_len; if (!EVP_Digest(context.data(), context.size(), hash_buf, &hash_len, digest, nullptr) || !EVP_Digest(nullptr, 0, export_context_buf, &export_context_len, digest, nullptr)) { return false; } auto hash = Span(hash_buf, hash_len); auto export_context = Span(export_context_buf, export_context_len); uint8_t derived_secret_buf[EVP_MAX_MD_SIZE]; auto derived_secret = Span(derived_secret_buf, EVP_MD_size(digest)); return hkdf_expand_label(derived_secret, digest, secret, label, export_context, SSL_is_dtls(ssl)) && hkdf_expand_label(out, digest, derived_secret, kTLS13LabelExportKeying, hash, SSL_is_dtls(ssl)); } static const char kTLS13LabelPSKBinder[] = "res binder"; static bool tls13_psk_binder(uint8_t *out, size_t *out_len, const SSL_SESSION *session, const SSLTranscript &transcript, Span client_hello, size_t binders_len, bool is_dtls) { const EVP_MD *digest = ssl_session_get_digest(session); // Compute the binder key. // // TODO(davidben): Ideally we wouldn't recompute early secret and the binder // key each time. uint8_t binder_context[EVP_MAX_MD_SIZE]; unsigned binder_context_len; uint8_t early_secret[EVP_MAX_MD_SIZE] = {0}; size_t early_secret_len; uint8_t binder_key_buf[EVP_MAX_MD_SIZE] = {0}; auto binder_key = Span(binder_key_buf, EVP_MD_size(digest)); if (!EVP_Digest(nullptr, 0, binder_context, &binder_context_len, digest, nullptr) || !HKDF_extract(early_secret, &early_secret_len, digest, session->secret.data(), session->secret.size(), nullptr, 0) || !hkdf_expand_label(binder_key, digest, Span(early_secret, early_secret_len), kTLS13LabelPSKBinder, Span(binder_context, binder_context_len), is_dtls)) { return false; } // Hash the transcript and truncated ClientHello. if (client_hello.size() < binders_len) { OPENSSL_PUT_ERROR(SSL, ERR_R_INTERNAL_ERROR); return false; } auto truncated = client_hello.subspan(0, client_hello.size() - binders_len); uint8_t context[EVP_MAX_MD_SIZE]; unsigned context_len; ScopedEVP_MD_CTX ctx; if (!is_dtls) { if (!transcript.CopyToHashContext(ctx.get(), digest) || !EVP_DigestUpdate(ctx.get(), truncated.data(), truncated.size()) || !EVP_DigestFinal_ex(ctx.get(), context, &context_len)) { return false; } } else { // In DTLS 1.3, the transcript hash is computed over only the TLS 1.3 // handshake messages (i.e. only type and length in the header), not the // full DTLSHandshake messages that are in |truncated|. This code pulls // the header and body out of the truncated ClientHello and writes those // to the hash context so the correct binder value is computed. if (truncated.size() < DTLS1_HM_HEADER_LENGTH) { return false; } auto header = truncated.subspan(0, 4); auto body = truncated.subspan(12); if (!transcript.CopyToHashContext(ctx.get(), digest) || !EVP_DigestUpdate(ctx.get(), header.data(), header.size()) || !EVP_DigestUpdate(ctx.get(), body.data(), body.size()) || !EVP_DigestFinal_ex(ctx.get(), context, &context_len)) { return false; } } if (!tls13_verify_data(out, out_len, digest, session->ssl_version, binder_key, Span(context, context_len), is_dtls)) { return false; } assert(*out_len == EVP_MD_size(digest)); return true; } bool tls13_write_psk_binder(const SSL_HANDSHAKE *hs, const SSLTranscript &transcript, Span msg, size_t *out_binder_len) { const SSL *const ssl = hs->ssl; const EVP_MD *digest = ssl_session_get_digest(ssl->session.get()); const size_t hash_len = EVP_MD_size(digest); // We only offer one PSK, so the binders are a u16 and u8 length // prefix, followed by the binder. The caller is assumed to have constructed // |msg| with placeholder binders. const size_t binders_len = 3 + hash_len; uint8_t verify_data[EVP_MAX_MD_SIZE]; size_t verify_data_len; if (!tls13_psk_binder(verify_data, &verify_data_len, ssl->session.get(), transcript, msg, binders_len, SSL_is_dtls(hs->ssl)) || verify_data_len != hash_len) { OPENSSL_PUT_ERROR(SSL, ERR_R_INTERNAL_ERROR); return false; } auto msg_binder = msg.last(verify_data_len); OPENSSL_memcpy(msg_binder.data(), verify_data, verify_data_len); if (out_binder_len != nullptr) { *out_binder_len = verify_data_len; } return true; } bool tls13_verify_psk_binder(const SSL_HANDSHAKE *hs, const SSL_SESSION *session, const SSLMessage &msg, CBS *binders) { uint8_t verify_data[EVP_MAX_MD_SIZE]; size_t verify_data_len; CBS binder; // The binders are computed over |msg| with |binders| and its u16 length // prefix removed. The caller is assumed to have parsed |msg|, extracted // |binders|, and verified the PSK extension is last. if (!tls13_psk_binder(verify_data, &verify_data_len, session, hs->transcript, msg.raw, 2 + CBS_len(binders), SSL_is_dtls(hs->ssl)) || // We only consider the first PSK, so compare against the first binder. !CBS_get_u8_length_prefixed(binders, &binder)) { OPENSSL_PUT_ERROR(SSL, ERR_R_INTERNAL_ERROR); return false; } bool binder_ok = CBS_len(&binder) == verify_data_len && CRYPTO_memcmp(CBS_data(&binder), verify_data, verify_data_len) == 0; if (CRYPTO_fuzzer_mode_enabled()) { binder_ok = true; } if (!binder_ok) { OPENSSL_PUT_ERROR(SSL, SSL_R_DIGEST_CHECK_FAILED); return false; } return true; } size_t ssl_ech_confirmation_signal_hello_offset(const SSL *ssl) { static_assert(ECH_CONFIRMATION_SIGNAL_LEN < SSL3_RANDOM_SIZE, "the confirmation signal is a suffix of the random"); const size_t header_len = SSL_is_dtls(ssl) ? DTLS1_HM_HEADER_LENGTH : SSL3_HM_HEADER_LENGTH; return header_len + 2 /* version */ + SSL3_RANDOM_SIZE - ECH_CONFIRMATION_SIGNAL_LEN; } bool ssl_ech_accept_confirmation(const SSL_HANDSHAKE *hs, Span out, Span client_random, const SSLTranscript &transcript, bool is_hrr, Span msg, size_t offset) { // See draft-ietf-tls-esni-13, sections 7.2 and 7.2.1. static const uint8_t kZeros[EVP_MAX_MD_SIZE] = {0}; // We hash |msg|, with bytes from |offset| zeroed. if (msg.size() < offset + ECH_CONFIRMATION_SIGNAL_LEN) { OPENSSL_PUT_ERROR(SSL, ERR_R_INTERNAL_ERROR); return false; } // We represent DTLS messages with the longer DTLS 1.2 header, but DTLS 1.3 // removes the extra fields from the transcript. auto header = msg.subspan(0, SSL3_HM_HEADER_LENGTH); size_t full_header_len = SSL_is_dtls(hs->ssl) ? DTLS1_HM_HEADER_LENGTH : SSL3_HM_HEADER_LENGTH; auto before_zeros = msg.subspan(full_header_len, offset - full_header_len); auto after_zeros = msg.subspan(offset + ECH_CONFIRMATION_SIGNAL_LEN); uint8_t context[EVP_MAX_MD_SIZE]; unsigned context_len; ScopedEVP_MD_CTX ctx; if (!transcript.CopyToHashContext(ctx.get(), transcript.Digest()) || !EVP_DigestUpdate(ctx.get(), header.data(), header.size()) || !EVP_DigestUpdate(ctx.get(), before_zeros.data(), before_zeros.size()) || !EVP_DigestUpdate(ctx.get(), kZeros, ECH_CONFIRMATION_SIGNAL_LEN) || !EVP_DigestUpdate(ctx.get(), after_zeros.data(), after_zeros.size()) || !EVP_DigestFinal_ex(ctx.get(), context, &context_len)) { return false; } uint8_t secret[EVP_MAX_MD_SIZE]; size_t secret_len; if (!HKDF_extract(secret, &secret_len, transcript.Digest(), client_random.data(), client_random.size(), kZeros, transcript.DigestLen())) { return false; } assert(out.size() == ECH_CONFIRMATION_SIGNAL_LEN); return hkdf_expand_label( out, transcript.Digest(), Span(secret, secret_len), is_hrr ? "hrr ech accept confirmation" : "ech accept confirmation", Span(context, context_len), SSL_is_dtls(hs->ssl)); } BSSL_NAMESPACE_END