/* * nghttp2 - HTTP/2 C Library * * Copyright (c) 2021 Tatsuhiro Tsujikawa * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE * LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION * OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION * WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include "shrpx_http3_upstream.h" #include #include #include #include #include #include #include "shrpx_client_handler.h" #include "shrpx_downstream.h" #include "shrpx_downstream_connection.h" #include "shrpx_log.h" #include "shrpx_quic.h" #include "shrpx_worker.h" #include "shrpx_http.h" #include "shrpx_connection_handler.h" #ifdef HAVE_MRUBY # include "shrpx_mruby.h" #endif // HAVE_MRUBY #include "http3.h" #include "util.h" namespace shrpx { namespace { void timeoutcb(struct ev_loop *loop, ev_timer *w, int revents) { auto upstream = static_cast(w->data); if (upstream->handle_expiry() != 0 || upstream->on_write() != 0) { goto fail; } return; fail: auto handler = upstream->get_client_handler(); delete handler; } } // namespace namespace { void shutdown_timeout_cb(struct ev_loop *loop, ev_timer *w, int revents) { auto upstream = static_cast(w->data); auto handler = upstream->get_client_handler(); if (upstream->submit_goaway() != 0) { delete handler; } } } // namespace namespace { void prepare_cb(struct ev_loop *loop, ev_prepare *w, int revent) { auto upstream = static_cast(w->data); auto handler = upstream->get_client_handler(); if (upstream->check_shutdown() != 0) { delete handler; } } } // namespace namespace { size_t downstream_queue_size(Worker *worker) { auto &downstreamconf = *worker->get_downstream_config(); if (get_config()->http2_proxy) { return downstreamconf.connections_per_host; } return downstreamconf.connections_per_frontend; } } // namespace namespace { ngtcp2_conn *get_conn(ngtcp2_crypto_conn_ref *conn_ref) { auto conn = static_cast(conn_ref->user_data); auto handler = static_cast(conn->data); auto upstream = static_cast(handler->get_upstream()); return upstream->get_conn(); } } // namespace Http3Upstream::Http3Upstream(ClientHandler *handler) : handler_{handler}, qlog_fd_{-1}, hashed_scid_{}, conn_{nullptr}, httpconn_{nullptr}, downstream_queue_{downstream_queue_size(handler->get_worker()), !get_config()->http2_proxy}, retry_close_{false}, tx_{ .data = std::unique_ptr(new uint8_t[64_k]), } { auto conn = handler_->get_connection(); conn->conn_ref.get_conn = shrpx::get_conn; ev_timer_init(&timer_, timeoutcb, 0., 0.); timer_.data = this; ngtcp2_connection_close_error_default(&last_error_); ev_timer_init(&shutdown_timer_, shutdown_timeout_cb, 0., 0.); shutdown_timer_.data = this; ev_prepare_init(&prep_, prepare_cb); prep_.data = this; ev_prepare_start(handler_->get_loop(), &prep_); } Http3Upstream::~Http3Upstream() { auto loop = handler_->get_loop(); ev_prepare_stop(loop, &prep_); ev_timer_stop(loop, &shutdown_timer_); ev_timer_stop(loop, &timer_); nghttp3_conn_del(httpconn_); ngtcp2_conn_del(conn_); if (qlog_fd_ != -1) { close(qlog_fd_); } } namespace { void log_printf(void *user_data, const char *fmt, ...) { va_list ap; std::array buf; va_start(ap, fmt); auto nwrite = vsnprintf(buf.data(), buf.size(), fmt, ap); va_end(ap); if (static_cast(nwrite) >= buf.size()) { nwrite = buf.size() - 1; } buf[nwrite++] = '\n'; while (write(fileno(stderr), buf.data(), nwrite) == -1 && errno == EINTR) ; } } // namespace namespace { void qlog_write(void *user_data, uint32_t flags, const void *data, size_t datalen) { auto upstream = static_cast(user_data); upstream->qlog_write(data, datalen, flags & NGTCP2_QLOG_WRITE_FLAG_FIN); } } // namespace void Http3Upstream::qlog_write(const void *data, size_t datalen, bool fin) { assert(qlog_fd_ != -1); while (write(qlog_fd_, data, datalen) == -1 && errno == EINTR) ; if (fin) { close(qlog_fd_); qlog_fd_ = -1; } } namespace { void rand(uint8_t *dest, size_t destlen, const ngtcp2_rand_ctx *rand_ctx) { util::random_bytes(dest, dest + destlen, *static_cast(rand_ctx->native_handle)); } } // namespace namespace { int get_new_connection_id(ngtcp2_conn *conn, ngtcp2_cid *cid, uint8_t *token, size_t cidlen, void *user_data) { auto upstream = static_cast(user_data); auto handler = upstream->get_client_handler(); auto worker = handler->get_worker(); auto conn_handler = worker->get_connection_handler(); auto &qkms = conn_handler->get_quic_keying_materials(); auto &qkm = qkms->keying_materials.front(); if (generate_quic_connection_id(*cid, cidlen, worker->get_cid_prefix(), qkm.id, qkm.cid_encryption_key.data()) != 0) { return NGTCP2_ERR_CALLBACK_FAILURE; } if (generate_quic_stateless_reset_token(token, *cid, qkm.secret.data(), qkm.secret.size()) != 0) { return NGTCP2_ERR_CALLBACK_FAILURE; } auto quic_connection_handler = worker->get_quic_connection_handler(); quic_connection_handler->add_connection_id(*cid, handler); return 0; } } // namespace namespace { int remove_connection_id(ngtcp2_conn *conn, const ngtcp2_cid *cid, void *user_data) { auto upstream = static_cast(user_data); auto handler = upstream->get_client_handler(); auto worker = handler->get_worker(); auto quic_conn_handler = worker->get_quic_connection_handler(); quic_conn_handler->remove_connection_id(*cid); return 0; } } // namespace void Http3Upstream::http_begin_request_headers(int64_t stream_id) { auto downstream = std::make_unique(this, handler_->get_mcpool(), stream_id); nghttp3_conn_set_stream_user_data(httpconn_, stream_id, downstream.get()); downstream->reset_upstream_rtimer(); handler_->repeat_read_timer(); auto &req = downstream->request(); req.http_major = 3; req.http_minor = 0; add_pending_downstream(std::move(downstream)); } void Http3Upstream::add_pending_downstream( std::unique_ptr downstream) { downstream_queue_.add_pending(std::move(downstream)); } namespace { int recv_stream_data(ngtcp2_conn *conn, uint32_t flags, int64_t stream_id, uint64_t offset, const uint8_t *data, size_t datalen, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); if (upstream->recv_stream_data(flags, stream_id, data, datalen) != 0) { return NGTCP2_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::recv_stream_data(uint32_t flags, int64_t stream_id, const uint8_t *data, size_t datalen) { assert(httpconn_); auto nconsumed = nghttp3_conn_read_stream( httpconn_, stream_id, data, datalen, flags & NGTCP2_STREAM_DATA_FLAG_FIN); if (nconsumed < 0) { ULOG(ERROR, this) << "nghttp3_conn_read_stream: " << nghttp3_strerror(nconsumed); ngtcp2_connection_close_error_set_application_error( &last_error_, nghttp3_err_infer_quic_app_error_code(nconsumed), nullptr, 0); return -1; } ngtcp2_conn_extend_max_stream_offset(conn_, stream_id, nconsumed); ngtcp2_conn_extend_max_offset(conn_, nconsumed); return 0; } namespace { int stream_close(ngtcp2_conn *conn, uint32_t flags, int64_t stream_id, uint64_t app_error_code, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); if (!(flags & NGTCP2_STREAM_CLOSE_FLAG_APP_ERROR_CODE_SET)) { app_error_code = NGHTTP3_H3_NO_ERROR; } if (upstream->stream_close(stream_id, app_error_code) != 0) { return NGTCP2_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::stream_close(int64_t stream_id, uint64_t app_error_code) { if (!httpconn_) { return 0; } auto rv = nghttp3_conn_close_stream(httpconn_, stream_id, app_error_code); switch (rv) { case 0: break; case NGHTTP3_ERR_STREAM_NOT_FOUND: if (ngtcp2_is_bidi_stream(stream_id)) { ngtcp2_conn_extend_max_streams_bidi(conn_, 1); } break; default: ULOG(ERROR, this) << "nghttp3_conn_close_stream: " << nghttp3_strerror(rv); ngtcp2_connection_close_error_set_application_error( &last_error_, nghttp3_err_infer_quic_app_error_code(rv), nullptr, 0); return -1; } return 0; } namespace { int acked_stream_data_offset(ngtcp2_conn *conn, int64_t stream_id, uint64_t offset, uint64_t datalen, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); if (upstream->acked_stream_data_offset(stream_id, datalen) != 0) { return NGTCP2_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::acked_stream_data_offset(int64_t stream_id, uint64_t datalen) { if (!httpconn_) { return 0; } auto rv = nghttp3_conn_add_ack_offset(httpconn_, stream_id, datalen); if (rv != 0) { ULOG(ERROR, this) << "nghttp3_conn_add_ack_offset: " << nghttp3_strerror(rv); return -1; } return 0; } namespace { int extend_max_stream_data(ngtcp2_conn *conn, int64_t stream_id, uint64_t max_data, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); if (upstream->extend_max_stream_data(stream_id) != 0) { return NGTCP2_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::extend_max_stream_data(int64_t stream_id) { if (!httpconn_) { return 0; } auto rv = nghttp3_conn_unblock_stream(httpconn_, stream_id); if (rv != 0) { ULOG(ERROR, this) << "nghttp3_conn_unblock_stream: " << nghttp3_strerror(rv); return -1; } return 0; } namespace { int extend_max_remote_streams_bidi(ngtcp2_conn *conn, uint64_t max_streams, void *user_data) { auto upstream = static_cast(user_data); upstream->extend_max_remote_streams_bidi(max_streams); return 0; } } // namespace void Http3Upstream::extend_max_remote_streams_bidi(uint64_t max_streams) { nghttp3_conn_set_max_client_streams_bidi(httpconn_, max_streams); } namespace { int stream_reset(ngtcp2_conn *conn, int64_t stream_id, uint64_t final_size, uint64_t app_error_code, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); if (upstream->http_shutdown_stream_read(stream_id) != 0) { return NGTCP2_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::http_shutdown_stream_read(int64_t stream_id) { if (!httpconn_) { return 0; } auto rv = nghttp3_conn_shutdown_stream_read(httpconn_, stream_id); if (rv != 0) { ULOG(ERROR, this) << "nghttp3_conn_shutdown_stream_read: " << nghttp3_strerror(rv); return -1; } return 0; } namespace { int stream_stop_sending(ngtcp2_conn *conn, int64_t stream_id, uint64_t app_error_code, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); if (upstream->http_shutdown_stream_read(stream_id) != 0) { return NGTCP2_ERR_CALLBACK_FAILURE; } return 0; } } // namespace namespace { int handshake_completed(ngtcp2_conn *conn, void *user_data) { auto upstream = static_cast(user_data); if (upstream->handshake_completed() != 0) { return NGTCP2_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::handshake_completed() { handler_->set_alpn_from_conn(); auto alpn = handler_->get_alpn(); if (alpn.empty()) { ULOG(ERROR, this) << "NO ALPN was negotiated"; return -1; } std::array token; size_t tokenlen; auto path = ngtcp2_conn_get_path(conn_); auto worker = handler_->get_worker(); auto conn_handler = worker->get_connection_handler(); auto &qkms = conn_handler->get_quic_keying_materials(); auto &qkm = qkms->keying_materials.front(); if (generate_token(token.data(), tokenlen, path->remote.addr, path->remote.addrlen, qkm.secret.data(), qkm.secret.size()) != 0) { return 0; } assert(tokenlen == NGTCP2_CRYPTO_MAX_REGULAR_TOKENLEN); token[tokenlen++] = qkm.id; auto rv = ngtcp2_conn_submit_new_token(conn_, token.data(), tokenlen); if (rv != 0) { ULOG(ERROR, this) << "ngtcp2_conn_submit_new_token: " << ngtcp2_strerror(rv); return -1; } return 0; } namespace { int recv_tx_key(ngtcp2_conn *conn, ngtcp2_crypto_level level, void *user_data) { if (level != NGTCP2_CRYPTO_LEVEL_APPLICATION) { return 0; } auto upstream = static_cast(user_data); if (upstream->setup_httpconn() != 0) { return NGTCP2_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::init(const UpstreamAddr *faddr, const Address &remote_addr, const Address &local_addr, const ngtcp2_pkt_hd &initial_hd, const ngtcp2_cid *odcid, const uint8_t *token, size_t tokenlen) { int rv; auto worker = handler_->get_worker(); auto conn_handler = worker->get_connection_handler(); auto callbacks = ngtcp2_callbacks{ nullptr, // client_initial ngtcp2_crypto_recv_client_initial_cb, ngtcp2_crypto_recv_crypto_data_cb, shrpx::handshake_completed, nullptr, // recv_version_negotiation ngtcp2_crypto_encrypt_cb, ngtcp2_crypto_decrypt_cb, ngtcp2_crypto_hp_mask_cb, shrpx::recv_stream_data, shrpx::acked_stream_data_offset, nullptr, // stream_open shrpx::stream_close, nullptr, // recv_stateless_reset nullptr, // recv_retry nullptr, // extend_max_local_streams_bidi nullptr, // extend_max_local_streams_uni rand, get_new_connection_id, remove_connection_id, ngtcp2_crypto_update_key_cb, nullptr, // path_validation nullptr, // select_preferred_addr shrpx::stream_reset, shrpx::extend_max_remote_streams_bidi, nullptr, // extend_max_remote_streams_uni shrpx::extend_max_stream_data, nullptr, // dcid_status nullptr, // handshake_confirmed nullptr, // recv_new_token ngtcp2_crypto_delete_crypto_aead_ctx_cb, ngtcp2_crypto_delete_crypto_cipher_ctx_cb, nullptr, // recv_datagram nullptr, // ack_datagram nullptr, // lost_datagram ngtcp2_crypto_get_path_challenge_data_cb, shrpx::stream_stop_sending, nullptr, // version_negotiation nullptr, // recv_rx_key shrpx::recv_tx_key, }; auto config = get_config(); auto &quicconf = config->quic; auto &http3conf = config->http3; auto &qkms = conn_handler->get_quic_keying_materials(); auto &qkm = qkms->keying_materials.front(); ngtcp2_cid scid; if (generate_quic_connection_id(scid, SHRPX_QUIC_SCIDLEN, worker->get_cid_prefix(), qkm.id, qkm.cid_encryption_key.data()) != 0) { return -1; } ngtcp2_settings settings; ngtcp2_settings_default(&settings); if (quicconf.upstream.debug.log) { settings.log_printf = log_printf; } if (!quicconf.upstream.qlog.dir.empty()) { auto fd = open_qlog_file(quicconf.upstream.qlog.dir, scid); if (fd != -1) { qlog_fd_ = fd; settings.qlog.odcid = initial_hd.dcid; settings.qlog.write = shrpx::qlog_write; } } settings.initial_ts = quic_timestamp(); settings.initial_rtt = static_cast( quicconf.upstream.initial_rtt * NGTCP2_SECONDS); settings.cc_algo = quicconf.upstream.congestion_controller; settings.max_window = http3conf.upstream.max_connection_window_size; settings.max_stream_window = http3conf.upstream.max_window_size; settings.max_tx_udp_payload_size = SHRPX_QUIC_MAX_UDP_PAYLOAD_SIZE; settings.rand_ctx.native_handle = &worker->get_randgen(); settings.token = ngtcp2_vec{const_cast(token), tokenlen}; ngtcp2_transport_params params; ngtcp2_transport_params_default(¶ms); params.initial_max_streams_bidi = http3conf.upstream.max_concurrent_streams; // The minimum number of unidirectional streams required for HTTP/3. params.initial_max_streams_uni = 3; params.initial_max_data = http3conf.upstream.connection_window_size; params.initial_max_stream_data_bidi_remote = http3conf.upstream.window_size; params.initial_max_stream_data_uni = http3conf.upstream.window_size; params.max_idle_timeout = static_cast( quicconf.upstream.timeout.idle * NGTCP2_SECONDS); #ifdef OPENSSL_IS_BORINGSSL if (quicconf.upstream.early_data) { ngtcp2_transport_params early_data_params{ .initial_max_stream_data_bidi_local = params.initial_max_stream_data_bidi_local, .initial_max_stream_data_bidi_remote = params.initial_max_stream_data_bidi_remote, .initial_max_stream_data_uni = params.initial_max_stream_data_uni, .initial_max_data = params.initial_max_data, .initial_max_streams_bidi = params.initial_max_streams_bidi, .initial_max_streams_uni = params.initial_max_streams_uni, }; // TODO include HTTP/3 SETTINGS std::array quic_early_data_ctx; auto quic_early_data_ctxlen = ngtcp2_encode_transport_params( quic_early_data_ctx.data(), quic_early_data_ctx.size(), NGTCP2_TRANSPORT_PARAMS_TYPE_ENCRYPTED_EXTENSIONS, &early_data_params); assert(quic_early_data_ctxlen > 0); assert(static_cast(quic_early_data_ctxlen) <= quic_early_data_ctx.size()); if (SSL_set_quic_early_data_context(handler_->get_ssl(), quic_early_data_ctx.data(), quic_early_data_ctxlen) != 1) { ULOG(ERROR, this) << "SSL_set_quic_early_data_context failed"; return -1; } } #endif // OPENSSL_IS_BORINGSSL if (odcid) { params.original_dcid = *odcid; params.retry_scid = initial_hd.dcid; params.retry_scid_present = 1; } else { params.original_dcid = initial_hd.dcid; } rv = generate_quic_stateless_reset_token( params.stateless_reset_token, scid, qkm.secret.data(), qkm.secret.size()); if (rv != 0) { ULOG(ERROR, this) << "generate_quic_stateless_reset_token failed"; return -1; } params.stateless_reset_token_present = 1; auto path = ngtcp2_path{ { const_cast(&local_addr.su.sa), static_cast(local_addr.len), }, { const_cast(&remote_addr.su.sa), static_cast(remote_addr.len), }, const_cast(faddr), }; rv = ngtcp2_conn_server_new(&conn_, &initial_hd.scid, &scid, &path, initial_hd.version, &callbacks, &settings, ¶ms, nullptr, this); if (rv != 0) { ULOG(ERROR, this) << "ngtcp2_conn_server_new: " << ngtcp2_strerror(rv); return -1; } ngtcp2_conn_set_tls_native_handle(conn_, handler_->get_ssl()); auto quic_connection_handler = worker->get_quic_connection_handler(); if (generate_quic_hashed_connection_id(hashed_scid_, remote_addr, local_addr, initial_hd.dcid) != 0) { return -1; } quic_connection_handler->add_connection_id(hashed_scid_, handler_); quic_connection_handler->add_connection_id(scid, handler_); return 0; } int Http3Upstream::on_read() { return 0; } int Http3Upstream::on_write() { int rv; if (tx_.send_blocked) { rv = send_blocked_packet(); if (rv != 0) { return -1; } if (tx_.send_blocked) { return 0; } } if (write_streams() != 0) { return -1; } reset_timer(); return 0; } int Http3Upstream::write_streams() { std::array vec; auto max_udp_payload_size = ngtcp2_conn_get_max_tx_udp_payload_size(conn_); #ifdef UDP_SEGMENT auto path_max_udp_payload_size = ngtcp2_conn_get_path_max_tx_udp_payload_size(conn_); #endif // UDP_SEGMENT auto max_pktcnt = ngtcp2_conn_get_send_quantum(conn_) / max_udp_payload_size; ngtcp2_pkt_info pi, prev_pi; uint8_t *bufpos = tx_.data.get(); ngtcp2_path_storage ps, prev_ps; size_t pktcnt = 0; int rv; size_t gso_size = 0; auto ts = quic_timestamp(); ngtcp2_path_storage_zero(&ps); ngtcp2_path_storage_zero(&prev_ps); for (;;) { int64_t stream_id = -1; int fin = 0; nghttp3_ssize sveccnt = 0; if (httpconn_ && ngtcp2_conn_get_max_data_left(conn_)) { sveccnt = nghttp3_conn_writev_stream(httpconn_, &stream_id, &fin, vec.data(), vec.size()); if (sveccnt < 0) { ULOG(ERROR, this) << "nghttp3_conn_writev_stream: " << nghttp3_strerror(sveccnt); ngtcp2_connection_close_error_set_application_error( &last_error_, nghttp3_err_infer_quic_app_error_code(sveccnt), nullptr, 0); return handle_error(); } } ngtcp2_ssize ndatalen; auto v = vec.data(); auto vcnt = static_cast(sveccnt); uint32_t flags = NGTCP2_WRITE_STREAM_FLAG_MORE; if (fin) { flags |= NGTCP2_WRITE_STREAM_FLAG_FIN; } auto nwrite = ngtcp2_conn_writev_stream( conn_, &ps.path, &pi, bufpos, max_udp_payload_size, &ndatalen, flags, stream_id, reinterpret_cast(v), vcnt, ts); if (nwrite < 0) { switch (nwrite) { case NGTCP2_ERR_STREAM_DATA_BLOCKED: assert(ndatalen == -1); nghttp3_conn_block_stream(httpconn_, stream_id); continue; case NGTCP2_ERR_STREAM_SHUT_WR: assert(ndatalen == -1); nghttp3_conn_shutdown_stream_write(httpconn_, stream_id); continue; case NGTCP2_ERR_WRITE_MORE: assert(ndatalen >= 0); rv = nghttp3_conn_add_write_offset(httpconn_, stream_id, ndatalen); if (rv != 0) { ULOG(ERROR, this) << "nghttp3_conn_add_write_offset: " << nghttp3_strerror(rv); ngtcp2_connection_close_error_set_application_error( &last_error_, nghttp3_err_infer_quic_app_error_code(rv), nullptr, 0); return handle_error(); } continue; } assert(ndatalen == -1); ULOG(ERROR, this) << "ngtcp2_conn_writev_stream: " << ngtcp2_strerror(nwrite); ngtcp2_connection_close_error_set_transport_error_liberr( &last_error_, nwrite, nullptr, 0); return handle_error(); } else if (ndatalen >= 0) { rv = nghttp3_conn_add_write_offset(httpconn_, stream_id, ndatalen); if (rv != 0) { ULOG(ERROR, this) << "nghttp3_conn_add_write_offset: " << nghttp3_strerror(rv); ngtcp2_connection_close_error_set_application_error( &last_error_, nghttp3_err_infer_quic_app_error_code(rv), nullptr, 0); return handle_error(); } } if (nwrite == 0) { if (bufpos - tx_.data.get()) { auto faddr = static_cast(prev_ps.path.user_data); auto data = tx_.data.get(); auto datalen = bufpos - data; rv = send_packet(faddr, prev_ps.path.remote.addr, prev_ps.path.remote.addrlen, prev_ps.path.local.addr, prev_ps.path.local.addrlen, prev_pi, data, datalen, gso_size); if (rv == SHRPX_ERR_SEND_BLOCKED) { on_send_blocked(faddr, prev_ps.path.remote, prev_ps.path.local, prev_pi, data, datalen, gso_size); ngtcp2_conn_update_pkt_tx_time(conn_, ts); signal_write_upstream_addr(faddr); return 0; } } ngtcp2_conn_update_pkt_tx_time(conn_, ts); handler_->get_connection()->wlimit.stopw(); return 0; } bufpos += nwrite; #ifdef UDP_SEGMENT if (pktcnt == 0) { ngtcp2_path_copy(&prev_ps.path, &ps.path); prev_pi = pi; gso_size = nwrite; } else if (!ngtcp2_path_eq(&prev_ps.path, &ps.path) || prev_pi.ecn != pi.ecn || static_cast(nwrite) > gso_size || (gso_size > path_max_udp_payload_size && static_cast(nwrite) != gso_size)) { auto faddr = static_cast(prev_ps.path.user_data); auto data = tx_.data.get(); auto datalen = bufpos - data - nwrite; rv = send_packet(faddr, prev_ps.path.remote.addr, prev_ps.path.remote.addrlen, prev_ps.path.local.addr, prev_ps.path.local.addrlen, prev_pi, data, datalen, gso_size); switch (rv) { case SHRPX_ERR_SEND_BLOCKED: on_send_blocked(faddr, prev_ps.path.remote, prev_ps.path.local, prev_pi, data, datalen, gso_size); on_send_blocked(static_cast(ps.path.user_data), ps.path.remote, ps.path.local, pi, bufpos - nwrite, nwrite, 0); signal_write_upstream_addr(faddr); break; default: { auto faddr = static_cast(ps.path.user_data); auto data = bufpos - nwrite; rv = send_packet(faddr, ps.path.remote.addr, ps.path.remote.addrlen, ps.path.local.addr, ps.path.local.addrlen, pi, data, nwrite, 0); if (rv == SHRPX_ERR_SEND_BLOCKED) { on_send_blocked(faddr, ps.path.remote, ps.path.local, pi, data, nwrite, 0); } signal_write_upstream_addr(faddr); } } ngtcp2_conn_update_pkt_tx_time(conn_, ts); return 0; } if (++pktcnt == max_pktcnt || static_cast(nwrite) < gso_size) { auto faddr = static_cast(ps.path.user_data); auto data = tx_.data.get(); auto datalen = bufpos - data; rv = send_packet(faddr, ps.path.remote.addr, ps.path.remote.addrlen, ps.path.local.addr, ps.path.local.addrlen, pi, data, datalen, gso_size); if (rv == SHRPX_ERR_SEND_BLOCKED) { on_send_blocked(faddr, ps.path.remote, ps.path.local, pi, data, datalen, gso_size); } ngtcp2_conn_update_pkt_tx_time(conn_, ts); signal_write_upstream_addr(faddr); return 0; } #else // !UDP_SEGMENT auto faddr = static_cast(ps.path.user_data); auto data = tx_.data.get(); auto datalen = bufpos - data; rv = send_packet(faddr, ps.path.remote.addr, ps.path.remote.addrlen, ps.path.local.addr, ps.path.local.addrlen, pi, data, datalen, 0); if (rv == SHRPX_ERR_SEND_BLOCKED) { on_send_blocked(faddr, ps.path.remote, ps.path.local, pi, data, datalen, 0); ngtcp2_conn_update_pkt_tx_time(conn_, ts); signal_write_upstream_addr(faddr); return 0; } if (++pktcnt == max_pktcnt) { ngtcp2_conn_update_pkt_tx_time(conn_, ts); signal_write_upstream_addr(faddr); return 0; } bufpos = tx_.data.get(); #endif // !UDP_SEGMENT } return 0; } int Http3Upstream::on_timeout(Downstream *downstream) { return 0; } int Http3Upstream::on_downstream_abort_request(Downstream *downstream, unsigned int status_code) { int rv; rv = error_reply(downstream, status_code); if (rv != 0) { return -1; } handler_->signal_write(); return 0; } int Http3Upstream::on_downstream_abort_request_with_https_redirect( Downstream *downstream) { assert(0); abort(); } namespace { uint64_t infer_upstream_shutdown_stream_error_code(uint32_t downstream_error_code) { // NGHTTP2_REFUSED_STREAM is important because it tells upstream // client to retry. switch (downstream_error_code) { case NGHTTP2_NO_ERROR: return NGHTTP3_H3_NO_ERROR; case NGHTTP2_REFUSED_STREAM: return NGHTTP3_H3_REQUEST_REJECTED; default: return NGHTTP3_H3_INTERNAL_ERROR; } } } // namespace int Http3Upstream::downstream_read(DownstreamConnection *dconn) { auto downstream = dconn->get_downstream(); if (downstream->get_response_state() == DownstreamState::MSG_RESET) { // The downstream stream was reset (canceled). In this case, // RST_STREAM to the upstream and delete downstream connection // here. Deleting downstream will be taken place at // on_stream_close_callback. shutdown_stream(downstream, infer_upstream_shutdown_stream_error_code( downstream->get_response_rst_stream_error_code())); downstream->pop_downstream_connection(); // dconn was deleted dconn = nullptr; } else if (downstream->get_response_state() == DownstreamState::MSG_BAD_HEADER) { if (error_reply(downstream, 502) != 0) { return -1; } downstream->pop_downstream_connection(); // dconn was deleted dconn = nullptr; } else { auto rv = downstream->on_read(); if (rv == SHRPX_ERR_EOF) { if (downstream->get_request_header_sent()) { return downstream_eof(dconn); } return SHRPX_ERR_RETRY; } if (rv == SHRPX_ERR_DCONN_CANCELED) { downstream->pop_downstream_connection(); handler_->signal_write(); return 0; } if (rv != 0) { if (rv != SHRPX_ERR_NETWORK) { if (LOG_ENABLED(INFO)) { DCLOG(INFO, dconn) << "HTTP parser failure"; } } return downstream_error(dconn, Downstream::EVENT_ERROR); } if (downstream->can_detach_downstream_connection()) { // Keep-alive downstream->detach_downstream_connection(); } } handler_->signal_write(); // At this point, downstream may be deleted. return 0; } int Http3Upstream::downstream_write(DownstreamConnection *dconn) { int rv; rv = dconn->on_write(); if (rv == SHRPX_ERR_NETWORK) { return downstream_error(dconn, Downstream::EVENT_ERROR); } if (rv != 0) { return rv; } return 0; } int Http3Upstream::downstream_eof(DownstreamConnection *dconn) { auto downstream = dconn->get_downstream(); if (LOG_ENABLED(INFO)) { DCLOG(INFO, dconn) << "EOF. stream_id=" << downstream->get_stream_id(); } // Delete downstream connection. If we don't delete it here, it will // be pooled in on_stream_close_callback. downstream->pop_downstream_connection(); // dconn was deleted dconn = nullptr; // downstream will be deleted in on_stream_close_callback. if (downstream->get_response_state() == DownstreamState::HEADER_COMPLETE) { // Server may indicate the end of the request by EOF if (LOG_ENABLED(INFO)) { ULOG(INFO, this) << "Downstream body was ended by EOF"; } downstream->set_response_state(DownstreamState::MSG_COMPLETE); // For tunneled connection, MSG_COMPLETE signals // downstream_read_data_callback to send RST_STREAM after pending // response body is sent. This is needed to ensure that RST_STREAM // is sent after all pending data are sent. if (on_downstream_body_complete(downstream) != 0) { return -1; } } else if (downstream->get_response_state() != DownstreamState::MSG_COMPLETE) { // If stream was not closed, then we set MSG_COMPLETE and let // on_stream_close_callback delete downstream. if (error_reply(downstream, 502) != 0) { return -1; } } handler_->signal_write(); // At this point, downstream may be deleted. return 0; } int Http3Upstream::downstream_error(DownstreamConnection *dconn, int events) { auto downstream = dconn->get_downstream(); if (LOG_ENABLED(INFO)) { if (events & Downstream::EVENT_ERROR) { DCLOG(INFO, dconn) << "Downstream network/general error"; } else { DCLOG(INFO, dconn) << "Timeout"; } if (downstream->get_upgraded()) { DCLOG(INFO, dconn) << "Note: this is tunnel connection"; } } // Delete downstream connection. If we don't delete it here, it will // be pooled in on_stream_close_callback. downstream->pop_downstream_connection(); // dconn was deleted dconn = nullptr; if (downstream->get_response_state() == DownstreamState::MSG_COMPLETE) { // For SSL tunneling, we issue RST_STREAM. For other types of // stream, we don't have to do anything since response was // complete. if (downstream->get_upgraded()) { shutdown_stream(downstream, NGHTTP3_H3_NO_ERROR); } } else { if (downstream->get_response_state() == DownstreamState::HEADER_COMPLETE) { if (downstream->get_upgraded()) { if (on_downstream_body_complete(downstream) != 0) { return -1; } } else { shutdown_stream(downstream, NGHTTP3_H3_INTERNAL_ERROR); } } else { unsigned int status; if (events & Downstream::EVENT_TIMEOUT) { if (downstream->get_request_header_sent()) { status = 504; } else { status = 408; } } else { status = 502; } if (error_reply(downstream, status) != 0) { return -1; } } downstream->set_response_state(DownstreamState::MSG_COMPLETE); } handler_->signal_write(); // At this point, downstream may be deleted. return 0; } ClientHandler *Http3Upstream::get_client_handler() const { return handler_; } namespace { nghttp3_ssize downstream_read_data_callback(nghttp3_conn *conn, int64_t stream_id, nghttp3_vec *vec, size_t veccnt, uint32_t *pflags, void *conn_user_data, void *stream_user_data) { auto upstream = static_cast(conn_user_data); auto downstream = static_cast(stream_user_data); assert(downstream); auto body = downstream->get_response_buf(); assert(body); if (downstream->get_response_state() != DownstreamState::MSG_COMPLETE && body->rleft_mark() == 0) { downstream->disable_upstream_wtimer(); return NGHTTP3_ERR_WOULDBLOCK; } downstream->reset_upstream_wtimer(); veccnt = body->riovec_mark(reinterpret_cast(vec), veccnt); if (downstream->get_response_state() == DownstreamState::MSG_COMPLETE && body->rleft_mark() == 0) { *pflags |= NGHTTP3_DATA_FLAG_EOF; } assert((*pflags & NGHTTP3_DATA_FLAG_EOF) || veccnt); downstream->response_sent_body_length += nghttp3_vec_len(vec, veccnt); if ((*pflags & NGHTTP3_DATA_FLAG_EOF) && upstream->shutdown_stream_read(stream_id, NGHTTP3_H3_NO_ERROR) != 0) { return NGHTTP3_ERR_CALLBACK_FAILURE; } return veccnt; } } // namespace int Http3Upstream::on_downstream_header_complete(Downstream *downstream) { int rv; const auto &req = downstream->request(); auto &resp = downstream->response(); auto &balloc = downstream->get_block_allocator(); if (LOG_ENABLED(INFO)) { if (downstream->get_non_final_response()) { DLOG(INFO, downstream) << "HTTP non-final response header"; } else { DLOG(INFO, downstream) << "HTTP response header completed"; } } auto config = get_config(); auto &httpconf = config->http; if (!config->http2_proxy && !httpconf.no_location_rewrite) { downstream->rewrite_location_response_header(req.scheme); } #ifdef HAVE_MRUBY if (!downstream->get_non_final_response()) { auto dconn = downstream->get_downstream_connection(); const auto &group = dconn->get_downstream_addr_group(); if (group) { const auto &dmruby_ctx = group->shared_addr->mruby_ctx; if (dmruby_ctx->run_on_response_proc(downstream) != 0) { if (error_reply(downstream, 500) != 0) { return -1; } // Returning -1 will signal deletion of dconn. return -1; } if (downstream->get_response_state() == DownstreamState::MSG_COMPLETE) { return -1; } } auto worker = handler_->get_worker(); auto mruby_ctx = worker->get_mruby_context(); if (mruby_ctx->run_on_response_proc(downstream) != 0) { if (error_reply(downstream, 500) != 0) { return -1; } // Returning -1 will signal deletion of dconn. return -1; } if (downstream->get_response_state() == DownstreamState::MSG_COMPLETE) { return -1; } } #endif // HAVE_MRUBY auto nva = std::vector(); // 4 means :status and possible server, via, and set-cookie (for // affinity cookie) header field. nva.reserve(resp.fs.headers().size() + 4 + httpconf.add_response_headers.size()); if (downstream->get_non_final_response()) { auto response_status = http2::stringify_status(balloc, resp.http_status); nva.push_back(http3::make_nv_ls_nocopy(":status", response_status)); http3::copy_headers_to_nva_nocopy(nva, resp.fs.headers(), http2::HDOP_STRIP_ALL); if (LOG_ENABLED(INFO)) { log_response_headers(downstream, nva); } rv = nghttp3_conn_submit_info(httpconn_, downstream->get_stream_id(), nva.data(), nva.size()); resp.fs.clear_headers(); if (rv != 0) { ULOG(FATAL, this) << "nghttp3_conn_submit_info() failed"; return -1; } return 0; } auto striphd_flags = http2::HDOP_STRIP_ALL & ~http2::HDOP_STRIP_VIA; StringRef response_status; if (req.connect_proto == ConnectProto::WEBSOCKET && resp.http_status == 101) { response_status = http2::stringify_status(balloc, 200); striphd_flags |= http2::HDOP_STRIP_SEC_WEBSOCKET_ACCEPT; } else { response_status = http2::stringify_status(balloc, resp.http_status); } nva.push_back(http3::make_nv_ls_nocopy(":status", response_status)); http3::copy_headers_to_nva_nocopy(nva, resp.fs.headers(), striphd_flags); if (!config->http2_proxy && !httpconf.no_server_rewrite) { nva.push_back(http3::make_nv_ls_nocopy("server", httpconf.server_name)); } else { auto server = resp.fs.header(http2::HD_SERVER); if (server) { nva.push_back(http3::make_nv_ls_nocopy("server", (*server).value)); } } if (!req.regular_connect_method() || !downstream->get_upgraded()) { auto affinity_cookie = downstream->get_affinity_cookie_to_send(); if (affinity_cookie) { auto dconn = downstream->get_downstream_connection(); assert(dconn); auto &group = dconn->get_downstream_addr_group(); auto &shared_addr = group->shared_addr; auto &cookieconf = shared_addr->affinity.cookie; auto secure = http::require_cookie_secure_attribute(cookieconf.secure, req.scheme); auto cookie_str = http::create_affinity_cookie( balloc, cookieconf.name, affinity_cookie, cookieconf.path, secure); nva.push_back(http3::make_nv_ls_nocopy("set-cookie", cookie_str)); } } auto via = resp.fs.header(http2::HD_VIA); if (httpconf.no_via) { if (via) { nva.push_back(http3::make_nv_ls_nocopy("via", (*via).value)); } } else { // we don't create more than 16 bytes in // http::create_via_header_value. size_t len = 16; if (via) { len += via->value.size() + 2; } auto iov = make_byte_ref(balloc, len + 1); auto p = iov.base; if (via) { p = std::copy(std::begin(via->value), std::end(via->value), p); p = util::copy_lit(p, ", "); } p = http::create_via_header_value(p, resp.http_major, resp.http_minor); *p = '\0'; nva.push_back(http3::make_nv_ls_nocopy("via", StringRef{iov.base, p})); } for (auto &p : httpconf.add_response_headers) { nva.push_back(http3::make_nv_nocopy(p.name, p.value)); } if (LOG_ENABLED(INFO)) { log_response_headers(downstream, nva); } nghttp3_data_reader data_read; data_read.read_data = downstream_read_data_callback; nghttp3_data_reader *data_readptr; if (downstream->expect_response_body() || downstream->expect_response_trailer()) { data_readptr = &data_read; } else { data_readptr = nullptr; } rv = nghttp3_conn_submit_response(httpconn_, downstream->get_stream_id(), nva.data(), nva.size(), data_readptr); if (rv != 0) { ULOG(FATAL, this) << "nghttp3_conn_submit_response() failed"; return -1; } if (data_readptr) { downstream->reset_upstream_wtimer(); } else if (shutdown_stream_read(downstream->get_stream_id(), NGHTTP3_H3_NO_ERROR) != 0) { return -1; } return 0; } int Http3Upstream::on_downstream_body(Downstream *downstream, const uint8_t *data, size_t len, bool flush) { auto body = downstream->get_response_buf(); body->append(data, len); if (flush) { nghttp3_conn_resume_stream(httpconn_, downstream->get_stream_id()); downstream->ensure_upstream_wtimer(); } return 0; } int Http3Upstream::on_downstream_body_complete(Downstream *downstream) { if (LOG_ENABLED(INFO)) { DLOG(INFO, downstream) << "HTTP response completed"; } auto &resp = downstream->response(); if (!downstream->validate_response_recv_body_length()) { shutdown_stream(downstream, NGHTTP3_H3_GENERAL_PROTOCOL_ERROR); resp.connection_close = true; return 0; } if (!downstream->get_upgraded()) { const auto &trailers = resp.fs.trailers(); if (!trailers.empty()) { std::vector nva; nva.reserve(trailers.size()); http3::copy_headers_to_nva_nocopy(nva, trailers, http2::HDOP_STRIP_ALL); if (!nva.empty()) { auto rv = nghttp3_conn_submit_trailers( httpconn_, downstream->get_stream_id(), nva.data(), nva.size()); if (rv != 0) { ULOG(FATAL, this) << "nghttp3_conn_submit_trailers() failed: " << nghttp3_strerror(rv); return -1; } } } } nghttp3_conn_resume_stream(httpconn_, downstream->get_stream_id()); downstream->ensure_upstream_wtimer(); return 0; } void Http3Upstream::on_handler_delete() { for (auto d = downstream_queue_.get_downstreams(); d; d = d->dlnext) { if (d->get_dispatch_state() == DispatchState::ACTIVE && d->accesslog_ready()) { handler_->write_accesslog(d); } } auto worker = handler_->get_worker(); auto quic_conn_handler = worker->get_quic_connection_handler(); std::vector scids(ngtcp2_conn_get_num_scid(conn_) + 1); ngtcp2_conn_get_scid(conn_, scids.data()); scids.back() = hashed_scid_; for (auto &cid : scids) { quic_conn_handler->remove_connection_id(cid); } if (retry_close_ || last_error_.type == NGTCP2_CONNECTION_CLOSE_ERROR_CODE_TYPE_TRANSPORT_IDLE_CLOSE) { return; } // If this is not idle close, send CONNECTION_CLOSE. if (!ngtcp2_conn_is_in_closing_period(conn_) && !ngtcp2_conn_is_in_draining_period(conn_)) { ngtcp2_path_storage ps; ngtcp2_pkt_info pi; conn_close_.resize(SHRPX_QUIC_CONN_CLOSE_PKTLEN); ngtcp2_path_storage_zero(&ps); ngtcp2_connection_close_error ccerr; ngtcp2_connection_close_error_default(&ccerr); auto nwrite = ngtcp2_conn_write_connection_close( conn_, &ps.path, &pi, conn_close_.data(), conn_close_.size(), &ccerr, quic_timestamp()); if (nwrite < 0) { if (nwrite != NGTCP2_ERR_INVALID_STATE) { ULOG(ERROR, this) << "ngtcp2_conn_write_connection_close: " << ngtcp2_strerror(nwrite); } return; } conn_close_.resize(nwrite); send_packet(static_cast(ps.path.user_data), ps.path.remote.addr, ps.path.remote.addrlen, ps.path.local.addr, ps.path.local.addrlen, pi, conn_close_.data(), nwrite, 0); } auto d = static_cast(ngtcp2_conn_get_pto(conn_) * 3) / NGTCP2_SECONDS; if (LOG_ENABLED(INFO)) { ULOG(INFO, this) << "Enter close-wait period " << d << "s with " << conn_close_.size() << " bytes sentinel packet"; } auto cw = std::make_unique(worker, std::move(scids), std::move(conn_close_), d); quic_conn_handler->add_close_wait(cw.get()); cw.release(); } int Http3Upstream::on_downstream_reset(Downstream *downstream, bool no_retry) { int rv; if (downstream->get_dispatch_state() != DispatchState::ACTIVE) { // This is error condition when we failed push_request_headers() // in initiate_downstream(). Otherwise, we have // DispatchState::ACTIVE state, or we did not set // DownstreamConnection. downstream->pop_downstream_connection(); handler_->signal_write(); return 0; } if (!downstream->request_submission_ready()) { if (downstream->get_response_state() == DownstreamState::MSG_COMPLETE) { // We have got all response body already. Send it off. downstream->pop_downstream_connection(); return 0; } // pushed stream is handled here shutdown_stream(downstream, NGHTTP3_H3_INTERNAL_ERROR); downstream->pop_downstream_connection(); handler_->signal_write(); return 0; } downstream->pop_downstream_connection(); downstream->add_retry(); std::unique_ptr dconn; rv = 0; if (no_retry || downstream->no_more_retry()) { goto fail; } // downstream connection is clean; we can retry with new // downstream connection. for (;;) { auto dconn = handler_->get_downstream_connection(rv, downstream); if (!dconn) { goto fail; } rv = downstream->attach_downstream_connection(std::move(dconn)); if (rv == 0) { break; } } rv = downstream->push_request_headers(); if (rv != 0) { goto fail; } return 0; fail: if (rv == SHRPX_ERR_TLS_REQUIRED) { assert(0); abort(); } rv = on_downstream_abort_request(downstream, 502); if (rv != 0) { shutdown_stream(downstream, NGHTTP3_H3_INTERNAL_ERROR); } downstream->pop_downstream_connection(); handler_->signal_write(); return 0; } void Http3Upstream::pause_read(IOCtrlReason reason) {} int Http3Upstream::resume_read(IOCtrlReason reason, Downstream *downstream, size_t consumed) { consume(downstream->get_stream_id(), consumed); auto &req = downstream->request(); req.consume(consumed); handler_->signal_write(); return 0; } int Http3Upstream::send_reply(Downstream *downstream, const uint8_t *body, size_t bodylen) { int rv; nghttp3_data_reader data_read, *data_read_ptr = nullptr; if (bodylen) { data_read.read_data = downstream_read_data_callback; data_read_ptr = &data_read; } const auto &resp = downstream->response(); auto config = get_config(); auto &httpconf = config->http; auto &balloc = downstream->get_block_allocator(); const auto &headers = resp.fs.headers(); auto nva = std::vector(); // 2 for :status and server nva.reserve(2 + headers.size() + httpconf.add_response_headers.size()); auto response_status = http2::stringify_status(balloc, resp.http_status); nva.push_back(http3::make_nv_ls_nocopy(":status", response_status)); for (auto &kv : headers) { if (kv.name.empty() || kv.name[0] == ':') { continue; } switch (kv.token) { case http2::HD_CONNECTION: case http2::HD_KEEP_ALIVE: case http2::HD_PROXY_CONNECTION: case http2::HD_TE: case http2::HD_TRANSFER_ENCODING: case http2::HD_UPGRADE: continue; } nva.push_back(http3::make_nv_nocopy(kv.name, kv.value, kv.no_index)); } if (!resp.fs.header(http2::HD_SERVER)) { nva.push_back(http3::make_nv_ls_nocopy("server", config->http.server_name)); } for (auto &p : httpconf.add_response_headers) { nva.push_back(http3::make_nv_nocopy(p.name, p.value)); } rv = nghttp3_conn_submit_response(httpconn_, downstream->get_stream_id(), nva.data(), nva.size(), data_read_ptr); if (nghttp3_err_is_fatal(rv)) { ULOG(FATAL, this) << "nghttp3_conn_submit_response() failed: " << nghttp3_strerror(rv); return -1; } auto buf = downstream->get_response_buf(); buf->append(body, bodylen); downstream->set_response_state(DownstreamState::MSG_COMPLETE); if (data_read_ptr) { downstream->reset_upstream_wtimer(); } if (shutdown_stream_read(downstream->get_stream_id(), NGHTTP3_H3_NO_ERROR) != 0) { return -1; } return 0; } int Http3Upstream::initiate_push(Downstream *downstream, const StringRef &uri) { return 0; } int Http3Upstream::response_riovec(struct iovec *iov, int iovcnt) const { return 0; } void Http3Upstream::response_drain(size_t n) {} bool Http3Upstream::response_empty() const { return false; } Downstream * Http3Upstream::on_downstream_push_promise(Downstream *downstream, int32_t promised_stream_id) { return nullptr; } int Http3Upstream::on_downstream_push_promise_complete( Downstream *downstream, Downstream *promised_downstream) { return 0; } bool Http3Upstream::push_enabled() const { return false; } void Http3Upstream::cancel_premature_downstream( Downstream *promised_downstream) {} int Http3Upstream::on_read(const UpstreamAddr *faddr, const Address &remote_addr, const Address &local_addr, const ngtcp2_pkt_info &pi, const uint8_t *data, size_t datalen) { int rv; auto path = ngtcp2_path{ { const_cast(&local_addr.su.sa), static_cast(local_addr.len), }, { const_cast(&remote_addr.su.sa), static_cast(remote_addr.len), }, const_cast(faddr), }; rv = ngtcp2_conn_read_pkt(conn_, &path, &pi, data, datalen, quic_timestamp()); if (rv != 0) { switch (rv) { case NGTCP2_ERR_DRAINING: return -1; case NGTCP2_ERR_RETRY: { auto worker = handler_->get_worker(); auto quic_conn_handler = worker->get_quic_connection_handler(); ngtcp2_version_cid vc; rv = ngtcp2_pkt_decode_version_cid(&vc, data, datalen, SHRPX_QUIC_SCIDLEN); if (rv != 0) { return -1; } if (worker->get_graceful_shutdown()) { ngtcp2_cid ini_dcid, ini_scid; ngtcp2_cid_init(&ini_dcid, vc.dcid, vc.dcidlen); ngtcp2_cid_init(&ini_scid, vc.scid, vc.scidlen); quic_conn_handler->send_connection_close( faddr, vc.version, ini_dcid, ini_scid, remote_addr, local_addr, NGTCP2_CONNECTION_REFUSED, datalen * 3); return -1; } retry_close_ = true; quic_conn_handler->send_retry(handler_->get_upstream_addr(), vc.version, vc.dcid, vc.dcidlen, vc.scid, vc.scidlen, remote_addr, local_addr, datalen * 3); return -1; } case NGTCP2_ERR_CRYPTO: if (!last_error_.error_code) { ngtcp2_connection_close_error_set_transport_error_tls_alert( &last_error_, ngtcp2_conn_get_tls_alert(conn_), nullptr, 0); } break; case NGTCP2_ERR_DROP_CONN: return -1; default: if (!last_error_.error_code) { ngtcp2_connection_close_error_set_transport_error_liberr( &last_error_, rv, nullptr, 0); } } ULOG(ERROR, this) << "ngtcp2_conn_read_pkt: " << ngtcp2_strerror(rv); return handle_error(); } return 0; } int Http3Upstream::send_packet(const UpstreamAddr *faddr, const sockaddr *remote_sa, size_t remote_salen, const sockaddr *local_sa, size_t local_salen, const ngtcp2_pkt_info &pi, const uint8_t *data, size_t datalen, size_t gso_size) { auto rv = quic_send_packet(faddr, remote_sa, remote_salen, local_sa, local_salen, pi, data, datalen, gso_size); switch (rv) { case 0: return 0; // With GSO, sendmsg may fail with EINVAL if UDP payload is too // large. case -EINVAL: case -EMSGSIZE: // Let the packet lost. break; case -EAGAIN: #if EAGAIN != EWOULDBLOCK case -EWOULDBLOCK: #endif // EAGAIN != EWOULDBLOCK return SHRPX_ERR_SEND_BLOCKED; default: break; } return -1; } void Http3Upstream::on_send_blocked(const UpstreamAddr *faddr, const ngtcp2_addr &remote_addr, const ngtcp2_addr &local_addr, const ngtcp2_pkt_info &pi, const uint8_t *data, size_t datalen, size_t gso_size) { assert(tx_.num_blocked || !tx_.send_blocked); assert(tx_.num_blocked < 2); tx_.send_blocked = true; auto &p = tx_.blocked[tx_.num_blocked++]; memcpy(&p.local_addr.su, local_addr.addr, local_addr.addrlen); memcpy(&p.remote_addr.su, remote_addr.addr, remote_addr.addrlen); p.local_addr.len = local_addr.addrlen; p.remote_addr.len = remote_addr.addrlen; p.faddr = faddr; p.pi = pi; p.data = data; p.datalen = datalen; p.gso_size = gso_size; } int Http3Upstream::send_blocked_packet() { int rv; assert(tx_.send_blocked); for (; tx_.num_blocked_sent < tx_.num_blocked; ++tx_.num_blocked_sent) { auto &p = tx_.blocked[tx_.num_blocked_sent]; rv = send_packet(p.faddr, &p.remote_addr.su.sa, p.remote_addr.len, &p.local_addr.su.sa, p.local_addr.len, p.pi, p.data, p.datalen, p.gso_size); if (rv == SHRPX_ERR_SEND_BLOCKED) { signal_write_upstream_addr(p.faddr); return 0; } } tx_.send_blocked = false; tx_.num_blocked = 0; tx_.num_blocked_sent = 0; return 0; } void Http3Upstream::signal_write_upstream_addr(const UpstreamAddr *faddr) { auto conn = handler_->get_connection(); if (faddr->fd != conn->wev.fd) { if (ev_is_active(&conn->wev)) { ev_io_stop(handler_->get_loop(), &conn->wev); } ev_io_set(&conn->wev, faddr->fd, EV_WRITE); } conn->wlimit.startw(); } int Http3Upstream::handle_error() { if (ngtcp2_conn_is_in_closing_period(conn_) || ngtcp2_conn_is_in_draining_period(conn_)) { return -1; } ngtcp2_path_storage ps; ngtcp2_pkt_info pi; ngtcp2_path_storage_zero(&ps); auto ts = quic_timestamp(); conn_close_.resize(SHRPX_QUIC_CONN_CLOSE_PKTLEN); auto nwrite = ngtcp2_conn_write_connection_close( conn_, &ps.path, &pi, conn_close_.data(), conn_close_.size(), &last_error_, ts); if (nwrite < 0) { ULOG(ERROR, this) << "ngtcp2_conn_write_connection_close: " << ngtcp2_strerror(nwrite); return -1; } conn_close_.resize(nwrite); if (nwrite == 0) { return -1; } send_packet(static_cast(ps.path.user_data), ps.path.remote.addr, ps.path.remote.addrlen, ps.path.local.addr, ps.path.local.addrlen, pi, conn_close_.data(), nwrite, 0); return -1; } int Http3Upstream::handle_expiry() { int rv; auto ts = quic_timestamp(); rv = ngtcp2_conn_handle_expiry(conn_, ts); if (rv != 0) { if (rv == NGTCP2_ERR_IDLE_CLOSE) { ULOG(INFO, this) << "Idle connection timeout"; } else { ULOG(ERROR, this) << "ngtcp2_conn_handle_expiry: " << ngtcp2_strerror(rv); } ngtcp2_connection_close_error_set_transport_error_liberr(&last_error_, rv, nullptr, 0); return handle_error(); } return 0; } void Http3Upstream::reset_timer() { auto ts = quic_timestamp(); auto expiry_ts = ngtcp2_conn_get_expiry(conn_); auto loop = handler_->get_loop(); if (expiry_ts <= ts) { ev_feed_event(loop, &timer_, EV_TIMER); return; } timer_.repeat = static_cast(expiry_ts - ts) / NGTCP2_SECONDS; ev_timer_again(loop, &timer_); } namespace { int http_deferred_consume(nghttp3_conn *conn, int64_t stream_id, size_t nconsumed, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); upstream->consume(stream_id, nconsumed); return 0; } } // namespace namespace { int http_acked_stream_data(nghttp3_conn *conn, int64_t stream_id, uint64_t datalen, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); auto downstream = static_cast(stream_user_data); assert(downstream); if (upstream->http_acked_stream_data(downstream, datalen) != 0) { return NGHTTP3_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::http_acked_stream_data(Downstream *downstream, uint64_t datalen) { if (LOG_ENABLED(INFO)) { ULOG(INFO, this) << "Stream " << downstream->get_stream_id() << " " << datalen << " bytes acknowledged"; } auto body = downstream->get_response_buf(); auto drained = body->drain_mark(datalen); (void)drained; assert(datalen == drained); if (downstream->resume_read(SHRPX_NO_BUFFER, datalen) != 0) { return -1; } return 0; } namespace { int http_begin_request_headers(nghttp3_conn *conn, int64_t stream_id, void *user_data, void *stream_user_data) { if (!ngtcp2_is_bidi_stream(stream_id)) { return 0; } auto upstream = static_cast(user_data); upstream->http_begin_request_headers(stream_id); return 0; } } // namespace namespace { int http_recv_request_header(nghttp3_conn *conn, int64_t stream_id, int32_t token, nghttp3_rcbuf *name, nghttp3_rcbuf *value, uint8_t flags, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); auto downstream = static_cast(stream_user_data); if (!downstream || downstream->get_stop_reading()) { return 0; } if (upstream->http_recv_request_header(downstream, token, name, value, flags, /* trailer = */ false) != 0) { return NGHTTP3_ERR_CALLBACK_FAILURE; } return 0; } } // namespace namespace { int http_recv_request_trailer(nghttp3_conn *conn, int64_t stream_id, int32_t token, nghttp3_rcbuf *name, nghttp3_rcbuf *value, uint8_t flags, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); auto downstream = static_cast(stream_user_data); if (!downstream || downstream->get_stop_reading()) { return 0; } if (upstream->http_recv_request_header(downstream, token, name, value, flags, /* trailer = */ true) != 0) { return NGHTTP3_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::http_recv_request_header(Downstream *downstream, int32_t h3token, nghttp3_rcbuf *name, nghttp3_rcbuf *value, uint8_t flags, bool trailer) { auto namebuf = nghttp3_rcbuf_get_buf(name); auto valuebuf = nghttp3_rcbuf_get_buf(value); auto &req = downstream->request(); auto config = get_config(); auto &httpconf = config->http; if (req.fs.buffer_size() + namebuf.len + valuebuf.len > httpconf.request_header_field_buffer || req.fs.num_fields() >= httpconf.max_request_header_fields) { downstream->set_stop_reading(true); if (downstream->get_response_state() == DownstreamState::MSG_COMPLETE) { return 0; } if (LOG_ENABLED(INFO)) { ULOG(INFO, this) << "Too large or many header field size=" << req.fs.buffer_size() + namebuf.len + valuebuf.len << ", num=" << req.fs.num_fields() + 1; } // just ignore if this is a trailer part. if (trailer) { return 0; } if (error_reply(downstream, 431) != 0) { return -1; } return 0; } auto token = http2::lookup_token(namebuf.base, namebuf.len); auto no_index = flags & NGHTTP3_NV_FLAG_NEVER_INDEX; downstream->add_rcbuf(name); downstream->add_rcbuf(value); if (trailer) { req.fs.add_trailer_token(StringRef{namebuf.base, namebuf.len}, StringRef{valuebuf.base, valuebuf.len}, no_index, token); return 0; } req.fs.add_header_token(StringRef{namebuf.base, namebuf.len}, StringRef{valuebuf.base, valuebuf.len}, no_index, token); return 0; } namespace { int http_end_request_headers(nghttp3_conn *conn, int64_t stream_id, int fin, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); auto handler = upstream->get_client_handler(); auto downstream = static_cast(stream_user_data); if (!downstream || downstream->get_stop_reading()) { return 0; } if (upstream->http_end_request_headers(downstream, fin) != 0) { return NGHTTP3_ERR_CALLBACK_FAILURE; } downstream->reset_upstream_rtimer(); handler->stop_read_timer(); return 0; } } // namespace int Http3Upstream::http_end_request_headers(Downstream *downstream, int fin) { auto lgconf = log_config(); lgconf->update_tstamp(std::chrono::system_clock::now()); auto &req = downstream->request(); req.tstamp = lgconf->tstamp; if (downstream->get_response_state() == DownstreamState::MSG_COMPLETE) { return 0; } auto &nva = req.fs.headers(); if (LOG_ENABLED(INFO)) { std::stringstream ss; for (auto &nv : nva) { if (nv.name == "authorization") { ss << TTY_HTTP_HD << nv.name << TTY_RST << ": \n"; continue; } ss << TTY_HTTP_HD << nv.name << TTY_RST << ": " << nv.value << "\n"; } ULOG(INFO, this) << "HTTP request headers. stream_id=" << downstream->get_stream_id() << "\n" << ss.str(); } auto content_length = req.fs.header(http2::HD_CONTENT_LENGTH); if (content_length) { // libnghttp3 guarantees this can be parsed req.fs.content_length = util::parse_uint(content_length->value); } // presence of mandatory header fields are guaranteed by libnghttp3. auto authority = req.fs.header(http2::HD__AUTHORITY); auto path = req.fs.header(http2::HD__PATH); auto method = req.fs.header(http2::HD__METHOD); auto scheme = req.fs.header(http2::HD__SCHEME); auto method_token = http2::lookup_method_token(method->value); if (method_token == -1) { if (error_reply(downstream, 501) != 0) { return -1; } return 0; } auto faddr = handler_->get_upstream_addr(); auto config = get_config(); // For HTTP/2 proxy, we require :authority. if (method_token != HTTP_CONNECT && config->http2_proxy && faddr->alt_mode == UpstreamAltMode::NONE && !authority) { shutdown_stream(downstream, NGHTTP3_H3_GENERAL_PROTOCOL_ERROR); return 0; } req.method = method_token; if (scheme) { req.scheme = scheme->value; } // nghttp2 library guarantees either :authority or host exist if (!authority) { req.no_authority = true; authority = req.fs.header(http2::HD_HOST); } if (authority) { req.authority = authority->value; } if (path) { if (method_token == HTTP_OPTIONS && path->value == StringRef::from_lit("*")) { // Server-wide OPTIONS request. Path is empty. } else if (config->http2_proxy && faddr->alt_mode == UpstreamAltMode::NONE) { req.path = path->value; } else { req.path = http2::rewrite_clean_path(downstream->get_block_allocator(), path->value); } } auto connect_proto = req.fs.header(http2::HD__PROTOCOL); if (connect_proto) { if (connect_proto->value != "websocket") { if (error_reply(downstream, 400) != 0) { return -1; } return 0; } req.connect_proto = ConnectProto::WEBSOCKET; } if (!fin) { req.http2_expect_body = true; } else if (req.fs.content_length == -1) { req.fs.content_length = 0; } downstream->inspect_http2_request(); downstream->set_request_state(DownstreamState::HEADER_COMPLETE); if (config->http.require_http_scheme && !http::check_http_scheme(req.scheme, /* encrypted = */ true)) { if (error_reply(downstream, 400) != 0) { return -1; } } #ifdef HAVE_MRUBY auto worker = handler_->get_worker(); auto mruby_ctx = worker->get_mruby_context(); if (mruby_ctx->run_on_request_proc(downstream) != 0) { if (error_reply(downstream, 500) != 0) { return -1; } return 0; } #endif // HAVE_MRUBY if (downstream->get_response_state() == DownstreamState::MSG_COMPLETE) { return 0; } start_downstream(downstream); return 0; } void Http3Upstream::start_downstream(Downstream *downstream) { if (downstream_queue_.can_activate(downstream->request().authority)) { initiate_downstream(downstream); return; } downstream_queue_.mark_blocked(downstream); } void Http3Upstream::initiate_downstream(Downstream *downstream) { int rv; #ifdef HAVE_MRUBY DownstreamConnection *dconn_ptr; #endif // HAVE_MRUBY for (;;) { auto dconn = handler_->get_downstream_connection(rv, downstream); if (!dconn) { if (rv == SHRPX_ERR_TLS_REQUIRED) { assert(0); abort(); } rv = error_reply(downstream, 502); if (rv != 0) { shutdown_stream(downstream, NGHTTP3_H3_INTERNAL_ERROR); } downstream->set_request_state(DownstreamState::CONNECT_FAIL); downstream_queue_.mark_failure(downstream); return; } #ifdef HAVE_MRUBY dconn_ptr = dconn.get(); #endif // HAVE_MRUBY rv = downstream->attach_downstream_connection(std::move(dconn)); if (rv == 0) { break; } } #ifdef HAVE_MRUBY const auto &group = dconn_ptr->get_downstream_addr_group(); if (group) { const auto &mruby_ctx = group->shared_addr->mruby_ctx; if (mruby_ctx->run_on_request_proc(downstream) != 0) { if (error_reply(downstream, 500) != 0) { shutdown_stream(downstream, NGHTTP3_H3_INTERNAL_ERROR); } downstream_queue_.mark_failure(downstream); return; } if (downstream->get_response_state() == DownstreamState::MSG_COMPLETE) { return; } } #endif // HAVE_MRUBY rv = downstream->push_request_headers(); if (rv != 0) { if (error_reply(downstream, 502) != 0) { shutdown_stream(downstream, NGHTTP3_H3_INTERNAL_ERROR); } downstream_queue_.mark_failure(downstream); return; } downstream_queue_.mark_active(downstream); auto &req = downstream->request(); if (!req.http2_expect_body) { rv = downstream->end_upload_data(); if (rv != 0) { shutdown_stream(downstream, NGHTTP3_H3_INTERNAL_ERROR); } } } namespace { int http_recv_data(nghttp3_conn *conn, int64_t stream_id, const uint8_t *data, size_t datalen, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); auto downstream = static_cast(stream_user_data); if (upstream->http_recv_data(downstream, data, datalen) != 0) { return NGHTTP3_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::http_recv_data(Downstream *downstream, const uint8_t *data, size_t datalen) { downstream->reset_upstream_rtimer(); if (downstream->push_upload_data_chunk(data, datalen) != 0) { if (downstream->get_response_state() != DownstreamState::MSG_COMPLETE) { shutdown_stream(downstream, NGHTTP3_H3_INTERNAL_ERROR); } consume(downstream->get_stream_id(), datalen); return 0; } return 0; } namespace { int http_end_stream(nghttp3_conn *conn, int64_t stream_id, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); auto downstream = static_cast(stream_user_data); if (!downstream || downstream->get_stop_reading()) { return 0; } if (upstream->http_end_stream(downstream) != 0) { return NGHTTP3_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::http_end_stream(Downstream *downstream) { downstream->disable_upstream_rtimer(); if (downstream->end_upload_data() != 0) { if (downstream->get_response_state() != DownstreamState::MSG_COMPLETE) { shutdown_stream(downstream, NGHTTP3_H3_INTERNAL_ERROR); } } downstream->set_request_state(DownstreamState::MSG_COMPLETE); return 0; } namespace { int http_stream_close(nghttp3_conn *conn, int64_t stream_id, uint64_t app_error_code, void *conn_user_data, void *stream_user_data) { auto upstream = static_cast(conn_user_data); auto downstream = static_cast(stream_user_data); if (!downstream) { return 0; } if (upstream->http_stream_close(downstream, app_error_code) != 0) { return NGHTTP3_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::http_stream_close(Downstream *downstream, uint64_t app_error_code) { auto stream_id = downstream->get_stream_id(); if (LOG_ENABLED(INFO)) { ULOG(INFO, this) << "Stream stream_id=" << stream_id << " is being closed with app_error_code=" << app_error_code; auto body = downstream->get_response_buf(); ULOG(INFO, this) << "response unacked_left=" << body->rleft() << " not_sent=" << body->rleft_mark(); } auto &req = downstream->request(); consume(stream_id, req.unconsumed_body_length); req.unconsumed_body_length = 0; ngtcp2_conn_extend_max_streams_bidi(conn_, 1); if (downstream->get_request_state() == DownstreamState::CONNECT_FAIL) { remove_downstream(downstream); // downstream was deleted return 0; } if (downstream->can_detach_downstream_connection()) { // Keep-alive downstream->detach_downstream_connection(); } downstream->set_request_state(DownstreamState::STREAM_CLOSED); // At this point, downstream read may be paused. // If shrpx_downstream::push_request_headers() failed, the // error is handled here. remove_downstream(downstream); // downstream was deleted return 0; } namespace { int http_stop_sending(nghttp3_conn *conn, int64_t stream_id, uint64_t app_error_code, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); if (upstream->http_stop_sending(stream_id, app_error_code) != 0) { return NGHTTP3_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::http_stop_sending(int64_t stream_id, uint64_t app_error_code) { auto rv = ngtcp2_conn_shutdown_stream_read(conn_, stream_id, app_error_code); if (ngtcp2_err_is_fatal(rv)) { ULOG(ERROR, this) << "ngtcp2_conn_shutdown_stream_read: " << ngtcp2_strerror(rv); return -1; } return 0; } namespace { int http_reset_stream(nghttp3_conn *conn, int64_t stream_id, uint64_t app_error_code, void *user_data, void *stream_user_data) { auto upstream = static_cast(user_data); if (upstream->http_reset_stream(stream_id, app_error_code) != 0) { return NGHTTP3_ERR_CALLBACK_FAILURE; } return 0; } } // namespace int Http3Upstream::http_reset_stream(int64_t stream_id, uint64_t app_error_code) { auto rv = ngtcp2_conn_shutdown_stream_write(conn_, stream_id, app_error_code); if (ngtcp2_err_is_fatal(rv)) { ULOG(ERROR, this) << "ngtcp2_conn_shutdown_stream_write: " << ngtcp2_strerror(rv); return -1; } return 0; } int Http3Upstream::setup_httpconn() { int rv; if (ngtcp2_conn_get_max_local_streams_uni(conn_) < 3) { return -1; } nghttp3_callbacks callbacks{ shrpx::http_acked_stream_data, shrpx::http_stream_close, shrpx::http_recv_data, http_deferred_consume, shrpx::http_begin_request_headers, shrpx::http_recv_request_header, shrpx::http_end_request_headers, nullptr, // begin_trailers shrpx::http_recv_request_trailer, nullptr, // end_trailers shrpx::http_stop_sending, shrpx::http_end_stream, shrpx::http_reset_stream, }; auto config = get_config(); nghttp3_settings settings; nghttp3_settings_default(&settings); settings.qpack_max_dtable_capacity = 4_k; if (!config->http2_proxy) { settings.enable_connect_protocol = 1; } auto mem = nghttp3_mem_default(); rv = nghttp3_conn_server_new(&httpconn_, &callbacks, &settings, mem, this); if (rv != 0) { ULOG(ERROR, this) << "nghttp3_conn_server_new: " << nghttp3_strerror(rv); return -1; } auto params = ngtcp2_conn_get_local_transport_params(conn_); nghttp3_conn_set_max_client_streams_bidi(httpconn_, params->initial_max_streams_bidi); int64_t ctrl_stream_id; rv = ngtcp2_conn_open_uni_stream(conn_, &ctrl_stream_id, nullptr); if (rv != 0) { ULOG(ERROR, this) << "ngtcp2_conn_open_uni_stream: " << ngtcp2_strerror(rv); return -1; } rv = nghttp3_conn_bind_control_stream(httpconn_, ctrl_stream_id); if (rv != 0) { ULOG(ERROR, this) << "nghttp3_conn_bind_control_stream: " << nghttp3_strerror(rv); return -1; } int64_t qpack_enc_stream_id, qpack_dec_stream_id; rv = ngtcp2_conn_open_uni_stream(conn_, &qpack_enc_stream_id, nullptr); if (rv != 0) { ULOG(ERROR, this) << "ngtcp2_conn_open_uni_stream: " << ngtcp2_strerror(rv); return -1; } rv = ngtcp2_conn_open_uni_stream(conn_, &qpack_dec_stream_id, nullptr); if (rv != 0) { ULOG(ERROR, this) << "ngtcp2_conn_open_uni_stream: " << ngtcp2_strerror(rv); return -1; } rv = nghttp3_conn_bind_qpack_streams(httpconn_, qpack_enc_stream_id, qpack_dec_stream_id); if (rv != 0) { ULOG(ERROR, this) << "nghttp3_conn_bind_qpack_streams: " << nghttp3_strerror(rv); return -1; } return 0; } int Http3Upstream::error_reply(Downstream *downstream, unsigned int status_code) { int rv; auto &resp = downstream->response(); auto &balloc = downstream->get_block_allocator(); auto html = http::create_error_html(balloc, status_code); resp.http_status = status_code; auto body = downstream->get_response_buf(); body->append(html); downstream->set_response_state(DownstreamState::MSG_COMPLETE); nghttp3_data_reader data_read; data_read.read_data = downstream_read_data_callback; auto lgconf = log_config(); lgconf->update_tstamp(std::chrono::system_clock::now()); auto response_status = http2::stringify_status(balloc, status_code); auto content_length = util::make_string_ref_uint(balloc, html.size()); auto date = make_string_ref(balloc, lgconf->tstamp->time_http); auto nva = std::array{ {http3::make_nv_ls_nocopy(":status", response_status), http3::make_nv_ll("content-type", "text/html; charset=UTF-8"), http3::make_nv_ls_nocopy("server", get_config()->http.server_name), http3::make_nv_ls_nocopy("content-length", content_length), http3::make_nv_ls_nocopy("date", date)}}; rv = nghttp3_conn_submit_response(httpconn_, downstream->get_stream_id(), nva.data(), nva.size(), &data_read); if (nghttp3_err_is_fatal(rv)) { ULOG(FATAL, this) << "nghttp3_conn_submit_response() failed: " << nghttp3_strerror(rv); return -1; } downstream->reset_upstream_wtimer(); if (shutdown_stream_read(downstream->get_stream_id(), NGHTTP3_H3_NO_ERROR) != 0) { return -1; } return 0; } int Http3Upstream::shutdown_stream(Downstream *downstream, uint64_t app_error_code) { auto stream_id = downstream->get_stream_id(); if (LOG_ENABLED(INFO)) { ULOG(INFO, this) << "Shutdown stream_id=" << stream_id << " with app_error_code=" << app_error_code; } auto rv = ngtcp2_conn_shutdown_stream(conn_, stream_id, app_error_code); if (rv != 0) { ULOG(FATAL, this) << "ngtcp2_conn_shutdown_stream() failed: " << ngtcp2_strerror(rv); return -1; } return 0; } int Http3Upstream::shutdown_stream_read(int64_t stream_id, uint64_t app_error_code) { auto rv = ngtcp2_conn_shutdown_stream_read(conn_, stream_id, NGHTTP3_H3_NO_ERROR); if (ngtcp2_err_is_fatal(rv)) { ULOG(FATAL, this) << "ngtcp2_conn_shutdown_stream_read: " << ngtcp2_strerror(rv); return -1; } return 0; } void Http3Upstream::consume(int64_t stream_id, size_t nconsumed) { ngtcp2_conn_extend_max_stream_offset(conn_, stream_id, nconsumed); ngtcp2_conn_extend_max_offset(conn_, nconsumed); } void Http3Upstream::remove_downstream(Downstream *downstream) { if (downstream->accesslog_ready()) { handler_->write_accesslog(downstream); } nghttp3_conn_set_stream_user_data(httpconn_, downstream->get_stream_id(), nullptr); auto next_downstream = downstream_queue_.remove_and_get_blocked(downstream); if (next_downstream) { initiate_downstream(next_downstream); } if (downstream_queue_.get_downstreams() == nullptr) { // There is no downstream at the moment. Start idle timer now. handler_->repeat_read_timer(); } } void Http3Upstream::log_response_headers( Downstream *downstream, const std::vector &nva) const { std::stringstream ss; for (auto &nv : nva) { ss << TTY_HTTP_HD << StringRef{nv.name, nv.namelen} << TTY_RST << ": " << StringRef{nv.value, nv.valuelen} << "\n"; } ULOG(INFO, this) << "HTTP response headers. stream_id=" << downstream->get_stream_id() << "\n" << ss.str(); } int Http3Upstream::check_shutdown() { auto worker = handler_->get_worker(); if (!worker->get_graceful_shutdown()) { return 0; } ev_prepare_stop(handler_->get_loop(), &prep_); return start_graceful_shutdown(); } int Http3Upstream::start_graceful_shutdown() { int rv; if (ev_is_active(&shutdown_timer_)) { return 0; } rv = nghttp3_conn_submit_shutdown_notice(httpconn_); if (rv != 0) { ULOG(FATAL, this) << "nghttp3_conn_submit_shutdown_notice: " << nghttp3_strerror(rv); return -1; } handler_->signal_write(); auto t = ngtcp2_conn_get_pto(conn_); ev_timer_set(&shutdown_timer_, static_cast(t * 3) / NGTCP2_SECONDS, 0.); ev_timer_start(handler_->get_loop(), &shutdown_timer_); return 0; } int Http3Upstream::submit_goaway() { int rv; rv = nghttp3_conn_shutdown(httpconn_); if (rv != 0) { ULOG(FATAL, this) << "nghttp3_conn_shutdown: " << nghttp3_strerror(rv); return -1; } handler_->signal_write(); return 0; } int Http3Upstream::open_qlog_file(const StringRef &dir, const ngtcp2_cid &scid) const { std::array buf; auto path = dir.str(); path += '/'; path += util::format_iso8601_basic(buf.data(), std::chrono::system_clock::now()); path += '-'; path += util::format_hex(scid.data, scid.datalen); path += ".sqlog"; int fd; #ifdef O_CLOEXEC while ((fd = open(path.c_str(), O_WRONLY | O_CREAT | O_TRUNC | O_CLOEXEC, S_IRUSR | S_IWUSR | S_IRGRP)) == -1 && errno == EINTR) ; #else // !O_CLOEXEC while ((fd = open(path.c_str(), O_WRONLY | O_CREAT | O_TRUNC, S_IRUSR | S_IWUSR | S_IRGRP)) == -1 && errno == EINTR) ; if (fd != -1) { util::make_socket_closeonexec(fd); } #endif // !O_CLOEXEC if (fd == -1) { auto error = errno; ULOG(ERROR, this) << "Failed to open qlog file " << path << ": errno=" << error; return -1; } return fd; } ngtcp2_conn *Http3Upstream::get_conn() const { return conn_; } } // namespace shrpx