/* * nghttp2 - HTTP/2.0 C Library * * Copyright (c) 2012 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_client_handler.h" #include #include #include "shrpx_upstream.h" #include "shrpx_http2_upstream.h" #include "shrpx_https_upstream.h" #include "shrpx_config.h" #include "shrpx_http_downstream_connection.h" #include "shrpx_http2_downstream_connection.h" #include "shrpx_accesslog.h" #include "shrpx_ssl.h" #ifdef HAVE_SPDYLAY #include "shrpx_spdy_upstream.h" #endif // HAVE_SPDYLAY #include "util.h" using namespace nghttp2; namespace shrpx { namespace { void upstream_readcb(bufferevent *bev, void *arg) { auto handler = static_cast(arg); int rv = handler->on_read(); if(rv != 0) { delete handler; } } } // namespace namespace { void upstream_writecb(bufferevent *bev, void *arg) { auto handler = static_cast(arg); // We actually depend on write low-warter mark == 0. if(handler->get_outbuf_length() > 0) { // Possibly because of deferred callback, we may get this callback // when the output buffer is not empty. return; } if(handler->get_should_close_after_write()) { delete handler; return; } auto upstream = handler->get_upstream(); if(!upstream) { return; } int rv = upstream->on_write(); if(rv != 0) { delete handler; } } } // namespace namespace { void upstream_eventcb(bufferevent *bev, short events, void *arg) { auto handler = static_cast(arg); bool finish = false; if(events & BEV_EVENT_EOF) { if(LOG_ENABLED(INFO)) { CLOG(INFO, handler) << "EOF"; } finish = true; } if(events & BEV_EVENT_ERROR) { if(LOG_ENABLED(INFO)) { CLOG(INFO, handler) << "Network error: " << evutil_socket_error_to_string (EVUTIL_SOCKET_ERROR()); } finish = true; } if(events & BEV_EVENT_TIMEOUT) { if(LOG_ENABLED(INFO)) { CLOG(INFO, handler) << "Time out"; } finish = true; } if(finish) { delete handler; } else { if(events & BEV_EVENT_CONNECTED) { handler->set_tls_handshake(true); if(LOG_ENABLED(INFO)) { CLOG(INFO, handler) << "SSL/TLS handshake completed"; } if(handler->validate_next_proto() != 0) { delete handler; return; } if(LOG_ENABLED(INFO)) { if(SSL_session_reused(handler->get_ssl())) { CLOG(INFO, handler) << "SSL/TLS session reused"; } } // At this point, input buffer is already filled with some // bytes. The read callback is not called until new data // come. So consume input buffer here. if(handler->get_upstream()->on_read() != 0) { delete handler; return; } } } } } // namespace namespace { void upstream_http2_connhd_readcb(bufferevent *bev, void *arg) { // This callback assumes upstream is Http2Upstream. uint8_t data[NGHTTP2_CLIENT_CONNECTION_HEADER_LEN]; auto handler = static_cast(arg); auto leftlen = handler->get_left_connhd_len(); auto input = bufferevent_get_input(bev); auto readlen = evbuffer_remove(input, data, leftlen); if(readlen == -1) { delete handler; return; } if(memcmp(NGHTTP2_CLIENT_CONNECTION_HEADER + NGHTTP2_CLIENT_CONNECTION_HEADER_LEN - leftlen, data, readlen) != 0) { // There is no downgrade path here. Just drop the connection. if(LOG_ENABLED(INFO)) { CLOG(INFO, handler) << "invalid client connection header"; } delete handler; return; } leftlen -= readlen; handler->set_left_connhd_len(leftlen); if(leftlen == 0) { handler->set_bev_cb(upstream_readcb, upstream_writecb, upstream_eventcb); // Run on_read to process data left in buffer since they are not // notified further if(handler->on_read() != 0) { delete handler; return; } } } } // namespace namespace { void upstream_http1_connhd_readcb(bufferevent *bev, void *arg) { // This callback assumes upstream is HttpsUpstream. uint8_t data[NGHTTP2_CLIENT_CONNECTION_HEADER_LEN]; auto handler = static_cast(arg); auto leftlen = handler->get_left_connhd_len(); auto input = bufferevent_get_input(bev); auto readlen = evbuffer_copyout(input, data, leftlen); if(readlen == -1) { delete handler; return; } if(memcmp(NGHTTP2_CLIENT_CONNECTION_HEADER + NGHTTP2_CLIENT_CONNECTION_HEADER_LEN - leftlen, data, readlen) != 0) { if(LOG_ENABLED(INFO)) { CLOG(INFO, handler) << "This is HTTP/1.1 connection, " << "but may be upgraded to HTTP/2.0 later."; } // Reset header length for later HTTP/2.0 upgrade handler->set_left_connhd_len(NGHTTP2_CLIENT_CONNECTION_HEADER_LEN); handler->set_bev_cb(upstream_readcb, upstream_writecb, upstream_eventcb); if(handler->on_read() != 0) { delete handler; return; } return; } if(evbuffer_drain(input, readlen) == -1) { delete handler; return; } leftlen -= readlen; handler->set_left_connhd_len(leftlen); if(leftlen == 0) { if(LOG_ENABLED(INFO)) { CLOG(INFO, handler) << "direct HTTP/2.0 connection"; } handler->direct_http2_upgrade(); handler->set_bev_cb(upstream_readcb, upstream_writecb, upstream_eventcb); // Run on_read to process data left in buffer since they are not // notified further if(handler->on_read() != 0) { delete handler; return; } } } } // namespace namespace { void tls_raw_readcb(evbuffer *buffer, const evbuffer_cb_info *info, void *arg) { auto handler = static_cast(arg); if(handler->get_tls_renegotiation()) { if(LOG_ENABLED(INFO)) { CLOG(INFO, handler) << "Close connection due to TLS renegotiation"; } delete handler; } } } // namespace namespace { void tls_raw_writecb(evbuffer *buffer, const evbuffer_cb_info *info, void *arg) { auto handler = static_cast(arg); // upstream_writecb() is called when external bufferevent // handler->bev's output buffer gets empty. But the underlying // bufferevent may have pending output buffer. upstream_writecb(handler->get_bev(), handler); } } // namespace ClientHandler::ClientHandler(bufferevent *bev, bufferevent_rate_limit_group *rate_limit_group, int fd, SSL *ssl, const char *ipaddr) : ipaddr_(ipaddr), bev_(bev), http2session_(nullptr), ssl_(ssl), left_connhd_len_(NGHTTP2_CLIENT_CONNECTION_HEADER_LEN), fd_(fd), should_close_after_write_(false), tls_handshake_(false), tls_renegotiation_(false) { int rv; auto rate_limit_bev = bufferevent_get_underlying(bev_); if(!rate_limit_bev) { rate_limit_bev = bev_; } rv = bufferevent_set_rate_limit(rate_limit_bev, get_config()->rate_limit_cfg); if(rv == -1) { CLOG(FATAL, this) << "bufferevent_set_rate_limit() failed"; } rv = bufferevent_add_to_rate_limit_group(rate_limit_bev, rate_limit_group); if(rv == -1) { CLOG(FATAL, this) << "bufferevent_add_to_rate_limit_group() failed"; } bufferevent_enable(bev_, EV_READ | EV_WRITE); bufferevent_setwatermark(bev_, EV_READ, 0, SHRPX_READ_WARTER_MARK); set_upstream_timeouts(&get_config()->upstream_read_timeout, &get_config()->upstream_write_timeout); if(ssl_) { SSL_set_app_data(ssl_, reinterpret_cast(this)); set_bev_cb(nullptr, upstream_writecb, upstream_eventcb); auto input = bufferevent_get_input(bufferevent_get_underlying(bev_)); evbuffer_add_cb(input, tls_raw_readcb, this); auto output = bufferevent_get_output(bufferevent_get_underlying(bev_)); evbuffer_add_cb(output, tls_raw_writecb, this); } else { // For non-TLS version, first create HttpsUpstream. It may be // upgraded to HTTP/2.0 through HTTP Upgrade or direct HTTP/2.0 // connection. upstream_ = util::make_unique(this); set_bev_cb(upstream_http1_connhd_readcb, nullptr, upstream_eventcb); } } ClientHandler::~ClientHandler() { if(LOG_ENABLED(INFO)) { CLOG(INFO, this) << "Deleting"; } if(ssl_) { SSL_set_app_data(ssl_, nullptr); SSL_set_shutdown(ssl_, SSL_RECEIVED_SHUTDOWN); SSL_shutdown(ssl_); } auto underlying = bufferevent_get_underlying(bev_); if(underlying) { bufferevent_remove_from_rate_limit_group(underlying); } else { bufferevent_remove_from_rate_limit_group(bev_); } bufferevent_disable(bev_, EV_READ | EV_WRITE); bufferevent_free(bev_); if(ssl_) { SSL_free(ssl_); } if(underlying) { bufferevent_disable(underlying, EV_READ | EV_WRITE); bufferevent_free(underlying); } shutdown(fd_, SHUT_WR); close(fd_); for(auto dconn : dconn_pool_) { delete dconn; } if(LOG_ENABLED(INFO)) { CLOG(INFO, this) << "Deleted"; } } Upstream* ClientHandler::get_upstream() { return upstream_.get(); } bufferevent* ClientHandler::get_bev() const { return bev_; } event_base* ClientHandler::get_evbase() const { return bufferevent_get_base(bev_); } void ClientHandler::set_bev_cb (bufferevent_data_cb readcb, bufferevent_data_cb writecb, bufferevent_event_cb eventcb) { bufferevent_setcb(bev_, readcb, writecb, eventcb, this); } void ClientHandler::set_upstream_timeouts(const timeval *read_timeout, const timeval *write_timeout) { bufferevent_set_timeouts(bev_, read_timeout, write_timeout); } int ClientHandler::validate_next_proto() { const unsigned char *next_proto = nullptr; unsigned int next_proto_len; // First set callback for catch all cases set_bev_cb(upstream_readcb, upstream_writecb, upstream_eventcb); SSL_get0_next_proto_negotiated(ssl_, &next_proto, &next_proto_len); for(int i = 0; i < 2; ++i) { if(next_proto) { if(LOG_ENABLED(INFO)) { std::string proto(next_proto, next_proto+next_proto_len); CLOG(INFO, this) << "The negotiated next protocol: " << proto; } if(!ssl::in_proto_list(get_config()->npn_list, get_config()->npn_list_len, next_proto, next_proto_len)) { break; } if(next_proto_len == NGHTTP2_PROTO_VERSION_ID_LEN && memcmp(NGHTTP2_PROTO_VERSION_ID, next_proto, NGHTTP2_PROTO_VERSION_ID_LEN) == 0) { set_bev_cb(upstream_http2_connhd_readcb, upstream_writecb, upstream_eventcb); upstream_ = util::make_unique(this); return 0; } else { #ifdef HAVE_SPDYLAY uint16_t version = spdylay_npn_get_version(next_proto, next_proto_len); if(version) { upstream_ = util::make_unique(version, this); return 0; } #endif // HAVE_SPDYLAY if(next_proto_len == 8 && memcmp("http/1.1", next_proto, 8) == 0) { upstream_ = util::make_unique(this); return 0; } } break; } #if OPENSSL_VERSION_NUMBER >= 0x10002000L SSL_get0_alpn_selected(ssl_, &next_proto, &next_proto_len); #else // OPENSSL_VERSION_NUMBER < 0x10002000L break; #endif // OPENSSL_VERSION_NUMBER < 0x10002000L } if(!next_proto) { if(LOG_ENABLED(INFO)) { CLOG(INFO, this) << "No protocol negotiated. Fallback to HTTP/1.1"; } upstream_ = util::make_unique(this); return 0; } if(LOG_ENABLED(INFO)) { CLOG(INFO, this) << "The negotiated protocol is not supported"; } return -1; } int ClientHandler::on_read() { return upstream_->on_read(); } int ClientHandler::on_event() { return upstream_->on_event(); } const std::string& ClientHandler::get_ipaddr() const { return ipaddr_; } bool ClientHandler::get_should_close_after_write() const { return should_close_after_write_; } void ClientHandler::set_should_close_after_write(bool f) { should_close_after_write_ = f; } void ClientHandler::pool_downstream_connection(DownstreamConnection *dconn) { if(LOG_ENABLED(INFO)) { CLOG(INFO, this) << "Pooling downstream connection DCONN:" << dconn; } dconn_pool_.insert(dconn); } void ClientHandler::remove_downstream_connection(DownstreamConnection *dconn) { if(LOG_ENABLED(INFO)) { CLOG(INFO, this) << "Removing downstream connection DCONN:" << dconn << " from pool"; } dconn_pool_.erase(dconn); } DownstreamConnection* ClientHandler::get_downstream_connection() { if(dconn_pool_.empty()) { if(LOG_ENABLED(INFO)) { CLOG(INFO, this) << "Downstream connection pool is empty." << " Create new one"; } if(http2session_) { return new Http2DownstreamConnection(this); } else { return new HttpDownstreamConnection(this); } } else { auto dconn = *std::begin(dconn_pool_); dconn_pool_.erase(dconn); if(LOG_ENABLED(INFO)) { CLOG(INFO, this) << "Reuse downstream connection DCONN:" << dconn << " from pool"; } return dconn; } } size_t ClientHandler::get_outbuf_length() { auto underlying = bufferevent_get_underlying(bev_); auto len = evbuffer_get_length(bufferevent_get_output(bev_)); if(underlying) { len += evbuffer_get_length(bufferevent_get_output(underlying)); } return len; } SSL* ClientHandler::get_ssl() const { return ssl_; } void ClientHandler::set_http2_session(Http2Session *http2session) { http2session_ = http2session; } Http2Session* ClientHandler::get_http2_session() const { return http2session_; } size_t ClientHandler::get_left_connhd_len() const { return left_connhd_len_; } void ClientHandler::set_left_connhd_len(size_t left) { left_connhd_len_ = left; } void ClientHandler::direct_http2_upgrade() { upstream_= util::make_unique(this); set_bev_cb(upstream_readcb, upstream_writecb, upstream_eventcb); } int ClientHandler::perform_http2_upgrade(HttpsUpstream *http) { int rv; auto upstream = util::make_unique(this); if(upstream->upgrade_upstream(http) != 0) { return -1; } // http pointer is now owned by upstream. upstream_.release(); upstream_ = std::move(upstream); set_bev_cb(upstream_http2_connhd_readcb, upstream_writecb, upstream_eventcb); static char res[] = "HTTP/1.1 101 Switching Protocols\r\n" "Connection: Upgrade\r\n" "Upgrade: " NGHTTP2_PROTO_VERSION_ID "\r\n" "\r\n"; rv = bufferevent_write(bev_, res, sizeof(res) - 1); if(rv != 0) { CLOG(FATAL, this) << "bufferevent_write() faild"; return -1; } return 0; } bool ClientHandler::get_http2_upgrade_allowed() const { return !ssl_; } std::string ClientHandler::get_upstream_scheme() const { if(ssl_) { return "https"; } else { return "http"; } } void ClientHandler::set_tls_handshake(bool f) { tls_handshake_ = f; } bool ClientHandler::get_tls_handshake() const { return tls_handshake_; } void ClientHandler::set_tls_renegotiation(bool f) { tls_renegotiation_ = f; } bool ClientHandler::get_tls_renegotiation() const { return tls_renegotiation_; } } // namespace shrpx