/* * nghttp2 - HTTP/2 C Library * * Copyright (c) 2015 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_worker_process.h" #include #ifdef HAVE_UNISTD_H #include #endif // HAVE_UNISTD_H #include #include #include #include #include #include #include "shrpx_config.h" #include "shrpx_connection_handler.h" #include "shrpx_log_config.h" #include "shrpx_worker.h" #include "shrpx_accept_handler.h" #include "shrpx_http2_upstream.h" #include "shrpx_http2_session.h" #include "shrpx_memcached_dispatcher.h" #include "shrpx_memcached_request.h" #include "shrpx_process.h" #include "shrpx_ssl.h" #include "util.h" #include "app_helper.h" #include "template.h" using namespace nghttp2; namespace shrpx { namespace { void drop_privileges( #ifdef HAVE_NEVERBLEED neverbleed_t *nb #endif // HAVE_NEVERBLEED ) { if (getuid() == 0 && get_config()->uid != 0) { if (initgroups(get_config()->user.get(), get_config()->gid) != 0) { auto error = errno; LOG(FATAL) << "Could not change supplementary groups: " << strerror(error); exit(EXIT_FAILURE); } if (setgid(get_config()->gid) != 0) { auto error = errno; LOG(FATAL) << "Could not change gid: " << strerror(error); exit(EXIT_FAILURE); } if (setuid(get_config()->uid) != 0) { auto error = errno; LOG(FATAL) << "Could not change uid: " << strerror(error); exit(EXIT_FAILURE); } if (setuid(0) != -1) { LOG(FATAL) << "Still have root privileges?"; exit(EXIT_FAILURE); } #ifdef HAVE_NEVERBLEED if (nb) { neverbleed_setuidgid(nb, get_config()->user.get(), 1); } #endif // HAVE_NEVERBLEED } } } // namespace namespace { void graceful_shutdown(ConnectionHandler *conn_handler) { if (conn_handler->get_graceful_shutdown()) { return; } LOG(NOTICE) << "Graceful shutdown signal received"; conn_handler->set_graceful_shutdown(true); conn_handler->disable_acceptor(); // After disabling accepting new connection, disptach incoming // connection in backlog. conn_handler->accept_pending_connection(); conn_handler->graceful_shutdown_worker(); if (get_config()->num_worker == 1) { if (conn_handler->get_single_worker()->get_worker_stat()->num_connections == 0) { ev_break(conn_handler->get_loop()); } return; } } } // namespace namespace { void reopen_log(ConnectionHandler *conn_handler) { LOG(NOTICE) << "Reopening log files: worker process (thread main)"; (void)reopen_log_files(); redirect_stderr_to_errorlog(); if (get_config()->num_worker > 1) { conn_handler->worker_reopen_log_files(); } } } // namespace namespace { void ipc_readcb(struct ev_loop *loop, ev_io *w, int revents) { auto conn_handler = static_cast(w->data); std::array buf; ssize_t nread; while ((nread = read(w->fd, buf.data(), buf.size())) == -1 && errno == EINTR) ; if (nread == -1) { auto error = errno; LOG(ERROR) << "Failed to read data from ipc channel: errno=" << error; return; } if (nread == 0) { // IPC socket closed. Perform immediate shutdown. LOG(FATAL) << "IPC socket is closed. Perform immediate shutdown."; _Exit(EXIT_FAILURE); } for (ssize_t i = 0; i < nread; ++i) { switch (buf[i]) { case SHRPX_IPC_GRACEFUL_SHUTDOWN: graceful_shutdown(conn_handler); break; case SHRPX_IPC_REOPEN_LOG: reopen_log(conn_handler); break; } } } } // namespace namespace { int generate_ticket_key(TicketKey &ticket_key) { ticket_key.cipher = get_config()->tls.ticket.cipher; ticket_key.hmac = EVP_sha256(); ticket_key.hmac_keylen = EVP_MD_size(ticket_key.hmac); assert(static_cast(EVP_CIPHER_key_length(ticket_key.cipher)) <= ticket_key.data.enc_key.size()); assert(ticket_key.hmac_keylen <= ticket_key.data.hmac_key.size()); if (LOG_ENABLED(INFO)) { LOG(INFO) << "enc_keylen=" << EVP_CIPHER_key_length(ticket_key.cipher) << ", hmac_keylen=" << ticket_key.hmac_keylen; } if (RAND_bytes(reinterpret_cast(&ticket_key.data), sizeof(ticket_key.data)) == 0) { return -1; } return 0; } } // namespace namespace { void renew_ticket_key_cb(struct ev_loop *loop, ev_timer *w, int revents) { auto conn_handler = static_cast(w->data); const auto &old_ticket_keys = conn_handler->get_ticket_keys(); auto ticket_keys = std::make_shared(); LOG(NOTICE) << "Renew new ticket keys"; // If old_ticket_keys is not empty, it should contain at least 2 // keys: one for encryption, and last one for the next encryption // key but decryption only. The keys in between are old keys and // decryption only. The next key is provided to ensure to mitigate // possible problem when one worker encrypt new key, but one worker, // which did not take the that key yet, and cannot decrypt it. // // We keep keys for get_config()->tls_session_timeout seconds. The // default is 12 hours. Thus the maximum ticket vector size is 12. if (old_ticket_keys) { auto &old_keys = old_ticket_keys->keys; auto &new_keys = ticket_keys->keys; assert(!old_keys.empty()); auto max_tickets = static_cast(std::chrono::duration_cast( get_config()->tls.session_timeout).count()); new_keys.resize(std::min(max_tickets, old_keys.size() + 1)); std::copy_n(std::begin(old_keys), new_keys.size() - 1, std::begin(new_keys) + 1); } else { ticket_keys->keys.resize(1); } auto &new_key = ticket_keys->keys[0]; if (generate_ticket_key(new_key) != 0) { if (LOG_ENABLED(INFO)) { LOG(INFO) << "failed to generate ticket key"; } conn_handler->set_ticket_keys(nullptr); conn_handler->set_ticket_keys_to_worker(nullptr); return; } if (LOG_ENABLED(INFO)) { LOG(INFO) << "ticket keys generation done"; assert(ticket_keys->keys.size() >= 1); LOG(INFO) << 0 << " enc+dec: " << util::format_hex(ticket_keys->keys[0].data.name); for (size_t i = 1; i < ticket_keys->keys.size(); ++i) { auto &key = ticket_keys->keys[i]; LOG(INFO) << i << " dec: " << util::format_hex(key.data.name); } } conn_handler->set_ticket_keys(ticket_keys); conn_handler->set_ticket_keys_to_worker(ticket_keys); } } // namespace namespace { void memcached_get_ticket_key_cb(struct ev_loop *loop, ev_timer *w, int revents) { auto conn_handler = static_cast(w->data); auto dispatcher = conn_handler->get_tls_ticket_key_memcached_dispatcher(); auto req = make_unique(); req->key = "nghttpx:tls-ticket-key"; req->op = MEMCACHED_OP_GET; req->cb = [conn_handler, dispatcher, w](MemcachedRequest *req, MemcachedResult res) { switch (res.status_code) { case MEMCACHED_ERR_NO_ERROR: break; case MEMCACHED_ERR_EXT_NETWORK_ERROR: conn_handler->on_tls_ticket_key_network_error(w); return; default: conn_handler->on_tls_ticket_key_not_found(w); return; } // |version (4bytes)|len (2bytes)|key (variable length)|... // (len, key) pairs are repeated as necessary. auto &value = res.value; if (value.size() < 4) { LOG(WARN) << "Memcached: tls ticket key value is too small: got " << value.size(); conn_handler->on_tls_ticket_key_not_found(w); return; } auto p = value.data(); auto version = util::get_uint32(p); // Currently supported version is 1. if (version != 1) { LOG(WARN) << "Memcached: tls ticket key version: want 1, got " << version; conn_handler->on_tls_ticket_key_not_found(w); return; } auto end = p + value.size(); p += 4; auto &ticketconf = get_config()->tls.ticket; size_t expectedlen; size_t enc_keylen; size_t hmac_keylen; if (ticketconf.cipher == EVP_aes_128_cbc()) { expectedlen = 48; enc_keylen = 16; hmac_keylen = 16; } else if (ticketconf.cipher == EVP_aes_256_cbc()) { expectedlen = 80; enc_keylen = 32; hmac_keylen = 32; } else { return; } auto ticket_keys = std::make_shared(); for (; p != end;) { if (end - p < 2) { LOG(WARN) << "Memcached: tls ticket key data is too small"; conn_handler->on_tls_ticket_key_not_found(w); return; } auto len = util::get_uint16(p); p += 2; if (len != expectedlen) { LOG(WARN) << "Memcached: wrong tls ticket key size: want " << expectedlen << ", got " << len; conn_handler->on_tls_ticket_key_not_found(w); return; } if (p + len > end) { LOG(WARN) << "Memcached: too short tls ticket key payload: want " << len << ", got " << (end - p); conn_handler->on_tls_ticket_key_not_found(w); return; } auto key = TicketKey(); key.cipher = ticketconf.cipher; key.hmac = EVP_sha256(); key.hmac_keylen = hmac_keylen; std::copy_n(p, key.data.name.size(), key.data.name.data()); p += key.data.name.size(); std::copy_n(p, enc_keylen, key.data.enc_key.data()); p += enc_keylen; std::copy_n(p, hmac_keylen, key.data.hmac_key.data()); p += hmac_keylen; ticket_keys->keys.push_back(std::move(key)); } conn_handler->on_tls_ticket_key_get_success(ticket_keys, w); }; if (LOG_ENABLED(INFO)) { LOG(INFO) << "Memcached: tls ticket key get request sent"; } dispatcher->add_request(std::move(req)); } } // namespace #ifdef HAVE_NEVERBLEED namespace { void nb_child_cb(struct ev_loop *loop, ev_child *w, int revents) { log_chld(w->rpid, w->rstatus, "neverbleed process"); ev_child_stop(loop, w); LOG(FATAL) << "neverbleed process exitted; aborting now"; _Exit(EXIT_FAILURE); } } // namespace #endif // HAVE_NEVERBLEED int worker_process_event_loop(WorkerProcessConfig *wpconf) { if (reopen_log_files() != 0) { LOG(FATAL) << "Failed to open log file"; return -1; } auto loop = EV_DEFAULT; ConnectionHandler conn_handler(loop); if (wpconf->server_fd6 != -1) { conn_handler.set_acceptor6( make_unique(wpconf->server_fd6, &conn_handler)); } if (wpconf->server_fd != -1) { conn_handler.set_acceptor( make_unique(wpconf->server_fd, &conn_handler)); } auto &upstreamconf = get_config()->conn.upstream; #ifdef HAVE_NEVERBLEED if (!upstreamconf.no_tls || ssl::downstream_tls_enabled()) { std::array errbuf; auto nb = make_unique(); if (neverbleed_init(nb.get(), errbuf.data()) != 0) { LOG(FATAL) << "neverbleed_init failed: " << errbuf.data(); return -1; } LOG(NOTICE) << "neverbleed process [" << nb->daemon_pid << "] spawned"; conn_handler.set_neverbleed(std::move(nb)); } auto nb = conn_handler.get_neverbleed(); ev_child nb_childev; if (nb) { ev_child_init(&nb_childev, nb_child_cb, nb->daemon_pid, 0); nb_childev.data = nullptr; ev_child_start(loop, &nb_childev); } #endif // HAVE_NEVERBLEED ev_timer renew_ticket_key_timer; if (!upstreamconf.no_tls) { auto &ticketconf = get_config()->tls.ticket; if (ticketconf.memcached.host) { conn_handler.set_tls_ticket_key_memcached_dispatcher( make_unique(&ticketconf.memcached.addr, loop)); ev_timer_init(&renew_ticket_key_timer, memcached_get_ticket_key_cb, 0., 0.); renew_ticket_key_timer.data = &conn_handler; // Get first ticket keys. memcached_get_ticket_key_cb(loop, &renew_ticket_key_timer, 0); } else { bool auto_tls_ticket_key = true; if (!ticketconf.files.empty()) { if (!ticketconf.cipher_given) { LOG(WARN) << "It is strongly recommended to specify " "--tls-ticket-key-cipher=aes-128-cbc (or " "tls-ticket-key-cipher=aes-128-cbc in configuration file) " "when --tls-ticket-key-file is used for the smooth " "transition when the default value of --tls-ticket-key-cipher " "becomes aes-256-cbc"; } auto ticket_keys = read_tls_ticket_key_file( ticketconf.files, ticketconf.cipher, EVP_sha256()); if (!ticket_keys) { LOG(WARN) << "Use internal session ticket key generator"; } else { conn_handler.set_ticket_keys(std::move(ticket_keys)); auto_tls_ticket_key = false; } } if (auto_tls_ticket_key) { // Generate new ticket key every 1hr. ev_timer_init(&renew_ticket_key_timer, renew_ticket_key_cb, 0., 1_h); renew_ticket_key_timer.data = &conn_handler; ev_timer_again(loop, &renew_ticket_key_timer); // Generate first session ticket key before running workers. renew_ticket_key_cb(loop, &renew_ticket_key_timer, 0); } } } int rv; if (get_config()->num_worker == 1) { rv = conn_handler.create_single_worker(); if (rv != 0) { return -1; } } else { #ifndef NOTHREADS sigset_t set; sigemptyset(&set); sigaddset(&set, SIGCHLD); rv = pthread_sigmask(SIG_BLOCK, &set, nullptr); if (rv != 0) { LOG(ERROR) << "Blocking SIGCHLD failed: " << strerror(rv); return -1; } #endif // !NOTHREADS rv = conn_handler.create_worker_thread(get_config()->num_worker); if (rv != 0) { return -1; } #ifndef NOTHREADS rv = pthread_sigmask(SIG_UNBLOCK, &set, nullptr); if (rv != 0) { LOG(ERROR) << "Unblocking SIGCHLD failed: " << strerror(rv); return -1; } #endif // !NOTHREADS } drop_privileges( #ifdef HAVE_NEVERBLEED nb #endif // HAVE_NEVERBLEED ); ev_io ipcev; ev_io_init(&ipcev, ipc_readcb, wpconf->ipc_fd, EV_READ); ipcev.data = &conn_handler; ev_io_start(loop, &ipcev); if (!upstreamconf.no_tls && !get_config()->tls.ocsp.disabled) { conn_handler.proceed_next_cert_ocsp(); } if (LOG_ENABLED(INFO)) { LOG(INFO) << "Entering event loop"; } ev_run(loop, 0); conn_handler.cancel_ocsp_update(); #ifdef HAVE_NEVERBLEED if (nb && nb->daemon_pid != -1) { kill(nb->daemon_pid, SIGTERM); } #endif // HAVE_NEVERBLEED return 0; } } // namespace shrpx