/* Copyright (c) 2012, Matthias Schiffer All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #define _GNU_SOURCE #include "fastd.h" #include "crypto.h" #include "handshake.h" #include "peer.h" #include "task.h" #include #include #include #include #include #include #include #include #include #include #include static volatile bool sighup = false; static volatile bool terminate = false; static void on_sighup(int signo) { sighup = true; } static void on_terminate(int signo) { terminate = true; } static void init_signals(fastd_context *ctx) { struct sigaction action; action.sa_flags = 0; sigemptyset(&action.sa_mask); action.sa_handler = on_sighup; if(sigaction(SIGHUP, &action, NULL)) exit_errno(ctx, "sigaction"); action.sa_handler = on_terminate; if(sigaction(SIGTERM, &action, NULL)) exit_errno(ctx, "sigaction"); if(sigaction(SIGQUIT, &action, NULL)) exit_errno(ctx, "sigaction"); if(sigaction(SIGINT, &action, NULL)) exit_errno(ctx, "sigaction"); action.sa_handler = SIG_IGN; if(sigaction(SIGPIPE, &action, NULL)) exit_errno(ctx, "sigaction"); } static void init_pipes(fastd_context *ctx) { int pipefd[2]; if (pipe(pipefd)) exit_errno(ctx, "pipe"); ctx->resolverfd = pipefd[0]; ctx->resolvewfd = pipefd[1]; } static void init_log(fastd_context *ctx) { if (ctx->conf->log_syslog_level >= 0) openlog(ctx->conf->log_syslog_ident, LOG_PID, LOG_DAEMON); fastd_log_file *config; for (config = ctx->conf->log_files; config; config = config->next) { fastd_log_fd *file = malloc(sizeof(fastd_log_fd)); file->config = config; file->fd = open(config->filename, O_WRONLY|O_APPEND|O_CREAT, 0600); file->next = ctx->log_files; ctx->log_files = file; } } static void close_log(fastd_context *ctx) { while (ctx->log_files) { fastd_log_fd *next = ctx->log_files->next; close(ctx->log_files->fd); free(ctx->log_files); ctx->log_files = next; } closelog(); } static void crypto_init(fastd_context *ctx) { #ifdef USE_CRYPTO_AES128CTR ctx->crypto_aes128ctr = ctx->conf->crypto_aes128ctr->init(ctx); if (!ctx->crypto_aes128ctr) exit_error(ctx, "Unable to initialize AES128-CTR implementation"); #endif #ifdef USE_CRYPTO_GHASH ctx->crypto_ghash = ctx->conf->crypto_ghash->init(ctx); if (!ctx->crypto_ghash) exit_error(ctx, "Unable to initialize GHASH implementation"); #endif } static void crypto_free(fastd_context *ctx) { #ifdef USE_CRYPTO_AES128CTR ctx->conf->crypto_aes128ctr->free(ctx, ctx->crypto_aes128ctr); ctx->crypto_aes128ctr = NULL; #endif #ifdef USE_CRYPTO_GHASH ctx->conf->crypto_ghash->free(ctx, ctx->crypto_ghash); ctx->crypto_ghash = NULL; #endif } static unsigned max_sockets(const fastd_config *conf) { unsigned n = 0; fastd_bind_address *addr; for (addr = conf->bind_addrs; addr; addr = addr->next) n++; return n; } static void init_sockets(fastd_context *ctx) { static const fastd_bind_address bind_any = {}; const fastd_bind_address *addr = ctx->conf->bind_addrs; const fastd_bind_address *default_v4 = ctx->conf->bind_addr_default_v4; const fastd_bind_address *default_v6 = ctx->conf->bind_addr_default_v6; if (!addr) addr = default_v4 = default_v6 = &bind_any; unsigned n_v4 = 0, n_v6 = 0; bool info_ipv6 = true; ctx->socks = calloc(max_sockets(ctx->conf), sizeof(fastd_socket)); while (addr) { int fd = -1; int af = AF_UNSPEC; if (addr->addr.sa.sa_family != AF_INET) { fd = socket(PF_INET6, SOCK_DGRAM, IPPROTO_UDP); if (fd < 0) { if (info_ipv6) { pr_warn(ctx, "there seems to be no IPv6 support; explicitely bind to an IPv4 address (or 0.0.0.0) to disable this warning"); info_ipv6 = false; } } else { af = AF_INET6; int val = (addr->addr.sa.sa_family == AF_INET6); if (setsockopt(fd, IPPROTO_IPV6, IPV6_V6ONLY, &val, sizeof(val))) { pr_warn_errno(ctx, "setsockopt"); goto error; } } } if (fd < 0 && addr->addr.sa.sa_family != AF_INET6) { fd = socket(PF_INET, SOCK_DGRAM, IPPROTO_UDP); if (fd < 0) exit_errno(ctx, "unable to create socket"); else af = AF_INET; } if (fd < 0) goto error; if (addr->bindtodev) { if (setsockopt(fd, SOL_SOCKET, SO_BINDTODEVICE, addr->bindtodev, strlen(addr->bindtodev))) { pr_warn_errno(ctx, "setsockopt: unable to bind to device"); goto error; } } fastd_peer_address bind_address = addr->addr; if (bind_address.sa.sa_family == AF_UNSPEC) { memset(&bind_address, 0, sizeof(bind_address)); bind_address.sa.sa_family = af; if (af == AF_INET6) bind_address.in6.sin6_port = addr->addr.in.sin_port; else bind_address.in.sin_port = addr->addr.in.sin_port; } if (bind(fd, (struct sockaddr*)&bind_address, af == AF_INET6 ? sizeof(struct sockaddr_in6) : sizeof(struct sockaddr_in))) { pr_warn(ctx, "bind"); goto error; } ctx->socks[ctx->n_socks] = (fastd_socket){fd, addr}; if (af == AF_INET6) { if (addr == default_v6) ctx->sock_default_v6 = &ctx->socks[ctx->n_socks]; n_v6++; if (addr->addr.sa.sa_family == AF_UNSPEC) { if (addr == default_v4) ctx->sock_default_v4 = &ctx->socks[ctx->n_socks]; n_v4++; } } else { if (addr == default_v4) ctx->sock_default_v4 = &ctx->socks[ctx->n_socks]; n_v4++; } ctx->n_socks++; addr = addr->next; continue; error: if (fd >= 0) { if (close(fd)) pr_error_errno(ctx, "close"); } if (addr->bindtodev) pr_warn(ctx, "unable to bind to %I on `%s'", &addr->addr, addr->bindtodev); else pr_warn(ctx, "unable to bind to %I", &addr->addr); if (addr == default_v4 || addr == default_v6) exit_error(ctx, "unable to bind to default address"); addr = addr->next; } if (!ctx->n_socks) exit_error(ctx, "all bind attempts failed"); if (!n_v4 && ctx->conf->n_v4) pr_warn(ctx, "there are IPv4 peers defined, but there was no successful IPv4 bind"); if (!n_v6 && ctx->conf->n_v6) pr_warn(ctx, "there are IPv6 peers defined, but there was no successful IPv4 bind"); } static void init_tuntap(fastd_context *ctx) { struct ifreq ifr; pr_debug(ctx, "initializing tun/tap device..."); if ((ctx->tunfd = open("/dev/net/tun", O_RDWR)) < 0) exit_errno(ctx, "could not open tun/tap device file"); memset(&ifr, 0, sizeof(ifr)); if (ctx->conf->ifname) strncpy(ifr.ifr_name, ctx->conf->ifname, IFNAMSIZ); switch (ctx->conf->mode) { case MODE_TAP: ifr.ifr_flags = IFF_TAP; break; case MODE_TUN: ifr.ifr_flags = IFF_TUN; break; default: exit_bug(ctx, "invalid mode"); } ifr.ifr_flags |= IFF_NO_PI; if (ioctl(ctx->tunfd, TUNSETIFF, &ifr) < 0) exit_errno(ctx, "TUNSETIFF ioctl failed"); ctx->ifname = strndup(ifr.ifr_name, IFNAMSIZ); int ctl_sock = ctx->socks[0].fd; ifr.ifr_mtu = ctx->conf->mtu; if (ioctl(ctl_sock, SIOCSIFMTU, &ifr) < 0) exit_errno(ctx, "SIOCSIFMTU ioctl failed"); pr_debug(ctx, "tun/tap device initialized."); } static void close_tuntap(fastd_context *ctx) { if(close(ctx->tunfd)) pr_warn_errno(ctx, "closing tun/tap: close"); free(ctx->ifname); } static void close_sockets(fastd_context *ctx) { unsigned i; for (i = 0; i < ctx->n_socks; i++) { if(close(ctx->socks[i].fd)) pr_warn_errno(ctx, "closing IPv4 socket: close"); } free(ctx->socks); } static size_t methods_max_packet_size(fastd_context *ctx) { size_t ret = ctx->conf->methods[0]->max_packet_size(ctx); int i; for (i = 0; i < MAX_METHODS; i++) { if (!ctx->conf->methods[i]) break; size_t s = ctx->conf->methods[i]->max_packet_size(ctx); if (s > ret) ret = s; } return ret; } static size_t methods_min_encrypt_head_space(fastd_context *ctx) { size_t ret = ctx->conf->methods[0]->min_encrypt_head_space(ctx); int i; for (i = 0; i < MAX_METHODS; i++) { if (!ctx->conf->methods[i]) break; size_t s = ctx->conf->methods[i]->min_encrypt_head_space(ctx); if (s > ret) ret = s; } return alignto(ret, 16); } static size_t methods_min_decrypt_head_space(fastd_context *ctx) { size_t ret = ctx->conf->methods[0]->min_decrypt_head_space(ctx); int i; for (i = 0; i < MAX_METHODS; i++) { if (!ctx->conf->methods[i]) break; size_t s = ctx->conf->methods[i]->min_decrypt_head_space(ctx); if (s > ret) ret = s; } /* ugly hack to get alignment right for aes128-gcm, which needs data aligned to 16 and has a 24 byte header */ return alignto(ret, 16) + 8; } static size_t methods_min_encrypt_tail_space(fastd_context *ctx) { size_t ret = ctx->conf->methods[0]->min_encrypt_tail_space(ctx); int i; for (i = 0; i < MAX_METHODS; i++) { if (!ctx->conf->methods[i]) break; size_t s = ctx->conf->methods[i]->min_encrypt_tail_space(ctx); if (s > ret) ret = s; } return ret; } static size_t methods_min_decrypt_tail_space(fastd_context *ctx) { size_t ret = ctx->conf->methods[0]->min_decrypt_tail_space(ctx); int i; for (i = 0; i < MAX_METHODS; i++) { if (!ctx->conf->methods[i]) break; size_t s = ctx->conf->methods[i]->min_decrypt_tail_space(ctx); if (s > ret) ret = s; } return ret; } static void fastd_send_type(fastd_context *ctx, const fastd_socket *sock, const fastd_peer_address *address, uint8_t packet_type, fastd_buffer buffer) { if (!sock) exit_bug(ctx, "send: sock == NULL"); struct msghdr msg; memset(&msg, 0, sizeof(msg)); switch (address->sa.sa_family) { case AF_INET: msg.msg_name = (void*)&address->in; msg.msg_namelen = sizeof(struct sockaddr_in); break; case AF_INET6: msg.msg_name = (void*)&address->in6; msg.msg_namelen = sizeof(struct sockaddr_in6); break; default: exit_bug(ctx, "unsupported address family"); } struct iovec iov[2] = { { .iov_base = &packet_type, .iov_len = 1 }, { .iov_base = buffer.data, .iov_len = buffer.len } }; msg.msg_iov = iov; msg.msg_iovlen = buffer.len ? 2 : 1; int ret; do { ret = sendmsg(sock->fd, &msg, 0); } while (ret < 0 && errno == EINTR); if (ret < 0) pr_warn_errno(ctx, "sendmsg"); fastd_buffer_free(buffer); } void fastd_send(fastd_context *ctx, const fastd_socket *sock, const fastd_peer_address *address, fastd_buffer buffer) { fastd_send_type(ctx, sock, address, PACKET_DATA, buffer); } void fastd_send_handshake(fastd_context *ctx, const fastd_socket *sock, const fastd_peer_address *address, fastd_buffer buffer) { fastd_send_type(ctx, sock, address, PACKET_HANDSHAKE, buffer); } void fastd_handle_receive(fastd_context *ctx, fastd_peer *peer, fastd_buffer buffer) { if (ctx->conf->mode == MODE_TAP) { const fastd_eth_addr *src_addr = fastd_get_source_address(ctx, buffer); if (fastd_eth_addr_is_unicast(src_addr)) fastd_peer_eth_addr_add(ctx, peer, src_addr); } if (write(ctx->tunfd, buffer.data, buffer.len) < 0) pr_warn_errno(ctx, "write"); if (ctx->conf->mode == MODE_TAP && ctx->conf->forward) { const fastd_eth_addr *dest_addr = fastd_get_dest_address(ctx, buffer); if (fastd_eth_addr_is_unicast(dest_addr)) { fastd_peer *dest_peer = fastd_peer_find_by_eth_addr(ctx, dest_addr); if (dest_peer && dest_peer != peer && fastd_peer_is_established(dest_peer)) { ctx->conf->protocol->send(ctx, dest_peer, buffer); } else { fastd_buffer_free(buffer); } } else { fastd_peer *dest_peer; for (dest_peer = ctx->peers; dest_peer; dest_peer = dest_peer->next) { if (dest_peer != peer && fastd_peer_is_established(dest_peer)) { fastd_buffer send_buffer = fastd_buffer_alloc(buffer.len, methods_min_encrypt_head_space(ctx), methods_min_encrypt_tail_space(ctx)); memcpy(send_buffer.data, buffer.data, buffer.len); ctx->conf->protocol->send(ctx, dest_peer, send_buffer); } } fastd_buffer_free(buffer); } } else { fastd_buffer_free(buffer); } } static void on_up(fastd_context *ctx) { if (!ctx->conf->on_up) return; char *cwd = get_current_dir_name(); if (!chdir(ctx->conf->on_up_dir)) { setenv("INTERFACE", ctx->ifname, 1); int ret = system(ctx->conf->on_up); if (WIFSIGNALED(ret)) pr_error(ctx, "on-up command exited with signal %i", WTERMSIG(ret)); else if(ret) pr_warn(ctx, "on-up command exited with status %i", WEXITSTATUS(ret)); if (chdir(cwd)) pr_error(ctx, "can't chdir to `%s': %s", cwd, strerror(errno)); } else { pr_error(ctx, "can't chdir to `%s': %s", ctx->conf->on_up_dir, strerror(errno)); } free(cwd); } static void on_down(fastd_context *ctx) { if (!ctx->conf->on_down) return; char *cwd = get_current_dir_name(); if(!chdir(ctx->conf->on_down_dir)) { setenv("INTERFACE", ctx->ifname, 1); int ret = system(ctx->conf->on_down); if (WIFSIGNALED(ret)) pr_error(ctx, "on-down command exited with signal %i", WTERMSIG(ret)); else if(ret) pr_warn(ctx, "on-down command exited with status %i", WEXITSTATUS(ret)); if (chdir(cwd)) pr_error(ctx, "can't chdir to `%s': %s", cwd, strerror(errno)); } else { pr_error(ctx, "can't chdir to `%s': %s", ctx->conf->on_down_dir, strerror(errno)); } free(cwd); } static void init_peers(fastd_context *ctx) { fastd_peer_config *peer_conf; for (peer_conf = ctx->conf->peers; peer_conf; peer_conf = peer_conf->next) { ctx->conf->protocol->peer_configure(ctx, peer_conf); if (peer_conf->enabled) fastd_peer_add(ctx, peer_conf); } } static void delete_peers(fastd_context *ctx) { fastd_peer *peer, *next; for (peer = ctx->peers; peer; peer = next) { next = peer->next; fastd_peer_delete(ctx, peer); } } static inline void update_time(fastd_context *ctx) { clock_gettime(CLOCK_MONOTONIC, &ctx->now); } static inline void send_handshake(fastd_context *ctx, fastd_peer *peer) { if (peer->address.sa.sa_family && peer->sock) { if (timespec_diff(&ctx->now, &peer->last_handshake) < ctx->conf->min_handshake_interval*1000 && fastd_peer_address_equal(&peer->address, &peer->last_handshake_address)) { pr_debug(ctx, "not sending a handshake to %P as we sent one a short time ago", peer); } else { pr_debug(ctx, "sending handshake to %P...", peer); peer->last_handshake = ctx->now; peer->last_handshake_address = peer->address; ctx->conf->protocol->handshake_init(ctx, peer->sock, &peer->address, peer->config); } } fastd_task_schedule_handshake(ctx, peer, fastd_rand(ctx, 17500, 22500)); } static void handle_tasks(fastd_context *ctx) { fastd_task *task; while ((task = fastd_task_get(ctx)) != NULL) { switch (task->type) { case TASK_HANDSHAKE: if (fastd_peer_is_dynamic(task->peer) && !(fastd_peer_is_floating(task->peer) && fastd_peer_is_established(task->peer))) fastd_resolve_peer(ctx, task->peer); else send_handshake(ctx, task->peer); break; case TASK_KEEPALIVE: pr_debug(ctx, "sending keepalive to %P", task->peer); ctx->conf->protocol->send(ctx, task->peer, fastd_buffer_alloc(0, methods_min_encrypt_head_space(ctx), methods_min_encrypt_tail_space(ctx))); break; default: exit_bug(ctx, "invalid task type"); } free(task); } } static void handle_tun(fastd_context *ctx) { size_t max_len = fastd_max_packet_size(ctx); fastd_buffer buffer = fastd_buffer_alloc(max_len, methods_min_encrypt_head_space(ctx), methods_min_encrypt_tail_space(ctx)); ssize_t len = read(ctx->tunfd, buffer.data, max_len); if (len < 0) { if (errno == EINTR) { fastd_buffer_free(buffer); return; } exit_errno(ctx, "read"); } buffer.len = len; fastd_peer *peer = NULL; if (ctx->conf->mode == MODE_TAP) { const fastd_eth_addr *dest_addr = fastd_get_dest_address(ctx, buffer); if (fastd_eth_addr_is_unicast(dest_addr)) { peer = fastd_peer_find_by_eth_addr(ctx, dest_addr); if (peer == NULL) { fastd_buffer_free(buffer); return; } if (fastd_peer_is_established(peer)) { ctx->conf->protocol->send(ctx, peer, buffer); } else { fastd_buffer_free(buffer); } } } if (peer == NULL) { for (peer = ctx->peers; peer; peer = peer->next) { if (fastd_peer_is_established(peer)) { fastd_buffer send_buffer = fastd_buffer_alloc(len, methods_min_encrypt_head_space(ctx), methods_min_encrypt_tail_space(ctx)); memcpy(send_buffer.data, buffer.data, len); ctx->conf->protocol->send(ctx, peer, send_buffer); } } fastd_buffer_free(buffer); } } static void handle_socket(fastd_context *ctx, const fastd_socket *sock) { size_t max_len = PACKET_TYPE_LEN + methods_max_packet_size(ctx); fastd_buffer buffer = fastd_buffer_alloc(max_len, methods_min_decrypt_head_space(ctx), methods_min_decrypt_tail_space(ctx)); uint8_t *packet_type; fastd_peer_address recvaddr; socklen_t recvaddrlen = sizeof(recvaddr); ssize_t len = recvfrom(sock->fd, buffer.data, buffer.len, 0, (struct sockaddr*)&recvaddr, &recvaddrlen); if (len < 0) { if (errno != EINTR) pr_warn(ctx, "recvfrom: %s", strerror(errno)); fastd_buffer_free(buffer); return; } packet_type = buffer.data; buffer.len = len; fastd_buffer_push_head(&buffer, 1); fastd_peer *peer; for (peer = ctx->peers; peer; peer = peer->next) { if (fastd_peer_address_equal(&peer->address, &recvaddr)) break; } if (peer) { switch (*packet_type) { case PACKET_DATA: ctx->conf->protocol->handle_recv(ctx, peer, buffer); break; case PACKET_HANDSHAKE: fastd_handshake_handle(ctx, sock, &recvaddr, peer->config, buffer); break; default: fastd_buffer_free(buffer); } } else if(ctx->conf->n_floating || ctx->conf->n_dynamic || (recvaddr.sa.sa_family == AF_INET && ctx->conf->n_dynamic_v4) || (recvaddr.sa.sa_family == AF_INET6 && ctx->conf->n_dynamic_v6)) { switch (*packet_type) { case PACKET_DATA: fastd_buffer_free(buffer); ctx->conf->protocol->handshake_init(ctx, sock, &recvaddr, NULL); break; case PACKET_HANDSHAKE: fastd_handshake_handle(ctx, sock, &recvaddr, NULL, buffer); break; default: fastd_buffer_free(buffer); } } else { pr_debug(ctx, "received packet from unknown peer %I", &recvaddr); fastd_buffer_free(buffer); } } static void handle_resolv_returns(fastd_context *ctx) { fastd_resolve_return resolve_return; if (read(ctx->resolverfd, &resolve_return, sizeof(resolve_return)) < 0) { if (errno != EINTR) pr_warn(ctx, "read: %s", strerror(errno)); return; } fastd_peer *peer; for (peer = ctx->peers; peer; peer = peer->next) { if (!peer->config) continue; if (!strequal(peer->config->hostname, resolve_return.hostname)) continue; if (!fastd_peer_config_matches_dynamic(peer->config, &resolve_return.constraints)) continue; peer->last_resolve_return = ctx->now; if (fastd_peer_claim_address(ctx, peer, NULL, &resolve_return.addr)) { if (!peer->sock) { switch(resolve_return.addr.sa.sa_family) { case AF_INET: peer->sock = ctx->sock_default_v4; break; case AF_INET6: peer->sock = ctx->sock_default_v6; } } send_handshake(ctx, peer); } else { pr_warn(ctx, "hostname `%s' resolved to address %I which is used by a fixed peer", resolve_return.hostname, &resolve_return.addr); fastd_task_schedule_handshake(ctx, peer, fastd_rand(ctx, 17500, 22500)); } break; } free(resolve_return.hostname); } static void handle_input(fastd_context *ctx) { struct pollfd fds[ctx->n_socks + 2]; fds[0].fd = ctx->tunfd; fds[0].events = POLLIN; fds[1].fd = ctx->resolverfd; fds[1].events = POLLIN; unsigned i; for (i = 0; i < ctx->n_socks; i++) { fds[i+2].fd = ctx->socks[i].fd; fds[i+2].events = POLLIN; } int timeout = fastd_task_timeout(ctx); if (timeout < 0 || timeout > 60000) timeout = 60000; /* call maintenance at least once a minute */ int ret = poll(fds, ctx->n_socks + 2, timeout); if (ret < 0) { if (errno == EINTR) return; exit_errno(ctx, "poll"); } update_time(ctx); if (fds[0].revents & POLLIN) handle_tun(ctx); if (fds[1].revents & POLLIN) handle_resolv_returns(ctx); for (i = 0; i < ctx->n_socks; i++) { if (fds[i+2].revents & POLLIN) handle_socket(ctx, &ctx->socks[i]); } } static void cleanup_peers(fastd_context *ctx) { fastd_peer *peer, *next; for (peer = ctx->peers; peer; peer = next) { next = peer->next; if (fastd_peer_is_established(peer)) { if (timespec_diff(&ctx->now, &peer->seen) > ctx->conf->peer_stale_time*1000) fastd_peer_reset(ctx, peer); } } } static void maintenance(fastd_context *ctx) { cleanup_peers(ctx); fastd_peer_eth_addr_cleanup(ctx); } static void close_fds(fastd_context *ctx) { struct rlimit rl; int fd, maxfd; if (getrlimit(RLIMIT_NOFILE, &rl) > 0) maxfd = (int)rl.rlim_max; else maxfd = sysconf(_SC_OPEN_MAX); for (fd = 3; fd < maxfd; fd++) { if (close(fd) < 0) { if (errno == EINTR) { fd--; continue; } if (errno != EBADF) pr_error_errno(ctx, "close"); } } } static void write_pid(fastd_context *ctx, pid_t pid) { if (!ctx->conf->pid_file) return; int fd = open(ctx->conf->pid_file, O_WRONLY|O_CREAT, 0666); if (fd < 0) { pr_error_errno(ctx, "can't write PID file: open"); return; } if (dprintf(fd, "%i", pid) < 0) pr_error_errno(ctx, "can't write PID file: dprintf"); if (close(fd) < 0) pr_warn_errno(ctx, "close"); } int main(int argc, char *argv[]) { fastd_context ctx; memset(&ctx, 0, sizeof(ctx)); close_fds(&ctx); fastd_random_bytes(&ctx, &ctx.randseed, sizeof(ctx.randseed), false); init_signals(&ctx); init_pipes(&ctx); fastd_config conf; fastd_configure(&ctx, &conf, argc, argv); ctx.conf = &conf; init_log(&ctx); crypto_init(&ctx); if (conf.generate_key) { conf.protocol->generate_key(&ctx); exit(0); } conf.protocol_config = conf.protocol->init(&ctx); if (conf.show_key) { conf.protocol->show_key(&ctx); exit(0); } update_time(&ctx); pr_info(&ctx, "fastd " FASTD_VERSION " starting"); init_sockets(&ctx); init_tuntap(&ctx); init_peers(&ctx); if (conf.daemon) { pid_t pid = fork(); if (pid < 0) { exit_errno(&ctx, "fork"); } else if (pid > 0) { write_pid(&ctx, pid); exit(0); } if (setsid() < 0) pr_error_errno(&ctx, "setsid"); } else { write_pid(&ctx, getpid()); } on_up(&ctx); while (!terminate) { handle_tasks(&ctx); handle_input(&ctx); maintenance(&ctx); sigset_t set, oldset; sigemptyset(&set); pthread_sigmask(SIG_SETMASK, &set, &oldset); if (sighup) { sighup = false; close_log(&ctx); init_log(&ctx); fastd_reconfigure(&ctx, &conf); } pthread_sigmask(SIG_SETMASK, &oldset, NULL); } on_down(&ctx); delete_peers(&ctx); close_tuntap(&ctx); close_sockets(&ctx); free(ctx.protocol_state); free(ctx.eth_addr); crypto_free(&ctx); close_log(&ctx); fastd_config_release(&ctx, &conf); return 0; }