/* net_setup.c -- Setup. Copyright (C) 1998-2005 Ivo Timmermans, 2000-2021 Guus Sliepen 2006 Scott Lamb 2010 Brandon Black This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include "system.h" #include "cipher.h" #include "conf.h" #include "connection.h" #include "control.h" #include "device.h" #include "digest.h" #include "ecdsa.h" #include "graph.h" #include "logger.h" #include "names.h" #include "net.h" #include "netutl.h" #include "process.h" #include "protocol.h" #include "route.h" #include "rsa.h" #include "script.h" #include "subnet.h" #include "utils.h" #include "xalloc.h" #ifdef HAVE_MINIUPNPC #include "upnp.h" #endif char *myport; static io_t device_io; devops_t devops; bool device_standby = false; char *proxyhost; char *proxyport; char *proxyuser; char *proxypass; proxytype_t proxytype; bool autoconnect; bool disablebuggypeers; char *scriptinterpreter; char *scriptextension; bool node_read_ecdsa_public_key(node_t *n) { if(ecdsa_active(n->ecdsa)) { return true; } splay_tree_t *config_tree; FILE *fp; char *pubname = NULL; char *p; init_configuration(&config_tree); if(!read_host_config(config_tree, n->name, true)) { goto exit; } /* First, check for simple Ed25519PublicKey statement */ if(get_config_string(lookup_config(config_tree, "Ed25519PublicKey"), &p)) { n->ecdsa = ecdsa_set_base64_public_key(p); free(p); goto exit; } /* Else, check for Ed25519PublicKeyFile statement and read it */ if(!get_config_string(lookup_config(config_tree, "Ed25519PublicKeyFile"), &pubname)) { xasprintf(&pubname, "%s" SLASH "hosts" SLASH "%s", confbase, n->name); } fp = fopen(pubname, "r"); if(!fp) { goto exit; } n->ecdsa = ecdsa_read_pem_public_key(fp); fclose(fp); exit: exit_configuration(&config_tree); free(pubname); return n->ecdsa; } bool read_ecdsa_public_key(connection_t *c) { if(ecdsa_active(c->ecdsa)) { return true; } FILE *fp; char *fname; char *p; if(!c->config_tree) { init_configuration(&c->config_tree); if(!read_host_config(c->config_tree, c->name, true)) { return false; } } /* First, check for simple Ed25519PublicKey statement */ if(get_config_string(lookup_config(c->config_tree, "Ed25519PublicKey"), &p)) { c->ecdsa = ecdsa_set_base64_public_key(p); free(p); return c->ecdsa; } /* Else, check for Ed25519PublicKeyFile statement and read it */ if(!get_config_string(lookup_config(c->config_tree, "Ed25519PublicKeyFile"), &fname)) { xasprintf(&fname, "%s" SLASH "hosts" SLASH "%s", confbase, c->name); } fp = fopen(fname, "r"); if(!fp) { logger(DEBUG_ALWAYS, LOG_ERR, "Error reading Ed25519 public key file `%s': %s", fname, strerror(errno)); free(fname); return false; } c->ecdsa = ecdsa_read_pem_public_key(fp); if(!c->ecdsa && errno != ENOENT) { logger(DEBUG_ALWAYS, LOG_ERR, "Parsing Ed25519 public key file `%s' failed.", fname); } fclose(fp); free(fname); return c->ecdsa; } #ifndef DISABLE_LEGACY bool read_rsa_public_key(connection_t *c) { FILE *fp; char *fname; char *n; /* First, check for simple PublicKey statement */ if(get_config_string(lookup_config(c->config_tree, "PublicKey"), &n)) { c->rsa = rsa_set_hex_public_key(n, "FFFF"); free(n); return c->rsa; } /* Else, check for PublicKeyFile statement and read it */ if(!get_config_string(lookup_config(c->config_tree, "PublicKeyFile"), &fname)) { xasprintf(&fname, "%s" SLASH "hosts" SLASH "%s", confbase, c->name); } fp = fopen(fname, "r"); if(!fp) { logger(DEBUG_ALWAYS, LOG_ERR, "Error reading RSA public key file `%s': %s", fname, strerror(errno)); free(fname); return false; } c->rsa = rsa_read_pem_public_key(fp); fclose(fp); if(!c->rsa) { logger(DEBUG_ALWAYS, LOG_ERR, "Reading RSA public key file `%s' failed: %s", fname, strerror(errno)); } free(fname); return c->rsa; } #endif static bool read_ecdsa_private_key(void) { FILE *fp; char *fname; /* Check for PrivateKeyFile statement and read it */ if(!get_config_string(lookup_config(config_tree, "Ed25519PrivateKeyFile"), &fname)) { xasprintf(&fname, "%s" SLASH "ed25519_key.priv", confbase); } fp = fopen(fname, "r"); if(!fp) { logger(DEBUG_ALWAYS, LOG_ERR, "Error reading Ed25519 private key file `%s': %s", fname, strerror(errno)); if(errno == ENOENT) { logger(DEBUG_ALWAYS, LOG_INFO, "Create an Ed25519 key pair with `tinc -n %s generate-ed25519-keys'.", netname ? netname : "."); } free(fname); return false; } #ifndef HAVE_MINGW struct stat s; if(fstat(fileno(fp), &s)) { logger(DEBUG_ALWAYS, LOG_ERR, "Could not stat Ed25519 private key file `%s': %s'", fname, strerror(errno)); free(fname); return false; } if(s.st_mode & ~0100700) { logger(DEBUG_ALWAYS, LOG_WARNING, "Warning: insecure file permissions for Ed25519 private key file `%s'!", fname); } #endif myself->connection->ecdsa = ecdsa_read_pem_private_key(fp); fclose(fp); if(!myself->connection->ecdsa) { logger(DEBUG_ALWAYS, LOG_ERR, "Reading Ed25519 private key file `%s' failed", fname); } free(fname); return myself->connection->ecdsa; } static bool read_invitation_key(void) { FILE *fp; char fname[PATH_MAX]; if(invitation_key) { ecdsa_free(invitation_key); invitation_key = NULL; } snprintf(fname, sizeof(fname), "%s" SLASH "invitations" SLASH "ed25519_key.priv", confbase); fp = fopen(fname, "r"); if(fp) { invitation_key = ecdsa_read_pem_private_key(fp); fclose(fp); if(!invitation_key) { logger(DEBUG_ALWAYS, LOG_ERR, "Reading Ed25519 private key file `%s' failed", fname); } } return invitation_key; } #ifndef DISABLE_LEGACY static bool read_rsa_private_key(void) { FILE *fp; char *fname; char *n, *d; /* First, check for simple PrivateKey statement */ if(get_config_string(lookup_config(config_tree, "PrivateKey"), &d)) { if(!get_config_string(lookup_config(config_tree, "PublicKey"), &n)) { logger(DEBUG_ALWAYS, LOG_ERR, "PrivateKey used but no PublicKey found!"); free(d); return false; } myself->connection->rsa = rsa_set_hex_private_key(n, "FFFF", d); free(n); free(d); return myself->connection->rsa; } /* Else, check for PrivateKeyFile statement and read it */ if(!get_config_string(lookup_config(config_tree, "PrivateKeyFile"), &fname)) { xasprintf(&fname, "%s" SLASH "rsa_key.priv", confbase); } fp = fopen(fname, "r"); if(!fp) { logger(DEBUG_ALWAYS, LOG_ERR, "Error reading RSA private key file `%s': %s", fname, strerror(errno)); if(errno == ENOENT) { logger(DEBUG_ALWAYS, LOG_INFO, "Create an RSA key pair with `tinc -n %s generate-rsa-keys'.", netname ? netname : "."); } free(fname); return false; } #ifndef HAVE_MINGW struct stat s; if(fstat(fileno(fp), &s)) { logger(DEBUG_ALWAYS, LOG_ERR, "Could not stat RSA private key file `%s': %s'", fname, strerror(errno)); free(fname); return false; } if(s.st_mode & ~0100700) { logger(DEBUG_ALWAYS, LOG_WARNING, "Warning: insecure file permissions for RSA private key file `%s'!", fname); } #endif myself->connection->rsa = rsa_read_pem_private_key(fp); fclose(fp); if(!myself->connection->rsa) { logger(DEBUG_ALWAYS, LOG_ERR, "Reading RSA private key file `%s' failed: %s", fname, strerror(errno)); } free(fname); return myself->connection->rsa; } #endif #ifndef DISABLE_LEGACY static timeout_t keyexpire_timeout; static void keyexpire_handler(void *data) { regenerate_key(); timeout_set(data, &(struct timeval) { keylifetime, rand() % 100000 }); } #endif void regenerate_key(void) { logger(DEBUG_STATUS, LOG_INFO, "Expiring symmetric keys"); send_key_changed(); for splay_each(node_t, n, node_tree) { n->status.validkey_in = false; } } void load_all_nodes(void) { DIR *dir; struct dirent *ent; char dname[PATH_MAX]; snprintf(dname, sizeof(dname), "%s" SLASH "hosts", confbase); dir = opendir(dname); if(!dir) { logger(DEBUG_ALWAYS, LOG_ERR, "Could not open %s: %s", dname, strerror(errno)); return; } while((ent = readdir(dir))) { if(!check_id(ent->d_name)) { continue; } node_t *n = lookup_node(ent->d_name); splay_tree_t *config_tree; init_configuration(&config_tree); read_config_options(config_tree, ent->d_name); read_host_config(config_tree, ent->d_name, true); if(!n) { n = new_node(); n->name = xstrdup(ent->d_name); node_add(n); } if(strictsubnets) { for(config_t *cfg = lookup_config(config_tree, "Subnet"); cfg; cfg = lookup_config_next(config_tree, cfg)) { subnet_t *s, *s2; if(!get_config_subnet(cfg, &s)) { continue; } if((s2 = lookup_subnet(n, s))) { s2->expires = -1; free(s); } else { subnet_add(n, s); } } } if(lookup_config(config_tree, "Address")) { n->status.has_address = true; } exit_configuration(&config_tree); } closedir(dir); } char *get_name(void) { char *name = NULL; char *returned_name; get_config_string(lookup_config(config_tree, "Name"), &name); if(!name) { return NULL; } returned_name = replace_name(name); free(name); return returned_name; } bool setup_myself_reloadable(void) { char *proxy = NULL; char *rmode = NULL; char *fmode = NULL; char *bmode = NULL; char *afname = NULL; char *space; bool choice; free(scriptinterpreter); scriptinterpreter = NULL; get_config_string(lookup_config(config_tree, "ScriptsInterpreter"), &scriptinterpreter); free(scriptextension); if(!get_config_string(lookup_config(config_tree, "ScriptsExtension"), &scriptextension)) { scriptextension = xstrdup(""); } get_config_string(lookup_config(config_tree, "Proxy"), &proxy); if(proxy) { if((space = strchr(proxy, ' '))) { *space++ = 0; } if(!strcasecmp(proxy, "none")) { proxytype = PROXY_NONE; } else if(!strcasecmp(proxy, "socks4")) { proxytype = PROXY_SOCKS4; } else if(!strcasecmp(proxy, "socks4a")) { proxytype = PROXY_SOCKS4A; } else if(!strcasecmp(proxy, "socks5")) { proxytype = PROXY_SOCKS5; } else if(!strcasecmp(proxy, "http")) { proxytype = PROXY_HTTP; } else if(!strcasecmp(proxy, "exec")) { proxytype = PROXY_EXEC; } else { logger(DEBUG_ALWAYS, LOG_ERR, "Unknown proxy type %s!", proxy); return false; } switch(proxytype) { case PROXY_NONE: default: break; case PROXY_EXEC: if(!space || !*space) { logger(DEBUG_ALWAYS, LOG_ERR, "Argument expected for proxy type exec!"); return false; } proxyhost = xstrdup(space); break; case PROXY_SOCKS4: case PROXY_SOCKS4A: case PROXY_SOCKS5: case PROXY_HTTP: proxyhost = space; if(space && (space = strchr(space, ' '))) { *space++ = 0, proxyport = space; } if(space && (space = strchr(space, ' '))) { *space++ = 0, proxyuser = space; } if(space && (space = strchr(space, ' '))) { *space++ = 0, proxypass = space; } if(!proxyhost || !*proxyhost || !proxyport || !*proxyport) { logger(DEBUG_ALWAYS, LOG_ERR, "Host and port argument expected for proxy!"); return false; } proxyhost = xstrdup(proxyhost); proxyport = xstrdup(proxyport); if(proxyuser && *proxyuser) { proxyuser = xstrdup(proxyuser); } if(proxypass && *proxypass) { proxypass = xstrdup(proxypass); } break; } free(proxy); } if(get_config_bool(lookup_config(config_tree, "IndirectData"), &choice) && choice) { myself->options |= OPTION_INDIRECT; } if(get_config_bool(lookup_config(config_tree, "TCPOnly"), &choice) && choice) { myself->options |= OPTION_TCPONLY; } if(myself->options & OPTION_TCPONLY) { myself->options |= OPTION_INDIRECT; } get_config_bool(lookup_config(config_tree, "UDPDiscovery"), &udp_discovery); get_config_int(lookup_config(config_tree, "UDPDiscoveryKeepaliveInterval"), &udp_discovery_keepalive_interval); get_config_int(lookup_config(config_tree, "UDPDiscoveryInterval"), &udp_discovery_interval); get_config_int(lookup_config(config_tree, "UDPDiscoveryTimeout"), &udp_discovery_timeout); get_config_int(lookup_config(config_tree, "MTUInfoInterval"), &mtu_info_interval); get_config_int(lookup_config(config_tree, "UDPInfoInterval"), &udp_info_interval); get_config_bool(lookup_config(config_tree, "DirectOnly"), &directonly); get_config_bool(lookup_config(config_tree, "LocalDiscovery"), &localdiscovery); if(get_config_string(lookup_config(config_tree, "Mode"), &rmode)) { if(!strcasecmp(rmode, "router")) { routing_mode = RMODE_ROUTER; } else if(!strcasecmp(rmode, "switch")) { routing_mode = RMODE_SWITCH; } else if(!strcasecmp(rmode, "hub")) { routing_mode = RMODE_HUB; } else { logger(DEBUG_ALWAYS, LOG_ERR, "Invalid routing mode!"); return false; } free(rmode); } if(get_config_string(lookup_config(config_tree, "Forwarding"), &fmode)) { if(!strcasecmp(fmode, "off")) { forwarding_mode = FMODE_OFF; } else if(!strcasecmp(fmode, "internal")) { forwarding_mode = FMODE_INTERNAL; } else if(!strcasecmp(fmode, "kernel")) { forwarding_mode = FMODE_KERNEL; } else { logger(DEBUG_ALWAYS, LOG_ERR, "Invalid forwarding mode!"); return false; } free(fmode); } choice = !(myself->options & OPTION_TCPONLY); get_config_bool(lookup_config(config_tree, "PMTUDiscovery"), &choice); if(choice) { myself->options |= OPTION_PMTU_DISCOVERY; } choice = true; get_config_bool(lookup_config(config_tree, "ClampMSS"), &choice); if(choice) { myself->options |= OPTION_CLAMP_MSS; } get_config_bool(lookup_config(config_tree, "PriorityInheritance"), &priorityinheritance); get_config_bool(lookup_config(config_tree, "DecrementTTL"), &decrement_ttl); if(get_config_string(lookup_config(config_tree, "Broadcast"), &bmode)) { if(!strcasecmp(bmode, "no")) { broadcast_mode = BMODE_NONE; } else if(!strcasecmp(bmode, "yes") || !strcasecmp(bmode, "mst")) { broadcast_mode = BMODE_MST; } else if(!strcasecmp(bmode, "direct")) { broadcast_mode = BMODE_DIRECT; } else { logger(DEBUG_ALWAYS, LOG_ERR, "Invalid broadcast mode!"); return false; } free(bmode); } const char *const DEFAULT_BROADCAST_SUBNETS[] = { "ff:ff:ff:ff:ff:ff", "255.255.255.255", "224.0.0.0/4", "ff00::/8" }; for(size_t i = 0; i < sizeof(DEFAULT_BROADCAST_SUBNETS) / sizeof(*DEFAULT_BROADCAST_SUBNETS); i++) { subnet_t *s = new_subnet(); if(!str2net(s, DEFAULT_BROADCAST_SUBNETS[i])) { abort(); } subnet_add(NULL, s); } for(config_t *cfg = lookup_config(config_tree, "BroadcastSubnet"); cfg; cfg = lookup_config_next(config_tree, cfg)) { subnet_t *s; if(!get_config_subnet(cfg, &s)) { continue; } subnet_add(NULL, s); } #if !defined(IP_TOS) if(priorityinheritance) { logger(DEBUG_ALWAYS, LOG_WARNING, "%s not supported on this platform for IPv4 connections", "PriorityInheritance"); } #endif #if !defined(IPV6_TCLASS) if(priorityinheritance) { logger(DEBUG_ALWAYS, LOG_WARNING, "%s not supported on this platform for IPv6 connections", "PriorityInheritance"); } #endif if(!get_config_int(lookup_config(config_tree, "MACExpire"), &macexpire)) { macexpire = 600; } if(get_config_int(lookup_config(config_tree, "MaxTimeout"), &maxtimeout)) { if(maxtimeout <= 0) { logger(DEBUG_ALWAYS, LOG_ERR, "Bogus maximum timeout!"); return false; } } else { maxtimeout = 900; } if(get_config_string(lookup_config(config_tree, "AddressFamily"), &afname)) { if(!strcasecmp(afname, "IPv4")) { addressfamily = AF_INET; } else if(!strcasecmp(afname, "IPv6")) { addressfamily = AF_INET6; } else if(!strcasecmp(afname, "any")) { addressfamily = AF_UNSPEC; } else { logger(DEBUG_ALWAYS, LOG_ERR, "Invalid address family!"); return false; } free(afname); } get_config_bool(lookup_config(config_tree, "Hostnames"), &hostnames); if(!get_config_int(lookup_config(config_tree, "KeyExpire"), &keylifetime)) { keylifetime = 3600; } if(!get_config_bool(lookup_config(config_tree, "AutoConnect"), &autoconnect)) { autoconnect = true; } get_config_bool(lookup_config(config_tree, "DisableBuggyPeers"), &disablebuggypeers); if(!get_config_int(lookup_config(config_tree, "InvitationExpire"), &invitation_lifetime)) { invitation_lifetime = 604800; // 1 week } read_invitation_key(); return true; } /* Add listening sockets. */ static bool add_listen_address(char *address, bool bindto) { char *port = myport; if(address) { char *space = strchr(address, ' '); if(space) { *space++ = 0; port = space; } if(!strcmp(address, "*")) { *address = 0; } } struct addrinfo *ai, hint = {0}; hint.ai_family = addressfamily; hint.ai_socktype = SOCK_STREAM; hint.ai_protocol = IPPROTO_TCP; hint.ai_flags = AI_PASSIVE; #if HAVE_DECL_RES_INIT res_init(); #endif int err = getaddrinfo(address && *address ? address : NULL, port, &hint, &ai); free(address); if(err || !ai) { logger(DEBUG_ALWAYS, LOG_ERR, "System call `%s' failed: %s", "getaddrinfo", err == EAI_SYSTEM ? strerror(err) : gai_strerror(err)); return false; } for(struct addrinfo *aip = ai; aip; aip = aip->ai_next) { // Ignore duplicate addresses bool found = false; for(int i = 0; i < listen_sockets; i++) if(!memcmp(&listen_socket[i].sa, aip->ai_addr, aip->ai_addrlen)) { found = true; break; } if(found) { continue; } if(listen_sockets >= MAXSOCKETS) { logger(DEBUG_ALWAYS, LOG_ERR, "Too many listening sockets"); return false; } int tcp_fd = setup_listen_socket((sockaddr_t *) aip->ai_addr); if(tcp_fd < 0) { continue; } int udp_fd = setup_vpn_in_socket((sockaddr_t *) aip->ai_addr); if(udp_fd < 0) { close(tcp_fd); continue; } io_add(&listen_socket[listen_sockets].tcp, handle_new_meta_connection, &listen_socket[listen_sockets], tcp_fd, IO_READ); io_add(&listen_socket[listen_sockets].udp, handle_incoming_vpn_data, &listen_socket[listen_sockets], udp_fd, IO_READ); if(debug_level >= DEBUG_CONNECTIONS) { char *hostname = sockaddr2hostname((sockaddr_t *) aip->ai_addr); logger(DEBUG_CONNECTIONS, LOG_NOTICE, "Listening on %s", hostname); free(hostname); } listen_socket[listen_sockets].bindto = bindto; memcpy(&listen_socket[listen_sockets].sa, aip->ai_addr, aip->ai_addrlen); listen_sockets++; } freeaddrinfo(ai); return true; } void device_enable(void) { if(devops.enable) { devops.enable(); } /* Run tinc-up script to further initialize the tap interface */ environment_t env; environment_init(&env); execute_script("tinc-up", &env); environment_exit(&env); } void device_disable(void) { environment_t env; environment_init(&env); execute_script("tinc-down", &env); environment_exit(&env); if(devops.disable) { devops.disable(); } } /* Configure node_t myself and set up the local sockets (listen only) */ static bool setup_myself(void) { char *name, *hostname, *type; char *address = NULL; bool port_specified = false; if(!(name = get_name())) { logger(DEBUG_ALWAYS, LOG_ERR, "Name for tinc daemon required!"); return false; } myname = xstrdup(name); myself = new_node(); myself->connection = new_connection(); myself->name = name; myself->connection->name = xstrdup(name); read_host_config(config_tree, name, true); if(!get_config_string(lookup_config(config_tree, "Port"), &myport)) { myport = xstrdup("655"); } else { port_specified = true; } myself->connection->options = 0; myself->connection->protocol_major = PROT_MAJOR; myself->connection->protocol_minor = PROT_MINOR; myself->options |= PROT_MINOR << 24; #ifdef DISABLE_LEGACY experimental = read_ecdsa_private_key(); if(!experimental) { logger(DEBUG_ALWAYS, LOG_ERR, "No private key available, cannot start tinc!"); return false; } #else if(!get_config_bool(lookup_config(config_tree, "ExperimentalProtocol"), &experimental)) { experimental = read_ecdsa_private_key(); if(!experimental) { logger(DEBUG_ALWAYS, LOG_WARNING, "Support for SPTPS disabled."); } } else { if(experimental && !read_ecdsa_private_key()) { return false; } } if(!read_rsa_private_key()) { if(experimental) { logger(DEBUG_ALWAYS, LOG_WARNING, "Support for legacy protocol disabled."); } else { logger(DEBUG_ALWAYS, LOG_ERR, "No private keys available, cannot start tinc!"); return false; } } #endif /* Ensure myport is numeric */ if(!atoi(myport)) { struct addrinfo *ai = str2addrinfo("localhost", myport, SOCK_DGRAM); sockaddr_t sa; if(!ai || !ai->ai_addr) { return false; } free(myport); memcpy(&sa, ai->ai_addr, ai->ai_addrlen); freeaddrinfo(ai); sockaddr2str(&sa, NULL, &myport); } /* Read in all the subnets specified in the host configuration file */ for(config_t *cfg = lookup_config(config_tree, "Subnet"); cfg; cfg = lookup_config_next(config_tree, cfg)) { subnet_t *subnet; if(!get_config_subnet(cfg, &subnet)) { return false; } subnet_add(myself, subnet); } /* Check some options */ if(!setup_myself_reloadable()) { return false; } get_config_bool(lookup_config(config_tree, "StrictSubnets"), &strictsubnets); get_config_bool(lookup_config(config_tree, "TunnelServer"), &tunnelserver); strictsubnets |= tunnelserver; if(get_config_int(lookup_config(config_tree, "MaxConnectionBurst"), &max_connection_burst)) { if(max_connection_burst <= 0) { logger(DEBUG_ALWAYS, LOG_ERR, "MaxConnectionBurst cannot be negative!"); return false; } } if(get_config_int(lookup_config(config_tree, "UDPRcvBuf"), &udp_rcvbuf)) { if(udp_rcvbuf < 0) { logger(DEBUG_ALWAYS, LOG_ERR, "UDPRcvBuf cannot be negative!"); return false; } } if(get_config_int(lookup_config(config_tree, "UDPSndBuf"), &udp_sndbuf)) { if(udp_sndbuf < 0) { logger(DEBUG_ALWAYS, LOG_ERR, "UDPSndBuf cannot be negative!"); return false; } } get_config_int(lookup_config(config_tree, "FWMark"), &fwmark); #ifndef SO_MARK if(fwmark) { logger(DEBUG_ALWAYS, LOG_ERR, "FWMark not supported on this platform!"); return false; } #endif int replaywin_int; if(get_config_int(lookup_config(config_tree, "ReplayWindow"), &replaywin_int)) { if(replaywin_int < 0) { logger(DEBUG_ALWAYS, LOG_ERR, "ReplayWindow cannot be negative!"); return false; } replaywin = (unsigned)replaywin_int; sptps_replaywin = replaywin; } #ifndef DISABLE_LEGACY /* Generate packet encryption key */ char *cipher; if(!get_config_string(lookup_config(config_tree, "Cipher"), &cipher)) { cipher = xstrdup("aes-256-cbc"); } if(!strcasecmp(cipher, "none")) { myself->incipher = NULL; } else if(!(myself->incipher = cipher_open_by_name(cipher))) { logger(DEBUG_ALWAYS, LOG_ERR, "Unrecognized cipher type!"); free(cipher); return false; } free(cipher); timeout_add(&keyexpire_timeout, keyexpire_handler, &keyexpire_timeout, &(struct timeval) { keylifetime, rand() % 100000 }); /* Check if we want to use message authentication codes... */ int maclength = 4; get_config_int(lookup_config(config_tree, "MACLength"), &maclength); if(maclength < 0) { logger(DEBUG_ALWAYS, LOG_ERR, "Bogus MAC length!"); return false; } char *digest; if(!get_config_string(lookup_config(config_tree, "Digest"), &digest)) { digest = xstrdup("sha256"); } if(!strcasecmp(digest, "none")) { myself->indigest = NULL; } else if(!(myself->indigest = digest_open_by_name(digest, maclength))) { logger(DEBUG_ALWAYS, LOG_ERR, "Unrecognized digest type!"); free(digest); return false; } free(digest); #endif /* Compression */ if(get_config_int(lookup_config(config_tree, "Compression"), &myself->incompression)) { if(myself->incompression < 0 || myself->incompression > 11) { logger(DEBUG_ALWAYS, LOG_ERR, "Bogus compression level!"); return false; } } else { myself->incompression = 0; } myself->connection->outcompression = 0; /* Done */ myself->nexthop = myself; myself->via = myself; myself->status.reachable = true; myself->last_state_change = now.tv_sec; myself->status.sptps = experimental; node_add(myself); graph(); load_all_nodes(); /* Open device */ devops = os_devops; if(get_config_string(lookup_config(config_tree, "DeviceType"), &type)) { if(!strcasecmp(type, "dummy")) { devops = dummy_devops; } else if(!strcasecmp(type, "raw_socket")) { devops = raw_socket_devops; } else if(!strcasecmp(type, "multicast")) { devops = multicast_devops; } #ifdef HAVE_SYS_UN_H else if(!strcasecmp(type, "fd")) { devops = fd_devops; } #endif #ifdef ENABLE_UML else if(!strcasecmp(type, "uml")) { devops = uml_devops; } #endif #ifdef ENABLE_VDE else if(!strcasecmp(type, "vde")) { devops = vde_devops; } #endif free(type); } get_config_bool(lookup_config(config_tree, "DeviceStandby"), &device_standby); if(!devops.setup()) { return false; } if(device_fd >= 0) { io_add(&device_io, handle_device_data, NULL, device_fd, IO_READ); } /* Open sockets */ if(!do_detach && getenv("LISTEN_FDS")) { sockaddr_t sa; socklen_t salen; listen_sockets = atoi(getenv("LISTEN_FDS")); #ifdef HAVE_UNSETENV unsetenv("LISTEN_FDS"); #endif if(listen_sockets > MAXSOCKETS) { logger(DEBUG_ALWAYS, LOG_ERR, "Too many listening sockets"); return false; } for(int i = 0; i < listen_sockets; i++) { salen = sizeof(sa); if(getsockname(i + 3, &sa.sa, &salen) < 0) { logger(DEBUG_ALWAYS, LOG_ERR, "Could not get address of listen fd %d: %s", i + 3, sockstrerror(sockerrno)); return false; } #ifdef FD_CLOEXEC fcntl(i + 3, F_SETFD, FD_CLOEXEC); #endif int udp_fd = setup_vpn_in_socket(&sa); if(udp_fd < 0) { return false; } io_add(&listen_socket[i].tcp, (io_cb_t)handle_new_meta_connection, &listen_socket[i], i + 3, IO_READ); io_add(&listen_socket[i].udp, (io_cb_t)handle_incoming_vpn_data, &listen_socket[i], udp_fd, IO_READ); if(debug_level >= DEBUG_CONNECTIONS) { hostname = sockaddr2hostname(&sa); logger(DEBUG_CONNECTIONS, LOG_NOTICE, "Listening on %s", hostname); free(hostname); } memcpy(&listen_socket[i].sa, &sa, salen); } } else { listen_sockets = 0; int cfgs = 0; for(config_t *cfg = lookup_config(config_tree, "BindToAddress"); cfg; cfg = lookup_config_next(config_tree, cfg)) { cfgs++; get_config_string(cfg, &address); if(!add_listen_address(address, true)) { return false; } } for(config_t *cfg = lookup_config(config_tree, "ListenAddress"); cfg; cfg = lookup_config_next(config_tree, cfg)) { cfgs++; get_config_string(cfg, &address); if(!add_listen_address(address, false)) { return false; } } if(!cfgs) if(!add_listen_address(address, NULL)) { return false; } } if(!listen_sockets) { logger(DEBUG_ALWAYS, LOG_ERR, "Unable to create any listening socket!"); return false; } /* If no Port option was specified, set myport to the port used by the first listening socket. */ if(!port_specified || atoi(myport) == 0) { sockaddr_t sa; socklen_t salen = sizeof(sa); if(!getsockname(listen_socket[0].udp.fd, &sa.sa, &salen)) { free(myport); sockaddr2str(&sa, NULL, &myport); if(!myport) { myport = xstrdup("655"); } } } xasprintf(&myself->hostname, "MYSELF port %s", myport); myself->connection->hostname = xstrdup(myself->hostname); char *upnp = NULL; get_config_string(lookup_config(config_tree, "UPnP"), &upnp); bool upnp_tcp = false; bool upnp_udp = false; if(upnp) { if(!strcasecmp(upnp, "yes")) { upnp_tcp = upnp_udp = true; } else if(!strcasecmp(upnp, "udponly")) { upnp_udp = true; } free(upnp); } if(upnp_tcp || upnp_udp) { #ifdef HAVE_MINIUPNPC upnp_init(upnp_tcp, upnp_udp); #else logger(DEBUG_ALWAYS, LOG_WARNING, "UPnP was requested, but tinc isn't built with miniupnpc support!"); #endif } /* Done. */ last_config_check = now.tv_sec; return true; } /* initialize network */ bool setup_network(void) { init_connections(); init_subnets(); init_nodes(); init_edges(); init_requests(); if(get_config_int(lookup_config(config_tree, "PingInterval"), &pinginterval)) { if(pinginterval < 1) { pinginterval = 86400; } } else { pinginterval = 60; } if(!get_config_int(lookup_config(config_tree, "PingTimeout"), &pingtimeout)) { pingtimeout = 5; } if(pingtimeout < 1 || pingtimeout > pinginterval) { pingtimeout = pinginterval; } if(!get_config_int(lookup_config(config_tree, "MaxOutputBufferSize"), &maxoutbufsize)) { maxoutbufsize = 10 * MTU; } if(!setup_myself()) { return false; } if(!init_control()) { return false; } if(!device_standby) { device_enable(); } /* Run subnet-up scripts for our own subnets */ subnet_update(myself, NULL, true); return true; } /* close all open network connections */ void close_network_connections(void) { for(list_node_t *node = connection_list->head, *next; node; node = next) { next = node->next; connection_t *c = node->data; /* Keep control connections open until the end, so they know when we really terminated */ if(c->status.control) { c->socket = -1; } c->outgoing = NULL; terminate_connection(c, false); } if(outgoing_list) { list_delete_list(outgoing_list); } if(myself && myself->connection) { subnet_update(myself, NULL, false); connection_del(myself->connection); } for(int i = 0; i < listen_sockets; i++) { io_del(&listen_socket[i].tcp); io_del(&listen_socket[i].udp); close(listen_socket[i].tcp.fd); close(listen_socket[i].udp.fd); } exit_requests(); exit_edges(); exit_subnets(); exit_nodes(); exit_connections(); if(!device_standby) { device_disable(); } free(myport); if(device_fd >= 0) { io_del(&device_io); } if(devops.close) { devops.close(); } exit_control(); free(scriptextension); free(scriptinterpreter); return; }