/* Copyright (c) 2001 Matej Pfajfar. * Copyright (c) 2001-2004, Roger Dingledine. * Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson. * Copyright (c) 2007-2011, The Tor Project, Inc. */ /* See LICENSE for licensing information */ #define ROUTER_PRIVATE #include "or.h" #include "circuitbuild.h" #include "circuitlist.h" #include "circuituse.h" #include "config.h" #include "connection.h" #include "control.h" #include "directory.h" #include "dirserv.h" #include "dns.h" #include "geoip.h" #include "hibernate.h" #include "main.h" #include "networkstatus.h" #include "nodelist.h" #include "policies.h" #include "relay.h" #include "rephist.h" #include "router.h" #include "routerlist.h" #include "routerparse.h" /** * \file router.c * \brief OR functionality, including key maintenance, generating * and uploading server descriptors, retrying OR connections. **/ extern long stats_n_seconds_working; /************************************************************/ /***** * Key management: ORs only. *****/ /** Private keys for this OR. There is also an SSL key managed by tortls.c. */ static tor_mutex_t *key_lock=NULL; static time_t onionkey_set_at=0; /**< When was onionkey last changed? */ /** Current private onionskin decryption key: used to decode CREATE cells. */ static crypto_pk_env_t *onionkey=NULL; /** Previous private onionskin decryption key: used to decode CREATE cells * generated by clients that have an older version of our descriptor. */ static crypto_pk_env_t *lastonionkey=NULL; /** Private server "identity key": used to sign directory info and TLS * certificates. Never changes. */ static crypto_pk_env_t *server_identitykey=NULL; /** Digest of server_identitykey. */ static char server_identitykey_digest[DIGEST_LEN]; /** Private client "identity key": used to sign bridges' and clients' * outbound TLS certificates. Regenerated on startup and on IP address * change. */ static crypto_pk_env_t *client_identitykey=NULL; /** Signing key used for v3 directory material; only set for authorities. */ static crypto_pk_env_t *authority_signing_key = NULL; /** Key certificate to authenticate v3 directory material; only set for * authorities. */ static authority_cert_t *authority_key_certificate = NULL; /** For emergency V3 authority key migration: An extra signing key that we use * with our old (obsolete) identity key for a while. */ static crypto_pk_env_t *legacy_signing_key = NULL; /** For emergency V3 authority key migration: An extra certificate to * authenticate legacy_signing_key with our obsolete identity key.*/ static authority_cert_t *legacy_key_certificate = NULL; /* (Note that v3 authorities also have a separate "authority identity key", * but this key is never actually loaded by the Tor process. Instead, it's * used by tor-gencert to sign new signing keys and make new key * certificates. */ /** Replace the current onion key with k. Does not affect * lastonionkey; to update lastonionkey correctly, call rotate_onion_key(). */ static void set_onion_key(crypto_pk_env_t *k) { if (onionkey && !crypto_pk_cmp_keys(onionkey, k)) { /* k is already our onion key; free it and return */ crypto_free_pk_env(k); return; } tor_mutex_acquire(key_lock); crypto_free_pk_env(onionkey); onionkey = k; tor_mutex_release(key_lock); mark_my_descriptor_dirty("set onion key"); } /** Return the current onion key. Requires that the onion key has been * loaded or generated. */ crypto_pk_env_t * get_onion_key(void) { tor_assert(onionkey); return onionkey; } /** Store a full copy of the current onion key into *key, and a full * copy of the most recent onion key into *last. */ void dup_onion_keys(crypto_pk_env_t **key, crypto_pk_env_t **last) { tor_assert(key); tor_assert(last); tor_mutex_acquire(key_lock); tor_assert(onionkey); *key = crypto_pk_copy_full(onionkey); if (lastonionkey) *last = crypto_pk_copy_full(lastonionkey); else *last = NULL; tor_mutex_release(key_lock); } /** Return the time when the onion key was last set. This is either the time * when the process launched, or the time of the most recent key rotation since * the process launched. */ time_t get_onion_key_set_at(void) { return onionkey_set_at; } /** Set the current server identity key to k. */ void set_server_identity_key(crypto_pk_env_t *k) { crypto_free_pk_env(server_identitykey); server_identitykey = k; crypto_pk_get_digest(server_identitykey, server_identitykey_digest); } /** Make sure that we have set up our identity keys to match or not match as * appropriate, and die with an assertion if we have not. */ static void assert_identity_keys_ok(void) { tor_assert(client_identitykey); if (public_server_mode(get_options())) { /* assert that we have set the client and server keys to be equal */ tor_assert(server_identitykey); tor_assert(0==crypto_pk_cmp_keys(client_identitykey, server_identitykey)); } else { /* assert that we have set the client and server keys to be unequal */ if (server_identitykey) tor_assert(0!=crypto_pk_cmp_keys(client_identitykey, server_identitykey)); } } /** Returns the current server identity key; requires that the key has * been set, and that we are running as a Tor server. */ crypto_pk_env_t * get_server_identity_key(void) { tor_assert(server_identitykey); tor_assert(server_mode(get_options())); assert_identity_keys_ok(); return server_identitykey; } /** Return true iff the server identity key has been set. */ int server_identity_key_is_set(void) { return server_identitykey != NULL; } /** Set the current client identity key to k. */ void set_client_identity_key(crypto_pk_env_t *k) { crypto_free_pk_env(client_identitykey); client_identitykey = k; } /** Returns the current client identity key for use on outgoing TLS * connections; requires that the key has been set. */ crypto_pk_env_t * get_tlsclient_identity_key(void) { tor_assert(client_identitykey); assert_identity_keys_ok(); return client_identitykey; } /** Return true iff the client identity key has been set. */ int client_identity_key_is_set(void) { return client_identitykey != NULL; } /** Return the key certificate for this v3 (voting) authority, or NULL * if we have no such certificate. */ authority_cert_t * get_my_v3_authority_cert(void) { return authority_key_certificate; } /** Return the v3 signing key for this v3 (voting) authority, or NULL * if we have no such key. */ crypto_pk_env_t * get_my_v3_authority_signing_key(void) { return authority_signing_key; } /** If we're an authority, and we're using a legacy authority identity key for * emergency migration purposes, return the certificate associated with that * key. */ authority_cert_t * get_my_v3_legacy_cert(void) { return legacy_key_certificate; } /** If we're an authority, and we're using a legacy authority identity key for * emergency migration purposes, return that key. */ crypto_pk_env_t * get_my_v3_legacy_signing_key(void) { return legacy_signing_key; } /** Replace the previous onion key with the current onion key, and generate * a new previous onion key. Immediately after calling this function, * the OR should: * - schedule all previous cpuworkers to shut down _after_ processing * pending work. (This will cause fresh cpuworkers to be generated.) * - generate and upload a fresh routerinfo. */ void rotate_onion_key(void) { char *fname, *fname_prev; crypto_pk_env_t *prkey; or_state_t *state = get_or_state(); time_t now; fname = get_datadir_fname2("keys", "secret_onion_key"); fname_prev = get_datadir_fname2("keys", "secret_onion_key.old"); if (!(prkey = crypto_new_pk_env())) { log_err(LD_GENERAL,"Error constructing rotated onion key"); goto error; } if (crypto_pk_generate_key(prkey)) { log_err(LD_BUG,"Error generating onion key"); goto error; } if (file_status(fname) == FN_FILE) { if (replace_file(fname, fname_prev)) goto error; } if (crypto_pk_write_private_key_to_filename(prkey, fname)) { log_err(LD_FS,"Couldn't write generated onion key to \"%s\".", fname); goto error; } log_info(LD_GENERAL, "Rotating onion key"); tor_mutex_acquire(key_lock); crypto_free_pk_env(lastonionkey); lastonionkey = onionkey; onionkey = prkey; now = time(NULL); state->LastRotatedOnionKey = onionkey_set_at = now; tor_mutex_release(key_lock); mark_my_descriptor_dirty("rotated onion key"); or_state_mark_dirty(state, get_options()->AvoidDiskWrites ? now+3600 : 0); goto done; error: log_warn(LD_GENERAL, "Couldn't rotate onion key."); if (prkey) crypto_free_pk_env(prkey); done: tor_free(fname); tor_free(fname_prev); } /** Try to read an RSA key from fname. If fname doesn't exist * and generate is true, create a new RSA key and save it in * fname. Return the read/created key, or NULL on error. Log all * errors at level severity. */ crypto_pk_env_t * init_key_from_file(const char *fname, int generate, int severity) { crypto_pk_env_t *prkey = NULL; if (!(prkey = crypto_new_pk_env())) { log(severity, LD_GENERAL,"Error constructing key"); goto error; } switch (file_status(fname)) { case FN_DIR: case FN_ERROR: log(severity, LD_FS,"Can't read key from \"%s\"", fname); goto error; case FN_NOENT: if (generate) { if (!have_lockfile()) { if (try_locking(get_options(), 0)<0) { /* Make sure that --list-fingerprint only creates new keys * if there is no possibility for a deadlock. */ log(severity, LD_FS, "Another Tor process has locked \"%s\". Not " "writing any new keys.", fname); /*XXXX The 'other process' might make a key in a second or two; * maybe we should wait for it. */ goto error; } } log_info(LD_GENERAL, "No key found in \"%s\"; generating fresh key.", fname); if (crypto_pk_generate_key(prkey)) { log(severity, LD_GENERAL,"Error generating onion key"); goto error; } if (crypto_pk_check_key(prkey) <= 0) { log(severity, LD_GENERAL,"Generated key seems invalid"); goto error; } log_info(LD_GENERAL, "Generated key seems valid"); if (crypto_pk_write_private_key_to_filename(prkey, fname)) { log(severity, LD_FS, "Couldn't write generated key to \"%s\".", fname); goto error; } } else { log_info(LD_GENERAL, "No key found in \"%s\"", fname); } return prkey; case FN_FILE: if (crypto_pk_read_private_key_from_filename(prkey, fname)) { log(severity, LD_GENERAL,"Error loading private key."); goto error; } return prkey; default: tor_assert(0); } error: if (prkey) crypto_free_pk_env(prkey); return NULL; } /** Try to load the vote-signing private key and certificate for being a v3 * directory authority, and make sure they match. If legacy, load a * legacy key/cert set for emergency key migration; otherwise load the regular * key/cert set. On success, store them into *key_out and * *cert_out respectively, and return 0. On failure, return -1. */ static int load_authority_keyset(int legacy, crypto_pk_env_t **key_out, authority_cert_t **cert_out) { int r = -1; char *fname = NULL, *cert = NULL; const char *eos = NULL; crypto_pk_env_t *signing_key = NULL; authority_cert_t *parsed = NULL; fname = get_datadir_fname2("keys", legacy ? "legacy_signing_key" : "authority_signing_key"); signing_key = init_key_from_file(fname, 0, LOG_INFO); if (!signing_key) { log_warn(LD_DIR, "No version 3 directory key found in %s", fname); goto done; } tor_free(fname); fname = get_datadir_fname2("keys", legacy ? "legacy_certificate" : "authority_certificate"); cert = read_file_to_str(fname, 0, NULL); if (!cert) { log_warn(LD_DIR, "Signing key found, but no certificate found in %s", fname); goto done; } parsed = authority_cert_parse_from_string(cert, &eos); if (!parsed) { log_warn(LD_DIR, "Unable to parse certificate in %s", fname); goto done; } if (crypto_pk_cmp_keys(signing_key, parsed->signing_key) != 0) { log_warn(LD_DIR, "Stored signing key does not match signing key in " "certificate"); goto done; } crypto_free_pk_env(*key_out); authority_cert_free(*cert_out); *key_out = signing_key; *cert_out = parsed; r = 0; signing_key = NULL; parsed = NULL; done: tor_free(fname); tor_free(cert); crypto_free_pk_env(signing_key); authority_cert_free(parsed); return r; } /** Load the v3 (voting) authority signing key and certificate, if they are * present. Return -1 if anything is missing, mismatched, or unloadable; * return 0 on success. */ static int init_v3_authority_keys(void) { if (load_authority_keyset(0, &authority_signing_key, &authority_key_certificate)<0) return -1; if (get_options()->V3AuthUseLegacyKey && load_authority_keyset(1, &legacy_signing_key, &legacy_key_certificate)<0) return -1; return 0; } /** If we're a v3 authority, check whether we have a certificate that's * likely to expire soon. Warn if we do, but not too often. */ void v3_authority_check_key_expiry(void) { time_t now, expires; static time_t last_warned = 0; int badness, time_left, warn_interval; if (!authdir_mode_v3(get_options()) || !authority_key_certificate) return; now = time(NULL); expires = authority_key_certificate->expires; time_left = (int)( expires - now ); if (time_left <= 0) { badness = LOG_ERR; warn_interval = 60*60; } else if (time_left <= 24*60*60) { badness = LOG_WARN; warn_interval = 60*60; } else if (time_left <= 24*60*60*7) { badness = LOG_WARN; warn_interval = 24*60*60; } else if (time_left <= 24*60*60*30) { badness = LOG_WARN; warn_interval = 24*60*60*5; } else { return; } if (last_warned + warn_interval > now) return; if (time_left <= 0) { log(badness, LD_DIR, "Your v3 authority certificate has expired." " Generate a new one NOW."); } else if (time_left <= 24*60*60) { log(badness, LD_DIR, "Your v3 authority certificate expires in %d hours;" " Generate a new one NOW.", time_left/(60*60)); } else { log(badness, LD_DIR, "Your v3 authority certificate expires in %d days;" " Generate a new one soon.", time_left/(24*60*60)); } last_warned = now; } /** Initialize all OR private keys, and the TLS context, as necessary. * On OPs, this only initializes the tls context. Return 0 on success, * or -1 if Tor should die. */ int init_keys(void) { char *keydir; char fingerprint[FINGERPRINT_LEN+1]; /*nicknamefp\n\0 */ char fingerprint_line[MAX_NICKNAME_LEN+FINGERPRINT_LEN+3]; const char *mydesc; crypto_pk_env_t *prkey; char digest[DIGEST_LEN]; char v3_digest[DIGEST_LEN]; char *cp; const or_options_t *options = get_options(); dirinfo_type_t type; time_t now = time(NULL); trusted_dir_server_t *ds; int v3_digest_set = 0; authority_cert_t *cert = NULL; if (!key_lock) key_lock = tor_mutex_new(); /* There are a couple of paths that put us here before we've asked * openssl to initialize itself. */ if (crypto_global_init(get_options()->HardwareAccel, get_options()->AccelName, get_options()->AccelDir)) { log_err(LD_BUG, "Unable to initialize OpenSSL. Exiting."); return -1; } /* OP's don't need persistent keys; just make up an identity and * initialize the TLS context. */ if (!server_mode(options)) { if (!(prkey = crypto_new_pk_env())) return -1; if (crypto_pk_generate_key(prkey)) { crypto_free_pk_env(prkey); return -1; } set_client_identity_key(prkey); /* Create a TLS context. */ if (tor_tls_context_init(0, get_tlsclient_identity_key(), NULL, MAX_SSL_KEY_LIFETIME_ADVERTISED) < 0) { log_err(LD_GENERAL,"Error creating TLS context for Tor client."); return -1; } return 0; } /* Make sure DataDirectory exists, and is private. */ if (check_private_dir(options->DataDirectory, CPD_CREATE, options->User)) { return -1; } /* Check the key directory. */ keydir = get_datadir_fname("keys"); if (check_private_dir(keydir, CPD_CREATE, options->User)) { tor_free(keydir); return -1; } tor_free(keydir); /* 1a. Read v3 directory authority key/cert information. */ memset(v3_digest, 0, sizeof(v3_digest)); if (authdir_mode_v3(options)) { if (init_v3_authority_keys()<0) { log_err(LD_GENERAL, "We're configured as a V3 authority, but we " "were unable to load our v3 authority keys and certificate! " "Use tor-gencert to generate them. Dying."); return -1; } cert = get_my_v3_authority_cert(); if (cert) { crypto_pk_get_digest(get_my_v3_authority_cert()->identity_key, v3_digest); v3_digest_set = 1; } } /* 1b. Read identity key. Make it if none is found. */ keydir = get_datadir_fname2("keys", "secret_id_key"); log_info(LD_GENERAL,"Reading/making identity key \"%s\"...",keydir); prkey = init_key_from_file(keydir, 1, LOG_ERR); tor_free(keydir); if (!prkey) return -1; set_server_identity_key(prkey); /* 1c. If we are configured as a bridge, generate a client key; * otherwise, set the server identity key as our client identity * key. */ if (public_server_mode(options)) { set_client_identity_key(crypto_pk_dup_key(prkey)); /* set above */ } else { if (!(prkey = crypto_new_pk_env())) return -1; if (crypto_pk_generate_key(prkey)) { crypto_free_pk_env(prkey); return -1; } set_client_identity_key(prkey); } /* 2. Read onion key. Make it if none is found. */ keydir = get_datadir_fname2("keys", "secret_onion_key"); log_info(LD_GENERAL,"Reading/making onion key \"%s\"...",keydir); prkey = init_key_from_file(keydir, 1, LOG_ERR); tor_free(keydir); if (!prkey) return -1; set_onion_key(prkey); if (options->command == CMD_RUN_TOR) { /* only mess with the state file if we're actually running Tor */ or_state_t *state = get_or_state(); if (state->LastRotatedOnionKey > 100 && state->LastRotatedOnionKey < now) { /* We allow for some parsing slop, but we don't want to risk accepting * values in the distant future. If we did, we might never rotate the * onion key. */ onionkey_set_at = state->LastRotatedOnionKey; } else { /* We have no LastRotatedOnionKey set; either we just created the key * or it's a holdover from 0.1.2.4-alpha-dev or earlier. In either case, * start the clock ticking now so that we will eventually rotate it even * if we don't stay up for a full MIN_ONION_KEY_LIFETIME. */ state->LastRotatedOnionKey = onionkey_set_at = now; or_state_mark_dirty(state, options->AvoidDiskWrites ? time(NULL)+3600 : 0); } } keydir = get_datadir_fname2("keys", "secret_onion_key.old"); if (!lastonionkey && file_status(keydir) == FN_FILE) { prkey = init_key_from_file(keydir, 1, LOG_ERR); if (prkey) lastonionkey = prkey; } tor_free(keydir); /* 3. Initialize link key and TLS context. */ if (tor_tls_context_init(public_server_mode(options), get_tlsclient_identity_key(), get_server_identity_key(), MAX_SSL_KEY_LIFETIME_ADVERTISED) < 0) { log_err(LD_GENERAL,"Error initializing TLS context"); return -1; } /* 4. Build our router descriptor. */ /* Must be called after keys are initialized. */ mydesc = router_get_my_descriptor(); if (authdir_mode_handles_descs(options, ROUTER_PURPOSE_GENERAL)) { const char *m = NULL; routerinfo_t *ri; /* We need to add our own fingerprint so it gets recognized. */ if (dirserv_add_own_fingerprint(options->Nickname, get_server_identity_key())) { log_err(LD_GENERAL,"Error adding own fingerprint to approved set"); return -1; } if (mydesc) { ri = router_parse_entry_from_string(mydesc, NULL, 1, 0, NULL); if (!ri) { log_err(LD_GENERAL,"Generated a routerinfo we couldn't parse."); return -1; } if (!WRA_WAS_ADDED(dirserv_add_descriptor(ri, &m, "self"))) { log_err(LD_GENERAL,"Unable to add own descriptor to directory: %s", m?m:""); return -1; } } } /* 5. Dump fingerprint to 'fingerprint' */ keydir = get_datadir_fname("fingerprint"); log_info(LD_GENERAL,"Dumping fingerprint to \"%s\"...",keydir); if (crypto_pk_get_fingerprint(get_server_identity_key(), fingerprint, 0) < 0) { log_err(LD_GENERAL,"Error computing fingerprint"); tor_free(keydir); return -1; } tor_assert(strlen(options->Nickname) <= MAX_NICKNAME_LEN); if (tor_snprintf(fingerprint_line, sizeof(fingerprint_line), "%s %s\n",options->Nickname, fingerprint) < 0) { log_err(LD_GENERAL,"Error writing fingerprint line"); tor_free(keydir); return -1; } /* Check whether we need to write the fingerprint file. */ cp = NULL; if (file_status(keydir) == FN_FILE) cp = read_file_to_str(keydir, 0, NULL); if (!cp || strcmp(cp, fingerprint_line)) { if (write_str_to_file(keydir, fingerprint_line, 0)) { log_err(LD_FS, "Error writing fingerprint line to file"); tor_free(keydir); tor_free(cp); return -1; } } tor_free(cp); tor_free(keydir); log(LOG_NOTICE, LD_GENERAL, "Your Tor server's identity key fingerprint is '%s %s'", options->Nickname, fingerprint); if (!authdir_mode(options)) return 0; /* 6. [authdirserver only] load approved-routers file */ if (dirserv_load_fingerprint_file() < 0) { log_err(LD_GENERAL,"Error loading fingerprints"); return -1; } /* 6b. [authdirserver only] add own key to approved directories. */ crypto_pk_get_digest(get_server_identity_key(), digest); type = ((options->V1AuthoritativeDir ? V1_DIRINFO : NO_DIRINFO) | (options->V2AuthoritativeDir ? V2_DIRINFO : NO_DIRINFO) | (options->V3AuthoritativeDir ? (V3_DIRINFO|MICRODESC_DIRINFO|EXTRAINFO_DIRINFO) : NO_DIRINFO) | (options->BridgeAuthoritativeDir ? BRIDGE_DIRINFO : NO_DIRINFO) | (options->HSAuthoritativeDir ? HIDSERV_DIRINFO : NO_DIRINFO)); ds = router_get_trusteddirserver_by_digest(digest); if (!ds) { ds = add_trusted_dir_server(options->Nickname, NULL, router_get_advertised_dir_port(options, 0), router_get_advertised_or_port(options), digest, v3_digest, type); if (!ds) { log_err(LD_GENERAL,"We want to be a directory authority, but we " "couldn't add ourselves to the authority list. Failing."); return -1; } } if (ds->type != type) { log_warn(LD_DIR, "Configured authority type does not match authority " "type in DirServer list. Adjusting. (%d v %d)", type, ds->type); ds->type = type; } if (v3_digest_set && (ds->type & V3_DIRINFO) && tor_memneq(v3_digest, ds->v3_identity_digest, DIGEST_LEN)) { log_warn(LD_DIR, "V3 identity key does not match identity declared in " "DirServer line. Adjusting."); memcpy(ds->v3_identity_digest, v3_digest, DIGEST_LEN); } if (cert) { /* add my own cert to the list of known certs */ log_info(LD_DIR, "adding my own v3 cert"); if (trusted_dirs_load_certs_from_string( cert->cache_info.signed_descriptor_body, 0, 0)<0) { log_warn(LD_DIR, "Unable to parse my own v3 cert! Failing."); return -1; } } return 0; /* success */ } /* Keep track of whether we should upload our server descriptor, * and what type of server we are. */ /** Whether we can reach our ORPort from the outside. */ static int can_reach_or_port = 0; /** Whether we can reach our DirPort from the outside. */ static int can_reach_dir_port = 0; /** Forget what we have learned about our reachability status. */ void router_reset_reachability(void) { can_reach_or_port = can_reach_dir_port = 0; } /** Return 1 if ORPort is known reachable; else return 0. */ int check_whether_orport_reachable(void) { const or_options_t *options = get_options(); return options->AssumeReachable || can_reach_or_port; } /** Return 1 if we don't have a dirport configured, or if it's reachable. */ int check_whether_dirport_reachable(void) { const or_options_t *options = get_options(); return !options->DirPort || options->AssumeReachable || we_are_hibernating() || can_reach_dir_port; } /** Look at a variety of factors, and return 0 if we don't want to * advertise the fact that we have a DirPort open. Else return the * DirPort we want to advertise. * * Log a helpful message if we change our mind about whether to publish * a DirPort. */ static int decide_to_advertise_dirport(const or_options_t *options, uint16_t dir_port) { static int advertising=1; /* start out assuming we will advertise */ int new_choice=1; const char *reason = NULL; /* Section one: reasons to publish or not publish that aren't * worth mentioning to the user, either because they're obvious * or because they're normal behavior. */ if (!dir_port) /* short circuit the rest of the function */ return 0; if (authdir_mode(options)) /* always publish */ return dir_port; if (we_are_hibernating()) return 0; if (!check_whether_dirport_reachable()) return 0; if (!router_get_advertised_dir_port(options, dir_port)) return 0; /* Section two: reasons to publish or not publish that the user * might find surprising. These are generally config options that * make us choose not to publish. */ if (accounting_is_enabled(options)) { /* if we might potentially hibernate */ new_choice = 0; reason = "AccountingMax enabled"; #define MIN_BW_TO_ADVERTISE_DIRPORT 51200 } else if (options->BandwidthRate < MIN_BW_TO_ADVERTISE_DIRPORT || (options->RelayBandwidthRate > 0 && options->RelayBandwidthRate < MIN_BW_TO_ADVERTISE_DIRPORT)) { /* if we're advertising a small amount */ new_choice = 0; reason = "BandwidthRate under 50KB"; } if (advertising != new_choice) { if (new_choice == 1) { log(LOG_NOTICE, LD_DIR, "Advertising DirPort as %d", dir_port); } else { tor_assert(reason); log(LOG_NOTICE, LD_DIR, "Not advertising DirPort (Reason: %s)", reason); } advertising = new_choice; } return advertising ? dir_port : 0; } /** Some time has passed, or we just got new directory information. * See if we currently believe our ORPort or DirPort to be * unreachable. If so, launch a new test for it. * * For ORPort, we simply try making a circuit that ends at ourselves. * Success is noticed in onionskin_answer(). * * For DirPort, we make a connection via Tor to our DirPort and ask * for our own server descriptor. * Success is noticed in connection_dir_client_reached_eof(). */ void consider_testing_reachability(int test_or, int test_dir) { const routerinfo_t *me = router_get_my_routerinfo(); int orport_reachable = check_whether_orport_reachable(); tor_addr_t addr; const or_options_t *options = get_options(); if (!me) return; if (routerset_contains_router(options->ExcludeNodes, me, -1) && options->StrictNodes) { /* If we've excluded ourself, and StrictNodes is set, we can't test * ourself. */ if (test_or || test_dir) { #define SELF_EXCLUDED_WARN_INTERVAL 3600 static ratelim_t warning_limit=RATELIM_INIT(SELF_EXCLUDED_WARN_INTERVAL); char *msg; if ((msg = rate_limit_log(&warning_limit, approx_time()))) { log_warn(LD_CIRC, "Can't peform self-tests for this relay: we have " "listed ourself in ExcludeNodes, and StrictNodes is set. " "We cannot learn whether we are usable, and will not " "be able to advertise ourself.%s", msg); tor_free(msg); } } return; } if (test_or && (!orport_reachable || !circuit_enough_testing_circs())) { extend_info_t *ei; log_info(LD_CIRC, "Testing %s of my ORPort: %s:%d.", !orport_reachable ? "reachability" : "bandwidth", me->address, me->or_port); ei = extend_info_from_router(me); circuit_launch_by_extend_info(CIRCUIT_PURPOSE_TESTING, ei, CIRCLAUNCH_NEED_CAPACITY|CIRCLAUNCH_IS_INTERNAL); extend_info_free(ei); } tor_addr_from_ipv4h(&addr, me->addr); if (test_dir && !check_whether_dirport_reachable() && !connection_get_by_type_addr_port_purpose( CONN_TYPE_DIR, &addr, me->dir_port, DIR_PURPOSE_FETCH_SERVERDESC)) { /* ask myself, via tor, for my server descriptor. */ directory_initiate_command(me->address, &addr, me->or_port, me->dir_port, 0, /* does not matter */ 0, me->cache_info.identity_digest, DIR_PURPOSE_FETCH_SERVERDESC, ROUTER_PURPOSE_GENERAL, 1, "authority.z", NULL, 0, 0); } } /** Annotate that we found our ORPort reachable. */ void router_orport_found_reachable(void) { const routerinfo_t *me = router_get_my_routerinfo(); if (!can_reach_or_port && me) { log_notice(LD_OR,"Self-testing indicates your ORPort is reachable from " "the outside. Excellent.%s", get_options()->_PublishServerDescriptor != NO_DIRINFO ? " Publishing server descriptor." : ""); can_reach_or_port = 1; mark_my_descriptor_dirty("ORPort found reachable"); control_event_server_status(LOG_NOTICE, "REACHABILITY_SUCCEEDED ORADDRESS=%s:%d", me->address, me->or_port); } } /** Annotate that we found our DirPort reachable. */ void router_dirport_found_reachable(void) { const routerinfo_t *me = router_get_my_routerinfo(); if (!can_reach_dir_port && me) { log_notice(LD_DIRSERV,"Self-testing indicates your DirPort is reachable " "from the outside. Excellent."); can_reach_dir_port = 1; if (decide_to_advertise_dirport(get_options(), me->dir_port)) mark_my_descriptor_dirty("DirPort found reachable"); control_event_server_status(LOG_NOTICE, "REACHABILITY_SUCCEEDED DIRADDRESS=%s:%d", me->address, me->dir_port); } } /** We have enough testing circuits open. Send a bunch of "drop" * cells down each of them, to exercise our bandwidth. */ void router_perform_bandwidth_test(int num_circs, time_t now) { int num_cells = (int)(get_options()->BandwidthRate * 10 / CELL_NETWORK_SIZE); int max_cells = num_cells < CIRCWINDOW_START ? num_cells : CIRCWINDOW_START; int cells_per_circuit = max_cells / num_circs; origin_circuit_t *circ = NULL; log_notice(LD_OR,"Performing bandwidth self-test...done."); while ((circ = circuit_get_next_by_pk_and_purpose(circ, NULL, CIRCUIT_PURPOSE_TESTING))) { /* dump cells_per_circuit drop cells onto this circ */ int i = cells_per_circuit; if (circ->_base.state != CIRCUIT_STATE_OPEN) continue; circ->_base.timestamp_dirty = now; while (i-- > 0) { if (relay_send_command_from_edge(0, TO_CIRCUIT(circ), RELAY_COMMAND_DROP, NULL, 0, circ->cpath->prev)<0) { return; /* stop if error */ } } } } /** Return true iff we believe ourselves to be an authoritative * directory server. */ int authdir_mode(const or_options_t *options) { return options->AuthoritativeDir != 0; } /** Return true iff we believe ourselves to be a v1 authoritative * directory server. */ int authdir_mode_v1(const or_options_t *options) { return authdir_mode(options) && options->V1AuthoritativeDir != 0; } /** Return true iff we believe ourselves to be a v2 authoritative * directory server. */ int authdir_mode_v2(const or_options_t *options) { return authdir_mode(options) && options->V2AuthoritativeDir != 0; } /** Return true iff we believe ourselves to be a v3 authoritative * directory server. */ int authdir_mode_v3(const or_options_t *options) { return authdir_mode(options) && options->V3AuthoritativeDir != 0; } /** Return true iff we are a v1, v2, or v3 directory authority. */ int authdir_mode_any_main(const or_options_t *options) { return options->V1AuthoritativeDir || options->V2AuthoritativeDir || options->V3AuthoritativeDir; } /** Return true if we believe ourselves to be any kind of * authoritative directory beyond just a hidserv authority. */ int authdir_mode_any_nonhidserv(const or_options_t *options) { return options->BridgeAuthoritativeDir || authdir_mode_any_main(options); } /** Return true iff we are an authoritative directory server that is * authoritative about receiving and serving descriptors of type * purpose on its dirport. Use -1 for "any purpose". */ int authdir_mode_handles_descs(const or_options_t *options, int purpose) { if (purpose < 0) return authdir_mode_any_nonhidserv(options); else if (purpose == ROUTER_PURPOSE_GENERAL) return authdir_mode_any_main(options); else if (purpose == ROUTER_PURPOSE_BRIDGE) return (options->BridgeAuthoritativeDir); else return 0; } /** Return true iff we are an authoritative directory server that * publishes its own network statuses. */ int authdir_mode_publishes_statuses(const or_options_t *options) { if (authdir_mode_bridge(options)) return 0; return authdir_mode_any_nonhidserv(options); } /** Return true iff we are an authoritative directory server that * tests reachability of the descriptors it learns about. */ int authdir_mode_tests_reachability(const or_options_t *options) { return authdir_mode_handles_descs(options, -1); } /** Return true iff we believe ourselves to be a bridge authoritative * directory server. */ int authdir_mode_bridge(const or_options_t *options) { return authdir_mode(options) && options->BridgeAuthoritativeDir != 0; } /** Return true iff we are trying to be a server. */ int server_mode(const or_options_t *options) { if (options->ClientOnly) return 0; return (options->ORPort != 0 || options->ORListenAddress); } /** Return true iff we are trying to be a non-bridge server. */ int public_server_mode(const or_options_t *options) { if (!server_mode(options)) return 0; return (!options->BridgeRelay); } /** Return true iff the combination of options in options and parameters * in the consensus mean that we don't want to allow exits from circuits * we got from addresses not known to be servers. */ int should_refuse_unknown_exits(const or_options_t *options) { if (options->RefuseUnknownExits != -1) { return options->RefuseUnknownExits; } else { return networkstatus_get_param(NULL, "refuseunknownexits", 1, 0, 1); } } /** Remember if we've advertised ourselves to the dirservers. */ static int server_is_advertised=0; /** Return true iff we have published our descriptor lately. */ int advertised_server_mode(void) { return server_is_advertised; } /** * Called with a boolean: set whether we have recently published our * descriptor. */ static void set_server_advertised(int s) { server_is_advertised = s; } /** Return true iff we are trying to proxy client connections. */ int proxy_mode(const or_options_t *options) { (void)options; return smartlist_len(get_configured_client_ports()) > 0; } /** Decide if we're a publishable server. We are a publishable server if: * - We don't have the ClientOnly option set * and * - We have the PublishServerDescriptor option set to non-empty * and * - We have ORPort set * and * - We believe we are reachable from the outside; or * - We are an authoritative directory server. */ static int decide_if_publishable_server(void) { const or_options_t *options = get_options(); if (options->ClientOnly) return 0; if (options->_PublishServerDescriptor == NO_DIRINFO) return 0; if (!server_mode(options)) return 0; if (authdir_mode(options)) return 1; if (!router_get_advertised_or_port(options)) return 0; return check_whether_orport_reachable(); } /** Initiate server descriptor upload as reasonable (if server is publishable, * etc). force is as for router_upload_dir_desc_to_dirservers. * * We need to rebuild the descriptor if it's dirty even if we're not * uploading, because our reachability testing *uses* our descriptor to * determine what IP address and ports to test. */ void consider_publishable_server(int force) { int rebuilt; if (!server_mode(get_options())) return; rebuilt = router_rebuild_descriptor(0); if (decide_if_publishable_server()) { set_server_advertised(1); if (rebuilt == 0) router_upload_dir_desc_to_dirservers(force); } else { set_server_advertised(0); } } /** Return the port that we should advertise as our ORPort; this is either * the one configured in the ORPort option, or the one we actually bound to * if ORPort is "auto". */ uint16_t router_get_advertised_or_port(const or_options_t *options) { if (options->ORPort == CFG_AUTO_PORT) { connection_t *c = connection_get_by_type(CONN_TYPE_OR_LISTENER); if (c) return c->port; return 0; } return options->ORPort; } /** Return the port that we should advertise as our DirPort; * this is one of three possibilities: * The one that is passed as dirport if the DirPort option is 0, or * the one configured in the DirPort option, * or the one we actually bound to if DirPort is "auto". */ uint16_t router_get_advertised_dir_port(const or_options_t *options, uint16_t dirport) { if (!options->DirPort) return dirport; if (options->DirPort == CFG_AUTO_PORT) { connection_t *c = connection_get_by_type(CONN_TYPE_DIR_LISTENER); if (c) return c->port; return 0; } return options->DirPort; } /* * OR descriptor generation. */ /** My routerinfo. */ static routerinfo_t *desc_routerinfo = NULL; /** My extrainfo */ static extrainfo_t *desc_extrainfo = NULL; /** Why did we most recently decide to regenerate our descriptor? Used to * tell the authorities why we're sending it to them. */ static const char *desc_gen_reason = NULL; /** Since when has our descriptor been "clean"? 0 if we need to regenerate it * now. */ static time_t desc_clean_since = 0; /** Why did we mark the descriptor dirty? */ static const char *desc_dirty_reason = NULL; /** Boolean: do we need to regenerate the above? */ static int desc_needs_upload = 0; /** OR only: If force is true, or we haven't uploaded this * descriptor successfully yet, try to upload our signed descriptor to * all the directory servers we know about. */ void router_upload_dir_desc_to_dirservers(int force) { const routerinfo_t *ri; extrainfo_t *ei; char *msg; size_t desc_len, extra_len = 0, total_len; dirinfo_type_t auth = get_options()->_PublishServerDescriptor; ri = router_get_my_routerinfo(); if (!ri) { log_info(LD_GENERAL, "No descriptor; skipping upload"); return; } ei = router_get_my_extrainfo(); if (auth == NO_DIRINFO) return; if (!force && !desc_needs_upload) return; log_info(LD_OR, "Uploading relay descriptor to directory authorities%s", force ? " (forced)" : ""); desc_needs_upload = 0; desc_len = ri->cache_info.signed_descriptor_len; extra_len = ei ? ei->cache_info.signed_descriptor_len : 0; total_len = desc_len + extra_len + 1; msg = tor_malloc(total_len); memcpy(msg, ri->cache_info.signed_descriptor_body, desc_len); if (ei) { memcpy(msg+desc_len, ei->cache_info.signed_descriptor_body, extra_len); } msg[desc_len+extra_len] = 0; directory_post_to_dirservers(DIR_PURPOSE_UPLOAD_DIR, (auth & BRIDGE_DIRINFO) ? ROUTER_PURPOSE_BRIDGE : ROUTER_PURPOSE_GENERAL, auth, msg, desc_len, extra_len); tor_free(msg); } /** OR only: Check whether my exit policy says to allow connection to * conn. Return 0 if we accept; non-0 if we reject. */ int router_compare_to_my_exit_policy(edge_connection_t *conn) { if (!router_get_my_routerinfo()) /* make sure desc_routerinfo exists */ return -1; /* make sure it's resolved to something. this way we can't get a 'maybe' below. */ if (tor_addr_is_null(&conn->_base.addr)) return -1; /* XXXX IPv6 */ if (tor_addr_family(&conn->_base.addr) != AF_INET) return -1; return compare_tor_addr_to_addr_policy(&conn->_base.addr, conn->_base.port, desc_routerinfo->exit_policy) != ADDR_POLICY_ACCEPTED; } /** Return true iff my exit policy is reject *:*. Return -1 if we don't * have a descriptor */ int router_my_exit_policy_is_reject_star(void) { if (!router_get_my_routerinfo()) /* make sure desc_routerinfo exists */ return -1; return desc_routerinfo->policy_is_reject_star; } /** Return true iff I'm a server and digest is equal to * my server identity key digest. */ int router_digest_is_me(const char *digest) { return (server_identitykey && tor_memeq(server_identitykey_digest, digest, DIGEST_LEN)); } /** Return true iff I'm a server and digest is equal to * my identity digest. */ int router_extrainfo_digest_is_me(const char *digest) { extrainfo_t *ei = router_get_my_extrainfo(); if (!ei) return 0; return tor_memeq(digest, ei->cache_info.signed_descriptor_digest, DIGEST_LEN); } /** A wrapper around router_digest_is_me(). */ int router_is_me(const routerinfo_t *router) { return router_digest_is_me(router->cache_info.identity_digest); } /** Return true iff fp is a hex fingerprint of my identity digest. */ int router_fingerprint_is_me(const char *fp) { char digest[DIGEST_LEN]; if (strlen(fp) == HEX_DIGEST_LEN && base16_decode(digest, sizeof(digest), fp, HEX_DIGEST_LEN) == 0) return router_digest_is_me(digest); return 0; } /** Return a routerinfo for this OR, rebuilding a fresh one if * necessary. Return NULL on error, or if called on an OP. */ const routerinfo_t * router_get_my_routerinfo(void) { if (!server_mode(get_options())) return NULL; if (router_rebuild_descriptor(0)) return NULL; return desc_routerinfo; } /** OR only: Return a signed server descriptor for this OR, rebuilding a fresh * one if necessary. Return NULL on error. */ const char * router_get_my_descriptor(void) { const char *body; if (!router_get_my_routerinfo()) return NULL; /* Make sure this is nul-terminated. */ tor_assert(desc_routerinfo->cache_info.saved_location == SAVED_NOWHERE); body = signed_descriptor_get_body(&desc_routerinfo->cache_info); tor_assert(!body[desc_routerinfo->cache_info.signed_descriptor_len]); log_debug(LD_GENERAL,"my desc is '%s'", body); return body; } /** Return the extrainfo document for this OR, or NULL if we have none. * Rebuilt it (and the server descriptor) if necessary. */ extrainfo_t * router_get_my_extrainfo(void) { if (!server_mode(get_options())) return NULL; if (router_rebuild_descriptor(0)) return NULL; return desc_extrainfo; } /** Return a human-readable string describing what triggered us to generate * our current descriptor, or NULL if we don't know. */ const char * router_get_descriptor_gen_reason(void) { return desc_gen_reason; } /** A list of nicknames that we've warned about including in our family * declaration verbatim rather than as digests. */ static smartlist_t *warned_nonexistent_family = NULL; static int router_guess_address_from_dir_headers(uint32_t *guess); /** Make a current best guess at our address, either because * it's configured in torrc, or because we've learned it from * dirserver headers. Place the answer in *addr and return * 0 on success, else return -1 if we have no guess. */ int router_pick_published_address(const or_options_t *options, uint32_t *addr) { if (resolve_my_address(LOG_INFO, options, addr, NULL) < 0) { log_info(LD_CONFIG, "Could not determine our address locally. " "Checking if directory headers provide any hints."); if (router_guess_address_from_dir_headers(addr) < 0) { log_info(LD_CONFIG, "No hints from directory headers either. " "Will try again later."); return -1; } } log_info(LD_CONFIG,"Success: chose address '%s'.", fmt_addr32(*addr)); return 0; } /** If force is true, or our descriptor is out-of-date, rebuild a fresh * routerinfo, signed server descriptor, and extra-info document for this OR. * Return 0 on success, -1 on temporary error. */ int router_rebuild_descriptor(int force) { routerinfo_t *ri; extrainfo_t *ei; uint32_t addr; char platform[256]; int hibernating = we_are_hibernating(); const or_options_t *options = get_options(); if (desc_clean_since && !force) return 0; if (router_pick_published_address(options, &addr) < 0 || router_get_advertised_or_port(options) == 0) { /* Stop trying to rebuild our descriptor every second. We'll * learn that it's time to try again when ip_address_changed() * marks it dirty. */ desc_clean_since = time(NULL); return -1; } log_info(LD_OR, "Rebuilding relay descriptor%s", force ? " (forced)" : ""); ri = tor_malloc_zero(sizeof(routerinfo_t)); ri->cache_info.routerlist_index = -1; ri->address = tor_dup_ip(addr); ri->nickname = tor_strdup(options->Nickname); ri->addr = addr; ri->or_port = router_get_advertised_or_port(options); ri->dir_port = router_get_advertised_dir_port(options, 0); ri->cache_info.published_on = time(NULL); ri->onion_pkey = crypto_pk_dup_key(get_onion_key()); /* must invoke from * main thread */ ri->identity_pkey = crypto_pk_dup_key(get_server_identity_key()); if (crypto_pk_get_digest(ri->identity_pkey, ri->cache_info.identity_digest)<0) { routerinfo_free(ri); return -1; } get_platform_str(platform, sizeof(platform)); ri->platform = tor_strdup(platform); /* compute ri->bandwidthrate as the min of various options */ ri->bandwidthrate = get_effective_bwrate(options); /* and compute ri->bandwidthburst similarly */ ri->bandwidthburst = get_effective_bwburst(options); ri->bandwidthcapacity = hibernating ? 0 : rep_hist_bandwidth_assess(); if (dns_seems_to_be_broken() || has_dns_init_failed()) { /* DNS is screwed up; don't claim to be an exit. */ policies_exit_policy_append_reject_star(&ri->exit_policy); } else { policies_parse_exit_policy(options->ExitPolicy, &ri->exit_policy, options->ExitPolicyRejectPrivate, ri->address, !options->BridgeRelay); } ri->policy_is_reject_star = policy_is_reject_star(ri->exit_policy); #if 0 /* XXXX NM NM I belive this is safe to remove */ if (authdir_mode(options)) ri->is_valid = ri->is_named = 1; /* believe in yourself */ #endif if (options->MyFamily) { smartlist_t *family; if (!warned_nonexistent_family) warned_nonexistent_family = smartlist_create(); family = smartlist_create(); ri->declared_family = smartlist_create(); smartlist_split_string(family, options->MyFamily, ",", SPLIT_SKIP_SPACE|SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 0); SMARTLIST_FOREACH_BEGIN(family, char *, name) { const node_t *member; if (!strcasecmp(name, options->Nickname)) goto skip; /* Don't list ourself, that's redundant */ else member = node_get_by_nickname(name, 1); if (!member) { int is_legal = is_legal_nickname_or_hexdigest(name); if (!smartlist_string_isin(warned_nonexistent_family, name) && !is_legal_hexdigest(name)) { if (is_legal) log_warn(LD_CONFIG, "I have no descriptor for the router named \"%s\" in my " "declared family; I'll use the nickname as is, but " "this may confuse clients.", name); else log_warn(LD_CONFIG, "There is a router named \"%s\" in my " "declared family, but that isn't a legal nickname. " "Skipping it.", escaped(name)); smartlist_add(warned_nonexistent_family, tor_strdup(name)); } if (is_legal) { smartlist_add(ri->declared_family, name); name = NULL; } } else if (router_digest_is_me(member->identity)) { /* Don't list ourself in our own family; that's redundant */ /* XXX shouldn't be possible */ } else { char *fp = tor_malloc(HEX_DIGEST_LEN+2); fp[0] = '$'; base16_encode(fp+1,HEX_DIGEST_LEN+1, member->identity, DIGEST_LEN); smartlist_add(ri->declared_family, fp); if (smartlist_string_isin(warned_nonexistent_family, name)) smartlist_string_remove(warned_nonexistent_family, name); } skip: tor_free(name); } SMARTLIST_FOREACH_END(name); /* remove duplicates from the list */ smartlist_sort_strings(ri->declared_family); smartlist_uniq_strings(ri->declared_family); smartlist_free(family); } /* Now generate the extrainfo. */ ei = tor_malloc_zero(sizeof(extrainfo_t)); ei->cache_info.is_extrainfo = 1; strlcpy(ei->nickname, get_options()->Nickname, sizeof(ei->nickname)); ei->cache_info.published_on = ri->cache_info.published_on; memcpy(ei->cache_info.identity_digest, ri->cache_info.identity_digest, DIGEST_LEN); if (extrainfo_dump_to_string(&ei->cache_info.signed_descriptor_body, ei, get_server_identity_key()) < 0) { log_warn(LD_BUG, "Couldn't generate extra-info descriptor."); extrainfo_free(ei); ei = NULL; } else { ei->cache_info.signed_descriptor_len = strlen(ei->cache_info.signed_descriptor_body); router_get_extrainfo_hash(ei->cache_info.signed_descriptor_body, ei->cache_info.signed_descriptor_digest); } /* Now finish the router descriptor. */ if (ei) { memcpy(ri->cache_info.extra_info_digest, ei->cache_info.signed_descriptor_digest, DIGEST_LEN); } else { /* ri was allocated with tor_malloc_zero, so there is no need to * zero ri->cache_info.extra_info_digest here. */ } ri->cache_info.signed_descriptor_body = tor_malloc(8192); if (router_dump_router_to_string(ri->cache_info.signed_descriptor_body, 8192, ri, get_server_identity_key()) < 0) { log_warn(LD_BUG, "Couldn't generate router descriptor."); routerinfo_free(ri); extrainfo_free(ei); return -1; } ri->cache_info.signed_descriptor_len = strlen(ri->cache_info.signed_descriptor_body); ri->purpose = options->BridgeRelay ? ROUTER_PURPOSE_BRIDGE : ROUTER_PURPOSE_GENERAL; ri->cache_info.send_unencrypted = 1; /* Let bridges serve their own descriptors unencrypted, so they can * pass reachability testing. (If they want to be harder to notice, * they can always leave the DirPort off). */ if (ei && !options->BridgeRelay) ei->cache_info.send_unencrypted = 1; router_get_router_hash(ri->cache_info.signed_descriptor_body, strlen(ri->cache_info.signed_descriptor_body), ri->cache_info.signed_descriptor_digest); if (ei) { tor_assert(! routerinfo_incompatible_with_extrainfo(ri, ei, NULL, NULL)); } routerinfo_free(desc_routerinfo); desc_routerinfo = ri; extrainfo_free(desc_extrainfo); desc_extrainfo = ei; desc_clean_since = time(NULL); desc_needs_upload = 1; desc_gen_reason = desc_dirty_reason; desc_dirty_reason = NULL; control_event_my_descriptor_changed(); return 0; } /** If our router descriptor ever goes this long without being regenerated * because something changed, we force an immediate regenerate-and-upload. */ #define FORCE_REGENERATE_DESCRIPTOR_INTERVAL (18*60*60) /** If our router descriptor seems to be missing or unacceptable according * to the authorities, regenerate and reupload it _this_ often. */ #define FAST_RETRY_DESCRIPTOR_INTERVAL (90*60) /** Mark descriptor out of date if it's been "too long" since we last tried * to upload one. */ void mark_my_descriptor_dirty_if_too_old(time_t now) { networkstatus_t *ns; const routerstatus_t *rs; const char *retry_fast_reason = NULL; /* Set if we should retry frequently */ const time_t slow_cutoff = now - FORCE_REGENERATE_DESCRIPTOR_INTERVAL; const time_t fast_cutoff = now - FAST_RETRY_DESCRIPTOR_INTERVAL; /* If it's already dirty, don't mark it. */ if (! desc_clean_since) return; /* If it's older than FORCE_REGENERATE_DESCRIPTOR_INTERVAL, it's always * time to rebuild it. */ if (desc_clean_since < slow_cutoff) { mark_my_descriptor_dirty("time for new descriptor"); return; } /* Now we see whether we want to be retrying frequently or no. The * rule here is that we'll retry frequently if we aren't listed in the * live consensus we have, or if the publication time of the * descriptor listed for us in the consensus is very old. */ ns = networkstatus_get_live_consensus(now); if (ns) { rs = networkstatus_vote_find_entry(ns, server_identitykey_digest); if (rs == NULL) retry_fast_reason = "not listed in consensus"; else if (rs->published_on < slow_cutoff) retry_fast_reason = "version listed in consensus is quite old"; } if (retry_fast_reason && desc_clean_since < fast_cutoff) mark_my_descriptor_dirty(retry_fast_reason); } /** Call when the current descriptor is out of date. */ void mark_my_descriptor_dirty(const char *reason) { desc_clean_since = 0; log_info(LD_OR, "Decided to publish new relay descriptor: %s", reason); if (!desc_dirty_reason) desc_dirty_reason = reason; } /** How frequently will we republish our descriptor because of large (factor * of 2) shifts in estimated bandwidth? */ #define MAX_BANDWIDTH_CHANGE_FREQ (20*60) /** Check whether bandwidth has changed a lot since the last time we announced * bandwidth. If so, mark our descriptor dirty. */ void check_descriptor_bandwidth_changed(time_t now) { static time_t last_changed = 0; uint64_t prev, cur; if (!desc_routerinfo) return; prev = desc_routerinfo->bandwidthcapacity; cur = we_are_hibernating() ? 0 : rep_hist_bandwidth_assess(); if ((prev != cur && (!prev || !cur)) || cur > prev*2 || cur < prev/2) { if (last_changed+MAX_BANDWIDTH_CHANGE_FREQ < now) { log_info(LD_GENERAL, "Measured bandwidth has changed; rebuilding descriptor."); mark_my_descriptor_dirty("bandwidth has changed"); last_changed = now; } } } /** Note at log level severity that our best guess of address has changed from * prev to cur. */ static void log_addr_has_changed(int severity, uint32_t prev, uint32_t cur, const char *source) { char addrbuf_prev[INET_NTOA_BUF_LEN]; char addrbuf_cur[INET_NTOA_BUF_LEN]; struct in_addr in_prev; struct in_addr in_cur; in_prev.s_addr = htonl(prev); tor_inet_ntoa(&in_prev, addrbuf_prev, sizeof(addrbuf_prev)); in_cur.s_addr = htonl(cur); tor_inet_ntoa(&in_cur, addrbuf_cur, sizeof(addrbuf_cur)); if (prev) log_fn(severity, LD_GENERAL, "Our IP Address has changed from %s to %s; " "rebuilding descriptor (source: %s).", addrbuf_prev, addrbuf_cur, source); else log_notice(LD_GENERAL, "Guessed our IP address as %s (source: %s).", addrbuf_cur, source); } /** Check whether our own address as defined by the Address configuration * has changed. This is for routers that get their address from a service * like dyndns. If our address has changed, mark our descriptor dirty. */ void check_descriptor_ipaddress_changed(time_t now) { uint32_t prev, cur; const or_options_t *options = get_options(); (void) now; if (!desc_routerinfo) return; prev = desc_routerinfo->addr; if (resolve_my_address(LOG_INFO, options, &cur, NULL) < 0) { log_info(LD_CONFIG,"options->Address didn't resolve into an IP."); return; } if (prev != cur) { log_addr_has_changed(LOG_NOTICE, prev, cur, "resolve"); ip_address_changed(0); } } /** The most recently guessed value of our IP address, based on directory * headers. */ static uint32_t last_guessed_ip = 0; /** A directory server d_conn told us our IP address is * suggestion. * If this address is different from the one we think we are now, and * if our computer doesn't actually know its IP address, then switch. */ void router_new_address_suggestion(const char *suggestion, const dir_connection_t *d_conn) { uint32_t addr, cur = 0; struct in_addr in; const or_options_t *options = get_options(); /* first, learn what the IP address actually is */ if (!tor_inet_aton(suggestion, &in)) { log_debug(LD_DIR, "Malformed X-Your-Address-Is header %s. Ignoring.", escaped(suggestion)); return; } addr = ntohl(in.s_addr); log_debug(LD_DIR, "Got X-Your-Address-Is: %s.", suggestion); if (!server_mode(options)) { last_guessed_ip = addr; /* store it in case we need it later */ return; } if (resolve_my_address(LOG_INFO, options, &cur, NULL) >= 0) { /* We're all set -- we already know our address. Great. */ last_guessed_ip = cur; /* store it in case we need it later */ return; } if (is_internal_IP(addr, 0)) { /* Don't believe anybody who says our IP is, say, 127.0.0.1. */ return; } if (tor_addr_eq_ipv4h(&d_conn->_base.addr, addr)) { /* Don't believe anybody who says our IP is their IP. */ log_debug(LD_DIR, "A directory server told us our IP address is %s, " "but he's just reporting his own IP address. Ignoring.", suggestion); return; } /* Okay. We can't resolve our own address, and X-Your-Address-Is is giving * us an answer different from what we had the last time we managed to * resolve it. */ if (last_guessed_ip != addr) { control_event_server_status(LOG_NOTICE, "EXTERNAL_ADDRESS ADDRESS=%s METHOD=DIRSERV", suggestion); log_addr_has_changed(LOG_NOTICE, last_guessed_ip, addr, d_conn->_base.address); ip_address_changed(0); last_guessed_ip = addr; /* router_rebuild_descriptor() will fetch it */ } } /** We failed to resolve our address locally, but we'd like to build * a descriptor and publish / test reachability. If we have a guess * about our address based on directory headers, answer it and return * 0; else return -1. */ static int router_guess_address_from_dir_headers(uint32_t *guess) { if (last_guessed_ip) { *guess = last_guessed_ip; return 0; } return -1; } /** Set platform (max length len) to a NUL-terminated short * string describing the version of Tor and the operating system we're * currently running on. */ void get_platform_str(char *platform, size_t len) { tor_snprintf(platform, len, "Tor %s on %s", get_version(), get_uname()); } /* XXX need to audit this thing and count fenceposts. maybe * refactor so we don't have to keep asking if we're * near the end of maxlen? */ #define DEBUG_ROUTER_DUMP_ROUTER_TO_STRING /** OR only: Given a routerinfo for this router, and an identity key to sign * with, encode the routerinfo as a signed server descriptor and write the * result into s, using at most maxlen bytes. Return -1 on * failure, and the number of bytes used on success. */ int router_dump_router_to_string(char *s, size_t maxlen, routerinfo_t *router, crypto_pk_env_t *ident_key) { char *onion_pkey; /* Onion key, PEM-encoded. */ char *identity_pkey; /* Identity key, PEM-encoded. */ char digest[DIGEST_LEN]; char published[ISO_TIME_LEN+1]; char fingerprint[FINGERPRINT_LEN+1]; int has_extra_info_digest; char extra_info_digest[HEX_DIGEST_LEN+1]; size_t onion_pkeylen, identity_pkeylen; size_t written; int result=0; addr_policy_t *tmpe; char *family_line; const or_options_t *options = get_options(); /* Make sure the identity key matches the one in the routerinfo. */ if (crypto_pk_cmp_keys(ident_key, router->identity_pkey)) { log_warn(LD_BUG,"Tried to sign a router with a private key that didn't " "match router's public key!"); return -1; } /* record our fingerprint, so we can include it in the descriptor */ if (crypto_pk_get_fingerprint(router->identity_pkey, fingerprint, 1)<0) { log_err(LD_BUG,"Error computing fingerprint"); return -1; } /* PEM-encode the onion key */ if (crypto_pk_write_public_key_to_string(router->onion_pkey, &onion_pkey,&onion_pkeylen)<0) { log_warn(LD_BUG,"write onion_pkey to string failed!"); return -1; } /* PEM-encode the identity key */ if (crypto_pk_write_public_key_to_string(router->identity_pkey, &identity_pkey,&identity_pkeylen)<0) { log_warn(LD_BUG,"write identity_pkey to string failed!"); tor_free(onion_pkey); return -1; } /* Encode the publication time. */ format_iso_time(published, router->cache_info.published_on); if (router->declared_family && smartlist_len(router->declared_family)) { size_t n; char *family = smartlist_join_strings(router->declared_family, " ", 0, &n); n += strlen("family ") + 2; /* 1 for \n, 1 for \0. */ family_line = tor_malloc(n); tor_snprintf(family_line, n, "family %s\n", family); tor_free(family); } else { family_line = tor_strdup(""); } has_extra_info_digest = ! tor_digest_is_zero(router->cache_info.extra_info_digest); if (has_extra_info_digest) { base16_encode(extra_info_digest, sizeof(extra_info_digest), router->cache_info.extra_info_digest, DIGEST_LEN); } /* Generate the easy portion of the router descriptor. */ result = tor_snprintf(s, maxlen, "router %s %s %d 0 %d\n" "platform %s\n" "opt protocols Link 1 2 Circuit 1\n" "published %s\n" "opt fingerprint %s\n" "uptime %ld\n" "bandwidth %d %d %d\n" "%s%s%s%s" "onion-key\n%s" "signing-key\n%s" "%s%s%s%s", router->nickname, router->address, router->or_port, decide_to_advertise_dirport(options, router->dir_port), router->platform, published, fingerprint, stats_n_seconds_working, (int) router->bandwidthrate, (int) router->bandwidthburst, (int) router->bandwidthcapacity, has_extra_info_digest ? "opt extra-info-digest " : "", has_extra_info_digest ? extra_info_digest : "", has_extra_info_digest ? "\n" : "", options->DownloadExtraInfo ? "opt caches-extra-info\n" : "", onion_pkey, identity_pkey, family_line, we_are_hibernating() ? "opt hibernating 1\n" : "", options->HidServDirectoryV2 ? "opt hidden-service-dir\n" : "", options->AllowSingleHopExits ? "opt allow-single-hop-exits\n" : ""); tor_free(family_line); tor_free(onion_pkey); tor_free(identity_pkey); if (result < 0) { log_warn(LD_BUG,"descriptor snprintf #1 ran out of room!"); return -1; } /* From now on, we use 'written' to remember the current length of 's'. */ written = result; if (options->ContactInfo && strlen(options->ContactInfo)) { const char *ci = options->ContactInfo; if (strchr(ci, '\n') || strchr(ci, '\r')) ci = escaped(ci); result = tor_snprintf(s+written,maxlen-written, "contact %s\n", ci); if (result<0) { log_warn(LD_BUG,"descriptor snprintf #2 ran out of room!"); return -1; } written += result; } /* Write the exit policy to the end of 's'. */ if (!router->exit_policy || !smartlist_len(router->exit_policy)) { strlcat(s+written, "reject *:*\n", maxlen-written); written += strlen("reject *:*\n"); tmpe = NULL; } else if (router->exit_policy) { int i; for (i = 0; i < smartlist_len(router->exit_policy); ++i) { tmpe = smartlist_get(router->exit_policy, i); result = policy_write_item(s+written, maxlen-written, tmpe, 1); if (result < 0) { log_warn(LD_BUG,"descriptor policy_write_item ran out of room!"); return -1; } tor_assert(result == (int)strlen(s+written)); written += result; if (written+2 > maxlen) { log_warn(LD_BUG,"descriptor policy_write_item ran out of room (2)!"); return -1; } s[written++] = '\n'; } } if (written + DIROBJ_MAX_SIG_LEN > maxlen) { /* Not enough room for signature. */ log_warn(LD_BUG,"not enough room left in descriptor for signature!"); return -1; } /* Sign the descriptor */ strlcpy(s+written, "router-signature\n", maxlen-written); written += strlen(s+written); s[written] = '\0'; if (router_get_router_hash(s, strlen(s), digest) < 0) { return -1; } note_crypto_pk_op(SIGN_RTR); if (router_append_dirobj_signature(s+written,maxlen-written, digest,DIGEST_LEN,ident_key)<0) { log_warn(LD_BUG, "Couldn't sign router descriptor"); return -1; } written += strlen(s+written); if (written+2 > maxlen) { log_warn(LD_BUG,"Not enough room to finish descriptor."); return -1; } /* include a last '\n' */ s[written] = '\n'; s[written+1] = 0; #ifdef DEBUG_ROUTER_DUMP_ROUTER_TO_STRING { char *s_dup; const char *cp; routerinfo_t *ri_tmp; cp = s_dup = tor_strdup(s); ri_tmp = router_parse_entry_from_string(cp, NULL, 1, 0, NULL); if (!ri_tmp) { log_err(LD_BUG, "We just generated a router descriptor we can't parse."); log_err(LD_BUG, "Descriptor was: <<%s>>", s); return -1; } tor_free(s_dup); routerinfo_free(ri_tmp); } #endif return (int)written+1; } /** Load the contents of filename, find the last line starting with * end_line, ensure that its timestamp is not more than 25 hours in * the past or more than 1 hour in the future with respect to now, * and write the file contents starting with that line to *out. * Return 1 for success, 0 if the file does not exist, or -1 if the file * does not contain a line matching these criteria or other failure. */ static int load_stats_file(const char *filename, const char *end_line, time_t now, char **out) { int r = -1; char *fname = get_datadir_fname(filename); char *contents, *start = NULL, *tmp, timestr[ISO_TIME_LEN+1]; time_t written; switch (file_status(fname)) { case FN_FILE: /* X022 Find an alternative to reading the whole file to memory. */ if ((contents = read_file_to_str(fname, 0, NULL))) { tmp = strstr(contents, end_line); /* Find last block starting with end_line */ while (tmp) { start = tmp; tmp = strstr(tmp + 1, end_line); } if (!start) goto notfound; if (strlen(start) < strlen(end_line) + 1 + sizeof(timestr)) goto notfound; strlcpy(timestr, start + 1 + strlen(end_line), sizeof(timestr)); if (parse_iso_time(timestr, &written) < 0) goto notfound; if (written < now - (25*60*60) || written > now + (1*60*60)) goto notfound; *out = tor_strdup(start); r = 1; } notfound: tor_free(contents); break; case FN_NOENT: r = 0; break; case FN_ERROR: case FN_DIR: default: break; } tor_free(fname); return r; } /** Write the contents of extrainfo and aggregated statistics to * *s_out, signing them with ident_key. Return 0 on * success, negative on failure. */ int extrainfo_dump_to_string(char **s_out, extrainfo_t *extrainfo, crypto_pk_env_t *ident_key) { const or_options_t *options = get_options(); char identity[HEX_DIGEST_LEN+1]; char published[ISO_TIME_LEN+1]; char digest[DIGEST_LEN]; char *bandwidth_usage; int result; static int write_stats_to_extrainfo = 1; char sig[DIROBJ_MAX_SIG_LEN+1]; char *s, *pre, *contents, *cp, *s_dup = NULL; time_t now = time(NULL); smartlist_t *chunks = smartlist_create(); extrainfo_t *ei_tmp = NULL; base16_encode(identity, sizeof(identity), extrainfo->cache_info.identity_digest, DIGEST_LEN); format_iso_time(published, extrainfo->cache_info.published_on); bandwidth_usage = rep_hist_get_bandwidth_lines(); tor_asprintf(&pre, "extra-info %s %s\npublished %s\n%s", extrainfo->nickname, identity, published, bandwidth_usage); tor_free(bandwidth_usage); smartlist_add(chunks, pre); if (geoip_is_loaded()) { char *chunk=NULL; tor_asprintf(&chunk, "geoip-db-digest %s\n", geoip_db_digest()); smartlist_add(chunks, chunk); } if (options->ExtraInfoStatistics && write_stats_to_extrainfo) { log_info(LD_GENERAL, "Adding stats to extra-info descriptor."); if (options->DirReqStatistics && load_stats_file("stats"PATH_SEPARATOR"dirreq-stats", "dirreq-stats-end", now, &contents) > 0) { smartlist_add(chunks, contents); } if (options->EntryStatistics && load_stats_file("stats"PATH_SEPARATOR"entry-stats", "entry-stats-end", now, &contents) > 0) { smartlist_add(chunks, contents); } if (options->CellStatistics && load_stats_file("stats"PATH_SEPARATOR"buffer-stats", "cell-stats-end", now, &contents) > 0) { smartlist_add(chunks, contents); } if (options->ExitPortStatistics && load_stats_file("stats"PATH_SEPARATOR"exit-stats", "exit-stats-end", now, &contents) > 0) { smartlist_add(chunks, contents); } if (options->ConnDirectionStatistics && load_stats_file("stats"PATH_SEPARATOR"conn-stats", "conn-bi-direct", now, &contents) > 0) { smartlist_add(chunks, contents); } } if (should_record_bridge_info(options) && write_stats_to_extrainfo) { const char *bridge_stats = geoip_get_bridge_stats_extrainfo(now); if (bridge_stats) { smartlist_add(chunks, tor_strdup(bridge_stats)); } } smartlist_add(chunks, tor_strdup("router-signature\n")); s = smartlist_join_strings(chunks, "", 0, NULL); while (strlen(s) > MAX_EXTRAINFO_UPLOAD_SIZE - DIROBJ_MAX_SIG_LEN) { /* So long as there are at least two chunks (one for the initial * extra-info line and one for the router-signature), we can keep removing * things. */ if (smartlist_len(chunks) > 2) { /* We remove the next-to-last element (remember, len-1 is the last element), since we need to keep the router-signature element. */ int idx = smartlist_len(chunks) - 2; char *e = smartlist_get(chunks, idx); smartlist_del_keeporder(chunks, idx); log_warn(LD_GENERAL, "We just generated an extra-info descriptor " "with statistics that exceeds the 50 KB " "upload limit. Removing last added " "statistics."); tor_free(e); tor_free(s); s = smartlist_join_strings(chunks, "", 0, NULL); } else { log_warn(LD_BUG, "We just generated an extra-info descriptors that " "exceeds the 50 KB upload limit."); goto err; } } memset(sig, 0, sizeof(sig)); if (router_get_extrainfo_hash(s, digest) < 0 || router_append_dirobj_signature(sig, sizeof(sig), digest, DIGEST_LEN, ident_key) < 0) { log_warn(LD_BUG, "Could not append signature to extra-info " "descriptor."); goto err; } smartlist_add(chunks, tor_strdup(sig)); tor_free(s); s = smartlist_join_strings(chunks, "", 0, NULL); cp = s_dup = tor_strdup(s); ei_tmp = extrainfo_parse_entry_from_string(cp, NULL, 1, NULL); if (!ei_tmp) { if (write_stats_to_extrainfo) { log_warn(LD_GENERAL, "We just generated an extra-info descriptor " "with statistics that we can't parse. Not " "adding statistics to this or any future " "extra-info descriptors."); write_stats_to_extrainfo = 0; result = extrainfo_dump_to_string(s_out, extrainfo, ident_key); goto done; } else { log_warn(LD_BUG, "We just generated an extrainfo descriptor we " "can't parse."); goto err; } } *s_out = s; s = NULL; /* prevent free */ result = 0; goto done; err: result = -1; done: tor_free(s); SMARTLIST_FOREACH(chunks, char *, cp, tor_free(cp)); smartlist_free(chunks); tor_free(s_dup); extrainfo_free(ei_tmp); return result; } /** Return true iff s is a legally valid server nickname. */ int is_legal_nickname(const char *s) { size_t len; tor_assert(s); len = strlen(s); return len > 0 && len <= MAX_NICKNAME_LEN && strspn(s,LEGAL_NICKNAME_CHARACTERS) == len; } /** Return true iff s is a legally valid server nickname or * hex-encoded identity-key digest. */ int is_legal_nickname_or_hexdigest(const char *s) { if (*s!='$') return is_legal_nickname(s); else return is_legal_hexdigest(s); } /** Return true iff s is a legally valid hex-encoded identity-key * digest. */ int is_legal_hexdigest(const char *s) { size_t len; tor_assert(s); if (s[0] == '$') s++; len = strlen(s); if (len > HEX_DIGEST_LEN) { if (s[HEX_DIGEST_LEN] == '=' || s[HEX_DIGEST_LEN] == '~') { if (!is_legal_nickname(s+HEX_DIGEST_LEN+1)) return 0; } else { return 0; } } return (len >= HEX_DIGEST_LEN && strspn(s,HEX_CHARACTERS)==HEX_DIGEST_LEN); } /** Use buf (which must be at least NODE_DESC_BUF_LEN bytes long) to * hold a human-readable description of a node with identity digest * id_digest, named-status is_named, nickname nickname, * and address addr or addr32h. * * The nickname and addr fields are optional and may be set to * NULL. The addr32h field is optional and may be set to 0. * * Return a pointer to the front of buf. */ const char * format_node_description(char *buf, const char *id_digest, int is_named, const char *nickname, const tor_addr_t *addr, uint32_t addr32h) { char *cp; if (!buf) return ""; buf[0] = '$'; base16_encode(buf+1, HEX_DIGEST_LEN+1, id_digest, DIGEST_LEN); cp = buf+1+HEX_DIGEST_LEN; if (nickname) { buf[1+HEX_DIGEST_LEN] = is_named ? '=' : '~'; strlcpy(buf+1+HEX_DIGEST_LEN+1, nickname, MAX_NICKNAME_LEN+1); cp += strlen(cp); } if (addr32h || addr) { memcpy(cp, " at ", 4); cp += 4; if (addr) { tor_addr_to_str(cp, addr, TOR_ADDR_BUF_LEN, 0); } else { struct in_addr in; in.s_addr = htonl(addr32h); tor_inet_ntoa(&in, cp, INET_NTOA_BUF_LEN); } } return buf; } /** Use buf (which must be at least NODE_DESC_BUF_LEN bytes long) to * hold a human-readable description of ri. * * * Return a pointer to the front of buf. */ const char * router_get_description(char *buf, const routerinfo_t *ri) { if (!ri) return ""; return format_node_description(buf, ri->cache_info.identity_digest, router_is_named(ri), ri->nickname, NULL, ri->addr); } /** Use buf (which must be at least NODE_DESC_BUF_LEN bytes long) to * hold a human-readable description of node. * * Return a pointer to the front of buf. */ const char * node_get_description(char *buf, const node_t *node) { const char *nickname = NULL; uint32_t addr32h = 0; int is_named = 0; if (!node) return ""; if (node->rs) { nickname = node->rs->nickname; is_named = node->rs->is_named; addr32h = node->rs->addr; } else if (node->ri) { nickname = node->ri->nickname; addr32h = node->ri->addr; } return format_node_description(buf, node->identity, is_named, nickname, NULL, addr32h); } /** Use buf (which must be at least NODE_DESC_BUF_LEN bytes long) to * hold a human-readable description of rs. * * Return a pointer to the front of buf. */ const char * routerstatus_get_description(char *buf, const routerstatus_t *rs) { if (!rs) return ""; return format_node_description(buf, rs->identity_digest, rs->is_named, rs->nickname, NULL, rs->addr); } /** Use buf (which must be at least NODE_DESC_BUF_LEN bytes long) to * hold a human-readable description of ei. * * Return a pointer to the front of buf. */ const char * extend_info_get_description(char *buf, const extend_info_t *ei) { if (!ei) return ""; return format_node_description(buf, ei->identity_digest, 0, ei->nickname, &ei->addr, 0); } /** Return a human-readable description of the routerinfo_t ri. * * This function is not thread-safe. Each call to this function invalidates * previous values returned by this function. */ const char * router_describe(const routerinfo_t *ri) { static char buf[NODE_DESC_BUF_LEN]; return router_get_description(buf, ri); } /** Return a human-readable description of the node_t node. * * This function is not thread-safe. Each call to this function invalidates * previous values returned by this function. */ const char * node_describe(const node_t *node) { static char buf[NODE_DESC_BUF_LEN]; return node_get_description(buf, node); } /** Return a human-readable description of the routerstatus_t rs. * * This function is not thread-safe. Each call to this function invalidates * previous values returned by this function. */ const char * routerstatus_describe(const routerstatus_t *rs) { static char buf[NODE_DESC_BUF_LEN]; return routerstatus_get_description(buf, rs); } /** Return a human-readable description of the extend_info_t ri. * * This function is not thread-safe. Each call to this function invalidates * previous values returned by this function. */ const char * extend_info_describe(const extend_info_t *ei) { static char buf[NODE_DESC_BUF_LEN]; return extend_info_get_description(buf, ei); } /** Set buf (which must have MAX_VERBOSE_NICKNAME_LEN+1 bytes) to the * verbose representation of the identity of router. The format is: * A dollar sign. * The upper-case hexadecimal encoding of the SHA1 hash of router's identity. * A "=" if the router is named; a "~" if it is not. * The router's nickname. **/ void router_get_verbose_nickname(char *buf, const routerinfo_t *router) { const char *good_digest = networkstatus_get_router_digest_by_nickname( router->nickname); int is_named = good_digest && tor_memeq(good_digest, router->cache_info.identity_digest, DIGEST_LEN); buf[0] = '$'; base16_encode(buf+1, HEX_DIGEST_LEN+1, router->cache_info.identity_digest, DIGEST_LEN); buf[1+HEX_DIGEST_LEN] = is_named ? '=' : '~'; strlcpy(buf+1+HEX_DIGEST_LEN+1, router->nickname, MAX_NICKNAME_LEN+1); } /** Set buf (which must have MAX_VERBOSE_NICKNAME_LEN+1 bytes) to the * verbose representation of the identity of router. The format is: * A dollar sign. * The upper-case hexadecimal encoding of the SHA1 hash of router's identity. * A "=" if the router is named; a "~" if it is not. * The router's nickname. **/ void routerstatus_get_verbose_nickname(char *buf, const routerstatus_t *router) { buf[0] = '$'; base16_encode(buf+1, HEX_DIGEST_LEN+1, router->identity_digest, DIGEST_LEN); buf[1+HEX_DIGEST_LEN] = router->is_named ? '=' : '~'; strlcpy(buf+1+HEX_DIGEST_LEN+1, router->nickname, MAX_NICKNAME_LEN+1); } /** Forget that we have issued any router-related warnings, so that we'll * warn again if we see the same errors. */ void router_reset_warnings(void) { if (warned_nonexistent_family) { SMARTLIST_FOREACH(warned_nonexistent_family, char *, cp, tor_free(cp)); smartlist_clear(warned_nonexistent_family); } } /** Given a router purpose, convert it to a string. Don't call this on * ROUTER_PURPOSE_UNKNOWN: The whole point of that value is that we don't * know its string representation. */ const char * router_purpose_to_string(uint8_t p) { switch (p) { case ROUTER_PURPOSE_GENERAL: return "general"; case ROUTER_PURPOSE_BRIDGE: return "bridge"; case ROUTER_PURPOSE_CONTROLLER: return "controller"; default: tor_assert(0); } return NULL; } /** Given a string, convert it to a router purpose. */ uint8_t router_purpose_from_string(const char *s) { if (!strcmp(s, "general")) return ROUTER_PURPOSE_GENERAL; else if (!strcmp(s, "bridge")) return ROUTER_PURPOSE_BRIDGE; else if (!strcmp(s, "controller")) return ROUTER_PURPOSE_CONTROLLER; else return ROUTER_PURPOSE_UNKNOWN; } /** Release all static resources held in router.c */ void router_free_all(void) { crypto_free_pk_env(onionkey); crypto_free_pk_env(lastonionkey); crypto_free_pk_env(server_identitykey); crypto_free_pk_env(client_identitykey); tor_mutex_free(key_lock); routerinfo_free(desc_routerinfo); extrainfo_free(desc_extrainfo); crypto_free_pk_env(authority_signing_key); authority_cert_free(authority_key_certificate); crypto_free_pk_env(legacy_signing_key); authority_cert_free(legacy_key_certificate); if (warned_nonexistent_family) { SMARTLIST_FOREACH(warned_nonexistent_family, char *, cp, tor_free(cp)); smartlist_free(warned_nonexistent_family); } }