args[i])); goto err; } } } else if (tok) { int i; for (i=0; i < tok->n_args; ++i) { if (!strcmp(tok->args[i], "Exit")) rs->is_exit = 1; else if (!strcmp(tok->args[i], "Stable")) rs->is_stable = 1; else if (!strcmp(tok->args[i], "Fast")) rs->is_fast = 1; else if (!strcmp(tok->args[i], "Running")) rs->is_running = 1; else if (!strcmp(tok->args[i], "Named")) rs->is_named = 1; else if (!strcmp(tok->args[i], "Valid")) rs->is_valid = 1; else if (!strcmp(tok->args[i], "V2Dir")) rs->is_v2_dir = 1; else if (!strcmp(tok->args[i], "Guard")) rs->is_possible_guard = 1; else if (!strcmp(tok->args[i], "BadExit")) rs->is_bad_exit = 1; else if (!strcmp(tok->args[i], "BadDirectory")) rs->is_bad_directory = 1; else if (!strcmp(tok->args[i], "Authority")) rs->is_authority = 1; else if (!strcmp(tok->args[i], "Unnamed") && consensus_method >= 2) { /* Unnamed is computed right by consensus method 2 and later. */ rs->is_unnamed = 1; } else if (!strcmp(tok->args[i], "HSDir")) { rs->is_hs_dir = 1; } } } if ((tok = find_opt_by_keyword(tokens, K_V))) { tor_assert(tok->n_args == 1); rs->version_known = 1; if (strcmpstart(tok->args[0], "Tor ")) { rs->version_supports_begindir = 1; rs->version_supports_extrainfo_upload = 1; rs->version_supports_conditional_consensus = 1; } else { rs->version_supports_begindir = tor_version_as_new_as(tok->args[0], "0.2.0.1-alpha"); rs->version_supports_extrainfo_upload = tor_version_as_new_as(tok->args[0], "0.2.0.0-alpha-dev (r10070)"); rs->version_supports_v3_dir = tor_version_as_new_as(tok->args[0], "0.2.0.8-alpha"); rs->version_supports_conditional_consensus = tor_version_as_new_as(tok->args[0], "0.2.1.1-alpha"); } if (vote_rs) { vote_rs->version = tor_strdup(tok->args[0]); } } /* handle weighting/bandwidth info */ if ((tok = find_opt_by_keyword(tokens, K_W))) { int i; for (i=0; i < tok->n_args; ++i) { if (!strcmpstart(tok->args[i], "Bandwidth=")) { int ok; rs->bandwidth = tor_parse_ulong(strchr(tok->args[i], '=')+1, 10, 0, UINT32_MAX, &ok, NULL); if (!ok) { log_warn(LD_DIR, "Invalid Bandwidth %s", escaped(tok->args[i])); goto err; } rs->has_bandwidth = 1; } } } /* parse exit policy summaries */ if ((tok = find_opt_by_keyword(tokens, K_P))) { tor_assert(tok->n_args == 1); if (strcmpstart(tok->args[0], "accept ") && strcmpstart(tok->args[0], "reject ")) { log_err(LD_DIR, "Unknown exit policy summary type %s.", escaped(tok->args[0])); goto err; } /* XXX weasel: parse this into ports and represent them somehow smart, * maybe not here but somewhere on if we need it for the client. * we should still parse it here to check it's valid tho. */ rs->exitsummary = tor_strdup(tok->args[0]); rs->has_exitsummary = 1; } if (!strcasecmp(rs->nickname, UNNAMED_ROUTER_NICKNAME)) rs->is_named = 0; goto done; err: if (rs && !vote_rs) routerstatus_free(rs); rs = NULL; done: SMARTLIST_FOREACH(tokens, directory_token_t *, t, token_free(t)); smartlist_clear(tokens); if (area) { DUMP_AREA(area, "routerstatus entry"); memarea_clear(area); } *s = eos; return rs; } /** Helper to sort a smartlist of pointers to routerstatus_t */ static int _compare_routerstatus_entries(const void **_a, const void **_b) { const routerstatus_t *a = *_a, *b = *_b; return memcmp(a->identity_digest, b->identity_digest, DIGEST_LEN); } /** Helper: used in call to _smartlist_uniq to clear out duplicate entries. */ static void _free_duplicate_routerstatus_entry(void *e) { log_warn(LD_DIR, "Network-status has two entries for the same router. " "Dropping one."); routerstatus_free(e); } /** Given a v2 network-status object in s, try to * parse it and return the result. Return NULL on failure. Check the * signature of the network status, but do not (yet) check the signing key for * authority. */ networkstatus_v2_t * networkstatus_v2_parse_from_string(const char *s) { const char *eos; smartlist_t *tokens = smartlist_create(); smartlist_t *footer_tokens = smartlist_create(); networkstatus_v2_t *ns = NULL; char ns_digest[DIGEST_LEN]; char tmp_digest[DIGEST_LEN]; struct in_addr in; directory_token_t *tok; int i; memarea_t *area = NULL; if (router_get_networkstatus_v2_hash(s, ns_digest)) { log_warn(LD_DIR, "Unable to compute digest of network-status"); goto err; } area = memarea_new(); eos = find_start_of_next_routerstatus(s); if (tokenize_string(area, s, eos, tokens, netstatus_token_table,0)) { log_warn(LD_DIR, "Error tokenizing network-status header."); goto err; } ns = tor_malloc_zero(sizeof(networkstatus_v2_t)); memcpy(ns->networkstatus_digest, ns_digest, DIGEST_LEN); tok = find_by_keyword(tokens, K_NETWORK_STATUS_VERSION); tor_assert(tok->n_args >= 1); if (strcmp(tok->args[0], "2")) { log_warn(LD_BUG, "Got a non-v2 networkstatus. Version was " "%s", escaped(tok->args[0])); goto err; } tok = find_by_keyword(tokens, K_DIR_SOURCE); tor_assert(tok->n_args >= 3); ns->source_address = tor_strdup(tok->args[0]); if (tor_inet_aton(tok->args[1], &in) == 0) { log_warn(LD_DIR, "Error parsing network-status source address %s", escaped(tok->args[1])); goto err; } ns->source_addr = ntohl(in.s_addr); ns->source_dirport = (uint16_t) tor_parse_long(tok->args[2],10,0,65535,NULL,NULL); if (ns->source_dirport == 0) { log_warn(LD_DIR, "Directory source without dirport; skipping."); goto err; } tok = find_by_keyword(tokens, K_FINGERPRINT); tor_assert(tok->n_args); if (base16_decode(ns->identity_digest, DIGEST_LEN, tok->args[0], strlen(tok->args[0]))) { log_warn(LD_DIR, "Couldn't decode networkstatus fingerprint %s", escaped(tok->args[0])); goto err; } if ((tok = find_opt_by_keyword(tokens, K_CONTACT))) { tor_assert(tok->n_args); ns->contact = tor_strdup(tok->args[0]); } tok = find_by_keyword(tokens, K_DIR_SIGNING_KEY); tor_assert(tok->key); ns->signing_key = tok->key; tok->key = NULL; if (crypto_pk_get_digest(ns->signing_key, tmp_digest)<0) { log_warn(LD_DIR, "Couldn't compute signing key digest"); goto err; } if (memcmp(tmp_digest, ns->identity_digest, DIGEST_LEN)) { log_warn(LD_DIR, "network-status fingerprint did not match dir-signing-key"); goto err; } if ((tok = find_opt_by_keyword(tokens, K_DIR_OPTIONS))) { for (i=0; i < tok->n_args; ++i) { if (!strcmp(tok->args[i], "Names")) ns->binds_names = 1; if (!strcmp(tok->args[i], "Versions")) ns->recommends_versions = 1; if (!strcmp(tok->args[i], "BadExits")) ns->lists_bad_exits = 1; if (!strcmp(tok->args[i], "BadDirectories")) ns->lists_bad_directories = 1; } } if (ns->recommends_versions) { if (!(tok = find_opt_by_keyword(tokens, K_CLIENT_VERSIONS))) { log_warn(LD_DIR, "Missing client-versions on versioning directory"); goto err; } ns->client_versions = tor_strdup(tok->args[0]); if (!(tok = find_opt_by_keyword(tokens, K_SERVER_VERSIONS)) || tok->n_args<1) { log_warn(LD_DIR, "Missing server-versions on versioning directory"); goto err; } ns->server_versions = tor_strdup(tok->args[0]); } tok = find_by_keyword(tokens, K_PUBLISHED); tor_assert(tok->n_args == 1); if (parse_iso_time(tok->args[0], &ns->published_on) < 0) { goto err; } ns->entries = smartlist_create(); s = eos; SMARTLIST_FOREACH(tokens, directory_token_t *, t, token_free(t)); smartlist_clear(tokens); memarea_clear(area); while (!strcmpstart(s, "r ")) { routerstatus_t *rs; if ((rs = routerstatus_parse_entry_from_string(area, &s, tokens, NULL, NULL, 0))) smartlist_add(ns->entries, rs); } smartlist_sort(ns->entries, _compare_routerstatus_entries); smartlist_uniq(ns->entries, _compare_routerstatus_entries, _free_duplicate_routerstatus_entry); if (tokenize_string(area,s, NULL, footer_tokens, dir_footer_token_table,0)) { log_warn(LD_DIR, "Error tokenizing network-status footer."); goto err; } if (smartlist_len(footer_tokens) < 1) { log_warn(LD_DIR, "Too few items in network-status footer."); goto err; } tok = smartlist_get(footer_tokens, smartlist_len(footer_tokens)-1); if (tok->tp != K_DIRECTORY_SIGNATURE) { log_warn(LD_DIR, "Expected network-status footer to end with a signature."); goto err; } note_crypto_pk_op(VERIFY_DIR); if (check_signature_token(ns_digest, tok, ns->signing_key, 0, "network-status") < 0) goto err; goto done; err: if (ns) networkstatus_v2_free(ns); ns = NULL; done: SMARTLIST_FOREACH(tokens, directory_token_t *, t, token_free(t)); smartlist_free(tokens); SMARTLIST_FOREACH(footer_tokens, directory_token_t *, t, token_free(t)); smartlist_free(footer_tokens); if (area) { DUMP_AREA(area, "v2 networkstatus"); memarea_drop_all(area); } return ns; } /** Parse a v3 networkstatus vote, opinion, or consensus (depending on * ns_type), from s, and return the result. Return NULL on failure. */ networkstatus_t * networkstatus_parse_vote_from_string(const char *s, const char **eos_out, networkstatus_type_t ns_type) { smartlist_t *tokens = smartlist_create(); smartlist_t *rs_tokens = NULL, *footer_tokens = NULL; networkstatus_voter_info_t *voter = NULL; networkstatus_t *ns = NULL; char ns_digest[DIGEST_LEN]; const char *cert, *end_of_header, *end_of_footer; directory_token_t *tok; int ok; struct in_addr in; int i, inorder, n_signatures = 0; memarea_t *area = NULL, *rs_area = NULL; tor_assert(s); if (router_get_networkstatus_v3_hash(s, ns_digest)) { log_warn(LD_DIR, "Unable to compute digest of network-status"); goto err; } area = memarea_new(); end_of_header = find_start_of_next_routerstatus(s); if (tokenize_string(area, s, end_of_header, tokens, (ns_type == NS_TYPE_CONSENSUS) ? networkstatus_consensus_token_table : networkstatus_token_table, 0)) { log_warn(LD_DIR, "Error tokenizing network-status vote header"); goto err; } ns = tor_malloc_zero(sizeof(networkstatus_t)); memcpy(ns->networkstatus_digest, ns_digest, DIGEST_LEN); if (ns_type != NS_TYPE_CONSENSUS) { const char *end_of_cert = NULL; if (!(cert = strstr(s, "\ndir-key-certificate-version"))) goto err; ++cert; ns->cert = authority_cert_parse_from_string(cert, &end_of_cert); if (!ns->cert || !end_of_cert || end_of_cert > end_of_header) goto err; } tok = find_by_keyword(tokens, K_VOTE_STATUS); tor_assert(tok->n_args); if (!strcmp(tok->args[0], "vote")) { ns->type = NS_TYPE_VOTE; } else if (!strcmp(tok->args[0], "consensus")) { ns->type = NS_TYPE_CONSENSUS; } else if (!strcmp(tok->args[0], "opinion")) { ns->type = NS_TYPE_OPINION; } else { log_warn(LD_DIR, "Unrecognized vote status %s in network-status", escaped(tok->args[0])); goto err; } if (ns_type != ns->type) { log_warn(LD_DIR, "Got the wrong kind of v3 networkstatus."); goto err; } if (ns->type == NS_TYPE_VOTE || ns->type == NS_TYPE_OPINION) { tok = find_by_keyword(tokens, K_PUBLISHED); if (parse_iso_time(tok->args[0], &ns->published)) goto err; ns->supported_methods = smartlist_create(); tok = find_opt_by_keyword(tokens, K_CONSENSUS_METHODS); if (tok) { for (i=0; i < tok->n_args; ++i) smartlist_add(ns->supported_methods, tor_strdup(tok->args[i])); } else { smartlist_add(ns->supported_methods, tor_strdup("1")); } } else { tok = find_opt_by_keyword(tokens, K_CONSENSUS_METHOD); if (tok) { ns->consensus_method = (int)tor_parse_long(tok->args[0], 10, 1, INT_MAX, &ok, NULL); if (!ok) goto err; } else { ns->consensus_method = 1; } } tok = find_by_keyword(tokens, K_VALID_AFTER); if (parse_iso_time(tok->args[0], &ns->valid_after)) goto err; tok = find_by_keyword(tokens, K_FRESH_UNTIL); if (parse_iso_time(tok->args[0], &ns->fresh_until)) goto err; tok = find_by_keyword(tokens, K_VALID_UNTIL); if (parse_iso_time(tok->args[0], &ns->valid_until)) goto err; tok = find_by_keyword(tokens, K_VOTING_DELAY); tor_assert(tok->n_args >= 2); ns->vote_seconds = (int) tor_parse_long(tok->args[0], 10, 0, INT_MAX, &ok, NULL); if (!ok) goto err; ns->dist_seconds = (int) tor_parse_long(tok->args[1], 10, 0, INT_MAX, &ok, NULL); if (!ok) goto err; if (ns->valid_after + MIN_VOTE_INTERVAL > ns->fresh_until) { log_warn(LD_DIR, "Vote/consensus freshness interval is too short"); goto err; } if (ns->valid_after + MIN_VOTE_INTERVAL*2 > ns->valid_until) { log_warn(LD_DIR, "Vote/consensus liveness interval is too short"); goto err; } if (ns->vote_seconds < MIN_VOTE_SECONDS) { log_warn(LD_DIR, "Vote seconds is too short"); goto err; } if (ns->dist_seconds < MIN_DIST_SECONDS) { log_warn(LD_DIR, "Dist seconds is too short"); goto err; } if ((tok = find_opt_by_keyword(tokens, K_CLIENT_VERSIONS))) { ns->client_versions = tor_strdup(tok->args[0]); } if ((tok = find_opt_by_keyword(tokens, K_SERVER_VERSIONS))) { ns->server_versions = tor_strdup(tok->args[0]); } tok = find_by_keyword(tokens, K_KNOWN_FLAGS); ns->known_flags = smartlist_create(); inorder = 1; for (i = 0; i < tok->n_args; ++i) { smartlist_add(ns->known_flags, tor_strdup(tok->args[i])); if (i>0 && strcmp(tok->args[i-1], tok->args[i])>= 0) { log_warn(LD_DIR, "%s >= %s", tok->args[i-1], tok->args[i]); inorder = 0; } } if (!inorder) { log_warn(LD_DIR, "known-flags not in order"); goto err; } ns->voters = smartlist_create(); SMARTLIST_FOREACH(tokens, directory_token_t *, _tok, { tok = _tok; if (tok->tp == K_DIR_SOURCE) { tor_assert(tok->n_args >= 6); if (voter) smartlist_add(ns->voters, voter); voter = tor_malloc_zero(sizeof(networkstatus_voter_info_t)); if (ns->type != NS_TYPE_CONSENSUS) memcpy(voter->vote_digest, ns_digest, DIGEST_LEN); voter->nickname = tor_strdup(tok->args[0]); if (strlen(tok->args[1]) != HEX_DIGEST_LEN || base16_decode(voter->identity_digest, sizeof(voter->identity_digest), tok->args[1], HEX_DIGEST_LEN) < 0) { log_warn(LD_DIR, "Error decoding identity digest %s in " "network-status vote.", escaped(tok->args[1])); goto err; } if (ns->type != NS_TYPE_CONSENSUS && memcmp(ns->cert->cache_info.identity_digest, voter->identity_digest, DIGEST_LEN)) { log_warn(LD_DIR,"Mismatch between identities in certificate and vote"); goto err; } voter->address = tor_strdup(tok->args[2]); if (!tor_inet_aton(tok->args[3], &in)) { log_warn(LD_DIR, "Error decoding IP address %s in network-status.", escaped(tok->args[3])); goto err; } voter->addr = ntohl(in.s_addr); voter->dir_port = (uint16_t) tor_parse_long(tok->args[4], 10, 0, 65535, &ok, NULL); if (!ok) goto err; voter->or_port = (uint16_t) tor_parse_long(tok->args[5], 10, 0, 65535, &ok, NULL); if (!ok) goto err; } else if (tok->tp == K_CONTACT) { if (!voter || voter->contact) { log_warn(LD_DIR, "contact element is out of place."); goto err; } voter->contact = tor_strdup(tok->args[0]); } else if (tok->tp == K_VOTE_DIGEST) { tor_assert(ns->type == NS_TYPE_CONSENSUS); tor_assert(tok->n_args >= 1); if (!voter || ! tor_digest_is_zero(voter->vote_digest)) { log_warn(LD_DIR, "vote-digest element is out of place."); goto err; } if (strlen(tok->args[0]) != HEX_DIGEST_LEN || base16_decode(voter->vote_digest, sizeof(voter->vote_digest), tok->args[0], HEX_DIGEST_LEN) < 0) { log_warn(LD_DIR, "Error decoding vote digest %s in " "network-status consensus.", escaped(tok->args[1])); goto err; } } }); if (voter) { smartlist_add(ns->voters, voter); voter = NULL; } if (smartlist_len(ns->voters) == 0) { log_warn(LD_DIR, "Missing dir-source elements in a vote networkstatus."); goto err; } else if (ns->type != NS_TYPE_CONSENSUS && smartlist_len(ns->voters) != 1) { log_warn(LD_DIR, "Too many dir-source elements in a vote networkstatus."); goto err; } if (ns->type != NS_TYPE_CONSENSUS && (tok = find_opt_by_keyword(tokens, K_LEGACY_DIR_KEY))) { int bad = 1; if (strlen(tok->args[0]) == HEX_DIGEST_LEN) { networkstatus_voter_info_t *voter = smartlist_get(ns->voters, 0); if (base16_decode(voter->legacy_id_digest, DIGEST_LEN, tok->args[0], HEX_DIGEST_LEN)<0) bad = 1; else bad = 0; } if (bad) { log_warn(LD_DIR, "Invalid legacy key digest %s on vote.", escaped(tok->args[0])); } } /* Parse routerstatus lines. */ rs_tokens = smartlist_create(); rs_area = memarea_new(); s = end_of_header; ns->routerstatus_list = smartlist_create(); while (!strcmpstart(s, "r ")) { if (ns->type != NS_TYPE_CONSENSUS) { vote_routerstatus_t *rs = tor_malloc_zero(sizeof(vote_routerstatus_t)); if (routerstatus_parse_entry_from_string(rs_area, &s, rs_tokens, ns, rs, 0)) smartlist_add(ns->routerstatus_list, rs); else { tor_free(rs->version); tor_free(rs); } } else { routerstatus_t *rs; if ((rs = routerstatus_parse_entry_from_string(rs_area, &s, rs_tokens, NULL, NULL, ns->consensus_method))) smartlist_add(ns->routerstatus_list, rs); } } for (i = 1; i < smartlist_len(ns->routerstatus_list); ++i) { routerstatus_t *rs1, *rs2; if (ns->type != NS_TYPE_CONSENSUS) { vote_routerstatus_t *a = smartlist_get(ns->routerstatus_list, i-1); vote_routerstatus_t *b = smartlist_get(ns->routerstatus_list, i); rs1 = &a->status; rs2 = &b->status; } else { rs1 = smartlist_get(ns->routerstatus_list, i-1); rs2 = smartlist_get(ns->routerstatus_list, i); } if (memcmp(rs1->identity_digest, rs2->identity_digest, DIGEST_LEN) >= 0) { log_warn(LD_DIR, "Vote networkstatus entries not sorted by identity " "digest"); goto err; } } /* Parse footer; check signature. */ footer_tokens = smartlist_create(); if ((end_of_footer = strstr(s, "\nnetwork-status-version "))) ++end_of_footer; else end_of_footer = s + strlen(s); if (tokenize_string(area,s, end_of_footer, footer_tokens, networkstatus_vote_footer_token_table, 0)) { log_warn(LD_DIR, "Error tokenizing network-status vote footer."); goto err; } SMARTLIST_FOREACH(footer_tokens, directory_token_t *, _tok, { char declared_identity[DIGEST_LEN]; networkstatus_voter_info_t *v; tok = _tok; if (tok->tp != K_DIRECTORY_SIGNATURE) continue; tor_assert(tok->n_args >= 2); if (!tok->object_type || strcmp(tok->object_type, "SIGNATURE") || tok->object_size < 128 || tok->object_size > 512) { log_warn(LD_DIR, "Bad object type or length on directory-signature"); goto err; } if (strlen(tok->args[0]) != HEX_DIGEST_LEN || base16_decode(declared_identity, sizeof(declared_identity), tok->args[0], HEX_DIGEST_LEN) < 0) { log_warn(LD_DIR, "Error decoding declared identity %s in " "network-status vote.", escaped(tok->args[0])); goto err; } if (!(v = networkstatus_get_voter_by_id(ns, declared_identity))) { log_warn(LD_DIR, "ID on signature on network-status vote does not match " "any declared directory source."); goto err; } if (strlen(tok->args[1]) != HEX_DIGEST_LEN || base16_decode(v->signing_key_digest, sizeof(v->signing_key_digest), tok->args[1], HEX_DIGEST_LEN) < 0) { log_warn(LD_DIR, "Error decoding declared digest %s in " "network-status vote.", escaped(tok->args[1])); goto err; } if (ns->type != NS_TYPE_CONSENSUS) { if (memcmp(declared_identity, ns->cert->cache_info.identity_digest, DIGEST_LEN)) { log_warn(LD_DIR, "Digest mismatch between declared and actual on " "network-status vote."); goto err; } } if (ns->type != NS_TYPE_CONSENSUS) { if (check_signature_token(ns_digest, tok, ns->cert->signing_key, 0, "network-status vote")) goto err; v->good_signature = 1; } else { if (tok->object_size >= INT_MAX) goto err; v->signature = tor_memdup(tok->object_body, tok->object_size); v->signature_len = (int) tok->object_size; } ++n_signatures; }); if (! n_signatures) { log_warn(LD_DIR, "No signatures on networkstatus vote."); goto err; } if (eos_out) *eos_out = end_of_footer; goto done; err: if (ns) networkstatus_vote_free(ns); ns = NULL; done: if (tokens) { SMARTLIST_FOREACH(tokens, directory_token_t *, t, token_free(t)); smartlist_free(tokens); } if (voter) { tor_free(voter->nickname); tor_free(voter->address); tor_free(voter->contact); tor_free(voter->signature); tor_free(voter); } if (rs_tokens) { SMARTLIST_FOREACH(rs_tokens, directory_token_t *, t, token_free(t)); smartlist_free(rs_tokens); } if (footer_tokens) { SMARTLIST_FOREACH(footer_tokens, directory_token_t *, t, token_free(t)); smartlist_free(footer_tokens); } if (area) { DUMP_AREA(area, "v3 networkstatus"); memarea_drop_all(area); } if (rs_area) memarea_drop_all(rs_area); return ns; } /** Parse a detached v3 networkstatus signature document between s and * eos and return the result. Return -1 on failure. */ ns_detached_signatures_t * networkstatus_parse_detached_signatures(const char *s, const char *eos) { /* XXXX021 there is too much duplicate code here. */ directory_token_t *tok; memarea_t *area = NULL; smartlist_t *tokens = smartlist_create(); ns_detached_signatures_t *sigs = tor_malloc_zero(sizeof(ns_detached_signatures_t)); if (!eos) eos = s + strlen(s); area = memarea_new(); if (tokenize_string(area,s, eos, tokens, networkstatus_detached_signature_token_table, 0)) { log_warn(LD_DIR, "Error tokenizing detached networkstatus signatures"); goto err; } tok = find_by_keyword(tokens, K_CONSENSUS_DIGEST); if (strlen(tok->args[0]) != HEX_DIGEST_LEN) { log_warn(LD_DIR, "Wrong length on consensus-digest in detached " "networkstatus signatures"); goto err; } if (base16_decode(sigs->networkstatus_digest, DIGEST_LEN, tok->args[0], strlen(tok->args[0])) < 0) { log_warn(LD_DIR, "Bad encoding on on consensus-digest in detached " "networkstatus signatures"); goto err; } tok = find_by_keyword(tokens, K_VALID_AFTER); if (parse_iso_time(tok->args[0], &sigs->valid_after)) { log_warn(LD_DIR, "Bad valid-after in detached networkstatus signatures"); goto err; } tok = find_by_keyword(tokens, K_FRESH_UNTIL); if (parse_iso_time(tok->args[0], &sigs->fresh_until)) { log_warn(LD_DIR, "Bad fresh-until in detached networkstatus signatures"); goto err; } tok = find_by_keyword(tokens, K_VALID_UNTIL); if (parse_iso_time(tok->args[0], &sigs->valid_until)) { log_warn(LD_DIR, "Bad valid-until in detached networkstatus signatures"); goto err; } sigs->signatures = smartlist_create(); SMARTLIST_FOREACH(tokens, directory_token_t *, _tok, { char id_digest[DIGEST_LEN]; char sk_digest[DIGEST_LEN]; networkstatus_voter_info_t *voter; tok = _tok; if (tok->tp != K_DIRECTORY_SIGNATURE) continue; tor_assert(tok->n_args >= 2); if (!tok->object_type || strcmp(tok->object_type, "SIGNATURE") || tok->object_size < 128 || tok->object_size > 512) { log_warn(LD_DIR, "Bad object type or length on directory-signature"); goto err; } if (strlen(tok->args[0]) != HEX_DIGEST_LEN || base16_decode(id_digest, sizeof(id_digest), tok->args[0], HEX_DIGEST_LEN) < 0) { log_warn(LD_DIR, "Error decoding declared identity %s in " "network-status vote.", escaped(tok->args[0])); goto err; } if (strlen(tok->args[1]) != HEX_DIGEST_LEN || base16_decode(sk_digest, sizeof(sk_digest), tok->args[1], HEX_DIGEST_LEN) < 0) { log_warn(LD_DIR, "Error decoding declared digest %s in " "network-status vote.", escaped(tok->args[1])); goto err; } voter = tor_malloc_zero(sizeof(networkstatus_voter_info_t)); memcpy(voter->identity_digest, id_digest, DIGEST_LEN); memcpy(voter->signing_key_digest, sk_digest, DIGEST_LEN); if (tok->object_size >= INT_MAX) goto err; voter->signature = tor_memdup(tok->object_body, tok->object_size); voter->signature_len = (int) tok->object_size; smartlist_add(sigs->signatures, voter); }); goto done; err: ns_detached_signatures_free(sigs); sigs = NULL; done: SMARTLIST_FOREACH(tokens, directory_token_t *, t, token_free(t)); smartlist_free(tokens); if (area) { DUMP_AREA(area, "detached signatures"); memarea_drop_all(area); } return sigs; } /** Parse the addr policy in the string s and return it. If * assume_action is nonnegative, then insert its action (ADDR_POLICY_ACCEPT or * ADDR_POLICY_REJECT) for items that specify no action. */ addr_policy_t * router_parse_addr_policy_item_from_string(const char *s, int assume_action) { directory_token_t *tok = NULL; const char *cp, *eos; /* Longest possible policy is "accept ffff:ffff:..255/ffff:...255:0-65535". * But note that there can be an arbitrary amount of space between the * accept and the address:mask/port element. */ char line[TOR_ADDR_BUF_LEN*2 + 32]; addr_policy_t *r; memarea_t *area = NULL; s = eat_whitespace(s); if ((*s == '*' || TOR_ISDIGIT(*s)) && assume_action >= 0) { if (tor_snprintf(line, sizeof(line), "%s %s", assume_action == ADDR_POLICY_ACCEPT?"accept":"reject", s)<0) { log_warn(LD_DIR, "Policy %s is too long.", escaped(s)); return NULL; } cp = line; tor_strlower(line); } else { /* assume an already well-formed address policy line */ cp = s; } eos = cp + strlen(cp); area = memarea_new(); tok = get_next_token(area, &cp, eos, routerdesc_token_table); if (tok->tp == _ERR) { log_warn(LD_DIR, "Error reading address policy: %s", tok->error); goto err; } if (tok->tp != K_ACCEPT && tok->tp != K_ACCEPT6 && tok->tp != K_REJECT && tok->tp != K_REJECT6) { log_warn(LD_DIR, "Expected 'accept' or 'reject'."); goto err; } r = router_parse_addr_policy(tok); goto done; err: r = NULL; done: token_free(tok); if (area) { DUMP_AREA(area, "policy item"); memarea_drop_all(area); } return r; } /** Add an exit policy stored in the token tok to the router info in * router. Return 0 on success, -1 on failure. */ static int router_add_exit_policy(routerinfo_t *router, directory_token_t *tok) { addr_policy_t *newe; newe = router_parse_addr_policy(tok); if (!newe) return -1; if (! router->exit_policy) router->exit_policy = smartlist_create(); if (((tok->tp == K_ACCEPT6 || tok->tp == K_REJECT6) && tor_addr_family(&newe->addr) == AF_INET) || ((tok->tp == K_ACCEPT || tok->tp == K_REJECT) && tor_addr_family(&newe->addr) == AF_INET6)) { log_warn(LD_DIR, "Mismatch between field type and address type in exit " "policy"); addr_policy_free(newe); return -1; } smartlist_add(router->exit_policy, newe); return 0; } /** Given a K_ACCEPT or K_REJECT token and a router, create and return * a new exit_policy_t corresponding to the token. */ static addr_policy_t * router_parse_addr_policy(directory_token_t *tok) { addr_policy_t newe; char *arg; tor_assert(tok->tp == K_REJECT || tok->tp == K_REJECT6 || tok->tp == K_ACCEPT || tok->tp == K_ACCEPT6); if (tok->n_args != 1) return NULL; arg = tok->args[0]; if (!strcmpstart(arg,"private")) return router_parse_addr_policy_private(tok); memset(&newe, 0, sizeof(newe)); if (tok->tp == K_REJECT || tok->tp == K_REJECT6) newe.policy_type = ADDR_POLICY_REJECT; else newe.policy_type = ADDR_POLICY_ACCEPT; if (tor_addr_parse_mask_ports(arg, &newe.addr, &newe.maskbits, &newe.prt_min, &newe.prt_max) < 0) { log_warn(LD_DIR,"Couldn't parse line %s. Dropping", escaped(arg)); return NULL; } return addr_policy_get_canonical_entry(&newe); } /** Parse an exit policy line of the format "accept/reject private:...". * This didn't exist until Tor 0.1.1.15, so nobody should generate it in * router descriptors until earlier versions are obsolete. */ static addr_policy_t * router_parse_addr_policy_private(directory_token_t *tok) { const char *arg; uint16_t port_min, port_max; addr_policy_t result; arg = tok->args[0]; if (strcmpstart(arg, "private")) return NULL; arg += strlen("private"); arg = (char*) eat_whitespace(arg); if (!arg || *arg != ':') return NULL; if (parse_port_range(arg+1, &port_min, &port_max)<0) return NULL; memset(&result, 0, sizeof(result)); if (tok->tp == K_REJECT || tok->tp == K_REJECT6) result.policy_type = ADDR_POLICY_REJECT; else result.policy_type = ADDR_POLICY_ACCEPT; result.is_private = 1; result.prt_min = port_min; result.prt_max = port_max; return addr_policy_get_canonical_entry(&result); } /** Log and exit if t is malformed */ void assert_addr_policy_ok(smartlist_t *lst) { if (!lst) return; SMARTLIST_FOREACH(lst, addr_policy_t *, t, { tor_assert(t->policy_type == ADDR_POLICY_REJECT || t->policy_type == ADDR_POLICY_ACCEPT); tor_assert(t->prt_min <= t->prt_max); }); } /* * Low-level tokenizer for router descriptors and directories. */ /** Free all resources allocated for tok */ static void token_free(directory_token_t *tok) { tor_assert(tok); if (tok->key) crypto_free_pk_env(tok->key); } #define ALLOC_ZERO(sz) memarea_alloc_zero(area,sz) #define ALLOC(sz) memarea_alloc(area,sz) #define STRDUP(str) memarea_strdup(area,str) #define STRNDUP(str,n) memarea_strndup(area,(str),(n)) #define RET_ERR(msg) \ STMT_BEGIN \ if (tok) token_free(tok); \ tok = ALLOC_ZERO(sizeof(directory_token_t)); \ tok->tp = _ERR; \ tok->error = STRDUP(msg); \ goto done_tokenizing; \ STMT_END /** Helper: make sure that the token tok with keyword kwd obeys * the object syntax of o_syn. Allocate all storage in area. * Return tok on success, or a new _ERR token if the token didn't * conform to the syntax we wanted. **/ static INLINE directory_token_t * token_check_object(memarea_t *area, const char *kwd, directory_token_t *tok, obj_syntax o_syn) { char ebuf[128]; switch (o_syn) { case NO_OBJ: /* No object is allowed for this token. */ if (tok->object_body) { tor_snprintf(ebuf, sizeof(ebuf), "Unexpected object for %s", kwd); RET_ERR(ebuf); } if (tok->key) { tor_snprintf(ebuf, sizeof(ebuf), "Unexpected public key for %s", kwd); RET_ERR(ebuf); } break; case NEED_OBJ: /* There must be a (non-key) object. */ if (!tok->object_body) { tor_snprintf(ebuf, sizeof(ebuf), "Missing object for %s", kwd); RET_ERR(ebuf); } break; case NEED_KEY_1024: /* There must be a 1024-bit public key. */ case NEED_SKEY_1024: /* There must be a 1024-bit private key. */ if (tok->key && crypto_pk_keysize(tok->key) != PK_BYTES) { tor_snprintf(ebuf, sizeof(ebuf), "Wrong size on key for %s: %d bits", kwd, (int)crypto_pk_keysize(tok->key)); RET_ERR(ebuf); } /* fall through */ case NEED_KEY: /* There must be some kind of key. */ if (!tok->key) { tor_snprintf(ebuf, sizeof(ebuf), "Missing public key for %s", kwd); } if (o_syn != NEED_SKEY_1024) { if (crypto_pk_key_is_private(tok->key)) { tor_snprintf(ebuf, sizeof(ebuf), "Private key given for %s, which wants a public key", kwd); RET_ERR(ebuf); } } else { /* o_syn == NEED_SKEY_1024 */ if (!crypto_pk_key_is_private(tok->key)) { tor_snprintf(ebuf, sizeof(ebuf), "Public key given for %s, which wants a private key", kwd); RET_ERR(ebuf); } } break; case OBJ_OK: /* Anything goes with this token. */ break; } done_tokenizing: return tok; } /** Helper function: read the next token from *s, advance *s to the end of the * token, and return the parsed token. Parse *s according to the list * of tokens in table. */ static directory_token_t * get_next_token(memarea_t *area, const char **s, const char *eos, token_rule_t *table) { const char *next, *eol, *obstart; size_t obname_len; int i; directory_token_t *tok; obj_syntax o_syn = NO_OBJ; char ebuf[128]; const char *kwd = ""; tor_assert(area); tok = ALLOC_ZERO(sizeof(directory_token_t)); tok->tp = _ERR; /* Set *s to first token, eol to end-of-line, next to after first token */ *s = eat_whitespace_eos(*s, eos); /* eat multi-line whitespace */ tor_assert(eos >= *s); eol = memchr(*s, '\n', eos-*s); if (!eol) eol = eos; next = find_whitespace_eos(*s, eol); if (!strcmp_len(*s, "opt", next-*s)) { /* Skip past an "opt" at the start of the line. */ *s = eat_whitespace_eos_no_nl(next, eol); next = find_whitespace_eos(*s, eol); } else if (*s == eos) { /* If no "opt", and end-of-line, line is invalid */ RET_ERR("Unexpected EOF"); } /* Search the table for the appropriate entry. (I tried a binary search * instead, but it wasn't any faster.) */ for (i = 0; table[i].t ; ++i) { if (!strcmp_len(*s, table[i].t, next-*s)) { /* We've found the keyword. */ kwd = table[i].t; tok->tp = table[i].v; o_syn = table[i].os; *s = eat_whitespace_eos_no_nl(next, eol); /* We go ahead whether there are arguments or not, so that tok->args is * always set if we want arguments. */ if (table[i].concat_args) { /* The keyword takes the line as a single argument */ tok->args = ALLOC(sizeof(char*)); tok->args[0] = STRNDUP(*s,eol-*s); /* Grab everything on line */ tok->n_args = 1; } else { /* This keyword takes multiple arguments. */ /* XXXX021 this code is still too complicated. */ char *mem = memarea_strndup(area, *s, eol-*s); char *cp = mem; int j = 0; while (*cp) { j++; cp = (char*)find_whitespace(cp); if (!cp || !*cp) break; cp = (char*)eat_whitespace(cp); } tok->n_args = j; if (tok->n_args) { tok->args = memarea_alloc(area, sizeof(char*)*tok->n_args); cp = mem; j = 0; while (*cp) { tok->args[j++] = cp; cp = (char*)find_whitespace(cp); if (!cp || !*cp) break; *cp++ = '\0'; cp = (char*)eat_whitespace(cp); } } *s = eol; } if (tok->n_args < table[i].min_args) { tor_snprintf(ebuf, sizeof(ebuf), "Too few arguments to %s", kwd); RET_ERR(ebuf); } else if (tok->n_args > table[i].max_args) { tor_snprintf(ebuf, sizeof(ebuf), "Too many arguments to %s", kwd); RET_ERR(ebuf); } break; } } if (tok->tp == _ERR) { /* No keyword matched; call it an "K_opt" or "A_unrecognized" */ if (**s == '@') tok->tp = _A_UNKNOWN; else tok->tp = K_OPT; tok->args = ALLOC(sizeof(char*)); tok->args[0] = STRNDUP(*s, eol-*s); tok->n_args = 1; o_syn = OBJ_OK; } /* Check whether there's an object present */ *s = eat_whitespace_eos(eol, eos); /* Scan from end of first line */ tor_assert(eos >= *s); eol = memchr(*s, '\n', eos-*s); if (!eol || eol-*s<11 || strcmpstart(*s, "-----BEGIN ")) /* No object. */ goto check_object; obstart = *s; /* Set obstart to start of object spec */ tor_assert(eol >= (*s+16)); if (*s+11 >= eol-5 || memchr(*s+11,'\0',eol-*s-16) || /* no short lines, */ strcmp_len(eol-5, "-----", 5)) { /* nuls or invalid endings */ RET_ERR("Malformed object: bad begin line"); } tok->object_type = STRNDUP(*s+11, eol-*s-16); obname_len = eol-*s-16; /* store objname length here to avoid a strlen() */ *s = eol+1; /* Set *s to possible start of object data (could be eos) */ /* Go to the end of the object */ next = tor_memstr(*s, eos-*s, "-----END "); if (!next) { RET_ERR("Malformed object: missing object end line"); } tor_assert(eos >= next); eol = memchr(next, '\n', eos-next); if (!eol) /* end-of-line marker, or eos if there's no '\n' */ eol = eos; /* Validate the ending tag, which should be 9 + NAME + 5 + eol */ if ((size_t)(eol-next) != 9+obname_len+5 || strcmp_len(next+9, tok->object_type, obname_len) || strcmp_len(eol-5, "-----", 5)) { snprintf(ebuf, sizeof(ebuf), "Malformed object: mismatched end tag %s", tok->object_type); ebuf[sizeof(ebuf)-1] = '\0'; RET_ERR(ebuf); } if (!strcmp(tok->object_type, "RSA PUBLIC KEY")) { /* If it's a public key */ tok->key = crypto_new_pk_env(); if (crypto_pk_read_public_key_from_string(tok->key, obstart, eol-obstart)) RET_ERR("Couldn't parse public key."); } else if (!strcmp(tok->object_type, "RSA PRIVATE KEY")) { /* private key */ tok->key = crypto_new_pk_env(); if (crypto_pk_read_private_key_from_string(tok->key, obstart)) RET_ERR("Couldn't parse private key."); } else { /* If it's something else, try to base64-decode it */ int r; tok->object_body = ALLOC(next-*s); /* really, this is too much RAM. */ r = base64_decode(tok->object_body, next-*s, *s, next-*s); if (r<0) RET_ERR("Malformed object: bad base64-encoded data"); tok->object_size = r; } *s = eol; check_object: tok = token_check_object(area, kwd, tok, o_syn); done_tokenizing: return tok; #undef RET_ERR #undef ALLOC #undef ALLOC_ZERO #undef STRDUP #undef STRNDUP } /** Read all tokens from a string between start and end, and add * them to out. Parse according to the token rules in table. * Caller must free tokens in out. If end is NULL, use the * entire string. */ static int tokenize_string(memarea_t *area, const char *start, const char *end, smartlist_t *out, token_rule_t *table, int flags) { const char **s; directory_token_t *tok = NULL; int counts[_NIL]; int i; int first_nonannotation; int prev_len = smartlist_len(out); tor_assert(area); s = &start; if (!end) end = start+strlen(start); for (i = 0; i < _NIL; ++i) counts[i] = 0; while (*s < end && (!tok || tok->tp != _EOF)) { tok = get_next_token(area, s, end, table); if (tok->tp == _ERR) { log_warn(LD_DIR, "parse error: %s", tok->error); token_free(tok); return -1; } ++counts[tok->tp]; smartlist_add(out, tok); *s = eat_whitespace_eos(*s, end); } if (flags & TS_NOCHECK) return 0; if ((flags & TS_ANNOTATIONS_OK)) { first_nonannotation = -1; for (i = 0; i < smartlist_len(out); ++i) { tok = smartlist_get(out, i); if (tok->tp < MIN_ANNOTATION || tok->tp > MAX_ANNOTATION) { first_nonannotation = i; break; } } if (first_nonannotation < 0) { log_warn(LD_DIR, "parse error: item contains only annotations"); return -1; } for (i=first_nonannotation; i < smartlist_len(out); ++i) { tok = smartlist_get(out, i); if (tok->tp >= MIN_ANNOTATION && tok->tp <= MAX_ANNOTATION) { log_warn(LD_DIR, "parse error: Annotations mixed with keywords"); return -1; } } if ((flags & TS_NO_NEW_ANNOTATIONS)) { if (first_nonannotation != prev_len) { log_warn(LD_DIR, "parse error: Unexpectd annotations."); return -1; } } } else { for (i=0; i < smartlist_len(out); ++i) { tok = smartlist_get(out, i); if (tok->tp >= MIN_ANNOTATION && tok->tp <= MAX_ANNOTATION) { log_warn(LD_DIR, "parse error: no annotations allowed."); return -1; } } first_nonannotation = 0; } for (i = 0; table[i].t; ++i) { if (counts[table[i].v] < table[i].min_cnt) { log_warn(LD_DIR, "Parse error: missing %s element.", table[i].t); return -1; } if (counts[table[i].v] > table[i].max_cnt) { log_warn(LD_DIR, "Parse error: too many %s elements.", table[i].t); return -1; } if (table[i].pos & AT_START) { if (smartlist_len(out) < 1 || (tok = smartlist_get(out, first_nonannotation))->tp != table[i].v) { log_warn(LD_DIR, "Parse error: first item is not %s.", table[i].t); return -1; } } if (table[i].pos & AT_END) { if (smartlist_len(out) < 1 || (tok = smartlist_get(out, smartlist_len(out)-1))->tp != table[i].v) { log_warn(LD_DIR, "Parse error: last item is not %s.", table[i].t); return -1; } } } return 0; } /** Find the first token in s whose keyword is keyword; return * NULL if no such keyword is found. */ static directory_token_t * find_opt_by_keyword(smartlist_t *s, directory_keyword keyword) { SMARTLIST_FOREACH(s, directory_token_t *, t, if (t->tp == keyword) return t); return NULL; } /** Find the first token in s whose keyword is keyword; fail * with an assert if no such keyword is found. */ static directory_token_t * _find_by_keyword(smartlist_t *s, directory_keyword keyword, const char *keyword_as_string) { directory_token_t *tok = find_opt_by_keyword(s, keyword); if (PREDICT_UNLIKELY(!tok)) { log_err(LD_BUG, "Missing %s [%d] in directory object that should have " "been validated. Internal error.", keyword_as_string, (int)keyword); tor_assert(tok); } return tok; } /** Return a newly allocated smartlist of all accept or reject tokens in * s. */ static smartlist_t * find_all_exitpolicy(smartlist_t *s) { smartlist_t *out = smartlist_create(); SMARTLIST_FOREACH(s, directory_token_t *, t, if (t->tp == K_ACCEPT || t->tp == K_ACCEPT6 || t->tp == K_REJECT || t->tp == K_REJECT6) smartlist_add(out,t)); return out; } /** Compute the SHA-1 digest of the substring of s taken from the first * occurrence of start_str through the first instance of c after the * first subsequent occurrence of end_str; store the 20-byte result in * digest; return 0 on success. * * If no such substring exists, return -1. */ static int router_get_hash_impl(const char *s, char *digest, const char *start_str, const char *end_str, char end_c) { char *start, *end; start = strstr(s, start_str); if (!start) { log_warn(LD_DIR,"couldn't find start of hashed material \"%s\"",start_str); return -1; } if (start != s && *(start-1) != '\n') { log_warn(LD_DIR, "first occurrence of \"%s\" is not at the start of a line", start_str); return -1; } end = strstr(start+strlen(start_str), end_str); if (!end) { log_warn(LD_DIR,"couldn't find end of hashed material \"%s\"",end_str); return -1; } end = strchr(end+strlen(end_str), end_c); if (!end) { log_warn(LD_DIR,"couldn't find EOL"); return -1; } ++end; if (crypto_digest(digest, start, end-start)) { log_warn(LD_BUG,"couldn't compute digest"); return -1; } return 0; } /** Parse the Tor version of the platform string platform, * and compare it to the version in cutoff. Return 1 if * the router is at least as new as the cutoff, else return 0. */ int tor_version_as_new_as(const char *platform, const char *cutoff) { tor_version_t cutoff_version, router_version; char *s, *s2, *start; char tmp[128]; tor_assert(platform); if (tor_version_parse(cutoff, &cutoff_version)<0) { log_warn(LD_BUG,"cutoff version '%s' unparseable.",cutoff); return 0; } if (strcmpstart(platform,"Tor ")) /* nonstandard Tor; be safe and say yes */ return 1; start = (char *)eat_whitespace(platform+3); if (!*start) return 0; s = (char *)find_whitespace(start); /* also finds '\0', which is fine */ s2 = (char*)eat_whitespace(s); if (!strcmpstart(s2, "(r")) s = (char*)find_whitespace(s2); if ((size_t)(s-start+1) >= sizeof(tmp)) /* too big, no */ return 0; strlcpy(tmp, start, s-start+1); if (tor_version_parse(tmp, &router_version)<0) { log_info(LD_DIR,"Router version '%s' unparseable.",tmp); return 1; /* be safe and say yes */ } /* Here's why we don't need to do any special handling for svn revisions: * - If neither has an svn revision, we're fine. * - If the router doesn't have an svn revision, we can't assume that it * is "at least" any svn revision, so we need to return 0. * - If the target version doesn't have an svn revision, any svn revision * (or none at all) is good enough, so return 1. * - If both target and router have an svn revision, we compare them. */ return tor_version_compare(&router_version, &cutoff_version) >= 0; } /** Parse a tor version from s, and store the result in out. * Return 0 on success, -1 on failure. */ int tor_version_parse(const char *s, tor_version_t *out) { char *eos=NULL; const char *cp=NULL; /* Format is: * "Tor " ? NUM dot NUM dot NUM [ ( pre | rc | dot ) NUM [ - tag ] ] */ tor_assert(s); tor_assert(out); memset(out, 0, sizeof(tor_version_t)); if (!strcasecmpstart(s, "Tor ")) s += 4; /* Get major. */ out->major = (int)strtol(s,&eos,10); if (!eos || eos==s || *eos != '.') return -1; cp = eos+1; /* Get minor */ out->minor = (int) strtol(cp,&eos,10); if (!eos || eos==cp || *eos != '.') return -1; cp = eos+1; /* Get micro */ out->micro = (int) strtol(cp,&eos,10); if (!eos || eos==cp) return -1; if (!*eos) { out->status = VER_RELEASE; out->patchlevel = 0; return 0; } cp = eos; /* Get status */ if (*cp == '.') { out->status = VER_RELEASE; ++cp; } else if (0==strncmp(cp, "pre", 3)) { out->status = VER_PRE; cp += 3; } else if (0==strncmp(cp, "rc", 2)) { out->status = VER_RC; cp += 2; } else { return -1; } /* Get patchlevel */ out->patchlevel = (int) strtol(cp,&eos,10); if (!eos || eos==cp) return -1; cp = eos; /* Get status tag. */ if (*cp == '-' || *cp == '.') ++cp; eos = (char*) find_whitespace(cp); if (eos-cp >= (int)sizeof(out->status_tag)) strlcpy(out->status_tag, cp, sizeof(out->status_tag)); else { memcpy(out->status_tag, cp, eos-cp); out->status_tag[eos-cp] = 0; } cp = eat_whitespace(eos); if (!strcmpstart(cp, "(r")) { cp += 2; out->svn_revision = (int) strtol(cp,&eos,10); } return 0; } /** Compare two tor versions; Return <0 if a < b; 0 if a ==b, >0 if a > * b. */ int tor_version_compare(tor_version_t *a, tor_version_t *b) { int i; tor_assert(a); tor_assert(b); if ((i = a->major - b->major)) return i; else if ((i = a->minor - b->minor)) return i; else if ((i = a->micro - b->micro)) return i; else if ((i = a->status - b->status)) return i; else if ((i = a->patchlevel - b->patchlevel)) return i; else if ((i = strcmp(a->status_tag, b->status_tag))) return i; else return a->svn_revision - b->svn_revision; } /** Return true iff versions a and b belong to the same series. */ static int tor_version_same_series(tor_version_t *a, tor_version_t *b) { tor_assert(a); tor_assert(b); return ((a->major == b->major) && (a->minor == b->minor) && (a->micro == b->micro)); } /** Helper: Given pointers to two strings describing tor versions, return -1 * if _a precedes _b, 1 if _b preceeds _a, and 0 if they are equivalent. * Used to sort a list of versions. */ static int _compare_tor_version_str_ptr(const void **_a, const void **_b) { const char *a = *_a, *b = *_b; int ca, cb; tor_version_t va, vb; ca = tor_version_parse(a, &va); cb = tor_version_parse(b, &vb); /* If they both parse, compare them. */ if (!ca && !cb) return tor_version_compare(&va,&vb); /* If one parses, it comes first. */ if (!ca && cb) return -1; if (ca && !cb) return 1; /* If neither parses, compare strings. Also, the directory server admin ** needs to be smacked upside the head. But Tor is tolerant and gentle. */ return strcmp(a,b); } /** Sort a list of string-representations of versions in ascending order. */ void sort_version_list(smartlist_t *versions, int remove_duplicates) { smartlist_sort(versions, _compare_tor_version_str_ptr); if (remove_duplicates) smartlist_uniq(versions, _compare_tor_version_str_ptr, _tor_free); } /** Parse and validate the ASCII-encoded v2 descriptor in desc, * write the parsed descriptor to the newly allocated *parsed_out, the * binary descriptor ID of length DIGEST_LEN to desc_id_out, the * encrypted introduction points to the newly allocated * *intro_points_encrypted_out, their encrypted size to * *intro_points_encrypted_size_out, the size of the encoded descriptor * to *encoded_size_out, and a pointer to the possibly next * descriptor to *next_out; return 0 for success (including validation) * and -1 for failure. */ int rend_parse_v2_service_descriptor(rend_service_descriptor_t **parsed_out, char *desc_id_out, char **intro_points_encrypted_out, size_t *intro_points_encrypted_size_out, size_t *encoded_size_out, const char **next_out, const char *desc) { rend_service_descriptor_t *result = tor_malloc_zero(sizeof(rend_service_descriptor_t)); char desc_hash[DIGEST_LEN]; const char *eos; smartlist_t *tokens = smartlist_create(); directory_token_t *tok; char secret_id_part[DIGEST_LEN]; int i, version, num_ok=1; smartlist_t *versions; char public_key_hash[DIGEST_LEN]; char test_desc_id[DIGEST_LEN]; memarea_t *area = NULL; tor_assert(desc); /* Check if desc starts correctly. */ if (strncmp(desc, "rendezvous-service-descriptor ", strlen("rendezvous-service-descriptor "))) { log_info(LD_REND, "Descriptor does not start correctly."); goto err; } /* Compute descriptor hash for later validation. */ if (router_get_hash_impl(desc, desc_hash, "rendezvous-service-descriptor ", "\nsignature", '\n') < 0) { log_warn(LD_REND, "Couldn't compute descriptor hash."); goto err; } /* Determine end of string. */ eos = strstr(desc, "\nrendezvous-service-descriptor "); if (!eos) eos = desc + strlen(desc); else eos = eos + 1; /* Check length. */ if (strlen(desc) > REND_DESC_MAX_SIZE) { log_warn(LD_REND, "Descriptor length is %i which exceeds " "maximum rendezvous descriptor size of %i kilobytes.", (int)strlen(desc), REND_DESC_MAX_SIZE); goto err; } /* Tokenize descriptor. */ area = memarea_new(); if (tokenize_string(area, desc, eos, tokens, desc_token_table, 0)) { log_warn(LD_REND, "Error tokenizing descriptor."); goto err; } /* Set next to next descriptor, if available. */ *next_out = eos; /* Set length of encoded descriptor. */ *encoded_size_out = eos - desc; /* Check min allowed length of token list. */ if (smartlist_len(tokens) < 7) { log_warn(LD_REND, "Impossibly short descriptor."); goto err; } /* Parse base32-encoded descriptor ID. */ tok = find_by_keyword(tokens, R_RENDEZVOUS_SERVICE_DESCRIPTOR); tor_assert(tok == smartlist_get(tokens, 0)); tor_assert(tok->n_args == 1); if (strlen(tok->args[0]) != REND_DESC_ID_V2_LEN_BASE32 || strspn(tok->args[0], BASE32_CHARS) != REND_DESC_ID_V2_LEN_BASE32) { log_warn(LD_REND, "Invalid descriptor ID: '%s'", tok->args[0]); goto err; } if (base32_decode(desc_id_out, DIGEST_LEN, tok->args[0], REND_DESC_ID_V2_LEN_BASE32) < 0) { log_warn(LD_REND, "Descriptor ID contains illegal characters: %s", tok->args[0]); goto err; } /* Parse descriptor version. */ tok = find_by_keyword(tokens, R_VERSION); tor_assert(tok->n_args == 1); result->version = (int) tor_parse_long(tok->args[0], 10, 0, INT_MAX, &num_ok, NULL); if (result->version != 2 || !num_ok) { /* If it's <2, it shouldn't be under this format. If the number * is greater than 2, we bumped it because we broke backward * compatibility. See how version numbers in our other formats * work. */ log_warn(LD_REND, "Unrecognized descriptor version: %s", escaped(tok->args[0])); goto err; } /* Parse public key. */ tok = find_by_keyword(tokens, R_PERMANENT_KEY); result->pk = tok->key; tok->key = NULL; /* Prevent free */ /* Parse secret ID part. */ tok = find_by_keyword(tokens, R_SECRET_ID_PART); tor_assert(tok->n_args == 1); if (strlen(tok->args[0]) != REND_SECRET_ID_PART_LEN_BASE32 || strspn(tok->args[0], BASE32_CHARS) != REND_SECRET_ID_PART_LEN_BASE32) { log_warn(LD_REND, "Invalid secret ID part: '%s'", tok->args[0]); goto err; } if (base32_decode(secret_id_part, DIGEST_LEN, tok->args[0], 32) < 0) { log_warn(LD_REND, "Secret ID part contains illegal characters: %s", tok->args[0]); goto err; } /* Parse publication time -- up-to-date check is done when storing the * descriptor. */ tok = find_by_keyword(tokens, R_PUBLICATION_TIME); tor_assert(tok->n_args == 1); if (parse_iso_time(tok->args[0], &result->timestamp) < 0) { log_warn(LD_REND, "Invalid publication time: '%s'", tok->args[0]); goto err; } /* Parse protocol versions. */ tok = find_by_keyword(tokens, R_PROTOCOL_VERSIONS); tor_assert(tok->n_args == 1); versions = smartlist_create(); smartlist_split_string(versions, tok->args[0], ",", SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 0); for (i = 0; i < smartlist_len(versions); i++) { version = (int) tor_parse_long(smartlist_get(versions, i), 10, 0, INT_MAX, &num_ok, NULL); if (!num_ok) /* It's a string; let's ignore it. */ continue; result->protocols |= 1 << version; } SMARTLIST_FOREACH(versions, char *, cp, tor_free(cp)); smartlist_free(versions); /* Parse encrypted introduction points. Don't verify. */ tok = find_opt_by_keyword(tokens, R_INTRODUCTION_POINTS); if (tok) { if (strcmp(tok->object_type, "MESSAGE")) { log_warn(LD_DIR, "Bad object type: introduction points should be of " "type MESSAGE"); goto err; } *intro_points_encrypted_out = tor_memdup(tok->object_body, tok->object_size); *intro_points_encrypted_size_out = tok->object_size; } else { *intro_points_encrypted_out = NULL; *intro_points_encrypted_size_out = 0; } /* Parse and verify signature. */ tok = find_by_keyword(tokens, R_SIGNATURE); note_crypto_pk_op(VERIFY_RTR); if (check_signature_token(desc_hash, tok, result->pk, 0, "v2 rendezvous service descriptor") < 0) goto err; /* Verify that descriptor ID belongs to public key and secret ID part. */ crypto_pk_get_digest(result->pk, public_key_hash); rend_get_descriptor_id_bytes(test_desc_id, public_key_hash, secret_id_part); if (memcmp(desc_id_out, test_desc_id, DIGEST_LEN)) { log_warn(LD_REND, "Parsed descriptor ID does not match " "computed descriptor ID."); goto err; } goto done; err: if (result) rend_service_descriptor_free(result); result = NULL; done: if (tokens) { SMARTLIST_FOREACH(tokens, directory_token_t *, t, token_free(t)); smartlist_free(tokens); } if (area) memarea_drop_all(area); *parsed_out = result; if (result) return 0; return -1; } /** Decrypt the encrypted introduction points in ipos_encrypted of * length ipos_encrypted_size using descriptor_cookie and * write the result to a newly allocated string that is pointed to by * ipos_decrypted and its length to ipos_decrypted_size. * Return 0 if decryption was successful and -1 otherwise. */ int rend_decrypt_introduction_points(char **ipos_decrypted, size_t *ipos_decrypted_size, const char *descriptor_cookie, const char *ipos_encrypted, size_t ipos_encrypted_size) { tor_assert(ipos_encrypted); tor_assert(descriptor_cookie); if (ipos_encrypted_size < 2) { log_warn(LD_REND, "Size of encrypted introduction points is too " "small."); return -1; } if (ipos_encrypted[0] == (int)REND_BASIC_AUTH) { char iv[CIPHER_IV_LEN], client_id[REND_BASIC_AUTH_CLIENT_ID_LEN], session_key[CIPHER_KEY_LEN], *dec; int declen, client_blocks; size_t pos = 0, len, client_entries_len; crypto_digest_env_t *digest; crypto_cipher_env_t *cipher; client_blocks = (int) ipos_encrypted[1]; client_entries_len = client_blocks * REND_BASIC_AUTH_CLIENT_MULTIPLE * REND_BASIC_AUTH_CLIENT_ENTRY_LEN; if (ipos_encrypted_size < 2 + client_entries_len + CIPHER_IV_LEN + 1) { log_warn(LD_REND, "Size of encrypted introduction points is too " "small."); return -1; } memcpy(iv, ipos_encrypted + 2 + client_entries_len, CIPHER_IV_LEN); digest = crypto_new_digest_env(); crypto_digest_add_bytes(digest, descriptor_cookie, REND_DESC_COOKIE_LEN); crypto_digest_add_bytes(digest, iv, CIPHER_IV_LEN); crypto_digest_get_digest(digest, client_id, REND_BASIC_AUTH_CLIENT_ID_LEN); crypto_free_digest_env(digest); for (pos = 2; pos < 2 + client_entries_len; pos += REND_BASIC_AUTH_CLIENT_ENTRY_LEN) { if (!memcmp(ipos_encrypted + pos, client_id, REND_BASIC_AUTH_CLIENT_ID_LEN)) { /* Attempt to decrypt introduction points. */ cipher = crypto_create_init_cipher(descriptor_cookie, 0); if (crypto_cipher_decrypt(cipher, session_key, ipos_encrypted + pos + REND_BASIC_AUTH_CLIENT_ID_LEN, CIPHER_KEY_LEN) < 0) { log_warn(LD_REND, "Could not decrypt session key for client."); crypto_free_cipher_env(cipher); return -1; } crypto_free_cipher_env(cipher); cipher = crypto_create_init_cipher(session_key, 0); len = ipos_encrypted_size - 2 - client_entries_len - CIPHER_IV_LEN; dec = tor_malloc(len); declen = crypto_cipher_decrypt_with_iv(cipher, dec, len, ipos_encrypted + 2 + client_entries_len, ipos_encrypted_size - 2 - client_entries_len); crypto_free_cipher_env(cipher); if (declen < 0) { log_warn(LD_REND, "Could not decrypt introduction point string."); tor_free(dec); return -1; } if (memcmpstart(dec, declen, "introduction-point ")) { log_warn(LD_REND, "Decrypted introduction points don't " "look like we could parse them."); tor_free(dec); continue; } *ipos_decrypted = dec; *ipos_decrypted_size = declen; return 0; } } log_warn(LD_REND, "Could not decrypt introduction points. Please " "check your authorization for this service!"); return -1; } else if (ipos_encrypted[0] == (int)REND_STEALTH_AUTH) { crypto_cipher_env_t *cipher; char *dec; int declen; dec = tor_malloc_zero(ipos_encrypted_size - CIPHER_IV_LEN - 1); cipher = crypto_create_init_cipher(descriptor_cookie, 0); declen = crypto_cipher_decrypt_with_iv(cipher, dec, ipos_encrypted_size - CIPHER_IV_LEN - 1, ipos_encrypted + 1, ipos_encrypted_size - 1); crypto_free_cipher_env(cipher); if (declen < 0) { log_warn(LD_REND, "Decrypting introduction points failed!"); tor_free(dec); return -1; } *ipos_decrypted = dec; *ipos_decrypted_size = declen; return 0; } else { log_warn(LD_REND, "Unknown authorization type number: %d", ipos_encrypted[0]); return -1; } } /** Parse the encoded introduction points in intro_points_encoded of * length intro_points_encoded_size and write the result to the * descriptor in parsed; return the number of successfully parsed * introduction points or -1 in case of a failure. */ int rend_parse_introduction_points(rend_service_descriptor_t *parsed, const char *intro_points_encoded, size_t intro_points_encoded_size) { const char *current_ipo, *end_of_intro_points; smartlist_t *tokens; directory_token_t *tok; rend_intro_point_t *intro; extend_info_t *info; int result, num_ok=1; memarea_t *area = NULL; tor_assert(parsed); /** Function may only be invoked once. */ tor_assert(!parsed->intro_nodes); tor_assert(intro_points_encoded); tor_assert(intro_points_encoded_size > 0); /* Consider one intro point after the other. */ current_ipo = intro_points_encoded; end_of_intro_points = intro_points_encoded + intro_points_encoded_size; tokens = smartlist_create(); parsed->intro_nodes = smartlist_create(); area = memarea_new(); while (!memcmpstart(current_ipo, end_of_intro_points-current_ipo, "introduction-point ")) { /* Determine end of string. */ const char *eos = tor_memstr(current_ipo, end_of_intro_points-current_ipo, "\nintroduction-point "); if (!eos) eos = end_of_intro_points; else eos = eos+1; tor_assert(eos <= intro_points_encoded+intro_points_encoded_size); /* Free tokens and clear token list. */ SMARTLIST_FOREACH(tokens, directory_token_t *, t, token_free(t)); smartlist_clear(tokens); memarea_clear(area); /* Tokenize string. */ if (tokenize_string(area, current_ipo, eos, tokens, ipo_token_table, 0)) { log_warn(LD_REND, "Error tokenizing introduction point"); goto err; } /* Advance to next introduction point, if available. */ current_ipo = eos; /* Check minimum allowed length of introduction point. */ if (smartlist_len(tokens) < 5) { log_warn(LD_REND, "Impossibly short introduction point."); goto err; } /* Allocate new intro point and extend info. */ intro = tor_malloc_zero(sizeof(rend_intro_point_t)); info = intro->extend_info = tor_malloc_zero(sizeof(extend_info_t)); /* Parse identifier. */ tok = find_by_keyword(tokens, R_IPO_IDENTIFIER); if (base32_decode(info->identity_digest, DIGEST_LEN, tok->args[0], REND_INTRO_POINT_ID_LEN_BASE32) < 0) { log_warn(LD_REND, "Identity digest contains illegal characters: %s", tok->args[0]); rend_intro_point_free(intro); goto err; } /* Write identifier to nickname. */ info->nickname[0] = '$'; base16_encode(info->nickname + 1, sizeof(info->nickname) - 1, info->identity_digest, DIGEST_LEN); /* Parse IP address. */ tok = find_by_keyword(tokens, R_IPO_IP_ADDRESS); if (tor_addr_from_str(&info->addr, tok->args[0])<0) { log_warn(LD_REND, "Could not parse introduction point address."); rend_intro_point_free(intro); goto err; } if (tor_addr_family(&info->addr) != AF_INET) { log_warn(LD_REND, "Introduction point address was not ipv4."); rend_intro_point_free(intro); goto err; } /* Parse onion port. */ tok = find_by_keyword(tokens, R_IPO_ONION_PORT); info->port = (uint16_t) tor_parse_long(tok->args[0],10,1,65535, &num_ok,NULL); if (!info->port || !num_ok) { log_warn(LD_REND, "Introduction point onion port %s is invalid", escaped(tok->args[0])); rend_intro_point_free(intro); goto err; } /* Parse onion key. */ tok = find_by_keyword(tokens, R_IPO_ONION_KEY); info->onion_key = tok->key; tok->key = NULL; /* Prevent free */ /* Parse service key. */ tok = find_by_keyword(tokens, R_IPO_SERVICE_KEY); intro->intro_key = tok->key; tok->key = NULL; /* Prevent free */ /* Add extend info to list of introduction points. */ smartlist_add(parsed->intro_nodes, intro); } result = smartlist_len(parsed->intro_nodes); goto done; err: result = -1; done: /* Free tokens and clear token list. */ SMARTLIST_FOREACH(tokens, directory_token_t *, t, token_free(t)); smartlist_free(tokens); if (area) memarea_drop_all(area); return result; } /** Parse the content of a client_key file in ckstr and add * rend_authorized_client_t's for each parsed client to * parsed_clients. Return the number of parsed clients as result * or -1 for failure. */ int rend_parse_client_keys(strmap_t *parsed_clients, const char *ckstr) { int result = -1; smartlist_t *tokens; directory_token_t *tok; const char *current_entry = NULL; memarea_t *area = NULL; if (!ckstr || strlen(ckstr) == 0) return -1; tokens = smartlist_create(); /* Begin parsing with first entry, skipping comments or whitespace at the * beginning. */ area = memarea_new(); current_entry = eat_whitespace(ckstr); while (!strcmpstart(current_entry, "client-name ")) { rend_authorized_client_t *parsed_entry; size_t len; char descriptor_cookie_base64[REND_DESC_COOKIE_LEN_BASE64+2+1]; char descriptor_cookie_tmp[REND_DESC_COOKIE_LEN+2]; /* Determine end of string. */ const char *eos = strstr(current_entry, "\nclient-name "); if (!eos) eos = current_entry + strlen(current_entry); else eos = eos + 1; /* Free tokens and clear token list. */ SMARTLIST_FOREACH(tokens, directory_token_t *, t, token_free(t)); smartlist_clear(tokens); memarea_clear(area); /* Tokenize string. */ if (tokenize_string(area, current_entry, eos, tokens, client_keys_token_table, 0)) { log_warn(LD_REND, "Error tokenizing client keys file."); goto err; } /* Advance to next entry, if available. */ current_entry = eos; /* Check minimum allowed length of token list. */ if (smartlist_len(tokens) < 2) { log_warn(LD_REND, "Impossibly short client key entry."); goto err; } /* Parse client name. */ tok = find_by_keyword(tokens, C_CLIENT_NAME); tor_assert(tok == smartlist_get(tokens, 0)); tor_assert(tok->n_args == 1); len = strlen(tok->args[0]); if (len < 1 || len > 19 || strspn(tok->args[0], REND_LEGAL_CLIENTNAME_CHARACTERS) != len) { log_warn(LD_CONFIG, "Illegal client name: %s. (Length must be " "between 1 and 19, and valid characters are " "[A-Za-z0-9+-_].)", tok->args[0]); goto err; } /* Check if client name is duplicate. */ if (strmap_get(parsed_clients, tok->args[0])) { log_warn(LD_CONFIG, "HiddenServiceAuthorizeClient contains a " "duplicate client name: '%s'. Ignoring.", tok->args[0]); goto err; } parsed_entry = tor_malloc_zero(sizeof(rend_authorized_client_t)); parsed_entry->client_name = tor_strdup(tok->args[0]); strmap_set(parsed_clients, parsed_entry->client_name, parsed_entry); /* Parse client key. */ tok = find_opt_by_keyword(tokens, C_CLIENT_KEY); if (tok) { parsed_entry->client_key = tok->key; tok->key = NULL; /* Prevent free */ } /* Parse descriptor cookie. */ tok = find_by_keyword(tokens, C_DESCRIPTOR_COOKIE); tor_assert(tok->n_args == 1); if (strlen(tok->args[0]) != REND_DESC_COOKIE_LEN_BASE64 + 2) { log_warn(LD_REND, "Descriptor cookie has illegal length: %s", escaped(tok->args[0])); goto err; } /* The size of descriptor_cookie_tmp needs to be REND_DESC_COOKIE_LEN+2, * because a base64 encoding of length 24 does not fit into 16 bytes in all * cases. */ if ((base64_decode(descriptor_cookie_tmp, REND_DESC_COOKIE_LEN+2, tok->args[0], REND_DESC_COOKIE_LEN_BASE64+2+1) != REND_DESC_COOKIE_LEN)) { log_warn(LD_REND, "Descriptor cookie contains illegal characters: " "%s", descriptor_cookie_base64); goto err; } memcpy(parsed_entry->descriptor_cookie, descriptor_cookie_tmp, REND_DESC_COOKIE_LEN); } result = strmap_size(parsed_clients); goto done; err: result = -1; done: /* Free tokens and clear token list. */ SMARTLIST_FOREACH(tokens, directory_token_t *, t, token_free(t)); smartlist_free(tokens); if (area) memarea_drop_all(area); return result; }