/* Copyright (c) 2015, The Tor Project, Inc. */ /* See LICENSE for licensing information */ /** * \file rendcache.c * \brief Hidden service descriptor cache. **/ #include "rendcache.h" #include "config.h" #include "rephist.h" #include "routerlist.h" #include "routerparse.h" /** Map from service id (as generated by rend_get_service_id) to * rend_cache_entry_t. */ static strmap_t *rend_cache = NULL; /** Map from service id to rend_cache_entry_t; only for hidden services. */ static strmap_t *rend_cache_service = NULL; /** Map from descriptor id to rend_cache_entry_t; only for hidden service * directories. */ static digestmap_t *rend_cache_v2_dir = NULL; /** (Client side only) Map from service id to rend_cache_failure_t. This * cache is used to track intro point(IP) failures so we know when to keep * or discard a new descriptor we just fetched. Here is a description of the * cache behavior. * * Everytime tor discards an IP (ex: receives a NACK), we add an entry to * this cache noting the identity digest of the IP and it's failure type for * the service ID. The reason we indexed this cache by service ID is to * differentiate errors that can occur only for a specific service like a * NACK for instance. It applies for one but maybe not for the others. * * Once a service descriptor is fetched and considered valid, each IP is * looked up in this cache and if present, it is discarded from the fetched * descriptor. At the end, all IP(s) in the cache, for a specific service * ID, that were NOT present in the descriptor are removed from this cache. * Which means that if at least one IP was not in this cache, thus usuable, * it's considered a new descriptor so we keep it. Else, if all IPs were in * this cache, we discard the descriptor as it's considered unsuable. * * Once a descriptor is removed from the rend cache or expires, the entry * in this cache is also removed for the service ID. * * This scheme allows us to not realy on the descriptor's timestamp (which * is rounded down to the hour) to know if we have a newer descriptor. We * only rely on the usability of intro points from an internal state. */ static strmap_t *rend_cache_failure = NULL; /** DOCDOC */ static size_t rend_cache_total_allocation = 0; /** Initializes the service descriptor cache. */ void rend_cache_init(void) { rend_cache = strmap_new(); rend_cache_v2_dir = digestmap_new(); rend_cache_service = strmap_new(); rend_cache_failure = strmap_new(); } /** Return the approximate number of bytes needed to hold e. */ static size_t rend_cache_entry_allocation(const rend_cache_entry_t *e) { if (!e) return 0; /* This doesn't count intro_nodes or key size */ return sizeof(*e) + e->len + sizeof(*e->parsed); } /** DOCDOC */ size_t rend_cache_get_total_allocation(void) { return rend_cache_total_allocation; } /** Decrement the total bytes attributed to the rendezvous cache by n. */ static void rend_cache_decrement_allocation(size_t n) { static int have_underflowed = 0; if (rend_cache_total_allocation >= n) { rend_cache_total_allocation -= n; } else { rend_cache_total_allocation = 0; if (! have_underflowed) { have_underflowed = 1; log_warn(LD_BUG, "Underflow in rend_cache_decrement_allocation"); } } } /** Increase the total bytes attributed to the rendezvous cache by n. */ static void rend_cache_increment_allocation(size_t n) { static int have_overflowed = 0; if (rend_cache_total_allocation <= SIZE_MAX - n) { rend_cache_total_allocation += n; } else { rend_cache_total_allocation = SIZE_MAX; if (! have_overflowed) { have_overflowed = 1; log_warn(LD_BUG, "Overflow in rend_cache_increment_allocation"); } } } /** Helper: free a rend cache failure intro object. */ static void rend_cache_failure_intro_entry_free(rend_cache_failure_intro_t *entry) { if (entry == NULL) { return; } tor_free(entry); } /** Allocate a rend cache failure intro object and return it. failure * is set into the object. This function can not fail. */ static rend_cache_failure_intro_t * rend_cache_failure_intro_entry_new(rend_intro_point_failure_t failure) { rend_cache_failure_intro_t *entry = tor_malloc(sizeof(*entry)); entry->failure_type = failure; entry->created_ts = time(NULL); return entry; } /** Helper: free a rend cache failure object. */ static void rend_cache_failure_entry_free(rend_cache_failure_t *entry) { if (entry == NULL) { return; } /* Free and remove every intro failure object. */ DIGESTMAP_FOREACH_MODIFY(entry->intro_failures, key, rend_cache_failure_intro_t *, e) { rend_cache_failure_intro_entry_free(e); MAP_DEL_CURRENT(key); } DIGESTMAP_FOREACH_END; tor_free(entry); } /** Helper: deallocate a rend_cache_failure_t. (Used with strmap_free(), * which requires a function pointer whose argument is void*). */ static void rend_cache_failure_entry_free_(void *entry) { rend_cache_failure_entry_free(entry); } /** Allocate a rend cache failure object and return it. This function can * not fail. */ static rend_cache_failure_t * rend_cache_failure_entry_new(void) { rend_cache_failure_t *entry = tor_malloc(sizeof(*entry)); entry->intro_failures = digestmap_new(); return entry; } /** Remove failure cache entry for the service ID in the given descriptor * desc. */ static void rend_cache_failure_remove(rend_service_descriptor_t *desc) { char service_id[REND_SERVICE_ID_LEN_BASE32 + 1]; rend_cache_failure_t *entry; if (desc == NULL) { return; } if (rend_get_service_id(desc->pk, service_id) < 0) { return; } entry = strmap_get_lc(rend_cache_failure, service_id); if (entry != NULL) { strmap_remove_lc(rend_cache_failure, service_id); rend_cache_failure_entry_free(entry); } } /** Helper: free storage held by a single service descriptor cache entry. */ static void rend_cache_entry_free(rend_cache_entry_t *e) { if (!e) return; rend_cache_decrement_allocation(rend_cache_entry_allocation(e)); /* We are about to remove a descriptor from the cache so remove the entry * in the failure cache. */ rend_cache_failure_remove(e->parsed); rend_service_descriptor_free(e->parsed); tor_free(e->desc); tor_free(e); } /** Helper: deallocate a rend_cache_entry_t. (Used with strmap_free(), which * requires a function pointer whose argument is void*). */ static void rend_cache_entry_free_(void *p) { rend_cache_entry_free(p); } /** Free all storage held by the service descriptor cache. */ void rend_cache_free_all(void) { strmap_free(rend_cache, rend_cache_entry_free_); digestmap_free(rend_cache_v2_dir, rend_cache_entry_free_); strmap_free(rend_cache_service, rend_cache_entry_free_); strmap_free(rend_cache_failure, rend_cache_failure_entry_free_); rend_cache = NULL; rend_cache_v2_dir = NULL; rend_cache_service = NULL; rend_cache_failure = NULL; rend_cache_total_allocation = 0; } /** Remove all entries that re REND_CACHE_FAILURE_MAX_AGE old. This is * called every second. * * We have to clean these regurlarly else if for whatever reasons an hidden * service goes offline and a client tries to connect to it during that * time, a failure entry is created and the client will be unable to connect * for a while even though the service has return online. */ void rend_cache_failure_clean(time_t now) { time_t cutoff = now - REND_CACHE_FAILURE_MAX_AGE; STRMAP_FOREACH_MODIFY(rend_cache_failure, key, rend_cache_failure_t *, ent) { /* Free and remove every intro failure object that match the cutoff. */ DIGESTMAP_FOREACH_MODIFY(ent->intro_failures, ip_key, rend_cache_failure_intro_t *, ip_ent) { if (ip_ent->created_ts < cutoff) { rend_cache_failure_intro_entry_free(ip_ent); MAP_DEL_CURRENT(ip_key); } } DIGESTMAP_FOREACH_END; /* If the entry is now empty of intro point failures, remove it. */ if (digestmap_isempty(ent->intro_failures)) { rend_cache_failure_entry_free(ent); MAP_DEL_CURRENT(key); } } STRMAP_FOREACH_END; } /** Removes all old entries from the service descriptor cache. */ void rend_cache_clean(time_t now) { strmap_iter_t *iter; const char *key; void *val; rend_cache_entry_t *ent; time_t cutoff = now - REND_CACHE_MAX_AGE - REND_CACHE_MAX_SKEW; for (iter = strmap_iter_init(rend_cache); !strmap_iter_done(iter); ) { strmap_iter_get(iter, &key, &val); ent = (rend_cache_entry_t*)val; if (ent->parsed->timestamp < cutoff) { iter = strmap_iter_next_rmv(rend_cache, iter); rend_cache_entry_free(ent); } else { iter = strmap_iter_next(rend_cache, iter); } } } /** Remove ALL entries from the rendezvous service descriptor cache. */ void rend_cache_purge(void) { if (rend_cache) { log_info(LD_REND, "Purging HS descriptor cache"); strmap_free(rend_cache, rend_cache_entry_free_); } rend_cache = strmap_new(); } /** Remove ALL entries from the failure cache. This is also called when a * NEWNYM signal is received. */ void rend_cache_failure_purge(void) { if (rend_cache_failure) { log_info(LD_REND, "Purging HS failure cache"); strmap_free(rend_cache_failure, rend_cache_failure_entry_free_); } rend_cache_failure = strmap_new(); } /** Lookup the rend failure cache using a relay identity digest in * identity and service ID service_id. If found, the intro * failure is set in intro_entry else it stays untouched. Return 1 * iff found else 0. */ static int cache_failure_intro_lookup(const uint8_t *identity, const char *service_id, rend_cache_failure_intro_t **intro_entry) { rend_cache_failure_t *elem; rend_cache_failure_intro_t *intro_elem; tor_assert(rend_cache_failure); if (intro_entry) { *intro_entry = NULL; } /* Lookup descriptor and return it. */ elem = strmap_get_lc(rend_cache_failure, service_id); if (elem == NULL) { goto not_found; } intro_elem = digestmap_get(elem->intro_failures, (char *) identity); if (intro_elem == NULL) { goto not_found; } if (intro_entry) { *intro_entry = intro_elem; } return 1; not_found: return 0; } /** Add an intro point failure to the failure cache using the relay * identity and service ID service_id. Record the * failure in that object. */ static void cache_failure_intro_add(const uint8_t *identity, const char *service_id, rend_intro_point_failure_t failure) { rend_cache_failure_t *fail_entry; rend_cache_failure_intro_t *entry; /* Make sure we have a failure object for this service ID and if not, * create it with this new intro failure entry. */ fail_entry = strmap_get_lc(rend_cache_failure, service_id); if (fail_entry == NULL) { fail_entry = rend_cache_failure_entry_new(); /* Add failure entry to global rend failure cache. */ strmap_set_lc(rend_cache_failure, service_id, fail_entry); } entry = rend_cache_failure_intro_entry_new(failure); digestmap_set(fail_entry->intro_failures, (char *) identity, entry); } /** Using a parsed descriptor desc, check if the introduction points * are present in the failure cache and if so they are removed from the * descriptor and kept into the failure cache. Then, each intro points that * are NOT in the descriptor but in the failure cache for the given * service_id are removed from the failure cache. */ static void validate_intro_point_failure(const rend_service_descriptor_t *desc, const char *service_id) { rend_cache_failure_t *new_entry, *cur_entry; /* New entry for the service ID that will be replacing the one in the * failure cache since we have a new descriptor. In the case where all * intro points are removed, we are assured that the new entry is the same * as the current one. */ new_entry = tor_malloc(sizeof(*new_entry)); new_entry->intro_failures = digestmap_new(); tor_assert(desc); SMARTLIST_FOREACH_BEGIN(desc->intro_nodes, rend_intro_point_t *, intro) { int found; rend_cache_failure_intro_t *entry; const uint8_t *identity = (uint8_t *) intro->extend_info->identity_digest; found = cache_failure_intro_lookup(identity, service_id, &entry); if (found) { /* This intro point is in our cache, discard it from the descriptor * because chances are that it's unusable. */ SMARTLIST_DEL_CURRENT(desc->intro_nodes, intro); rend_intro_point_free(intro); /* Keep it for our new entry. */ digestmap_set(new_entry->intro_failures, (char *) identity, entry); continue; } } SMARTLIST_FOREACH_END(intro); /* Swap the failure entry in the cache and free the current one. */ cur_entry = strmap_get_lc(rend_cache_failure, service_id); if (cur_entry != NULL) { rend_cache_failure_entry_free(cur_entry); } strmap_set_lc(rend_cache_failure, service_id, new_entry); } /** Note down an intro failure in the rend failure cache using the type of * failure in failure for the relay identity digest in * identity and service ID service_id. If an entry already * exists in the cache, the failure type is changed with failure. */ void rend_cache_intro_failure_note(rend_intro_point_failure_t failure, const uint8_t *identity, const char *service_id) { int found; rend_cache_failure_intro_t *entry; found = cache_failure_intro_lookup(identity, service_id, &entry); if (!found) { cache_failure_intro_add(identity, service_id, failure); } else { /* Replace introduction point failure with this one. */ entry->failure_type = failure; } } /** Remove all old v2 descriptors and those for which this hidden service * directory is not responsible for any more. * * If at all possible, remove at least force_remove bytes of data. */ void rend_cache_clean_v2_descs_as_dir(time_t now, size_t force_remove) { digestmap_iter_t *iter; time_t cutoff = now - REND_CACHE_MAX_AGE - REND_CACHE_MAX_SKEW; const int LAST_SERVED_CUTOFF_STEP = 1800; time_t last_served_cutoff = cutoff; size_t bytes_removed = 0; do { for (iter = digestmap_iter_init(rend_cache_v2_dir); !digestmap_iter_done(iter); ) { const char *key; void *val; rend_cache_entry_t *ent; digestmap_iter_get(iter, &key, &val); ent = val; if (ent->parsed->timestamp < cutoff || ent->last_served < last_served_cutoff || !hid_serv_responsible_for_desc_id(key)) { char key_base32[REND_DESC_ID_V2_LEN_BASE32 + 1]; base32_encode(key_base32, sizeof(key_base32), key, DIGEST_LEN); log_info(LD_REND, "Removing descriptor with ID '%s' from cache", safe_str_client(key_base32)); bytes_removed += rend_cache_entry_allocation(ent); iter = digestmap_iter_next_rmv(rend_cache_v2_dir, iter); rend_cache_entry_free(ent); } else { iter = digestmap_iter_next(rend_cache_v2_dir, iter); } } /* In case we didn't remove enough bytes, advance the cutoff a little. */ last_served_cutoff += LAST_SERVED_CUTOFF_STEP; if (last_served_cutoff > now) break; } while (bytes_removed < force_remove); } /** Lookup in the client or service cache the given service ID query for * version. The service argument determines if the lookup should * be from the client cache or the service cache. * * Return 0 if found and if e is non NULL, set it with the entry * found. Else, a negative value is returned and e is untouched. * -EINVAL means that query is not a valid service id. * -ENOENT means that no entry in the cache was found. */ int rend_cache_lookup_entry(const char *query, int version, rend_cache_entry_t **e, rend_cache_type_t cache) { int ret = 0; char key[REND_SERVICE_ID_LEN_BASE32 + 2]; /* \0 */ rend_cache_entry_t *entry = NULL; static const int default_version = 2; tor_assert(rend_cache_service); tor_assert(rend_cache); tor_assert(query); tor_assert(cache); if (!rend_valid_service_id(query)) { ret = -EINVAL; goto end; } switch (version) { case 0: log_warn(LD_REND, "Cache lookup of a v0 renddesc is deprecated."); break; case 2: /* Default is version 2. */ default: if(cache == REND_CACHE_TYPE_SERVICE){ entry = strmap_get_lc(rend_cache_service, query); } else if (cache == REND_CACHE_TYPE_CLIENT) { tor_snprintf(key, sizeof(key), "%d%s", default_version, query); entry = strmap_get_lc(rend_cache, key); } break; } if (!entry) { ret = -ENOENT; goto end; } /* Check descriptor is parsed only if lookup is from client cache */ if(cache == REND_CACHE_TYPE_CLIENT){ tor_assert(entry->parsed && entry->parsed->intro_nodes); } if (e) { *e = entry; } end: return ret; } /** Lookup the v2 service descriptor with base32-encoded desc_id and * copy the pointer to it to *desc. Return 1 on success, 0 on * well-formed-but-not-found, and -1 on failure. */ int rend_cache_lookup_v2_desc_as_dir(const char *desc_id, const char **desc) { rend_cache_entry_t *e; char desc_id_digest[DIGEST_LEN]; tor_assert(rend_cache_v2_dir); if (base32_decode(desc_id_digest, DIGEST_LEN, desc_id, REND_DESC_ID_V2_LEN_BASE32) < 0) { log_fn(LOG_PROTOCOL_WARN, LD_REND, "Rejecting v2 rendezvous descriptor request -- descriptor ID " "contains illegal characters: %s", safe_str(desc_id)); return -1; } /* Lookup descriptor and return. */ e = digestmap_get(rend_cache_v2_dir, desc_id_digest); if (e) { *desc = e->desc; e->last_served = approx_time(); return 1; } return 0; } /** Parse the v2 service descriptor(s) in desc and store it/them to the * local rend cache. Don't attempt to decrypt the included list of introduction * points (as we don't have a descriptor cookie for it). * * If we have a newer descriptor with the same ID, ignore this one. * If we have an older descriptor with the same ID, replace it. * * Return an appropriate rend_cache_store_status_t. */ rend_cache_store_status_t rend_cache_store_v2_desc_as_dir(const char *desc) { const or_options_t *options = get_options(); rend_service_descriptor_t *parsed; char desc_id[DIGEST_LEN]; char *intro_content; size_t intro_size; size_t encoded_size; char desc_id_base32[REND_DESC_ID_V2_LEN_BASE32 + 1]; int number_parsed = 0, number_stored = 0; const char *current_desc = desc; const char *next_desc; rend_cache_entry_t *e; time_t now = time(NULL); tor_assert(rend_cache_v2_dir); tor_assert(desc); if (!hid_serv_acting_as_directory()) { /* Cannot store descs, because we are (currently) not acting as * hidden service directory. */ log_info(LD_REND, "Cannot store descs: Not acting as hs dir"); return RCS_NOTDIR; } while (rend_parse_v2_service_descriptor(&parsed, desc_id, &intro_content, &intro_size, &encoded_size, &next_desc, current_desc, 1) >= 0) { number_parsed++; /* We don't care about the introduction points. */ tor_free(intro_content); /* For pretty log statements. */ base32_encode(desc_id_base32, sizeof(desc_id_base32), desc_id, DIGEST_LEN); /* Is desc ID in the range that we are (directly or indirectly) responsible * for? */ if (!hid_serv_responsible_for_desc_id(desc_id)) { log_info(LD_REND, "Service descriptor with desc ID %s is not in " "interval that we are responsible for.", safe_str_client(desc_id_base32)); goto skip; } /* Is descriptor too old? */ if (parsed->timestamp < now - REND_CACHE_MAX_AGE-REND_CACHE_MAX_SKEW) { log_info(LD_REND, "Service descriptor with desc ID %s is too old.", safe_str(desc_id_base32)); goto skip; } /* Is descriptor too far in the future? */ if (parsed->timestamp > now + REND_CACHE_MAX_SKEW) { log_info(LD_REND, "Service descriptor with desc ID %s is too far in the " "future.", safe_str(desc_id_base32)); goto skip; } /* Do we already have a newer descriptor? */ e = digestmap_get(rend_cache_v2_dir, desc_id); if (e && e->parsed->timestamp > parsed->timestamp) { log_info(LD_REND, "We already have a newer service descriptor with the " "same desc ID %s and version.", safe_str(desc_id_base32)); goto skip; } /* Do we already have this descriptor? */ if (e && !strcmp(desc, e->desc)) { log_info(LD_REND, "We already have this service descriptor with desc " "ID %s.", safe_str(desc_id_base32)); goto skip; } /* Store received descriptor. */ if (!e) { e = tor_malloc_zero(sizeof(rend_cache_entry_t)); digestmap_set(rend_cache_v2_dir, desc_id, e); /* Treat something just uploaded as having been served a little * while ago, so that flooding with new descriptors doesn't help * too much. */ e->last_served = approx_time() - 3600; } else { rend_cache_decrement_allocation(rend_cache_entry_allocation(e)); rend_service_descriptor_free(e->parsed); tor_free(e->desc); } e->parsed = parsed; e->desc = tor_strndup(current_desc, encoded_size); e->len = encoded_size; rend_cache_increment_allocation(rend_cache_entry_allocation(e)); log_info(LD_REND, "Successfully stored service descriptor with desc ID " "'%s' and len %d.", safe_str(desc_id_base32), (int)encoded_size); /* Statistics: Note down this potentially new HS. */ if (options->HiddenServiceStatistics) { rep_hist_stored_maybe_new_hs(e->parsed->pk); } number_stored++; goto advance; skip: rend_service_descriptor_free(parsed); advance: /* advance to next descriptor, if available. */ current_desc = next_desc; /* check if there is a next descriptor. */ if (!current_desc || strcmpstart(current_desc, "rendezvous-service-descriptor ")) break; } if (!number_parsed) { log_info(LD_REND, "Could not parse any descriptor."); return RCS_BADDESC; } log_info(LD_REND, "Parsed %d and added %d descriptor%s.", number_parsed, number_stored, number_stored != 1 ? "s" : ""); return RCS_OKAY; } /** Parse the v2 service descriptor in desc and store it to the * local service rend cache. Don't attempt to decrypt the included list of * introduction points. * * If we have a newer descriptor with the same ID, ignore this one. * If we have an older descriptor with the same ID, replace it. * * Return an appropriate rend_cache_store_status_t. */ rend_cache_store_status_t rend_cache_store_v2_desc_as_service(const char *desc) { rend_service_descriptor_t *parsed = NULL; char desc_id[DIGEST_LEN]; char *intro_content = NULL; size_t intro_size; size_t encoded_size; const char *next_desc; char service_id[REND_SERVICE_ID_LEN_BASE32+1]; rend_cache_entry_t *e; rend_cache_store_status_t retval = RCS_BADDESC; tor_assert(rend_cache_service); tor_assert(desc); /* Parse the descriptor. */ if (rend_parse_v2_service_descriptor(&parsed, desc_id, &intro_content, &intro_size, &encoded_size, &next_desc, desc, 0) < 0) { log_warn(LD_REND, "Could not parse descriptor."); goto err; } /* Compute service ID from public key. */ if (rend_get_service_id(parsed->pk, service_id)<0) { log_warn(LD_REND, "Couldn't compute service ID."); goto err; } /* Do we already have a newer descriptor? Allow new descriptors with a rounded timestamp equal to or newer than the current descriptor */ e = (rend_cache_entry_t*) strmap_get_lc(rend_cache_service, service_id); if (e && e->parsed->timestamp > parsed->timestamp) { log_info(LD_REND, "We already have a newer service descriptor for " "service ID %s.", safe_str_client(service_id)); goto okay; } /* We don't care about the introduction points. */ tor_free(intro_content); if (!e) { e = tor_malloc_zero(sizeof(rend_cache_entry_t)); strmap_set_lc(rend_cache_service, service_id, e); } else { rend_cache_decrement_allocation(rend_cache_entry_allocation(e)); rend_service_descriptor_free(e->parsed); tor_free(e->desc); } e->parsed = parsed; e->desc = tor_malloc_zero(encoded_size + 1); strlcpy(e->desc, desc, encoded_size + 1); e->len = encoded_size; rend_cache_increment_allocation(rend_cache_entry_allocation(e)); log_debug(LD_REND,"Successfully stored rend desc '%s', len %d.", safe_str_client(service_id), (int)encoded_size); return RCS_OKAY; okay: retval = RCS_OKAY; err: rend_service_descriptor_free(parsed); tor_free(intro_content); return retval; } /** Parse the v2 service descriptor in desc, decrypt the included list * of introduction points with descriptor_cookie (which may also be * NULL if decryption is not necessary), and store the descriptor to * the local cache under its version and service id. * * If we have a newer v2 descriptor with the same ID, ignore this one. * If we have an older descriptor with the same ID, replace it. * If the descriptor's service ID does not match * rend_query-\>onion_address, reject it. * * If the descriptor's descriptor ID doesn't match desc_id_base32, * reject it. * * Return an appropriate rend_cache_store_status_t. If entry is not NULL, * set it with the cache entry pointer of the descriptor. */ rend_cache_store_status_t rend_cache_store_v2_desc_as_client(const char *desc, const char *desc_id_base32, const rend_data_t *rend_query, rend_cache_entry_t **entry) { /*XXXX this seems to have a bit of duplicate code with * rend_cache_store_v2_desc_as_dir(). Fix that. */ /* Though having similar elements, both functions were separated on * purpose: * - dirs don't care about encoded/encrypted introduction points, clients * do. * - dirs store descriptors in a separate cache by descriptor ID, whereas * clients store them by service ID; both caches are different data * structures and have different access methods. * - dirs store a descriptor only if they are responsible for its ID, * clients do so in every way (because they have requested it before). * - dirs can process multiple concatenated descriptors which is required * for replication, whereas clients only accept a single descriptor. * Thus, combining both methods would result in a lot of if statements * which probably would not improve, but worsen code readability. -KL */ rend_service_descriptor_t *parsed = NULL; char desc_id[DIGEST_LEN]; char *intro_content = NULL; size_t intro_size; size_t encoded_size; const char *next_desc; time_t now = time(NULL); char key[REND_SERVICE_ID_LEN_BASE32+2]; char service_id[REND_SERVICE_ID_LEN_BASE32+1]; char want_desc_id[DIGEST_LEN]; rend_cache_entry_t *e; rend_cache_store_status_t retval = RCS_BADDESC; tor_assert(rend_cache); tor_assert(desc); tor_assert(desc_id_base32); memset(want_desc_id, 0, sizeof(want_desc_id)); if (entry) { *entry = NULL; } if (base32_decode(want_desc_id, sizeof(want_desc_id), desc_id_base32, strlen(desc_id_base32)) != 0) { log_warn(LD_BUG, "Couldn't decode base32 %s for descriptor id.", escaped_safe_str_client(desc_id_base32)); goto err; } /* Parse the descriptor. */ if (rend_parse_v2_service_descriptor(&parsed, desc_id, &intro_content, &intro_size, &encoded_size, &next_desc, desc, 0) < 0) { log_warn(LD_REND, "Could not parse descriptor."); goto err; } /* Compute service ID from public key. */ if (rend_get_service_id(parsed->pk, service_id)<0) { log_warn(LD_REND, "Couldn't compute service ID."); goto err; } if (rend_query->onion_address[0] != '\0' && strcmp(rend_query->onion_address, service_id)) { log_warn(LD_REND, "Received service descriptor for service ID %s; " "expected descriptor for service ID %s.", service_id, safe_str(rend_query->onion_address)); goto err; } if (tor_memneq(desc_id, want_desc_id, DIGEST_LEN)) { log_warn(LD_REND, "Received service descriptor for %s with incorrect " "descriptor ID.", service_id); goto err; } /* Decode/decrypt introduction points. */ if (intro_content && intro_size > 0) { int n_intro_points; if (rend_query->auth_type != REND_NO_AUTH && !tor_mem_is_zero(rend_query->descriptor_cookie, sizeof(rend_query->descriptor_cookie))) { char *ipos_decrypted = NULL; size_t ipos_decrypted_size; if (rend_decrypt_introduction_points(&ipos_decrypted, &ipos_decrypted_size, rend_query->descriptor_cookie, intro_content, intro_size) < 0) { log_warn(LD_REND, "Failed to decrypt introduction points. We are " "probably unable to parse the encoded introduction points."); } else { /* Replace encrypted with decrypted introduction points. */ log_info(LD_REND, "Successfully decrypted introduction points."); tor_free(intro_content); intro_content = ipos_decrypted; intro_size = ipos_decrypted_size; } } n_intro_points = rend_parse_introduction_points(parsed, intro_content, intro_size); if (n_intro_points <= 0) { log_warn(LD_REND, "Failed to parse introduction points. Either the " "service has published a corrupt descriptor or you have " "provided invalid authorization data."); goto err; } else if (n_intro_points > MAX_INTRO_POINTS) { log_warn(LD_REND, "Found too many introduction points on a hidden " "service descriptor for %s. This is probably a (misguided) " "attempt to improve reliability, but it could also be an " "attempt to do a guard enumeration attack. Rejecting.", safe_str_client(service_id)); goto err; } } else { log_info(LD_REND, "Descriptor does not contain any introduction points."); parsed->intro_nodes = smartlist_new(); } /* We don't need the encoded/encrypted introduction points any longer. */ tor_free(intro_content); /* Is descriptor too old? */ if (parsed->timestamp < now - REND_CACHE_MAX_AGE-REND_CACHE_MAX_SKEW) { log_warn(LD_REND, "Service descriptor with service ID %s is too old.", safe_str_client(service_id)); goto err; } /* Is descriptor too far in the future? */ if (parsed->timestamp > now + REND_CACHE_MAX_SKEW) { log_warn(LD_REND, "Service descriptor with service ID %s is too far in " "the future.", safe_str_client(service_id)); goto err; } /* Do we have the same exact copy already in our cache? */ tor_snprintf(key, sizeof(key), "2%s", service_id); e = (rend_cache_entry_t*) strmap_get_lc(rend_cache, key); if (e && !strcmp(desc, e->desc)) { log_info(LD_REND,"We already have this service descriptor %s.", safe_str_client(service_id)); goto okay; } /* Verify that we are not replacing an older descriptor. It's important to * avoid an evil HSDir serving old descriptor. We validate if the * timestamp is greater than and not equal because it's a rounded down * timestamp to the hour so if the descriptor changed in the same hour, * the rend cache failure will tells us if we have a new descriptor. */ if (e && e->parsed->timestamp > parsed->timestamp) { log_info(LD_REND, "We already have a new enough service descriptor for " "service ID %s with the same desc ID and version.", safe_str_client(service_id)); goto okay; } /* Lookup our failure cache for intro point that might be unsuable. */ validate_intro_point_failure(parsed, service_id); /* It's now possible that our intro point list is empty, this means that * this descriptor is useless to us because intro points have all failed * somehow before. Discard the descriptor. */ if (smartlist_len(parsed->intro_nodes) == 0) { log_info(LD_REND, "Service descriptor with service ID %s, every " "intro points are unusable. Discarding it.", safe_str_client(service_id)); goto err; } /* Now either purge the current one and replace it's content or create a * new one and add it to the rend cache. */ if (!e) { e = tor_malloc_zero(sizeof(rend_cache_entry_t)); strmap_set_lc(rend_cache, key, e); } else { rend_cache_decrement_allocation(rend_cache_entry_allocation(e)); rend_cache_failure_remove(e->parsed); rend_service_descriptor_free(e->parsed); tor_free(e->desc); } e->parsed = parsed; e->desc = tor_malloc_zero(encoded_size + 1); strlcpy(e->desc, desc, encoded_size + 1); e->len = encoded_size; rend_cache_increment_allocation(rend_cache_entry_allocation(e)); log_debug(LD_REND,"Successfully stored rend desc '%s', len %d.", safe_str_client(service_id), (int)encoded_size); if (entry) { *entry = e; } return RCS_OKAY; okay: if (entry) { *entry = e; } retval = RCS_OKAY; err: rend_service_descriptor_free(parsed); tor_free(intro_content); return retval; }