/* Copyright (c) 2016-2018, The Tor Project, Inc. */ /* See LICENSE for licensing information */ /** * \file hs_cache.c * \brief Handle hidden service descriptor caches. **/ /* For unit tests.*/ #define HS_CACHE_PRIVATE #include "or.h" #include "config.h" #include "crypto_util.h" #include "hs_ident.h" #include "hs_common.h" #include "hs_client.h" #include "hs_descriptor.h" #include "networkstatus.h" #include "rendcache.h" #include "hs_cache.h" #include "networkstatus_st.h" static int cached_client_descriptor_has_expired(time_t now, const hs_cache_client_descriptor_t *cached_desc); /********************** Directory HS cache ******************/ /* Directory descriptor cache. Map indexed by blinded key. */ static digest256map_t *hs_cache_v3_dir; /* Remove a given descriptor from our cache. */ static void remove_v3_desc_as_dir(const hs_cache_dir_descriptor_t *desc) { tor_assert(desc); digest256map_remove(hs_cache_v3_dir, desc->key); } /* Store a given descriptor in our cache. */ static void store_v3_desc_as_dir(hs_cache_dir_descriptor_t *desc) { tor_assert(desc); digest256map_set(hs_cache_v3_dir, desc->key, desc); } /* Query our cache and return the entry or NULL if not found. */ static hs_cache_dir_descriptor_t * lookup_v3_desc_as_dir(const uint8_t *key) { tor_assert(key); return digest256map_get(hs_cache_v3_dir, key); } #define cache_dir_desc_free(val) \ FREE_AND_NULL(hs_cache_dir_descriptor_t, cache_dir_desc_free_, (val)) /* Free a directory descriptor object. */ static void cache_dir_desc_free_(hs_cache_dir_descriptor_t *desc) { if (desc == NULL) { return; } hs_desc_plaintext_data_free(desc->plaintext_data); tor_free(desc->encoded_desc); tor_free(desc); } /* Helper function: Use by the free all function using the digest256map * interface to cache entries. */ static void cache_dir_desc_free_void(void *ptr) { cache_dir_desc_free_(ptr); } /* Create a new directory cache descriptor object from a encoded descriptor. * On success, return the heap-allocated cache object, otherwise return NULL if * we can't decode the descriptor. */ static hs_cache_dir_descriptor_t * cache_dir_desc_new(const char *desc) { hs_cache_dir_descriptor_t *dir_desc; tor_assert(desc); dir_desc = tor_malloc_zero(sizeof(hs_cache_dir_descriptor_t)); dir_desc->plaintext_data = tor_malloc_zero(sizeof(hs_desc_plaintext_data_t)); dir_desc->encoded_desc = tor_strdup(desc); if (hs_desc_decode_plaintext(desc, dir_desc->plaintext_data) < 0) { log_debug(LD_DIR, "Unable to decode descriptor. Rejecting."); goto err; } /* The blinded pubkey is the indexed key. */ dir_desc->key = dir_desc->plaintext_data->blinded_pubkey.pubkey; dir_desc->created_ts = time(NULL); return dir_desc; err: cache_dir_desc_free(dir_desc); return NULL; } /* Return the size of a cache entry in bytes. */ static size_t cache_get_dir_entry_size(const hs_cache_dir_descriptor_t *entry) { return (sizeof(*entry) + hs_desc_plaintext_obj_size(entry->plaintext_data) + strlen(entry->encoded_desc)); } /* Try to store a valid version 3 descriptor in the directory cache. Return 0 * on success else a negative value is returned indicating that we have a * newer version in our cache. On error, caller is responsible to free the * given descriptor desc. */ static int cache_store_v3_as_dir(hs_cache_dir_descriptor_t *desc) { hs_cache_dir_descriptor_t *cache_entry; tor_assert(desc); /* Verify if we have an entry in the cache for that key and if yes, check * if we should replace it? */ cache_entry = lookup_v3_desc_as_dir(desc->key); if (cache_entry != NULL) { /* Only replace descriptor if revision-counter is greater than the one * in our cache */ if (cache_entry->plaintext_data->revision_counter >= desc->plaintext_data->revision_counter) { log_info(LD_REND, "Descriptor revision counter in our cache is " "greater or equal than the one we received (%d/%d). " "Rejecting!", (int)cache_entry->plaintext_data->revision_counter, (int)desc->plaintext_data->revision_counter); goto err; } /* We now know that the descriptor we just received is a new one so * remove the entry we currently have from our cache so we can then * store the new one. */ remove_v3_desc_as_dir(cache_entry); rend_cache_decrement_allocation(cache_get_dir_entry_size(cache_entry)); cache_dir_desc_free(cache_entry); } /* Store the descriptor we just got. We are sure here that either we * don't have the entry or we have a newer descriptor and the old one * has been removed from the cache. */ store_v3_desc_as_dir(desc); /* Update our total cache size with this entry for the OOM. This uses the * old HS protocol cache subsystem for which we are tied with. */ rend_cache_increment_allocation(cache_get_dir_entry_size(desc)); /* XXX: Update HS statistics. We should have specific stats for v3. */ return 0; err: return -1; } /* Using the query which is the base64 encoded blinded key of a version 3 * descriptor, lookup in our directory cache the entry. If found, 1 is * returned and desc_out is populated with a newly allocated string being the * encoded descriptor. If not found, 0 is returned and desc_out is untouched. * On error, a negative value is returned and desc_out is untouched. */ static int cache_lookup_v3_as_dir(const char *query, const char **desc_out) { int found = 0; ed25519_public_key_t blinded_key; const hs_cache_dir_descriptor_t *entry; tor_assert(query); /* Decode blinded key using the given query value. */ if (ed25519_public_from_base64(&blinded_key, query) < 0) { log_info(LD_REND, "Unable to decode the v3 HSDir query %s.", safe_str_client(query)); goto err; } entry = lookup_v3_desc_as_dir(blinded_key.pubkey); if (entry != NULL) { found = 1; if (desc_out) { *desc_out = entry->encoded_desc; } } return found; err: return -1; } /* Clean the v3 cache by removing any entry that has expired using the * global_cutoff value. If global_cutoff is 0, the cleaning * process will use the lifetime found in the plaintext data section. Return * the number of bytes cleaned. */ STATIC size_t cache_clean_v3_as_dir(time_t now, time_t global_cutoff) { size_t bytes_removed = 0; /* Code flow error if this ever happens. */ tor_assert(global_cutoff >= 0); if (!hs_cache_v3_dir) { /* No cache to clean. Just return. */ return 0; } DIGEST256MAP_FOREACH_MODIFY(hs_cache_v3_dir, key, hs_cache_dir_descriptor_t *, entry) { size_t entry_size; time_t cutoff = global_cutoff; if (!cutoff) { /* Cutoff is the lifetime of the entry found in the descriptor. */ cutoff = now - entry->plaintext_data->lifetime_sec; } /* If the entry has been created _after_ the cutoff, not expired so * continue to the next entry in our v3 cache. */ if (entry->created_ts > cutoff) { continue; } /* Here, our entry has expired, remove and free. */ MAP_DEL_CURRENT(key); entry_size = cache_get_dir_entry_size(entry); bytes_removed += entry_size; /* Entry is not in the cache anymore, destroy it. */ cache_dir_desc_free(entry); /* Update our cache entry allocation size for the OOM. */ rend_cache_decrement_allocation(entry_size); /* Logging. */ { char key_b64[BASE64_DIGEST256_LEN + 1]; digest256_to_base64(key_b64, (const char *) key); log_info(LD_REND, "Removing v3 descriptor '%s' from HSDir cache", safe_str_client(key_b64)); } } DIGEST256MAP_FOREACH_END; return bytes_removed; } /* Given an encoded descriptor, store it in the directory cache depending on * which version it is. Return a negative value on error. On success, 0 is * returned. */ int hs_cache_store_as_dir(const char *desc) { hs_cache_dir_descriptor_t *dir_desc = NULL; tor_assert(desc); /* Create a new cache object. This can fail if the descriptor plaintext data * is unparseable which in this case a log message will be triggered. */ dir_desc = cache_dir_desc_new(desc); if (dir_desc == NULL) { goto err; } /* Call the right function against the descriptor version. At this point, * we are sure that the descriptor's version is supported else the * decoding would have failed. */ switch (dir_desc->plaintext_data->version) { case HS_VERSION_THREE: default: if (cache_store_v3_as_dir(dir_desc) < 0) { goto err; } break; } return 0; err: cache_dir_desc_free(dir_desc); return -1; } /* Using the query, lookup in our directory cache the entry. If found, 1 is * returned and desc_out is populated with a newly allocated string being * the encoded descriptor. If not found, 0 is returned and desc_out is * untouched. On error, a negative value is returned and desc_out is * untouched. */ int hs_cache_lookup_as_dir(uint32_t version, const char *query, const char **desc_out) { int found; tor_assert(query); /* This should never be called with an unsupported version. */ tor_assert(hs_desc_is_supported_version(version)); switch (version) { case HS_VERSION_THREE: default: found = cache_lookup_v3_as_dir(query, desc_out); break; } return found; } /* Clean all directory caches using the current time now. */ void hs_cache_clean_as_dir(time_t now) { time_t cutoff; /* Start with v2 cache cleaning. */ cutoff = now - rend_cache_max_entry_lifetime(); rend_cache_clean_v2_descs_as_dir(cutoff); /* Now, clean the v3 cache. Set the cutoff to 0 telling the cleanup function * to compute the cutoff by itself using the lifetime value. */ cache_clean_v3_as_dir(now, 0); } /********************** Client-side HS cache ******************/ /* Client-side HS descriptor cache. Map indexed by service identity key. */ static digest256map_t *hs_cache_v3_client; /* Client-side introduction point state cache. Map indexed by service public * identity key (onion address). It contains hs_cache_client_intro_state_t * objects all related to a specific service. */ static digest256map_t *hs_cache_client_intro_state; /* Return the size of a client cache entry in bytes. */ static size_t cache_get_client_entry_size(const hs_cache_client_descriptor_t *entry) { return sizeof(*entry) + strlen(entry->encoded_desc) + hs_desc_obj_size(entry->desc); } /* Remove a given descriptor from our cache. */ static void remove_v3_desc_as_client(const hs_cache_client_descriptor_t *desc) { tor_assert(desc); digest256map_remove(hs_cache_v3_client, desc->key.pubkey); /* Update cache size with this entry for the OOM handler. */ rend_cache_decrement_allocation(cache_get_client_entry_size(desc)); } /* Store a given descriptor in our cache. */ static void store_v3_desc_as_client(hs_cache_client_descriptor_t *desc) { tor_assert(desc); digest256map_set(hs_cache_v3_client, desc->key.pubkey, desc); /* Update cache size with this entry for the OOM handler. */ rend_cache_increment_allocation(cache_get_client_entry_size(desc)); } /* Query our cache and return the entry or NULL if not found or if expired. */ STATIC hs_cache_client_descriptor_t * lookup_v3_desc_as_client(const uint8_t *key) { time_t now = approx_time(); hs_cache_client_descriptor_t *cached_desc; tor_assert(key); /* Do the lookup */ cached_desc = digest256map_get(hs_cache_v3_client, key); if (!cached_desc) { return NULL; } /* Don't return expired entries */ if (cached_client_descriptor_has_expired(now, cached_desc)) { return NULL; } return cached_desc; } /* Parse the encoded descriptor in desc_str using * service_identity_pk to decrypt it first. * * If everything goes well, allocate and return a new * hs_cache_client_descriptor_t object. In case of error, return NULL. */ static hs_cache_client_descriptor_t * cache_client_desc_new(const char *desc_str, const ed25519_public_key_t *service_identity_pk) { hs_descriptor_t *desc = NULL; hs_cache_client_descriptor_t *client_desc = NULL; tor_assert(desc_str); tor_assert(service_identity_pk); /* Decode the descriptor we just fetched. */ if (hs_client_decode_descriptor(desc_str, service_identity_pk, &desc) < 0) { goto end; } tor_assert(desc); /* All is good: make a cache object for this descriptor */ client_desc = tor_malloc_zero(sizeof(hs_cache_client_descriptor_t)); ed25519_pubkey_copy(&client_desc->key, service_identity_pk); /* Set expiration time for this cached descriptor to be the start of the next * time period since that's when clients need to start using the next blinded * pk of the service (and hence will need its next descriptor). */ client_desc->expiration_ts = hs_get_start_time_of_next_time_period(0); client_desc->desc = desc; client_desc->encoded_desc = tor_strdup(desc_str); end: return client_desc; } #define cache_client_desc_free(val) \ FREE_AND_NULL(hs_cache_client_descriptor_t, cache_client_desc_free_, (val)) /** Free memory allocated by desc. */ static void cache_client_desc_free_(hs_cache_client_descriptor_t *desc) { if (desc == NULL) { return; } hs_descriptor_free(desc->desc); memwipe(&desc->key, 0, sizeof(desc->key)); memwipe(desc->encoded_desc, 0, strlen(desc->encoded_desc)); tor_free(desc->encoded_desc); tor_free(desc); } /** Helper function: Use by the free all function to clear the client cache */ static void cache_client_desc_free_void(void *ptr) { hs_cache_client_descriptor_t *desc = ptr; cache_client_desc_free(desc); } /* Return a newly allocated and initialized hs_cache_intro_state_t object. */ static hs_cache_intro_state_t * cache_intro_state_new(void) { hs_cache_intro_state_t *state = tor_malloc_zero(sizeof(*state)); state->created_ts = approx_time(); return state; } #define cache_intro_state_free(val) \ FREE_AND_NULL(hs_cache_intro_state_t, cache_intro_state_free_, (val)) /* Free an hs_cache_intro_state_t object. */ static void cache_intro_state_free_(hs_cache_intro_state_t *state) { tor_free(state); } /* Helper function: use by the free all function. */ static void cache_intro_state_free_void(void *state) { cache_intro_state_free_(state); } /* Return a newly allocated and initialized hs_cache_client_intro_state_t * object. */ static hs_cache_client_intro_state_t * cache_client_intro_state_new(void) { hs_cache_client_intro_state_t *cache = tor_malloc_zero(sizeof(*cache)); cache->intro_points = digest256map_new(); return cache; } #define cache_client_intro_state_free(val) \ FREE_AND_NULL(hs_cache_client_intro_state_t, \ cache_client_intro_state_free_, (val)) /* Free a cache client intro state object. */ static void cache_client_intro_state_free_(hs_cache_client_intro_state_t *cache) { if (cache == NULL) { return; } digest256map_free(cache->intro_points, cache_intro_state_free_void); tor_free(cache); } /* Helper function: use by the free all function. */ static void cache_client_intro_state_free_void(void *entry) { cache_client_intro_state_free_(entry); } /* For the given service identity key service_pk and an introduction * authentication key auth_key, lookup the intro state object. Return 1 if * found and put it in entry if not NULL. Return 0 if not found and entry is * untouched. */ static int cache_client_intro_state_lookup(const ed25519_public_key_t *service_pk, const ed25519_public_key_t *auth_key, hs_cache_intro_state_t **entry) { hs_cache_intro_state_t *state; hs_cache_client_intro_state_t *cache; tor_assert(service_pk); tor_assert(auth_key); /* Lookup the intro state cache for this service key. */ cache = digest256map_get(hs_cache_client_intro_state, service_pk->pubkey); if (cache == NULL) { goto not_found; } /* From the cache we just found for the service, lookup in the introduction * points map for the given authentication key. */ state = digest256map_get(cache->intro_points, auth_key->pubkey); if (state == NULL) { goto not_found; } if (entry) { *entry = state; } return 1; not_found: return 0; } /* Note the given failure in state. */ static void cache_client_intro_state_note(hs_cache_intro_state_t *state, rend_intro_point_failure_t failure) { tor_assert(state); switch (failure) { case INTRO_POINT_FAILURE_GENERIC: state->error = 1; break; case INTRO_POINT_FAILURE_TIMEOUT: state->timed_out = 1; break; case INTRO_POINT_FAILURE_UNREACHABLE: state->unreachable_count++; break; default: tor_assert_nonfatal_unreached(); return; } } /* For the given service identity key service_pk and an introduction * authentication key auth_key, add an entry in the client intro state cache * If no entry exists for the service, it will create one. If state is non * NULL, it will point to the new intro state entry. */ static void cache_client_intro_state_add(const ed25519_public_key_t *service_pk, const ed25519_public_key_t *auth_key, hs_cache_intro_state_t **state) { hs_cache_intro_state_t *entry, *old_entry; hs_cache_client_intro_state_t *cache; tor_assert(service_pk); tor_assert(auth_key); /* Lookup the state cache for this service key. */ cache = digest256map_get(hs_cache_client_intro_state, service_pk->pubkey); if (cache == NULL) { cache = cache_client_intro_state_new(); digest256map_set(hs_cache_client_intro_state, service_pk->pubkey, cache); } entry = cache_intro_state_new(); old_entry = digest256map_set(cache->intro_points, auth_key->pubkey, entry); /* This should never happened because the code flow is to lookup the entry * before adding it. But, just in case, non fatal assert and free it. */ tor_assert_nonfatal(old_entry == NULL); tor_free(old_entry); if (state) { *state = entry; } } /* Remove every intro point state entry from cache that has been created * before or at the cutoff. */ static void cache_client_intro_state_clean(time_t cutoff, hs_cache_client_intro_state_t *cache) { tor_assert(cache); DIGEST256MAP_FOREACH_MODIFY(cache->intro_points, key, hs_cache_intro_state_t *, entry) { if (entry->created_ts <= cutoff) { cache_intro_state_free(entry); MAP_DEL_CURRENT(key); } } DIGEST256MAP_FOREACH_END; } /* Return true iff no intro points are in this cache. */ static int cache_client_intro_state_is_empty(const hs_cache_client_intro_state_t *cache) { return digest256map_isempty(cache->intro_points); } /** Check whether client_desc is useful for us, and store it in the * client-side HS cache if so. The client_desc is freed if we already have a * fresher (higher revision counter count) in the cache. */ static int cache_store_as_client(hs_cache_client_descriptor_t *client_desc) { hs_cache_client_descriptor_t *cache_entry; /* TODO: Heavy code duplication with cache_store_as_dir(). Consider * refactoring and uniting! */ tor_assert(client_desc); /* Check if we already have a descriptor from this HS in cache. If we do, * check if this descriptor is newer than the cached one */ cache_entry = lookup_v3_desc_as_client(client_desc->key.pubkey); if (cache_entry != NULL) { /* If we have an entry in our cache that has a revision counter greater * than the one we just fetched, discard the one we fetched. */ if (cache_entry->desc->plaintext_data.revision_counter > client_desc->desc->plaintext_data.revision_counter) { cache_client_desc_free(client_desc); goto done; } /* Remove old entry. Make space for the new one! */ remove_v3_desc_as_client(cache_entry); cache_client_desc_free(cache_entry); } /* Store descriptor in cache */ store_v3_desc_as_client(client_desc); done: return 0; } /* Return true iff the cached client descriptor at cached_descexpiration_ts <= ns->valid_after) { return 1; } return 0; } /* clean the client cache using now as the current time. Return the total size * of removed bytes from the cache. */ static size_t cache_clean_v3_as_client(time_t now) { size_t bytes_removed = 0; if (!hs_cache_v3_client) { /* No cache to clean. Just return. */ return 0; } DIGEST256MAP_FOREACH_MODIFY(hs_cache_v3_client, key, hs_cache_client_descriptor_t *, entry) { size_t entry_size; /* If the entry has not expired, continue to the next cached entry */ if (!cached_client_descriptor_has_expired(now, entry)) { continue; } /* Here, our entry has expired, remove and free. */ MAP_DEL_CURRENT(key); entry_size = cache_get_client_entry_size(entry); bytes_removed += entry_size; /* Entry is not in the cache anymore, destroy it. */ cache_client_desc_free(entry); /* Update our OOM. We didn't use the remove() function because we are in * a loop so we have to explicitly decrement. */ rend_cache_decrement_allocation(entry_size); /* Logging. */ { char key_b64[BASE64_DIGEST256_LEN + 1]; digest256_to_base64(key_b64, (const char *) key); log_info(LD_REND, "Removing hidden service v3 descriptor '%s' " "from client cache", safe_str_client(key_b64)); } } DIGEST256MAP_FOREACH_END; return bytes_removed; } /** Public API: Given the HS ed25519 identity public key in key, return * its HS encoded descriptor if it's stored in our cache, or NULL if not. */ const char * hs_cache_lookup_encoded_as_client(const ed25519_public_key_t *key) { hs_cache_client_descriptor_t *cached_desc = NULL; tor_assert(key); cached_desc = lookup_v3_desc_as_client(key->pubkey); if (cached_desc) { tor_assert(cached_desc->encoded_desc); return cached_desc->encoded_desc; } return NULL; } /** Public API: Given the HS ed25519 identity public key in key, return * its HS descriptor if it's stored in our cache, or NULL if not. */ const hs_descriptor_t * hs_cache_lookup_as_client(const ed25519_public_key_t *key) { hs_cache_client_descriptor_t *cached_desc = NULL; tor_assert(key); cached_desc = lookup_v3_desc_as_client(key->pubkey); if (cached_desc) { tor_assert(cached_desc->desc); return cached_desc->desc; } return NULL; } /** Public API: Given an encoded descriptor, store it in the client HS * cache. Return -1 on error, 0 on success .*/ int hs_cache_store_as_client(const char *desc_str, const ed25519_public_key_t *identity_pk) { hs_cache_client_descriptor_t *client_desc = NULL; tor_assert(desc_str); tor_assert(identity_pk); /* Create client cache descriptor object */ client_desc = cache_client_desc_new(desc_str, identity_pk); if (!client_desc) { log_warn(LD_GENERAL, "Failed to parse received descriptor %s.", escaped(desc_str)); goto err; } /* Push it to the cache */ if (cache_store_as_client(client_desc) < 0) { goto err; } return 0; err: cache_client_desc_free(client_desc); return -1; } /* Clean all client caches using the current time now. */ void hs_cache_clean_as_client(time_t now) { /* Start with v2 cache cleaning. */ rend_cache_clean(now, REND_CACHE_TYPE_CLIENT); /* Now, clean the v3 cache. Set the cutoff to 0 telling the cleanup function * to compute the cutoff by itself using the lifetime value. */ cache_clean_v3_as_client(now); } /* Purge the client descriptor cache. */ void hs_cache_purge_as_client(void) { DIGEST256MAP_FOREACH_MODIFY(hs_cache_v3_client, key, hs_cache_client_descriptor_t *, entry) { size_t entry_size = cache_get_client_entry_size(entry); MAP_DEL_CURRENT(key); cache_client_desc_free(entry); /* Update our OOM. We didn't use the remove() function because we are in * a loop so we have to explicitly decrement. */ rend_cache_decrement_allocation(entry_size); } DIGEST256MAP_FOREACH_END; log_info(LD_REND, "Hidden service client descriptor cache purged."); } /* For a given service identity public key and an introduction authentication * key, note the given failure in the client intro state cache. */ void hs_cache_client_intro_state_note(const ed25519_public_key_t *service_pk, const ed25519_public_key_t *auth_key, rend_intro_point_failure_t failure) { int found; hs_cache_intro_state_t *entry; tor_assert(service_pk); tor_assert(auth_key); found = cache_client_intro_state_lookup(service_pk, auth_key, &entry); if (!found) { /* Create a new entry and add it to the cache. */ cache_client_intro_state_add(service_pk, auth_key, &entry); } /* Note down the entry. */ cache_client_intro_state_note(entry, failure); } /* For a given service identity public key and an introduction authentication * key, return true iff it is present in the failure cache. */ const hs_cache_intro_state_t * hs_cache_client_intro_state_find(const ed25519_public_key_t *service_pk, const ed25519_public_key_t *auth_key) { hs_cache_intro_state_t *state = NULL; cache_client_intro_state_lookup(service_pk, auth_key, &state); return state; } /* Cleanup the client introduction state cache. */ void hs_cache_client_intro_state_clean(time_t now) { time_t cutoff = now - HS_CACHE_CLIENT_INTRO_STATE_MAX_AGE; DIGEST256MAP_FOREACH_MODIFY(hs_cache_client_intro_state, key, hs_cache_client_intro_state_t *, cache) { /* Cleanup intro points failure. */ cache_client_intro_state_clean(cutoff, cache); /* Is this cache empty for this service key? If yes, remove it from the * cache. Else keep it. */ if (cache_client_intro_state_is_empty(cache)) { cache_client_intro_state_free(cache); MAP_DEL_CURRENT(key); } } DIGEST256MAP_FOREACH_END; } /* Purge the client introduction state cache. */ void hs_cache_client_intro_state_purge(void) { DIGEST256MAP_FOREACH_MODIFY(hs_cache_client_intro_state, key, hs_cache_client_intro_state_t *, cache) { MAP_DEL_CURRENT(key); cache_client_intro_state_free(cache); } DIGEST256MAP_FOREACH_END; log_info(LD_REND, "Hidden service client introduction point state " "cache purged."); } /**************** Generics *********************************/ /* Do a round of OOM cleanup on all directory caches. Return the amount of * removed bytes. It is possible that the returned value is lower than * min_remove_bytes if the caches get emptied out so the caller should be * aware of this. */ size_t hs_cache_handle_oom(time_t now, size_t min_remove_bytes) { time_t k; size_t bytes_removed = 0; /* Our OOM handler called with 0 bytes to remove is a code flow error. */ tor_assert(min_remove_bytes != 0); /* The algorithm is as follow. K is the oldest expected descriptor age. * * 1) Deallocate all entries from v2 cache that are older than K hours. * 1.1) If the amount of remove bytes has been reached, stop. * 2) Deallocate all entries from v3 cache that are older than K hours * 2.1) If the amount of remove bytes has been reached, stop. * 3) Set K = K - RendPostPeriod and repeat process until K is < 0. * * This ends up being O(Kn). */ /* Set K to the oldest expected age in seconds which is the maximum * lifetime of a cache entry. We'll use the v2 lifetime because it's much * bigger than the v3 thus leading to cleaning older descriptors. */ k = rend_cache_max_entry_lifetime(); do { time_t cutoff; /* If K becomes negative, it means we've empty the caches so stop and * return what we were able to cleanup. */ if (k < 0) { break; } /* Compute a cutoff value with K and the current time. */ cutoff = now - k; /* Start by cleaning the v2 cache with that cutoff. */ bytes_removed += rend_cache_clean_v2_descs_as_dir(cutoff); if (bytes_removed < min_remove_bytes) { /* We haven't remove enough bytes so clean v3 cache. */ bytes_removed += cache_clean_v3_as_dir(now, cutoff); /* Decrement K by a post period to shorten the cutoff. */ k -= get_options()->RendPostPeriod; } } while (bytes_removed < min_remove_bytes); return bytes_removed; } /* Return the maximum size of a v3 HS descriptor. */ unsigned int hs_cache_get_max_descriptor_size(void) { return (unsigned) networkstatus_get_param(NULL, "HSV3MaxDescriptorSize", HS_DESC_MAX_LEN, 1, INT32_MAX); } /* Initialize the hidden service cache subsystem. */ void hs_cache_init(void) { /* Calling this twice is very wrong code flow. */ tor_assert(!hs_cache_v3_dir); hs_cache_v3_dir = digest256map_new(); tor_assert(!hs_cache_v3_client); hs_cache_v3_client = digest256map_new(); tor_assert(!hs_cache_client_intro_state); hs_cache_client_intro_state = digest256map_new(); } /* Cleanup the hidden service cache subsystem. */ void hs_cache_free_all(void) { digest256map_free(hs_cache_v3_dir, cache_dir_desc_free_void); hs_cache_v3_dir = NULL; digest256map_free(hs_cache_v3_client, cache_client_desc_free_void); hs_cache_v3_client = NULL; digest256map_free(hs_cache_client_intro_state, cache_client_intro_state_free_void); hs_cache_client_intro_state = NULL; }