/* This file is part of GNUnet. (C) 2009, 2010, 2011 Christian Grothoff (and other contributing authors) GNUnet is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. GNUnet is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with GNUnet; see the file COPYING. If not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /** * @file fs/gnunet-service-fs_pr.c * @brief API to handle pending requests * @author Christian Grothoff */ #include "platform.h" #include "gnunet_load_lib.h" #include "gnunet-service-fs.h" #include "gnunet-service-fs_cp.h" #include "gnunet-service-fs_indexing.h" #include "gnunet-service-fs_pe.h" #include "gnunet-service-fs_pr.h" /** * Maximum size of the datastore queue for P2P operations. Needs to * be large enough to queue MAX_QUEUE_PER_PEER operations for roughly * the number of active (connected) peers. */ #define MAX_DATASTORE_QUEUE (16 * MAX_QUEUE_PER_PEER) /** * Bandwidth value of a 0-priority content (must be fairly high * compared to query since content is typically significantly larger * -- and more valueable since it can take many queries to get one * piece of content). */ #define CONTENT_BANDWIDTH_VALUE 800 /** * Hard limit on the number of results we may get from the datastore per query. */ #define MAX_RESULTS (100 * 1024) /** * An active request. */ struct GSF_PendingRequest { /** * Public data for the request. */ struct GSF_PendingRequestData public_data; /** * Function to call if we encounter a reply. */ GSF_PendingRequestReplyHandler rh; /** * Closure for 'rh' */ void *rh_cls; /** * Array of hash codes of replies we've already seen. */ GNUNET_HashCode *replies_seen; /** * Bloomfilter masking replies we've already seen. */ struct GNUNET_CONTAINER_BloomFilter *bf; /** * Entry for this pending request in the expiration heap, or NULL. */ struct GNUNET_CONTAINER_HeapNode *hnode; /** * Datastore queue entry for this request (or NULL for none). */ struct GNUNET_DATASTORE_QueueEntry *qe; /** * DHT request handle for this request (or NULL for none). */ struct GNUNET_DHT_GetHandle *gh; /** * Function to call upon completion of the local get * request, or NULL for none. */ GSF_LocalLookupContinuation llc_cont; /** * Closure for llc_cont. */ void *llc_cont_cls; /** * Last result from the local datastore lookup evaluation. */ enum GNUNET_BLOCK_EvaluationResult local_result; /** * Identity of the peer that we should use for the 'sender' * (recipient of the response) when forwarding (0 for none). */ GNUNET_PEER_Id sender_pid; /** * Identity of the peer that we should never forward this query * to since it originated this query (0 for none). */ GNUNET_PEER_Id origin_pid; /** * Time we started the last datastore lookup. */ struct GNUNET_TIME_Absolute qe_start; /** * Task that warns us if the local datastore lookup takes too long. */ GNUNET_SCHEDULER_TaskIdentifier warn_task; /** * Current offset for querying our local datastore for results. * Starts at a random value, incremented until we get the same * UID again (detected using 'first_uid'), which is then used * to termiante the iteration. */ uint64_t local_result_offset; /** * Unique ID of the first result from the local datastore; * used to detect wrap-around of the offset. */ uint64_t first_uid; /** * Number of valid entries in the 'replies_seen' array. */ unsigned int replies_seen_count; /** * Length of the 'replies_seen' array. */ unsigned int replies_seen_size; /** * Mingle value we currently use for the bf. */ uint32_t mingle; /** * Do we have a first UID yet? */ unsigned int have_first_uid; }; /** * All pending requests, ordered by the query. Entries * are of type 'struct GSF_PendingRequest*'. */ static struct GNUNET_CONTAINER_MultiHashMap *pr_map; /** * Datastore 'PUT' load tracking. */ static struct GNUNET_LOAD_Value *datastore_put_load; /** * Are we allowed to migrate content to this peer. */ static int active_to_migration; /** * Size of the datastore queue we assume for common requests. * Determined based on the network quota. */ static unsigned int datastore_queue_size; /** * Heap with the request that will expire next at the top. Contains * pointers of type "struct PendingRequest*"; these will *also* be * aliased from the "requests_by_peer" data structures and the * "requests_by_query" table. Note that requests from our clients * don't expire and are thus NOT in the "requests_by_expiration" * (or the "requests_by_peer" tables). */ static struct GNUNET_CONTAINER_Heap *requests_by_expiration_heap; /** * Maximum number of requests (from other peers, overall) that we're * willing to have pending at any given point in time. Can be changed * via the configuration file (32k is just the default). */ static unsigned long long max_pending_requests = (32 * 1024); /** * Recalculate our bloom filter for filtering replies. This function * will create a new bloom filter from scratch, so it should only be * called if we have no bloomfilter at all (and hence can create a * fresh one of minimal size without problems) OR if our peer is the * initiator (in which case we may resize to larger than mimimum size). * * @param pr request for which the BF is to be recomputed */ static void refresh_bloomfilter (struct GSF_PendingRequest *pr) { if (pr->bf != NULL) GNUNET_CONTAINER_bloomfilter_free (pr->bf); pr->mingle = GNUNET_CRYPTO_random_u32 (GNUNET_CRYPTO_QUALITY_WEAK, UINT32_MAX); pr->bf = GNUNET_BLOCK_construct_bloomfilter (pr->mingle, pr->replies_seen, pr->replies_seen_count); } /** * Create a new pending request. * * @param options request options * @param type type of the block that is being requested * @param query key for the lookup * @param namespace namespace to lookup, NULL for no namespace * @param target preferred target for the request, NULL for none * @param bf_data raw data for bloom filter for known replies, can be NULL * @param bf_size number of bytes in bf_data * @param mingle mingle value for bf * @param anonymity_level desired anonymity level * @param priority maximum outgoing cummulative request priority to use * @param ttl current time-to-live for the request * @param sender_pid peer ID to use for the sender when forwarding, 0 for none * @param origin_pid peer ID of origin of query (do not loop back) * @param replies_seen hash codes of known local replies * @param replies_seen_count size of the 'replies_seen' array * @param rh handle to call when we get a reply * @param rh_cls closure for rh * @return handle for the new pending request */ struct GSF_PendingRequest * GSF_pending_request_create_ (enum GSF_PendingRequestOptions options, enum GNUNET_BLOCK_Type type, const GNUNET_HashCode * query, const GNUNET_HashCode * namespace, const struct GNUNET_PeerIdentity *target, const char *bf_data, size_t bf_size, uint32_t mingle, uint32_t anonymity_level, uint32_t priority, int32_t ttl, GNUNET_PEER_Id sender_pid, GNUNET_PEER_Id origin_pid, const GNUNET_HashCode * replies_seen, unsigned int replies_seen_count, GSF_PendingRequestReplyHandler rh, void *rh_cls) { struct GSF_PendingRequest *pr; struct GSF_PendingRequest *dpr; #if DEBUG_FS GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Creating request handle for `%s' of type %d\n", GNUNET_h2s (query), type); #endif GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Pending requests created"), 1, GNUNET_NO); pr = GNUNET_malloc (sizeof (struct GSF_PendingRequest)); pr->local_result_offset = GNUNET_CRYPTO_random_u64 (GNUNET_CRYPTO_QUALITY_WEAK, UINT64_MAX); pr->public_data.query = *query; if (GNUNET_BLOCK_TYPE_FS_SBLOCK == type) { GNUNET_assert (NULL != namespace); pr->public_data.namespace = *namespace; } if (NULL != target) { pr->public_data.target = *target; pr->public_data.has_target = GNUNET_YES; } pr->public_data.anonymity_level = anonymity_level; pr->public_data.priority = priority; pr->public_data.original_priority = priority; pr->public_data.options = options; pr->public_data.type = type; pr->public_data.start_time = GNUNET_TIME_absolute_get (); pr->sender_pid = sender_pid; pr->origin_pid = origin_pid; pr->rh = rh; pr->rh_cls = rh_cls; GNUNET_assert ((sender_pid != 0) || (0 == (options & GSF_PRO_FORWARD_ONLY))); if (ttl >= 0) pr->public_data.ttl = GNUNET_TIME_relative_to_absolute (GNUNET_TIME_relative_multiply (GNUNET_TIME_UNIT_SECONDS, (uint32_t) ttl)); else pr->public_data.ttl = GNUNET_TIME_absolute_subtract (pr->public_data.start_time, GNUNET_TIME_relative_multiply (GNUNET_TIME_UNIT_SECONDS, (uint32_t) (-ttl))); if (replies_seen_count > 0) { pr->replies_seen_size = replies_seen_count; pr->replies_seen = GNUNET_malloc (sizeof (GNUNET_HashCode) * pr->replies_seen_size); memcpy (pr->replies_seen, replies_seen, replies_seen_count * sizeof (GNUNET_HashCode)); pr->replies_seen_count = replies_seen_count; } if (NULL != bf_data) { pr->bf = GNUNET_CONTAINER_bloomfilter_init (bf_data, bf_size, GNUNET_CONSTANTS_BLOOMFILTER_K); pr->mingle = mingle; } else if ((replies_seen_count > 0) && (0 != (options & GSF_PRO_BLOOMFILTER_FULL_REFRESH))) { refresh_bloomfilter (pr); } GNUNET_CONTAINER_multihashmap_put (pr_map, query, pr, GNUNET_CONTAINER_MULTIHASHMAPOPTION_MULTIPLE); if (0 != (options & GSF_PRO_REQUEST_EXPIRES)) { pr->hnode = GNUNET_CONTAINER_heap_insert (requests_by_expiration_heap, pr, pr->public_data.ttl.abs_value); /* make sure we don't track too many requests */ while (GNUNET_CONTAINER_heap_get_size (requests_by_expiration_heap) > max_pending_requests) { dpr = GNUNET_CONTAINER_heap_peek (requests_by_expiration_heap); GNUNET_assert (dpr != NULL); if (pr == dpr) break; /* let the request live briefly... */ dpr->rh (dpr->rh_cls, GNUNET_BLOCK_EVALUATION_REQUEST_VALID, dpr, UINT32_MAX, GNUNET_TIME_UNIT_FOREVER_ABS, GNUNET_BLOCK_TYPE_ANY, NULL, 0); GSF_pending_request_cancel_ (dpr, GNUNET_YES); } } GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Pending requests active"), 1, GNUNET_NO); return pr; } /** * Obtain the public data associated with a pending request * * @param pr pending request * @return associated public data */ struct GSF_PendingRequestData * GSF_pending_request_get_data_ (struct GSF_PendingRequest *pr) { return &pr->public_data; } /** * Test if two pending requests are compatible (would generate * the same query modulo filters and should thus be processed * jointly). * * @param pra a pending request * @param prb another pending request * @return GNUNET_OK if the requests are compatible */ int GSF_pending_request_is_compatible_ (struct GSF_PendingRequest *pra, struct GSF_PendingRequest *prb) { if ((pra->public_data.type != prb->public_data.type) || (0 != memcmp (&pra->public_data.query, &prb->public_data.query, sizeof (GNUNET_HashCode))) || ((pra->public_data.type == GNUNET_BLOCK_TYPE_FS_SBLOCK) && (0 != memcmp (&pra->public_data.namespace, &prb->public_data.namespace, sizeof (GNUNET_HashCode))))) return GNUNET_NO; return GNUNET_OK; } /** * Update a given pending request with additional replies * that have been seen. * * @param pr request to update * @param replies_seen hash codes of replies that we've seen * @param replies_seen_count size of the replies_seen array */ void GSF_pending_request_update_ (struct GSF_PendingRequest *pr, const GNUNET_HashCode * replies_seen, unsigned int replies_seen_count) { unsigned int i; GNUNET_HashCode mhash; if (replies_seen_count + pr->replies_seen_count < pr->replies_seen_count) return; /* integer overflow */ if (0 != (pr->public_data.options & GSF_PRO_BLOOMFILTER_FULL_REFRESH)) { /* we're responsible for the BF, full refresh */ if (replies_seen_count + pr->replies_seen_count > pr->replies_seen_size) GNUNET_array_grow (pr->replies_seen, pr->replies_seen_size, replies_seen_count + pr->replies_seen_count); memcpy (&pr->replies_seen[pr->replies_seen_count], replies_seen, sizeof (GNUNET_HashCode) * replies_seen_count); pr->replies_seen_count += replies_seen_count; refresh_bloomfilter (pr); } else { if (NULL == pr->bf) { /* we're not the initiator, but the initiator did not give us * any bloom-filter, so we need to create one on-the-fly */ pr->mingle = GNUNET_CRYPTO_random_u32 (GNUNET_CRYPTO_QUALITY_WEAK, UINT32_MAX); pr->bf = GNUNET_BLOCK_construct_bloomfilter (pr->mingle, replies_seen, replies_seen_count); } else { for (i = 0; i < pr->replies_seen_count; i++) { GNUNET_BLOCK_mingle_hash (&replies_seen[i], pr->mingle, &mhash); GNUNET_CONTAINER_bloomfilter_add (pr->bf, &mhash); } } } } /** * Generate the message corresponding to the given pending request for * transmission to other peers (or at least determine its size). * * @param pr request to generate the message for * @param buf_size number of bytes available in buf * @param buf where to copy the message (can be NULL) * @return number of bytes needed (if > buf_size) or used */ size_t GSF_pending_request_get_message_ (struct GSF_PendingRequest *pr, size_t buf_size, void *buf) { char lbuf[GNUNET_SERVER_MAX_MESSAGE_SIZE]; struct GetMessage *gm; GNUNET_HashCode *ext; size_t msize; unsigned int k; uint32_t bm; uint32_t prio; size_t bf_size; struct GNUNET_TIME_Absolute now; int64_t ttl; int do_route; #if DEBUG_FS if (buf_size > 0) GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Building request message for `%s' of type %d\n", GNUNET_h2s (&pr->public_data.query), pr->public_data.type); #endif k = 0; bm = 0; do_route = (0 == (pr->public_data.options & GSF_PRO_FORWARD_ONLY)); if ((!do_route) && (pr->sender_pid == 0)) { GNUNET_break (0); do_route = GNUNET_YES; } if (!do_route) { bm |= GET_MESSAGE_BIT_RETURN_TO; k++; } if (GNUNET_BLOCK_TYPE_FS_SBLOCK == pr->public_data.type) { bm |= GET_MESSAGE_BIT_SKS_NAMESPACE; k++; } if (GNUNET_YES == pr->public_data.has_target) { bm |= GET_MESSAGE_BIT_TRANSMIT_TO; k++; } bf_size = GNUNET_CONTAINER_bloomfilter_get_size (pr->bf); msize = sizeof (struct GetMessage) + bf_size + k * sizeof (GNUNET_HashCode); GNUNET_assert (msize < GNUNET_SERVER_MAX_MESSAGE_SIZE); if (buf_size < msize) return msize; gm = (struct GetMessage *) lbuf; gm->header.type = htons (GNUNET_MESSAGE_TYPE_FS_GET); gm->header.size = htons (msize); gm->type = htonl (pr->public_data.type); if (do_route) prio = GNUNET_CRYPTO_random_u32 (GNUNET_CRYPTO_QUALITY_WEAK, pr->public_data.priority + 1); else prio = 0; pr->public_data.priority -= prio; gm->priority = htonl (prio); now = GNUNET_TIME_absolute_get (); ttl = (int64_t) (pr->public_data.ttl.abs_value - now.abs_value); gm->ttl = htonl (ttl / 1000); gm->filter_mutator = htonl (pr->mingle); gm->hash_bitmap = htonl (bm); gm->query = pr->public_data.query; ext = (GNUNET_HashCode *) & gm[1]; k = 0; if (!do_route) GNUNET_PEER_resolve (pr->sender_pid, (struct GNUNET_PeerIdentity *) &ext[k++]); if (GNUNET_BLOCK_TYPE_FS_SBLOCK == pr->public_data.type) memcpy (&ext[k++], &pr->public_data.namespace, sizeof (GNUNET_HashCode)); if (GNUNET_YES == pr->public_data.has_target) ext[k++] = pr->public_data.target.hashPubKey; if (pr->bf != NULL) GNUNET_assert (GNUNET_SYSERR != GNUNET_CONTAINER_bloomfilter_get_raw_data (pr->bf, (char *) &ext[k], bf_size)); memcpy (buf, gm, msize); return msize; } /** * Iterator to free pending requests. * * @param cls closure, unused * @param key current key code * @param value value in the hash map (pending request) * @return GNUNET_YES (we should continue to iterate) */ static int clean_request (void *cls, const GNUNET_HashCode * key, void *value) { struct GSF_PendingRequest *pr = value; GSF_LocalLookupContinuation cont; #if DEBUG_FS GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Cleaning up pending request for `%s'.\n", GNUNET_h2s (key)); #endif if (NULL != (cont = pr->llc_cont)) { pr->llc_cont = NULL; cont (pr->llc_cont_cls, pr, pr->local_result); } GSF_plan_notify_request_done_ (pr); GNUNET_free_non_null (pr->replies_seen); if (NULL != pr->bf) { GNUNET_CONTAINER_bloomfilter_free (pr->bf); pr->bf = NULL; } GNUNET_PEER_change_rc (pr->sender_pid, -1); pr->sender_pid = 0; GNUNET_PEER_change_rc (pr->origin_pid, -1); pr->origin_pid = 0; if (NULL != pr->hnode) { GNUNET_CONTAINER_heap_remove_node (pr->hnode); pr->hnode = NULL; } if (NULL != pr->qe) { GNUNET_DATASTORE_cancel (pr->qe); pr->qe = NULL; } if (NULL != pr->gh) { GNUNET_DHT_get_stop (pr->gh); pr->gh = NULL; } if (GNUNET_SCHEDULER_NO_TASK != pr->warn_task) { GNUNET_SCHEDULER_cancel (pr->warn_task); pr->warn_task = GNUNET_SCHEDULER_NO_TASK; } GNUNET_assert (GNUNET_OK == GNUNET_CONTAINER_multihashmap_remove (pr_map, &pr->public_data.query, pr)); GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Pending requests active"), -1, GNUNET_NO); GNUNET_free (pr); return GNUNET_YES; } /** * Explicitly cancel a pending request. * * @param pr request to cancel * @param full_cleanup fully purge the request */ void GSF_pending_request_cancel_ (struct GSF_PendingRequest *pr, int full_cleanup) { GSF_LocalLookupContinuation cont; if (NULL == pr_map) return; /* already cleaned up! */ if (GNUNET_YES != full_cleanup) { /* make request inactive (we're no longer interested in more results), * but do NOT remove from our data-structures, we still need it there * to prevent the request from looping */ pr->rh = NULL; if (NULL != (cont = pr->llc_cont)) { pr->llc_cont = NULL; cont (pr->llc_cont_cls, pr, pr->local_result); } GSF_plan_notify_request_done_ (pr); if (NULL != pr->qe) { GNUNET_DATASTORE_cancel (pr->qe); pr->qe = NULL; } if (NULL != pr->gh) { GNUNET_DHT_get_stop (pr->gh); pr->gh = NULL; } if (GNUNET_SCHEDULER_NO_TASK != pr->warn_task) { GNUNET_SCHEDULER_cancel (pr->warn_task); pr->warn_task = GNUNET_SCHEDULER_NO_TASK; } return; } GNUNET_assert (GNUNET_YES == clean_request (NULL, &pr->public_data.query, pr)); } /** * Iterate over all pending requests. * * @param it function to call for each request * @param cls closure for it */ void GSF_iterate_pending_requests_ (GSF_PendingRequestIterator it, void *cls) { GNUNET_CONTAINER_multihashmap_iterate (pr_map, (GNUNET_CONTAINER_HashMapIterator) it, cls); } /** * Closure for "process_reply" function. */ struct ProcessReplyClosure { /** * The data for the reply. */ const void *data; /** * Who gave us this reply? NULL for local host (or DHT) */ struct GSF_ConnectedPeer *sender; /** * When the reply expires. */ struct GNUNET_TIME_Absolute expiration; /** * Size of data. */ size_t size; /** * Type of the block. */ enum GNUNET_BLOCK_Type type; /** * How much was this reply worth to us? */ uint32_t priority; /** * Anonymity requirements for this reply. */ uint32_t anonymity_level; /** * Evaluation result (returned). */ enum GNUNET_BLOCK_EvaluationResult eval; /** * Did we find a matching request? */ int request_found; }; /** * Update the performance data for the sender (if any) since * the sender successfully answered one of our queries. * * @param prq information about the sender * @param pr request that was satisfied */ static void update_request_performance_data (struct ProcessReplyClosure *prq, struct GSF_PendingRequest *pr) { if (prq->sender == NULL) return; GSF_peer_update_performance_ (prq->sender, pr->public_data.start_time, prq->priority); } /** * We have received a reply; handle it! * * @param cls response (struct ProcessReplyClosure) * @param key our query * @param value value in the hash map (info about the query) * @return GNUNET_YES (we should continue to iterate) */ static int process_reply (void *cls, const GNUNET_HashCode * key, void *value) { struct ProcessReplyClosure *prq = cls; struct GSF_PendingRequest *pr = value; GNUNET_HashCode chash; if (NULL == pr->rh) return GNUNET_YES; #if DEBUG_FS GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Matched result (type %u) for query `%s' with pending request\n", (unsigned int) prq->type, GNUNET_h2s (key)); #endif GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# replies received and matched"), 1, GNUNET_NO); prq->eval = GNUNET_BLOCK_evaluate (GSF_block_ctx, prq->type, key, &pr->bf, pr->mingle, &pr->public_data.namespace, (prq->type == GNUNET_BLOCK_TYPE_FS_SBLOCK) ? sizeof (GNUNET_HashCode) : 0, prq->data, prq->size); switch (prq->eval) { case GNUNET_BLOCK_EVALUATION_OK_MORE: update_request_performance_data (prq, pr); break; case GNUNET_BLOCK_EVALUATION_OK_LAST: /* short cut: stop processing early, no BF-update, etc. */ update_request_performance_data (prq, pr); GNUNET_LOAD_update (GSF_rt_entry_lifetime, GNUNET_TIME_absolute_get_duration (pr-> public_data.start_time).rel_value); /* pass on to other peers / local clients */ pr->rh (pr->rh_cls, prq->eval, pr, prq->anonymity_level, prq->expiration, prq->type, prq->data, prq->size); return GNUNET_YES; case GNUNET_BLOCK_EVALUATION_OK_DUPLICATE: GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# duplicate replies discarded (bloomfilter)"), 1, GNUNET_NO); #if DEBUG_FS && 0 GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Duplicate response `%s', discarding.\n", GNUNET_h2s (&mhash)); #endif return GNUNET_YES; /* duplicate */ case GNUNET_BLOCK_EVALUATION_RESULT_INVALID: return GNUNET_YES; /* wrong namespace */ case GNUNET_BLOCK_EVALUATION_REQUEST_VALID: GNUNET_break (0); return GNUNET_YES; case GNUNET_BLOCK_EVALUATION_REQUEST_INVALID: GNUNET_break (0); return GNUNET_YES; case GNUNET_BLOCK_EVALUATION_TYPE_NOT_SUPPORTED: GNUNET_log (GNUNET_ERROR_TYPE_ERROR, _("Unsupported block type %u\n"), prq->type); return GNUNET_NO; } /* update bloomfilter */ GNUNET_CRYPTO_hash (prq->data, prq->size, &chash); GSF_pending_request_update_ (pr, &chash, 1); if (NULL == prq->sender) { #if DEBUG_FS GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Found result for query `%s' in local datastore\n", GNUNET_h2s (key)); #endif GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# results found locally"), 1, GNUNET_NO); } else { GSF_dht_lookup_ (pr); } prq->priority += pr->public_data.original_priority; pr->public_data.priority = 0; pr->public_data.original_priority = 0; pr->public_data.results_found++; prq->request_found = GNUNET_YES; /* finally, pass on to other peer / local client */ pr->rh (pr->rh_cls, prq->eval, pr, prq->anonymity_level, prq->expiration, prq->type, prq->data, prq->size); return GNUNET_YES; } /** * Context for the 'put_migration_continuation'. */ struct PutMigrationContext { /** * Start time for the operation. */ struct GNUNET_TIME_Absolute start; /** * Request origin. */ struct GNUNET_PeerIdentity origin; /** * GNUNET_YES if we had a matching request for this block, * GNUNET_NO if not. */ int requested; }; /** * Continuation called to notify client about result of the * operation. * * @param cls closure * @param success GNUNET_SYSERR on failure * @param msg NULL on success, otherwise an error message */ static void put_migration_continuation (void *cls, int success, const char *msg) { struct PutMigrationContext *pmc = cls; struct GNUNET_TIME_Relative delay; struct GNUNET_TIME_Relative block_time; struct GSF_ConnectedPeer *cp; struct GSF_PeerPerformanceData *ppd; delay = GNUNET_TIME_absolute_get_duration (pmc->start); cp = GSF_peer_get_ (&pmc->origin); if ((GNUNET_OK != success) && (GNUNET_NO == pmc->requested)) { /* block migration for a bit... */ if (NULL != cp) { ppd = GSF_get_peer_performance_data_ (cp); ppd->migration_duplication++; block_time = GNUNET_TIME_relative_multiply (GNUNET_TIME_UNIT_SECONDS, 5 * ppd->migration_duplication + GNUNET_CRYPTO_random_u32 (GNUNET_CRYPTO_QUALITY_WEAK, 5)); GSF_block_peer_migration_ (cp, block_time); } } else { if (NULL != cp) { ppd = GSF_get_peer_performance_data_ (cp); ppd->migration_duplication = 0; /* reset counter */ } } GNUNET_free (pmc); /* FIXME: should we really update the load value on failure? */ if (NULL != datastore_put_load) GNUNET_LOAD_update (datastore_put_load, delay.rel_value); if (GNUNET_OK == success) return; GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Datastore `PUT' failures"), 1, GNUNET_NO); } /** * Test if the DATABASE (PUT) load on this peer is too high * to even consider processing the query at * all. * * @return GNUNET_YES if the load is too high to do anything (load high) * GNUNET_NO to process normally (load normal or low) */ static int test_put_load_too_high (uint32_t priority) { double ld; if (NULL == datastore_put_load) return GNUNET_NO; if (GNUNET_LOAD_get_average (datastore_put_load) < 50) return GNUNET_NO; /* very fast */ ld = GNUNET_LOAD_get_load (datastore_put_load); if (ld < 2.0 * (1 + priority)) return GNUNET_NO; GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# storage requests dropped due to high load"), 1, GNUNET_NO); return GNUNET_YES; } /** * Iterator called on each result obtained for a DHT * operation that expects a reply * * @param cls closure * @param exp when will this value expire * @param key key of the result * @param get_path peers on reply path (or NULL if not recorded) * @param get_path_length number of entries in get_path * @param put_path peers on the PUT path (or NULL if not recorded) * @param put_path_length number of entries in get_path * @param type type of the result * @param size number of bytes in data * @param data pointer to the result data */ static void handle_dht_reply (void *cls, struct GNUNET_TIME_Absolute exp, const GNUNET_HashCode * key, const struct GNUNET_PeerIdentity *get_path, unsigned int get_path_length, const struct GNUNET_PeerIdentity *put_path, unsigned int put_path_length, enum GNUNET_BLOCK_Type type, size_t size, const void *data) { struct GSF_PendingRequest *pr = cls; struct ProcessReplyClosure prq; struct PutMigrationContext *pmc; GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Replies received from DHT"), 1, GNUNET_NO); memset (&prq, 0, sizeof (prq)); prq.data = data; prq.expiration = exp; prq.size = size; prq.type = type; process_reply (&prq, key, pr); if ((GNUNET_YES == active_to_migration) && (GNUNET_NO == test_put_load_too_high (prq.priority))) { #if DEBUG_FS GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Replicating result for query `%s' with priority %u\n", GNUNET_h2s (key), prq.priority); #endif pmc = GNUNET_malloc (sizeof (struct PutMigrationContext)); pmc->start = GNUNET_TIME_absolute_get (); pmc->requested = GNUNET_YES; if (NULL == GNUNET_DATASTORE_put (GSF_dsh, 0, key, size, data, type, prq.priority, 1 /* anonymity */ , 0 /* replication */ , exp, 1 + prq.priority, MAX_DATASTORE_QUEUE, GNUNET_CONSTANTS_SERVICE_TIMEOUT, &put_migration_continuation, pmc)) { put_migration_continuation (pmc, GNUNET_NO, NULL); } } } /** * Consider looking up the data in the DHT (anonymity-level permitting). * * @param pr the pending request to process */ void GSF_dht_lookup_ (struct GSF_PendingRequest *pr) { const void *xquery; size_t xquery_size; struct GNUNET_PeerIdentity pi; char buf[sizeof (GNUNET_HashCode) * 2]; if (0 != pr->public_data.anonymity_level) return; if (NULL != pr->gh) { GNUNET_DHT_get_stop (pr->gh); pr->gh = NULL; } xquery = NULL; xquery_size = 0; if (GNUNET_BLOCK_TYPE_FS_SBLOCK == pr->public_data.type) { xquery = buf; memcpy (buf, &pr->public_data.namespace, sizeof (GNUNET_HashCode)); xquery_size = sizeof (GNUNET_HashCode); } if (0 != (pr->public_data.options & GSF_PRO_FORWARD_ONLY)) { GNUNET_assert (0 != pr->sender_pid); GNUNET_PEER_resolve (pr->sender_pid, &pi); memcpy (&buf[xquery_size], &pi, sizeof (struct GNUNET_PeerIdentity)); xquery_size += sizeof (struct GNUNET_PeerIdentity); } pr->gh = GNUNET_DHT_get_start (GSF_dht, GNUNET_TIME_UNIT_FOREVER_REL, pr->public_data.type, &pr->public_data.query, 5 /* DEFAULT_GET_REPLICATION */ , GNUNET_DHT_RO_DEMULTIPLEX_EVERYWHERE, /* FIXME: can no longer pass pr->bf/pr->mingle... */ xquery, xquery_size, &handle_dht_reply, pr); } /** * Task that issues a warning if the datastore lookup takes too long. * * @param cls the 'struct GSF_PendingRequest' * @param tc task context */ static void warn_delay_task (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct GSF_PendingRequest *pr = cls; GNUNET_log (GNUNET_ERROR_TYPE_WARNING, _("Datastore lookup already took %llu ms!\n"), (unsigned long long) GNUNET_TIME_absolute_get_duration (pr->qe_start).rel_value); pr->warn_task = GNUNET_SCHEDULER_add_delayed (GNUNET_TIME_UNIT_MINUTES, &warn_delay_task, pr); } /** * Task that issues a warning if the datastore lookup takes too long. * * @param cls the 'struct GSF_PendingRequest' * @param tc task context */ static void odc_warn_delay_task (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct GSF_PendingRequest *pr = cls; GNUNET_log (GNUNET_ERROR_TYPE_WARNING, _("On-demand lookup already took %llu ms!\n"), (unsigned long long) GNUNET_TIME_absolute_get_duration (pr->qe_start).rel_value); pr->warn_task = GNUNET_SCHEDULER_add_delayed (GNUNET_TIME_UNIT_MINUTES, &odc_warn_delay_task, pr); } /** * We're processing (local) results for a search request * from another peer. Pass applicable results to the * peer and if we are done either clean up (operation * complete) or forward to other peers (more results possible). * * @param cls our closure (struct PendingRequest) * @param key key for the content * @param size number of bytes in data * @param data content stored * @param type type of the content * @param priority priority of the content * @param anonymity anonymity-level for the content * @param expiration expiration time for the content * @param uid unique identifier for the datum; * maybe 0 if no unique identifier is available */ static void process_local_reply (void *cls, const GNUNET_HashCode * key, size_t size, const void *data, enum GNUNET_BLOCK_Type type, uint32_t priority, uint32_t anonymity, struct GNUNET_TIME_Absolute expiration, uint64_t uid) { struct GSF_PendingRequest *pr = cls; GSF_LocalLookupContinuation cont; struct ProcessReplyClosure prq; GNUNET_HashCode query; unsigned int old_rf; GNUNET_SCHEDULER_cancel (pr->warn_task); pr->warn_task = GNUNET_SCHEDULER_NO_TASK; if (NULL != pr->qe) { pr->qe = NULL; if (NULL == key) { GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Datastore lookups concluded (no results)"), 1, GNUNET_NO); } if (GNUNET_NO == pr->have_first_uid) { pr->first_uid = uid; pr->have_first_uid = 1; } else { if ((uid == pr->first_uid) && (key != NULL)) { GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Datastore lookups concluded (seen all)"), 1, GNUNET_NO); key = NULL; /* all replies seen! */ } pr->have_first_uid++; if ((pr->have_first_uid > MAX_RESULTS) && (key != NULL)) { GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Datastore lookups aborted (more than MAX_RESULTS)"), 1, GNUNET_NO); key = NULL; /* all replies seen! */ } } } if (NULL == key) { #if DEBUG_FS GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "No further local responses available.\n"); #endif if ((pr->public_data.type == GNUNET_BLOCK_TYPE_FS_DBLOCK) || (pr->public_data.type == GNUNET_BLOCK_TYPE_FS_IBLOCK)) GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# requested DBLOCK or IBLOCK not found"), 1, GNUNET_NO); goto check_error_and_continue; } #if DEBUG_FS GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Received reply for `%s' of type %d with UID %llu from datastore.\n", GNUNET_h2s (key), type, (unsigned long long) uid); #endif if (type == GNUNET_BLOCK_TYPE_FS_ONDEMAND) { #if DEBUG_FS GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Found ONDEMAND block, performing on-demand encoding\n"); #endif GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# on-demand blocks matched requests"), 1, GNUNET_NO); pr->qe_start = GNUNET_TIME_absolute_get (); pr->warn_task = GNUNET_SCHEDULER_add_delayed (GNUNET_TIME_UNIT_MINUTES, &odc_warn_delay_task, pr); if (GNUNET_OK == GNUNET_FS_handle_on_demand_block (key, size, data, type, priority, anonymity, expiration, uid, &process_local_reply, pr)) { GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# on-demand lookups performed successfully"), 1, GNUNET_NO); return; /* we're done */ } GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# on-demand lookups failed"), 1, GNUNET_NO); GNUNET_SCHEDULER_cancel (pr->warn_task); pr->warn_task = GNUNET_SCHEDULER_add_delayed (GNUNET_TIME_UNIT_MINUTES, &warn_delay_task, pr); pr->qe = GNUNET_DATASTORE_get_key (GSF_dsh, pr->local_result_offset - 1, &pr->public_data.query, pr->public_data.type == GNUNET_BLOCK_TYPE_FS_DBLOCK ? GNUNET_BLOCK_TYPE_ANY : pr->public_data.type, (0 != (GSF_PRO_PRIORITY_UNLIMITED & pr->public_data.options)) ? UINT_MAX : 1 /* queue priority */ , (0 != (GSF_PRO_PRIORITY_UNLIMITED & pr->public_data.options)) ? UINT_MAX : datastore_queue_size /* max queue size */ , GNUNET_TIME_UNIT_FOREVER_REL, &process_local_reply, pr); if (NULL != pr->qe) return; /* we're done */ GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Datastore lookups concluded (error queueing)"), 1, GNUNET_NO); goto check_error_and_continue; } old_rf = pr->public_data.results_found; memset (&prq, 0, sizeof (prq)); prq.data = data; prq.expiration = expiration; prq.size = size; if (GNUNET_OK != GNUNET_BLOCK_get_key (GSF_block_ctx, type, data, size, &query)) { GNUNET_break (0); GNUNET_DATASTORE_remove (GSF_dsh, key, size, data, -1, -1, GNUNET_TIME_UNIT_FOREVER_REL, NULL, NULL); pr->qe_start = GNUNET_TIME_absolute_get (); pr->warn_task = GNUNET_SCHEDULER_add_delayed (GNUNET_TIME_UNIT_MINUTES, &warn_delay_task, pr); pr->qe = GNUNET_DATASTORE_get_key (GSF_dsh, pr->local_result_offset - 1, &pr->public_data.query, pr->public_data.type == GNUNET_BLOCK_TYPE_FS_DBLOCK ? GNUNET_BLOCK_TYPE_ANY : pr->public_data.type, (0 != (GSF_PRO_PRIORITY_UNLIMITED & pr->public_data.options)) ? UINT_MAX : 1 /* queue priority */ , (0 != (GSF_PRO_PRIORITY_UNLIMITED & pr->public_data.options)) ? UINT_MAX : datastore_queue_size /* max queue size */ , GNUNET_TIME_UNIT_FOREVER_REL, &process_local_reply, pr); if (pr->qe == NULL) { GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Datastore lookups concluded (error queueing)"), 1, GNUNET_NO); goto check_error_and_continue; } return; } prq.type = type; prq.priority = priority; prq.request_found = GNUNET_NO; prq.anonymity_level = anonymity; if ((old_rf == 0) && (pr->public_data.results_found == 0)) GSF_update_datastore_delay_ (pr->public_data.start_time); process_reply (&prq, key, pr); pr->local_result = prq.eval; if (prq.eval == GNUNET_BLOCK_EVALUATION_OK_LAST) { GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Datastore lookups concluded (found last result)"), 1, GNUNET_NO); goto check_error_and_continue; } if ((0 == (GSF_PRO_PRIORITY_UNLIMITED & pr->public_data.options)) && ((GNUNET_YES == GSF_test_get_load_too_high_ (0)) || (pr->public_data.results_found > 5 + 2 * pr->public_data.priority))) { #if DEBUG_FS > 2 GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Load too high, done with request\n"); #endif GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Datastore lookups concluded (load too high)"), 1, GNUNET_NO); goto check_error_and_continue; } pr->qe_start = GNUNET_TIME_absolute_get (); pr->warn_task = GNUNET_SCHEDULER_add_delayed (GNUNET_TIME_UNIT_MINUTES, &warn_delay_task, pr); pr->qe = GNUNET_DATASTORE_get_key (GSF_dsh, pr->local_result_offset++, &pr->public_data.query, pr->public_data.type == GNUNET_BLOCK_TYPE_FS_DBLOCK ? GNUNET_BLOCK_TYPE_ANY : pr->public_data.type, (0 != (GSF_PRO_PRIORITY_UNLIMITED & pr-> public_data.options)) ? UINT_MAX : 1 /* queue priority */ , (0 != (GSF_PRO_PRIORITY_UNLIMITED & pr-> public_data.options)) ? UINT_MAX : datastore_queue_size /* max queue size */ , GNUNET_TIME_UNIT_FOREVER_REL, &process_local_reply, pr); /* check if we successfully queued another datastore request; * if so, return, otherwise call our continuation (if we have * any) */ check_error_and_continue: if (NULL != pr->qe) return; if (GNUNET_SCHEDULER_NO_TASK != pr->warn_task) { GNUNET_SCHEDULER_cancel (pr->warn_task); pr->warn_task = GNUNET_SCHEDULER_NO_TASK; } if (NULL == (cont = pr->llc_cont)) return; /* no continuation */ pr->llc_cont = NULL; cont (pr->llc_cont_cls, pr, pr->local_result); } /** * Is the given target a legitimate peer for forwarding the given request? * * @param pr request * @param target * @return GNUNET_YES if this request could be forwarded to the given peer */ int GSF_pending_request_test_target_ (struct GSF_PendingRequest *pr, const struct GNUNET_PeerIdentity *target) { struct GNUNET_PeerIdentity pi; if (0 == pr->origin_pid) return GNUNET_YES; GNUNET_PEER_resolve (pr->origin_pid, &pi); return (0 == memcmp (&pi, target, sizeof (struct GNUNET_PeerIdentity))) ? GNUNET_NO : GNUNET_YES; } /** * Look up the request in the local datastore. * * @param pr the pending request to process * @param cont function to call at the end * @param cont_cls closure for cont */ void GSF_local_lookup_ (struct GSF_PendingRequest *pr, GSF_LocalLookupContinuation cont, void *cont_cls) { GNUNET_assert (NULL == pr->gh); GNUNET_assert (NULL == pr->llc_cont); pr->llc_cont = cont; pr->llc_cont_cls = cont_cls; pr->qe_start = GNUNET_TIME_absolute_get (); pr->warn_task = GNUNET_SCHEDULER_add_delayed (GNUNET_TIME_UNIT_MINUTES, &warn_delay_task, pr); GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Datastore lookups initiated"), 1, GNUNET_NO); pr->qe = GNUNET_DATASTORE_get_key (GSF_dsh, pr->local_result_offset++, &pr->public_data.query, pr->public_data.type == GNUNET_BLOCK_TYPE_FS_DBLOCK ? GNUNET_BLOCK_TYPE_ANY : pr->public_data.type, (0 != (GSF_PRO_PRIORITY_UNLIMITED & pr-> public_data.options)) ? UINT_MAX : 1 /* queue priority */ , (0 != (GSF_PRO_PRIORITY_UNLIMITED & pr-> public_data.options)) ? UINT_MAX : datastore_queue_size /* max queue size */ , GNUNET_TIME_UNIT_FOREVER_REL, &process_local_reply, pr); if (NULL != pr->qe) return; GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# Datastore lookups concluded (error queueing)"), 1, GNUNET_NO); GNUNET_SCHEDULER_cancel (pr->warn_task); pr->warn_task = GNUNET_SCHEDULER_NO_TASK; pr->llc_cont = NULL; if (NULL != cont) cont (cont_cls, pr, pr->local_result); } /** * Handle P2P "CONTENT" message. Checks that the message is * well-formed and then checks if there are any pending requests for * this content and possibly passes it on (to local clients or other * peers). Does NOT perform migration (content caching at this peer). * * @param cp the other peer involved (sender or receiver, NULL * for loopback messages where we are both sender and receiver) * @param message the actual message * @return GNUNET_OK if the message was well-formed, * GNUNET_SYSERR if the message was malformed (close connection, * do not cache under any circumstances) */ int GSF_handle_p2p_content_ (struct GSF_ConnectedPeer *cp, const struct GNUNET_MessageHeader *message) { const struct PutMessage *put; uint16_t msize; size_t dsize; enum GNUNET_BLOCK_Type type; struct GNUNET_TIME_Absolute expiration; GNUNET_HashCode query; struct ProcessReplyClosure prq; struct GNUNET_TIME_Relative block_time; double putl; struct PutMigrationContext *pmc; msize = ntohs (message->size); if (msize < sizeof (struct PutMessage)) { GNUNET_break_op (0); return GNUNET_SYSERR; } put = (const struct PutMessage *) message; dsize = msize - sizeof (struct PutMessage); type = ntohl (put->type); expiration = GNUNET_TIME_absolute_ntoh (put->expiration); if (type == GNUNET_BLOCK_TYPE_FS_ONDEMAND) return GNUNET_SYSERR; if (GNUNET_OK != GNUNET_BLOCK_get_key (GSF_block_ctx, type, &put[1], dsize, &query)) { GNUNET_break_op (0); return GNUNET_SYSERR; } GNUNET_STATISTICS_update (GSF_stats, gettext_noop ("# GAP PUT messages received"), 1, GNUNET_NO); /* now, lookup 'query' */ prq.data = (const void *) &put[1]; if (NULL != cp) prq.sender = cp; else prq.sender = NULL; prq.size = dsize; prq.type = type; prq.expiration = expiration; prq.priority = 0; prq.anonymity_level = UINT32_MAX; prq.request_found = GNUNET_NO; GNUNET_CONTAINER_multihashmap_get_multiple (pr_map, &query, &process_reply, &prq); if (NULL != cp) { GSF_connected_peer_change_preference_ (cp, CONTENT_BANDWIDTH_VALUE + 1000 * prq.priority); GSF_get_peer_performance_data_ (cp)->trust += prq.priority; } if ((GNUNET_YES == active_to_migration) && (GNUNET_NO == test_put_load_too_high (prq.priority))) { #if DEBUG_FS GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Replicating result for query `%s' with priority %u\n", GNUNET_h2s (&query), prq.priority); #endif pmc = GNUNET_malloc (sizeof (struct PutMigrationContext)); pmc->start = GNUNET_TIME_absolute_get (); pmc->requested = prq.request_found; GNUNET_assert (0 != GSF_get_peer_performance_data_ (cp)->pid); GNUNET_PEER_resolve (GSF_get_peer_performance_data_ (cp)->pid, &pmc->origin); if (NULL == GNUNET_DATASTORE_put (GSF_dsh, 0, &query, dsize, &put[1], type, prq.priority, 1 /* anonymity */ , 0 /* replication */ , expiration, 1 + prq.priority, MAX_DATASTORE_QUEUE, GNUNET_CONSTANTS_SERVICE_TIMEOUT, &put_migration_continuation, pmc)) { put_migration_continuation (pmc, GNUNET_NO, NULL); } } else { #if DEBUG_FS GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Choosing not to keep content `%s' (%d/%d)\n", GNUNET_h2s (&query), active_to_migration, test_put_load_too_high (prq.priority)); #endif } putl = GNUNET_LOAD_get_load (datastore_put_load); if ((NULL != (cp = prq.sender)) && (GNUNET_NO == prq.request_found) && ((GNUNET_YES != active_to_migration) || (putl > 2.5 * (1 + prq.priority)))) { if (GNUNET_YES != active_to_migration) putl = 1.0 + GNUNET_CRYPTO_random_u32 (GNUNET_CRYPTO_QUALITY_WEAK, 5); block_time = GNUNET_TIME_relative_multiply (GNUNET_TIME_UNIT_MILLISECONDS, 5000 + GNUNET_CRYPTO_random_u32 (GNUNET_CRYPTO_QUALITY_WEAK, (unsigned int) (60000 * putl * putl))); GSF_block_peer_migration_ (cp, block_time); } return GNUNET_OK; } /** * Setup the subsystem. */ void GSF_pending_request_init_ () { unsigned long long bps; if (GNUNET_OK != GNUNET_CONFIGURATION_get_value_number (GSF_cfg, "fs", "MAX_PENDING_REQUESTS", &max_pending_requests)) { GNUNET_log (GNUNET_ERROR_TYPE_INFO, _ ("Configuration fails to specify `%s', assuming default value."), "MAX_PENDING_REQUESTS"); } if (GNUNET_OK != GNUNET_CONFIGURATION_get_value_size (GSF_cfg, "ats", "WAN_QUOTA_OUT", &bps)) { GNUNET_log (GNUNET_ERROR_TYPE_INFO, _ ("Configuration fails to specify `%s', assuming default value."), "WAN_QUOTA_OUT"); bps = 65536; } /* queue size should be #queries we can have pending and satisfy within * a carry interval: */ datastore_queue_size = bps * GNUNET_CONSTANTS_MAX_BANDWIDTH_CARRY_S / DBLOCK_SIZE; active_to_migration = GNUNET_CONFIGURATION_get_value_yesno (GSF_cfg, "FS", "CONTENT_CACHING"); datastore_put_load = GNUNET_LOAD_value_init (DATASTORE_LOAD_AUTODECLINE); pr_map = GNUNET_CONTAINER_multihashmap_create (32 * 1024); requests_by_expiration_heap = GNUNET_CONTAINER_heap_create (GNUNET_CONTAINER_HEAP_ORDER_MIN); } /** * Shutdown the subsystem. */ void GSF_pending_request_done_ () { GNUNET_CONTAINER_multihashmap_iterate (pr_map, &clean_request, NULL); GNUNET_CONTAINER_multihashmap_destroy (pr_map); pr_map = NULL; GNUNET_CONTAINER_heap_destroy (requests_by_expiration_heap); requests_by_expiration_heap = NULL; GNUNET_LOAD_value_free (datastore_put_load); datastore_put_load = NULL; } /* end of gnunet-service-fs_pr.c */