/* This file is part of GNUnet (C) 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010 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/fs_namespace.c * @brief create and destroy namespaces * @author Christian Grothoff */ #include "platform.h" #include "gnunet_constants.h" #include "gnunet_signatures.h" #include "gnunet_util_lib.h" #include "gnunet_fs_service.h" #include "fs_api.h" /** * Maximum legal size for an sblock. */ #define MAX_SBLOCK_SIZE (60 * 1024) /** * Return the name of the directory in which we store * our local namespaces (or rather, their public keys). * * @param h global fs handle * @return NULL on error, otherwise the name of the directory */ static char * get_namespace_directory (struct GNUNET_FS_Handle *h) { char *dn; if (GNUNET_OK != GNUNET_CONFIGURATION_get_value_filename (h->cfg, "FS", "IDENTITY_DIR", &dn)) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, _("Configuration fails to specify `%s' in section `%s'\n"), "IDENTITY_DIR", "fs"); return NULL; } return dn; } /** * Return the name of the directory in which we store * the update information graph for the given local namespace. * * @param ns namespace handle * @return NULL on error, otherwise the name of the directory */ static char * get_update_information_directory (struct GNUNET_FS_Namespace *ns) { char *dn; char *ret; if (GNUNET_OK != GNUNET_CONFIGURATION_get_value_filename (ns->h->cfg, "FS", "UPDATE_DIR", &dn)) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, _("Configuration fails to specify `%s' in section `%s'\n"), "UPDATE_DIR", "fs"); return NULL; } GNUNET_asprintf (&ret, "%s%s%s", dn, DIR_SEPARATOR_STR, ns->name); GNUNET_free (dn); return ret; } /** * Write the namespace update node graph to a file. * * @param ns namespace to dump */ static void write_update_information_graph (struct GNUNET_FS_Namespace *ns) { char *fn; struct GNUNET_BIO_WriteHandle *wh; unsigned int i; struct NamespaceUpdateNode *n; char *uris; fn = get_update_information_directory (ns); wh = GNUNET_BIO_write_open (fn); if (wh == NULL) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, _("Failed to open `%s' for writing: %s\n"), STRERROR (errno)); GNUNET_free (fn); return; } if (GNUNET_OK != GNUNET_BIO_write_int32 (wh, ns->update_node_count)) goto END; for (i = 0; i < ns->update_node_count; i++) { n = ns->update_nodes[i]; uris = GNUNET_FS_uri_to_string (n->uri); if ((GNUNET_OK != GNUNET_BIO_write_string (wh, n->id)) || (GNUNET_OK != GNUNET_BIO_write_meta_data (wh, n->md)) || (GNUNET_OK != GNUNET_BIO_write_string (wh, n->update)) || (GNUNET_OK != GNUNET_BIO_write_string (wh, uris))) { GNUNET_free (uris); break; } GNUNET_free (uris); } END: if (GNUNET_OK != GNUNET_BIO_write_close (wh)) GNUNET_log (GNUNET_ERROR_TYPE_ERROR, _("Failed to write `%s': %s\n"), STRERROR (errno)); GNUNET_free (fn); } /** * Read the namespace update node graph from a file. * * @param ns namespace to read */ static void read_update_information_graph (struct GNUNET_FS_Namespace *ns) { char *fn; struct GNUNET_BIO_ReadHandle *rh; unsigned int i; struct NamespaceUpdateNode *n; char *uris; uint32_t count; char *emsg; fn = get_update_information_directory (ns); if (GNUNET_YES != GNUNET_DISK_file_test (fn)) { GNUNET_free (fn); return; } rh = GNUNET_BIO_read_open (fn); if (rh == NULL) { GNUNET_free (fn); return; } if (GNUNET_OK != GNUNET_BIO_read_int32 (rh, &count)) { GNUNET_break (0); goto END; } if (count > 1024 * 1024) { GNUNET_break (0); goto END; } if (count == 0) { GNUNET_break (GNUNET_OK == GNUNET_BIO_read_close (rh, NULL)); GNUNET_free (fn); return; } ns->update_nodes = GNUNET_malloc (count * sizeof (struct NamespaceUpdateNode *)); for (i = 0; i < count; i++) { n = GNUNET_malloc (sizeof (struct NamespaceUpdateNode)); if ((GNUNET_OK != GNUNET_BIO_read_string (rh, "identifier", &n->id, 1024)) || (GNUNET_OK != GNUNET_BIO_read_meta_data (rh, "meta", &n->md)) || (GNUNET_OK != GNUNET_BIO_read_string (rh, "update-id", &n->update, 1024)) || (GNUNET_OK != GNUNET_BIO_read_string (rh, "uri", &uris, 1024 * 2))) { GNUNET_break (0); GNUNET_free_non_null (n->id); GNUNET_free_non_null (n->update); if (n->md != NULL) GNUNET_CONTAINER_meta_data_destroy (n->md); GNUNET_free (n); break; } n->uri = GNUNET_FS_uri_parse (uris, &emsg); GNUNET_free (uris); if (n->uri == NULL) { GNUNET_break (0); GNUNET_free (emsg); GNUNET_free (n->id); GNUNET_free_non_null (n->update); GNUNET_CONTAINER_meta_data_destroy (n->md); GNUNET_free (n); break; } ns->update_nodes[i] = n; } ns->update_node_count = i; END: if (GNUNET_OK != GNUNET_BIO_read_close (rh, &emsg)) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, _("Failed to write `%s': %s\n"), emsg); GNUNET_free (emsg); } GNUNET_free (fn); } /** * Create a namespace with the given name; if one already * exists, return a handle to the existing namespace. * * @param h handle to the file sharing subsystem * @param name name to use for the namespace * @return handle to the namespace, NULL on error */ struct GNUNET_FS_Namespace * GNUNET_FS_namespace_create (struct GNUNET_FS_Handle *h, const char *name) { char *dn; char *fn; struct GNUNET_FS_Namespace *ret; dn = get_namespace_directory (h); GNUNET_asprintf (&fn, "%s%s%s", dn, DIR_SEPARATOR_STR, name); GNUNET_free (dn); ret = GNUNET_malloc (sizeof (struct GNUNET_FS_Namespace)); ret->h = h; ret->rc = 1; ret->key = GNUNET_CRYPTO_rsa_key_create_from_file (fn); if (ret->key == NULL) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, _("Failed to create or read private key for namespace `%s'\n"), name); GNUNET_free (ret); GNUNET_free (fn); return NULL; } ret->name = GNUNET_strdup (name); ret->filename = fn; return ret; } /** * Duplicate a namespace handle. * * @param ns namespace handle * @return duplicated handle to the namespace */ struct GNUNET_FS_Namespace * GNUNET_FS_namespace_dup (struct GNUNET_FS_Namespace *ns) { ns->rc++; return ns; } /** * Delete a namespace handle. Can be used for a clean shutdown (free * memory) or also to freeze the namespace to prevent further * insertions by anyone. * * @param namespace handle to the namespace that should be deleted / freed * @param freeze prevents future insertions; creating a namespace * with the same name again will create a fresh namespace instead * * @return GNUNET_OK on success, GNUNET_SYSERR on error */ int GNUNET_FS_namespace_delete (struct GNUNET_FS_Namespace *namespace, int freeze) { unsigned int i; struct NamespaceUpdateNode *nsn; namespace->rc--; if (freeze) { if (0 != UNLINK (namespace->filename)) GNUNET_log_strerror_file (GNUNET_ERROR_TYPE_ERROR, "unlink", namespace->filename); } if (0 != namespace->rc) return GNUNET_OK; GNUNET_CRYPTO_rsa_key_free (namespace->key); GNUNET_free (namespace->filename); GNUNET_free (namespace->name); for (i = 0; i < namespace->update_node_count; i++) { nsn = namespace->update_nodes[i]; GNUNET_CONTAINER_meta_data_destroy (nsn->md); GNUNET_FS_uri_destroy (nsn->uri); GNUNET_free (nsn->id); GNUNET_free (nsn->update); GNUNET_free (nsn); } GNUNET_array_grow (namespace->update_nodes, namespace->update_node_count, 0); if (namespace->update_map != NULL) GNUNET_CONTAINER_multihashmap_destroy (namespace->update_map); GNUNET_free (namespace); return GNUNET_OK; } /** * Context for the 'process_namespace' callback. * Specifies a function to call on each namespace. */ struct ProcessNamespaceContext { /** * Function to call. */ GNUNET_FS_NamespaceInfoProcessor cb; /** * Closure for 'cb'. */ void *cb_cls; }; /** * Function called with a filename of a namespace. Reads the key and * calls the callback. * * @param cls closure (struct ProcessNamespaceContext) * @param filename complete filename (absolute path) * @return GNUNET_OK to continue to iterate, * GNUNET_SYSERR to abort iteration with error! */ static int process_namespace (void *cls, const char *filename) { struct ProcessNamespaceContext *pnc = cls; struct GNUNET_CRYPTO_RsaPrivateKey *key; struct GNUNET_CRYPTO_RsaPublicKeyBinaryEncoded pk; GNUNET_HashCode id; const char *name; const char *t; key = GNUNET_CRYPTO_rsa_key_create_from_file (filename); if (key == NULL) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, _ ("Failed to read namespace private key file `%s', deleting it!\n"), filename); if (0 != UNLINK (filename)) GNUNET_log_strerror_file (GNUNET_ERROR_TYPE_WARNING, "unlink", filename); return GNUNET_OK; } GNUNET_CRYPTO_rsa_key_get_public (key, &pk); GNUNET_CRYPTO_rsa_key_free (key); GNUNET_CRYPTO_hash (&pk, sizeof (pk), &id); name = filename; while (NULL != (t = strstr (name, DIR_SEPARATOR_STR))) name = t + 1; pnc->cb (pnc->cb_cls, name, &id); return GNUNET_OK; } /** * Build a list of all available local (!) namespaces The returned * names are only the nicknames since we only iterate over the local * namespaces. * * @param h handle to the file sharing subsystem * @param cb function to call on each known namespace * @param cb_cls closure for cb */ void GNUNET_FS_namespace_list (struct GNUNET_FS_Handle *h, GNUNET_FS_NamespaceInfoProcessor cb, void *cb_cls) { char *dn; struct ProcessNamespaceContext ctx; dn = get_namespace_directory (h); if (dn == NULL) return; ctx.cb = cb; ctx.cb_cls = cb_cls; GNUNET_DISK_directory_scan (dn, &process_namespace, &ctx); GNUNET_free (dn); } /** * Context for the SKS publication. */ struct GNUNET_FS_PublishSksContext { /** * URI of the new entry in the namespace. */ struct GNUNET_FS_Uri *uri; /** * Namespace update node to add to namespace on success (or to be * deleted if publishing failed). */ struct NamespaceUpdateNode *nsn; /** * Namespace we're publishing to. */ struct GNUNET_FS_Namespace *namespace; /** * Handle to the datastore. */ struct GNUNET_DATASTORE_Handle *dsh; /** * Function to call once we're done. */ GNUNET_FS_PublishContinuation cont; /** * Closure for cont. */ void *cont_cls; /** * Handle for our datastore request. */ struct GNUNET_DATASTORE_QueueEntry *dqe; }; /** * Function called by the datastore API with * the result from the PUT (SBlock) request. * * @param cls closure of type "struct GNUNET_FS_PublishSksContext*" * @param success GNUNET_OK on success * @param min_expiration minimum expiration time required for content to be stored * @param msg error message (or NULL) */ static void sb_put_cont (void *cls, int success, struct GNUNET_TIME_Absolute min_expiration, const char *msg) { struct GNUNET_FS_PublishSksContext *psc = cls; GNUNET_HashCode hc; psc->dqe = NULL; if (GNUNET_OK != success) { if (NULL != psc->cont) psc->cont (psc->cont_cls, NULL, msg); GNUNET_FS_publish_sks_cancel (psc); return; } if (NULL != psc->nsn) { /* FIXME: this can be done much more * efficiently by simply appending to the * file and overwriting the 4-byte header */ if (psc->namespace->update_nodes == NULL) read_update_information_graph (psc->namespace); GNUNET_array_append (psc->namespace->update_nodes, psc->namespace->update_node_count, psc->nsn); if (psc->namespace->update_map != NULL) { GNUNET_CRYPTO_hash (psc->nsn->id, strlen (psc->nsn->id), &hc); GNUNET_CONTAINER_multihashmap_put (psc->namespace->update_map, &hc, psc->nsn, GNUNET_CONTAINER_MULTIHASHMAPOPTION_MULTIPLE); } psc->nsn = NULL; write_update_information_graph (psc->namespace); } if (NULL != psc->cont) psc->cont (psc->cont_cls, psc->uri, NULL); GNUNET_FS_publish_sks_cancel (psc); } /** * Publish an SBlock on GNUnet. * * @param h handle to the file sharing subsystem * @param namespace namespace to publish in * @param identifier identifier to use * @param update update identifier to use * @param meta metadata to use * @param uri URI to refer to in the SBlock * @param bo block options * @param options publication options * @param cont continuation * @param cont_cls closure for cont * @return NULL on error ('cont' will still be called) */ struct GNUNET_FS_PublishSksContext * GNUNET_FS_publish_sks (struct GNUNET_FS_Handle *h, struct GNUNET_FS_Namespace *namespace, const char *identifier, const char *update, const struct GNUNET_CONTAINER_MetaData *meta, const struct GNUNET_FS_Uri *uri, const struct GNUNET_FS_BlockOptions *bo, enum GNUNET_FS_PublishOptions options, GNUNET_FS_PublishContinuation cont, void *cont_cls) { struct GNUNET_FS_PublishSksContext *psc; struct GNUNET_CRYPTO_AesSessionKey sk; struct GNUNET_CRYPTO_AesInitializationVector iv; struct GNUNET_FS_Uri *sks_uri; char *uris; size_t size; size_t slen; size_t nidlen; size_t idlen; ssize_t mdsize; struct SBlock *sb; struct SBlock *sb_enc; char *dest; struct GNUNET_CONTAINER_MetaData *mmeta; GNUNET_HashCode key; /* hash of thisId = key */ GNUNET_HashCode id; /* hash of hc = identifier */ GNUNET_HashCode query; /* id ^ nsid = DB query */ if (NULL == meta) mmeta = GNUNET_CONTAINER_meta_data_create (); else mmeta = GNUNET_CONTAINER_meta_data_duplicate (meta); uris = GNUNET_FS_uri_to_string (uri); slen = strlen (uris) + 1; idlen = strlen (identifier); if (update != NULL) nidlen = strlen (update) + 1; else nidlen = 1; mdsize = GNUNET_CONTAINER_meta_data_get_serialized_size (mmeta); size = sizeof (struct SBlock) + slen + nidlen + mdsize; if (size > MAX_SBLOCK_SIZE) { size = MAX_SBLOCK_SIZE; mdsize = size - (sizeof (struct SBlock) + slen + nidlen); } sb = GNUNET_malloc (sizeof (struct SBlock) + size); dest = (char *) &sb[1]; if (update != NULL) memcpy (dest, update, nidlen); else memset (dest, 0, 1); dest += nidlen; memcpy (dest, uris, slen); GNUNET_free (uris); dest += slen; mdsize = GNUNET_CONTAINER_meta_data_serialize (mmeta, &dest, mdsize, GNUNET_CONTAINER_META_DATA_SERIALIZE_PART); GNUNET_CONTAINER_meta_data_destroy (mmeta); if (mdsize == -1) { GNUNET_break (0); GNUNET_free (sb); if (NULL != cont) cont (cont_cls, NULL, _("Internal error.")); return NULL; } size = sizeof (struct SBlock) + mdsize + slen + nidlen; sb_enc = GNUNET_malloc (size); GNUNET_CRYPTO_hash (identifier, idlen, &key); GNUNET_CRYPTO_hash (&key, sizeof (GNUNET_HashCode), &id); sks_uri = GNUNET_malloc (sizeof (struct GNUNET_FS_Uri)); sks_uri->type = sks; GNUNET_CRYPTO_rsa_key_get_public (namespace->key, &sb_enc->subspace); GNUNET_CRYPTO_hash (&sb_enc->subspace, sizeof (struct GNUNET_CRYPTO_RsaPublicKeyBinaryEncoded), &sks_uri->data.sks.namespace); sks_uri->data.sks.identifier = GNUNET_strdup (identifier); GNUNET_CRYPTO_hash_xor (&id, &sks_uri->data.sks.namespace, &sb_enc->identifier); GNUNET_CRYPTO_hash_to_aes_key (&key, &sk, &iv); GNUNET_CRYPTO_aes_encrypt (&sb[1], size - sizeof (struct SBlock), &sk, &iv, &sb_enc[1]); sb_enc->purpose.purpose = htonl (GNUNET_SIGNATURE_PURPOSE_FS_SBLOCK); sb_enc->purpose.size = htonl (slen + mdsize + nidlen + sizeof (struct SBlock) - sizeof (struct GNUNET_CRYPTO_RsaSignature)); GNUNET_assert (GNUNET_OK == GNUNET_CRYPTO_rsa_sign (namespace->key, &sb_enc->purpose, &sb_enc->signature)); psc = GNUNET_malloc (sizeof (struct GNUNET_FS_PublishSksContext)); psc->uri = sks_uri; psc->cont = cont; psc->namespace = GNUNET_FS_namespace_dup (namespace); psc->cont_cls = cont_cls; if (0 != (options & GNUNET_FS_PUBLISH_OPTION_SIMULATE_ONLY)) { GNUNET_free (sb_enc); GNUNET_free (sb); sb_put_cont (psc, GNUNET_OK, GNUNET_TIME_UNIT_ZERO_ABS, NULL); return NULL; } psc->dsh = GNUNET_DATASTORE_connect (h->cfg); if (NULL == psc->dsh) { GNUNET_free (sb_enc); GNUNET_free (sb); sb_put_cont (psc, GNUNET_NO, GNUNET_TIME_UNIT_ZERO_ABS, _("Failed to connect to datastore.")); return NULL; } GNUNET_CRYPTO_hash_xor (&sks_uri->data.sks.namespace, &id, &query); if (NULL != update) { psc->nsn = GNUNET_malloc (sizeof (struct NamespaceUpdateNode)); psc->nsn->id = GNUNET_strdup (identifier); psc->nsn->update = GNUNET_strdup (update); psc->nsn->md = GNUNET_CONTAINER_meta_data_duplicate (meta); psc->nsn->uri = GNUNET_FS_uri_dup (uri); } psc->dqe = GNUNET_DATASTORE_put (psc->dsh, 0, &sb_enc->identifier, size, sb_enc, GNUNET_BLOCK_TYPE_FS_SBLOCK, bo->content_priority, bo->anonymity_level, bo->replication_level, bo->expiration_time, -2, 1, GNUNET_CONSTANTS_SERVICE_TIMEOUT, &sb_put_cont, psc); GNUNET_free (sb); GNUNET_free (sb_enc); return psc; } /** * Abort the SKS publishing operation. * * @param psc context of the operation to abort. */ void GNUNET_FS_publish_sks_cancel (struct GNUNET_FS_PublishSksContext *psc) { if (NULL != psc->dqe) { GNUNET_DATASTORE_cancel (psc->dqe); psc->dqe = NULL; } if (NULL != psc->dsh) { GNUNET_DATASTORE_disconnect (psc->dsh, GNUNET_NO); psc->dsh = NULL; } GNUNET_FS_namespace_delete (psc->namespace, GNUNET_NO); GNUNET_FS_uri_destroy (psc->uri); if (NULL != psc->nsn) { GNUNET_CONTAINER_meta_data_destroy (psc->nsn->md); GNUNET_FS_uri_destroy (psc->nsn->uri); GNUNET_free (psc->nsn->id); GNUNET_free (psc->nsn->update); GNUNET_free (psc->nsn); } GNUNET_free (psc); } /** * Closure for 'process_update_node'. */ struct ProcessUpdateClosure { /** * Function to call for each node. */ GNUNET_FS_IdentifierProcessor ip; /** * Closure for 'ip'. */ void *ip_cls; }; /** * Call the iterator in the closure for each node. * * @param cls closure (of type 'struct ProcessUpdateClosure *') * @param key current key code * @param value value in the hash map (of type 'struct NamespaceUpdateNode *') * @return GNUNET_YES if we should continue to * iterate, * GNUNET_NO if not. */ static int process_update_node (void *cls, const GNUNET_HashCode * key, void *value) { struct ProcessUpdateClosure *pc = cls; struct NamespaceUpdateNode *nsn = value; pc->ip (pc->ip_cls, nsn->id, nsn->uri, nsn->md, nsn->update); return GNUNET_YES; } /** * Closure for 'find_trees'. */ struct FindTreeClosure { /** * Namespace we are operating on. */ struct GNUNET_FS_Namespace *namespace; /** * Array with 'head's of TREEs. */ struct NamespaceUpdateNode **tree_array; /** * Size of 'tree_array' */ unsigned int tree_array_size; /** * Current generational ID used. */ unsigned int nug; /** * Identifier for the current TREE, or UINT_MAX for none yet. */ unsigned int id; }; /** * Find all nodes reachable from the current node (including the * current node itself). If they are in no tree, add them to the * current one. If they are the head of another tree, merge the * trees. If they are in the middle of another tree, let them be. * We can tell that a node is already in an tree by checking if * its 'nug' field is set to the current 'nug' value. It is the * head of an tree if it is in the 'tree_array' under its respective * 'tree_id'. * * In short, we're trying to find the smallest number of tree to * cover a directed graph. * * @param cls closure (of type 'struct FindTreeClosure') * @param key current key code * @param value value in the hash map * @return GNUNET_YES if we should continue to * iterate, * GNUNET_NO if not. */ static int find_trees (void *cls, const GNUNET_HashCode * key, void *value) { struct FindTreeClosure *fc = cls; struct NamespaceUpdateNode *nsn = value; GNUNET_HashCode hc; if (nsn->nug == fc->nug) { if (nsn->tree_id == UINT_MAX) return GNUNET_YES; /* circular */ GNUNET_assert (nsn->tree_id < fc->tree_array_size); if (fc->tree_array[nsn->tree_id] != nsn) return GNUNET_YES; /* part of "another" (directed) TREE, * and not root of it, end trace */ if (nsn->tree_id == fc->id) return GNUNET_YES; /* that's our own root (can this be?) */ /* merge existing TREE, we have a root for both */ fc->tree_array[nsn->tree_id] = NULL; if (fc->id == UINT_MAX) fc->id = nsn->tree_id; /* take over ID */ } else { nsn->nug = fc->nug; nsn->tree_id = UINT_MAX; /* mark as undef */ /* trace */ GNUNET_CRYPTO_hash (nsn->update, strlen (nsn->update), &hc); GNUNET_CONTAINER_multihashmap_get_multiple (fc->namespace->update_map, &hc, &find_trees, fc); } return GNUNET_YES; } /** * List all of the identifiers in the namespace for which we could * produce an update. Namespace updates form a graph where each node * has a name. Each node can have any number of URI/meta-data entries * which can each be linked to other nodes. Cycles are possible. * * Calling this function with "next_id" NULL will cause the library to * call "ip" with a root for each strongly connected component of the * graph (a root being a node from which all other nodes in the Tree * are reachable). * * Calling this function with "next_id" being the name of a node will * cause the library to call "ip" with all children of the node. Note * that cycles within the final tree are possible (including self-loops). * I know, odd definition of a tree, but the GUI will display an actual * tree (GtkTreeView), so that's what counts for the term here. * * @param namespace namespace to inspect for updateable content * @param next_id ID to look for; use NULL to look for tree roots * @param ip function to call on each updateable identifier * @param ip_cls closure for ip */ void GNUNET_FS_namespace_list_updateable (struct GNUNET_FS_Namespace *namespace, const char *next_id, GNUNET_FS_IdentifierProcessor ip, void *ip_cls) { unsigned int i; unsigned int nug; GNUNET_HashCode hc; struct NamespaceUpdateNode *nsn; struct ProcessUpdateClosure pc; struct FindTreeClosure fc; if (namespace->update_nodes == NULL) read_update_information_graph (namespace); if (namespace->update_nodes == NULL) { GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "No updateable nodes found for ID `%s'\n", next_id); return; /* no nodes */ } if (namespace->update_map == NULL) { /* need to construct */ namespace->update_map = GNUNET_CONTAINER_multihashmap_create (2 + 3 * namespace->update_node_count / 4); for (i = 0; i < namespace->update_node_count; i++) { nsn = namespace->update_nodes[i]; GNUNET_CRYPTO_hash (nsn->id, strlen (nsn->id), &hc); GNUNET_CONTAINER_multihashmap_put (namespace->update_map, &hc, nsn, GNUNET_CONTAINER_MULTIHASHMAPOPTION_MULTIPLE); } } if (next_id != NULL) { GNUNET_CRYPTO_hash (next_id, strlen (next_id), &hc); pc.ip = ip; pc.ip_cls = ip_cls; GNUNET_CONTAINER_multihashmap_get_multiple (namespace->update_map, &hc, &process_update_node, &pc); return; } GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Calculating TREEs to find roots of update trees\n"); /* Find heads of TREEs in update graph */ nug = ++namespace->nug_gen; fc.tree_array = NULL; fc.tree_array_size = 0; for (i = 0; i < namespace->update_node_count; i++) { nsn = namespace->update_nodes[i]; if (nsn->nug == nug) { GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "TREE of node `%s' is %u\n", nsn->id, nsn->nug); continue; /* already placed in TREE */ } GNUNET_CRYPTO_hash (nsn->update, strlen (nsn->update), &hc); nsn->nug = nug; nsn->tree_id = UINT_MAX; fc.id = UINT_MAX; fc.nug = nug; fc.namespace = namespace; GNUNET_CONTAINER_multihashmap_get_multiple (namespace->update_map, &hc, &find_trees, &fc); if (fc.id == UINT_MAX) { /* start new TREE */ for (fc.id = 0; fc.id < fc.tree_array_size; fc.id++) { if (fc.tree_array[fc.id] == NULL) { fc.tree_array[fc.id] = nsn; nsn->tree_id = fc.id; break; } } if (fc.id == fc.tree_array_size) { GNUNET_array_append (fc.tree_array, fc.tree_array_size, nsn); nsn->tree_id = fc.id; } GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Starting new TREE %u with node `%s'\n", nsn->tree_id, nsn->id); /* put all nodes with same identifier into this TREE */ GNUNET_CRYPTO_hash (nsn->id, strlen (nsn->id), &hc); fc.id = nsn->tree_id; fc.nug = nug; fc.namespace = namespace; GNUNET_CONTAINER_multihashmap_get_multiple (namespace->update_map, &hc, &find_trees, &fc); } else { /* make head of TREE "id" */ fc.tree_array[fc.id] = nsn; nsn->tree_id = fc.id; } GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "TREE of node `%s' is %u\n", nsn->id, fc.id); } for (i = 0; i < fc.tree_array_size; i++) { nsn = fc.tree_array[i]; if (NULL != nsn) { GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Root of TREE %u is node `%s'\n", i, nsn->id); ip (ip_cls, nsn->id, nsn->uri, nsn->md, nsn->update); } } GNUNET_array_grow (fc.tree_array, fc.tree_array_size, 0); GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Done processing TREEs\n"); } /* end of fs_namespace.c */