/* Copyright (c) 2013-2020, The Tor Project, Inc. */ /* See LICENSE for licensing information */ /** * \file fp_pair.c * * \brief Manages data structures for associating pairs of fingerprints. Used * to handle combinations of identity/signing-key fingerprints for * authorities. * * This is a nice, simple, compact data structure module that handles a map * from (signing key fingerprint, identity key fingerprint) to void *. The * fingerprints here are SHA1 digests of RSA keys. * * This structure is used in directory.c and in routerlist.c for handling * handling authority certificates, since we never want more than a single * certificate for any (ID key, signing key) pair. **/ #include "core/or/or.h" #include "feature/dircommon/fp_pair.h" /* Define fp_pair_map_t structures */ struct fp_pair_map_entry_t { HT_ENTRY(fp_pair_map_entry_t) node; void *val; fp_pair_t key; }; struct fp_pair_map_t { HT_HEAD(fp_pair_map_impl, fp_pair_map_entry_t) head; }; /* * Hash function and equality checker for fp_pair_map_t */ /** Compare fp_pair_entry_t objects by key value. */ static inline int fp_pair_map_entries_eq(const fp_pair_map_entry_t *a, const fp_pair_map_entry_t *b) { return tor_memeq(&(a->key), &(b->key), sizeof(fp_pair_t)); } /** Return a hash value for an fp_pair_entry_t. */ static inline unsigned int fp_pair_map_entry_hash(const fp_pair_map_entry_t *a) { tor_assert(sizeof(a->key) == DIGEST_LEN*2); return (unsigned) siphash24g(&a->key, DIGEST_LEN*2); } /* * Hash table functions for fp_pair_map_t */ HT_PROTOTYPE(fp_pair_map_impl, fp_pair_map_entry_t, node, fp_pair_map_entry_hash, fp_pair_map_entries_eq) HT_GENERATE2(fp_pair_map_impl, fp_pair_map_entry_t, node, fp_pair_map_entry_hash, fp_pair_map_entries_eq, 0.6, tor_reallocarray_, tor_free_) /** Constructor to create a new empty map from fp_pair_t to void * */ fp_pair_map_t * fp_pair_map_new(void) { fp_pair_map_t *result; result = tor_malloc(sizeof(fp_pair_map_t)); HT_INIT(fp_pair_map_impl, &result->head); return result; } /** Set the current value for key to val; returns the previous * value for key if one was set, or NULL if one was not. */ void * fp_pair_map_set(fp_pair_map_t *map, const fp_pair_t *key, void *val) { fp_pair_map_entry_t *resolve; fp_pair_map_entry_t search; void *oldval; tor_assert(map); tor_assert(key); tor_assert(val); memcpy(&(search.key), key, sizeof(*key)); resolve = HT_FIND(fp_pair_map_impl, &(map->head), &search); if (resolve) { oldval = resolve->val; resolve->val = val; } else { resolve = tor_malloc_zero(sizeof(fp_pair_map_entry_t)); memcpy(&(resolve->key), key, sizeof(*key)); resolve->val = val; HT_INSERT(fp_pair_map_impl, &(map->head), resolve); oldval = NULL; } return oldval; } /** Set the current value for the key (first, second) to val; returns * the previous value for key if one was set, or NULL if one was not. */ void * fp_pair_map_set_by_digests(fp_pair_map_t *map, const char *first, const char *second, void *val) { fp_pair_t k; tor_assert(first); tor_assert(second); memcpy(k.first, first, DIGEST_LEN); memcpy(k.second, second, DIGEST_LEN); return fp_pair_map_set(map, &k, val); } /** Return the current value associated with key, or NULL if no value is set. */ void * fp_pair_map_get(const fp_pair_map_t *map, const fp_pair_t *key) { fp_pair_map_entry_t *resolve; fp_pair_map_entry_t search; void *val = NULL; tor_assert(map); tor_assert(key); memcpy(&(search.key), key, sizeof(*key)); resolve = HT_FIND(fp_pair_map_impl, &(map->head), &search); if (resolve) val = resolve->val; return val; } /** Return the current value associated the key (first, second), or * NULL if no value is set. */ void * fp_pair_map_get_by_digests(const fp_pair_map_t *map, const char *first, const char *second) { fp_pair_t k; tor_assert(first); tor_assert(second); memcpy(k.first, first, DIGEST_LEN); memcpy(k.second, second, DIGEST_LEN); return fp_pair_map_get(map, &k); } /** Remove the value currently associated with key from the map. * Return the value if one was set, or NULL if there was no entry for * key. The caller must free any storage associated with the * returned value. */ void * fp_pair_map_remove(fp_pair_map_t *map, const fp_pair_t *key) { fp_pair_map_entry_t *resolve; fp_pair_map_entry_t search; void *val = NULL; tor_assert(map); tor_assert(key); memcpy(&(search.key), key, sizeof(*key)); resolve = HT_REMOVE(fp_pair_map_impl, &(map->head), &search); if (resolve) { val = resolve->val; tor_free(resolve); } return val; } /** Remove all entries from map, and deallocate storage for those entries. * If free_val is provided, it is invoked on every value in map. */ void fp_pair_map_free_(fp_pair_map_t *map, void (*free_val)(void*)) { fp_pair_map_entry_t **ent, **next, *this; if (map) { for (ent = HT_START(fp_pair_map_impl, &(map->head)); ent != NULL; ent = next) { this = *ent; next = HT_NEXT_RMV(fp_pair_map_impl, &(map->head), ent); if (free_val) free_val(this->val); tor_free(this); } tor_assert(HT_EMPTY(&(map->head))); HT_CLEAR(fp_pair_map_impl, &(map->head)); tor_free(map); } } /** Return true iff map has no entries. */ int fp_pair_map_isempty(const fp_pair_map_t *map) { tor_assert(map); return HT_EMPTY(&(map->head)); } /** Return the number of items in map. */ int fp_pair_map_size(const fp_pair_map_t *map) { tor_assert(map); return HT_SIZE(&(map->head)); } /** return an iterator pointing to the start of map. */ fp_pair_map_iter_t * fp_pair_map_iter_init(fp_pair_map_t *map) { tor_assert(map); return HT_START(fp_pair_map_impl, &(map->head)); } /** Advance iter a single step to the next entry of map, and return * its new value. */ fp_pair_map_iter_t * fp_pair_map_iter_next(fp_pair_map_t *map, fp_pair_map_iter_t *iter) { tor_assert(map); tor_assert(iter); return HT_NEXT(fp_pair_map_impl, &(map->head), iter); } /** Advance iter a single step to the next entry of map, removing the current * entry, and return its new value. */ fp_pair_map_iter_t * fp_pair_map_iter_next_rmv(fp_pair_map_t *map, fp_pair_map_iter_t *iter) { fp_pair_map_entry_t *rmv; tor_assert(map); tor_assert(iter); tor_assert(*iter); rmv = *iter; iter = HT_NEXT_RMV(fp_pair_map_impl, &(map->head), iter); tor_free(rmv); return iter; } /** Set *key_out and *val_out to the current entry pointed to by iter. */ void fp_pair_map_iter_get(fp_pair_map_iter_t *iter, fp_pair_t *key_out, void **val_out) { tor_assert(iter); tor_assert(*iter); if (key_out) memcpy(key_out, &((*iter)->key), sizeof(fp_pair_t)); if (val_out) *val_out = (*iter)->val; } /** Return true iff iter has advanced past the last entry of its map. */ int fp_pair_map_iter_done(fp_pair_map_iter_t *iter) { return (iter == NULL); } /** Assert if anything has gone wrong with the internal * representation of map. */ void fp_pair_map_assert_ok(const fp_pair_map_t *map) { tor_assert(!fp_pair_map_impl_HT_REP_IS_BAD_(&(map->head))); }