/* * hash.c: chained hash tables for domain and domain/connection deallocations * * Reference: Your favorite introductory book on algorithms * * Copyright (C) 2000 Bjorn Reese and Daniel Veillard. * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR IMPLIED * WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED WARRANTIES OF * MERCHANTIBILITY AND FITNESS FOR A PARTICULAR PURPOSE. THE AUTHORS AND * CONTRIBUTORS ACCEPT NO RESPONSIBILITY IN ANY CONCEIVABLE MANNER. * * Author: breese@users.sourceforge.net * Daniel Veillard */ #include #include #include #include #include "virterror_internal.h" #include "hash.h" #include "memory.h" #define MAX_HASH_LEN 8 /* #define DEBUG_GROW */ /* * A single entry in the hash table */ typedef struct _virHashEntry virHashEntry; typedef virHashEntry *virHashEntryPtr; struct _virHashEntry { struct _virHashEntry *next; char *name; void *payload; int valid; }; /* * The entire hash table */ struct _virHashTable { struct _virHashEntry *table; int size; int nbElems; }; /* * virHashComputeKey: * Calculate the hash key */ static unsigned long virHashComputeKey(virHashTablePtr table, const char *name) { unsigned long value = 0L; char ch; if (name != NULL) { value += 30 * (*name); while ((ch = *name++) != 0) { value = value ^ ((value << 5) + (value >> 3) + (unsigned long) ch); } } return (value % table->size); } /** * virHashCreate: * @size: the size of the hash table * * Create a new virHashTablePtr. * * Returns the newly created object, or NULL if an error occured. */ virHashTablePtr virHashCreate(int size) { virHashTablePtr table = NULL; if (size <= 0) size = 256; if (VIR_ALLOC(table) < 0) return NULL; table->size = size; table->nbElems = 0; if (VIR_ALLOC_N(table->table, size) < 0) { VIR_FREE(table); return NULL; } return table; } /** * virHashGrow: * @table: the hash table * @size: the new size of the hash table * * resize the hash table * * Returns 0 in case of success, -1 in case of failure */ static int virHashGrow(virHashTablePtr table, int size) { unsigned long key; int oldsize, i; virHashEntryPtr iter, next; struct _virHashEntry *oldtable; #ifdef DEBUG_GROW unsigned long nbElem = 0; #endif if (table == NULL) return (-1); if (size < 8) return (-1); if (size > 8 * 2048) return (-1); oldsize = table->size; oldtable = table->table; if (oldtable == NULL) return (-1); if (VIR_ALLOC_N(table->table, size) < 0) { table->table = oldtable; return (-1); } table->size = size; /* If the two loops are merged, there would be situations where * a new entry needs to allocated and data copied into it from * the main table. So instead, we run through the array twice, first * copying all the elements in the main array (where we can't get * conflicts) and then the rest, so we only free (and don't allocate) */ for (i = 0; i < oldsize; i++) { if (oldtable[i].valid == 0) continue; key = virHashComputeKey(table, oldtable[i].name); memcpy(&(table->table[key]), &(oldtable[i]), sizeof(virHashEntry)); table->table[key].next = NULL; } for (i = 0; i < oldsize; i++) { iter = oldtable[i].next; while (iter) { next = iter->next; /* * put back the entry in the new table */ key = virHashComputeKey(table, iter->name); if (table->table[key].valid == 0) { memcpy(&(table->table[key]), iter, sizeof(virHashEntry)); table->table[key].next = NULL; VIR_FREE(iter); } else { iter->next = table->table[key].next; table->table[key].next = iter; } #ifdef DEBUG_GROW nbElem++; #endif iter = next; } } VIR_FREE(oldtable); #ifdef DEBUG_GROW xmlGenericError(xmlGenericErrorContext, "virHashGrow : from %d to %d, %d elems\n", oldsize, size, nbElem); #endif return (0); } /** * virHashFree: * @table: the hash table * @f: the deallocator function for items in the hash * * Free the hash @table and its contents. The userdata is * deallocated with @f if provided. */ void virHashFree(virHashTablePtr table, virHashDeallocator f) { int i; virHashEntryPtr iter; virHashEntryPtr next; int inside_table = 0; int nbElems; if (table == NULL) return; if (table->table) { nbElems = table->nbElems; for (i = 0; (i < table->size) && (nbElems > 0); i++) { iter = &(table->table[i]); if (iter->valid == 0) continue; inside_table = 1; while (iter) { next = iter->next; if ((f != NULL) && (iter->payload != NULL)) f(iter->payload, iter->name); VIR_FREE(iter->name); iter->payload = NULL; if (!inside_table) VIR_FREE(iter); nbElems--; inside_table = 0; iter = next; } inside_table = 0; } VIR_FREE(table->table); } VIR_FREE(table); } /** * virHashAddEntry3: * @table: the hash table * @name: the name of the userdata * @userdata: a pointer to the userdata * * Add the @userdata to the hash @table. This can later be retrieved * by using @name. Duplicate entries generate errors. * * Returns 0 the addition succeeded and -1 in case of error. */ int virHashAddEntry(virHashTablePtr table, const char *name, void *userdata) { unsigned long key, len = 0; virHashEntryPtr entry; virHashEntryPtr insert; if ((table == NULL) || (name == NULL)) return (-1); /* * Check for duplicate and insertion location. */ key = virHashComputeKey(table, name); if (table->table[key].valid == 0) { insert = NULL; } else { for (insert = &(table->table[key]); insert->next != NULL; insert = insert->next) { if (STREQ(insert->name, name)) return (-1); len++; } if (STREQ(insert->name, name)) return (-1); } if (insert == NULL) { entry = &(table->table[key]); } else { if (VIR_ALLOC(entry) < 0) return (-1); } entry->name = strdup(name); entry->payload = userdata; entry->next = NULL; entry->valid = 1; if (insert != NULL) insert->next = entry; table->nbElems++; if (len > MAX_HASH_LEN) virHashGrow(table, MAX_HASH_LEN * table->size); return (0); } /** * virHashUpdateEntry: * @table: the hash table * @name: the name of the userdata * @userdata: a pointer to the userdata * @f: the deallocator function for replaced item (if any) * * Add the @userdata to the hash @table. This can later be retrieved * by using @name. Existing entry for this tuple * will be removed and freed with @f if found. * * Returns 0 the addition succeeded and -1 in case of error. */ int virHashUpdateEntry(virHashTablePtr table, const char *name, void *userdata, virHashDeallocator f) { unsigned long key; virHashEntryPtr entry; virHashEntryPtr insert; if ((table == NULL) || name == NULL) return (-1); /* * Check for duplicate and insertion location. */ key = virHashComputeKey(table, name); if (table->table[key].valid == 0) { insert = NULL; } else { for (insert = &(table->table[key]); insert->next != NULL; insert = insert->next) { if (STREQ(insert->name, name)) { if (f) f(insert->payload, insert->name); insert->payload = userdata; return (0); } } if (STREQ(insert->name, name)) { if (f) f(insert->payload, insert->name); insert->payload = userdata; return (0); } } if (insert == NULL) { entry = &(table->table[key]); } else { if (VIR_ALLOC(entry) < 0) return (-1); } entry->name = strdup(name); entry->payload = userdata; entry->next = NULL; entry->valid = 1; table->nbElems++; if (insert != NULL) { insert->next = entry; } return (0); } /** * virHashLookup: * @table: the hash table * @name: the name of the userdata * * Find the userdata specified by the (@name, @name2, @name3) tuple. * * Returns the a pointer to the userdata */ void * virHashLookup(virHashTablePtr table, const char *name) { unsigned long key; virHashEntryPtr entry; if (table == NULL) return (NULL); if (name == NULL) return (NULL); key = virHashComputeKey(table, name); if (table->table[key].valid == 0) return (NULL); for (entry = &(table->table[key]); entry != NULL; entry = entry->next) { if (STREQ(entry->name, name)) return (entry->payload); } return (NULL); } /** * virHashSize: * @table: the hash table * * Query the number of elements installed in the hash @table. * * Returns the number of elements in the hash table or * -1 in case of error */ int virHashSize(virHashTablePtr table) { if (table == NULL) return (-1); return (table->nbElems); } /** * virHashRemoveEntry: * @table: the hash table * @name: the name of the userdata * @f: the deallocator function for removed item (if any) * * Find the userdata specified by the @name and remove * it from the hash @table. Existing userdata for this tuple will be removed * and freed with @f. * * Returns 0 if the removal succeeded and -1 in case of error or not found. */ int virHashRemoveEntry(virHashTablePtr table, const char *name, virHashDeallocator f) { unsigned long key; virHashEntryPtr entry; virHashEntryPtr prev = NULL; if (table == NULL || name == NULL) return (-1); key = virHashComputeKey(table, name); if (table->table[key].valid == 0) { return (-1); } else { for (entry = &(table->table[key]); entry != NULL; entry = entry->next) { if (STREQ(entry->name, name)) { if ((f != NULL) && (entry->payload != NULL)) f(entry->payload, entry->name); entry->payload = NULL; VIR_FREE(entry->name); if (prev) { prev->next = entry->next; VIR_FREE(entry); } else { if (entry->next == NULL) { entry->valid = 0; } else { entry = entry->next; memcpy(&(table->table[key]), entry, sizeof(virHashEntry)); VIR_FREE(entry); } } table->nbElems--; return (0); } prev = entry; } return (-1); } } /** * virHashForEach * @table: the hash table to process * @iter: callback to process each element * @data: opaque data to pass to the iterator * * Iterates over every element in the hash table, invoking the * 'iter' callback. The callback must not call any other virHash* * functions, and in particular must not attempt to remove the * element. * * Returns number of items iterated over upon completion, -1 on failure */ int virHashForEach(virHashTablePtr table, virHashIterator iter, const void *data) { int i, count = 0; if (table == NULL || iter == NULL) return (-1); for (i = 0 ; i < table->size ; i++) { virHashEntryPtr entry = table->table + i; while (entry) { if (entry->valid) { iter(entry->payload, entry->name, data); count++; } entry = entry->next; } } return (count); } /** * virHashRemoveSet * @table: the hash table to process * @iter: callback to identify elements for removal * @f: callback to free memory from element payload * @data: opaque data to pass to the iterator * * Iterates over all elements in the hash table, invoking the 'iter' * callback. If the callback returns a non-zero value, the element * will be removed from the hash table & its payload passed to the * callback 'f' for de-allocation. * * Returns number of items removed on success, -1 on failure */ int virHashRemoveSet(virHashTablePtr table, virHashSearcher iter, virHashDeallocator f, const void *data) { int i, count = 0; if (table == NULL || iter == NULL) return (-1); for (i = 0 ; i < table->size ; i++) { virHashEntryPtr prev = NULL; virHashEntryPtr entry = &(table->table[i]); while (entry && entry->valid) { if (iter(entry->payload, entry->name, data)) { count++; f(entry->payload, entry->name); VIR_FREE(entry->name); table->nbElems--; if (prev) { prev->next = entry->next; VIR_FREE(entry); entry = prev; } else { if (entry->next == NULL) { entry->valid = 0; entry->name = NULL; } else { entry = entry->next; memcpy(&(table->table[i]), entry, sizeof(virHashEntry)); VIR_FREE(entry); entry = &(table->table[i]); continue; } } } prev = entry; if (entry) { entry = entry->next; } } } return (count); } /** * virHashSearch: * @table: the hash table to search * @iter: an iterator to identify the desired element * @data: extra opaque information passed to the iter * * Iterates over the hash table calling the 'iter' callback * for each element. The first element for which the iter * returns non-zero will be returned by this function. * The elements are processed in a undefined order */ void *virHashSearch(virHashTablePtr table, virHashSearcher iter, const void *data) { int i; if (table == NULL || iter == NULL) return (NULL); for (i = 0 ; i < table->size ; i++) { virHashEntryPtr entry = table->table + i; while (entry) { if (entry->valid) { if (iter(entry->payload, entry->name, data)) return entry->payload; } entry = entry->next; } } return (NULL); }