/* Copyright (C) 2000-2010 Red Hat, Inc. This file is part of elfutils. Written by Ulrich Drepper <drepper@redhat.com>, 2000. This file is free software; you can redistribute it and/or modify it under the terms of either * the GNU Lesser General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version or * the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version or both in parallel, as here. elfutils 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 copies of the GNU General Public License and the GNU Lesser General Public License along with this program. If not, see <http://www.gnu.org/licenses/>. */ #include <assert.h> #include <stdlib.h> #include <system.h> /* Before including this file the following macros must be defined: NAME name of the hash table structure. TYPE data type of the hash table entries COMPARE comparison function taking two pointers to TYPE objects The following macros if present select features: ITERATE iterating over the table entries is possible REVERSE iterate in reverse order of insert */ static size_t lookup (htab, hval, val) NAME *htab; HASHTYPE hval; TYPE val __attribute__ ((unused)); { /* First hash function: simply take the modul but prevent zero. Small values can skip the division, which helps performance when this is common. */ size_t idx = 1 + (hval < htab->size ? hval : hval % htab->size); if (htab->table[idx].hashval != 0) { HASHTYPE hash; if (htab->table[idx].hashval == hval && COMPARE (htab->table[idx].data, val) == 0) return idx; /* Second hash function as suggested in [Knuth]. */ hash = 1 + hval % (htab->size - 2); do { if (idx <= hash) idx = htab->size + idx - hash; else idx -= hash; /* If entry is found use it. */ if (htab->table[idx].hashval == hval && COMPARE (htab->table[idx].data, val) == 0) return idx; } while (htab->table[idx].hashval); } return idx; } static void insert_entry_2 (NAME *htab, HASHTYPE hval, size_t idx, TYPE data) { #ifdef ITERATE if (htab->table[idx].hashval == 0) { # ifdef REVERSE htab->table[idx].next = htab->first; htab->first = &htab->table[idx]; # else /* Add the new value to the list. */ if (htab->first == NULL) htab->first = htab->table[idx].next = &htab->table[idx]; else { htab->table[idx].next = htab->first->next; htab->first = htab->first->next = &htab->table[idx]; } # endif } #endif htab->table[idx].hashval = hval; htab->table[idx].data = data; ++htab->filled; if (100 * htab->filled > 90 * htab->size) { /* Table is filled more than 90%. Resize the table. */ #ifdef ITERATE __typeof__ (htab->first) first; # ifndef REVERSE __typeof__ (htab->first) runp; # endif #else size_t old_size = htab->size; #endif #define _TABLE(name) \ name##_ent *table = htab->table #define TABLE(name) _TABLE (name) TABLE(NAME); htab->size = next_prime (htab->size * 2); htab->filled = 0; #ifdef ITERATE first = htab->first; htab->first = NULL; #endif htab->table = calloc ((1 + htab->size), sizeof (htab->table[0])); if (htab->table == NULL) { /* We cannot enlarge the table. Live with what we got. This might lead to an infinite loop at some point, though. */ htab->table = table; return; } /* Add the old entries to the new table. When iteration is supported we maintain the order. */ #ifdef ITERATE # ifdef REVERSE while (first != NULL) { insert_entry_2 (htab, first->hashval, lookup (htab, first->hashval, first->data), first->data); first = first->next; } # else assert (first != NULL); runp = first = first->next; do insert_entry_2 (htab, runp->hashval, lookup (htab, runp->hashval, runp->data), runp->data); while ((runp = runp->next) != first); # endif #else for (idx = 1; idx <= old_size; ++idx) if (table[idx].hashval != 0) insert_entry_2 (htab, table[idx].hashval, lookup (htab, table[idx].hashval, table[idx].data), table[idx].data); #endif free (table); } } int #define INIT(name) _INIT (name) #define _INIT(name) \ name##_init INIT(NAME) (htab, init_size) NAME *htab; size_t init_size; { /* We need the size to be a prime. */ init_size = next_prime (init_size); /* Initialize the data structure. */ htab->size = init_size; htab->filled = 0; #ifdef ITERATE htab->first = NULL; #endif htab->table = (void *) calloc ((init_size + 1), sizeof (htab->table[0])); if (htab->table == NULL) return -1; return 0; } int #define FREE(name) _FREE (name) #define _FREE(name) \ name##_free FREE(NAME) (htab) NAME *htab; { free (htab->table); return 0; } int #define INSERT(name) _INSERT (name) #define _INSERT(name) \ name##_insert INSERT(NAME) (htab, hval, data) NAME *htab; HASHTYPE hval; TYPE data; { size_t idx; /* Make the hash value nonzero. */ hval = hval ?: 1; idx = lookup (htab, hval, data); if (htab->table[idx].hashval != 0) /* We don't want to overwrite the old value. */ return -1; /* An empty bucket has been found. */ insert_entry_2 (htab, hval, idx, data); return 0; } #ifdef OVERWRITE int #define INSERT(name) _INSERT (name) #define _INSERT(name) \ name##_overwrite INSERT(NAME) (htab, hval, data) NAME *htab; HASHTYPE hval; TYPE data; { size_t idx; /* Make the hash value nonzero. */ hval = hval ?: 1; idx = lookup (htab, hval, data); /* The correct bucket has been found. */ insert_entry_2 (htab, hval, idx, data); return 0; } #endif TYPE #define FIND(name) _FIND (name) #define _FIND(name) \ name##_find FIND(NAME) (htab, hval, val) NAME *htab; HASHTYPE hval; TYPE val; { size_t idx; /* Make the hash value nonzero. */ hval = hval ?: 1; idx = lookup (htab, hval, val); if (htab->table[idx].hashval == 0) return NULL; return htab->table[idx].data; } #ifdef ITERATE # define ITERATEFCT(name) _ITERATEFCT (name) # define _ITERATEFCT(name) \ name##_iterate TYPE ITERATEFCT(NAME) (htab, ptr) NAME *htab; void **ptr; { void *p = *ptr; # define TYPENAME(name) _TYPENAME (name) # define _TYPENAME(name) name##_ent # ifdef REVERSE if (p == NULL) p = htab->first; else p = ((TYPENAME(NAME) *) p)->next; if (p == NULL) { *ptr = NULL; return NULL; } # else if (p == NULL) { if (htab->first == NULL) return NULL; p = htab->first->next; } else { if (p == htab->first) return NULL; p = ((TYPENAME(NAME) *) p)->next; } # endif /* Prepare the next element. If possible this will pull the data into the cache, for reading. */ __builtin_prefetch (((TYPENAME(NAME) *) p)->next, 0, 2); return ((TYPENAME(NAME) *) (*ptr = p))->data; } #endif