Mercurial > hg > xemacs-beta
view src/hash.c @ 778:2923009caf47
[xemacs-hg @ 2002-03-16 10:38:59 by ben]
cm.c, file-coding.c: fix warnings.
.cvsignore: Those pesky *.tmp files.
mule\arabic.el, mule\canna-leim.el, mule\china-util.el, mule\chinese.el, mule\cyril-util.el, mule\cyrillic.el, mule\devan-util.el, mule\devanagari.el, mule\english.el, mule\ethio-util.el, mule\ethiopic.el, mule\european.el, mule\greek.el, mule\hebrew.el, mule\indian.el, mule\japan-util.el, mule\japanese.el, mule\korea-util.el, mule\korean.el, mule\lao-util.el, mule\lao.el, mule\misc-lang.el, mule\mule-charset.el, mule\mule-cmds.el, mule\thai-util.el, mule\thai.el, mule\tibet-util.el, mule\tibetan.el, mule\viet-util.el, mule\vietnamese.el, unicode.el: Fix lots of warnings. Sync up some files to FSF 21.1. Copy over
all charset definitions from FSF 21.1, convert them to our format,
and stick them in the relevant files. Eventually we will actually
be able to dump these files (though they may not quite work).
autoload.el: Support defun*, defmacro*.
mule/mule-composite.el, mule/mule-composite-stub.el: New file, stubs for
nonexistent composition funs/vars.
mule/viet-chars.el, dumped-lisp.el: Account for these changes.
font.el, mouse.el, msw-font-menu.el, printer.el, startup.el: fix warnings.
| author | ben |
|---|---|
| date | Sat, 16 Mar 2002 10:39:19 +0000 |
| parents | fdefd0186b75 |
| children | e22b0213b713 |
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/* Hash tables. Copyright (C) 1992, 1993, 1994 Free Software Foundation, Inc. This file is part of XEmacs. XEmacs 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 2, or (at your option) any later version. XEmacs 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 XEmacs; see the file COPYING. If not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /* Synched up with: Not in FSF. */ #include <config.h> #include "lisp.h" #include "hash.h" #define NULL_ENTRY ((void *) 0xdeadbeef) #define COMFORTABLE_SIZE(size) (21 * (size) / 16) #define KEYS_DIFFER_P(old, new, testfun) \ (((old) != (new)) && (!(testfun) || !(testfun) ((old),(new)))) static void rehash (hentry *harray, struct hash_table *ht, Elemcount size); Hashcode memory_hash (const void *xv, Bytecount size) { Hashcode h = 0; unsigned const char *x = (unsigned const char *) xv; if (!x) return 0; while (size--) { Hashcode g; h = (h << 4) + *x++; if ((g = h & 0xf0000000) != 0) h = (h ^ (g >> 24)) ^ g; } return h; } Hashcode string_hash (const char *xv) { Hashcode h = 0; unsigned const char *x = (unsigned const char *) xv; if (!x) return 0; while (*x) { Hashcode g; h = (h << 4) + *x++; if ((g = h & 0xf0000000) != 0) h = (h ^ (g >> 24)) ^ g; } return h; } /* Return a suitable size for a hash table, with at least SIZE slots. */ static Elemcount hash_table_size (Elemcount requested_size) { /* Return some prime near, but greater than or equal to, SIZE. Decades from the time of writing, someone will have a system large enough that the list below will be too short... */ static const Elemcount primes [] = { 19, 29, 41, 59, 79, 107, 149, 197, 263, 347, 457, 599, 787, 1031, 1361, 1777, 2333, 3037, 3967, 5167, 6719, 8737, 11369, 14783, 19219, 24989, 32491, 42257, 54941, 71429, 92861, 120721, 156941, 204047, 265271, 344857, 448321, 582821, 757693, 985003, 1280519, 1664681, 2164111, 2813353, 3657361, 4754591, 6180989, 8035301, 10445899, 13579681, 17653589, 22949669, 29834603, 38784989, 50420551, 65546729, 85210757, 110774011, 144006217, 187208107, 243370577, 316381771, 411296309, 534685237, 695090819, 903618083, 1174703521, 1527114613, 1985248999 /* , 2580823717UL, 3355070839UL */ }; /* We've heard of binary search. */ int low, high; for (low = 0, high = countof (primes) - 1; high - low > 1;) { /* Loop Invariant: size < primes [high] */ int mid = (low + high) / 2; if (primes [mid] < requested_size) low = mid; else high = mid; } return primes [high]; } const void * gethash (const void *key, struct hash_table *hash_table, const void **ret_value) { if (!key) { *ret_value = hash_table->zero_entry; return (void *) hash_table->zero_set; } else { hentry *harray = hash_table->harray; hash_table_test_function test_function = hash_table->test_function; Elemcount size = hash_table->size; Hashcode hcode_initial = hash_table->hash_function ? hash_table->hash_function (key) : (Hashcode) key; Elemcount hcode = (Elemcount) (hcode_initial % size); hentry *e = &harray [hcode]; const void *e_key = e->key; if (e_key ? KEYS_DIFFER_P (e_key, key, test_function) : e->contents == NULL_ENTRY) { Elemcount h2 = size - 2; Elemcount incr = (Elemcount) (1 + (hcode_initial % h2)); do { hcode += incr; if (hcode >= size) hcode -= size; e = &harray [hcode]; e_key = e->key; } while (e_key ? KEYS_DIFFER_P (e_key, key, test_function) : e->contents == NULL_ENTRY); } *ret_value = e->contents; return e->key; } } void clrhash (struct hash_table *hash_table) { memset (hash_table->harray, 0, sizeof (hentry) * hash_table->size); hash_table->zero_entry = 0; hash_table->zero_set = 0; hash_table->fullness = 0; } void free_hash_table (struct hash_table *hash_table) { xfree (hash_table->harray); xfree (hash_table); } struct hash_table* make_hash_table (Elemcount size) { struct hash_table *hash_table = xnew_and_zero (struct hash_table); hash_table->size = hash_table_size (COMFORTABLE_SIZE (size)); hash_table->harray = xnew_array (hentry, hash_table->size); clrhash (hash_table); return hash_table; } struct hash_table * make_general_hash_table (Elemcount size, hash_table_hash_function hash_function, hash_table_test_function test_function) { struct hash_table* hash_table = make_hash_table (size); hash_table->hash_function = hash_function; hash_table->test_function = test_function; return hash_table; } static void grow_hash_table (struct hash_table *hash_table, Elemcount new_size) { Elemcount old_size = hash_table->size; hentry *old_harray = hash_table->harray; hash_table->size = hash_table_size (new_size); hash_table->harray = xnew_array (hentry, hash_table->size); /* do the rehash on the "grown" table */ { long old_zero_set = hash_table->zero_set; void *old_zero_entry = hash_table->zero_entry; clrhash (hash_table); hash_table->zero_set = old_zero_set; hash_table->zero_entry = old_zero_entry; rehash (old_harray, hash_table, old_size); } xfree (old_harray); } void puthash (const void *key, void *contents, struct hash_table *hash_table) { if (!key) { hash_table->zero_entry = contents; hash_table->zero_set = 1; } else { hash_table_test_function test_function = hash_table->test_function; Elemcount size = hash_table->size; hentry *harray = hash_table->harray; Hashcode hcode_initial = hash_table->hash_function ? hash_table->hash_function (key) : (Hashcode) key; Elemcount hcode = (Elemcount) (hcode_initial % size); Elemcount h2 = size - 2; Elemcount incr = (Elemcount) (1 + (hcode_initial % h2)); const void *e_key = harray [hcode].key; const void *oldcontents; if (e_key && KEYS_DIFFER_P (e_key, key, test_function)) { do { hcode += incr; if (hcode >= size) hcode -= size; e_key = harray [hcode].key; } while (e_key && KEYS_DIFFER_P (e_key, key, test_function)); } oldcontents = harray [hcode].contents; harray [hcode].key = key; harray [hcode].contents = contents; /* If the entry that we used was a deleted entry, check for a non deleted entry of the same key, then delete it. */ if (!e_key && oldcontents == NULL_ENTRY) { hentry *e; do { hcode += incr; if (hcode >= size) hcode -= size; e = &harray [hcode]; e_key = e->key; } while (e_key ? KEYS_DIFFER_P (e_key, key, test_function): e->contents == NULL_ENTRY); if (e_key) { e->key = 0; e->contents = NULL_ENTRY; } } /* only increment the fullness when we used up a new hentry */ if (!e_key || KEYS_DIFFER_P (e_key, key, test_function)) { Elemcount comfortable_size = COMFORTABLE_SIZE (++(hash_table->fullness)); if (hash_table->size < comfortable_size) grow_hash_table (hash_table, comfortable_size + 1); } } } static void rehash (hentry *harray, struct hash_table *hash_table, Elemcount size) { hentry *limit = harray + size; hentry *e; for (e = harray; e < limit; e++) { if (e->key) puthash (e->key, e->contents, hash_table); } } void remhash (const void *key, struct hash_table *hash_table) { if (!key) { hash_table->zero_entry = 0; hash_table->zero_set = 0; } else { hentry *harray = hash_table->harray; hash_table_test_function test_function = hash_table->test_function; Elemcount size = hash_table->size; Hashcode hcode_initial = (hash_table->hash_function) ? (hash_table->hash_function (key)) : ((Hashcode) key); Elemcount hcode = (Elemcount) (hcode_initial % size); hentry *e = &harray [hcode]; const void *e_key = e->key; if (e_key ? KEYS_DIFFER_P (e_key, key, test_function) : e->contents == NULL_ENTRY) { Elemcount h2 = size - 2; Elemcount incr = (Elemcount) (1 + (hcode_initial % h2)); do { hcode += incr; if (hcode >= size) hcode -= size; e = &harray [hcode]; e_key = e->key; } while (e_key? KEYS_DIFFER_P (e_key, key, test_function): e->contents == NULL_ENTRY); } if (e_key) { e->key = 0; e->contents = NULL_ENTRY; /* Note: you can't do fullness-- here, it breaks the world. */ } } } void maphash (maphash_function mf, struct hash_table *hash_table, void *arg) { hentry *e; hentry *limit; if (hash_table->zero_set) { if (mf (0, hash_table->zero_entry, arg)) return; } for (e = hash_table->harray, limit = e + hash_table->size; e < limit; e++) { if (e->key && mf (e->key, e->contents, arg)) return; } } void map_remhash (remhash_predicate predicate, struct hash_table *hash_table, void *arg) { hentry *e; hentry *limit; if (hash_table->zero_set && predicate (0, hash_table->zero_entry, arg)) { hash_table->zero_set = 0; hash_table->zero_entry = 0; } for (e = hash_table->harray, limit = e + hash_table->size; e < limit; e++) if (predicate (e->key, e->contents, arg)) { e->key = 0; e->contents = NULL_ENTRY; } }