/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ /* * PL hash table package. */ #include "plhash.h" #include "prbit.h" #include "prlog.h" #include "prmem.h" #include "prtypes.h" #include #include /* Compute the number of buckets in ht */ #define NBUCKETS(ht) (1 << (PL_HASH_BITS - (ht)->shift)) /* The smallest table has 16 buckets */ #define MINBUCKETSLOG2 4 #define MINBUCKETS (1 << MINBUCKETSLOG2) /* Compute the maximum entries given n buckets that we will tolerate, ~90% */ #define OVERLOADED(n) ((n) - ((n) >> 3)) /* Compute the number of entries below which we shrink the table by half */ #define UNDERLOADED(n) (((n) > MINBUCKETS) ? ((n) >> 2) : 0) /* ** Stubs for default hash allocator ops. */ static void * PR_CALLBACK DefaultAllocTable(void *pool, PRSize size) { return PR_MALLOC(size); } static void PR_CALLBACK DefaultFreeTable(void *pool, void *item) { PR_Free(item); } static PLHashEntry * PR_CALLBACK DefaultAllocEntry(void *pool, const void *key) { return PR_NEW(PLHashEntry); } static void PR_CALLBACK DefaultFreeEntry(void *pool, PLHashEntry *he, PRUintn flag) { if (flag == HT_FREE_ENTRY) { PR_Free(he); } } static PLHashAllocOps defaultHashAllocOps = { DefaultAllocTable, DefaultFreeTable, DefaultAllocEntry, DefaultFreeEntry }; PR_IMPLEMENT(PLHashTable *) PL_NewHashTable(PRUint32 n, PLHashFunction keyHash, PLHashComparator keyCompare, PLHashComparator valueCompare, const PLHashAllocOps *allocOps, void *allocPriv) { PLHashTable *ht; PRSize nb; if (n <= MINBUCKETS) { n = MINBUCKETSLOG2; } else { n = PR_CeilingLog2(n); if ((PRInt32)n < 0) { return 0; } } if (!allocOps) { allocOps = &defaultHashAllocOps; } ht = (PLHashTable*)((*allocOps->allocTable)(allocPriv, sizeof *ht)); if (!ht) { return 0; } memset(ht, 0, sizeof *ht); ht->shift = PL_HASH_BITS - n; n = 1 << n; nb = n * sizeof(PLHashEntry *); ht->buckets = (PLHashEntry**)((*allocOps->allocTable)(allocPriv, nb)); if (!ht->buckets) { (*allocOps->freeTable)(allocPriv, ht); return 0; } memset(ht->buckets, 0, nb); ht->keyHash = keyHash; ht->keyCompare = keyCompare; ht->valueCompare = valueCompare; ht->allocOps = allocOps; ht->allocPriv = allocPriv; return ht; } PR_IMPLEMENT(void) PL_HashTableDestroy(PLHashTable *ht) { PRUint32 i, n; PLHashEntry *he, *next; const PLHashAllocOps *allocOps = ht->allocOps; void *allocPriv = ht->allocPriv; n = NBUCKETS(ht); for (i = 0; i < n; i++) { for (he = ht->buckets[i]; he; he = next) { next = he->next; (*allocOps->freeEntry)(allocPriv, he, HT_FREE_ENTRY); } } #ifdef DEBUG memset(ht->buckets, 0xDB, n * sizeof ht->buckets[0]); #endif (*allocOps->freeTable)(allocPriv, ht->buckets); #ifdef DEBUG memset(ht, 0xDB, sizeof *ht); #endif (*allocOps->freeTable)(allocPriv, ht); } /* ** Multiplicative hash, from Knuth 6.4. */ #define GOLDEN_RATIO 0x9E3779B9U /* 2/(1+sqrt(5))*(2^32) */ PR_IMPLEMENT(PLHashEntry **) PL_HashTableRawLookup(PLHashTable *ht, PLHashNumber keyHash, const void *key) { PLHashEntry *he, **hep, **hep0; PLHashNumber h; #ifdef HASHMETER ht->nlookups++; #endif h = keyHash * GOLDEN_RATIO; h >>= ht->shift; hep = hep0 = &ht->buckets[h]; while ((he = *hep) != 0) { if (he->keyHash == keyHash && (*ht->keyCompare)(key, he->key)) { /* Move to front of chain if not already there */ if (hep != hep0) { *hep = he->next; he->next = *hep0; *hep0 = he; } return hep0; } hep = &he->next; #ifdef HASHMETER ht->nsteps++; #endif } return hep; } /* ** Same as PL_HashTableRawLookup but doesn't reorder the hash entries. */ PR_IMPLEMENT(PLHashEntry **) PL_HashTableRawLookupConst(PLHashTable *ht, PLHashNumber keyHash, const void *key) { PLHashEntry *he, **hep; PLHashNumber h; #ifdef HASHMETER ht->nlookups++; #endif h = keyHash * GOLDEN_RATIO; h >>= ht->shift; hep = &ht->buckets[h]; while ((he = *hep) != 0) { if (he->keyHash == keyHash && (*ht->keyCompare)(key, he->key)) { break; } hep = &he->next; #ifdef HASHMETER ht->nsteps++; #endif } return hep; } PR_IMPLEMENT(PLHashEntry *) PL_HashTableRawAdd(PLHashTable *ht, PLHashEntry **hep, PLHashNumber keyHash, const void *key, void *value) { PRUint32 i, n; PLHashEntry *he, *next, **oldbuckets; PRSize nb; /* Grow the table if it is overloaded */ n = NBUCKETS(ht); if (ht->nentries >= OVERLOADED(n)) { oldbuckets = ht->buckets; nb = 2 * n * sizeof(PLHashEntry *); ht->buckets = (PLHashEntry**) ((*ht->allocOps->allocTable)(ht->allocPriv, nb)); if (!ht->buckets) { ht->buckets = oldbuckets; return 0; } memset(ht->buckets, 0, nb); #ifdef HASHMETER ht->ngrows++; #endif ht->shift--; for (i = 0; i < n; i++) { for (he = oldbuckets[i]; he; he = next) { next = he->next; hep = PL_HashTableRawLookup(ht, he->keyHash, he->key); PR_ASSERT(*hep == 0); he->next = 0; *hep = he; } } #ifdef DEBUG memset(oldbuckets, 0xDB, n * sizeof oldbuckets[0]); #endif (*ht->allocOps->freeTable)(ht->allocPriv, oldbuckets); hep = PL_HashTableRawLookup(ht, keyHash, key); } /* Make a new key value entry */ he = (*ht->allocOps->allocEntry)(ht->allocPriv, key); if (!he) { return 0; } he->keyHash = keyHash; he->key = key; he->value = value; he->next = *hep; *hep = he; ht->nentries++; return he; } PR_IMPLEMENT(PLHashEntry *) PL_HashTableAdd(PLHashTable *ht, const void *key, void *value) { PLHashNumber keyHash; PLHashEntry *he, **hep; keyHash = (*ht->keyHash)(key); hep = PL_HashTableRawLookup(ht, keyHash, key); if ((he = *hep) != 0) { /* Hit; see if values match */ if ((*ht->valueCompare)(he->value, value)) { /* key,value pair is already present in table */ return he; } if (he->value) { (*ht->allocOps->freeEntry)(ht->allocPriv, he, HT_FREE_VALUE); } he->value = value; return he; } return PL_HashTableRawAdd(ht, hep, keyHash, key, value); } PR_IMPLEMENT(void) PL_HashTableRawRemove(PLHashTable *ht, PLHashEntry **hep, PLHashEntry *he) { PRUint32 i, n; PLHashEntry *next, **oldbuckets; PRSize nb; *hep = he->next; (*ht->allocOps->freeEntry)(ht->allocPriv, he, HT_FREE_ENTRY); /* Shrink table if it's underloaded */ n = NBUCKETS(ht); if (--ht->nentries < UNDERLOADED(n)) { oldbuckets = ht->buckets; nb = n * sizeof(PLHashEntry*) / 2; ht->buckets = (PLHashEntry**)( (*ht->allocOps->allocTable)(ht->allocPriv, nb)); if (!ht->buckets) { ht->buckets = oldbuckets; return; } memset(ht->buckets, 0, nb); #ifdef HASHMETER ht->nshrinks++; #endif ht->shift++; for (i = 0; i < n; i++) { for (he = oldbuckets[i]; he; he = next) { next = he->next; hep = PL_HashTableRawLookup(ht, he->keyHash, he->key); PR_ASSERT(*hep == 0); he->next = 0; *hep = he; } } #ifdef DEBUG memset(oldbuckets, 0xDB, n * sizeof oldbuckets[0]); #endif (*ht->allocOps->freeTable)(ht->allocPriv, oldbuckets); } } PR_IMPLEMENT(PRBool) PL_HashTableRemove(PLHashTable *ht, const void *key) { PLHashNumber keyHash; PLHashEntry *he, **hep; keyHash = (*ht->keyHash)(key); hep = PL_HashTableRawLookup(ht, keyHash, key); if ((he = *hep) == 0) { return PR_FALSE; } /* Hit; remove element */ PL_HashTableRawRemove(ht, hep, he); return PR_TRUE; } PR_IMPLEMENT(void *) PL_HashTableLookup(PLHashTable *ht, const void *key) { PLHashNumber keyHash; PLHashEntry *he, **hep; keyHash = (*ht->keyHash)(key); hep = PL_HashTableRawLookup(ht, keyHash, key); if ((he = *hep) != 0) { return he->value; } return 0; } /* ** Same as PL_HashTableLookup but doesn't reorder the hash entries. */ PR_IMPLEMENT(void *) PL_HashTableLookupConst(PLHashTable *ht, const void *key) { PLHashNumber keyHash; PLHashEntry *he, **hep; keyHash = (*ht->keyHash)(key); hep = PL_HashTableRawLookupConst(ht, keyHash, key); if ((he = *hep) != 0) { return he->value; } return 0; } /* ** Iterate over the entries in the hash table calling func for each ** entry found. Stop if "f" says to (return value & PR_ENUMERATE_STOP). ** Return a count of the number of elements scanned. */ PR_IMPLEMENT(int) PL_HashTableEnumerateEntries(PLHashTable *ht, PLHashEnumerator f, void *arg) { PLHashEntry *he, **hep; PRUint32 i, nbuckets; int rv, n = 0; PLHashEntry *todo = 0; nbuckets = NBUCKETS(ht); for (i = 0; i < nbuckets; i++) { hep = &ht->buckets[i]; while ((he = *hep) != 0) { rv = (*f)(he, n, arg); n++; if (rv & (HT_ENUMERATE_REMOVE | HT_ENUMERATE_UNHASH)) { *hep = he->next; if (rv & HT_ENUMERATE_REMOVE) { he->next = todo; todo = he; } } else { hep = &he->next; } if (rv & HT_ENUMERATE_STOP) { goto out; } } } out: hep = &todo; while ((he = *hep) != 0) { PL_HashTableRawRemove(ht, hep, he); } return n; } #ifdef HASHMETER #include #include PR_IMPLEMENT(void) PL_HashTableDumpMeter(PLHashTable *ht, PLHashEnumerator dump, FILE *fp) { double mean, variance; PRUint32 nchains, nbuckets; PRUint32 i, n, maxChain, maxChainLen; PLHashEntry *he; variance = 0; nchains = 0; maxChainLen = 0; nbuckets = NBUCKETS(ht); for (i = 0; i < nbuckets; i++) { he = ht->buckets[i]; if (!he) { continue; } nchains++; for (n = 0; he; he = he->next) { n++; } variance += n * n; if (n > maxChainLen) { maxChainLen = n; maxChain = i; } } mean = (double)ht->nentries / nchains; variance = fabs(variance / nchains - mean * mean); fprintf(fp, "\nHash table statistics:\n"); fprintf(fp, " number of lookups: %u\n", ht->nlookups); fprintf(fp, " number of entries: %u\n", ht->nentries); fprintf(fp, " number of grows: %u\n", ht->ngrows); fprintf(fp, " number of shrinks: %u\n", ht->nshrinks); fprintf(fp, " mean steps per hash: %g\n", (double)ht->nsteps / ht->nlookups); fprintf(fp, "mean hash chain length: %g\n", mean); fprintf(fp, " standard deviation: %g\n", sqrt(variance)); fprintf(fp, " max hash chain length: %u\n", maxChainLen); fprintf(fp, " max hash chain: [%u]\n", maxChain); for (he = ht->buckets[maxChain], i = 0; he; he = he->next, i++) if ((*dump)(he, i, fp) != HT_ENUMERATE_NEXT) { break; } } #endif /* HASHMETER */ PR_IMPLEMENT(int) PL_HashTableDump(PLHashTable *ht, PLHashEnumerator dump, FILE *fp) { int count; count = PL_HashTableEnumerateEntries(ht, dump, fp); #ifdef HASHMETER PL_HashTableDumpMeter(ht, dump, fp); #endif return count; } PR_IMPLEMENT(PLHashNumber) PL_HashString(const void *key) { PLHashNumber h; const PRUint8 *s; h = 0; for (s = (const PRUint8*)key; *s; s++) { h = PR_ROTATE_LEFT32(h, 4) ^ *s; } return h; } PR_IMPLEMENT(int) PL_CompareStrings(const void *v1, const void *v2) { return strcmp((const char*)v1, (const char*)v2) == 0; } PR_IMPLEMENT(int) PL_CompareValues(const void *v1, const void *v2) { return v1 == v2; }