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/*
* Copyright (c) 2017 Cisco and/or its affiliates.
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/**
* Implements an open-addressing hash table. We use linear probing of +1 per step.
*
* Table is rehashed when we reach 75% utilization.
* The table is rehashed if we go more than 10 linear probes without being able to insert.
*
* HashCodeTable is a wrapper that holds the key/data management functions. It also
* has LinearAddressingHashTable that is the actual hash table.
*
* This open-addressing table is inefficient for GET or DEL if the element does not exist.
* The whole table needs to be
*
*/
#include <config.h>
#include <LongBow/runtime.h>
#include <stdio.h>
#include <string.h>
#include <parc/algol/parc_HashCodeTable.h>
#include <parc/algol/parc_Memory.h>
// minimum size if nothing specified
#define MIN_SIZE 256
// when we expand, use this factor
#define EXPAND_FACTOR 2
#define MAX_PROBE_LENGTH 20
typedef enum {
ADD_OK, // we added the key
ADD_DUP, // the key is a duplicate
ADD_NOSPACE // ran out of space
} PARCHashCodeTable_AddResult;
typedef struct hashtable_entry {
// A hashtable entry is in use if the key is non-null
void *key;
void *data;
HashCodeType hashcode;
} HashTableEntry;
typedef struct linear_address_hash_table {
HashTableEntry *entries;
// Number of elements allocated
size_t tableLimit;
// Number of elements in use
size_t tableSize;
// When the tableSize equals or exceeds this
// threshold, we should expand and re-hash the table∫
size_t expandThreshold;
} LinearAddressingHashTable;
struct parc_hashcode_table {
LinearAddressingHashTable hashtable;
PARCHashCodeTable_KeyEqualsFunc keyEqualsFunc;
PARCHashCodeTable_HashCodeFunc keyHashCodeFunc;
PARCHashCodeTable_Destroyer keyDestroyer;
PARCHashCodeTable_Destroyer dataDestroyer;
unsigned expandCount;
};
static bool
_findIndex(PARCHashCodeTable *table, const void *key, size_t *outputIndexPtr)
{
size_t index, start;
HashCodeType hashcode;
LinearAddressingHashTable *innerTable;
innerTable = &table->hashtable;
hashcode = table->keyHashCodeFunc(key);
index = hashcode % innerTable->tableLimit;
start = index;
// check until we've gone MAX_PROBE_LENGTH
unsigned steps = 0;
do {
if (innerTable->entries[index].key != NULL) {
if ((innerTable->entries[index].hashcode == hashcode) && table->keyEqualsFunc(key, innerTable->entries[index].key)) {
// the key already exists in the table
*outputIndexPtr = index;
return true;
}
}
steps++;
index = index + 1;
if (index == innerTable->tableLimit) {
index = 0;
}
} while (index != start && steps < MAX_PROBE_LENGTH);
return false;
}
static PARCHashCodeTable_AddResult
_innerTableAdd(LinearAddressingHashTable *innerTable, PARCHashCodeTable_KeyEqualsFunc keyEqualsFunc,
HashCodeType hashcode, void *key, void *data)
{
size_t index = hashcode % innerTable->tableLimit;
unsigned steps = 0;
// we know the size < limit, so it will fit eventually
while (steps < MAX_PROBE_LENGTH) {
if (innerTable->entries[index].key == NULL) {
innerTable->entries[index].hashcode = hashcode;
innerTable->entries[index].key = key;
innerTable->entries[index].data = data;
innerTable->tableSize++;
return ADD_OK;
}
if ((innerTable->entries[index].hashcode == hashcode) && keyEqualsFunc(key, innerTable->entries[index].key)) {
// the key already exists in the table
return ADD_DUP;
}
steps++;
index = index + 1;
if (index == innerTable->tableLimit) {
index = 0;
}
}
return ADD_NOSPACE;
}
static PARCHashCodeTable_AddResult
_rehash(LinearAddressingHashTable *old_table, LinearAddressingHashTable *new_table, PARCHashCodeTable_KeyEqualsFunc keyEqualsFunc)
{
size_t i;
for (i = 0; i < old_table->tableLimit; i++) {
if (old_table->entries[i].key != NULL) {
PARCHashCodeTable_AddResult result = _innerTableAdd(new_table, keyEqualsFunc, old_table->entries[i].hashcode,
old_table->entries[i].key, old_table->entries[i].data);
if (result != ADD_OK) {
return result;
}
}
}
return ADD_OK;
}
static void
_expand(PARCHashCodeTable *hashCodeTable)
{
LinearAddressingHashTable temp_table;
LinearAddressingHashTable *old_table = &hashCodeTable->hashtable;
size_t expandby = EXPAND_FACTOR;
// start with a copy of the current table
PARCHashCodeTable_AddResult result = ADD_OK;
do {
hashCodeTable->expandCount++;
temp_table.tableSize = 0;
temp_table.tableLimit = old_table->tableLimit * expandby;
temp_table.expandThreshold = temp_table.tableLimit - temp_table.tableLimit / 4;
temp_table.entries = parcMemory_AllocateAndClear(temp_table.tableLimit * sizeof(HashTableEntry));
assertNotNull(temp_table.entries, "parcMemory_AllocateAndClear(%zu) returned NULL", temp_table.tableLimit * sizeof(HashTableEntry));
result = _rehash(old_table, &temp_table, hashCodeTable->keyEqualsFunc);
if (result == ADD_NOSPACE) {
// could not rehash, so expand by more and try again
parcMemory_Deallocate((void **) &(temp_table.entries));
expandby++;
}
} while (result == ADD_NOSPACE);
parcMemory_Deallocate((void **) &old_table->entries);
hashCodeTable->hashtable = temp_table;
}
PARCHashCodeTable *
parcHashCodeTable_Create_Size(PARCHashCodeTable_KeyEqualsFunc keyEqualsFunc,
PARCHashCodeTable_HashCodeFunc keyHashCodeFunc,
PARCHashCodeTable_Destroyer keyDestroyer,
PARCHashCodeTable_Destroyer dataDestroyer,
size_t minimumSize)
{
PARCHashCodeTable *table = parcMemory_AllocateAndClear(sizeof(PARCHashCodeTable));
assertNotNull(table, "parcMemory_AllocateAndClear(%zu) returned NULL", sizeof(PARCHashCodeTable));
assertNotNull(keyEqualsFunc, "keyEqualsFunc must be non-null");
assertNotNull(keyHashCodeFunc, "keyHashCodeFunc must be non-null");
assertTrue(minimumSize > 0, "minimumSize must be greater than zero");
table->keyEqualsFunc = keyEqualsFunc;
table->keyHashCodeFunc = keyHashCodeFunc;
table->keyDestroyer = keyDestroyer;
table->dataDestroyer = dataDestroyer;
table->hashtable.entries = parcMemory_AllocateAndClear(minimumSize * sizeof(HashTableEntry));
assertNotNull(table->hashtable.entries, "parcMemory_AllocateAndClear(%zu) returned NULL", minimumSize * sizeof(HashTableEntry));
table->hashtable.tableLimit = minimumSize;
table->hashtable.tableSize = 0;
memset(table->hashtable.entries, 0, minimumSize * sizeof(HashTableEntry));
// expand at 75% utilization
table->hashtable.expandThreshold = minimumSize - minimumSize / 4;
return table;
}
PARCHashCodeTable *
parcHashCodeTable_Create(PARCHashCodeTable_KeyEqualsFunc keyEqualsFunc,
PARCHashCodeTable_HashCodeFunc keyHashCodeFunc,
PARCHashCodeTable_Destroyer keyDestroyer,
PARCHashCodeTable_Destroyer dataDestroyer)
{
return parcHashCodeTable_Create_Size(keyEqualsFunc, keyHashCodeFunc, keyDestroyer, dataDestroyer, MIN_SIZE);
}
void
parcHashCodeTable_Destroy(PARCHashCodeTable **tablePtr)
{
assertNotNull(tablePtr, "Parameter must be non-null double pointer");
assertNotNull(*tablePtr, "Parameter must dereference to non-null pointer");
PARCHashCodeTable *table = *tablePtr;
size_t i;
for (i = 0; i < table->hashtable.tableLimit; i++) {
if (table->hashtable.entries[i].key != NULL) {
if (table->keyDestroyer) {
table->keyDestroyer(&table->hashtable.entries[i].key);
}
if (table->dataDestroyer) {
table->dataDestroyer(&table->hashtable.entries[i].data);
}
}
}
parcMemory_Deallocate((void **) &(table->hashtable.entries));
parcMemory_Deallocate((void **) &table);
*tablePtr = NULL;
}
bool
parcHashCodeTable_Add(PARCHashCodeTable *table, void *key, void *data)
{
assertNotNull(table, "Parameter table must be non-null");
assertNotNull(key, "Parameter key must be non-null");
assertNotNull(data, "Parameter data must be non-null");
if (table->hashtable.tableSize >= table->hashtable.expandThreshold) {
_expand(table);
}
HashCodeType hashcode = table->keyHashCodeFunc(key);
PARCHashCodeTable_AddResult result = ADD_OK;
do {
result = _innerTableAdd(&table->hashtable, table->keyEqualsFunc, hashcode, key, data);
if (result == ADD_NOSPACE) {
_expand(table);
}
} while (result == ADD_NOSPACE);
return (result == ADD_OK);
}
void
parcHashCodeTable_Del(PARCHashCodeTable *table, const void *key)
{
size_t index;
bool found;
assertNotNull(table, "Parameter table must be non-null");
assertNotNull(key, "parameter key must be non-null");
found = _findIndex(table, key, &index);
if (found) {
assertTrue(table->hashtable.tableSize > 0, "Illegal state: found entry in a hash table with 0 size");
if (table->keyDestroyer) {
table->keyDestroyer(&table->hashtable.entries[index].key);
}
if (table->dataDestroyer) {
table->dataDestroyer(&table->hashtable.entries[index].data);
}
memset(&table->hashtable.entries[index], 0, sizeof(HashTableEntry));
table->hashtable.tableSize--;
}
}
void *
parcHashCodeTable_Get(PARCHashCodeTable *table, const void *key)
{
size_t index;
assertNotNull(table, "Parameter table must be non-null");
assertNotNull(key, "parameter key must be non-null");
bool found = _findIndex(table, key, &index);
if (found) {
return table->hashtable.entries[index].data;
}
return NULL;
}
size_t
parcHashCodeTable_Length(const PARCHashCodeTable *table)
{
assertNotNull(table, "Parameter table must be non-null");
return table->hashtable.tableSize;
}
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