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/**
* \file hash.c
* Generic hash table.
*
* This code taken from Mesa and adapted.
*/
#include <assert.h>
#include <stdlib.h>
#include <stdio.h>
#include "eglhash.h"
#define TABLE_SIZE 1023 /**< Size of lookup table/array */
#define HASH_FUNC(K) ((K) % TABLE_SIZE)
/*
* Unfinished mutex stuff
*/
typedef int _EGLMutex;
static void
_eglInitMutex(_EGLMutex m)
{
}
static void
_eglDestroyMutex(_EGLMutex m)
{
}
static void
_eglLockMutex(_EGLMutex m)
{
}
static void
_eglUnlockMutex(_EGLMutex m)
{
}
typedef struct _egl_hashentry _EGLHashentry;
struct _egl_hashentry
{
EGLuint Key; /**< the entry's key */
void *Data; /**< the entry's data */
_EGLHashentry *Next; /**< pointer to next entry */
};
struct _egl_hashtable
{
_EGLHashentry *Table[TABLE_SIZE]; /**< the lookup table */
EGLuint MaxKey; /**< highest key inserted so far */
_EGLMutex Mutex; /**< mutual exclusion lock */
};
/**
* Create a new hash table.
*
* \return pointer to a new, empty hash table.
*/
_EGLHashtable *
_eglNewHashTable(void)
{
_EGLHashtable *table = (_EGLHashtable *) calloc(1, sizeof(_EGLHashtable));
if (table) {
_eglInitMutex(table->Mutex);
table->MaxKey = 1;
}
return table;
}
/**
* Delete a hash table.
* Frees each entry on the hash table and then the hash table structure itself.
* Note that the caller should have already traversed the table and deleted
* the objects in the table (i.e. We don't free the entries' data pointer).
*
* \param table the hash table to delete.
*/
void
_eglDeleteHashTable(_EGLHashtable *table)
{
EGLuint i;
assert(table);
for (i = 0; i < TABLE_SIZE; i++) {
_EGLHashentry *entry = table->Table[i];
while (entry) {
_EGLHashentry *next = entry->Next;
free(entry);
entry = next;
}
}
_eglDestroyMutex(table->Mutex);
free(table);
}
/**
* Lookup an entry in the hash table.
*
* \param table the hash table.
* \param key the key.
*
* \return pointer to user's data or NULL if key not in table
*/
void *
_eglHashLookup(const _EGLHashtable *table, EGLuint key)
{
EGLuint pos;
const _EGLHashentry *entry;
assert(table);
if (!key)
return NULL;
pos = HASH_FUNC(key);
entry = table->Table[pos];
while (entry) {
if (entry->Key == key) {
return entry->Data;
}
entry = entry->Next;
}
return NULL;
}
/**
* Insert a key/pointer pair into the hash table.
* If an entry with this key already exists we'll replace the existing entry.
*
* \param table the hash table.
* \param key the key (not zero).
* \param data pointer to user data.
*/
void
_eglHashInsert(_EGLHashtable *table, EGLuint key, void *data)
{
/* search for existing entry with this key */
EGLuint pos;
_EGLHashentry *entry;
assert(table);
assert(key);
_eglLockMutex(table->Mutex);
if (key > table->MaxKey)
table->MaxKey = key;
pos = HASH_FUNC(key);
entry = table->Table[pos];
while (entry) {
if (entry->Key == key) {
/* replace entry's data */
entry->Data = data;
_eglUnlockMutex(table->Mutex);
return;
}
entry = entry->Next;
}
/* alloc and insert new table entry */
entry = (_EGLHashentry *) malloc(sizeof(_EGLHashentry));
entry->Key = key;
entry->Data = data;
entry->Next = table->Table[pos];
table->Table[pos] = entry;
_eglUnlockMutex(table->Mutex);
}
/**
* Remove an entry from the hash table.
*
* \param table the hash table.
* \param key key of entry to remove.
*
* While holding the hash table's lock, searches the entry with the matching
* key and unlinks it.
*/
void
_eglHashRemove(_EGLHashtable *table, EGLuint key)
{
EGLuint pos;
_EGLHashentry *entry, *prev;
assert(table);
assert(key);
_eglLockMutex(table->Mutex);
pos = HASH_FUNC(key);
prev = NULL;
entry = table->Table[pos];
while (entry) {
if (entry->Key == key) {
/* found it! */
if (prev) {
prev->Next = entry->Next;
}
else {
table->Table[pos] = entry->Next;
}
free(entry);
_eglUnlockMutex(table->Mutex);
return;
}
prev = entry;
entry = entry->Next;
}
_eglUnlockMutex(table->Mutex);
}
/**
* Get the key of the "first" entry in the hash table.
*
* This is used in the course of deleting all display lists when
* a context is destroyed.
*
* \param table the hash table
*
* \return key for the "first" entry in the hash table.
*
* While holding the lock, walks through all table positions until finding
* the first entry of the first non-empty one.
*/
EGLuint
_eglHashFirstEntry(_EGLHashtable *table)
{
EGLuint pos;
assert(table);
_eglLockMutex(table->Mutex);
for (pos = 0; pos < TABLE_SIZE; pos++) {
if (table->Table[pos]) {
_eglUnlockMutex(table->Mutex);
return table->Table[pos]->Key;
}
}
_eglUnlockMutex(table->Mutex);
return 0;
}
/**
* Given a hash table key, return the next key. This is used to walk
* over all entries in the table. Note that the keys returned during
* walking won't be in any particular order.
* \return next hash key or 0 if end of table.
*/
EGLuint
_eglHashNextEntry(const _EGLHashtable *table, EGLuint key)
{
const _EGLHashentry *entry;
EGLuint pos;
assert(table);
assert(key);
/* Find the entry with given key */
pos = HASH_FUNC(key);
entry = table->Table[pos];
while (entry) {
if (entry->Key == key) {
break;
}
entry = entry->Next;
}
if (!entry) {
/* the key was not found, we can't find next entry */
return 0;
}
if (entry->Next) {
/* return next in linked list */
return entry->Next->Key;
}
else {
/* look for next non-empty table slot */
pos++;
while (pos < TABLE_SIZE) {
if (table->Table[pos]) {
return table->Table[pos]->Key;
}
pos++;
}
return 0;
}
}
/**
* Dump contents of hash table for debugging.
*
* \param table the hash table.
*/
void
_eglHashPrint(const _EGLHashtable *table)
{
EGLuint i;
assert(table);
for (i = 0; i < TABLE_SIZE; i++) {
const _EGLHashentry *entry = table->Table[i];
while (entry) {
printf("%u %p\n", entry->Key, entry->Data);
entry = entry->Next;
}
}
}
/**
* Return a new, unused hash key.
*/
EGLuint
_eglHashGenKey(_EGLHashtable *table)
{
EGLuint k;
_eglLockMutex(table->Mutex);
k = table->MaxKey;
table->MaxKey++;
_eglUnlockMutex(table->Mutex);
return k;
}
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