/* * Copyright (c) 2007 Intel Corporation. All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sub license, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice (including the * next paragraph) shall be included in all copies or substantial portions * of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. * IN NO EVENT SHALL PRECISION INSIGHT AND/OR ITS SUPPLIERS BE LIABLE FOR * ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include "object_heap.h" #include "assert.h" #include #include #include #define ASSERT assert #define LAST_FREE -1 #define ALLOCATED -2 /* * Expands the heap * Return 0 on success, -1 on error */ static int object_heap_expand( object_heap_p heap ) { int i; void *new_heap_index; int next_free; int new_heap_size = heap->heap_size + heap->heap_increment; new_heap_index = (void *) realloc( heap->heap_index, new_heap_size * heap->object_size ); if ( NULL == new_heap_index ) { return -1; /* Out of memory */ } heap->heap_index = new_heap_index; next_free = heap->next_free; for(i = new_heap_size; i-- > heap->heap_size; ) { object_base_p obj = (object_base_p) (heap->heap_index + i * heap->object_size); obj->id = i + heap->id_offset; obj->next_free = next_free; next_free = i; } heap->next_free = next_free; heap->heap_size = new_heap_size; return 0; /* Success */ } /* * Return 0 on success, -1 on error */ int object_heap_init( object_heap_p heap, int object_size, int id_offset) { heap->object_size = object_size; heap->id_offset = id_offset & OBJECT_HEAP_OFFSET_MASK; heap->heap_size = 0; heap->heap_increment = 16; heap->heap_index = NULL; heap->next_free = LAST_FREE; _i965InitMutex(&heap->mutex); return object_heap_expand(heap); } /* * Allocates an object * Returns the object ID on success, returns -1 on error */ int object_heap_allocate( object_heap_p heap ) { object_base_p obj; _i965LockMutex(&heap->mutex); if ( LAST_FREE == heap->next_free ) { if( -1 == object_heap_expand( heap ) ) { _i965UnlockMutex(&heap->mutex); return -1; /* Out of memory */ } } ASSERT( heap->next_free >= 0 ); obj = (object_base_p) (heap->heap_index + heap->next_free * heap->object_size); heap->next_free = obj->next_free; _i965UnlockMutex(&heap->mutex); obj->next_free = ALLOCATED; return obj->id; } /* * Lookup an object by object ID * Returns a pointer to the object on success, returns NULL on error */ object_base_p object_heap_lookup( object_heap_p heap, int id ) { object_base_p obj; _i965LockMutex(&heap->mutex); if ( (id < heap->id_offset) || (id > (heap->heap_size+heap->id_offset)) ) { _i965UnlockMutex(&heap->mutex); return NULL; } id &= OBJECT_HEAP_ID_MASK; obj = (object_base_p) (heap->heap_index + id * heap->object_size); _i965UnlockMutex(&heap->mutex); /* Check if the object has in fact been allocated */ if ( obj->next_free != ALLOCATED ) { return NULL; } return obj; } /* * Iterate over all objects in the heap. * Returns a pointer to the first object on the heap, returns NULL if heap is empty. */ object_base_p object_heap_first( object_heap_p heap, object_heap_iterator *iter ) { *iter = -1; return object_heap_next( heap, iter ); } /* * Iterate over all objects in the heap. * Returns a pointer to the next object on the heap, returns NULL if heap is empty. */ object_base_p object_heap_next( object_heap_p heap, object_heap_iterator *iter ) { object_base_p obj; int i = *iter + 1; _i965LockMutex(&heap->mutex); while ( i < heap->heap_size) { obj = (object_base_p) (heap->heap_index + i * heap->object_size); if (obj->next_free == ALLOCATED) { _i965UnlockMutex(&heap->mutex); *iter = i; return obj; } i++; } _i965UnlockMutex(&heap->mutex); *iter = i; return NULL; } /* * Frees an object */ void object_heap_free( object_heap_p heap, object_base_p obj ) { /* Don't complain about NULL pointers */ if (NULL != obj) { /* Check if the object has in fact been allocated */ ASSERT( obj->next_free == ALLOCATED ); _i965LockMutex(&heap->mutex); obj->next_free = heap->next_free; heap->next_free = obj->id & OBJECT_HEAP_ID_MASK; _i965UnlockMutex(&heap->mutex); } } /* * Destroys a heap, the heap must be empty. */ void object_heap_destroy( object_heap_p heap ) { object_base_p obj; int i; _i965DestroyMutex(&heap->mutex); /* Check if heap is empty */ for (i = 0; i < heap->heap_size; i++) { /* Check if object is not still allocated */ obj = (object_base_p) (heap->heap_index + i * heap->object_size); ASSERT( obj->next_free != ALLOCATED ); } free(heap->heap_index); heap->heap_size = 0; heap->heap_index = NULL; heap->next_free = LAST_FREE; }