framework/delibs/depool/deMemPool.c - third_party/vulkan-cts - Git at Google

 /*-------------------------------------------------------------------------
  * drawElements Memory Pool Library
  * --------------------------------
  *
  * Copyright 2014 The Android Open Source Project
  *
  * 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.
  *
  *//*!
  * \file
  * \brief Memory pool management.
  *//*--------------------------------------------------------------------*/

 #include "deMemPool.h"
 #include "deMemory.h"
 #include "deInt32.h"

 #if defined(DE_SUPPORT_FAILING_POOL_ALLOC)
 #	include "deRandom.h"
 #endif

 #include <stdlib.h>
 #include <string.h>

 enum
 {
 	INITIAL_PAGE_SIZE		= 128,		/*!< Size for the first allocated memory page.			*/
 	MAX_PAGE_SIZE			= 8096,		/*!< Maximum size for a memory page.					*/
 	MEM_PAGE_BASE_ALIGN		= 4			/*!< Base alignment guarantee for mem page data ptr.	*/
 };

 typedef struct MemPage_s MemPage;

 /*--------------------------------------------------------------------*//*!
  * \internal
  * \brief Memory page header.
  *
  * Represent a page of memory allocate by a memory pool.
  *//*--------------------------------------------------------------------*/
 struct MemPage_s
 {
 	int			capacity;
 	int			bytesAllocated;

 	MemPage*	nextPage;
 };

 #if defined(DE_SUPPORT_DEBUG_POOLS)
 typedef struct DebugAlloc_s DebugAlloc;

 struct DebugAlloc_s
 {
 	void*			memPtr;
 	DebugAlloc*		next;
 };
 #endif

 /*--------------------------------------------------------------------*//*!
  * \brief Memory pool.
  *
  * A pool of memory from which individual memory allocations can be made.
  * The memory pools don't have a freeing operation for individual allocations,
  * but rather all of the memory allocated from a pool is freed when the pool
  * is destroyed.
  *
  * The pools can be arranged into a hierarchy. If a pool with children is
  * destroyed, all of the children are first recursively destroyed and then
  * the pool itself.
  *
  * The memory pools support a feature where individual allocations can be
  * made to simulate failure (i.e., return null). This can be enabled by
  * creating the root pool with the deMemPool_createFailingRoot() function.
  * When the feature is enabled, also creation of sub-pools occasionally
  * fails.
  *//*--------------------------------------------------------------------*/
 struct deMemPool_s
 {
 	deUint32		flags;				/*!< Flags.											*/
 	deMemPool*		parent;				/*!< Pointer to parent (null for root pools).		*/
 	deMemPoolUtil*	util;				/*!< Utilities (callbacks etc.).					*/
 	int				numChildren;		/*!< Number of child pools.							*/
 	deMemPool*		firstChild;			/*!< Pointer to first child pool in linked list.	*/
 	deMemPool*		prevPool;			/*!< Previous pool in parent's linked list.			*/
 	deMemPool*		nextPool;			/*!< Next pool in parent's linked list.				*/

 	MemPage*		currentPage;		/*!< Current memory page from which to allocate.	*/

 #if defined(DE_SUPPORT_FAILING_POOL_ALLOC)
 	deBool			allowFailing;		/*!< Is allocation failure simulation enabled?		*/
 	deRandom		failRandom;			/*!< RNG for failing allocations.					*/
 #endif
 #if defined(DE_SUPPORT_DEBUG_POOLS)
 	deBool			enableDebugAllocs;	/*!< If true, always allocates using deMalloc().	*/
 	DebugAlloc*		debugAllocListHead;	/*!< List of allocation in debug mode.				*/

 	int				lastAllocatedIndex;	/*!< Index of last allocated pool (rootPool only).	*/
 	int				allocIndex;			/*!< Allocation index (running counter).			*/
 #endif
 #if defined(DE_SUPPORT_POOL_MEMORY_TRACKING)
 	int				maxMemoryAllocated;	/*!< Maximum amount of memory allocated from pools.	*/
 	int				maxMemoryCapacity;	/*!< Maximum amount of memory allocated for pools.	*/
 #endif
 };

 /*--------------------------------------------------------------------*//*!
  * \internal
  * \brief Initialize a memory page.
  * \param page		Memory page to initialize.
  * \param capacity	Capacity allocated for the memory page.
  *//*--------------------------------------------------------------------*/
 static void MemPage_init (MemPage* page, size_t capacity)
 {
 	memset(page, 0, sizeof(MemPage));
 #if defined(DE_DEBUG)
 	memset(page + 1, 0xCD, capacity);
 #endif
 	page->capacity = (int)capacity;
 }

 /*--------------------------------------------------------------------*//*!
  * \internal
  * \brief Create a new memory page.
  * \param capacity	Capacity for the memory page.
  * \return The created memory page (or null on failure).
  *//*--------------------------------------------------------------------*/
 static MemPage* MemPage_create (size_t capacity)
 {
 	MemPage* page = (MemPage*)deMalloc(sizeof(MemPage) + capacity);
 	if (!page)
 		return DE_NULL;

 	DE_ASSERT(deIsAlignedPtr(page+1, MEM_PAGE_BASE_ALIGN));

 	MemPage_init(page, capacity);
 	return page;
 }

 /*--------------------------------------------------------------------*//*!
  * \internal
  * \brief Destroy a memory page.
  * \param page	Memory page to destroy.
  *//*--------------------------------------------------------------------*/
 static void MemPage_destroy (MemPage* page)
 {
 #if defined(DE_DEBUG)
 	/* Fill with garbage to hopefully catch dangling pointer bugs easier. */
 	deUint8* dataPtr = (deUint8*)(page + 1);
 	memset(dataPtr, 0xCD, (size_t)page->capacity);
 #endif
 	deFree(page);
 }

 /*--------------------------------------------------------------------*//*!
  * \internal
  * \brief Internal function for creating a new memory pool.
  * \param parent	Parent pool (may be null).
  * \return The created memory pool (or null on failure).
  *//*--------------------------------------------------------------------*/
 static deMemPool* createPoolInternal (deMemPool* parent)
 {
 	deMemPool*	pool;
 	MemPage*	initialPage;

 #if defined(DE_SUPPORT_FAILING_POOL_ALLOC)
 	if (parent && parent->allowFailing)
 	{
 		if ((deRandom_getUint32(&parent->failRandom) & 16383) <= 15)
 			return DE_NULL;
 	}
 #endif

 	/* Init first page. */
 	initialPage = MemPage_create(INITIAL_PAGE_SIZE);
 	if (!initialPage)
 		return DE_NULL;

 	/* Alloc pool from initial page. */
 	DE_ASSERT((int)sizeof(deMemPool) <= initialPage->capacity);
 	pool = (deMemPool*)(initialPage + 1);
 	initialPage->bytesAllocated += (int)sizeof(deMemPool);

 	memset(pool, 0, sizeof(deMemPool));
 	pool->currentPage = initialPage;

 	/* Register to parent. */
 	pool->parent = parent;
 	if (parent)
 	{
 		parent->numChildren++;
 		if (parent->firstChild) parent->firstChild->prevPool = pool;
 		pool->nextPool = parent->firstChild;
 		parent->firstChild = pool;
 	}

 	/* Get utils from parent. */
 	pool->util = parent ? parent->util : DE_NULL;

 #if defined(DE_SUPPORT_FAILING_POOL_ALLOC)
 	pool->allowFailing = parent ? parent->allowFailing : DE_FALSE;
 	deRandom_init(&pool->failRandom, parent ? deRandom_getUint32(&parent->failRandom) : 0x1234abcd);
 #endif

 #if defined(DE_SUPPORT_DEBUG_POOLS)
 	pool->enableDebugAllocs		= parent ? parent->enableDebugAllocs : DE_FALSE;
 	pool->debugAllocListHead	= DE_NULL;

 	/* Pool allocation index. */
 	{
 		deMemPool* root = pool;
 		while (root->parent)
 			root = root->parent;

 		if (pool == root)
 			root->lastAllocatedIndex = 0;

 		pool->allocIndex = ++root->lastAllocatedIndex;

 		/* \note Put the index of leaking pool here and add a breakpoint to catch leaks easily. */
 /*		if (pool->allocIndex == 51)
 			root = root;*/
 	}
 #endif

 	return pool;
 }

 /*--------------------------------------------------------------------*//*!
  * \brief Create a new root memory pool.
  * \return The created memory pool (or null on failure).
  *//*--------------------------------------------------------------------*/
 deMemPool* deMemPool_createRoot	(const deMemPoolUtil* util, deUint32 flags)
 {
 	deMemPool* pool = createPoolInternal(DE_NULL);
 	if (!pool)
 		return DE_NULL;
 #if defined(DE_SUPPORT_FAILING_POOL_ALLOC)
 	if (flags & DE_MEMPOOL_ENABLE_FAILING_ALLOCS)
 		pool->allowFailing = DE_TRUE;
 #endif
 #if defined(DE_SUPPORT_DEBUG_POOLS)
 	if (flags & DE_MEMPOOL_ENABLE_DEBUG_ALLOCS)
 	{
 		pool->enableDebugAllocs		= DE_TRUE;
 		pool->debugAllocListHead	= DE_NULL;
 	}
 #endif
 	DE_UNREF(flags); /* in case no debug features enabled */

 	/* Get copy of utilities. */
 	if (util)
 	{
 		deMemPoolUtil* utilCopy = DE_POOL_NEW(pool, deMemPoolUtil);
 		DE_ASSERT(util->allocFailCallback);
 		if (!utilCopy)
 		{
 			deMemPool_destroy(pool);
 			return DE_NULL;
 		}

 		memcpy(utilCopy, util, sizeof(deMemPoolUtil));
 		pool->util = utilCopy;
 	}

 	return pool;
 }

 /*--------------------------------------------------------------------*//*!
  * \brief Create a sub-pool for an existing memory pool.
  * \return The created memory pool (or null on failure).
  *//*--------------------------------------------------------------------*/
 deMemPool* deMemPool_create (deMemPool* parent)
 {
 	deMemPool* pool;
 	DE_ASSERT(parent);
 	pool = createPoolInternal(parent);
 	if (!pool && parent->util)
 		parent->util->allocFailCallback(parent->util->userPointer);
 	return pool;
 }

 /*--------------------------------------------------------------------*//*!
  * \brief Destroy a memory pool.
  * \param pool	Pool to be destroyed.
  *
  * Frees all the memory allocated from the pool. Also destroyed any child
  * pools that the pool has (recursively).
  *//*--------------------------------------------------------------------*/
 void deMemPool_destroy (deMemPool* pool)
 {
 	deMemPool* iter;
 	deMemPool* iterNext;

 #if defined(DE_SUPPORT_POOL_MEMORY_TRACKING)
 	/* Update memory consumption statistics. */
 	if (pool->parent)
 	{
 		deMemPool* root = pool->parent;
 		while (root->parent)
 			root = root->parent;
 		root->maxMemoryAllocated	= deMax32(root->maxMemoryAllocated, deMemPool_getNumAllocatedBytes(root, DE_TRUE));
 		root->maxMemoryCapacity		= deMax32(root->maxMemoryCapacity, deMemPool_getCapacity(root, DE_TRUE));
 	}
 #endif

 	/* Destroy all children. */
 	iter = pool->firstChild;
 	while (iter)
 	{
 		iterNext = iter->nextPool;
 		deMemPool_destroy(iter);
 		iter = iterNext;
 	}

 	DE_ASSERT(pool->numChildren == 0);

 	/* Update pointers. */
 	if (pool->prevPool) pool->prevPool->nextPool = pool->nextPool;
 	if (pool->nextPool) pool->nextPool->prevPool = pool->prevPool;

 	if (pool->parent)
 	{
 		deMemPool* parent = pool->parent;
 		if (parent->firstChild == pool)
 			parent->firstChild = pool->nextPool;

 		parent->numChildren--;
 		DE_ASSERT(parent->numChildren >= 0);
 	}

 #if defined(DE_SUPPORT_DEBUG_POOLS)
 	/* Free all debug allocations. */
 	if (pool->enableDebugAllocs)
 	{
 		DebugAlloc* alloc	= pool->debugAllocListHead;
 		DebugAlloc* next;

 		while (alloc)
 		{
 			next = alloc->next;
 			deAlignedFree(alloc->memPtr);
 			deFree(alloc);
 			alloc = next;
 		}

 		pool->debugAllocListHead = DE_NULL;
 	}
 #endif

 	/* Free pages. */
 	/* \note Pool itself is allocated from first page, so we must not touch the pool after freeing the page! */
 	{
 		MemPage* page = pool->currentPage;
 		MemPage* nextPage;

 		while (page)
 		{
 			nextPage = page->nextPage;
 			MemPage_destroy(page);
 			page = nextPage;
 		}
 	}
 }

 /*--------------------------------------------------------------------*//*!
  * \brief Get the number of children for a pool.
  * \return The number of (immediate) child pools a memory pool has.
  *//*--------------------------------------------------------------------*/
 int deMemPool_getNumChildren (const deMemPool* pool)
 {
 	return pool->numChildren;
 }

 /*--------------------------------------------------------------------*//*!
  * \brief Get the number of bytes allocated (by the user) from the pool.
  * \param pool		Pool pointer.
  * \param recurse	Is operation recursive to child pools?
  * \return The number of bytes allocated by the pool (including child pools
  *		   if 'recurse' is true).
  *//*--------------------------------------------------------------------*/
 int deMemPool_getNumAllocatedBytes (const deMemPool* pool, deBool recurse)
 {
 	int			numAllocatedBytes = 0;
 	MemPage*	memPage;

 	for (memPage = pool->currentPage; memPage; memPage = memPage->nextPage)
 		numAllocatedBytes += memPage->bytesAllocated;

 	if (recurse)
 	{
 		deMemPool* child;
 		for (child = pool->firstChild; child; child = child->nextPool)
 			numAllocatedBytes += deMemPool_getNumAllocatedBytes(child, DE_TRUE);
 	}

 	return numAllocatedBytes;
 }

 int deMemPool_getCapacity (const deMemPool* pool, deBool recurse)
 {
 	int			numCapacityBytes = 0;
 	MemPage*	memPage;

 	for (memPage = pool->currentPage; memPage; memPage = memPage->nextPage)
 		numCapacityBytes += memPage->capacity;

 	if (recurse)
 	{
 		deMemPool* child;
 		for (child = pool->firstChild; child; child = child->nextPool)
 			numCapacityBytes += deMemPool_getCapacity(child, DE_TRUE);
 	}

 	return numCapacityBytes;
 }

 DE_INLINE void* deMemPool_allocInternal (deMemPool* pool, size_t numBytes, deUint32 alignBytes)
 {
 	MemPage* curPage = pool->currentPage;

 #if defined(DE_SUPPORT_FAILING_POOL_ALLOC)
 	if (pool->allowFailing)
 	{
 		if ((deRandom_getUint32(&pool->failRandom) & 16383) <= 15)
 			return DE_NULL;
 	}
 #endif

 #if defined(DE_SUPPORT_DEBUG_POOLS)
 	if (pool->enableDebugAllocs)
 	{
 		DebugAlloc*	header	= DE_NEW(DebugAlloc);
 		void*		ptr		= deAlignedMalloc(numBytes, alignBytes);

 		if (!header || !ptr)
 		{
 			deFree(header);
 			deAlignedFree(ptr);
 			return DE_NULL;
 		}

 		header->memPtr	= ptr;
 		header->next	= pool->debugAllocListHead;
 		pool->debugAllocListHead = header;

 		return ptr;
 	}
 #endif

 	DE_ASSERT(curPage);
 	DE_ASSERT(deIsPowerOfTwo32((int)alignBytes));
 	{
 		void*	curPagePtr		= (void*)((deUint8*)(curPage + 1) + curPage->bytesAllocated);
 		void*	alignedPtr		= deAlignPtr(curPagePtr, alignBytes);
 		size_t	alignPadding	= (size_t)((deUintptr)alignedPtr - (deUintptr)curPagePtr);

 		if (numBytes + alignPadding > (size_t)(curPage->capacity - curPage->bytesAllocated))
 		{
 			/* Does not fit to current page. */
 			int		maxAlignPadding		= deMax32(0, ((int)alignBytes)-MEM_PAGE_BASE_ALIGN);
 			int		newPageCapacity		= deMax32(deMin32(2*curPage->capacity, MAX_PAGE_SIZE), ((int)numBytes)+maxAlignPadding);

 			curPage = MemPage_create((size_t)newPageCapacity);
 			if (!curPage)
 				return DE_NULL;

 			curPage->nextPage	= pool->currentPage;
 			pool->currentPage	= curPage;

 			DE_ASSERT(curPage->bytesAllocated == 0);

 			curPagePtr			= (void*)(curPage + 1);
 			alignedPtr			= deAlignPtr(curPagePtr, alignBytes);
 			alignPadding		= (size_t)((deUintptr)alignedPtr - (deUintptr)curPagePtr);

 			DE_ASSERT(numBytes + alignPadding <= (size_t)curPage->capacity);
 		}

 		curPage->bytesAllocated += (int)(numBytes + alignPadding);
 		return alignedPtr;
 	}
 }

 /*--------------------------------------------------------------------*//*!
  * \brief Allocate memory from a pool.
  * \param pool		Memory pool to allocate from.
  * \param numBytes	Number of bytes to allocate.
  * \return Pointer to the allocate memory (or null on failure).
  *//*--------------------------------------------------------------------*/
 void* deMemPool_alloc (deMemPool* pool, size_t numBytes)
 {
 	void* ptr;
 	DE_ASSERT(pool);
 	DE_ASSERT(numBytes > 0);
 	ptr = deMemPool_allocInternal(pool, numBytes, DE_POOL_DEFAULT_ALLOC_ALIGNMENT);
 	if (!ptr && pool->util)
 		pool->util->allocFailCallback(pool->util->userPointer);
 	return ptr;
 }

 /*--------------------------------------------------------------------*//*!
  * \brief Allocate aligned memory from a pool.
  * \param pool			Memory pool to allocate from.
  * \param numBytes		Number of bytes to allocate.
  * \param alignBytes	Required alignment in bytes, must be power of two.
  * \return Pointer to the allocate memory (or null on failure).
  *//*--------------------------------------------------------------------*/
 void* deMemPool_alignedAlloc (deMemPool* pool, size_t numBytes, deUint32 alignBytes)
 {
 	void* ptr;
 	DE_ASSERT(pool);
 	DE_ASSERT(numBytes > 0);
 	DE_ASSERT(deIsPowerOfTwo32((int)alignBytes));
 	ptr = deMemPool_allocInternal(pool, numBytes, alignBytes);
 	DE_ASSERT(deIsAlignedPtr(ptr, alignBytes));
 	if (!ptr && pool->util)
 		pool->util->allocFailCallback(pool->util->userPointer);
 	return ptr;
 }

 /*--------------------------------------------------------------------*//*!
  * \brief Duplicate a piece of memory into a memory pool.
  * \param pool	Memory pool to allocate from.
  * \param ptr	Piece of memory to duplicate.
  * \return Pointer to the copied memory block (or null on failure).
  *//*--------------------------------------------------------------------*/
 void* deMemPool_memDup (deMemPool* pool, const void* ptr, size_t numBytes)
 {
 	void* newPtr = deMemPool_alloc(pool, numBytes);
 	if (newPtr)
 		memcpy(newPtr, ptr, numBytes);
 	return newPtr;
 }

 /*--------------------------------------------------------------------*//*!
  * \brief Duplicate a string into a memory pool.
  * \param pool	Memory pool to allocate from.
  * \param str	String to duplicate.
  * \return Pointer to the new string (or null on failure).
  *//*--------------------------------------------------------------------*/
 char* deMemPool_strDup (deMemPool* pool, const char* str)
 {
 	size_t	len		= strlen(str);
 	char*	newStr	= (char*)deMemPool_alloc(pool, len+1);
 	if (newStr)
 		memcpy(newStr, str, len+1);
 	return newStr;
 }

 /*--------------------------------------------------------------------*//*!
  * \brief Duplicate a string into a memory pool, with a maximum length.
  * \param pool		Memory pool to allocate from.
  * \param str		String to duplicate.
  * \param maxLength	Maximum number of characters to duplicate.
  * \return Pointer to the new string (or null on failure).
  *//*--------------------------------------------------------------------*/
 char* deMemPool_strnDup (deMemPool* pool, const char* str, int maxLength)
 {
 	size_t	len			= (size_t)deMin32((int)strlen(str), deMax32(0, maxLength));
 	char*	newStr		= (char*)deMemPool_alloc(pool, len + 1);

 	DE_ASSERT(maxLength >= 0);

 	if (newStr)
 	{
 		memcpy(newStr, str, len);
 		newStr[len] = 0;
 	}
 	return newStr;
 }

 #if defined(DE_SUPPORT_POOL_MEMORY_TRACKING)

 int deMemPool_getMaxNumAllocatedBytes (const deMemPool* pool)
 {
 	DE_ASSERT(pool && !pool->parent); /* must be root */
 	return deMax32(pool->maxMemoryAllocated, deMemPool_getNumAllocatedBytes(pool, DE_TRUE));
 }

 int deMemPool_getMaxCapacity (const deMemPool* pool)
 {
 	DE_ASSERT(pool && !pool->parent); /* must be root */
 	return deMax32(pool->maxMemoryCapacity, deMemPool_getCapacity(pool, DE_TRUE));
 }

 #endif
	/*-------------------------------------------------------------------------
	* drawElements Memory Pool Library
	* --------------------------------
	*
	* Copyright 2014 The Android Open Source Project
	*
	* 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.
	*
	//!
	* \file
	* \brief Memory pool management.
	//--------------------------------------------------------------------*/

	#include "deMemPool.h"
	#include "deMemory.h"
	#include "deInt32.h"

	#if defined(DE_SUPPORT_FAILING_POOL_ALLOC)
	# include "deRandom.h"
	#endif

	#include <stdlib.h>
	#include <string.h>

	enum
	{
	INITIAL_PAGE_SIZE = 128, /!< Size for the first allocated memory page. /
	MAX_PAGE_SIZE = 8096, /!< Maximum size for a memory page. /
	MEM_PAGE_BASE_ALIGN = 4 /!< Base alignment guarantee for mem page data ptr. /
	};

	typedef struct MemPage_s MemPage;

	/--------------------------------------------------------------------//*!
	* \internal
	* \brief Memory page header.
	*
	* Represent a page of memory allocate by a memory pool.
	//--------------------------------------------------------------------*/
	struct MemPage_s
	{
	int capacity;
	int bytesAllocated;

	MemPage* nextPage;
	};

	#if defined(DE_SUPPORT_DEBUG_POOLS)
	typedef struct DebugAlloc_s DebugAlloc;

	struct DebugAlloc_s
	{
	void* memPtr;
	DebugAlloc* next;
	};
	#endif

	/--------------------------------------------------------------------//*!
	* \brief Memory pool.
	*
	* A pool of memory from which individual memory allocations can be made.
	* The memory pools don't have a freeing operation for individual allocations,
	* but rather all of the memory allocated from a pool is freed when the pool
	* is destroyed.
	*
	* The pools can be arranged into a hierarchy. If a pool with children is
	* destroyed, all of the children are first recursively destroyed and then
	* the pool itself.
	*
	* The memory pools support a feature where individual allocations can be
	* made to simulate failure (i.e., return null). This can be enabled by
	* creating the root pool with the deMemPool_createFailingRoot() function.
	* When the feature is enabled, also creation of sub-pools occasionally
	* fails.
	//--------------------------------------------------------------------*/
	struct deMemPool_s
	{
	deUint32 flags; /!< Flags. /
	deMemPool* parent; /!< Pointer to parent (null for root pools). /
	deMemPoolUtil* util; /!< Utilities (callbacks etc.). /
	int numChildren; /!< Number of child pools. /
	deMemPool* firstChild; /!< Pointer to first child pool in linked list. /
	deMemPool* prevPool; /!< Previous pool in parent's linked list. /
	deMemPool* nextPool; /!< Next pool in parent's linked list. /

	MemPage* currentPage; /!< Current memory page from which to allocate. /

	#if defined(DE_SUPPORT_FAILING_POOL_ALLOC)
	deBool allowFailing; /!< Is allocation failure simulation enabled? /
	deRandom failRandom; /!< RNG for failing allocations. /
	#endif
	#if defined(DE_SUPPORT_DEBUG_POOLS)
	deBool enableDebugAllocs; /!< If true, always allocates using deMalloc(). /
	DebugAlloc* debugAllocListHead; /!< List of allocation in debug mode. /

	int lastAllocatedIndex; /!< Index of last allocated pool (rootPool only). /
	int allocIndex; /!< Allocation index (running counter). /
	#endif
	#if defined(DE_SUPPORT_POOL_MEMORY_TRACKING)
	int maxMemoryAllocated; /!< Maximum amount of memory allocated from pools. /
	int maxMemoryCapacity; /!< Maximum amount of memory allocated for pools. /
	#endif
	};

	/--------------------------------------------------------------------//*!
	* \internal
	* \brief Initialize a memory page.
	* \param page Memory page to initialize.
	* \param capacity Capacity allocated for the memory page.
	//--------------------------------------------------------------------*/
	static void MemPage_init (MemPage* page, size_t capacity)
	{
	memset(page, 0, sizeof(MemPage));
	#if defined(DE_DEBUG)
	memset(page + 1, 0xCD, capacity);
	#endif
	page->capacity = (int)capacity;
	}

	/--------------------------------------------------------------------//*!
	* \internal
	* \brief Create a new memory page.
	* \param capacity Capacity for the memory page.
	* \return The created memory page (or null on failure).
	//--------------------------------------------------------------------*/
	static MemPage* MemPage_create (size_t capacity)
	{
	MemPage* page = (MemPage*)deMalloc(sizeof(MemPage) + capacity);
	if (!page)
	return DE_NULL;

	DE_ASSERT(deIsAlignedPtr(page+1, MEM_PAGE_BASE_ALIGN));

	MemPage_init(page, capacity);
	return page;
	}

	/--------------------------------------------------------------------//*!
	* \internal
	* \brief Destroy a memory page.
	* \param page Memory page to destroy.
	//--------------------------------------------------------------------*/
	static void MemPage_destroy (MemPage* page)
	{
	#if defined(DE_DEBUG)
	/* Fill with garbage to hopefully catch dangling pointer bugs easier. */
	deUint8* dataPtr = (deUint8*)(page + 1);
	memset(dataPtr, 0xCD, (size_t)page->capacity);
	#endif
	deFree(page);
	}

	/--------------------------------------------------------------------//*!
	* \internal
	* \brief Internal function for creating a new memory pool.
	* \param parent Parent pool (may be null).
	* \return The created memory pool (or null on failure).
	//--------------------------------------------------------------------*/
	static deMemPool* createPoolInternal (deMemPool* parent)
	{
	deMemPool* pool;
	MemPage* initialPage;

	#if defined(DE_SUPPORT_FAILING_POOL_ALLOC)
	if (parent && parent->allowFailing)
	{
	if ((deRandom_getUint32(&parent->failRandom) & 16383) <= 15)
	return DE_NULL;
	}
	#endif

	/* Init first page. */
	initialPage = MemPage_create(INITIAL_PAGE_SIZE);
	if (!initialPage)
	return DE_NULL;

	/* Alloc pool from initial page. */
	DE_ASSERT((int)sizeof(deMemPool) <= initialPage->capacity);
	pool = (deMemPool*)(initialPage + 1);
	initialPage->bytesAllocated += (int)sizeof(deMemPool);

	memset(pool, 0, sizeof(deMemPool));
	pool->currentPage = initialPage;

	/* Register to parent. */
	pool->parent = parent;
	if (parent)
	{
	parent->numChildren++;
	if (parent->firstChild) parent->firstChild->prevPool = pool;
	pool->nextPool = parent->firstChild;
	parent->firstChild = pool;
	}

	/* Get utils from parent. */
	pool->util = parent ? parent->util : DE_NULL;

	#if defined(DE_SUPPORT_FAILING_POOL_ALLOC)
	pool->allowFailing = parent ? parent->allowFailing : DE_FALSE;
	deRandom_init(&pool->failRandom, parent ? deRandom_getUint32(&parent->failRandom) : 0x1234abcd);
	#endif

	#if defined(DE_SUPPORT_DEBUG_POOLS)
	pool->enableDebugAllocs = parent ? parent->enableDebugAllocs : DE_FALSE;
	pool->debugAllocListHead = DE_NULL;

	/* Pool allocation index. */
	{
	deMemPool* root = pool;
	while (root->parent)
	root = root->parent;

	if (pool == root)
	root->lastAllocatedIndex = 0;

	pool->allocIndex = ++root->lastAllocatedIndex;

	/* \note Put the index of leaking pool here and add a breakpoint to catch leaks easily. */
	/* if (pool->allocIndex == 51)
	root = root;*/
	}
	#endif

	return pool;
	}

	/--------------------------------------------------------------------//*!
	* \brief Create a new root memory pool.
	* \return The created memory pool (or null on failure).
	//--------------------------------------------------------------------*/
	deMemPool* deMemPool_createRoot (const deMemPoolUtil* util, deUint32 flags)
	{
	deMemPool* pool = createPoolInternal(DE_NULL);
	if (!pool)
	return DE_NULL;
	#if defined(DE_SUPPORT_FAILING_POOL_ALLOC)
	if (flags & DE_MEMPOOL_ENABLE_FAILING_ALLOCS)
	pool->allowFailing = DE_TRUE;
	#endif
	#if defined(DE_SUPPORT_DEBUG_POOLS)
	if (flags & DE_MEMPOOL_ENABLE_DEBUG_ALLOCS)
	{
	pool->enableDebugAllocs = DE_TRUE;
	pool->debugAllocListHead = DE_NULL;
	}
	#endif
	DE_UNREF(flags); /* in case no debug features enabled */

	/* Get copy of utilities. */
	if (util)
	{
	deMemPoolUtil* utilCopy = DE_POOL_NEW(pool, deMemPoolUtil);
	DE_ASSERT(util->allocFailCallback);
	if (!utilCopy)
	{
	deMemPool_destroy(pool);
	return DE_NULL;
	}

	memcpy(utilCopy, util, sizeof(deMemPoolUtil));
	pool->util = utilCopy;
	}

	return pool;
	}

	/--------------------------------------------------------------------//*!
	* \brief Create a sub-pool for an existing memory pool.
	* \return The created memory pool (or null on failure).
	//--------------------------------------------------------------------*/
	deMemPool* deMemPool_create (deMemPool* parent)
	{
	deMemPool* pool;
	DE_ASSERT(parent);
	pool = createPoolInternal(parent);
	if (!pool && parent->util)
	parent->util->allocFailCallback(parent->util->userPointer);
	return pool;
	}

	/--------------------------------------------------------------------//*!
	* \brief Destroy a memory pool.
	* \param pool Pool to be destroyed.
	*
	* Frees all the memory allocated from the pool. Also destroyed any child
	* pools that the pool has (recursively).
	//--------------------------------------------------------------------*/
	void deMemPool_destroy (deMemPool* pool)
	{
	deMemPool* iter;
	deMemPool* iterNext;

	#if defined(DE_SUPPORT_POOL_MEMORY_TRACKING)
	/* Update memory consumption statistics. */
	if (pool->parent)
	{
	deMemPool* root = pool->parent;
	while (root->parent)
	root = root->parent;
	root->maxMemoryAllocated = deMax32(root->maxMemoryAllocated, deMemPool_getNumAllocatedBytes(root, DE_TRUE));
	root->maxMemoryCapacity = deMax32(root->maxMemoryCapacity, deMemPool_getCapacity(root, DE_TRUE));
	}
	#endif

	/* Destroy all children. */
	iter = pool->firstChild;
	while (iter)
	{
	iterNext = iter->nextPool;
	deMemPool_destroy(iter);
	iter = iterNext;
	}

	DE_ASSERT(pool->numChildren == 0);

	/* Update pointers. */
	if (pool->prevPool) pool->prevPool->nextPool = pool->nextPool;
	if (pool->nextPool) pool->nextPool->prevPool = pool->prevPool;

	if (pool->parent)
	{
	deMemPool* parent = pool->parent;
	if (parent->firstChild == pool)
	parent->firstChild = pool->nextPool;

	parent->numChildren--;
	DE_ASSERT(parent->numChildren >= 0);
	}

	#if defined(DE_SUPPORT_DEBUG_POOLS)
	/* Free all debug allocations. */
	if (pool->enableDebugAllocs)
	{
	DebugAlloc* alloc = pool->debugAllocListHead;
	DebugAlloc* next;

	while (alloc)
	{
	next = alloc->next;
	deAlignedFree(alloc->memPtr);
	deFree(alloc);
	alloc = next;
	}

	pool->debugAllocListHead = DE_NULL;
	}
	#endif

	/* Free pages. */
	/* \note Pool itself is allocated from first page, so we must not touch the pool after freeing the page! */
	{
	MemPage* page = pool->currentPage;
	MemPage* nextPage;

	while (page)
	{
	nextPage = page->nextPage;
	MemPage_destroy(page);
	page = nextPage;
	}
	}
	}

	/--------------------------------------------------------------------//*!
	* \brief Get the number of children for a pool.
	* \return The number of (immediate) child pools a memory pool has.
	//--------------------------------------------------------------------*/
	int deMemPool_getNumChildren (const deMemPool* pool)
	{
	return pool->numChildren;
	}

	/--------------------------------------------------------------------//*!
	* \brief Get the number of bytes allocated (by the user) from the pool.
	* \param pool Pool pointer.
	* \param recurse Is operation recursive to child pools?
	* \return The number of bytes allocated by the pool (including child pools
	* if 'recurse' is true).
	//--------------------------------------------------------------------*/
	int deMemPool_getNumAllocatedBytes (const deMemPool* pool, deBool recurse)
	{
	int numAllocatedBytes = 0;
	MemPage* memPage;

	for (memPage = pool->currentPage; memPage; memPage = memPage->nextPage)
	numAllocatedBytes += memPage->bytesAllocated;

	if (recurse)
	{
	deMemPool* child;
	for (child = pool->firstChild; child; child = child->nextPool)
	numAllocatedBytes += deMemPool_getNumAllocatedBytes(child, DE_TRUE);
	}

	return numAllocatedBytes;
	}

	int deMemPool_getCapacity (const deMemPool* pool, deBool recurse)
	{
	int numCapacityBytes = 0;
	MemPage* memPage;

	for (memPage = pool->currentPage; memPage; memPage = memPage->nextPage)
	numCapacityBytes += memPage->capacity;

	if (recurse)
	{
	deMemPool* child;
	for (child = pool->firstChild; child; child = child->nextPool)
	numCapacityBytes += deMemPool_getCapacity(child, DE_TRUE);
	}

	return numCapacityBytes;
	}

	DE_INLINE void* deMemPool_allocInternal (deMemPool* pool, size_t numBytes, deUint32 alignBytes)
	{
	MemPage* curPage = pool->currentPage;

	#if defined(DE_SUPPORT_FAILING_POOL_ALLOC)
	if (pool->allowFailing)
	{
	if ((deRandom_getUint32(&pool->failRandom) & 16383) <= 15)
	return DE_NULL;
	}
	#endif

	#if defined(DE_SUPPORT_DEBUG_POOLS)
	if (pool->enableDebugAllocs)
	{
	DebugAlloc* header = DE_NEW(DebugAlloc);
	void* ptr = deAlignedMalloc(numBytes, alignBytes);

	if (!header \|\| !ptr)
	{
	deFree(header);
	deAlignedFree(ptr);
	return DE_NULL;
	}

	header->memPtr = ptr;
	header->next = pool->debugAllocListHead;
	pool->debugAllocListHead = header;

	return ptr;
	}
	#endif

	DE_ASSERT(curPage);
	DE_ASSERT(deIsPowerOfTwo32((int)alignBytes));
	{
	void* curPagePtr = (void)((deUint8)(curPage + 1) + curPage->bytesAllocated);
	void* alignedPtr = deAlignPtr(curPagePtr, alignBytes);
	size_t alignPadding = (size_t)((deUintptr)alignedPtr - (deUintptr)curPagePtr);

	if (numBytes + alignPadding > (size_t)(curPage->capacity - curPage->bytesAllocated))
	{
	/* Does not fit to current page. */
	int maxAlignPadding = deMax32(0, ((int)alignBytes)-MEM_PAGE_BASE_ALIGN);
	int newPageCapacity = deMax32(deMin32(2*curPage->capacity, MAX_PAGE_SIZE), ((int)numBytes)+maxAlignPadding);

	curPage = MemPage_create((size_t)newPageCapacity);
	if (!curPage)
	return DE_NULL;

	curPage->nextPage = pool->currentPage;
	pool->currentPage = curPage;

	DE_ASSERT(curPage->bytesAllocated == 0);

	curPagePtr = (void*)(curPage + 1);
	alignedPtr = deAlignPtr(curPagePtr, alignBytes);
	alignPadding = (size_t)((deUintptr)alignedPtr - (deUintptr)curPagePtr);

	DE_ASSERT(numBytes + alignPadding <= (size_t)curPage->capacity);
	}

	curPage->bytesAllocated += (int)(numBytes + alignPadding);
	return alignedPtr;
	}
	}

	/--------------------------------------------------------------------//*!
	* \brief Allocate memory from a pool.
	* \param pool Memory pool to allocate from.
	* \param numBytes Number of bytes to allocate.
	* \return Pointer to the allocate memory (or null on failure).
	//--------------------------------------------------------------------*/
	void* deMemPool_alloc (deMemPool* pool, size_t numBytes)
	{
	void* ptr;
	DE_ASSERT(pool);
	DE_ASSERT(numBytes > 0);
	ptr = deMemPool_allocInternal(pool, numBytes, DE_POOL_DEFAULT_ALLOC_ALIGNMENT);
	if (!ptr && pool->util)
	pool->util->allocFailCallback(pool->util->userPointer);
	return ptr;
	}

	/--------------------------------------------------------------------//*!
	* \brief Allocate aligned memory from a pool.
	* \param pool Memory pool to allocate from.
	* \param numBytes Number of bytes to allocate.
	* \param alignBytes Required alignment in bytes, must be power of two.
	* \return Pointer to the allocate memory (or null on failure).
	//--------------------------------------------------------------------*/
	void* deMemPool_alignedAlloc (deMemPool* pool, size_t numBytes, deUint32 alignBytes)
	{
	void* ptr;
	DE_ASSERT(pool);
	DE_ASSERT(numBytes > 0);
	DE_ASSERT(deIsPowerOfTwo32((int)alignBytes));
	ptr = deMemPool_allocInternal(pool, numBytes, alignBytes);
	DE_ASSERT(deIsAlignedPtr(ptr, alignBytes));
	if (!ptr && pool->util)
	pool->util->allocFailCallback(pool->util->userPointer);
	return ptr;
	}

	/--------------------------------------------------------------------//*!
	* \brief Duplicate a piece of memory into a memory pool.
	* \param pool Memory pool to allocate from.
	* \param ptr Piece of memory to duplicate.
	* \return Pointer to the copied memory block (or null on failure).
	//--------------------------------------------------------------------*/
	void* deMemPool_memDup (deMemPool* pool, const void* ptr, size_t numBytes)
	{
	void* newPtr = deMemPool_alloc(pool, numBytes);
	if (newPtr)
	memcpy(newPtr, ptr, numBytes);
	return newPtr;
	}

	/--------------------------------------------------------------------//*!
	* \brief Duplicate a string into a memory pool.
	* \param pool Memory pool to allocate from.
	* \param str String to duplicate.
	* \return Pointer to the new string (or null on failure).
	//--------------------------------------------------------------------*/
	char* deMemPool_strDup (deMemPool* pool, const char* str)
	{
	size_t len = strlen(str);
	char* newStr = (char*)deMemPool_alloc(pool, len+1);
	if (newStr)
	memcpy(newStr, str, len+1);
	return newStr;
	}

	/--------------------------------------------------------------------//*!
	* \brief Duplicate a string into a memory pool, with a maximum length.
	* \param pool Memory pool to allocate from.
	* \param str String to duplicate.
	* \param maxLength Maximum number of characters to duplicate.
	* \return Pointer to the new string (or null on failure).
	//--------------------------------------------------------------------*/
	char* deMemPool_strnDup (deMemPool* pool, const char* str, int maxLength)
	{
	size_t len = (size_t)deMin32((int)strlen(str), deMax32(0, maxLength));
	char* newStr = (char*)deMemPool_alloc(pool, len + 1);

	DE_ASSERT(maxLength >= 0);

	if (newStr)
	{
	memcpy(newStr, str, len);
	newStr[len] = 0;
	}
	return newStr;
	}

	#if defined(DE_SUPPORT_POOL_MEMORY_TRACKING)

	int deMemPool_getMaxNumAllocatedBytes (const deMemPool* pool)
	{
	DE_ASSERT(pool && !pool->parent); /* must be root */
	return deMax32(pool->maxMemoryAllocated, deMemPool_getNumAllocatedBytes(pool, DE_TRUE));
	}

	int deMemPool_getMaxCapacity (const deMemPool* pool)
	{
	DE_ASSERT(pool && !pool->parent); /* must be root */
	return deMax32(pool->maxMemoryCapacity, deMemPool_getCapacity(pool, DE_TRUE));
	}

	#endif