kernel/mem_pool.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2016 Wind River Systems, Inc.
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 /**
  * @brief Memory pools.
  */

 #include <kernel.h>
 #include <kernel_structs.h>
 #include <debug/object_tracing_common.h>
 #include <ksched.h>
 #include <wait_q.h>
 #include <init.h>
 #include <stdlib.h>
 #include <string.h>

 #define _QUAD_BLOCK_AVAILABLE 0x0F
 #define _QUAD_BLOCK_ALLOCATED 0x0

 extern struct k_mem_pool _k_mem_pool_list_start[];
 extern struct k_mem_pool _k_mem_pool_list_end[];

 struct k_mem_pool *_trace_list_k_mem_pool;

 static void init_one_memory_pool(struct k_mem_pool *pool);

 /**
  *
  * @brief Initialize kernel memory pool subsystem
  *
  * Perform any initialization of memory pool that wasn't done at build time.
  *
  * @return N/A
  */
 static int init_static_pools(struct device *unused)
 {
 	ARG_UNUSED(unused);
 	struct k_mem_pool *pool;

 	/* perform initialization for each memory pool */

 	for (pool = _k_mem_pool_list_start;
 	     pool < _k_mem_pool_list_end;
 	     pool++) {
 		init_one_memory_pool(pool);
 	}
 	return 0;
 }

 SYS_INIT(init_static_pools, PRE_KERNEL_1, CONFIG_KERNEL_INIT_PRIORITY_OBJECTS);

 /**
  *
  * @brief Initialize the memory pool
  *
  * Initialize the internal memory accounting structures of the memory pool
  *
  * @param pool memory pool descriptor
  *
  * @return N/A
  */
 static void init_one_memory_pool(struct k_mem_pool *pool)
 {
 	/*
 	 * mark block set for largest block size
 	 * as owning all of the memory pool buffer space
 	 */

 	int remaining_blocks = pool->nr_of_maxblocks;
 	int j = 0;
 	char *memptr = pool->bufblock;

 	while (remaining_blocks >= 4) {
 		pool->block_set[0].quad_block[j].mem_blocks = memptr;
 		pool->block_set[0].quad_block[j].mem_status =
 			_QUAD_BLOCK_AVAILABLE;
 		j++;
 		remaining_blocks -= 4;
 		memptr +=
 			OCTET_TO_SIZEOFUNIT(pool->block_set[0].block_size)
 			* 4;
 	}

 	if (remaining_blocks != 0) {
 		pool->block_set[0].quad_block[j].mem_blocks = memptr;
 		pool->block_set[0].quad_block[j].mem_status =
 			_QUAD_BLOCK_AVAILABLE >> (4 - remaining_blocks);
 		/* non-existent blocks are marked as unavailable */
 	}

 	/*
 	 * note: all other block sets own no blocks, since their
 	 * first quad-block has a NULL memory pointer
 	 */
 	sys_dlist_init(&pool->wait_q);
 	SYS_TRACING_OBJ_INIT(k_mem_pool, pool);
 }

 /**
  *
  * @brief Determines which block set corresponds to the specified data size
  *
  * Finds the block set with the smallest blocks that can hold the specified
  * amount of data.
  *
  * @return block set index
  */
 static int compute_block_set_index(struct k_mem_pool *pool, size_t data_size)
 {
 	size_t block_size = pool->min_block_size;
 	int offset = pool->nr_of_block_sets - 1;

 	while (data_size > block_size) {
 		block_size *= 4;
 		offset--;
 	}

 	return offset;
 }


 /**
  *
  * @brief Return an allocated block to its block set
  *
  * @param ptr pointer to start of block
  * @param pool memory pool descriptor
  * @param index block set identifier
  *
  * @return N/A
  */
 static void free_existing_block(char *ptr, struct k_mem_pool *pool, int index)
 {
 	struct k_mem_pool_quad_block *quad_block =
 		pool->block_set[index].quad_block;
 	char *block_ptr;
 	uint32_t i, j;

 	/*
 	 * search block set's quad-blocks until the block is located,
 	 * then mark it as unused
 	 *
 	 * note: block *must* exist, so no need to do array bounds checking
 	 */

 	for (i = 0; ; i++) {
 		__ASSERT((i < pool->block_set[index].nr_of_entries) &&
 			 (quad_block[i].mem_blocks != NULL),
 			 "Attempt to free unallocated memory pool block\n");

 		block_ptr = quad_block[i].mem_blocks;
 		for (j = 0; j < 4; j++) {
 			if (ptr == block_ptr) {
 				quad_block[i].mem_status |= (1 << j);
 				return;
 			}
 			block_ptr += OCTET_TO_SIZEOFUNIT(
 				pool->block_set[index].block_size);
 		}
 	}
 }


 /**
  *
  * @brief Defragment the specified memory pool block sets
  *
  * Reassembles any quad-blocks that are entirely unused into larger blocks
  * (to the extent permitted).
  *
  * @param pool memory pool descriptor
  * @param start_block_set_index index of smallest block set to defragment
  * @param last_block_set_index index of largest block set to defragment
  *
  * @return N/A
  */
 static void defrag(struct k_mem_pool *pool,
 		   int start_block_set_index, int last_block_set_index)
 {
 	uint32_t i;
 	uint32_t k;
 	int j;
 	struct k_mem_pool_quad_block *quad_block;

 	/* process block sets from smallest to largest permitted sizes */

 	for (j = start_block_set_index; j > last_block_set_index; j--) {

 		quad_block = pool->block_set[j].quad_block;
 		i = 0;

 		do {
 			/* block set is done if no more quad-blocks exist */

 			if (quad_block[i].mem_blocks == NULL) {
 				break;
 			}

 			/* reassemble current quad-block, if possible */

 			if (quad_block[i].mem_status == _QUAD_BLOCK_AVAILABLE) {

 				/*
 				 * mark the corresponding block in next larger
 				 * block set as free
 				 */

 				free_existing_block(
 					quad_block[i].mem_blocks, pool, j - 1);

 				/*
 				 * delete the quad-block from this block set
 				 * by replacing it with the last quad-block
 				 *
 				 * (algorithm works even when the deleted
 				 * quad-block is the last quad_block)
 				 */

 				k = i;
 				while (((k+1) !=
 					pool->block_set[j].nr_of_entries) &&
 				       (quad_block[k + 1].mem_blocks != NULL)) {
 					k++;
 				}

 				quad_block[i].mem_blocks =
 					quad_block[k].mem_blocks;
 				quad_block[i].mem_status =
 					quad_block[k].mem_status;

 				quad_block[k].mem_blocks = NULL;

 				/* loop & process replacement quad_block[i] */
 			} else {
 				i++;
 			}

 			/* block set is done if at end of quad-block array */

 		} while (i < pool->block_set[j].nr_of_entries);
 	}
 }


 /**
  *
  * @brief Allocate block from an existing block set
  *
  * @param block_set pointer to block set
  * @param unused_block_index the index of first unused quad-block
  *                     when allocation fails, it is the number of quad
  *                     blocks in the block set
  *
  * @return pointer to allocated block, or NULL if none available
  */
 static char *get_existing_block(struct k_mem_pool_block_set *block_set,
 				int *unused_block_index)
 {
 	char *found = NULL;
 	uint32_t i = 0;
 	int status;
 	int free_bit;

 	do {
 		/* give up if no more quad-blocks exist */

 		if (block_set->quad_block[i].mem_blocks == NULL) {
 			break;
 		}

 		/* allocate a block from current quad-block, if possible */

 		status = block_set->quad_block[i].mem_status;
 		if (status != _QUAD_BLOCK_ALLOCATED) {
 			/* identify first free block */
 			free_bit = find_lsb_set(status) - 1;

 			/* compute address of free block */
 			found = block_set->quad_block[i].mem_blocks +
 				(OCTET_TO_SIZEOFUNIT(free_bit *
 					block_set->block_size));

 			/* mark block as unavailable (using XOR to invert) */
 			block_set->quad_block[i].mem_status ^=
 				1 << free_bit;
 #ifdef CONFIG_OBJECT_MONITOR
 			block_set->count++;
 #endif
 			break;
 		}

 		/* move on to next quad-block; give up if at end of array */

 	} while (++i < block_set->nr_of_entries);

 	*unused_block_index = i;
 	return found;
 }


 /**
  *
  * @brief Allocate a block, recursively fragmenting larger blocks if necessary
  *
  * @param pool memory pool descriptor
  * @param index index of block set currently being examined
  * @param start_index index of block set for which allocation is being done
  *
  * @return pointer to allocated block, or NULL if none available
  */
 static char *get_block_recursive(struct k_mem_pool *pool,
 				 int index, int start_index)
 {
 	int i;
 	char *found, *larger_block;
 	struct k_mem_pool_block_set *fr_table;

 	/* give up if we've exhausted the set of maximum size blocks */

 	if (index < 0) {
 		return NULL;
 	}

 	/* try allocating a block from the current block set */

 	fr_table = pool->block_set;
 	i = 0;

 	found = get_existing_block(&(fr_table[index]), &i);
 	if (found != NULL) {
 		return found;
 	}

 #ifdef CONFIG_MEM_POOL_DEFRAG_BEFORE_SPLIT
 	/*
 	 * do a partial defragmentation of memory pool & try allocating again
 	 * - do this on initial invocation only, not recursive ones
 	 *   (since there is no benefit in repeating the defrag)
 	 * - defrag only the blocks smaller than the desired size,
 	 *   and only until the size needed is reached
 	 *
 	 * note: defragging at this time tries to preserve the memory pool's
 	 * larger blocks by fragmenting them only when necessary
 	 * (i.e. at the cost of doing more frequent auto-defragmentations)
 	 */

 	if (index == start_index) {
 		defrag(pool, pool->nr_of_block_sets - 1, start_index);
 		found = get_existing_block(&(fr_table[index]), &i);
 		if (found != NULL) {
 			return found;
 		}
 	}
 #endif

 	/* try allocating a block from the next largest block set */

 	larger_block = get_block_recursive(pool, index - 1, start_index);
 	if (larger_block != NULL) {
 		/*
 		 * add a new quad-block to the current block set,
 		 * then mark one of its 4 blocks as used and return it
 		 *
 		 * note: "i" was earlier set to indicate the first unused
 		 * quad-block entry in the current block set
 		 */

 		fr_table[index].quad_block[i].mem_blocks = larger_block;
 		fr_table[index].quad_block[i].mem_status =
 			_QUAD_BLOCK_AVAILABLE & (~0x1);
 #ifdef CONFIG_OBJECT_MONITOR
 		fr_table[index].count++;
 #endif
 		return larger_block;
 	}

 #ifdef CONFIG_MEM_POOL_SPLIT_BEFORE_DEFRAG
 	/*
 	 * do a partial defragmentation of memory pool & try allocating again
 	 * - do this on initial invocation only, not recursive ones
 	 *   (since there is no benefit in repeating the defrag)
 	 * - defrag only the blocks smaller than the desired size,
 	 *   and only until the size needed is reached
 	 *
 	 * note: defragging at this time tries to limit the cost of doing
 	 * auto-defragmentations by doing them only when necessary
 	 * (i.e. at the cost of fragmenting the memory pool's larger blocks)
 	 */

 	if (index == start_index) {
 		defrag(pool, pool->nr_of_block_sets - 1, start_index);
 		found = get_existing_block(&(fr_table[index]), &i);
 		if (found != NULL) {
 			return found;
 		}
 	}
 #endif

 	return NULL; /* can't find (or create) desired block */
 }


 /**
  *
  * @brief Examine threads that are waiting for memory pool blocks.
  *
  * This routine attempts to satisfy any incomplete block allocation requests for
  * the specified memory pool. It can be invoked either by the explicit freeing
  * of a used block or as a result of defragmenting the pool (which may create
  * one or more new, larger blocks).
  *
  * @return N/A
  */
 static void block_waiters_check(struct k_mem_pool *pool)
 {
 	char *found_block;
 	struct k_thread *waiter;
 	struct k_thread *next_waiter;
 	int offset;

 	unsigned int key = irq_lock();
 	waiter = (struct k_thread *)sys_dlist_peek_head(&pool->wait_q);

 	/* loop all waiters */
 	while (waiter != NULL) {
 		uint32_t req_size = (uint32_t)(waiter->base.swap_data);

 		/* locate block set to try allocating from */
 		offset = compute_block_set_index(pool, req_size);

 		/* allocate block (fragmenting a larger block, if needed) */
 		found_block = get_block_recursive(pool, offset, offset);

 		next_waiter = (struct k_thread *)sys_dlist_peek_next(
 			&pool->wait_q, &waiter->base.k_q_node);

 		/* if success : remove task from list and reschedule */
 		if (found_block != NULL) {
 			/* return found block */
 			_set_thread_return_value_with_data(waiter, 0,
 							   found_block);


 			/*
 			 * Schedule the thread. Threads will be rescheduled
 			 * outside the function by k_sched_unlock()
 			 */
 			_unpend_thread(waiter);
 			_abort_thread_timeout(waiter);
 			_ready_thread(waiter);
 		}
 		waiter = next_waiter;
 	}
 	irq_unlock(key);
 }

 void k_mem_pool_defrag(struct k_mem_pool *pool)
 {
 	_sched_lock();

 	/* do complete defragmentation of memory pool (i.e. all block sets) */
 	defrag(pool, pool->nr_of_block_sets - 1, 0);

 	/* reschedule anybody waiting for a block */
 	block_waiters_check(pool);
 	k_sched_unlock();
 }

 int k_mem_pool_alloc(struct k_mem_pool *pool, struct k_mem_block *block,
 		     size_t size, int32_t timeout)
 {
 	char *found_block;
 	int offset;

 	_sched_lock();
 	/* locate block set to try allocating from */
 	offset = compute_block_set_index(pool, size);

 	/* allocate block (fragmenting a larger block, if needed) */
 	found_block = get_block_recursive(pool, offset, offset);


 	if (found_block != NULL) {
 		k_sched_unlock();
 		block->pool_id = pool;
 		block->addr_in_pool = found_block;
 		block->data = found_block;
 		block->req_size = size;
 		return 0;
 	}

 	/*
 	 * no suitable block is currently available,
 	 * so either wait for one to appear or indicate failure
 	 */
 	if (likely(timeout != K_NO_WAIT)) {
 		int result;
 		unsigned int key = irq_lock();
 		_sched_unlock_no_reschedule();

 		_current->base.swap_data = (void *)size;
 		_pend_current_thread(&pool->wait_q, timeout);
 		result = _Swap(key);
 		if (result == 0) {
 			block->pool_id = pool;
 			block->addr_in_pool = _current->base.swap_data;
 			block->data = _current->base.swap_data;
 			block->req_size = size;
 		}
 		return result;
 	}
 	k_sched_unlock();
 	return -ENOMEM;
 }

 void k_mem_pool_free(struct k_mem_block *block)
 {
 	int offset;
 	struct k_mem_pool *pool = block->pool_id;

 	_sched_lock();
 	/* determine block set that block belongs to */
 	offset = compute_block_set_index(pool, block->req_size);

 	/* mark the block as unused */
 	free_existing_block(block->addr_in_pool, pool, offset);

 	/* reschedule anybody waiting for a block */
 	block_waiters_check(pool);
 	k_sched_unlock();
 }


 /*
  * Heap memory pool support
  */

 #if (CONFIG_HEAP_MEM_POOL_SIZE > 0)

 /*
  * Case 1: Heap is defined using HEAP_MEM_POOL_SIZE configuration option.
  *
  * This module defines the heap memory pool and the _HEAP_MEM_POOL symbol
  * that has the address of the associated memory pool struct.
  */

 K_MEM_POOL_DEFINE(_heap_mem_pool, 64, CONFIG_HEAP_MEM_POOL_SIZE, 1, 4);
 #define _HEAP_MEM_POOL (&_heap_mem_pool)

 #else

 /*
  * Case 2: Heap is defined using HEAP_SIZE item type in MDEF.
  *
  * Sysgen defines the heap memory pool and the _heap_mem_pool_ptr variable
  * that has the address of the associated memory pool struct. This module
  * defines the _HEAP_MEM_POOL symbol as an alias for _heap_mem_pool_ptr.
  *
  * Note: If the MDEF does not define the heap memory pool k_malloc() will
  * compile successfully, but will trigger a link error if it is used.
  */

 extern struct k_mem_pool * const _heap_mem_pool_ptr;
 #define _HEAP_MEM_POOL _heap_mem_pool_ptr

 #endif /* CONFIG_HEAP_MEM_POOL_SIZE */


 void *k_malloc(size_t size)
 {
 	struct k_mem_block block;

 	/*
 	 * get a block large enough to hold an initial (hidden) block
 	 * descriptor, as well as the space the caller requested
 	 */
 	size += sizeof(struct k_mem_block);
 	if (k_mem_pool_alloc(_HEAP_MEM_POOL, &block, size, K_NO_WAIT) != 0) {
 		return NULL;
 	}

 	/* save the block descriptor info at the start of the actual block */
 	memcpy(block.data, &block, sizeof(struct k_mem_block));

 	/* return address of the user area part of the block to the caller */
 	return (char *)block.data + sizeof(struct k_mem_block);
 }


 void k_free(void *ptr)
 {
 	if (ptr != NULL) {
 		/* point to hidden block descriptor at start of block */
 		ptr = (char *)ptr - sizeof(struct k_mem_block);

 		/* return block to the heap memory pool */
 		k_mem_pool_free(ptr);
 	}
 }
	/*
	* Copyright (c) 2016 Wind River Systems, Inc.
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	/**
	* @brief Memory pools.
	*/

	#include <kernel.h>
	#include <kernel_structs.h>
	#include <debug/object_tracing_common.h>
	#include <ksched.h>
	#include <wait_q.h>
	#include <init.h>
	#include <stdlib.h>
	#include <string.h>

	#define _QUAD_BLOCK_AVAILABLE 0x0F
	#define _QUAD_BLOCK_ALLOCATED 0x0

	extern struct k_mem_pool _k_mem_pool_list_start[];
	extern struct k_mem_pool _k_mem_pool_list_end[];

	struct k_mem_pool *_trace_list_k_mem_pool;

	static void init_one_memory_pool(struct k_mem_pool *pool);

	/**
	*
	* @brief Initialize kernel memory pool subsystem
	*
	* Perform any initialization of memory pool that wasn't done at build time.
	*
	* @return N/A
	*/
	static int init_static_pools(struct device *unused)
	{
	ARG_UNUSED(unused);
	struct k_mem_pool *pool;

	/* perform initialization for each memory pool */

	for (pool = _k_mem_pool_list_start;
	pool < _k_mem_pool_list_end;
	pool++) {
	init_one_memory_pool(pool);
	}
	return 0;
	}

	SYS_INIT(init_static_pools, PRE_KERNEL_1, CONFIG_KERNEL_INIT_PRIORITY_OBJECTS);

	/**
	*
	* @brief Initialize the memory pool
	*
	* Initialize the internal memory accounting structures of the memory pool
	*
	* @param pool memory pool descriptor
	*
	* @return N/A
	*/
	static void init_one_memory_pool(struct k_mem_pool *pool)
	{
	/*
	* mark block set for largest block size
	* as owning all of the memory pool buffer space
	*/

	int remaining_blocks = pool->nr_of_maxblocks;
	int j = 0;
	char *memptr = pool->bufblock;

	while (remaining_blocks >= 4) {
	pool->block_set[0].quad_block[j].mem_blocks = memptr;
	pool->block_set[0].quad_block[j].mem_status =
	_QUAD_BLOCK_AVAILABLE;
	j++;
	remaining_blocks -= 4;
	memptr +=
	OCTET_TO_SIZEOFUNIT(pool->block_set[0].block_size)
	* 4;
	}

	if (remaining_blocks != 0) {
	pool->block_set[0].quad_block[j].mem_blocks = memptr;
	pool->block_set[0].quad_block[j].mem_status =
	_QUAD_BLOCK_AVAILABLE >> (4 - remaining_blocks);
	/* non-existent blocks are marked as unavailable */
	}

	/*
	* note: all other block sets own no blocks, since their
	* first quad-block has a NULL memory pointer
	*/
	sys_dlist_init(&pool->wait_q);
	SYS_TRACING_OBJ_INIT(k_mem_pool, pool);
	}

	/**
	*
	* @brief Determines which block set corresponds to the specified data size
	*
	* Finds the block set with the smallest blocks that can hold the specified
	* amount of data.
	*
	* @return block set index
	*/
	static int compute_block_set_index(struct k_mem_pool *pool, size_t data_size)
	{
	size_t block_size = pool->min_block_size;
	int offset = pool->nr_of_block_sets - 1;

	while (data_size > block_size) {
	block_size *= 4;
	offset--;
	}

	return offset;
	}


	/**
	*
	* @brief Return an allocated block to its block set
	*
	* @param ptr pointer to start of block
	* @param pool memory pool descriptor
	* @param index block set identifier
	*
	* @return N/A
	*/
	static void free_existing_block(char ptr, struct k_mem_pool pool, int index)
	{
	struct k_mem_pool_quad_block *quad_block =
	pool->block_set[index].quad_block;
	char *block_ptr;
	uint32_t i, j;

	/*
	* search block set's quad-blocks until the block is located,
	* then mark it as unused
	*
	* note: block must exist, so no need to do array bounds checking
	*/

	for (i = 0; ; i++) {
	__ASSERT((i < pool->block_set[index].nr_of_entries) &&
	(quad_block[i].mem_blocks != NULL),
	"Attempt to free unallocated memory pool block\n");

	block_ptr = quad_block[i].mem_blocks;
	for (j = 0; j < 4; j++) {
	if (ptr == block_ptr) {
	quad_block[i].mem_status \|= (1 << j);
	return;
	}
	block_ptr += OCTET_TO_SIZEOFUNIT(
	pool->block_set[index].block_size);
	}
	}
	}


	/**
	*
	* @brief Defragment the specified memory pool block sets
	*
	* Reassembles any quad-blocks that are entirely unused into larger blocks
	* (to the extent permitted).
	*
	* @param pool memory pool descriptor
	* @param start_block_set_index index of smallest block set to defragment
	* @param last_block_set_index index of largest block set to defragment
	*
	* @return N/A
	*/
	static void defrag(struct k_mem_pool *pool,
	int start_block_set_index, int last_block_set_index)
	{
	uint32_t i;
	uint32_t k;
	int j;
	struct k_mem_pool_quad_block *quad_block;

	/* process block sets from smallest to largest permitted sizes */

	for (j = start_block_set_index; j > last_block_set_index; j--) {

	quad_block = pool->block_set[j].quad_block;
	i = 0;

	do {
	/* block set is done if no more quad-blocks exist */

	if (quad_block[i].mem_blocks == NULL) {
	break;
	}

	/* reassemble current quad-block, if possible */

	if (quad_block[i].mem_status == _QUAD_BLOCK_AVAILABLE) {

	/*
	* mark the corresponding block in next larger
	* block set as free
	*/

	free_existing_block(
	quad_block[i].mem_blocks, pool, j - 1);

	/*
	* delete the quad-block from this block set
	* by replacing it with the last quad-block
	*
	* (algorithm works even when the deleted
	* quad-block is the last quad_block)
	*/

	k = i;
	while (((k+1) !=
	pool->block_set[j].nr_of_entries) &&
	(quad_block[k + 1].mem_blocks != NULL)) {
	k++;
	}

	quad_block[i].mem_blocks =
	quad_block[k].mem_blocks;
	quad_block[i].mem_status =
	quad_block[k].mem_status;

	quad_block[k].mem_blocks = NULL;

	/* loop & process replacement quad_block[i] */
	} else {
	i++;
	}

	/* block set is done if at end of quad-block array */

	} while (i < pool->block_set[j].nr_of_entries);
	}
	}


	/**
	*
	* @brief Allocate block from an existing block set
	*
	* @param block_set pointer to block set
	* @param unused_block_index the index of first unused quad-block
	* when allocation fails, it is the number of quad
	* blocks in the block set
	*
	* @return pointer to allocated block, or NULL if none available
	*/
	static char get_existing_block(struct k_mem_pool_block_set block_set,
	int *unused_block_index)
	{
	char *found = NULL;
	uint32_t i = 0;
	int status;
	int free_bit;

	do {
	/* give up if no more quad-blocks exist */

	if (block_set->quad_block[i].mem_blocks == NULL) {
	break;
	}

	/* allocate a block from current quad-block, if possible */

	status = block_set->quad_block[i].mem_status;
	if (status != _QUAD_BLOCK_ALLOCATED) {
	/* identify first free block */
	free_bit = find_lsb_set(status) - 1;

	/* compute address of free block */
	found = block_set->quad_block[i].mem_blocks +
	(OCTET_TO_SIZEOFUNIT(free_bit *
	block_set->block_size));

	/* mark block as unavailable (using XOR to invert) */
	block_set->quad_block[i].mem_status ^=
	1 << free_bit;
	#ifdef CONFIG_OBJECT_MONITOR
	block_set->count++;
	#endif
	break;
	}

	/* move on to next quad-block; give up if at end of array */

	} while (++i < block_set->nr_of_entries);

	*unused_block_index = i;
	return found;
	}


	/**
	*
	* @brief Allocate a block, recursively fragmenting larger blocks if necessary
	*
	* @param pool memory pool descriptor
	* @param index index of block set currently being examined
	* @param start_index index of block set for which allocation is being done
	*
	* @return pointer to allocated block, or NULL if none available
	*/
	static char get_block_recursive(struct k_mem_pool pool,
	int index, int start_index)
	{
	int i;
	char found, larger_block;
	struct k_mem_pool_block_set *fr_table;

	/* give up if we've exhausted the set of maximum size blocks */

	if (index < 0) {
	return NULL;
	}

	/* try allocating a block from the current block set */

	fr_table = pool->block_set;
	i = 0;

	found = get_existing_block(&(fr_table[index]), &i);
	if (found != NULL) {
	return found;
	}

	#ifdef CONFIG_MEM_POOL_DEFRAG_BEFORE_SPLIT
	/*
	* do a partial defragmentation of memory pool & try allocating again
	* - do this on initial invocation only, not recursive ones
	* (since there is no benefit in repeating the defrag)
	* - defrag only the blocks smaller than the desired size,
	* and only until the size needed is reached
	*
	* note: defragging at this time tries to preserve the memory pool's
	* larger blocks by fragmenting them only when necessary
	* (i.e. at the cost of doing more frequent auto-defragmentations)
	*/

	if (index == start_index) {
	defrag(pool, pool->nr_of_block_sets - 1, start_index);
	found = get_existing_block(&(fr_table[index]), &i);
	if (found != NULL) {
	return found;
	}
	}
	#endif

	/* try allocating a block from the next largest block set */

	larger_block = get_block_recursive(pool, index - 1, start_index);
	if (larger_block != NULL) {
	/*
	* add a new quad-block to the current block set,
	* then mark one of its 4 blocks as used and return it
	*
	* note: "i" was earlier set to indicate the first unused
	* quad-block entry in the current block set
	*/

	fr_table[index].quad_block[i].mem_blocks = larger_block;
	fr_table[index].quad_block[i].mem_status =
	_QUAD_BLOCK_AVAILABLE & (~0x1);
	#ifdef CONFIG_OBJECT_MONITOR
	fr_table[index].count++;
	#endif
	return larger_block;
	}

	#ifdef CONFIG_MEM_POOL_SPLIT_BEFORE_DEFRAG
	/*
	* do a partial defragmentation of memory pool & try allocating again
	* - do this on initial invocation only, not recursive ones
	* (since there is no benefit in repeating the defrag)
	* - defrag only the blocks smaller than the desired size,
	* and only until the size needed is reached
	*
	* note: defragging at this time tries to limit the cost of doing
	* auto-defragmentations by doing them only when necessary
	* (i.e. at the cost of fragmenting the memory pool's larger blocks)
	*/

	if (index == start_index) {
	defrag(pool, pool->nr_of_block_sets - 1, start_index);
	found = get_existing_block(&(fr_table[index]), &i);
	if (found != NULL) {
	return found;
	}
	}
	#endif

	return NULL; /* can't find (or create) desired block */
	}


	/**
	*
	* @brief Examine threads that are waiting for memory pool blocks.
	*
	* This routine attempts to satisfy any incomplete block allocation requests for
	* the specified memory pool. It can be invoked either by the explicit freeing
	* of a used block or as a result of defragmenting the pool (which may create
	* one or more new, larger blocks).
	*
	* @return N/A
	*/
	static void block_waiters_check(struct k_mem_pool *pool)
	{
	char *found_block;
	struct k_thread *waiter;
	struct k_thread *next_waiter;
	int offset;

	unsigned int key = irq_lock();
	waiter = (struct k_thread *)sys_dlist_peek_head(&pool->wait_q);

	/* loop all waiters */
	while (waiter != NULL) {
	uint32_t req_size = (uint32_t)(waiter->base.swap_data);

	/* locate block set to try allocating from */
	offset = compute_block_set_index(pool, req_size);

	/* allocate block (fragmenting a larger block, if needed) */
	found_block = get_block_recursive(pool, offset, offset);

	next_waiter = (struct k_thread *)sys_dlist_peek_next(
	&pool->wait_q, &waiter->base.k_q_node);

	/* if success : remove task from list and reschedule */
	if (found_block != NULL) {
	/* return found block */
	_set_thread_return_value_with_data(waiter, 0,
	found_block);


	/*
	* Schedule the thread. Threads will be rescheduled
	* outside the function by k_sched_unlock()
	*/
	_unpend_thread(waiter);
	_abort_thread_timeout(waiter);
	_ready_thread(waiter);
	}
	waiter = next_waiter;
	}
	irq_unlock(key);
	}

	void k_mem_pool_defrag(struct k_mem_pool *pool)
	{
	_sched_lock();

	/* do complete defragmentation of memory pool (i.e. all block sets) */
	defrag(pool, pool->nr_of_block_sets - 1, 0);

	/* reschedule anybody waiting for a block */
	block_waiters_check(pool);
	k_sched_unlock();
	}

	int k_mem_pool_alloc(struct k_mem_pool pool, struct k_mem_block block,
	size_t size, int32_t timeout)
	{
	char *found_block;
	int offset;

	_sched_lock();
	/* locate block set to try allocating from */
	offset = compute_block_set_index(pool, size);

	/* allocate block (fragmenting a larger block, if needed) */
	found_block = get_block_recursive(pool, offset, offset);


	if (found_block != NULL) {
	k_sched_unlock();
	block->pool_id = pool;
	block->addr_in_pool = found_block;
	block->data = found_block;
	block->req_size = size;
	return 0;
	}

	/*
	* no suitable block is currently available,
	* so either wait for one to appear or indicate failure
	*/
	if (likely(timeout != K_NO_WAIT)) {
	int result;
	unsigned int key = irq_lock();
	_sched_unlock_no_reschedule();

	_current->base.swap_data = (void *)size;
	_pend_current_thread(&pool->wait_q, timeout);
	result = _Swap(key);
	if (result == 0) {
	block->pool_id = pool;
	block->addr_in_pool = _current->base.swap_data;
	block->data = _current->base.swap_data;
	block->req_size = size;
	}
	return result;
	}
	k_sched_unlock();
	return -ENOMEM;
	}

	void k_mem_pool_free(struct k_mem_block *block)
	{
	int offset;
	struct k_mem_pool *pool = block->pool_id;

	_sched_lock();
	/* determine block set that block belongs to */
	offset = compute_block_set_index(pool, block->req_size);

	/* mark the block as unused */
	free_existing_block(block->addr_in_pool, pool, offset);

	/* reschedule anybody waiting for a block */
	block_waiters_check(pool);
	k_sched_unlock();
	}


	/*
	* Heap memory pool support
	*/

	#if (CONFIG_HEAP_MEM_POOL_SIZE > 0)

	/*
	* Case 1: Heap is defined using HEAP_MEM_POOL_SIZE configuration option.
	*
	* This module defines the heap memory pool and the _HEAP_MEM_POOL symbol
	* that has the address of the associated memory pool struct.
	*/

	K_MEM_POOL_DEFINE(_heap_mem_pool, 64, CONFIG_HEAP_MEM_POOL_SIZE, 1, 4);
	#define _HEAP_MEM_POOL (&_heap_mem_pool)

	#else

	/*
	* Case 2: Heap is defined using HEAP_SIZE item type in MDEF.
	*
	* Sysgen defines the heap memory pool and the _heap_mem_pool_ptr variable
	* that has the address of the associated memory pool struct. This module
	* defines the _HEAP_MEM_POOL symbol as an alias for _heap_mem_pool_ptr.
	*
	* Note: If the MDEF does not define the heap memory pool k_malloc() will
	* compile successfully, but will trigger a link error if it is used.
	*/

	extern struct k_mem_pool * const _heap_mem_pool_ptr;
	#define _HEAP_MEM_POOL _heap_mem_pool_ptr

	#endif /* CONFIG_HEAP_MEM_POOL_SIZE */


	void *k_malloc(size_t size)
	{
	struct k_mem_block block;

	/*
	* get a block large enough to hold an initial (hidden) block
	* descriptor, as well as the space the caller requested
	*/
	size += sizeof(struct k_mem_block);
	if (k_mem_pool_alloc(_HEAP_MEM_POOL, &block, size, K_NO_WAIT) != 0) {
	return NULL;
	}

	/* save the block descriptor info at the start of the actual block */
	memcpy(block.data, &block, sizeof(struct k_mem_block));

	/* return address of the user area part of the block to the caller */
	return (char *)block.data + sizeof(struct k_mem_block);
	}


	void k_free(void *ptr)
	{
	if (ptr != NULL) {
	/* point to hidden block descriptor at start of block */
	ptr = (char *)ptr - sizeof(struct k_mem_block);

	/* return block to the heap memory pool */
	k_mem_pool_free(ptr);
	}
	}