lib/os/heap.h - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2019 Intel Corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */
 #ifndef ZEPHYR_INCLUDE_LIB_OS_HEAP_H_
 #define ZEPHYR_INCLUDE_LIB_OS_HEAP_H_

 /*
  * Internal heap APIs
  */

 /* Theese validation checks are non-trivially expensive, so enable
  * only when debugging the heap code.  They shouldn't be routine
  * assertions.
  */
 #ifdef CONFIG_SYS_HEAP_VALIDATE
 #define CHECK(x) __ASSERT(x, "")
 #else
 #define CHECK(x) /**/
 #endif

 /* Chunks are identified by their offset in 8 byte units from the
  * first address in the buffer (a zero-valued chunkid_t is used as a
  * null; that chunk would always point into the metadata at the start
  * of the heap and cannot be allocated).  They are prefixed by a
  * variable size header that depends on the size of the heap.  Heaps
  * with fewer than 2^15 units (256kb) of storage use shorts to store
  * the fields, otherwise the units are 32 bit integers for a 16Gb heap
  * space (larger spaces really aren't in scope for this code, but
  * could be handled similarly I suppose).  Because of that design
  * there's a certain amount of boilerplate API needed to expose the
  * field accessors since we can't use natural syntax.
  *
  * The fields are:
  *   LEFT_SIZE: The size of the left (next lower chunk in memory)
  *              neighbor chunk.
  *   SIZE_AND_USED: the total size (including header) of the chunk in
  *                  8-byte units.  The bottom bit stores a "used" flag.
  *   FREE_PREV: Chunk ID of the previous node in a free list.
  *   FREE_NEXT: Chunk ID of the next node in a free list.
  *
  * The free lists are circular lists, one for each power-of-two size
  * category.  The free list pointers exist only for free chunks,
  * obviously.  This memory is part of the user's buffer when
  * allocated.
  *
  * The field order is so that allocated buffers are immediately bounded
  * by SIZE_AND_USED of the current chunk at the bottom, and LEFT_SIZE of
  * the following chunk at the top. This ordering allows for quick buffer
  * overflow detection by testing left_chunk(c + chunk_size(c)) == c.
  */

 enum chunk_fields { LEFT_SIZE, SIZE_AND_USED, FREE_PREV, FREE_NEXT };

 #define CHUNK_UNIT 8U

 typedef struct { char bytes[CHUNK_UNIT]; } chunk_unit_t;

 /* big_heap needs uint32_t, small_heap needs uint16_t */
 typedef uint32_t chunkid_t;
 typedef uint32_t chunksz_t;

 struct z_heap_bucket {
 	chunkid_t next;
 };

 struct z_heap {
 	chunkid_t chunk0_hdr[2];
 	chunkid_t end_chunk;
 	uint32_t avail_buckets;
 #ifdef CONFIG_SYS_HEAP_RUNTIME_STATS
 	size_t free_bytes;
 	size_t allocated_bytes;
 	size_t max_allocated_bytes;
 #endif
 	struct z_heap_bucket buckets[0];
 };

 static inline bool big_heap_chunks(chunksz_t chunks)
 {
 	if (IS_ENABLED(CONFIG_SYS_HEAP_SMALL_ONLY)) {
 		return false;
 	}
 	if (IS_ENABLED(CONFIG_SYS_HEAP_BIG_ONLY) || sizeof(void *) > 4U) {
 		return true;
 	}
 	return chunks > 0x7fffU;
 }

 static inline bool big_heap_bytes(size_t bytes)
 {
 	return big_heap_chunks(bytes / CHUNK_UNIT);
 }

 static inline bool big_heap(struct z_heap *h)
 {
 	return big_heap_chunks(h->end_chunk);
 }

 static inline chunk_unit_t *chunk_buf(struct z_heap *h)
 {
 	/* the struct z_heap matches with the first chunk */
 	return (chunk_unit_t *)h;
 }

 static inline chunkid_t chunk_field(struct z_heap *h, chunkid_t c,
 				    enum chunk_fields f)
 {
 	chunk_unit_t *buf = chunk_buf(h);
 	void *cmem = &buf[c];

 	if (big_heap(h)) {
 		return ((uint32_t *)cmem)[f];
 	} else {
 		return ((uint16_t *)cmem)[f];
 	}
 }

 static inline void chunk_set(struct z_heap *h, chunkid_t c,
 			     enum chunk_fields f, chunkid_t val)
 {
 	CHECK(c <= h->end_chunk);

 	chunk_unit_t *buf = chunk_buf(h);
 	void *cmem = &buf[c];

 	if (big_heap(h)) {
 		CHECK(val == (uint32_t)val);
 		((uint32_t *)cmem)[f] = val;
 	} else {
 		CHECK(val == (uint16_t)val);
 		((uint16_t *)cmem)[f] = val;
 	}
 }

 static inline bool chunk_used(struct z_heap *h, chunkid_t c)
 {
 	return chunk_field(h, c, SIZE_AND_USED) & 1U;
 }

 static inline chunksz_t chunk_size(struct z_heap *h, chunkid_t c)
 {
 	return chunk_field(h, c, SIZE_AND_USED) >> 1;
 }

 static inline void set_chunk_used(struct z_heap *h, chunkid_t c, bool used)
 {
 	chunk_unit_t *buf = chunk_buf(h);
 	void *cmem = &buf[c];

 	if (big_heap(h)) {
 		if (used) {
 			((uint32_t *)cmem)[SIZE_AND_USED] |= 1U;
 		} else {
 			((uint32_t *)cmem)[SIZE_AND_USED] &= ~1U;
 		}
 	} else {
 		if (used) {
 			((uint16_t *)cmem)[SIZE_AND_USED] |= 1U;
 		} else {
 			((uint16_t *)cmem)[SIZE_AND_USED] &= ~1U;
 		}
 	}
 }

 /*
  * Note: no need to preserve the used bit here as the chunk is never in use
  * when its size is modified, and potential set_chunk_used() is always
  * invoked after set_chunk_size().
  */
 static inline void set_chunk_size(struct z_heap *h, chunkid_t c, chunksz_t size)
 {
 	chunk_set(h, c, SIZE_AND_USED, size << 1);
 }

 static inline chunkid_t prev_free_chunk(struct z_heap *h, chunkid_t c)
 {
 	return chunk_field(h, c, FREE_PREV);
 }

 static inline chunkid_t next_free_chunk(struct z_heap *h, chunkid_t c)
 {
 	return chunk_field(h, c, FREE_NEXT);
 }

 static inline void set_prev_free_chunk(struct z_heap *h, chunkid_t c,
 				       chunkid_t prev)
 {
 	chunk_set(h, c, FREE_PREV, prev);
 }

 static inline void set_next_free_chunk(struct z_heap *h, chunkid_t c,
 				       chunkid_t next)
 {
 	chunk_set(h, c, FREE_NEXT, next);
 }

 static inline chunkid_t left_chunk(struct z_heap *h, chunkid_t c)
 {
 	return c - chunk_field(h, c, LEFT_SIZE);
 }

 static inline chunkid_t right_chunk(struct z_heap *h, chunkid_t c)
 {
 	return c + chunk_size(h, c);
 }

 static inline void set_left_chunk_size(struct z_heap *h, chunkid_t c,
 				       chunksz_t size)
 {
 	chunk_set(h, c, LEFT_SIZE, size);
 }

 static inline bool solo_free_header(struct z_heap *h, chunkid_t c)
 {
 	return big_heap(h) && chunk_size(h, c) == 1U;
 }

 static inline size_t chunk_header_bytes(struct z_heap *h)
 {
 	return big_heap(h) ? 8 : 4;
 }

 static inline size_t heap_footer_bytes(size_t size)
 {
 	return big_heap_bytes(size) ? 8 : 4;
 }

 static inline chunksz_t chunksz(size_t bytes)
 {
 	return (bytes + CHUNK_UNIT - 1U) / CHUNK_UNIT;
 }

 static inline chunksz_t bytes_to_chunksz(struct z_heap *h, size_t bytes)
 {
 	return chunksz(chunk_header_bytes(h) + bytes);
 }

 static inline chunksz_t min_chunk_size(struct z_heap *h)
 {
 	return bytes_to_chunksz(h, 1);
 }

 static inline size_t chunksz_to_bytes(struct z_heap *h, chunksz_t chunksz_in)
 {
 	return chunksz_in * CHUNK_UNIT - chunk_header_bytes(h);
 }

 static inline int bucket_idx(struct z_heap *h, chunksz_t sz)
 {
 	unsigned int usable_sz = sz - min_chunk_size(h) + 1;
 	return 31 - __builtin_clz(usable_sz);
 }

 static inline bool size_too_big(struct z_heap *h, size_t bytes)
 {
 	/*
 	 * Quick check to bail out early if size is too big.
 	 * Also guards against potential arithmetic overflows elsewhere.
 	 */
 	return (bytes / CHUNK_UNIT) >= h->end_chunk;
 }

 /* For debugging */
 void heap_print_info(struct z_heap *h, bool dump_chunks);

 #endif /* ZEPHYR_INCLUDE_LIB_OS_HEAP_H_ */
	/*
	* Copyright (c) 2019 Intel Corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/
	#ifndef ZEPHYR_INCLUDE_LIB_OS_HEAP_H_
	#define ZEPHYR_INCLUDE_LIB_OS_HEAP_H_

	/*
	* Internal heap APIs
	*/

	/* Theese validation checks are non-trivially expensive, so enable
	* only when debugging the heap code. They shouldn't be routine
	* assertions.
	*/
	#ifdef CONFIG_SYS_HEAP_VALIDATE
	#define CHECK(x) __ASSERT(x, "")
	#else
	#define CHECK(x) /**/
	#endif

	/* Chunks are identified by their offset in 8 byte units from the
	* first address in the buffer (a zero-valued chunkid_t is used as a
	* null; that chunk would always point into the metadata at the start
	* of the heap and cannot be allocated). They are prefixed by a
	* variable size header that depends on the size of the heap. Heaps
	* with fewer than 2^15 units (256kb) of storage use shorts to store
	* the fields, otherwise the units are 32 bit integers for a 16Gb heap
	* space (larger spaces really aren't in scope for this code, but
	* could be handled similarly I suppose). Because of that design
	* there's a certain amount of boilerplate API needed to expose the
	* field accessors since we can't use natural syntax.
	*
	* The fields are:
	* LEFT_SIZE: The size of the left (next lower chunk in memory)
	* neighbor chunk.
	* SIZE_AND_USED: the total size (including header) of the chunk in
	* 8-byte units. The bottom bit stores a "used" flag.
	* FREE_PREV: Chunk ID of the previous node in a free list.
	* FREE_NEXT: Chunk ID of the next node in a free list.
	*
	* The free lists are circular lists, one for each power-of-two size
	* category. The free list pointers exist only for free chunks,
	* obviously. This memory is part of the user's buffer when
	* allocated.
	*
	* The field order is so that allocated buffers are immediately bounded
	* by SIZE_AND_USED of the current chunk at the bottom, and LEFT_SIZE of
	* the following chunk at the top. This ordering allows for quick buffer
	* overflow detection by testing left_chunk(c + chunk_size(c)) == c.
	*/

	enum chunk_fields { LEFT_SIZE, SIZE_AND_USED, FREE_PREV, FREE_NEXT };

	#define CHUNK_UNIT 8U

	typedef struct { char bytes[CHUNK_UNIT]; } chunk_unit_t;

	/* big_heap needs uint32_t, small_heap needs uint16_t */
	typedef uint32_t chunkid_t;
	typedef uint32_t chunksz_t;

	struct z_heap_bucket {
	chunkid_t next;
	};

	struct z_heap {
	chunkid_t chunk0_hdr[2];
	chunkid_t end_chunk;
	uint32_t avail_buckets;
	#ifdef CONFIG_SYS_HEAP_RUNTIME_STATS
	size_t free_bytes;
	size_t allocated_bytes;
	size_t max_allocated_bytes;
	#endif
	struct z_heap_bucket buckets[0];
	};

	static inline bool big_heap_chunks(chunksz_t chunks)
	{
	if (IS_ENABLED(CONFIG_SYS_HEAP_SMALL_ONLY)) {
	return false;
	}
	if (IS_ENABLED(CONFIG_SYS_HEAP_BIG_ONLY) \|\| sizeof(void *) > 4U) {
	return true;
	}
	return chunks > 0x7fffU;
	}

	static inline bool big_heap_bytes(size_t bytes)
	{
	return big_heap_chunks(bytes / CHUNK_UNIT);
	}

	static inline bool big_heap(struct z_heap *h)
	{
	return big_heap_chunks(h->end_chunk);
	}

	static inline chunk_unit_t chunk_buf(struct z_heap h)
	{
	/* the struct z_heap matches with the first chunk */
	return (chunk_unit_t *)h;
	}

	static inline chunkid_t chunk_field(struct z_heap *h, chunkid_t c,
	enum chunk_fields f)
	{
	chunk_unit_t *buf = chunk_buf(h);
	void *cmem = &buf[c];

	if (big_heap(h)) {
	return ((uint32_t *)cmem)[f];
	} else {
	return ((uint16_t *)cmem)[f];
	}
	}

	static inline void chunk_set(struct z_heap *h, chunkid_t c,
	enum chunk_fields f, chunkid_t val)
	{
	CHECK(c <= h->end_chunk);

	chunk_unit_t *buf = chunk_buf(h);
	void *cmem = &buf[c];

	if (big_heap(h)) {
	CHECK(val == (uint32_t)val);
	((uint32_t *)cmem)[f] = val;
	} else {
	CHECK(val == (uint16_t)val);
	((uint16_t *)cmem)[f] = val;
	}
	}

	static inline bool chunk_used(struct z_heap *h, chunkid_t c)
	{
	return chunk_field(h, c, SIZE_AND_USED) & 1U;
	}

	static inline chunksz_t chunk_size(struct z_heap *h, chunkid_t c)
	{
	return chunk_field(h, c, SIZE_AND_USED) >> 1;
	}

	static inline void set_chunk_used(struct z_heap *h, chunkid_t c, bool used)
	{
	chunk_unit_t *buf = chunk_buf(h);
	void *cmem = &buf[c];

	if (big_heap(h)) {
	if (used) {
	((uint32_t *)cmem)[SIZE_AND_USED] \|= 1U;
	} else {
	((uint32_t *)cmem)[SIZE_AND_USED] &= ~1U;
	}
	} else {
	if (used) {
	((uint16_t *)cmem)[SIZE_AND_USED] \|= 1U;
	} else {
	((uint16_t *)cmem)[SIZE_AND_USED] &= ~1U;
	}
	}
	}

	/*
	* Note: no need to preserve the used bit here as the chunk is never in use
	* when its size is modified, and potential set_chunk_used() is always
	* invoked after set_chunk_size().
	*/
	static inline void set_chunk_size(struct z_heap *h, chunkid_t c, chunksz_t size)
	{
	chunk_set(h, c, SIZE_AND_USED, size << 1);
	}

	static inline chunkid_t prev_free_chunk(struct z_heap *h, chunkid_t c)
	{
	return chunk_field(h, c, FREE_PREV);
	}

	static inline chunkid_t next_free_chunk(struct z_heap *h, chunkid_t c)
	{
	return chunk_field(h, c, FREE_NEXT);
	}

	static inline void set_prev_free_chunk(struct z_heap *h, chunkid_t c,
	chunkid_t prev)
	{
	chunk_set(h, c, FREE_PREV, prev);
	}

	static inline void set_next_free_chunk(struct z_heap *h, chunkid_t c,
	chunkid_t next)
	{
	chunk_set(h, c, FREE_NEXT, next);
	}

	static inline chunkid_t left_chunk(struct z_heap *h, chunkid_t c)
	{
	return c - chunk_field(h, c, LEFT_SIZE);
	}

	static inline chunkid_t right_chunk(struct z_heap *h, chunkid_t c)
	{
	return c + chunk_size(h, c);
	}

	static inline void set_left_chunk_size(struct z_heap *h, chunkid_t c,
	chunksz_t size)
	{
	chunk_set(h, c, LEFT_SIZE, size);
	}

	static inline bool solo_free_header(struct z_heap *h, chunkid_t c)
	{
	return big_heap(h) && chunk_size(h, c) == 1U;
	}

	static inline size_t chunk_header_bytes(struct z_heap *h)
	{
	return big_heap(h) ? 8 : 4;
	}

	static inline size_t heap_footer_bytes(size_t size)
	{
	return big_heap_bytes(size) ? 8 : 4;
	}

	static inline chunksz_t chunksz(size_t bytes)
	{
	return (bytes + CHUNK_UNIT - 1U) / CHUNK_UNIT;
	}

	static inline chunksz_t bytes_to_chunksz(struct z_heap *h, size_t bytes)
	{
	return chunksz(chunk_header_bytes(h) + bytes);
	}

	static inline chunksz_t min_chunk_size(struct z_heap *h)
	{
	return bytes_to_chunksz(h, 1);
	}

	static inline size_t chunksz_to_bytes(struct z_heap *h, chunksz_t chunksz_in)
	{
	return chunksz_in * CHUNK_UNIT - chunk_header_bytes(h);
	}

	static inline int bucket_idx(struct z_heap *h, chunksz_t sz)
	{
	unsigned int usable_sz = sz - min_chunk_size(h) + 1;
	return 31 - __builtin_clz(usable_sz);
	}

	static inline bool size_too_big(struct z_heap *h, size_t bytes)
	{
	/*
	* Quick check to bail out early if size is too big.
	* Also guards against potential arithmetic overflows elsewhere.
	*/
	return (bytes / CHUNK_UNIT) >= h->end_chunk;
	}

	/* For debugging */
	void heap_print_info(struct z_heap *h, bool dump_chunks);

	#endif /* ZEPHYR_INCLUDE_LIB_OS_HEAP_H_ */