include/linux/min_heap.h - kernel/common - Git at Google

 /* SPDX-License-Identifier: GPL-2.0 */
 #ifndef _LINUX_MIN_HEAP_H
 #define _LINUX_MIN_HEAP_H

 #include <linux/bug.h>
 #include <linux/string.h>
 #include <linux/types.h>

 /*
  * The Min Heap API provides utilities for managing min-heaps, a binary tree
  * structure where each node's value is less than or equal to its children's
  * values, ensuring the smallest element is at the root.
  *
  * Users should avoid directly calling functions prefixed with __min_heap_*().
  * Instead, use the provided macro wrappers.
  *
  * For further details and examples, refer to Documentation/core-api/min_heap.rst.
  */

 /**
  * Data structure to hold a min-heap.
  * @nr: Number of elements currently in the heap.
  * @size: Maximum number of elements that can be held in current storage.
  * @data: Pointer to the start of array holding the heap elements.
  * @preallocated: Start of the static preallocated array holding the heap elements.
  */
 #define MIN_HEAP_PREALLOCATED(_type, _name, _nr)	\
 struct _name {	\
 	size_t nr;	\
 	size_t size;	\
 	_type *data;	\
 	_type preallocated[_nr];	\
 }

 #define DEFINE_MIN_HEAP(_type, _name) MIN_HEAP_PREALLOCATED(_type, _name, 0)

 typedef DEFINE_MIN_HEAP(char, min_heap_char) min_heap_char;

 #define __minheap_cast(_heap)		(typeof((_heap)->data[0]) *)
 #define __minheap_obj_size(_heap)	sizeof((_heap)->data[0])

 /**
  * struct min_heap_callbacks - Data/functions to customise the min_heap.
  * @less: Partial order function for this heap.
  * @swp: Swap elements function.
  */
 struct min_heap_callbacks {
 	bool (*less)(const void *lhs, const void *rhs, void *args);
 	void (*swp)(void *lhs, void *rhs, void *args);
 };

 /**
  * is_aligned - is this pointer & size okay for word-wide copying?
  * @base: pointer to data
  * @size: size of each element
  * @align: required alignment (typically 4 or 8)
  *
  * Returns true if elements can be copied using word loads and stores.
  * The size must be a multiple of the alignment, and the base address must
  * be if we do not have CONFIG_HAVE_EFFICIENT_UNALIGNED_ACCESS.
  *
  * For some reason, gcc doesn't know to optimize "if (a & mask || b & mask)"
  * to "if ((a | b) & mask)", so we do that by hand.
  */
 __attribute_const__ __always_inline
 static bool is_aligned(const void *base, size_t size, unsigned char align)
 {
 	unsigned char lsbits = (unsigned char)size;

 	(void)base;
 #ifndef CONFIG_HAVE_EFFICIENT_UNALIGNED_ACCESS
 	lsbits |= (unsigned char)(uintptr_t)base;
 #endif
 	return (lsbits & (align - 1)) == 0;
 }

 /**
  * swap_words_32 - swap two elements in 32-bit chunks
  * @a: pointer to the first element to swap
  * @b: pointer to the second element to swap
  * @n: element size (must be a multiple of 4)
  *
  * Exchange the two objects in memory.  This exploits base+index addressing,
  * which basically all CPUs have, to minimize loop overhead computations.
  *
  * For some reason, on x86 gcc 7.3.0 adds a redundant test of n at the
  * bottom of the loop, even though the zero flag is still valid from the
  * subtract (since the intervening mov instructions don't alter the flags).
  * Gcc 8.1.0 doesn't have that problem.
  */
 static __always_inline
 void swap_words_32(void *a, void *b, size_t n)
 {
 	do {
 		u32 t = *(u32 *)(a + (n -= 4));
 		*(u32 *)(a + n) = *(u32 *)(b + n);
 		*(u32 *)(b + n) = t;
 	} while (n);
 }

 /**
  * swap_words_64 - swap two elements in 64-bit chunks
  * @a: pointer to the first element to swap
  * @b: pointer to the second element to swap
  * @n: element size (must be a multiple of 8)
  *
  * Exchange the two objects in memory.  This exploits base+index
  * addressing, which basically all CPUs have, to minimize loop overhead
  * computations.
  *
  * We'd like to use 64-bit loads if possible.  If they're not, emulating
  * one requires base+index+4 addressing which x86 has but most other
  * processors do not.  If CONFIG_64BIT, we definitely have 64-bit loads,
  * but it's possible to have 64-bit loads without 64-bit pointers (e.g.
  * x32 ABI).  Are there any cases the kernel needs to worry about?
  */
 static __always_inline
 void swap_words_64(void *a, void *b, size_t n)
 {
 	do {
 #ifdef CONFIG_64BIT
 		u64 t = *(u64 *)(a + (n -= 8));
 		*(u64 *)(a + n) = *(u64 *)(b + n);
 		*(u64 *)(b + n) = t;
 #else
 		/* Use two 32-bit transfers to avoid base+index+4 addressing */
 		u32 t = *(u32 *)(a + (n -= 4));
 		*(u32 *)(a + n) = *(u32 *)(b + n);
 		*(u32 *)(b + n) = t;

 		t = *(u32 *)(a + (n -= 4));
 		*(u32 *)(a + n) = *(u32 *)(b + n);
 		*(u32 *)(b + n) = t;
 #endif
 	} while (n);
 }

 /**
  * swap_bytes - swap two elements a byte at a time
  * @a: pointer to the first element to swap
  * @b: pointer to the second element to swap
  * @n: element size
  *
  * This is the fallback if alignment doesn't allow using larger chunks.
  */
 static __always_inline
 void swap_bytes(void *a, void *b, size_t n)
 {
 	do {
 		char t = ((char *)a)[--n];
 		((char *)a)[n] = ((char *)b)[n];
 		((char *)b)[n] = t;
 	} while (n);
 }

 /*
  * The values are arbitrary as long as they can't be confused with
  * a pointer, but small integers make for the smallest compare
  * instructions.
  */
 #define SWAP_WORDS_64 ((void (*)(void *, void *, void *))0)
 #define SWAP_WORDS_32 ((void (*)(void *, void *, void *))1)
 #define SWAP_BYTES    ((void (*)(void *, void *, void *))2)

 /*
  * Selects the appropriate swap function based on the element size.
  */
 static __always_inline
 void *select_swap_func(const void *base, size_t size)
 {
 	if (is_aligned(base, size, 8))
 		return SWAP_WORDS_64;
 	else if (is_aligned(base, size, 4))
 		return SWAP_WORDS_32;
 	else
 		return SWAP_BYTES;
 }

 static __always_inline
 void do_swap(void *a, void *b, size_t size, void (*swap_func)(void *lhs, void *rhs, void *args),
 	     void *priv)
 {
 	if (swap_func == SWAP_WORDS_64)
 		swap_words_64(a, b, size);
 	else if (swap_func == SWAP_WORDS_32)
 		swap_words_32(a, b, size);
 	else if (swap_func == SWAP_BYTES)
 		swap_bytes(a, b, size);
 	else
 		swap_func(a, b, priv);
 }

 /**
  * parent - given the offset of the child, find the offset of the parent.
  * @i: the offset of the heap element whose parent is sought.  Non-zero.
  * @lsbit: a precomputed 1-bit mask, equal to "size & -size"
  * @size: size of each element
  *
  * In terms of array indexes, the parent of element j = @i/@size is simply
  * (j-1)/2.  But when working in byte offsets, we can't use implicit
  * truncation of integer divides.
  *
  * Fortunately, we only need one bit of the quotient, not the full divide.
  * @size has a least significant bit.  That bit will be clear if @i is
  * an even multiple of @size, and set if it's an odd multiple.
  *
  * Logically, we're doing "if (i & lsbit) i -= size;", but since the
  * branch is unpredictable, it's done with a bit of clever branch-free
  * code instead.
  */
 __attribute_const__ __always_inline
 static size_t parent(size_t i, unsigned int lsbit, size_t size)
 {
 	i -= size;
 	i -= size & -(i & lsbit);
 	return i / 2;
 }

 /* Initialize a min-heap. */
 static __always_inline
 void __min_heap_init_inline(min_heap_char *heap, void *data, int size)
 {
 	heap->nr = 0;
 	heap->size = size;
 	if (data)
 		heap->data = data;
 	else
 		heap->data = heap->preallocated;
 }

 #define min_heap_init_inline(_heap, _data, _size)	\
 	__min_heap_init_inline(container_of(&(_heap)->nr, min_heap_char, nr), _data, _size)

 /* Get the minimum element from the heap. */
 static __always_inline
 void *__min_heap_peek_inline(struct min_heap_char *heap)
 {
 	return heap->nr ? heap->data : NULL;
 }

 #define min_heap_peek_inline(_heap)	\
 	(__minheap_cast(_heap)	\
 	 __min_heap_peek_inline(container_of(&(_heap)->nr, min_heap_char, nr)))

 /* Check if the heap is full. */
 static __always_inline
 bool __min_heap_full_inline(min_heap_char *heap)
 {
 	return heap->nr == heap->size;
 }

 #define min_heap_full_inline(_heap)	\
 	__min_heap_full_inline(container_of(&(_heap)->nr, min_heap_char, nr))

 /* Sift the element at pos down the heap. */
 static __always_inline
 void __min_heap_sift_down_inline(min_heap_char *heap, int pos, size_t elem_size,
 				 const struct min_heap_callbacks *func, void *args)
 {
 	const unsigned long lsbit = elem_size & -elem_size;
 	void *data = heap->data;
 	void (*swp)(void *lhs, void *rhs, void *args) = func->swp;
 	/* pre-scale counters for performance */
 	size_t a = pos * elem_size;
 	size_t b, c, d;
 	size_t n = heap->nr * elem_size;

 	if (!swp)
 		swp = select_swap_func(data, elem_size);

 	/* Find the sift-down path all the way to the leaves. */
 	for (b = a; c = 2 * b + elem_size, (d = c + elem_size) < n;)
 		b = func->less(data + c, data + d, args) ? c : d;

 	/* Special case for the last leaf with no sibling. */
 	if (d == n)
 		b = c;

 	/* Backtrack to the correct location. */
 	while (b != a && func->less(data + a, data + b, args))
 		b = parent(b, lsbit, elem_size);

 	/* Shift the element into its correct place. */
 	c = b;
 	while (b != a) {
 		b = parent(b, lsbit, elem_size);
 		do_swap(data + b, data + c, elem_size, swp, args);
 	}
 }

 #define min_heap_sift_down_inline(_heap, _pos, _func, _args)	\
 	__min_heap_sift_down_inline(container_of(&(_heap)->nr, min_heap_char, nr), _pos,	\
 				    __minheap_obj_size(_heap), _func, _args)

 /* Sift up ith element from the heap, O(log2(nr)). */
 static __always_inline
 void __min_heap_sift_up_inline(min_heap_char *heap, size_t elem_size, size_t idx,
 			       const struct min_heap_callbacks *func, void *args)
 {
 	const unsigned long lsbit = elem_size & -elem_size;
 	void *data = heap->data;
 	void (*swp)(void *lhs, void *rhs, void *args) = func->swp;
 	/* pre-scale counters for performance */
 	size_t a = idx * elem_size, b;

 	if (!swp)
 		swp = select_swap_func(data, elem_size);

 	while (a) {
 		b = parent(a, lsbit, elem_size);
 		if (func->less(data + b, data + a, args))
 			break;
 		do_swap(data + a, data + b, elem_size, swp, args);
 		a = b;
 	}
 }

 #define min_heap_sift_up_inline(_heap, _idx, _func, _args)	\
 	__min_heap_sift_up_inline(container_of(&(_heap)->nr, min_heap_char, nr),	\
 				  __minheap_obj_size(_heap), _idx, _func, _args)

 /* Floyd's approach to heapification that is O(nr). */
 static __always_inline
 void __min_heapify_all_inline(min_heap_char *heap, size_t elem_size,
 			      const struct min_heap_callbacks *func, void *args)
 {
 	int i;

 	for (i = heap->nr / 2 - 1; i >= 0; i--)
 		__min_heap_sift_down_inline(heap, i, elem_size, func, args);
 }

 #define min_heapify_all_inline(_heap, _func, _args)	\
 	__min_heapify_all_inline(container_of(&(_heap)->nr, min_heap_char, nr),	\
 				 __minheap_obj_size(_heap), _func, _args)

 /* Remove minimum element from the heap, O(log2(nr)). */
 static __always_inline
 bool __min_heap_pop_inline(min_heap_char *heap, size_t elem_size,
 			   const struct min_heap_callbacks *func, void *args)
 {
 	void *data = heap->data;

 	if (WARN_ONCE(heap->nr <= 0, "Popping an empty heap"))
 		return false;

 	/* Place last element at the root (position 0) and then sift down. */
 	heap->nr--;
 	memcpy(data, data + (heap->nr * elem_size), elem_size);
 	__min_heap_sift_down_inline(heap, 0, elem_size, func, args);

 	return true;
 }

 #define min_heap_pop_inline(_heap, _func, _args)	\
 	__min_heap_pop_inline(container_of(&(_heap)->nr, min_heap_char, nr),	\
 			      __minheap_obj_size(_heap), _func, _args)

 /*
  * Remove the minimum element and then push the given element. The
  * implementation performs 1 sift (O(log2(nr))) and is therefore more
  * efficient than a pop followed by a push that does 2.
  */
 static __always_inline
 void __min_heap_pop_push_inline(min_heap_char *heap, const void *element, size_t elem_size,
 				const struct min_heap_callbacks *func, void *args)
 {
 	memcpy(heap->data, element, elem_size);
 	__min_heap_sift_down_inline(heap, 0, elem_size, func, args);
 }

 #define min_heap_pop_push_inline(_heap, _element, _func, _args)	\
 	__min_heap_pop_push_inline(container_of(&(_heap)->nr, min_heap_char, nr), _element,	\
 				   __minheap_obj_size(_heap), _func, _args)

 /* Push an element on to the heap, O(log2(nr)). */
 static __always_inline
 bool __min_heap_push_inline(min_heap_char *heap, const void *element, size_t elem_size,
 			    const struct min_heap_callbacks *func, void *args)
 {
 	void *data = heap->data;
 	int pos;

 	if (WARN_ONCE(heap->nr >= heap->size, "Pushing on a full heap"))
 		return false;

 	/* Place at the end of data. */
 	pos = heap->nr;
 	memcpy(data + (pos * elem_size), element, elem_size);
 	heap->nr++;

 	/* Sift child at pos up. */
 	__min_heap_sift_up_inline(heap, elem_size, pos, func, args);

 	return true;
 }

 #define min_heap_push_inline(_heap, _element, _func, _args)	\
 	__min_heap_push_inline(container_of(&(_heap)->nr, min_heap_char, nr), _element,	\
 					    __minheap_obj_size(_heap), _func, _args)

 /* Remove ith element from the heap, O(log2(nr)). */
 static __always_inline
 bool __min_heap_del_inline(min_heap_char *heap, size_t elem_size, size_t idx,
 			   const struct min_heap_callbacks *func, void *args)
 {
 	void *data = heap->data;
 	void (*swp)(void *lhs, void *rhs, void *args) = func->swp;

 	if (WARN_ONCE(heap->nr <= 0, "Popping an empty heap"))
 		return false;

 	if (!swp)
 		swp = select_swap_func(data, elem_size);

 	/* Place last element at the root (position 0) and then sift down. */
 	heap->nr--;
 	if (idx == heap->nr)
 		return true;
 	do_swap(data + (idx * elem_size), data + (heap->nr * elem_size), elem_size, swp, args);
 	__min_heap_sift_up_inline(heap, elem_size, idx, func, args);
 	__min_heap_sift_down_inline(heap, idx, elem_size, func, args);

 	return true;
 }

 #define min_heap_del_inline(_heap, _idx, _func, _args)	\
 	__min_heap_del_inline(container_of(&(_heap)->nr, min_heap_char, nr),	\
 			      __minheap_obj_size(_heap), _idx, _func, _args)

 void __min_heap_init(min_heap_char *heap, void *data, int size);
 void *__min_heap_peek(struct min_heap_char *heap);
 bool __min_heap_full(min_heap_char *heap);
 void __min_heap_sift_down(min_heap_char *heap, int pos, size_t elem_size,
 			  const struct min_heap_callbacks *func, void *args);
 void __min_heap_sift_up(min_heap_char *heap, size_t elem_size, size_t idx,
 			const struct min_heap_callbacks *func, void *args);
 void __min_heapify_all(min_heap_char *heap, size_t elem_size,
 		       const struct min_heap_callbacks *func, void *args);
 bool __min_heap_pop(min_heap_char *heap, size_t elem_size,
 		    const struct min_heap_callbacks *func, void *args);
 void __min_heap_pop_push(min_heap_char *heap, const void *element, size_t elem_size,
 			 const struct min_heap_callbacks *func, void *args);
 bool __min_heap_push(min_heap_char *heap, const void *element, size_t elem_size,
 		     const struct min_heap_callbacks *func, void *args);
 bool __min_heap_del(min_heap_char *heap, size_t elem_size, size_t idx,
 		    const struct min_heap_callbacks *func, void *args);

 #define min_heap_init(_heap, _data, _size)	\
 	__min_heap_init(container_of(&(_heap)->nr, min_heap_char, nr), _data, _size)
 #define min_heap_peek(_heap)	\
 	(__minheap_cast(_heap) __min_heap_peek(container_of(&(_heap)->nr, min_heap_char, nr)))
 #define min_heap_full(_heap)	\
 	__min_heap_full(container_of(&(_heap)->nr, min_heap_char, nr))
 #define min_heap_sift_down(_heap, _pos, _func, _args)	\
 	__min_heap_sift_down(container_of(&(_heap)->nr, min_heap_char, nr), _pos,	\
 			     __minheap_obj_size(_heap), _func, _args)
 #define min_heap_sift_up(_heap, _idx, _func, _args)	\
 	__min_heap_sift_up(container_of(&(_heap)->nr, min_heap_char, nr),	\
 			   __minheap_obj_size(_heap), _idx, _func, _args)
 #define min_heapify_all(_heap, _func, _args)	\
 	__min_heapify_all(container_of(&(_heap)->nr, min_heap_char, nr),	\
 			  __minheap_obj_size(_heap), _func, _args)
 #define min_heap_pop(_heap, _func, _args)	\
 	__min_heap_pop(container_of(&(_heap)->nr, min_heap_char, nr),	\
 		       __minheap_obj_size(_heap), _func, _args)
 #define min_heap_pop_push(_heap, _element, _func, _args)	\
 	__min_heap_pop_push(container_of(&(_heap)->nr, min_heap_char, nr), _element,	\
 			    __minheap_obj_size(_heap), _func, _args)
 #define min_heap_push(_heap, _element, _func, _args)	\
 	__min_heap_push(container_of(&(_heap)->nr, min_heap_char, nr), _element,	\
 			__minheap_obj_size(_heap), _func, _args)
 #define min_heap_del(_heap, _idx, _func, _args)	\
 	__min_heap_del(container_of(&(_heap)->nr, min_heap_char, nr),	\
 		       __minheap_obj_size(_heap), _idx, _func, _args)

 #endif /* _LINUX_MIN_HEAP_H */
	/* SPDX-License-Identifier: GPL-2.0 */
	#ifndef _LINUX_MIN_HEAP_H
	#define _LINUX_MIN_HEAP_H

	#include <linux/bug.h>
	#include <linux/string.h>
	#include <linux/types.h>

	/*
	* The Min Heap API provides utilities for managing min-heaps, a binary tree
	* structure where each node's value is less than or equal to its children's
	* values, ensuring the smallest element is at the root.
	*
	* Users should avoid directly calling functions prefixed with __min_heap_*().
	* Instead, use the provided macro wrappers.
	*
	* For further details and examples, refer to Documentation/core-api/min_heap.rst.
	*/

	/**
	* Data structure to hold a min-heap.
	* @nr: Number of elements currently in the heap.
	* @size: Maximum number of elements that can be held in current storage.
	* @data: Pointer to the start of array holding the heap elements.
	* @preallocated: Start of the static preallocated array holding the heap elements.
	*/
	#define MIN_HEAP_PREALLOCATED(_type, _name, _nr) \
	struct _name { \
	size_t nr; \
	size_t size; \
	_type *data; \
	_type preallocated[_nr]; \
	}

	#define DEFINE_MIN_HEAP(_type, _name) MIN_HEAP_PREALLOCATED(_type, _name, 0)

	typedef DEFINE_MIN_HEAP(char, min_heap_char) min_heap_char;

	#define __minheap_cast(_heap) (typeof((_heap)->data[0]) *)
	#define __minheap_obj_size(_heap) sizeof((_heap)->data[0])

	/**
	* struct min_heap_callbacks - Data/functions to customise the min_heap.
	* @less: Partial order function for this heap.
	* @swp: Swap elements function.
	*/
	struct min_heap_callbacks {
	bool (less)(const void lhs, const void rhs, void args);
	void (swp)(void lhs, void rhs, void args);
	};

	/**
	* is_aligned - is this pointer & size okay for word-wide copying?
	* @base: pointer to data
	* @size: size of each element
	* @align: required alignment (typically 4 or 8)
	*
	* Returns true if elements can be copied using word loads and stores.
	* The size must be a multiple of the alignment, and the base address must
	* be if we do not have CONFIG_HAVE_EFFICIENT_UNALIGNED_ACCESS.
	*
	* For some reason, gcc doesn't know to optimize "if (a & mask \|\| b & mask)"
	* to "if ((a \| b) & mask)", so we do that by hand.
	*/
	__attribute_const__ __always_inline
	static bool is_aligned(const void *base, size_t size, unsigned char align)
	{
	unsigned char lsbits = (unsigned char)size;

	(void)base;
	#ifndef CONFIG_HAVE_EFFICIENT_UNALIGNED_ACCESS
	lsbits \|= (unsigned char)(uintptr_t)base;
	#endif
	return (lsbits & (align - 1)) == 0;
	}

	/**
	* swap_words_32 - swap two elements in 32-bit chunks
	* @a: pointer to the first element to swap
	* @b: pointer to the second element to swap
	* @n: element size (must be a multiple of 4)
	*
	* Exchange the two objects in memory. This exploits base+index addressing,
	* which basically all CPUs have, to minimize loop overhead computations.
	*
	* For some reason, on x86 gcc 7.3.0 adds a redundant test of n at the
	* bottom of the loop, even though the zero flag is still valid from the
	* subtract (since the intervening mov instructions don't alter the flags).
	* Gcc 8.1.0 doesn't have that problem.
	*/
	static __always_inline
	void swap_words_32(void a, void b, size_t n)
	{
	do {
	u32 t = (u32 )(a + (n -= 4));
	(u32 )(a + n) = (u32 )(b + n);
	(u32 )(b + n) = t;
	} while (n);
	}

	/**
	* swap_words_64 - swap two elements in 64-bit chunks
	* @a: pointer to the first element to swap
	* @b: pointer to the second element to swap
	* @n: element size (must be a multiple of 8)
	*
	* Exchange the two objects in memory. This exploits base+index
	* addressing, which basically all CPUs have, to minimize loop overhead
	* computations.
	*
	* We'd like to use 64-bit loads if possible. If they're not, emulating
	* one requires base+index+4 addressing which x86 has but most other
	* processors do not. If CONFIG_64BIT, we definitely have 64-bit loads,
	* but it's possible to have 64-bit loads without 64-bit pointers (e.g.
	* x32 ABI). Are there any cases the kernel needs to worry about?
	*/
	static __always_inline
	void swap_words_64(void a, void b, size_t n)
	{
	do {
	#ifdef CONFIG_64BIT
	u64 t = (u64 )(a + (n -= 8));
	(u64 )(a + n) = (u64 )(b + n);
	(u64 )(b + n) = t;
	#else
	/* Use two 32-bit transfers to avoid base+index+4 addressing */
	u32 t = (u32 )(a + (n -= 4));
	(u32 )(a + n) = (u32 )(b + n);
	(u32 )(b + n) = t;

	t = (u32 )(a + (n -= 4));
	(u32 )(a + n) = (u32 )(b + n);
	(u32 )(b + n) = t;
	#endif
	} while (n);
	}

	/**
	* swap_bytes - swap two elements a byte at a time
	* @a: pointer to the first element to swap
	* @b: pointer to the second element to swap
	* @n: element size
	*
	* This is the fallback if alignment doesn't allow using larger chunks.
	*/
	static __always_inline
	void swap_bytes(void a, void b, size_t n)
	{
	do {
	char t = ((char *)a)[--n];
	((char )a)[n] = ((char )b)[n];
	((char *)b)[n] = t;
	} while (n);
	}

	/*
	* The values are arbitrary as long as they can't be confused with
	* a pointer, but small integers make for the smallest compare
	* instructions.
	*/
	#define SWAP_WORDS_64 ((void ()(void , void , void ))0)
	#define SWAP_WORDS_32 ((void ()(void , void , void ))1)
	#define SWAP_BYTES ((void ()(void , void , void ))2)

	/*
	* Selects the appropriate swap function based on the element size.
	*/
	static __always_inline
	void select_swap_func(const void base, size_t size)
	{
	if (is_aligned(base, size, 8))
	return SWAP_WORDS_64;
	else if (is_aligned(base, size, 4))
	return SWAP_WORDS_32;
	else
	return SWAP_BYTES;
	}

	static __always_inline
	void do_swap(void a, void b, size_t size, void (swap_func)(void lhs, void rhs, void args),
	void *priv)
	{
	if (swap_func == SWAP_WORDS_64)
	swap_words_64(a, b, size);
	else if (swap_func == SWAP_WORDS_32)
	swap_words_32(a, b, size);
	else if (swap_func == SWAP_BYTES)
	swap_bytes(a, b, size);
	else
	swap_func(a, b, priv);
	}

	/**
	* parent - given the offset of the child, find the offset of the parent.
	* @i: the offset of the heap element whose parent is sought. Non-zero.
	* @lsbit: a precomputed 1-bit mask, equal to "size & -size"
	* @size: size of each element
	*
	* In terms of array indexes, the parent of element j = @i/@size is simply
	* (j-1)/2. But when working in byte offsets, we can't use implicit
	* truncation of integer divides.
	*
	* Fortunately, we only need one bit of the quotient, not the full divide.
	* @size has a least significant bit. That bit will be clear if @i is
	* an even multiple of @size, and set if it's an odd multiple.
	*
	* Logically, we're doing "if (i & lsbit) i -= size;", but since the
	* branch is unpredictable, it's done with a bit of clever branch-free
	* code instead.
	*/
	__attribute_const__ __always_inline
	static size_t parent(size_t i, unsigned int lsbit, size_t size)
	{
	i -= size;
	i -= size & -(i & lsbit);
	return i / 2;
	}

	/* Initialize a min-heap. */
	static __always_inline
	void __min_heap_init_inline(min_heap_char heap, void data, int size)
	{
	heap->nr = 0;
	heap->size = size;
	if (data)
	heap->data = data;
	else
	heap->data = heap->preallocated;
	}

	#define min_heap_init_inline(_heap, _data, _size) \
	__min_heap_init_inline(container_of(&(_heap)->nr, min_heap_char, nr), _data, _size)

	/* Get the minimum element from the heap. */
	static __always_inline
	void __min_heap_peek_inline(struct min_heap_char heap)
	{
	return heap->nr ? heap->data : NULL;
	}

	#define min_heap_peek_inline(_heap) \
	(__minheap_cast(_heap) \
	__min_heap_peek_inline(container_of(&(_heap)->nr, min_heap_char, nr)))

	/* Check if the heap is full. */
	static __always_inline
	bool __min_heap_full_inline(min_heap_char *heap)
	{
	return heap->nr == heap->size;
	}

	#define min_heap_full_inline(_heap) \
	__min_heap_full_inline(container_of(&(_heap)->nr, min_heap_char, nr))

	/* Sift the element at pos down the heap. */
	static __always_inline
	void __min_heap_sift_down_inline(min_heap_char *heap, int pos, size_t elem_size,
	const struct min_heap_callbacks func, void args)
	{
	const unsigned long lsbit = elem_size & -elem_size;
	void *data = heap->data;
	void (swp)(void lhs, void rhs, void args) = func->swp;
	/* pre-scale counters for performance */
	size_t a = pos * elem_size;
	size_t b, c, d;
	size_t n = heap->nr * elem_size;

	if (!swp)
	swp = select_swap_func(data, elem_size);

	/* Find the sift-down path all the way to the leaves. */
	for (b = a; c = 2 * b + elem_size, (d = c + elem_size) < n;)
	b = func->less(data + c, data + d, args) ? c : d;

	/* Special case for the last leaf with no sibling. */
	if (d == n)
	b = c;

	/* Backtrack to the correct location. */
	while (b != a && func->less(data + a, data + b, args))
	b = parent(b, lsbit, elem_size);

	/* Shift the element into its correct place. */
	c = b;
	while (b != a) {
	b = parent(b, lsbit, elem_size);
	do_swap(data + b, data + c, elem_size, swp, args);
	}
	}

	#define min_heap_sift_down_inline(_heap, _pos, _func, _args) \
	__min_heap_sift_down_inline(container_of(&(_heap)->nr, min_heap_char, nr), _pos, \
	__minheap_obj_size(_heap), _func, _args)

	/* Sift up ith element from the heap, O(log2(nr)). */
	static __always_inline
	void __min_heap_sift_up_inline(min_heap_char *heap, size_t elem_size, size_t idx,
	const struct min_heap_callbacks func, void args)
	{
	const unsigned long lsbit = elem_size & -elem_size;
	void *data = heap->data;
	void (swp)(void lhs, void rhs, void args) = func->swp;
	/* pre-scale counters for performance */
	size_t a = idx * elem_size, b;

	if (!swp)
	swp = select_swap_func(data, elem_size);

	while (a) {
	b = parent(a, lsbit, elem_size);
	if (func->less(data + b, data + a, args))
	break;
	do_swap(data + a, data + b, elem_size, swp, args);
	a = b;
	}
	}

	#define min_heap_sift_up_inline(_heap, _idx, _func, _args) \
	__min_heap_sift_up_inline(container_of(&(_heap)->nr, min_heap_char, nr), \
	__minheap_obj_size(_heap), _idx, _func, _args)

	/* Floyd's approach to heapification that is O(nr). */
	static __always_inline
	void __min_heapify_all_inline(min_heap_char *heap, size_t elem_size,
	const struct min_heap_callbacks func, void args)
	{
	int i;

	for (i = heap->nr / 2 - 1; i >= 0; i--)
	__min_heap_sift_down_inline(heap, i, elem_size, func, args);
	}

	#define min_heapify_all_inline(_heap, _func, _args) \
	__min_heapify_all_inline(container_of(&(_heap)->nr, min_heap_char, nr), \
	__minheap_obj_size(_heap), _func, _args)

	/* Remove minimum element from the heap, O(log2(nr)). */
	static __always_inline
	bool __min_heap_pop_inline(min_heap_char *heap, size_t elem_size,
	const struct min_heap_callbacks func, void args)
	{
	void *data = heap->data;

	if (WARN_ONCE(heap->nr <= 0, "Popping an empty heap"))
	return false;

	/* Place last element at the root (position 0) and then sift down. */
	heap->nr--;
	memcpy(data, data + (heap->nr * elem_size), elem_size);
	__min_heap_sift_down_inline(heap, 0, elem_size, func, args);

	return true;
	}

	#define min_heap_pop_inline(_heap, _func, _args) \
	__min_heap_pop_inline(container_of(&(_heap)->nr, min_heap_char, nr), \
	__minheap_obj_size(_heap), _func, _args)

	/*
	* Remove the minimum element and then push the given element. The
	* implementation performs 1 sift (O(log2(nr))) and is therefore more
	* efficient than a pop followed by a push that does 2.
	*/
	static __always_inline
	void __min_heap_pop_push_inline(min_heap_char heap, const void element, size_t elem_size,
	const struct min_heap_callbacks func, void args)
	{
	memcpy(heap->data, element, elem_size);
	__min_heap_sift_down_inline(heap, 0, elem_size, func, args);
	}

	#define min_heap_pop_push_inline(_heap, _element, _func, _args) \
	__min_heap_pop_push_inline(container_of(&(_heap)->nr, min_heap_char, nr), _element, \
	__minheap_obj_size(_heap), _func, _args)

	/* Push an element on to the heap, O(log2(nr)). */
	static __always_inline
	bool __min_heap_push_inline(min_heap_char heap, const void element, size_t elem_size,
	const struct min_heap_callbacks func, void args)
	{
	void *data = heap->data;
	int pos;

	if (WARN_ONCE(heap->nr >= heap->size, "Pushing on a full heap"))
	return false;

	/* Place at the end of data. */
	pos = heap->nr;
	memcpy(data + (pos * elem_size), element, elem_size);
	heap->nr++;

	/* Sift child at pos up. */
	__min_heap_sift_up_inline(heap, elem_size, pos, func, args);

	return true;
	}

	#define min_heap_push_inline(_heap, _element, _func, _args) \
	__min_heap_push_inline(container_of(&(_heap)->nr, min_heap_char, nr), _element, \
	__minheap_obj_size(_heap), _func, _args)

	/* Remove ith element from the heap, O(log2(nr)). */
	static __always_inline
	bool __min_heap_del_inline(min_heap_char *heap, size_t elem_size, size_t idx,
	const struct min_heap_callbacks func, void args)
	{
	void *data = heap->data;
	void (swp)(void lhs, void rhs, void args) = func->swp;

	if (WARN_ONCE(heap->nr <= 0, "Popping an empty heap"))
	return false;

	if (!swp)
	swp = select_swap_func(data, elem_size);

	/* Place last element at the root (position 0) and then sift down. */
	heap->nr--;
	if (idx == heap->nr)
	return true;
	do_swap(data + (idx * elem_size), data + (heap->nr * elem_size), elem_size, swp, args);
	__min_heap_sift_up_inline(heap, elem_size, idx, func, args);
	__min_heap_sift_down_inline(heap, idx, elem_size, func, args);

	return true;
	}

	#define min_heap_del_inline(_heap, _idx, _func, _args) \
	__min_heap_del_inline(container_of(&(_heap)->nr, min_heap_char, nr), \
	__minheap_obj_size(_heap), _idx, _func, _args)

	void __min_heap_init(min_heap_char heap, void data, int size);
	void __min_heap_peek(struct min_heap_char heap);
	bool __min_heap_full(min_heap_char *heap);
	void __min_heap_sift_down(min_heap_char *heap, int pos, size_t elem_size,
	const struct min_heap_callbacks func, void args);
	void __min_heap_sift_up(min_heap_char *heap, size_t elem_size, size_t idx,
	const struct min_heap_callbacks func, void args);
	void __min_heapify_all(min_heap_char *heap, size_t elem_size,
	const struct min_heap_callbacks func, void args);
	bool __min_heap_pop(min_heap_char *heap, size_t elem_size,
	const struct min_heap_callbacks func, void args);
	void __min_heap_pop_push(min_heap_char heap, const void element, size_t elem_size,
	const struct min_heap_callbacks func, void args);
	bool __min_heap_push(min_heap_char heap, const void element, size_t elem_size,
	const struct min_heap_callbacks func, void args);
	bool __min_heap_del(min_heap_char *heap, size_t elem_size, size_t idx,
	const struct min_heap_callbacks func, void args);

	#define min_heap_init(_heap, _data, _size) \
	__min_heap_init(container_of(&(_heap)->nr, min_heap_char, nr), _data, _size)
	#define min_heap_peek(_heap) \
	(__minheap_cast(_heap) __min_heap_peek(container_of(&(_heap)->nr, min_heap_char, nr)))
	#define min_heap_full(_heap) \
	__min_heap_full(container_of(&(_heap)->nr, min_heap_char, nr))
	#define min_heap_sift_down(_heap, _pos, _func, _args) \
	__min_heap_sift_down(container_of(&(_heap)->nr, min_heap_char, nr), _pos, \
	__minheap_obj_size(_heap), _func, _args)
	#define min_heap_sift_up(_heap, _idx, _func, _args) \
	__min_heap_sift_up(container_of(&(_heap)->nr, min_heap_char, nr), \
	__minheap_obj_size(_heap), _idx, _func, _args)
	#define min_heapify_all(_heap, _func, _args) \
	__min_heapify_all(container_of(&(_heap)->nr, min_heap_char, nr), \
	__minheap_obj_size(_heap), _func, _args)
	#define min_heap_pop(_heap, _func, _args) \
	__min_heap_pop(container_of(&(_heap)->nr, min_heap_char, nr), \
	__minheap_obj_size(_heap), _func, _args)
	#define min_heap_pop_push(_heap, _element, _func, _args) \
	__min_heap_pop_push(container_of(&(_heap)->nr, min_heap_char, nr), _element, \
	__minheap_obj_size(_heap), _func, _args)
	#define min_heap_push(_heap, _element, _func, _args) \
	__min_heap_push(container_of(&(_heap)->nr, min_heap_char, nr), _element, \
	__minheap_obj_size(_heap), _func, _args)
	#define min_heap_del(_heap, _idx, _func, _args) \
	__min_heap_del(container_of(&(_heap)->nr, min_heap_char, nr), \
	__minheap_obj_size(_heap), _idx, _func, _args)

	#endif /* _LINUX_MIN_HEAP_H */