tools/lib/list_sort.c - kernel/common - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 #include <linux/kernel.h>
 #include <linux/compiler.h>
 #include <linux/export.h>
 #include <linux/string.h>
 #include <linux/list_sort.h>
 #include <linux/list.h>

 /*
  * Returns a list organized in an intermediate format suited
  * to chaining of merge() calls: null-terminated, no reserved or
  * sentinel head node, "prev" links not maintained.
  */
 __attribute__((nonnull(2,3,4)))
 static struct list_head *merge(void *priv, list_cmp_func_t cmp,
 				struct list_head *a, struct list_head *b)
 {
 	struct list_head *head, **tail = &head;

 	for (;;) {
 		/* if equal, take 'a' -- important for sort stability */
 		if (cmp(priv, a, b) <= 0) {
 			*tail = a;
 			tail = &a->next;
 			a = a->next;
 			if (!a) {
 				*tail = b;
 				break;
 			}
 		} else {
 			*tail = b;
 			tail = &b->next;
 			b = b->next;
 			if (!b) {
 				*tail = a;
 				break;
 			}
 		}
 	}
 	return head;
 }

 /*
  * Combine final list merge with restoration of standard doubly-linked
  * list structure.  This approach duplicates code from merge(), but
  * runs faster than the tidier alternatives of either a separate final
  * prev-link restoration pass, or maintaining the prev links
  * throughout.
  */
 __attribute__((nonnull(2,3,4,5)))
 static void merge_final(void *priv, list_cmp_func_t cmp, struct list_head *head,
 			struct list_head *a, struct list_head *b)
 {
 	struct list_head *tail = head;
 	u8 count = 0;

 	for (;;) {
 		/* if equal, take 'a' -- important for sort stability */
 		if (cmp(priv, a, b) <= 0) {
 			tail->next = a;
 			a->prev = tail;
 			tail = a;
 			a = a->next;
 			if (!a)
 				break;
 		} else {
 			tail->next = b;
 			b->prev = tail;
 			tail = b;
 			b = b->next;
 			if (!b) {
 				b = a;
 				break;
 			}
 		}
 	}

 	/* Finish linking remainder of list b on to tail */
 	tail->next = b;
 	do {
 		/*
 		 * If the merge is highly unbalanced (e.g. the input is
 		 * already sorted), this loop may run many iterations.
 		 * Continue callbacks to the client even though no
 		 * element comparison is needed, so the client's cmp()
 		 * routine can invoke cond_resched() periodically.
 		 */
 		if (unlikely(!++count))
 			cmp(priv, b, b);
 		b->prev = tail;
 		tail = b;
 		b = b->next;
 	} while (b);

 	/* And the final links to make a circular doubly-linked list */
 	tail->next = head;
 	head->prev = tail;
 }

 /**
  * list_sort - sort a list
  * @priv: private data, opaque to list_sort(), passed to @cmp
  * @head: the list to sort
  * @cmp: the elements comparison function
  *
  * The comparison function @cmp must return > 0 if @a should sort after
  * @b ("@a > @b" if you want an ascending sort), and <= 0 if @a should
  * sort before @b *or* their original order should be preserved.  It is
  * always called with the element that came first in the input in @a,
  * and list_sort is a stable sort, so it is not necessary to distinguish
  * the @a < @b and @a == @b cases.
  *
  * This is compatible with two styles of @cmp function:
  * - The traditional style which returns <0 / =0 / >0, or
  * - Returning a boolean 0/1.
  * The latter offers a chance to save a few cycles in the comparison
  * (which is used by e.g. plug_ctx_cmp() in block/blk-mq.c).
  *
  * A good way to write a multi-word comparison is::
  *
  *	if (a->high != b->high)
  *		return a->high > b->high;
  *	if (a->middle != b->middle)
  *		return a->middle > b->middle;
  *	return a->low > b->low;
  *
  *
  * This mergesort is as eager as possible while always performing at least
  * 2:1 balanced merges.  Given two pending sublists of size 2^k, they are
  * merged to a size-2^(k+1) list as soon as we have 2^k following elements.
  *
  * Thus, it will avoid cache thrashing as long as 3*2^k elements can
  * fit into the cache.  Not quite as good as a fully-eager bottom-up
  * mergesort, but it does use 0.2*n fewer comparisons, so is faster in
  * the common case that everything fits into L1.
  *
  *
  * The merging is controlled by "count", the number of elements in the
  * pending lists.  This is beautifully simple code, but rather subtle.
  *
  * Each time we increment "count", we set one bit (bit k) and clear
  * bits k-1 .. 0.  Each time this happens (except the very first time
  * for each bit, when count increments to 2^k), we merge two lists of
  * size 2^k into one list of size 2^(k+1).
  *
  * This merge happens exactly when the count reaches an odd multiple of
  * 2^k, which is when we have 2^k elements pending in smaller lists,
  * so it's safe to merge away two lists of size 2^k.
  *
  * After this happens twice, we have created two lists of size 2^(k+1),
  * which will be merged into a list of size 2^(k+2) before we create
  * a third list of size 2^(k+1), so there are never more than two pending.
  *
  * The number of pending lists of size 2^k is determined by the
  * state of bit k of "count" plus two extra pieces of information:
  *
  * - The state of bit k-1 (when k == 0, consider bit -1 always set), and
  * - Whether the higher-order bits are zero or non-zero (i.e.
  *   is count >= 2^(k+1)).
  *
  * There are six states we distinguish.  "x" represents some arbitrary
  * bits, and "y" represents some arbitrary non-zero bits:
  * 0:  00x: 0 pending of size 2^k;           x pending of sizes < 2^k
  * 1:  01x: 0 pending of size 2^k; 2^(k-1) + x pending of sizes < 2^k
  * 2: x10x: 0 pending of size 2^k; 2^k     + x pending of sizes < 2^k
  * 3: x11x: 1 pending of size 2^k; 2^(k-1) + x pending of sizes < 2^k
  * 4: y00x: 1 pending of size 2^k; 2^k     + x pending of sizes < 2^k
  * 5: y01x: 2 pending of size 2^k; 2^(k-1) + x pending of sizes < 2^k
  * (merge and loop back to state 2)
  *
  * We gain lists of size 2^k in the 2->3 and 4->5 transitions (because
  * bit k-1 is set while the more significant bits are non-zero) and
  * merge them away in the 5->2 transition.  Note in particular that just
  * before the 5->2 transition, all lower-order bits are 11 (state 3),
  * so there is one list of each smaller size.
  *
  * When we reach the end of the input, we merge all the pending
  * lists, from smallest to largest.  If you work through cases 2 to
  * 5 above, you can see that the number of elements we merge with a list
  * of size 2^k varies from 2^(k-1) (cases 3 and 5 when x == 0) to
  * 2^(k+1) - 1 (second merge of case 5 when x == 2^(k-1) - 1).
  */
 __attribute__((nonnull(2,3)))
 void list_sort(void *priv, struct list_head *head, list_cmp_func_t cmp)
 {
 	struct list_head *list = head->next, *pending = NULL;
 	size_t count = 0;	/* Count of pending */

 	if (list == head->prev)	/* Zero or one elements */
 		return;

 	/* Convert to a null-terminated singly-linked list. */
 	head->prev->next = NULL;

 	/*
 	 * Data structure invariants:
 	 * - All lists are singly linked and null-terminated; prev
 	 *   pointers are not maintained.
 	 * - pending is a prev-linked "list of lists" of sorted
 	 *   sublists awaiting further merging.
 	 * - Each of the sorted sublists is power-of-two in size.
 	 * - Sublists are sorted by size and age, smallest & newest at front.
 	 * - There are zero to two sublists of each size.
 	 * - A pair of pending sublists are merged as soon as the number
 	 *   of following pending elements equals their size (i.e.
 	 *   each time count reaches an odd multiple of that size).
 	 *   That ensures each later final merge will be at worst 2:1.
 	 * - Each round consists of:
 	 *   - Merging the two sublists selected by the highest bit
 	 *     which flips when count is incremented, and
 	 *   - Adding an element from the input as a size-1 sublist.
 	 */
 	do {
 		size_t bits;
 		struct list_head **tail = &pending;

 		/* Find the least-significant clear bit in count */
 		for (bits = count; bits & 1; bits >>= 1)
 			tail = &(*tail)->prev;
 		/* Do the indicated merge */
 		if (likely(bits)) {
 			struct list_head *a = *tail, *b = a->prev;

 			a = merge(priv, cmp, b, a);
 			/* Install the merged result in place of the inputs */
 			a->prev = b->prev;
 			*tail = a;
 		}

 		/* Move one element from input list to pending */
 		list->prev = pending;
 		pending = list;
 		list = list->next;
 		pending->next = NULL;
 		count++;
 	} while (list);

 	/* End of input; merge together all the pending lists. */
 	list = pending;
 	pending = pending->prev;
 	for (;;) {
 		struct list_head *next = pending->prev;

 		if (!next)
 			break;
 		list = merge(priv, cmp, pending, list);
 		pending = next;
 	}
 	/* The final merge, rebuilding prev links */
 	merge_final(priv, cmp, head, pending, list);
 }
 EXPORT_SYMBOL(list_sort);
	// SPDX-License-Identifier: GPL-2.0
	#include <linux/kernel.h>
	#include <linux/compiler.h>
	#include <linux/export.h>
	#include <linux/string.h>
	#include <linux/list_sort.h>
	#include <linux/list.h>

	/*
	* Returns a list organized in an intermediate format suited
	* to chaining of merge() calls: null-terminated, no reserved or
	* sentinel head node, "prev" links not maintained.
	*/
	__attribute__((nonnull(2,3,4)))
	static struct list_head merge(void priv, list_cmp_func_t cmp,
	struct list_head a, struct list_head b)
	{
	struct list_head head, *tail = &head;

	for (;;) {
	/* if equal, take 'a' -- important for sort stability */
	if (cmp(priv, a, b) <= 0) {
	*tail = a;
	tail = &a->next;
	a = a->next;
	if (!a) {
	*tail = b;
	break;
	}
	} else {
	*tail = b;
	tail = &b->next;
	b = b->next;
	if (!b) {
	*tail = a;
	break;
	}
	}
	}
	return head;
	}

	/*
	* Combine final list merge with restoration of standard doubly-linked
	* list structure. This approach duplicates code from merge(), but
	* runs faster than the tidier alternatives of either a separate final
	* prev-link restoration pass, or maintaining the prev links
	* throughout.
	*/
	__attribute__((nonnull(2,3,4,5)))
	static void merge_final(void priv, list_cmp_func_t cmp, struct list_head head,
	struct list_head a, struct list_head b)
	{
	struct list_head *tail = head;
	u8 count = 0;

	for (;;) {
	/* if equal, take 'a' -- important for sort stability */
	if (cmp(priv, a, b) <= 0) {
	tail->next = a;
	a->prev = tail;
	tail = a;
	a = a->next;
	if (!a)
	break;
	} else {
	tail->next = b;
	b->prev = tail;
	tail = b;
	b = b->next;
	if (!b) {
	b = a;
	break;
	}
	}
	}

	/* Finish linking remainder of list b on to tail */
	tail->next = b;
	do {
	/*
	* If the merge is highly unbalanced (e.g. the input is
	* already sorted), this loop may run many iterations.
	* Continue callbacks to the client even though no
	* element comparison is needed, so the client's cmp()
	* routine can invoke cond_resched() periodically.
	*/
	if (unlikely(!++count))
	cmp(priv, b, b);
	b->prev = tail;
	tail = b;
	b = b->next;
	} while (b);

	/* And the final links to make a circular doubly-linked list */
	tail->next = head;
	head->prev = tail;
	}

	/**
	* list_sort - sort a list
	* @priv: private data, opaque to list_sort(), passed to @cmp
	* @head: the list to sort
	* @cmp: the elements comparison function
	*
	* The comparison function @cmp must return > 0 if @a should sort after
	* @b ("@a > @b" if you want an ascending sort), and <= 0 if @a should
	* sort before @b or their original order should be preserved. It is
	* always called with the element that came first in the input in @a,
	* and list_sort is a stable sort, so it is not necessary to distinguish
	* the @a < @b and @a == @b cases.
	*
	* This is compatible with two styles of @cmp function:
	* - The traditional style which returns <0 / =0 / >0, or
	* - Returning a boolean 0/1.
	* The latter offers a chance to save a few cycles in the comparison
	* (which is used by e.g. plug_ctx_cmp() in block/blk-mq.c).
	*
	* A good way to write a multi-word comparison is::
	*
	* if (a->high != b->high)
	* return a->high > b->high;
	* if (a->middle != b->middle)
	* return a->middle > b->middle;
	* return a->low > b->low;
	*
	*
	* This mergesort is as eager as possible while always performing at least
	* 2:1 balanced merges. Given two pending sublists of size 2^k, they are
	* merged to a size-2^(k+1) list as soon as we have 2^k following elements.
	*
	* Thus, it will avoid cache thrashing as long as 3*2^k elements can
	* fit into the cache. Not quite as good as a fully-eager bottom-up
	* mergesort, but it does use 0.2*n fewer comparisons, so is faster in
	* the common case that everything fits into L1.
	*
	*
	* The merging is controlled by "count", the number of elements in the
	* pending lists. This is beautifully simple code, but rather subtle.
	*
	* Each time we increment "count", we set one bit (bit k) and clear
	* bits k-1 .. 0. Each time this happens (except the very first time
	* for each bit, when count increments to 2^k), we merge two lists of
	* size 2^k into one list of size 2^(k+1).
	*
	* This merge happens exactly when the count reaches an odd multiple of
	* 2^k, which is when we have 2^k elements pending in smaller lists,
	* so it's safe to merge away two lists of size 2^k.
	*
	* After this happens twice, we have created two lists of size 2^(k+1),
	* which will be merged into a list of size 2^(k+2) before we create
	* a third list of size 2^(k+1), so there are never more than two pending.
	*
	* The number of pending lists of size 2^k is determined by the
	* state of bit k of "count" plus two extra pieces of information:
	*
	* - The state of bit k-1 (when k == 0, consider bit -1 always set), and
	* - Whether the higher-order bits are zero or non-zero (i.e.
	* is count >= 2^(k+1)).
	*
	* There are six states we distinguish. "x" represents some arbitrary
	* bits, and "y" represents some arbitrary non-zero bits:
	* 0: 00x: 0 pending of size 2^k; x pending of sizes < 2^k
	* 1: 01x: 0 pending of size 2^k; 2^(k-1) + x pending of sizes < 2^k
	* 2: x10x: 0 pending of size 2^k; 2^k + x pending of sizes < 2^k
	* 3: x11x: 1 pending of size 2^k; 2^(k-1) + x pending of sizes < 2^k
	* 4: y00x: 1 pending of size 2^k; 2^k + x pending of sizes < 2^k
	* 5: y01x: 2 pending of size 2^k; 2^(k-1) + x pending of sizes < 2^k
	* (merge and loop back to state 2)
	*
	* We gain lists of size 2^k in the 2->3 and 4->5 transitions (because
	* bit k-1 is set while the more significant bits are non-zero) and
	* merge them away in the 5->2 transition. Note in particular that just
	* before the 5->2 transition, all lower-order bits are 11 (state 3),
	* so there is one list of each smaller size.
	*
	* When we reach the end of the input, we merge all the pending
	* lists, from smallest to largest. If you work through cases 2 to
	* 5 above, you can see that the number of elements we merge with a list
	* of size 2^k varies from 2^(k-1) (cases 3 and 5 when x == 0) to
	* 2^(k+1) - 1 (second merge of case 5 when x == 2^(k-1) - 1).
	*/
	__attribute__((nonnull(2,3)))
	void list_sort(void priv, struct list_head head, list_cmp_func_t cmp)
	{
	struct list_head list = head->next, pending = NULL;
	size_t count = 0; /* Count of pending */

	if (list == head->prev) /* Zero or one elements */
	return;

	/* Convert to a null-terminated singly-linked list. */
	head->prev->next = NULL;

	/*
	* Data structure invariants:
	* - All lists are singly linked and null-terminated; prev
	* pointers are not maintained.
	* - pending is a prev-linked "list of lists" of sorted
	* sublists awaiting further merging.
	* - Each of the sorted sublists is power-of-two in size.
	* - Sublists are sorted by size and age, smallest & newest at front.
	* - There are zero to two sublists of each size.
	* - A pair of pending sublists are merged as soon as the number
	* of following pending elements equals their size (i.e.
	* each time count reaches an odd multiple of that size).
	* That ensures each later final merge will be at worst 2:1.
	* - Each round consists of:
	* - Merging the two sublists selected by the highest bit
	* which flips when count is incremented, and
	* - Adding an element from the input as a size-1 sublist.
	*/
	do {
	size_t bits;
	struct list_head **tail = &pending;

	/* Find the least-significant clear bit in count */
	for (bits = count; bits & 1; bits >>= 1)
	tail = &(*tail)->prev;
	/* Do the indicated merge */
	if (likely(bits)) {
	struct list_head a = tail, *b = a->prev;

	a = merge(priv, cmp, b, a);
	/* Install the merged result in place of the inputs */
	a->prev = b->prev;
	*tail = a;
	}

	/* Move one element from input list to pending */
	list->prev = pending;
	pending = list;
	list = list->next;
	pending->next = NULL;
	count++;
	} while (list);

	/* End of input; merge together all the pending lists. */
	list = pending;
	pending = pending->prev;
	for (;;) {
	struct list_head *next = pending->prev;

	if (!next)
	break;
	list = merge(priv, cmp, pending, list);
	pending = next;
	}
	/* The final merge, rebuilding prev links */
	merge_final(priv, cmp, head, pending, list);
	}
	EXPORT_SYMBOL(list_sort);