include/linux/rbtree_latch.h - nest-learning-thermostat/5.10/linux-imx-4.9.88 - Git at Google

 /*
  * Latched RB-trees
  *
  * Copyright (C) 2015 Intel Corp., Peter Zijlstra <peterz@infradead.org>
  *
  * Since RB-trees have non-atomic modifications they're not immediately suited
  * for RCU/lockless queries. Even though we made RB-tree lookups non-fatal for
  * lockless lookups; we cannot guarantee they return a correct result.
  *
  * The simplest solution is a seqlock + RB-tree, this will allow lockless
  * lookups; but has the constraint (inherent to the seqlock) that read sides
  * cannot nest in write sides.
  *
  * If we need to allow unconditional lookups (say as required for NMI context
  * usage) we need a more complex setup; this data structure provides this by
  * employing the latch technique -- see @raw_write_seqcount_latch -- to
  * implement a latched RB-tree which does allow for unconditional lookups by
  * virtue of always having (at least) one stable copy of the tree.
  *
  * However, while we have the guarantee that there is at all times one stable
  * copy, this does not guarantee an iteration will not observe modifications.
  * What might have been a stable copy at the start of the iteration, need not
  * remain so for the duration of the iteration.
  *
  * Therefore, this does require a lockless RB-tree iteration to be non-fatal;
  * see the comment in lib/rbtree.c. Note however that we only require the first
  * condition -- not seeing partial stores -- because the latch thing isolates
  * us from loops. If we were to interrupt a modification the lookup would be
  * pointed at the stable tree and complete while the modification was halted.
  */

 #ifndef RB_TREE_LATCH_H
 #define RB_TREE_LATCH_H

 #include <linux/rbtree.h>
 #include <linux/seqlock.h>

 struct latch_tree_node {
 	struct rb_node node[2];
 };

 struct latch_tree_root {
 	seqcount_t	seq;
 	struct rb_root	tree[2];
 };

 /**
  * latch_tree_ops - operators to define the tree order
  * @less: used for insertion; provides the (partial) order between two elements.
  * @comp: used for lookups; provides the order between the search key and an element.
  *
  * The operators are related like:
  *
  *	comp(a->key,b) < 0  := less(a,b)
  *	comp(a->key,b) > 0  := less(b,a)
  *	comp(a->key,b) == 0 := !less(a,b) && !less(b,a)
  *
  * If these operators define a partial order on the elements we make no
  * guarantee on which of the elements matching the key is found. See
  * latch_tree_find().
  */
 struct latch_tree_ops {
 	bool (*less)(struct latch_tree_node *a, struct latch_tree_node *b);
 	int  (*comp)(void *key,                 struct latch_tree_node *b);
 };

 static __always_inline struct latch_tree_node *
 __lt_from_rb(struct rb_node *node, int idx)
 {
 	return container_of(node, struct latch_tree_node, node[idx]);
 }

 static __always_inline void
 __lt_insert(struct latch_tree_node *ltn, struct latch_tree_root *ltr, int idx,
 	    bool (*less)(struct latch_tree_node *a, struct latch_tree_node *b))
 {
 	struct rb_root *root = &ltr->tree[idx];
 	struct rb_node **link = &root->rb_node;
 	struct rb_node *node = &ltn->node[idx];
 	struct rb_node *parent = NULL;
 	struct latch_tree_node *ltp;

 	while (*link) {
 		parent = *link;
 		ltp = __lt_from_rb(parent, idx);

 		if (less(ltn, ltp))
 			link = &parent->rb_left;
 		else
 			link = &parent->rb_right;
 	}

 	rb_link_node_rcu(node, parent, link);
 	rb_insert_color(node, root);
 }

 static __always_inline void
 __lt_erase(struct latch_tree_node *ltn, struct latch_tree_root *ltr, int idx)
 {
 	rb_erase(&ltn->node[idx], &ltr->tree[idx]);
 }

 static __always_inline struct latch_tree_node *
 __lt_find(void *key, struct latch_tree_root *ltr, int idx,
 	  int (*comp)(void *key, struct latch_tree_node *node))
 {
 	struct rb_node *node = rcu_dereference_raw(ltr->tree[idx].rb_node);
 	struct latch_tree_node *ltn;
 	int c;

 	while (node) {
 		ltn = __lt_from_rb(node, idx);
 		c = comp(key, ltn);

 		if (c < 0)
 			node = rcu_dereference_raw(node->rb_left);
 		else if (c > 0)
 			node = rcu_dereference_raw(node->rb_right);
 		else
 			return ltn;
 	}

 	return NULL;
 }

 /**
  * latch_tree_insert() - insert @node into the trees @root
  * @node: nodes to insert
  * @root: trees to insert @node into
  * @ops: operators defining the node order
  *
  * It inserts @node into @root in an ordered fashion such that we can always
  * observe one complete tree. See the comment for raw_write_seqcount_latch().
  *
  * The inserts use rcu_assign_pointer() to publish the element such that the
  * tree structure is stored before we can observe the new @node.
  *
  * All modifications (latch_tree_insert, latch_tree_remove) are assumed to be
  * serialized.
  */
 static __always_inline void
 latch_tree_insert(struct latch_tree_node *node,
 		  struct latch_tree_root *root,
 		  const struct latch_tree_ops *ops)
 {
 	raw_write_seqcount_latch(&root->seq);
 	__lt_insert(node, root, 0, ops->less);
 	raw_write_seqcount_latch(&root->seq);
 	__lt_insert(node, root, 1, ops->less);
 }

 /**
  * latch_tree_erase() - removes @node from the trees @root
  * @node: nodes to remote
  * @root: trees to remove @node from
  * @ops: operators defining the node order
  *
  * Removes @node from the trees @root in an ordered fashion such that we can
  * always observe one complete tree. See the comment for
  * raw_write_seqcount_latch().
  *
  * It is assumed that @node will observe one RCU quiescent state before being
  * reused of freed.
  *
  * All modifications (latch_tree_insert, latch_tree_remove) are assumed to be
  * serialized.
  */
 static __always_inline void
 latch_tree_erase(struct latch_tree_node *node,
 		 struct latch_tree_root *root,
 		 const struct latch_tree_ops *ops)
 {
 	raw_write_seqcount_latch(&root->seq);
 	__lt_erase(node, root, 0);
 	raw_write_seqcount_latch(&root->seq);
 	__lt_erase(node, root, 1);
 }

 /**
  * latch_tree_find() - find the node matching @key in the trees @root
  * @key: search key
  * @root: trees to search for @key
  * @ops: operators defining the node order
  *
  * Does a lockless lookup in the trees @root for the node matching @key.
  *
  * It is assumed that this is called while holding the appropriate RCU read
  * side lock.
  *
  * If the operators define a partial order on the elements (there are multiple
  * elements which have the same key value) it is undefined which of these
  * elements will be found. Nor is it possible to iterate the tree to find
  * further elements with the same key value.
  *
  * Returns: a pointer to the node matching @key or NULL.
  */
 static __always_inline struct latch_tree_node *
 latch_tree_find(void *key, struct latch_tree_root *root,
 		const struct latch_tree_ops *ops)
 {
 	struct latch_tree_node *node;
 	unsigned int seq;

 	do {
 		seq = raw_read_seqcount_latch(&root->seq);
 		node = __lt_find(key, root, seq & 1, ops->comp);
 	} while (read_seqcount_retry(&root->seq, seq));

 	return node;
 }

 #endif /* RB_TREE_LATCH_H */
	/*
	* Latched RB-trees
	*
	* Copyright (C) 2015 Intel Corp., Peter Zijlstra <peterz@infradead.org>
	*
	* Since RB-trees have non-atomic modifications they're not immediately suited
	* for RCU/lockless queries. Even though we made RB-tree lookups non-fatal for
	* lockless lookups; we cannot guarantee they return a correct result.
	*
	* The simplest solution is a seqlock + RB-tree, this will allow lockless
	* lookups; but has the constraint (inherent to the seqlock) that read sides
	* cannot nest in write sides.
	*
	* If we need to allow unconditional lookups (say as required for NMI context
	* usage) we need a more complex setup; this data structure provides this by
	* employing the latch technique -- see @raw_write_seqcount_latch -- to
	* implement a latched RB-tree which does allow for unconditional lookups by
	* virtue of always having (at least) one stable copy of the tree.
	*
	* However, while we have the guarantee that there is at all times one stable
	* copy, this does not guarantee an iteration will not observe modifications.
	* What might have been a stable copy at the start of the iteration, need not
	* remain so for the duration of the iteration.
	*
	* Therefore, this does require a lockless RB-tree iteration to be non-fatal;
	* see the comment in lib/rbtree.c. Note however that we only require the first
	* condition -- not seeing partial stores -- because the latch thing isolates
	* us from loops. If we were to interrupt a modification the lookup would be
	* pointed at the stable tree and complete while the modification was halted.
	*/

	#ifndef RB_TREE_LATCH_H
	#define RB_TREE_LATCH_H

	#include <linux/rbtree.h>
	#include <linux/seqlock.h>

	struct latch_tree_node {
	struct rb_node node[2];
	};

	struct latch_tree_root {
	seqcount_t seq;
	struct rb_root tree[2];
	};

	/**
	* latch_tree_ops - operators to define the tree order
	* @less: used for insertion; provides the (partial) order between two elements.
	* @comp: used for lookups; provides the order between the search key and an element.
	*
	* The operators are related like:
	*
	* comp(a->key,b) < 0 := less(a,b)
	* comp(a->key,b) > 0 := less(b,a)
	* comp(a->key,b) == 0 := !less(a,b) && !less(b,a)
	*
	* If these operators define a partial order on the elements we make no
	* guarantee on which of the elements matching the key is found. See
	* latch_tree_find().
	*/
	struct latch_tree_ops {
	bool (less)(struct latch_tree_node a, struct latch_tree_node *b);
	int (comp)(void key, struct latch_tree_node *b);
	};

	static __always_inline struct latch_tree_node *
	__lt_from_rb(struct rb_node *node, int idx)
	{
	return container_of(node, struct latch_tree_node, node[idx]);
	}

	static __always_inline void
	__lt_insert(struct latch_tree_node ltn, struct latch_tree_root ltr, int idx,
	bool (less)(struct latch_tree_node a, struct latch_tree_node *b))
	{
	struct rb_root *root = &ltr->tree[idx];
	struct rb_node **link = &root->rb_node;
	struct rb_node *node = &ltn->node[idx];
	struct rb_node *parent = NULL;
	struct latch_tree_node *ltp;

	while (*link) {
	parent = *link;
	ltp = __lt_from_rb(parent, idx);

	if (less(ltn, ltp))
	link = &parent->rb_left;
	else
	link = &parent->rb_right;
	}

	rb_link_node_rcu(node, parent, link);
	rb_insert_color(node, root);
	}

	static __always_inline void
	__lt_erase(struct latch_tree_node ltn, struct latch_tree_root ltr, int idx)
	{
	rb_erase(&ltn->node[idx], &ltr->tree[idx]);
	}

	static __always_inline struct latch_tree_node *
	__lt_find(void key, struct latch_tree_root ltr, int idx,
	int (comp)(void key, struct latch_tree_node *node))
	{
	struct rb_node *node = rcu_dereference_raw(ltr->tree[idx].rb_node);
	struct latch_tree_node *ltn;
	int c;

	while (node) {
	ltn = __lt_from_rb(node, idx);
	c = comp(key, ltn);

	if (c < 0)
	node = rcu_dereference_raw(node->rb_left);
	else if (c > 0)
	node = rcu_dereference_raw(node->rb_right);
	else
	return ltn;
	}

	return NULL;
	}

	/**
	* latch_tree_insert() - insert @node into the trees @root
	* @node: nodes to insert
	* @root: trees to insert @node into
	* @ops: operators defining the node order
	*
	* It inserts @node into @root in an ordered fashion such that we can always
	* observe one complete tree. See the comment for raw_write_seqcount_latch().
	*
	* The inserts use rcu_assign_pointer() to publish the element such that the
	* tree structure is stored before we can observe the new @node.
	*
	* All modifications (latch_tree_insert, latch_tree_remove) are assumed to be
	* serialized.
	*/
	static __always_inline void
	latch_tree_insert(struct latch_tree_node *node,
	struct latch_tree_root *root,
	const struct latch_tree_ops *ops)
	{
	raw_write_seqcount_latch(&root->seq);
	__lt_insert(node, root, 0, ops->less);
	raw_write_seqcount_latch(&root->seq);
	__lt_insert(node, root, 1, ops->less);
	}

	/**
	* latch_tree_erase() - removes @node from the trees @root
	* @node: nodes to remote
	* @root: trees to remove @node from
	* @ops: operators defining the node order
	*
	* Removes @node from the trees @root in an ordered fashion such that we can
	* always observe one complete tree. See the comment for
	* raw_write_seqcount_latch().
	*
	* It is assumed that @node will observe one RCU quiescent state before being
	* reused of freed.
	*
	* All modifications (latch_tree_insert, latch_tree_remove) are assumed to be
	* serialized.
	*/
	static __always_inline void
	latch_tree_erase(struct latch_tree_node *node,
	struct latch_tree_root *root,
	const struct latch_tree_ops *ops)
	{
	raw_write_seqcount_latch(&root->seq);
	__lt_erase(node, root, 0);
	raw_write_seqcount_latch(&root->seq);
	__lt_erase(node, root, 1);
	}

	/**
	* latch_tree_find() - find the node matching @key in the trees @root
	* @key: search key
	* @root: trees to search for @key
	* @ops: operators defining the node order
	*
	* Does a lockless lookup in the trees @root for the node matching @key.
	*
	* It is assumed that this is called while holding the appropriate RCU read
	* side lock.
	*
	* If the operators define a partial order on the elements (there are multiple
	* elements which have the same key value) it is undefined which of these
	* elements will be found. Nor is it possible to iterate the tree to find
	* further elements with the same key value.
	*
	* Returns: a pointer to the node matching @key or NULL.
	*/
	static __always_inline struct latch_tree_node *
	latch_tree_find(void key, struct latch_tree_root root,
	const struct latch_tree_ops *ops)
	{
	struct latch_tree_node *node;
	unsigned int seq;

	do {
	seq = raw_read_seqcount_latch(&root->seq);
	node = __lt_find(key, root, seq & 1, ops->comp);
	} while (read_seqcount_retry(&root->seq, seq));

	return node;
	}

	#endif /* RB_TREE_LATCH_H */