drivers/md/bcache/btree.h - linux/kernel/git/viro/vfs - Git at Google

 #ifndef _BCACHE_BTREE_H
 #define _BCACHE_BTREE_H

 /*
  * THE BTREE:
  *
  * At a high level, bcache's btree is relatively standard b+ tree. All keys and
  * pointers are in the leaves; interior nodes only have pointers to the child
  * nodes.
  *
  * In the interior nodes, a struct bkey always points to a child btree node, and
  * the key is the highest key in the child node - except that the highest key in
  * an interior node is always MAX_KEY. The size field refers to the size on disk
  * of the child node - this would allow us to have variable sized btree nodes
  * (handy for keeping the depth of the btree 1 by expanding just the root).
  *
  * Btree nodes are themselves log structured, but this is hidden fairly
  * thoroughly. Btree nodes on disk will in practice have extents that overlap
  * (because they were written at different times), but in memory we never have
  * overlapping extents - when we read in a btree node from disk, the first thing
  * we do is resort all the sets of keys with a mergesort, and in the same pass
  * we check for overlapping extents and adjust them appropriately.
  *
  * struct btree_op is a central interface to the btree code. It's used for
  * specifying read vs. write locking, and the embedded closure is used for
  * waiting on IO or reserve memory.
  *
  * BTREE CACHE:
  *
  * Btree nodes are cached in memory; traversing the btree might require reading
  * in btree nodes which is handled mostly transparently.
  *
  * bch_btree_node_get() looks up a btree node in the cache and reads it in from
  * disk if necessary. This function is almost never called directly though - the
  * btree() macro is used to get a btree node, call some function on it, and
  * unlock the node after the function returns.
  *
  * The root is special cased - it's taken out of the cache's lru (thus pinning
  * it in memory), so we can find the root of the btree by just dereferencing a
  * pointer instead of looking it up in the cache. This makes locking a bit
  * tricky, since the root pointer is protected by the lock in the btree node it
  * points to - the btree_root() macro handles this.
  *
  * In various places we must be able to allocate memory for multiple btree nodes
  * in order to make forward progress. To do this we use the btree cache itself
  * as a reserve; if __get_free_pages() fails, we'll find a node in the btree
  * cache we can reuse. We can't allow more than one thread to be doing this at a
  * time, so there's a lock, implemented by a pointer to the btree_op closure -
  * this allows the btree_root() macro to implicitly release this lock.
  *
  * BTREE IO:
  *
  * Btree nodes never have to be explicitly read in; bch_btree_node_get() handles
  * this.
  *
  * For writing, we have two btree_write structs embeddded in struct btree - one
  * write in flight, and one being set up, and we toggle between them.
  *
  * Writing is done with a single function -  bch_btree_write() really serves two
  * different purposes and should be broken up into two different functions. When
  * passing now = false, it merely indicates that the node is now dirty - calling
  * it ensures that the dirty keys will be written at some point in the future.
  *
  * When passing now = true, bch_btree_write() causes a write to happen
  * "immediately" (if there was already a write in flight, it'll cause the write
  * to happen as soon as the previous write completes). It returns immediately
  * though - but it takes a refcount on the closure in struct btree_op you passed
  * to it, so a closure_sync() later can be used to wait for the write to
  * complete.
  *
  * This is handy because btree_split() and garbage collection can issue writes
  * in parallel, reducing the amount of time they have to hold write locks.
  *
  * LOCKING:
  *
  * When traversing the btree, we may need write locks starting at some level -
  * inserting a key into the btree will typically only require a write lock on
  * the leaf node.
  *
  * This is specified with the lock field in struct btree_op; lock = 0 means we
  * take write locks at level <= 0, i.e. only leaf nodes. bch_btree_node_get()
  * checks this field and returns the node with the appropriate lock held.
  *
  * If, after traversing the btree, the insertion code discovers it has to split
  * then it must restart from the root and take new locks - to do this it changes
  * the lock field and returns -EINTR, which causes the btree_root() macro to
  * loop.
  *
  * Handling cache misses require a different mechanism for upgrading to a write
  * lock. We do cache lookups with only a read lock held, but if we get a cache
  * miss and we wish to insert this data into the cache, we have to insert a
  * placeholder key to detect races - otherwise, we could race with a write and
  * overwrite the data that was just written to the cache with stale data from
  * the backing device.
  *
  * For this we use a sequence number that write locks and unlocks increment - to
  * insert the check key it unlocks the btree node and then takes a write lock,
  * and fails if the sequence number doesn't match.
  */

 #include "bset.h"
 #include "debug.h"

 struct btree_write {
 	atomic_t		*journal;

 	/* If btree_split() frees a btree node, it writes a new pointer to that
 	 * btree node indicating it was freed; it takes a refcount on
 	 * c->prio_blocked because we can't write the gens until the new
 	 * pointer is on disk. This allows btree_write_endio() to release the
 	 * refcount that btree_split() took.
 	 */
 	int			prio_blocked;
 };

 struct btree {
 	/* Hottest entries first */
 	struct hlist_node	hash;

 	/* Key/pointer for this btree node */
 	BKEY_PADDED(key);

 	/* Single bit - set when accessed, cleared by shrinker */
 	unsigned long		accessed;
 	unsigned long		seq;
 	struct rw_semaphore	lock;
 	struct cache_set	*c;

 	unsigned long		flags;
 	uint16_t		written;	/* would be nice to kill */
 	uint8_t			level;
 	uint8_t			nsets;
 	uint8_t			page_order;

 	/*
 	 * Set of sorted keys - the real btree node - plus a binary search tree
 	 *
 	 * sets[0] is special; set[0]->tree, set[0]->prev and set[0]->data point
 	 * to the memory we have allocated for this btree node. Additionally,
 	 * set[0]->data points to the entire btree node as it exists on disk.
 	 */
 	struct bset_tree	sets[MAX_BSETS];

 	/* For outstanding btree writes, used as a lock - protects write_idx */
 	struct closure_with_waitlist	io;

 	struct list_head	list;
 	struct delayed_work	work;

 	struct btree_write	writes[2];
 	struct bio		*bio;
 };

 #define BTREE_FLAG(flag)						\
 static inline bool btree_node_ ## flag(struct btree *b)			\
 {	return test_bit(BTREE_NODE_ ## flag, &b->flags); }		\
 									\
 static inline void set_btree_node_ ## flag(struct btree *b)		\
 {	set_bit(BTREE_NODE_ ## flag, &b->flags); }			\

 enum btree_flags {
 	BTREE_NODE_io_error,
 	BTREE_NODE_dirty,
 	BTREE_NODE_write_idx,
 };

 BTREE_FLAG(io_error);
 BTREE_FLAG(dirty);
 BTREE_FLAG(write_idx);

 static inline struct btree_write *btree_current_write(struct btree *b)
 {
 	return b->writes + btree_node_write_idx(b);
 }

 static inline struct btree_write *btree_prev_write(struct btree *b)
 {
 	return b->writes + (btree_node_write_idx(b) ^ 1);
 }

 static inline unsigned bset_offset(struct btree *b, struct bset *i)
 {
 	return (((size_t) i) - ((size_t) b->sets->data)) >> 9;
 }

 static inline struct bset *write_block(struct btree *b)
 {
 	return ((void *) b->sets[0].data) + b->written * block_bytes(b->c);
 }

 static inline bool bset_written(struct btree *b, struct bset_tree *t)
 {
 	return t->data < write_block(b);
 }

 static inline bool bkey_written(struct btree *b, struct bkey *k)
 {
 	return k < write_block(b)->start;
 }

 static inline void set_gc_sectors(struct cache_set *c)
 {
 	atomic_set(&c->sectors_to_gc, c->sb.bucket_size * c->nbuckets / 8);
 }

 static inline bool bch_ptr_invalid(struct btree *b, const struct bkey *k)
 {
 	return __bch_ptr_invalid(b->c, b->level, k);
 }

 static inline struct bkey *bch_btree_iter_init(struct btree *b,
 					       struct btree_iter *iter,
 					       struct bkey *search)
 {
 	return __bch_btree_iter_init(b, iter, search, b->sets);
 }

 /* Looping macros */

 #define for_each_cached_btree(b, c, iter)				\
 	for (iter = 0;							\
 	     iter < ARRAY_SIZE((c)->bucket_hash);			\
 	     iter++)							\
 		hlist_for_each_entry_rcu((b), (c)->bucket_hash + iter, hash)

 #define for_each_key_filter(b, k, iter, filter)				\
 	for (bch_btree_iter_init((b), (iter), NULL);			\
 	     ((k) = bch_btree_iter_next_filter((iter), b, filter));)

 #define for_each_key(b, k, iter)					\
 	for (bch_btree_iter_init((b), (iter), NULL);			\
 	     ((k) = bch_btree_iter_next(iter));)

 /* Recursing down the btree */

 struct btree_op {
 	struct closure		cl;
 	struct cache_set	*c;

 	/* Journal entry we have a refcount on */
 	atomic_t		*journal;

 	/* Bio to be inserted into the cache */
 	struct bio		*cache_bio;

 	unsigned		inode;

 	uint16_t		write_prio;

 	/* Btree level at which we start taking write locks */
 	short			lock;

 	/* Btree insertion type */
 	enum {
 		BTREE_INSERT,
 		BTREE_REPLACE
 	} type:8;

 	unsigned		csum:1;
 	unsigned		skip:1;
 	unsigned		flush_journal:1;

 	unsigned		insert_data_done:1;
 	unsigned		lookup_done:1;
 	unsigned		insert_collision:1;

 	/* Anything after this point won't get zeroed in do_bio_hook() */

 	/* Keys to be inserted */
 	struct keylist		keys;
 	BKEY_PADDED(replace);
 };

 enum {
 	BTREE_INSERT_STATUS_INSERT,
 	BTREE_INSERT_STATUS_BACK_MERGE,
 	BTREE_INSERT_STATUS_OVERWROTE,
 	BTREE_INSERT_STATUS_FRONT_MERGE,
 };

 void bch_btree_op_init_stack(struct btree_op *);

 static inline void rw_lock(bool w, struct btree *b, int level)
 {
 	w ? down_write_nested(&b->lock, level + 1)
 	  : down_read_nested(&b->lock, level + 1);
 	if (w)
 		b->seq++;
 }

 static inline void rw_unlock(bool w, struct btree *b)
 {
 #ifdef CONFIG_BCACHE_EDEBUG
 	unsigned i;

 	if (w && b->key.ptr[0])
 		for (i = 0; i <= b->nsets; i++)
 			bch_check_key_order(b, b->sets[i].data);
 #endif

 	if (w)
 		b->seq++;
 	(w ? up_write : up_read)(&b->lock);
 }

 #define insert_lock(s, b)	((b)->level <= (s)->lock)

 /*
  * These macros are for recursing down the btree - they handle the details of
  * locking and looking up nodes in the cache for you. They're best treated as
  * mere syntax when reading code that uses them.
  *
  * op->lock determines whether we take a read or a write lock at a given depth.
  * If you've got a read lock and find that you need a write lock (i.e. you're
  * going to have to split), set op->lock and return -EINTR; btree_root() will
  * call you again and you'll have the correct lock.
  */

 /**
  * btree - recurse down the btree on a specified key
  * @fn:		function to call, which will be passed the child node
  * @key:	key to recurse on
  * @b:		parent btree node
  * @op:		pointer to struct btree_op
  */
 #define btree(fn, key, b, op, ...)					\
 ({									\
 	int _r, l = (b)->level - 1;					\
 	bool _w = l <= (op)->lock;					\
 	struct btree *_b = bch_btree_node_get((b)->c, key, l, op);	\
 	if (!IS_ERR(_b)) {						\
 		_r = bch_btree_ ## fn(_b, op, ##__VA_ARGS__);		\
 		rw_unlock(_w, _b);					\
 	} else								\
 		_r = PTR_ERR(_b);					\
 	_r;								\
 })

 /**
  * btree_root - call a function on the root of the btree
  * @fn:		function to call, which will be passed the child node
  * @c:		cache set
  * @op:		pointer to struct btree_op
  */
 #define btree_root(fn, c, op, ...)					\
 ({									\
 	int _r = -EINTR;						\
 	do {								\
 		struct btree *_b = (c)->root;				\
 		bool _w = insert_lock(op, _b);				\
 		rw_lock(_w, _b, _b->level);				\
 		if (_b == (c)->root &&					\
 		    _w == insert_lock(op, _b))				\
 			_r = bch_btree_ ## fn(_b, op, ##__VA_ARGS__);	\
 		rw_unlock(_w, _b);					\
 		bch_cannibalize_unlock(c, &(op)->cl);		\
 	} while (_r == -EINTR);						\
 									\
 	_r;								\
 })

 static inline bool should_split(struct btree *b)
 {
 	struct bset *i = write_block(b);
 	return b->written >= btree_blocks(b) ||
 		(i->seq == b->sets[0].data->seq &&
 		 b->written + __set_blocks(i, i->keys + 15, b->c)
 		 > btree_blocks(b));
 }

 void bch_btree_node_read(struct btree *);
 void bch_btree_node_write(struct btree *, struct closure *);

 void bch_cannibalize_unlock(struct cache_set *, struct closure *);
 void bch_btree_set_root(struct btree *);
 struct btree *bch_btree_node_alloc(struct cache_set *, int, struct closure *);
 struct btree *bch_btree_node_get(struct cache_set *, struct bkey *,
 				int, struct btree_op *);

 bool bch_btree_insert_check_key(struct btree *, struct btree_op *,
 				   struct bio *);
 int bch_btree_insert(struct btree_op *, struct cache_set *);

 int bch_btree_search_recurse(struct btree *, struct btree_op *);

 void bch_queue_gc(struct cache_set *);
 size_t bch_btree_gc_finish(struct cache_set *);
 void bch_moving_gc(struct closure *);
 int bch_btree_check(struct cache_set *, struct btree_op *);
 uint8_t __bch_btree_mark_key(struct cache_set *, int, struct bkey *);

 void bch_keybuf_init(struct keybuf *);
 void bch_refill_keybuf(struct cache_set *, struct keybuf *, struct bkey *,
 		       keybuf_pred_fn *);
 bool bch_keybuf_check_overlapping(struct keybuf *, struct bkey *,
 				  struct bkey *);
 void bch_keybuf_del(struct keybuf *, struct keybuf_key *);
 struct keybuf_key *bch_keybuf_next(struct keybuf *);
 struct keybuf_key *bch_keybuf_next_rescan(struct cache_set *, struct keybuf *,
 					  struct bkey *, keybuf_pred_fn *);

 #endif
	#ifndef _BCACHE_BTREE_H
	#define _BCACHE_BTREE_H

	/*
	* THE BTREE:
	*
	* At a high level, bcache's btree is relatively standard b+ tree. All keys and
	* pointers are in the leaves; interior nodes only have pointers to the child
	* nodes.
	*
	* In the interior nodes, a struct bkey always points to a child btree node, and
	* the key is the highest key in the child node - except that the highest key in
	* an interior node is always MAX_KEY. The size field refers to the size on disk
	* of the child node - this would allow us to have variable sized btree nodes
	* (handy for keeping the depth of the btree 1 by expanding just the root).
	*
	* Btree nodes are themselves log structured, but this is hidden fairly
	* thoroughly. Btree nodes on disk will in practice have extents that overlap
	* (because they were written at different times), but in memory we never have
	* overlapping extents - when we read in a btree node from disk, the first thing
	* we do is resort all the sets of keys with a mergesort, and in the same pass
	* we check for overlapping extents and adjust them appropriately.
	*
	* struct btree_op is a central interface to the btree code. It's used for
	* specifying read vs. write locking, and the embedded closure is used for
	* waiting on IO or reserve memory.
	*
	* BTREE CACHE:
	*
	* Btree nodes are cached in memory; traversing the btree might require reading
	* in btree nodes which is handled mostly transparently.
	*
	* bch_btree_node_get() looks up a btree node in the cache and reads it in from
	* disk if necessary. This function is almost never called directly though - the
	* btree() macro is used to get a btree node, call some function on it, and
	* unlock the node after the function returns.
	*
	* The root is special cased - it's taken out of the cache's lru (thus pinning
	* it in memory), so we can find the root of the btree by just dereferencing a
	* pointer instead of looking it up in the cache. This makes locking a bit
	* tricky, since the root pointer is protected by the lock in the btree node it
	* points to - the btree_root() macro handles this.
	*
	* In various places we must be able to allocate memory for multiple btree nodes
	* in order to make forward progress. To do this we use the btree cache itself
	* as a reserve; if __get_free_pages() fails, we'll find a node in the btree
	* cache we can reuse. We can't allow more than one thread to be doing this at a
	* time, so there's a lock, implemented by a pointer to the btree_op closure -
	* this allows the btree_root() macro to implicitly release this lock.
	*
	* BTREE IO:
	*
	* Btree nodes never have to be explicitly read in; bch_btree_node_get() handles
	* this.
	*
	* For writing, we have two btree_write structs embeddded in struct btree - one
	* write in flight, and one being set up, and we toggle between them.
	*
	* Writing is done with a single function - bch_btree_write() really serves two
	* different purposes and should be broken up into two different functions. When
	* passing now = false, it merely indicates that the node is now dirty - calling
	* it ensures that the dirty keys will be written at some point in the future.
	*
	* When passing now = true, bch_btree_write() causes a write to happen
	* "immediately" (if there was already a write in flight, it'll cause the write
	* to happen as soon as the previous write completes). It returns immediately
	* though - but it takes a refcount on the closure in struct btree_op you passed
	* to it, so a closure_sync() later can be used to wait for the write to
	* complete.
	*
	* This is handy because btree_split() and garbage collection can issue writes
	* in parallel, reducing the amount of time they have to hold write locks.
	*
	* LOCKING:
	*
	* When traversing the btree, we may need write locks starting at some level -
	* inserting a key into the btree will typically only require a write lock on
	* the leaf node.
	*
	* This is specified with the lock field in struct btree_op; lock = 0 means we
	* take write locks at level <= 0, i.e. only leaf nodes. bch_btree_node_get()
	* checks this field and returns the node with the appropriate lock held.
	*
	* If, after traversing the btree, the insertion code discovers it has to split
	* then it must restart from the root and take new locks - to do this it changes
	* the lock field and returns -EINTR, which causes the btree_root() macro to
	* loop.
	*
	* Handling cache misses require a different mechanism for upgrading to a write
	* lock. We do cache lookups with only a read lock held, but if we get a cache
	* miss and we wish to insert this data into the cache, we have to insert a
	* placeholder key to detect races - otherwise, we could race with a write and
	* overwrite the data that was just written to the cache with stale data from
	* the backing device.
	*
	* For this we use a sequence number that write locks and unlocks increment - to
	* insert the check key it unlocks the btree node and then takes a write lock,
	* and fails if the sequence number doesn't match.
	*/

	#include "bset.h"
	#include "debug.h"

	struct btree_write {
	atomic_t *journal;

	/* If btree_split() frees a btree node, it writes a new pointer to that
	* btree node indicating it was freed; it takes a refcount on
	* c->prio_blocked because we can't write the gens until the new
	* pointer is on disk. This allows btree_write_endio() to release the
	* refcount that btree_split() took.
	*/
	int prio_blocked;
	};

	struct btree {
	/* Hottest entries first */
	struct hlist_node hash;

	/* Key/pointer for this btree node */
	BKEY_PADDED(key);

	/* Single bit - set when accessed, cleared by shrinker */
	unsigned long accessed;
	unsigned long seq;
	struct rw_semaphore lock;
	struct cache_set *c;

	unsigned long flags;
	uint16_t written; /* would be nice to kill */
	uint8_t level;
	uint8_t nsets;
	uint8_t page_order;

	/*
	* Set of sorted keys - the real btree node - plus a binary search tree
	*
	* sets[0] is special; set[0]->tree, set[0]->prev and set[0]->data point
	* to the memory we have allocated for this btree node. Additionally,
	* set[0]->data points to the entire btree node as it exists on disk.
	*/
	struct bset_tree sets[MAX_BSETS];

	/* For outstanding btree writes, used as a lock - protects write_idx */
	struct closure_with_waitlist io;

	struct list_head list;
	struct delayed_work work;

	struct btree_write writes[2];
	struct bio *bio;
	};

	#define BTREE_FLAG(flag) \
	static inline bool btree_node_ ## flag(struct btree *b) \
	{ return test_bit(BTREE_NODE_ ## flag, &b->flags); } \
	\
	static inline void set_btree_node_ ## flag(struct btree *b) \
	{ set_bit(BTREE_NODE_ ## flag, &b->flags); } \

	enum btree_flags {
	BTREE_NODE_io_error,
	BTREE_NODE_dirty,
	BTREE_NODE_write_idx,
	};

	BTREE_FLAG(io_error);
	BTREE_FLAG(dirty);
	BTREE_FLAG(write_idx);

	static inline struct btree_write btree_current_write(struct btree b)
	{
	return b->writes + btree_node_write_idx(b);
	}

	static inline struct btree_write btree_prev_write(struct btree b)
	{
	return b->writes + (btree_node_write_idx(b) ^ 1);
	}

	static inline unsigned bset_offset(struct btree b, struct bset i)
	{
	return (((size_t) i) - ((size_t) b->sets->data)) >> 9;
	}

	static inline struct bset write_block(struct btree b)
	{
	return ((void ) b->sets[0].data) + b->written block_bytes(b->c);
	}

	static inline bool bset_written(struct btree b, struct bset_tree t)
	{
	return t->data < write_block(b);
	}

	static inline bool bkey_written(struct btree b, struct bkey k)
	{
	return k < write_block(b)->start;
	}

	static inline void set_gc_sectors(struct cache_set *c)
	{
	atomic_set(&c->sectors_to_gc, c->sb.bucket_size * c->nbuckets / 8);
	}

	static inline bool bch_ptr_invalid(struct btree b, const struct bkey k)
	{
	return __bch_ptr_invalid(b->c, b->level, k);
	}

	static inline struct bkey bch_btree_iter_init(struct btree b,
	struct btree_iter *iter,
	struct bkey *search)
	{
	return __bch_btree_iter_init(b, iter, search, b->sets);
	}

	/* Looping macros */

	#define for_each_cached_btree(b, c, iter) \
	for (iter = 0; \
	iter < ARRAY_SIZE((c)->bucket_hash); \
	iter++) \
	hlist_for_each_entry_rcu((b), (c)->bucket_hash + iter, hash)

	#define for_each_key_filter(b, k, iter, filter) \
	for (bch_btree_iter_init((b), (iter), NULL); \
	((k) = bch_btree_iter_next_filter((iter), b, filter));)

	#define for_each_key(b, k, iter) \
	for (bch_btree_iter_init((b), (iter), NULL); \
	((k) = bch_btree_iter_next(iter));)

	/* Recursing down the btree */

	struct btree_op {
	struct closure cl;
	struct cache_set *c;

	/* Journal entry we have a refcount on */
	atomic_t *journal;

	/* Bio to be inserted into the cache */
	struct bio *cache_bio;

	unsigned inode;

	uint16_t write_prio;

	/* Btree level at which we start taking write locks */
	short lock;

	/* Btree insertion type */
	enum {
	BTREE_INSERT,
	BTREE_REPLACE
	} type:8;

	unsigned csum:1;
	unsigned skip:1;
	unsigned flush_journal:1;

	unsigned insert_data_done:1;
	unsigned lookup_done:1;
	unsigned insert_collision:1;

	/* Anything after this point won't get zeroed in do_bio_hook() */

	/* Keys to be inserted */
	struct keylist keys;
	BKEY_PADDED(replace);
	};

	enum {
	BTREE_INSERT_STATUS_INSERT,
	BTREE_INSERT_STATUS_BACK_MERGE,
	BTREE_INSERT_STATUS_OVERWROTE,
	BTREE_INSERT_STATUS_FRONT_MERGE,
	};

	void bch_btree_op_init_stack(struct btree_op *);

	static inline void rw_lock(bool w, struct btree *b, int level)
	{
	w ? down_write_nested(&b->lock, level + 1)
	: down_read_nested(&b->lock, level + 1);
	if (w)
	b->seq++;
	}

	static inline void rw_unlock(bool w, struct btree *b)
	{
	#ifdef CONFIG_BCACHE_EDEBUG
	unsigned i;

	if (w && b->key.ptr[0])
	for (i = 0; i <= b->nsets; i++)
	bch_check_key_order(b, b->sets[i].data);
	#endif

	if (w)
	b->seq++;
	(w ? up_write : up_read)(&b->lock);
	}

	#define insert_lock(s, b) ((b)->level <= (s)->lock)

	/*
	* These macros are for recursing down the btree - they handle the details of
	* locking and looking up nodes in the cache for you. They're best treated as
	* mere syntax when reading code that uses them.
	*
	* op->lock determines whether we take a read or a write lock at a given depth.
	* If you've got a read lock and find that you need a write lock (i.e. you're
	* going to have to split), set op->lock and return -EINTR; btree_root() will
	* call you again and you'll have the correct lock.
	*/

	/**
	* btree - recurse down the btree on a specified key
	* @fn: function to call, which will be passed the child node
	* @key: key to recurse on
	* @b: parent btree node
	* @op: pointer to struct btree_op
	*/
	#define btree(fn, key, b, op, ...) \
	({ \
	int _r, l = (b)->level - 1; \
	bool _w = l <= (op)->lock; \
	struct btree *_b = bch_btree_node_get((b)->c, key, l, op); \
	if (!IS_ERR(_b)) { \
	_r = bch_btree_ ## fn(_b, op, ##__VA_ARGS__); \
	rw_unlock(_w, _b); \
	} else \
	_r = PTR_ERR(_b); \
	_r; \
	})

	/**
	* btree_root - call a function on the root of the btree
	* @fn: function to call, which will be passed the child node
	* @c: cache set
	* @op: pointer to struct btree_op
	*/
	#define btree_root(fn, c, op, ...) \
	({ \
	int _r = -EINTR; \
	do { \
	struct btree *_b = (c)->root; \
	bool _w = insert_lock(op, _b); \
	rw_lock(_w, _b, _b->level); \
	if (_b == (c)->root && \
	_w == insert_lock(op, _b)) \
	_r = bch_btree_ ## fn(_b, op, ##__VA_ARGS__); \
	rw_unlock(_w, _b); \
	bch_cannibalize_unlock(c, &(op)->cl); \
	} while (_r == -EINTR); \
	\
	_r; \
	})

	static inline bool should_split(struct btree *b)
	{
	struct bset *i = write_block(b);
	return b->written >= btree_blocks(b) \|\|
	(i->seq == b->sets[0].data->seq &&
	b->written + __set_blocks(i, i->keys + 15, b->c)
	> btree_blocks(b));
	}

	void bch_btree_node_read(struct btree *);
	void bch_btree_node_write(struct btree , struct closure );

	void bch_cannibalize_unlock(struct cache_set , struct closure );
	void bch_btree_set_root(struct btree *);
	struct btree bch_btree_node_alloc(struct cache_set , int, struct closure *);
	struct btree bch_btree_node_get(struct cache_set , struct bkey *,
	int, struct btree_op *);

	bool bch_btree_insert_check_key(struct btree , struct btree_op ,
	struct bio *);
	int bch_btree_insert(struct btree_op , struct cache_set );

	int bch_btree_search_recurse(struct btree , struct btree_op );

	void bch_queue_gc(struct cache_set *);
	size_t bch_btree_gc_finish(struct cache_set *);
	void bch_moving_gc(struct closure *);
	int bch_btree_check(struct cache_set , struct btree_op );
	uint8_t __bch_btree_mark_key(struct cache_set , int, struct bkey );

	void bch_keybuf_init(struct keybuf *);
	void bch_refill_keybuf(struct cache_set , struct keybuf , struct bkey *,
	keybuf_pred_fn *);
	bool bch_keybuf_check_overlapping(struct keybuf , struct bkey ,
	struct bkey *);
	void bch_keybuf_del(struct keybuf , struct keybuf_key );
	struct keybuf_key bch_keybuf_next(struct keybuf );
	struct keybuf_key bch_keybuf_next_rescan(struct cache_set , struct keybuf *,
	struct bkey , keybuf_pred_fn );

	#endif