drivers/md/persistent-data/dm-bitset.h - pub/scm/linux/kernel/git/vfs/idmapping - Git at Google

 /*
  * Copyright (C) 2012 Red Hat, Inc.
  *
  * This file is released under the GPL.
  */
 #ifndef _LINUX_DM_BITSET_H
 #define _LINUX_DM_BITSET_H

 #include "dm-array.h"

 /*----------------------------------------------------------------*/

 /*
  * This bitset type is a thin wrapper round a dm_array of 64bit words.  It
  * uses a tiny, one word cache to reduce the number of array lookups and so
  * increase performance.
  *
  * Like the dm-array that it's based on, the caller needs to keep track of
  * the size of the bitset separately.  The underlying dm-array implicitly
  * knows how many words it's storing and will return -ENODATA if you try
  * and access an out of bounds word.  However, an out of bounds bit in the
  * final word will _not_ be detected, you have been warned.
  *
  * Bits are indexed from zero.

  * Typical use:
  *
  * a) Initialise a dm_disk_bitset structure with dm_disk_bitset_init().
  *    This describes the bitset and includes the cache.  It's not called it
  *    dm_bitset_info in line with other data structures because it does
  *    include instance data.
  *
  * b) Get yourself a root.  The root is the index of a block of data on the
  *    disk that holds a particular instance of an bitset.  You may have a
  *    pre existing root in your metadata that you wish to use, or you may
  *    want to create a brand new, empty bitset with dm_bitset_empty().
  *
  * Like the other data structures in this library, dm_bitset objects are
  * immutable between transactions.  Update functions will return you the
  * root for a _new_ array.  If you've incremented the old root, via
  * dm_tm_inc(), before calling the update function you may continue to use
  * it in parallel with the new root.
  *
  * Even read operations may trigger the cache to be flushed and as such
  * return a root for a new, updated bitset.
  *
  * c) resize a bitset with dm_bitset_resize().
  *
  * d) Set a bit with dm_bitset_set_bit().
  *
  * e) Clear a bit with dm_bitset_clear_bit().
  *
  * f) Test a bit with dm_bitset_test_bit().
  *
  * g) Flush all updates from the cache with dm_bitset_flush().
  *
  * h) Destroy the bitset with dm_bitset_del().  This tells the transaction
  *    manager that you're no longer using this data structure so it can
  *    recycle it's blocks.  (dm_bitset_dec() would be a better name for it,
  *    but del is in keeping with dm_btree_del()).
  */

 /*
  * Opaque object.  Unlike dm_array_info, you should have one of these per
  * bitset.  Initialise with dm_disk_bitset_init().
  */
 struct dm_disk_bitset {
 	struct dm_array_info array_info;

 	uint32_t current_index;
 	uint64_t current_bits;

 	bool current_index_set:1;
 	bool dirty:1;
 };

 /*
  * Sets up a dm_disk_bitset structure.  You don't need to do anything with
  * this structure when you finish using it.
  *
  * tm - the transaction manager that should supervise this structure
  * info - the structure being initialised
  */
 void dm_disk_bitset_init(struct dm_transaction_manager *tm,
 			 struct dm_disk_bitset *info);

 /*
  * Create an empty, zero length bitset.
  *
  * info - describes the bitset
  * new_root - on success, points to the new root block
  */
 int dm_bitset_empty(struct dm_disk_bitset *info, dm_block_t *new_root);

 /*
  * Creates a new bitset populated with values provided by a callback
  * function.  This is more efficient than creating an empty bitset,
  * resizing, and then setting values since that process incurs a lot of
  * copying.
  *
  * info - describes the array
  * root - the root block of the array on disk
  * size - the number of entries in the array
  * fn - the callback
  * context - passed to the callback
  */
 typedef int (*bit_value_fn)(uint32_t index, bool *value, void *context);
 int dm_bitset_new(struct dm_disk_bitset *info, dm_block_t *root,
 		  uint32_t size, bit_value_fn fn, void *context);

 /*
  * Resize the bitset.
  *
  * info - describes the bitset
  * old_root - the root block of the array on disk
  * old_nr_entries - the number of bits in the old bitset
  * new_nr_entries - the number of bits you want in the new bitset
  * default_value - the value for any new bits
  * new_root - on success, points to the new root block
  */
 int dm_bitset_resize(struct dm_disk_bitset *info, dm_block_t old_root,
 		     uint32_t old_nr_entries, uint32_t new_nr_entries,
 		     bool default_value, dm_block_t *new_root);

 /*
  * Frees the bitset.
  */
 int dm_bitset_del(struct dm_disk_bitset *info, dm_block_t root);

 /*
  * Set a bit.
  *
  * info - describes the bitset
  * root - the root block of the bitset
  * index - the bit index
  * new_root - on success, points to the new root block
  *
  * -ENODATA will be returned if the index is out of bounds.
  */
 int dm_bitset_set_bit(struct dm_disk_bitset *info, dm_block_t root,
 		      uint32_t index, dm_block_t *new_root);

 /*
  * Clears a bit.
  *
  * info - describes the bitset
  * root - the root block of the bitset
  * index - the bit index
  * new_root - on success, points to the new root block
  *
  * -ENODATA will be returned if the index is out of bounds.
  */
 int dm_bitset_clear_bit(struct dm_disk_bitset *info, dm_block_t root,
 			uint32_t index, dm_block_t *new_root);

 /*
  * Tests a bit.
  *
  * info - describes the bitset
  * root - the root block of the bitset
  * index - the bit index
  * new_root - on success, points to the new root block (cached values may have been written)
  * result - the bit value you're after
  *
  * -ENODATA will be returned if the index is out of bounds.
  */
 int dm_bitset_test_bit(struct dm_disk_bitset *info, dm_block_t root,
 		       uint32_t index, dm_block_t *new_root, bool *result);

 /*
  * Flush any cached changes to disk.
  *
  * info - describes the bitset
  * root - the root block of the bitset
  * new_root - on success, points to the new root block
  */
 int dm_bitset_flush(struct dm_disk_bitset *info, dm_block_t root,
 		    dm_block_t *new_root);

 struct dm_bitset_cursor {
 	struct dm_disk_bitset *info;
 	struct dm_array_cursor cursor;

 	uint32_t entries_remaining;
 	uint32_t array_index;
 	uint32_t bit_index;
 	uint64_t current_bits;
 };

 /*
  * Make sure you've flush any dm_disk_bitset and updated the root before
  * using this.
  */
 int dm_bitset_cursor_begin(struct dm_disk_bitset *info,
 			   dm_block_t root, uint32_t nr_entries,
 			   struct dm_bitset_cursor *c);
 void dm_bitset_cursor_end(struct dm_bitset_cursor *c);

 int dm_bitset_cursor_next(struct dm_bitset_cursor *c);
 int dm_bitset_cursor_skip(struct dm_bitset_cursor *c, uint32_t count);
 bool dm_bitset_cursor_get_value(struct dm_bitset_cursor *c);

 /*----------------------------------------------------------------*/

 #endif /* _LINUX_DM_BITSET_H */
	/*
	* Copyright (C) 2012 Red Hat, Inc.
	*
	* This file is released under the GPL.
	*/
	#ifndef _LINUX_DM_BITSET_H
	#define _LINUX_DM_BITSET_H

	#include "dm-array.h"

	/----------------------------------------------------------------/

	/*
	* This bitset type is a thin wrapper round a dm_array of 64bit words. It
	* uses a tiny, one word cache to reduce the number of array lookups and so
	* increase performance.
	*
	* Like the dm-array that it's based on, the caller needs to keep track of
	* the size of the bitset separately. The underlying dm-array implicitly
	* knows how many words it's storing and will return -ENODATA if you try
	* and access an out of bounds word. However, an out of bounds bit in the
	* final word will _not_ be detected, you have been warned.
	*
	* Bits are indexed from zero.

	* Typical use:
	*
	* a) Initialise a dm_disk_bitset structure with dm_disk_bitset_init().
	* This describes the bitset and includes the cache. It's not called it
	* dm_bitset_info in line with other data structures because it does
	* include instance data.
	*
	* b) Get yourself a root. The root is the index of a block of data on the
	* disk that holds a particular instance of an bitset. You may have a
	* pre existing root in your metadata that you wish to use, or you may
	* want to create a brand new, empty bitset with dm_bitset_empty().
	*
	* Like the other data structures in this library, dm_bitset objects are
	* immutable between transactions. Update functions will return you the
	* root for a _new_ array. If you've incremented the old root, via
	* dm_tm_inc(), before calling the update function you may continue to use
	* it in parallel with the new root.
	*
	* Even read operations may trigger the cache to be flushed and as such
	* return a root for a new, updated bitset.
	*
	* c) resize a bitset with dm_bitset_resize().
	*
	* d) Set a bit with dm_bitset_set_bit().
	*
	* e) Clear a bit with dm_bitset_clear_bit().
	*
	* f) Test a bit with dm_bitset_test_bit().
	*
	* g) Flush all updates from the cache with dm_bitset_flush().
	*
	* h) Destroy the bitset with dm_bitset_del(). This tells the transaction
	* manager that you're no longer using this data structure so it can
	* recycle it's blocks. (dm_bitset_dec() would be a better name for it,
	* but del is in keeping with dm_btree_del()).
	*/

	/*
	* Opaque object. Unlike dm_array_info, you should have one of these per
	* bitset. Initialise with dm_disk_bitset_init().
	*/
	struct dm_disk_bitset {
	struct dm_array_info array_info;

	uint32_t current_index;
	uint64_t current_bits;

	bool current_index_set:1;
	bool dirty:1;
	};

	/*
	* Sets up a dm_disk_bitset structure. You don't need to do anything with
	* this structure when you finish using it.
	*
	* tm - the transaction manager that should supervise this structure
	* info - the structure being initialised
	*/
	void dm_disk_bitset_init(struct dm_transaction_manager *tm,
	struct dm_disk_bitset *info);

	/*
	* Create an empty, zero length bitset.
	*
	* info - describes the bitset
	* new_root - on success, points to the new root block
	*/
	int dm_bitset_empty(struct dm_disk_bitset info, dm_block_t new_root);

	/*
	* Creates a new bitset populated with values provided by a callback
	* function. This is more efficient than creating an empty bitset,
	* resizing, and then setting values since that process incurs a lot of
	* copying.
	*
	* info - describes the array
	* root - the root block of the array on disk
	* size - the number of entries in the array
	* fn - the callback
	* context - passed to the callback
	*/
	typedef int (bit_value_fn)(uint32_t index, bool value, void *context);
	int dm_bitset_new(struct dm_disk_bitset info, dm_block_t root,
	uint32_t size, bit_value_fn fn, void *context);

	/*
	* Resize the bitset.
	*
	* info - describes the bitset
	* old_root - the root block of the array on disk
	* old_nr_entries - the number of bits in the old bitset
	* new_nr_entries - the number of bits you want in the new bitset
	* default_value - the value for any new bits
	* new_root - on success, points to the new root block
	*/
	int dm_bitset_resize(struct dm_disk_bitset *info, dm_block_t old_root,
	uint32_t old_nr_entries, uint32_t new_nr_entries,
	bool default_value, dm_block_t *new_root);

	/*
	* Frees the bitset.
	*/
	int dm_bitset_del(struct dm_disk_bitset *info, dm_block_t root);

	/*
	* Set a bit.
	*
	* info - describes the bitset
	* root - the root block of the bitset
	* index - the bit index
	* new_root - on success, points to the new root block
	*
	* -ENODATA will be returned if the index is out of bounds.
	*/
	int dm_bitset_set_bit(struct dm_disk_bitset *info, dm_block_t root,
	uint32_t index, dm_block_t *new_root);

	/*
	* Clears a bit.
	*
	* info - describes the bitset
	* root - the root block of the bitset
	* index - the bit index
	* new_root - on success, points to the new root block
	*
	* -ENODATA will be returned if the index is out of bounds.
	*/
	int dm_bitset_clear_bit(struct dm_disk_bitset *info, dm_block_t root,
	uint32_t index, dm_block_t *new_root);

	/*
	* Tests a bit.
	*
	* info - describes the bitset
	* root - the root block of the bitset
	* index - the bit index
	* new_root - on success, points to the new root block (cached values may have been written)
	* result - the bit value you're after
	*
	* -ENODATA will be returned if the index is out of bounds.
	*/
	int dm_bitset_test_bit(struct dm_disk_bitset *info, dm_block_t root,
	uint32_t index, dm_block_t new_root, bool result);

	/*
	* Flush any cached changes to disk.
	*
	* info - describes the bitset
	* root - the root block of the bitset
	* new_root - on success, points to the new root block
	*/
	int dm_bitset_flush(struct dm_disk_bitset *info, dm_block_t root,
	dm_block_t *new_root);

	struct dm_bitset_cursor {
	struct dm_disk_bitset *info;
	struct dm_array_cursor cursor;

	uint32_t entries_remaining;
	uint32_t array_index;
	uint32_t bit_index;
	uint64_t current_bits;
	};

	/*
	* Make sure you've flush any dm_disk_bitset and updated the root before
	* using this.
	*/
	int dm_bitset_cursor_begin(struct dm_disk_bitset *info,
	dm_block_t root, uint32_t nr_entries,
	struct dm_bitset_cursor *c);
	void dm_bitset_cursor_end(struct dm_bitset_cursor *c);

	int dm_bitset_cursor_next(struct dm_bitset_cursor *c);
	int dm_bitset_cursor_skip(struct dm_bitset_cursor *c, uint32_t count);
	bool dm_bitset_cursor_get_value(struct dm_bitset_cursor *c);

	/----------------------------------------------------------------/

	#endif /* _LINUX_DM_BITSET_H */