kernel/power/power.h - pub/scm/linux/kernel/git/mraynal/linux - Git at Google

 #include <linux/suspend.h>
 #include <linux/utsname.h>

 struct swsusp_info {
 	struct new_utsname	uts;
 	u32			version_code;
 	unsigned long		num_physpages;
 	int			cpus;
 	unsigned long		image_pages;
 	unsigned long		pages;
 	unsigned long		size;
 } __attribute__((aligned(PAGE_SIZE)));


 #ifdef CONFIG_SOFTWARE_SUSPEND
 extern int pm_suspend_disk(void);

 #else
 static inline int pm_suspend_disk(void)
 {
 	return -EPERM;
 }
 #endif

 extern struct mutex pm_mutex;

 #define power_attr(_name) \
 static struct subsys_attribute _name##_attr = {	\
 	.attr	= {				\
 		.name = __stringify(_name),	\
 		.mode = 0644,			\
 	},					\
 	.show	= _name##_show,			\
 	.store	= _name##_store,		\
 }

 extern struct subsystem power_subsys;

 /* References to section boundaries */
 extern const void __nosave_begin, __nosave_end;

 /* Preferred image size in bytes (default 500 MB) */
 extern unsigned long image_size;
 extern int in_suspend;
 extern dev_t swsusp_resume_device;
 extern sector_t swsusp_resume_block;

 extern asmlinkage int swsusp_arch_suspend(void);
 extern asmlinkage int swsusp_arch_resume(void);

 extern unsigned int count_data_pages(void);

 /**
  *	Auxiliary structure used for reading the snapshot image data and
  *	metadata from and writing them to the list of page backup entries
  *	(PBEs) which is the main data structure of swsusp.
  *
  *	Using struct snapshot_handle we can transfer the image, including its
  *	metadata, as a continuous sequence of bytes with the help of
  *	snapshot_read_next() and snapshot_write_next().
  *
  *	The code that writes the image to a storage or transfers it to
  *	the user land is required to use snapshot_read_next() for this
  *	purpose and it should not make any assumptions regarding the internal
  *	structure of the image.  Similarly, the code that reads the image from
  *	a storage or transfers it from the user land is required to use
  *	snapshot_write_next().
  *
  *	This may allow us to change the internal structure of the image
  *	in the future with considerably less effort.
  */

 struct snapshot_handle {
 	loff_t		offset;	/* number of the last byte ready for reading
 				 * or writing in the sequence
 				 */
 	unsigned int	cur;	/* number of the block of PAGE_SIZE bytes the
 				 * next operation will refer to (ie. current)
 				 */
 	unsigned int	cur_offset;	/* offset with respect to the current
 					 * block (for the next operation)
 					 */
 	unsigned int	prev;	/* number of the block of PAGE_SIZE bytes that
 				 * was the current one previously
 				 */
 	void		*buffer;	/* address of the block to read from
 					 * or write to
 					 */
 	unsigned int	buf_offset;	/* location to read from or write to,
 					 * given as a displacement from 'buffer'
 					 */
 	int		sync_read;	/* Set to one to notify the caller of
 					 * snapshot_write_next() that it may
 					 * need to call wait_on_bio_chain()
 					 */
 };

 /* This macro returns the address from/to which the caller of
  * snapshot_read_next()/snapshot_write_next() is allowed to
  * read/write data after the function returns
  */
 #define data_of(handle)	((handle).buffer + (handle).buf_offset)

 extern unsigned int snapshot_additional_pages(struct zone *zone);
 extern int snapshot_read_next(struct snapshot_handle *handle, size_t count);
 extern int snapshot_write_next(struct snapshot_handle *handle, size_t count);
 extern void snapshot_write_finalize(struct snapshot_handle *handle);
 extern int snapshot_image_loaded(struct snapshot_handle *handle);

 /*
  * This structure is used to pass the values needed for the identification
  * of the resume swap area from a user space to the kernel via the
  * SNAPSHOT_SET_SWAP_AREA ioctl
  */
 struct resume_swap_area {
 	loff_t offset;
 	u_int32_t dev;
 } __attribute__((packed));

 #define SNAPSHOT_IOC_MAGIC	'3'
 #define SNAPSHOT_FREEZE			_IO(SNAPSHOT_IOC_MAGIC, 1)
 #define SNAPSHOT_UNFREEZE		_IO(SNAPSHOT_IOC_MAGIC, 2)
 #define SNAPSHOT_ATOMIC_SNAPSHOT	_IOW(SNAPSHOT_IOC_MAGIC, 3, void *)
 #define SNAPSHOT_ATOMIC_RESTORE		_IO(SNAPSHOT_IOC_MAGIC, 4)
 #define SNAPSHOT_FREE			_IO(SNAPSHOT_IOC_MAGIC, 5)
 #define SNAPSHOT_SET_IMAGE_SIZE		_IOW(SNAPSHOT_IOC_MAGIC, 6, unsigned long)
 #define SNAPSHOT_AVAIL_SWAP		_IOR(SNAPSHOT_IOC_MAGIC, 7, void *)
 #define SNAPSHOT_GET_SWAP_PAGE		_IOR(SNAPSHOT_IOC_MAGIC, 8, void *)
 #define SNAPSHOT_FREE_SWAP_PAGES	_IO(SNAPSHOT_IOC_MAGIC, 9)
 #define SNAPSHOT_SET_SWAP_FILE		_IOW(SNAPSHOT_IOC_MAGIC, 10, unsigned int)
 #define SNAPSHOT_S2RAM			_IO(SNAPSHOT_IOC_MAGIC, 11)
 #define SNAPSHOT_PMOPS			_IOW(SNAPSHOT_IOC_MAGIC, 12, unsigned int)
 #define SNAPSHOT_SET_SWAP_AREA		_IOW(SNAPSHOT_IOC_MAGIC, 13, \
 							struct resume_swap_area)
 #define SNAPSHOT_IOC_MAXNR	13

 #define PMOPS_PREPARE	1
 #define PMOPS_ENTER	2
 #define PMOPS_FINISH	3

 /**
  *	The bitmap is used for tracing allocated swap pages
  *
  *	The entire bitmap consists of a number of bitmap_page
  *	structures linked with the help of the .next member.
  *	Thus each page can be allocated individually, so we only
  *	need to make 0-order memory allocations to create
  *	the bitmap.
  */

 #define BITMAP_PAGE_SIZE	(PAGE_SIZE - sizeof(void *))
 #define BITMAP_PAGE_CHUNKS	(BITMAP_PAGE_SIZE / sizeof(long))
 #define BITS_PER_CHUNK		(sizeof(long) * 8)
 #define BITMAP_PAGE_BITS	(BITMAP_PAGE_CHUNKS * BITS_PER_CHUNK)

 struct bitmap_page {
 	unsigned long		chunks[BITMAP_PAGE_CHUNKS];
 	struct bitmap_page	*next;
 };

 extern void free_bitmap(struct bitmap_page *bitmap);
 extern struct bitmap_page *alloc_bitmap(unsigned int nr_bits);
 extern sector_t alloc_swapdev_block(int swap, struct bitmap_page *bitmap);
 extern void free_all_swap_pages(int swap, struct bitmap_page *bitmap);

 extern int swsusp_check(void);
 extern int swsusp_shrink_memory(void);
 extern void swsusp_free(void);
 extern int swsusp_suspend(void);
 extern int swsusp_resume(void);
 extern int swsusp_read(void);
 extern int swsusp_write(void);
 extern void swsusp_close(void);
 extern int suspend_enter(suspend_state_t state);

 struct timeval;
 extern void swsusp_show_speed(struct timeval *, struct timeval *,
 				unsigned int, char *);
	#include <linux/suspend.h>
	#include <linux/utsname.h>

	struct swsusp_info {
	struct new_utsname uts;
	u32 version_code;
	unsigned long num_physpages;
	int cpus;
	unsigned long image_pages;
	unsigned long pages;
	unsigned long size;
	} __attribute__((aligned(PAGE_SIZE)));



	#ifdef CONFIG_SOFTWARE_SUSPEND
	extern int pm_suspend_disk(void);

	#else
	static inline int pm_suspend_disk(void)
	{
	return -EPERM;
	}
	#endif

	extern struct mutex pm_mutex;

	#define power_attr(_name) \
	static struct subsys_attribute _name##_attr = { \
	.attr = { \
	.name = __stringify(_name), \
	.mode = 0644, \
	}, \
	.show = _name##_show, \
	.store = _name##_store, \
	}

	extern struct subsystem power_subsys;

	/* References to section boundaries */
	extern const void __nosave_begin, __nosave_end;

	/* Preferred image size in bytes (default 500 MB) */
	extern unsigned long image_size;
	extern int in_suspend;
	extern dev_t swsusp_resume_device;
	extern sector_t swsusp_resume_block;

	extern asmlinkage int swsusp_arch_suspend(void);
	extern asmlinkage int swsusp_arch_resume(void);

	extern unsigned int count_data_pages(void);

	/**
	* Auxiliary structure used for reading the snapshot image data and
	* metadata from and writing them to the list of page backup entries
	* (PBEs) which is the main data structure of swsusp.
	*
	* Using struct snapshot_handle we can transfer the image, including its
	* metadata, as a continuous sequence of bytes with the help of
	* snapshot_read_next() and snapshot_write_next().
	*
	* The code that writes the image to a storage or transfers it to
	* the user land is required to use snapshot_read_next() for this
	* purpose and it should not make any assumptions regarding the internal
	* structure of the image. Similarly, the code that reads the image from
	* a storage or transfers it from the user land is required to use
	* snapshot_write_next().
	*
	* This may allow us to change the internal structure of the image
	* in the future with considerably less effort.
	*/

	struct snapshot_handle {
	loff_t offset; /* number of the last byte ready for reading
	* or writing in the sequence
	*/
	unsigned int cur; /* number of the block of PAGE_SIZE bytes the
	* next operation will refer to (ie. current)
	*/
	unsigned int cur_offset; /* offset with respect to the current
	* block (for the next operation)
	*/
	unsigned int prev; /* number of the block of PAGE_SIZE bytes that
	* was the current one previously
	*/
	void buffer; / address of the block to read from
	* or write to
	*/
	unsigned int buf_offset; /* location to read from or write to,
	* given as a displacement from 'buffer'
	*/
	int sync_read; /* Set to one to notify the caller of
	* snapshot_write_next() that it may
	* need to call wait_on_bio_chain()
	*/
	};

	/* This macro returns the address from/to which the caller of
	* snapshot_read_next()/snapshot_write_next() is allowed to
	* read/write data after the function returns
	*/
	#define data_of(handle) ((handle).buffer + (handle).buf_offset)

	extern unsigned int snapshot_additional_pages(struct zone *zone);
	extern int snapshot_read_next(struct snapshot_handle *handle, size_t count);
	extern int snapshot_write_next(struct snapshot_handle *handle, size_t count);
	extern void snapshot_write_finalize(struct snapshot_handle *handle);
	extern int snapshot_image_loaded(struct snapshot_handle *handle);

	/*
	* This structure is used to pass the values needed for the identification
	* of the resume swap area from a user space to the kernel via the
	* SNAPSHOT_SET_SWAP_AREA ioctl
	*/
	struct resume_swap_area {
	loff_t offset;
	u_int32_t dev;
	} __attribute__((packed));

	#define SNAPSHOT_IOC_MAGIC '3'
	#define SNAPSHOT_FREEZE _IO(SNAPSHOT_IOC_MAGIC, 1)
	#define SNAPSHOT_UNFREEZE _IO(SNAPSHOT_IOC_MAGIC, 2)
	#define SNAPSHOT_ATOMIC_SNAPSHOT _IOW(SNAPSHOT_IOC_MAGIC, 3, void *)
	#define SNAPSHOT_ATOMIC_RESTORE _IO(SNAPSHOT_IOC_MAGIC, 4)
	#define SNAPSHOT_FREE _IO(SNAPSHOT_IOC_MAGIC, 5)
	#define SNAPSHOT_SET_IMAGE_SIZE _IOW(SNAPSHOT_IOC_MAGIC, 6, unsigned long)
	#define SNAPSHOT_AVAIL_SWAP _IOR(SNAPSHOT_IOC_MAGIC, 7, void *)
	#define SNAPSHOT_GET_SWAP_PAGE _IOR(SNAPSHOT_IOC_MAGIC, 8, void *)
	#define SNAPSHOT_FREE_SWAP_PAGES _IO(SNAPSHOT_IOC_MAGIC, 9)
	#define SNAPSHOT_SET_SWAP_FILE _IOW(SNAPSHOT_IOC_MAGIC, 10, unsigned int)
	#define SNAPSHOT_S2RAM _IO(SNAPSHOT_IOC_MAGIC, 11)
	#define SNAPSHOT_PMOPS _IOW(SNAPSHOT_IOC_MAGIC, 12, unsigned int)
	#define SNAPSHOT_SET_SWAP_AREA _IOW(SNAPSHOT_IOC_MAGIC, 13, \
	struct resume_swap_area)
	#define SNAPSHOT_IOC_MAXNR 13

	#define PMOPS_PREPARE 1
	#define PMOPS_ENTER 2
	#define PMOPS_FINISH 3

	/**
	* The bitmap is used for tracing allocated swap pages
	*
	* The entire bitmap consists of a number of bitmap_page
	* structures linked with the help of the .next member.
	* Thus each page can be allocated individually, so we only
	* need to make 0-order memory allocations to create
	* the bitmap.
	*/

	#define BITMAP_PAGE_SIZE (PAGE_SIZE - sizeof(void *))
	#define BITMAP_PAGE_CHUNKS (BITMAP_PAGE_SIZE / sizeof(long))
	#define BITS_PER_CHUNK (sizeof(long) * 8)
	#define BITMAP_PAGE_BITS (BITMAP_PAGE_CHUNKS * BITS_PER_CHUNK)

	struct bitmap_page {
	unsigned long chunks[BITMAP_PAGE_CHUNKS];
	struct bitmap_page *next;
	};

	extern void free_bitmap(struct bitmap_page *bitmap);
	extern struct bitmap_page *alloc_bitmap(unsigned int nr_bits);
	extern sector_t alloc_swapdev_block(int swap, struct bitmap_page *bitmap);
	extern void free_all_swap_pages(int swap, struct bitmap_page *bitmap);

	extern int swsusp_check(void);
	extern int swsusp_shrink_memory(void);
	extern void swsusp_free(void);
	extern int swsusp_suspend(void);
	extern int swsusp_resume(void);
	extern int swsusp_read(void);
	extern int swsusp_write(void);
	extern void swsusp_close(void);
	extern int suspend_enter(suspend_state_t state);

	struct timeval;
	extern void swsusp_show_speed(struct timeval , struct timeval ,
	unsigned int, char *);