Documentation/block/writeback_cache_control.txt - third_party/linux - Git at Google


 Explicit volatile write back cache control
 =====================================

 Introduction
 ------------

 Many storage devices, especially in the consumer market, come with volatile
 write back caches.  That means the devices signal I/O completion to the
 operating system before data actually has hit the non-volatile storage.  This
 behavior obviously speeds up various workloads, but it means the operating
 system needs to force data out to the non-volatile storage when it performs
 a data integrity operation like fsync, sync or an unmount.

 The Linux block layer provides two simple mechanisms that let filesystems
 control the caching behavior of the storage device.  These mechanisms are
 a forced cache flush, and the Force Unit Access (FUA) flag for requests.


 Explicit cache flushes
 ----------------------

 The REQ_PREFLUSH flag can be OR ed into the r/w flags of a bio submitted from
 the filesystem and will make sure the volatile cache of the storage device
 has been flushed before the actual I/O operation is started.  This explicitly
 guarantees that previously completed write requests are on non-volatile
 storage before the flagged bio starts. In addition the REQ_PREFLUSH flag can be
 set on an otherwise empty bio structure, which causes only an explicit cache
 flush without any dependent I/O.  It is recommend to use
 the blkdev_issue_flush() helper for a pure cache flush.


 Forced Unit Access
 -----------------

 The REQ_FUA flag can be OR ed into the r/w flags of a bio submitted from the
 filesystem and will make sure that I/O completion for this request is only
 signaled after the data has been committed to non-volatile storage.


 Implementation details for filesystems
 --------------------------------------

 Filesystems can simply set the REQ_PREFLUSH and REQ_FUA bits and do not have to
 worry if the underlying devices need any explicit cache flushing and how
 the Forced Unit Access is implemented.  The REQ_PREFLUSH and REQ_FUA flags
 may both be set on a single bio.


 Implementation details for make_request_fn based block drivers
 --------------------------------------------------------------

 These drivers will always see the REQ_PREFLUSH and REQ_FUA bits as they sit
 directly below the submit_bio interface.  For remapping drivers the REQ_FUA
 bits need to be propagated to underlying devices, and a global flush needs
 to be implemented for bios with the REQ_PREFLUSH bit set.  For real device
 drivers that do not have a volatile cache the REQ_PREFLUSH and REQ_FUA bits
 on non-empty bios can simply be ignored, and REQ_PREFLUSH requests without
 data can be completed successfully without doing any work.  Drivers for
 devices with volatile caches need to implement the support for these
 flags themselves without any help from the block layer.


 Implementation details for request_fn based block drivers
 --------------------------------------------------------------

 For devices that do not support volatile write caches there is no driver
 support required, the block layer completes empty REQ_PREFLUSH requests before
 entering the driver and strips off the REQ_PREFLUSH and REQ_FUA bits from
 requests that have a payload.  For devices with volatile write caches the
 driver needs to tell the block layer that it supports flushing caches by
 doing:

 	blk_queue_write_cache(sdkp->disk->queue, true, false);

 and handle empty REQ_OP_FLUSH requests in its prep_fn/request_fn.  Note that
 REQ_PREFLUSH requests with a payload are automatically turned into a sequence
 of an empty REQ_OP_FLUSH request followed by the actual write by the block
 layer.  For devices that also support the FUA bit the block layer needs
 to be told to pass through the REQ_FUA bit using:

 	blk_queue_write_cache(sdkp->disk->queue, true, true);

 and the driver must handle write requests that have the REQ_FUA bit set
 in prep_fn/request_fn.  If the FUA bit is not natively supported the block
 layer turns it into an empty REQ_OP_FLUSH request after the actual write.

	Explicit volatile write back cache control
	=====================================

	Introduction
	------------

	Many storage devices, especially in the consumer market, come with volatile
	write back caches. That means the devices signal I/O completion to the
	operating system before data actually has hit the non-volatile storage. This
	behavior obviously speeds up various workloads, but it means the operating
	system needs to force data out to the non-volatile storage when it performs
	a data integrity operation like fsync, sync or an unmount.

	The Linux block layer provides two simple mechanisms that let filesystems
	control the caching behavior of the storage device. These mechanisms are
	a forced cache flush, and the Force Unit Access (FUA) flag for requests.


	Explicit cache flushes
	----------------------

	The REQ_PREFLUSH flag can be OR ed into the r/w flags of a bio submitted from
	the filesystem and will make sure the volatile cache of the storage device
	has been flushed before the actual I/O operation is started. This explicitly
	guarantees that previously completed write requests are on non-volatile
	storage before the flagged bio starts. In addition the REQ_PREFLUSH flag can be
	set on an otherwise empty bio structure, which causes only an explicit cache
	flush without any dependent I/O. It is recommend to use
	the blkdev_issue_flush() helper for a pure cache flush.


	Forced Unit Access
	-----------------

	The REQ_FUA flag can be OR ed into the r/w flags of a bio submitted from the
	filesystem and will make sure that I/O completion for this request is only
	signaled after the data has been committed to non-volatile storage.


	Implementation details for filesystems
	--------------------------------------

	Filesystems can simply set the REQ_PREFLUSH and REQ_FUA bits and do not have to
	worry if the underlying devices need any explicit cache flushing and how
	the Forced Unit Access is implemented. The REQ_PREFLUSH and REQ_FUA flags
	may both be set on a single bio.


	Implementation details for make_request_fn based block drivers
	--------------------------------------------------------------

	These drivers will always see the REQ_PREFLUSH and REQ_FUA bits as they sit
	directly below the submit_bio interface. For remapping drivers the REQ_FUA
	bits need to be propagated to underlying devices, and a global flush needs
	to be implemented for bios with the REQ_PREFLUSH bit set. For real device
	drivers that do not have a volatile cache the REQ_PREFLUSH and REQ_FUA bits
	on non-empty bios can simply be ignored, and REQ_PREFLUSH requests without
	data can be completed successfully without doing any work. Drivers for
	devices with volatile caches need to implement the support for these
	flags themselves without any help from the block layer.


	Implementation details for request_fn based block drivers
	--------------------------------------------------------------

	For devices that do not support volatile write caches there is no driver
	support required, the block layer completes empty REQ_PREFLUSH requests before
	entering the driver and strips off the REQ_PREFLUSH and REQ_FUA bits from
	requests that have a payload. For devices with volatile write caches the
	driver needs to tell the block layer that it supports flushing caches by
	doing:

	blk_queue_write_cache(sdkp->disk->queue, true, false);

	and handle empty REQ_OP_FLUSH requests in its prep_fn/request_fn. Note that
	REQ_PREFLUSH requests with a payload are automatically turned into a sequence
	of an empty REQ_OP_FLUSH request followed by the actual write by the block
	layer. For devices that also support the FUA bit the block layer needs
	to be told to pass through the REQ_FUA bit using:

	blk_queue_write_cache(sdkp->disk->queue, true, true);

	and the driver must handle write requests that have the REQ_FUA bit set
	in prep_fn/request_fn. If the FUA bit is not natively supported the block
	layer turns it into an empty REQ_OP_FLUSH request after the actual write.