Documentation/filesystems/xip.txt - kernel/msm-4.9 - Gitiles

 Execute-in-place for file mappings
 ----------------------------------

 Motivation
 ----------
 File mappings are performed by mapping page cache pages to userspace. In
 addition, read&write type file operations also transfer data from/to the page
 cache.

 For memory backed storage devices that use the block device interface, the page
 cache pages are in fact copies of the original storage. Various approaches
 exist to work around the need for an extra copy. The ramdisk driver for example
 does read the data into the page cache, keeps a reference, and discards the
 original data behind later on.

 Execute-in-place solves this issue the other way around: instead of keeping
 data in the page cache, the need to have a page cache copy is eliminated
 completely. With execute-in-place, read&write type operations are performed
 directly from/to the memory backed storage device. For file mappings, the
 storage device itself is mapped directly into userspace.

 This implementation was initially written for shared memory segments between
 different virtual machines on s390 hardware to allow multiple machines to
 share the same binaries and libraries.

 Implementation
 --------------
 Execute-in-place is implemented in three steps: block device operation,
 address space operation, and file operations.

 A block device operation named direct_access is used to retrieve a
 reference (pointer) to a block on-disk. The reference is supposed to be
 cpu-addressable, physical address and remain valid until the release operation
 is performed. A struct block_device reference is used to address the device,
 and a sector_t argument is used to identify the individual block. As an
 alternative, memory technology devices can be used for this.

 The block device operation is optional, these block devices support it as of
 today:
 - dcssblk: s390 dcss block device driver

 An address space operation named get_xip_page is used to retrieve reference
 to a struct page. To address the target page, a reference to an address_space,
 and a sector number is provided. A 3rd argument indicates whether the
 function should allocate blocks if needed.

 This address space operation is mutually exclusive with readpage&writepage that
 do page cache read/write operations.
 The following filesystems support it as of today:
 - ext2: the second extended filesystem, see Documentation/filesystems/ext2.txt

 A set of file operations that do utilize get_xip_page can be found in
 mm/filemap_xip.c . The following file operation implementations are provided:
 - aio_read/aio_write
 - readv/writev
 - sendfile

 The generic file operations do_sync_read/do_sync_write can be used to implement
 classic synchronous IO calls.

 Shortcomings
 ------------
 This implementation is limited to storage devices that are cpu addressable at
 all times (no highmem or such). It works well on rom/ram, but enhancements are
 needed to make it work with flash in read+write mode.
 Putting the Linux kernel and/or its modules on a xip filesystem does not mean
 they are not copied.
	Execute-in-place for file mappings
	----------------------------------

	Motivation
	----------
	File mappings are performed by mapping page cache pages to userspace. In
	addition, read&write type file operations also transfer data from/to the page
	cache.

	For memory backed storage devices that use the block device interface, the page
	cache pages are in fact copies of the original storage. Various approaches
	exist to work around the need for an extra copy. The ramdisk driver for example
	does read the data into the page cache, keeps a reference, and discards the
	original data behind later on.

	Execute-in-place solves this issue the other way around: instead of keeping
	data in the page cache, the need to have a page cache copy is eliminated
	completely. With execute-in-place, read&write type operations are performed
	directly from/to the memory backed storage device. For file mappings, the
	storage device itself is mapped directly into userspace.

	This implementation was initially written for shared memory segments between
	different virtual machines on s390 hardware to allow multiple machines to
	share the same binaries and libraries.

	Implementation
	--------------
	Execute-in-place is implemented in three steps: block device operation,
	address space operation, and file operations.

	A block device operation named direct_access is used to retrieve a
	reference (pointer) to a block on-disk. The reference is supposed to be
	cpu-addressable, physical address and remain valid until the release operation
	is performed. A struct block_device reference is used to address the device,
	and a sector_t argument is used to identify the individual block. As an
	alternative, memory technology devices can be used for this.

	The block device operation is optional, these block devices support it as of
	today:
	- dcssblk: s390 dcss block device driver

	An address space operation named get_xip_page is used to retrieve reference
	to a struct page. To address the target page, a reference to an address_space,
	and a sector number is provided. A 3rd argument indicates whether the
	function should allocate blocks if needed.

	This address space operation is mutually exclusive with readpage&writepage that
	do page cache read/write operations.
	The following filesystems support it as of today:
	- ext2: the second extended filesystem, see Documentation/filesystems/ext2.txt

	A set of file operations that do utilize get_xip_page can be found in
	mm/filemap_xip.c . The following file operation implementations are provided:
	- aio_read/aio_write
	- readv/writev
	- sendfile

	The generic file operations do_sync_read/do_sync_write can be used to implement
	classic synchronous IO calls.

	Shortcomings
	------------
	This implementation is limited to storage devices that are cpu addressable at
	all times (no highmem or such). It works well on rom/ram, but enhancements are
	needed to make it work with flash in read+write mode.
	Putting the Linux kernel and/or its modules on a xip filesystem does not mean
	they are not copied.