Documentation/admin-guide/device-mapper/dm-io.rst
Source file repositories/reference/linux-study-clean/Documentation/admin-guide/device-mapper/dm-io.rst
File Facts
- System
- Linux kernel
- Corpus path
Documentation/admin-guide/device-mapper/dm-io.rst- Extension
.rst- Size
- 3308 bytes
- Lines
- 76
- Domain
- Support Tooling And Documentation
- Bucket
- Documentation
- Inferred role
- Support Tooling And Documentation: documentation
- Status
- atlas-only
Why This File Exists
Repository support layer: documentation, build tooling, samples, user-space helper tools, generated initramfs support, licenses, and validation utilities.
- Repository support layer: documentation, build tooling, samples, user-space helper tools, generated initramfs support, licenses, and validation utilities.
- Allocates kernel memory; connect allocation flags and lifetime to context constraints.
- Defines or uses C structs; map object ownership, embedded links, reference counts, and lock ownership.
Dependency Surface
- No C-style include directives detected by the generator.
Detected Declarations
struct io_regionstruct page_list
Annotated Snippet
struct io_region {
struct block_device *bdev;
sector_t sector;
sector_t count;
};
Dm-io can read from one io_region or write to one or more io_regions. Writes
to multiple regions are specified by an array of io_region structures.
The first I/O service type takes a list of memory pages as the data buffer for
the I/O, along with an offset into the first page::
struct page_list {
struct page_list *next;
struct page *page;
};
int dm_io_sync(unsigned int num_regions, struct io_region *where, int rw,
struct page_list *pl, unsigned int offset,
unsigned long *error_bits);
int dm_io_async(unsigned int num_regions, struct io_region *where, int rw,
struct page_list *pl, unsigned int offset,
io_notify_fn fn, void *context);
The second I/O service type takes an array of bio vectors as the data buffer
for the I/O. This service can be handy if the caller has a pre-assembled bio,
but wants to direct different portions of the bio to different devices::
int dm_io_sync_bvec(unsigned int num_regions, struct io_region *where,
int rw, struct bio_vec *bvec,
unsigned long *error_bits);
int dm_io_async_bvec(unsigned int num_regions, struct io_region *where,
int rw, struct bio_vec *bvec,
io_notify_fn fn, void *context);
The third I/O service type takes a pointer to a vmalloc'd memory buffer as the
data buffer for the I/O. This service can be handy if the caller needs to do
I/O to a large region but doesn't want to allocate a large number of individual
memory pages::
int dm_io_sync_vm(unsigned int num_regions, struct io_region *where, int rw,
void *data, unsigned long *error_bits);
int dm_io_async_vm(unsigned int num_regions, struct io_region *where, int rw,
void *data, io_notify_fn fn, void *context);
Callers of the asynchronous I/O services must include the name of a completion
callback routine and a pointer to some context data for the I/O::
typedef void (*io_notify_fn)(unsigned long error, void *context);
The "error" parameter in this callback, as well as the `*error` parameter in
all of the synchronous versions, is a bitset (instead of a simple error value).
In the case of an write-I/O to multiple regions, this bitset allows dm-io to
indicate success or failure on each individual region.
Before using any of the dm-io services, the user should call dm_io_get()
and specify the number of pages they expect to perform I/O on concurrently.
Dm-io will attempt to resize its mempool to make sure enough pages are
always available in order to avoid unnecessary waiting while performing I/O.
When the user is finished using the dm-io services, they should call
dm_io_put() and specify the same number of pages that were given on the
dm_io_get() call.
Annotation
- Detected declarations: `struct io_region`, `struct page_list`.
- Atlas domain: Support Tooling And Documentation / Documentation.
- Implementation status: atlas-only.
Implementation Notes
- This generated page is the file-by-file coverage layer; curated subsystem chapters should link here when they synthesize a multi-file control flow.
- Core OS pages should be promoted from atlas-only to deep-reviewed when they explain data structures, invariants, locking, lifecycle, and C implementation snippets.
- Driver-family pages are intentionally pattern-oriented unless they are part of the selected PCIe/NVMe representative device path.