biodoc.txt 53 KB

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  1. Notes on the Generic Block Layer Rewrite in Linux 2.5
  2. =====================================================
  3. Notes Written on Jan 15, 2002:
  4. Jens Axboe <jens.axboe@oracle.com>
  5. Suparna Bhattacharya <suparna@in.ibm.com>
  6. Last Updated May 2, 2002
  7. September 2003: Updated I/O Scheduler portions
  8. Nick Piggin <npiggin@kernel.dk>
  9. Introduction:
  10. These are some notes describing some aspects of the 2.5 block layer in the
  11. context of the bio rewrite. The idea is to bring out some of the key
  12. changes and a glimpse of the rationale behind those changes.
  13. Please mail corrections & suggestions to suparna@in.ibm.com.
  14. Credits:
  15. ---------
  16. 2.5 bio rewrite:
  17. Jens Axboe <jens.axboe@oracle.com>
  18. Many aspects of the generic block layer redesign were driven by and evolved
  19. over discussions, prior patches and the collective experience of several
  20. people. See sections 8 and 9 for a list of some related references.
  21. The following people helped with review comments and inputs for this
  22. document:
  23. Christoph Hellwig <hch@infradead.org>
  24. Arjan van de Ven <arjanv@redhat.com>
  25. Randy Dunlap <rdunlap@xenotime.net>
  26. Andre Hedrick <andre@linux-ide.org>
  27. The following people helped with fixes/contributions to the bio patches
  28. while it was still work-in-progress:
  29. David S. Miller <davem@redhat.com>
  30. Description of Contents:
  31. ------------------------
  32. 1. Scope for tuning of logic to various needs
  33. 1.1 Tuning based on device or low level driver capabilities
  34. - Per-queue parameters
  35. - Highmem I/O support
  36. - I/O scheduler modularization
  37. 1.2 Tuning based on high level requirements/capabilities
  38. 1.2.1 Request Priority/Latency
  39. 1.3 Direct access/bypass to lower layers for diagnostics and special
  40. device operations
  41. 1.3.1 Pre-built commands
  42. 2. New flexible and generic but minimalist i/o structure or descriptor
  43. (instead of using buffer heads at the i/o layer)
  44. 2.1 Requirements/Goals addressed
  45. 2.2 The bio struct in detail (multi-page io unit)
  46. 2.3 Changes in the request structure
  47. 3. Using bios
  48. 3.1 Setup/teardown (allocation, splitting)
  49. 3.2 Generic bio helper routines
  50. 3.2.1 Traversing segments and completion units in a request
  51. 3.2.2 Setting up DMA scatterlists
  52. 3.2.3 I/O completion
  53. 3.2.4 Implications for drivers that do not interpret bios (don't handle
  54. multiple segments)
  55. 3.2.5 Request command tagging
  56. 3.3 I/O submission
  57. 4. The I/O scheduler
  58. 5. Scalability related changes
  59. 5.1 Granular locking: Removal of io_request_lock
  60. 5.2 Prepare for transition to 64 bit sector_t
  61. 6. Other Changes/Implications
  62. 6.1 Partition re-mapping handled by the generic block layer
  63. 7. A few tips on migration of older drivers
  64. 8. A list of prior/related/impacted patches/ideas
  65. 9. Other References/Discussion Threads
  66. ---------------------------------------------------------------------------
  67. Bio Notes
  68. --------
  69. Let us discuss the changes in the context of how some overall goals for the
  70. block layer are addressed.
  71. 1. Scope for tuning the generic logic to satisfy various requirements
  72. The block layer design supports adaptable abstractions to handle common
  73. processing with the ability to tune the logic to an appropriate extent
  74. depending on the nature of the device and the requirements of the caller.
  75. One of the objectives of the rewrite was to increase the degree of tunability
  76. and to enable higher level code to utilize underlying device/driver
  77. capabilities to the maximum extent for better i/o performance. This is
  78. important especially in the light of ever improving hardware capabilities
  79. and application/middleware software designed to take advantage of these
  80. capabilities.
  81. 1.1 Tuning based on low level device / driver capabilities
  82. Sophisticated devices with large built-in caches, intelligent i/o scheduling
  83. optimizations, high memory DMA support, etc may find some of the
  84. generic processing an overhead, while for less capable devices the
  85. generic functionality is essential for performance or correctness reasons.
  86. Knowledge of some of the capabilities or parameters of the device should be
  87. used at the generic block layer to take the right decisions on
  88. behalf of the driver.
  89. How is this achieved ?
  90. Tuning at a per-queue level:
  91. i. Per-queue limits/values exported to the generic layer by the driver
  92. Various parameters that the generic i/o scheduler logic uses are set at
  93. a per-queue level (e.g maximum request size, maximum number of segments in
  94. a scatter-gather list, logical block size)
  95. Some parameters that were earlier available as global arrays indexed by
  96. major/minor are now directly associated with the queue. Some of these may
  97. move into the block device structure in the future. Some characteristics
  98. have been incorporated into a queue flags field rather than separate fields
  99. in themselves. There are blk_queue_xxx functions to set the parameters,
  100. rather than update the fields directly
  101. Some new queue property settings:
  102. blk_queue_bounce_limit(q, u64 dma_address)
  103. Enable I/O to highmem pages, dma_address being the
  104. limit. No highmem default.
  105. blk_queue_max_sectors(q, max_sectors)
  106. Sets two variables that limit the size of the request.
  107. - The request queue's max_sectors, which is a soft size in
  108. units of 512 byte sectors, and could be dynamically varied
  109. by the core kernel.
  110. - The request queue's max_hw_sectors, which is a hard limit
  111. and reflects the maximum size request a driver can handle
  112. in units of 512 byte sectors.
  113. The default for both max_sectors and max_hw_sectors is
  114. 255. The upper limit of max_sectors is 1024.
  115. blk_queue_max_phys_segments(q, max_segments)
  116. Maximum physical segments you can handle in a request. 128
  117. default (driver limit). (See 3.2.2)
  118. blk_queue_max_hw_segments(q, max_segments)
  119. Maximum dma segments the hardware can handle in a request. 128
  120. default (host adapter limit, after dma remapping).
  121. (See 3.2.2)
  122. blk_queue_max_segment_size(q, max_seg_size)
  123. Maximum size of a clustered segment, 64kB default.
  124. blk_queue_logical_block_size(q, logical_block_size)
  125. Lowest possible sector size that the hardware can operate
  126. on, 512 bytes default.
  127. New queue flags:
  128. QUEUE_FLAG_CLUSTER (see 3.2.2)
  129. QUEUE_FLAG_QUEUED (see 3.2.4)
  130. ii. High-mem i/o capabilities are now considered the default
  131. The generic bounce buffer logic, present in 2.4, where the block layer would
  132. by default copyin/out i/o requests on high-memory buffers to low-memory buffers
  133. assuming that the driver wouldn't be able to handle it directly, has been
  134. changed in 2.5. The bounce logic is now applied only for memory ranges
  135. for which the device cannot handle i/o. A driver can specify this by
  136. setting the queue bounce limit for the request queue for the device
  137. (blk_queue_bounce_limit()). This avoids the inefficiencies of the copyin/out
  138. where a device is capable of handling high memory i/o.
  139. In order to enable high-memory i/o where the device is capable of supporting
  140. it, the pci dma mapping routines and associated data structures have now been
  141. modified to accomplish a direct page -> bus translation, without requiring
  142. a virtual address mapping (unlike the earlier scheme of virtual address
  143. -> bus translation). So this works uniformly for high-memory pages (which
  144. do not have a corresponding kernel virtual address space mapping) and
  145. low-memory pages.
  146. Note: Please refer to Documentation/DMA-API-HOWTO.txt for a discussion
  147. on PCI high mem DMA aspects and mapping of scatter gather lists, and support
  148. for 64 bit PCI.
  149. Special handling is required only for cases where i/o needs to happen on
  150. pages at physical memory addresses beyond what the device can support. In these
  151. cases, a bounce bio representing a buffer from the supported memory range
  152. is used for performing the i/o with copyin/copyout as needed depending on
  153. the type of the operation. For example, in case of a read operation, the
  154. data read has to be copied to the original buffer on i/o completion, so a
  155. callback routine is set up to do this, while for write, the data is copied
  156. from the original buffer to the bounce buffer prior to issuing the
  157. operation. Since an original buffer may be in a high memory area that's not
  158. mapped in kernel virtual addr, a kmap operation may be required for
  159. performing the copy, and special care may be needed in the completion path
  160. as it may not be in irq context. Special care is also required (by way of
  161. GFP flags) when allocating bounce buffers, to avoid certain highmem
  162. deadlock possibilities.
  163. It is also possible that a bounce buffer may be allocated from high-memory
  164. area that's not mapped in kernel virtual addr, but within the range that the
  165. device can use directly; so the bounce page may need to be kmapped during
  166. copy operations. [Note: This does not hold in the current implementation,
  167. though]
  168. There are some situations when pages from high memory may need to
  169. be kmapped, even if bounce buffers are not necessary. For example a device
  170. may need to abort DMA operations and revert to PIO for the transfer, in
  171. which case a virtual mapping of the page is required. For SCSI it is also
  172. done in some scenarios where the low level driver cannot be trusted to
  173. handle a single sg entry correctly. The driver is expected to perform the
  174. kmaps as needed on such occasions using the __bio_kmap_atomic and bio_kmap_irq
  175. routines as appropriate. A driver could also use the blk_queue_bounce()
  176. routine on its own to bounce highmem i/o to low memory for specific requests
  177. if so desired.
  178. iii. The i/o scheduler algorithm itself can be replaced/set as appropriate
  179. As in 2.4, it is possible to plugin a brand new i/o scheduler for a particular
  180. queue or pick from (copy) existing generic schedulers and replace/override
  181. certain portions of it. The 2.5 rewrite provides improved modularization
  182. of the i/o scheduler. There are more pluggable callbacks, e.g for init,
  183. add request, extract request, which makes it possible to abstract specific
  184. i/o scheduling algorithm aspects and details outside of the generic loop.
  185. It also makes it possible to completely hide the implementation details of
  186. the i/o scheduler from block drivers.
  187. I/O scheduler wrappers are to be used instead of accessing the queue directly.
  188. See section 4. The I/O scheduler for details.
  189. 1.2 Tuning Based on High level code capabilities
  190. i. Application capabilities for raw i/o
  191. This comes from some of the high-performance database/middleware
  192. requirements where an application prefers to make its own i/o scheduling
  193. decisions based on an understanding of the access patterns and i/o
  194. characteristics
  195. ii. High performance filesystems or other higher level kernel code's
  196. capabilities
  197. Kernel components like filesystems could also take their own i/o scheduling
  198. decisions for optimizing performance. Journalling filesystems may need
  199. some control over i/o ordering.
  200. What kind of support exists at the generic block layer for this ?
  201. The flags and rw fields in the bio structure can be used for some tuning
  202. from above e.g indicating that an i/o is just a readahead request, or priority
  203. settings (currently unused). As far as user applications are concerned they
  204. would need an additional mechanism either via open flags or ioctls, or some
  205. other upper level mechanism to communicate such settings to block.
  206. 1.2.1 Request Priority/Latency
  207. Todo/Under discussion:
  208. Arjan's proposed request priority scheme allows higher levels some broad
  209. control (high/med/low) over the priority of an i/o request vs other pending
  210. requests in the queue. For example it allows reads for bringing in an
  211. executable page on demand to be given a higher priority over pending write
  212. requests which haven't aged too much on the queue. Potentially this priority
  213. could even be exposed to applications in some manner, providing higher level
  214. tunability. Time based aging avoids starvation of lower priority
  215. requests. Some bits in the bi_opf flags field in the bio structure are
  216. intended to be used for this priority information.
  217. 1.3 Direct Access to Low level Device/Driver Capabilities (Bypass mode)
  218. (e.g Diagnostics, Systems Management)
  219. There are situations where high-level code needs to have direct access to
  220. the low level device capabilities or requires the ability to issue commands
  221. to the device bypassing some of the intermediate i/o layers.
  222. These could, for example, be special control commands issued through ioctl
  223. interfaces, or could be raw read/write commands that stress the drive's
  224. capabilities for certain kinds of fitness tests. Having direct interfaces at
  225. multiple levels without having to pass through upper layers makes
  226. it possible to perform bottom up validation of the i/o path, layer by
  227. layer, starting from the media.
  228. The normal i/o submission interfaces, e.g submit_bio, could be bypassed
  229. for specially crafted requests which such ioctl or diagnostics
  230. interfaces would typically use, and the elevator add_request routine
  231. can instead be used to directly insert such requests in the queue or preferably
  232. the blk_do_rq routine can be used to place the request on the queue and
  233. wait for completion. Alternatively, sometimes the caller might just
  234. invoke a lower level driver specific interface with the request as a
  235. parameter.
  236. If the request is a means for passing on special information associated with
  237. the command, then such information is associated with the request->special
  238. field (rather than misuse the request->buffer field which is meant for the
  239. request data buffer's virtual mapping).
  240. For passing request data, the caller must build up a bio descriptor
  241. representing the concerned memory buffer if the underlying driver interprets
  242. bio segments or uses the block layer end*request* functions for i/o
  243. completion. Alternatively one could directly use the request->buffer field to
  244. specify the virtual address of the buffer, if the driver expects buffer
  245. addresses passed in this way and ignores bio entries for the request type
  246. involved. In the latter case, the driver would modify and manage the
  247. request->buffer, request->sector and request->nr_sectors or
  248. request->current_nr_sectors fields itself rather than using the block layer
  249. end_request or end_that_request_first completion interfaces.
  250. (See 2.3 or Documentation/block/request.txt for a brief explanation of
  251. the request structure fields)
  252. [TBD: end_that_request_last should be usable even in this case;
  253. Perhaps an end_that_direct_request_first routine could be implemented to make
  254. handling direct requests easier for such drivers; Also for drivers that
  255. expect bios, a helper function could be provided for setting up a bio
  256. corresponding to a data buffer]
  257. <JENS: I dont understand the above, why is end_that_request_first() not
  258. usable? Or _last for that matter. I must be missing something>
  259. <SUP: What I meant here was that if the request doesn't have a bio, then
  260. end_that_request_first doesn't modify nr_sectors or current_nr_sectors,
  261. and hence can't be used for advancing request state settings on the
  262. completion of partial transfers. The driver has to modify these fields
  263. directly by hand.
  264. This is because end_that_request_first only iterates over the bio list,
  265. and always returns 0 if there are none associated with the request.
  266. _last works OK in this case, and is not a problem, as I mentioned earlier
  267. >
  268. 1.3.1 Pre-built Commands
  269. A request can be created with a pre-built custom command to be sent directly
  270. to the device. The cmd block in the request structure has room for filling
  271. in the command bytes. (i.e rq->cmd is now 16 bytes in size, and meant for
  272. command pre-building, and the type of the request is now indicated
  273. through rq->flags instead of via rq->cmd)
  274. The request structure flags can be set up to indicate the type of request
  275. in such cases (REQ_PC: direct packet command passed to driver, REQ_BLOCK_PC:
  276. packet command issued via blk_do_rq, REQ_SPECIAL: special request).
  277. It can help to pre-build device commands for requests in advance.
  278. Drivers can now specify a request prepare function (q->prep_rq_fn) that the
  279. block layer would invoke to pre-build device commands for a given request,
  280. or perform other preparatory processing for the request. This is routine is
  281. called by elv_next_request(), i.e. typically just before servicing a request.
  282. (The prepare function would not be called for requests that have REQ_DONTPREP
  283. enabled)
  284. Aside:
  285. Pre-building could possibly even be done early, i.e before placing the
  286. request on the queue, rather than construct the command on the fly in the
  287. driver while servicing the request queue when it may affect latencies in
  288. interrupt context or responsiveness in general. One way to add early
  289. pre-building would be to do it whenever we fail to merge on a request.
  290. Now REQ_NOMERGE is set in the request flags to skip this one in the future,
  291. which means that it will not change before we feed it to the device. So
  292. the pre-builder hook can be invoked there.
  293. 2. Flexible and generic but minimalist i/o structure/descriptor.
  294. 2.1 Reason for a new structure and requirements addressed
  295. Prior to 2.5, buffer heads were used as the unit of i/o at the generic block
  296. layer, and the low level request structure was associated with a chain of
  297. buffer heads for a contiguous i/o request. This led to certain inefficiencies
  298. when it came to large i/o requests and readv/writev style operations, as it
  299. forced such requests to be broken up into small chunks before being passed
  300. on to the generic block layer, only to be merged by the i/o scheduler
  301. when the underlying device was capable of handling the i/o in one shot.
  302. Also, using the buffer head as an i/o structure for i/os that didn't originate
  303. from the buffer cache unnecessarily added to the weight of the descriptors
  304. which were generated for each such chunk.
  305. The following were some of the goals and expectations considered in the
  306. redesign of the block i/o data structure in 2.5.
  307. i. Should be appropriate as a descriptor for both raw and buffered i/o -
  308. avoid cache related fields which are irrelevant in the direct/page i/o path,
  309. or filesystem block size alignment restrictions which may not be relevant
  310. for raw i/o.
  311. ii. Ability to represent high-memory buffers (which do not have a virtual
  312. address mapping in kernel address space).
  313. iii.Ability to represent large i/os w/o unnecessarily breaking them up (i.e
  314. greater than PAGE_SIZE chunks in one shot)
  315. iv. At the same time, ability to retain independent identity of i/os from
  316. different sources or i/o units requiring individual completion (e.g. for
  317. latency reasons)
  318. v. Ability to represent an i/o involving multiple physical memory segments
  319. (including non-page aligned page fragments, as specified via readv/writev)
  320. without unnecessarily breaking it up, if the underlying device is capable of
  321. handling it.
  322. vi. Preferably should be based on a memory descriptor structure that can be
  323. passed around different types of subsystems or layers, maybe even
  324. networking, without duplication or extra copies of data/descriptor fields
  325. themselves in the process
  326. vii.Ability to handle the possibility of splits/merges as the structure passes
  327. through layered drivers (lvm, md, evms), with minimal overhead.
  328. The solution was to define a new structure (bio) for the block layer,
  329. instead of using the buffer head structure (bh) directly, the idea being
  330. avoidance of some associated baggage and limitations. The bio structure
  331. is uniformly used for all i/o at the block layer ; it forms a part of the
  332. bh structure for buffered i/o, and in the case of raw/direct i/o kiobufs are
  333. mapped to bio structures.
  334. 2.2 The bio struct
  335. The bio structure uses a vector representation pointing to an array of tuples
  336. of <page, offset, len> to describe the i/o buffer, and has various other
  337. fields describing i/o parameters and state that needs to be maintained for
  338. performing the i/o.
  339. Notice that this representation means that a bio has no virtual address
  340. mapping at all (unlike buffer heads).
  341. struct bio_vec {
  342. struct page *bv_page;
  343. unsigned short bv_len;
  344. unsigned short bv_offset;
  345. };
  346. /*
  347. * main unit of I/O for the block layer and lower layers (ie drivers)
  348. */
  349. struct bio {
  350. struct bio *bi_next; /* request queue link */
  351. struct block_device *bi_bdev; /* target device */
  352. unsigned long bi_flags; /* status, command, etc */
  353. unsigned long bi_opf; /* low bits: r/w, high: priority */
  354. unsigned int bi_vcnt; /* how may bio_vec's */
  355. struct bvec_iter bi_iter; /* current index into bio_vec array */
  356. unsigned int bi_size; /* total size in bytes */
  357. unsigned short bi_phys_segments; /* segments after physaddr coalesce*/
  358. unsigned short bi_hw_segments; /* segments after DMA remapping */
  359. unsigned int bi_max; /* max bio_vecs we can hold
  360. used as index into pool */
  361. struct bio_vec *bi_io_vec; /* the actual vec list */
  362. bio_end_io_t *bi_end_io; /* bi_end_io (bio) */
  363. atomic_t bi_cnt; /* pin count: free when it hits zero */
  364. void *bi_private;
  365. };
  366. With this multipage bio design:
  367. - Large i/os can be sent down in one go using a bio_vec list consisting
  368. of an array of <page, offset, len> fragments (similar to the way fragments
  369. are represented in the zero-copy network code)
  370. - Splitting of an i/o request across multiple devices (as in the case of
  371. lvm or raid) is achieved by cloning the bio (where the clone points to
  372. the same bi_io_vec array, but with the index and size accordingly modified)
  373. - A linked list of bios is used as before for unrelated merges (*) - this
  374. avoids reallocs and makes independent completions easier to handle.
  375. - Code that traverses the req list can find all the segments of a bio
  376. by using rq_for_each_segment. This handles the fact that a request
  377. has multiple bios, each of which can have multiple segments.
  378. - Drivers which can't process a large bio in one shot can use the bi_iter
  379. field to keep track of the next bio_vec entry to process.
  380. (e.g a 1MB bio_vec needs to be handled in max 128kB chunks for IDE)
  381. [TBD: Should preferably also have a bi_voffset and bi_vlen to avoid modifying
  382. bi_offset an len fields]
  383. (*) unrelated merges -- a request ends up containing two or more bios that
  384. didn't originate from the same place.
  385. bi_end_io() i/o callback gets called on i/o completion of the entire bio.
  386. At a lower level, drivers build a scatter gather list from the merged bios.
  387. The scatter gather list is in the form of an array of <page, offset, len>
  388. entries with their corresponding dma address mappings filled in at the
  389. appropriate time. As an optimization, contiguous physical pages can be
  390. covered by a single entry where <page> refers to the first page and <len>
  391. covers the range of pages (up to 16 contiguous pages could be covered this
  392. way). There is a helper routine (blk_rq_map_sg) which drivers can use to build
  393. the sg list.
  394. Note: Right now the only user of bios with more than one page is ll_rw_kio,
  395. which in turn means that only raw I/O uses it (direct i/o may not work
  396. right now). The intent however is to enable clustering of pages etc to
  397. become possible. The pagebuf abstraction layer from SGI also uses multi-page
  398. bios, but that is currently not included in the stock development kernels.
  399. The same is true of Andrew Morton's work-in-progress multipage bio writeout
  400. and readahead patches.
  401. 2.3 Changes in the Request Structure
  402. The request structure is the structure that gets passed down to low level
  403. drivers. The block layer make_request function builds up a request structure,
  404. places it on the queue and invokes the drivers request_fn. The driver makes
  405. use of block layer helper routine elv_next_request to pull the next request
  406. off the queue. Control or diagnostic functions might bypass block and directly
  407. invoke underlying driver entry points passing in a specially constructed
  408. request structure.
  409. Only some relevant fields (mainly those which changed or may be referred
  410. to in some of the discussion here) are listed below, not necessarily in
  411. the order in which they occur in the structure (see include/linux/blkdev.h)
  412. Refer to Documentation/block/request.txt for details about all the request
  413. structure fields and a quick reference about the layers which are
  414. supposed to use or modify those fields.
  415. struct request {
  416. struct list_head queuelist; /* Not meant to be directly accessed by
  417. the driver.
  418. Used by q->elv_next_request_fn
  419. rq->queue is gone
  420. */
  421. .
  422. .
  423. unsigned char cmd[16]; /* prebuilt command data block */
  424. unsigned long flags; /* also includes earlier rq->cmd settings */
  425. .
  426. .
  427. sector_t sector; /* this field is now of type sector_t instead of int
  428. preparation for 64 bit sectors */
  429. .
  430. .
  431. /* Number of scatter-gather DMA addr+len pairs after
  432. * physical address coalescing is performed.
  433. */
  434. unsigned short nr_phys_segments;
  435. /* Number of scatter-gather addr+len pairs after
  436. * physical and DMA remapping hardware coalescing is performed.
  437. * This is the number of scatter-gather entries the driver
  438. * will actually have to deal with after DMA mapping is done.
  439. */
  440. unsigned short nr_hw_segments;
  441. /* Various sector counts */
  442. unsigned long nr_sectors; /* no. of sectors left: driver modifiable */
  443. unsigned long hard_nr_sectors; /* block internal copy of above */
  444. unsigned int current_nr_sectors; /* no. of sectors left in the
  445. current segment:driver modifiable */
  446. unsigned long hard_cur_sectors; /* block internal copy of the above */
  447. .
  448. .
  449. int tag; /* command tag associated with request */
  450. void *special; /* same as before */
  451. char *buffer; /* valid only for low memory buffers up to
  452. current_nr_sectors */
  453. .
  454. .
  455. struct bio *bio, *biotail; /* bio list instead of bh */
  456. struct request_list *rl;
  457. }
  458. See the rq_flag_bits definitions for an explanation of the various flags
  459. available. Some bits are used by the block layer or i/o scheduler.
  460. The behaviour of the various sector counts are almost the same as before,
  461. except that since we have multi-segment bios, current_nr_sectors refers
  462. to the numbers of sectors in the current segment being processed which could
  463. be one of the many segments in the current bio (i.e i/o completion unit).
  464. The nr_sectors value refers to the total number of sectors in the whole
  465. request that remain to be transferred (no change). The purpose of the
  466. hard_xxx values is for block to remember these counts every time it hands
  467. over the request to the driver. These values are updated by block on
  468. end_that_request_first, i.e. every time the driver completes a part of the
  469. transfer and invokes block end*request helpers to mark this. The
  470. driver should not modify these values. The block layer sets up the
  471. nr_sectors and current_nr_sectors fields (based on the corresponding
  472. hard_xxx values and the number of bytes transferred) and updates it on
  473. every transfer that invokes end_that_request_first. It does the same for the
  474. buffer, bio, bio->bi_iter fields too.
  475. The buffer field is just a virtual address mapping of the current segment
  476. of the i/o buffer in cases where the buffer resides in low-memory. For high
  477. memory i/o, this field is not valid and must not be used by drivers.
  478. Code that sets up its own request structures and passes them down to
  479. a driver needs to be careful about interoperation with the block layer helper
  480. functions which the driver uses. (Section 1.3)
  481. 3. Using bios
  482. 3.1 Setup/Teardown
  483. There are routines for managing the allocation, and reference counting, and
  484. freeing of bios (bio_alloc, bio_get, bio_put).
  485. This makes use of Ingo Molnar's mempool implementation, which enables
  486. subsystems like bio to maintain their own reserve memory pools for guaranteed
  487. deadlock-free allocations during extreme VM load. For example, the VM
  488. subsystem makes use of the block layer to writeout dirty pages in order to be
  489. able to free up memory space, a case which needs careful handling. The
  490. allocation logic draws from the preallocated emergency reserve in situations
  491. where it cannot allocate through normal means. If the pool is empty and it
  492. can wait, then it would trigger action that would help free up memory or
  493. replenish the pool (without deadlocking) and wait for availability in the pool.
  494. If it is in IRQ context, and hence not in a position to do this, allocation
  495. could fail if the pool is empty. In general mempool always first tries to
  496. perform allocation without having to wait, even if it means digging into the
  497. pool as long it is not less that 50% full.
  498. On a free, memory is released to the pool or directly freed depending on
  499. the current availability in the pool. The mempool interface lets the
  500. subsystem specify the routines to be used for normal alloc and free. In the
  501. case of bio, these routines make use of the standard slab allocator.
  502. The caller of bio_alloc is expected to taken certain steps to avoid
  503. deadlocks, e.g. avoid trying to allocate more memory from the pool while
  504. already holding memory obtained from the pool.
  505. [TBD: This is a potential issue, though a rare possibility
  506. in the bounce bio allocation that happens in the current code, since
  507. it ends up allocating a second bio from the same pool while
  508. holding the original bio ]
  509. Memory allocated from the pool should be released back within a limited
  510. amount of time (in the case of bio, that would be after the i/o is completed).
  511. This ensures that if part of the pool has been used up, some work (in this
  512. case i/o) must already be in progress and memory would be available when it
  513. is over. If allocating from multiple pools in the same code path, the order
  514. or hierarchy of allocation needs to be consistent, just the way one deals
  515. with multiple locks.
  516. The bio_alloc routine also needs to allocate the bio_vec_list (bvec_alloc())
  517. for a non-clone bio. There are the 6 pools setup for different size biovecs,
  518. so bio_alloc(gfp_mask, nr_iovecs) will allocate a vec_list of the
  519. given size from these slabs.
  520. The bio_get() routine may be used to hold an extra reference on a bio prior
  521. to i/o submission, if the bio fields are likely to be accessed after the
  522. i/o is issued (since the bio may otherwise get freed in case i/o completion
  523. happens in the meantime).
  524. The bio_clone() routine may be used to duplicate a bio, where the clone
  525. shares the bio_vec_list with the original bio (i.e. both point to the
  526. same bio_vec_list). This would typically be used for splitting i/o requests
  527. in lvm or md.
  528. 3.2 Generic bio helper Routines
  529. 3.2.1 Traversing segments and completion units in a request
  530. The macro rq_for_each_segment() should be used for traversing the bios
  531. in the request list (drivers should avoid directly trying to do it
  532. themselves). Using these helpers should also make it easier to cope
  533. with block changes in the future.
  534. struct req_iterator iter;
  535. rq_for_each_segment(bio_vec, rq, iter)
  536. /* bio_vec is now current segment */
  537. I/O completion callbacks are per-bio rather than per-segment, so drivers
  538. that traverse bio chains on completion need to keep that in mind. Drivers
  539. which don't make a distinction between segments and completion units would
  540. need to be reorganized to support multi-segment bios.
  541. 3.2.2 Setting up DMA scatterlists
  542. The blk_rq_map_sg() helper routine would be used for setting up scatter
  543. gather lists from a request, so a driver need not do it on its own.
  544. nr_segments = blk_rq_map_sg(q, rq, scatterlist);
  545. The helper routine provides a level of abstraction which makes it easier
  546. to modify the internals of request to scatterlist conversion down the line
  547. without breaking drivers. The blk_rq_map_sg routine takes care of several
  548. things like collapsing physically contiguous segments (if QUEUE_FLAG_CLUSTER
  549. is set) and correct segment accounting to avoid exceeding the limits which
  550. the i/o hardware can handle, based on various queue properties.
  551. - Prevents a clustered segment from crossing a 4GB mem boundary
  552. - Avoids building segments that would exceed the number of physical
  553. memory segments that the driver can handle (phys_segments) and the
  554. number that the underlying hardware can handle at once, accounting for
  555. DMA remapping (hw_segments) (i.e. IOMMU aware limits).
  556. Routines which the low level driver can use to set up the segment limits:
  557. blk_queue_max_hw_segments() : Sets an upper limit of the maximum number of
  558. hw data segments in a request (i.e. the maximum number of address/length
  559. pairs the host adapter can actually hand to the device at once)
  560. blk_queue_max_phys_segments() : Sets an upper limit on the maximum number
  561. of physical data segments in a request (i.e. the largest sized scatter list
  562. a driver could handle)
  563. 3.2.3 I/O completion
  564. The existing generic block layer helper routines end_request,
  565. end_that_request_first and end_that_request_last can be used for i/o
  566. completion (and setting things up so the rest of the i/o or the next
  567. request can be kicked of) as before. With the introduction of multi-page
  568. bio support, end_that_request_first requires an additional argument indicating
  569. the number of sectors completed.
  570. 3.2.4 Implications for drivers that do not interpret bios (don't handle
  571. multiple segments)
  572. Drivers that do not interpret bios e.g those which do not handle multiple
  573. segments and do not support i/o into high memory addresses (require bounce
  574. buffers) and expect only virtually mapped buffers, can access the rq->buffer
  575. field. As before the driver should use current_nr_sectors to determine the
  576. size of remaining data in the current segment (that is the maximum it can
  577. transfer in one go unless it interprets segments), and rely on the block layer
  578. end_request, or end_that_request_first/last to take care of all accounting
  579. and transparent mapping of the next bio segment when a segment boundary
  580. is crossed on completion of a transfer. (The end*request* functions should
  581. be used if only if the request has come down from block/bio path, not for
  582. direct access requests which only specify rq->buffer without a valid rq->bio)
  583. 3.2.5 Generic request command tagging
  584. 3.2.5.1 Tag helpers
  585. Block now offers some simple generic functionality to help support command
  586. queueing (typically known as tagged command queueing), ie manage more than
  587. one outstanding command on a queue at any given time.
  588. blk_queue_init_tags(struct request_queue *q, int depth)
  589. Initialize internal command tagging structures for a maximum
  590. depth of 'depth'.
  591. blk_queue_free_tags((struct request_queue *q)
  592. Teardown tag info associated with the queue. This will be done
  593. automatically by block if blk_queue_cleanup() is called on a queue
  594. that is using tagging.
  595. The above are initialization and exit management, the main helpers during
  596. normal operations are:
  597. blk_queue_start_tag(struct request_queue *q, struct request *rq)
  598. Start tagged operation for this request. A free tag number between
  599. 0 and 'depth' is assigned to the request (rq->tag holds this number),
  600. and 'rq' is added to the internal tag management. If the maximum depth
  601. for this queue is already achieved (or if the tag wasn't started for
  602. some other reason), 1 is returned. Otherwise 0 is returned.
  603. blk_queue_end_tag(struct request_queue *q, struct request *rq)
  604. End tagged operation on this request. 'rq' is removed from the internal
  605. book keeping structures.
  606. To minimize struct request and queue overhead, the tag helpers utilize some
  607. of the same request members that are used for normal request queue management.
  608. This means that a request cannot both be an active tag and be on the queue
  609. list at the same time. blk_queue_start_tag() will remove the request, but
  610. the driver must remember to call blk_queue_end_tag() before signalling
  611. completion of the request to the block layer. This means ending tag
  612. operations before calling end_that_request_last()! For an example of a user
  613. of these helpers, see the IDE tagged command queueing support.
  614. Certain hardware conditions may dictate a need to invalidate the block tag
  615. queue. For instance, on IDE any tagged request error needs to clear both
  616. the hardware and software block queue and enable the driver to sanely restart
  617. all the outstanding requests. There's a third helper to do that:
  618. blk_queue_invalidate_tags(struct request_queue *q)
  619. Clear the internal block tag queue and re-add all the pending requests
  620. to the request queue. The driver will receive them again on the
  621. next request_fn run, just like it did the first time it encountered
  622. them.
  623. 3.2.5.2 Tag info
  624. Some block functions exist to query current tag status or to go from a
  625. tag number to the associated request. These are, in no particular order:
  626. blk_queue_tagged(q)
  627. Returns 1 if the queue 'q' is using tagging, 0 if not.
  628. blk_queue_tag_request(q, tag)
  629. Returns a pointer to the request associated with tag 'tag'.
  630. blk_queue_tag_depth(q)
  631. Return current queue depth.
  632. blk_queue_tag_queue(q)
  633. Returns 1 if the queue can accept a new queued command, 0 if we are
  634. at the maximum depth already.
  635. blk_queue_rq_tagged(rq)
  636. Returns 1 if the request 'rq' is tagged.
  637. 3.2.5.2 Internal structure
  638. Internally, block manages tags in the blk_queue_tag structure:
  639. struct blk_queue_tag {
  640. struct request **tag_index; /* array or pointers to rq */
  641. unsigned long *tag_map; /* bitmap of free tags */
  642. struct list_head busy_list; /* fifo list of busy tags */
  643. int busy; /* queue depth */
  644. int max_depth; /* max queue depth */
  645. };
  646. Most of the above is simple and straight forward, however busy_list may need
  647. a bit of explaining. Normally we don't care too much about request ordering,
  648. but in the event of any barrier requests in the tag queue we need to ensure
  649. that requests are restarted in the order they were queue. This may happen
  650. if the driver needs to use blk_queue_invalidate_tags().
  651. 3.3 I/O Submission
  652. The routine submit_bio() is used to submit a single io. Higher level i/o
  653. routines make use of this:
  654. (a) Buffered i/o:
  655. The routine submit_bh() invokes submit_bio() on a bio corresponding to the
  656. bh, allocating the bio if required. ll_rw_block() uses submit_bh() as before.
  657. (b) Kiobuf i/o (for raw/direct i/o):
  658. The ll_rw_kio() routine breaks up the kiobuf into page sized chunks and
  659. maps the array to one or more multi-page bios, issuing submit_bio() to
  660. perform the i/o on each of these.
  661. The embedded bh array in the kiobuf structure has been removed and no
  662. preallocation of bios is done for kiobufs. [The intent is to remove the
  663. blocks array as well, but it's currently in there to kludge around direct i/o.]
  664. Thus kiobuf allocation has switched back to using kmalloc rather than vmalloc.
  665. Todo/Observation:
  666. A single kiobuf structure is assumed to correspond to a contiguous range
  667. of data, so brw_kiovec() invokes ll_rw_kio for each kiobuf in a kiovec.
  668. So right now it wouldn't work for direct i/o on non-contiguous blocks.
  669. This is to be resolved. The eventual direction is to replace kiobuf
  670. by kvec's.
  671. Badari Pulavarty has a patch to implement direct i/o correctly using
  672. bio and kvec.
  673. (c) Page i/o:
  674. Todo/Under discussion:
  675. Andrew Morton's multi-page bio patches attempt to issue multi-page
  676. writeouts (and reads) from the page cache, by directly building up
  677. large bios for submission completely bypassing the usage of buffer
  678. heads. This work is still in progress.
  679. Christoph Hellwig had some code that uses bios for page-io (rather than
  680. bh). This isn't included in bio as yet. Christoph was also working on a
  681. design for representing virtual/real extents as an entity and modifying
  682. some of the address space ops interfaces to utilize this abstraction rather
  683. than buffer_heads. (This is somewhat along the lines of the SGI XFS pagebuf
  684. abstraction, but intended to be as lightweight as possible).
  685. (d) Direct access i/o:
  686. Direct access requests that do not contain bios would be submitted differently
  687. as discussed earlier in section 1.3.
  688. Aside:
  689. Kvec i/o:
  690. Ben LaHaise's aio code uses a slightly different structure instead
  691. of kiobufs, called a kvec_cb. This contains an array of <page, offset, len>
  692. tuples (very much like the networking code), together with a callback function
  693. and data pointer. This is embedded into a brw_cb structure when passed
  694. to brw_kvec_async().
  695. Now it should be possible to directly map these kvecs to a bio. Just as while
  696. cloning, in this case rather than PRE_BUILT bio_vecs, we set the bi_io_vec
  697. array pointer to point to the veclet array in kvecs.
  698. TBD: In order for this to work, some changes are needed in the way multi-page
  699. bios are handled today. The values of the tuples in such a vector passed in
  700. from higher level code should not be modified by the block layer in the course
  701. of its request processing, since that would make it hard for the higher layer
  702. to continue to use the vector descriptor (kvec) after i/o completes. Instead,
  703. all such transient state should either be maintained in the request structure,
  704. and passed on in some way to the endio completion routine.
  705. 4. The I/O scheduler
  706. I/O scheduler, a.k.a. elevator, is implemented in two layers. Generic dispatch
  707. queue and specific I/O schedulers. Unless stated otherwise, elevator is used
  708. to refer to both parts and I/O scheduler to specific I/O schedulers.
  709. Block layer implements generic dispatch queue in block/*.c.
  710. The generic dispatch queue is responsible for requeueing, handling non-fs
  711. requests and all other subtleties.
  712. Specific I/O schedulers are responsible for ordering normal filesystem
  713. requests. They can also choose to delay certain requests to improve
  714. throughput or whatever purpose. As the plural form indicates, there are
  715. multiple I/O schedulers. They can be built as modules but at least one should
  716. be built inside the kernel. Each queue can choose different one and can also
  717. change to another one dynamically.
  718. A block layer call to the i/o scheduler follows the convention elv_xxx(). This
  719. calls elevator_xxx_fn in the elevator switch (block/elevator.c). Oh, xxx
  720. and xxx might not match exactly, but use your imagination. If an elevator
  721. doesn't implement a function, the switch does nothing or some minimal house
  722. keeping work.
  723. 4.1. I/O scheduler API
  724. The functions an elevator may implement are: (* are mandatory)
  725. elevator_merge_fn called to query requests for merge with a bio
  726. elevator_merge_req_fn called when two requests get merged. the one
  727. which gets merged into the other one will be
  728. never seen by I/O scheduler again. IOW, after
  729. being merged, the request is gone.
  730. elevator_merged_fn called when a request in the scheduler has been
  731. involved in a merge. It is used in the deadline
  732. scheduler for example, to reposition the request
  733. if its sorting order has changed.
  734. elevator_allow_merge_fn called whenever the block layer determines
  735. that a bio can be merged into an existing
  736. request safely. The io scheduler may still
  737. want to stop a merge at this point if it
  738. results in some sort of conflict internally,
  739. this hook allows it to do that. Note however
  740. that two *requests* can still be merged at later
  741. time. Currently the io scheduler has no way to
  742. prevent that. It can only learn about the fact
  743. from elevator_merge_req_fn callback.
  744. elevator_dispatch_fn* fills the dispatch queue with ready requests.
  745. I/O schedulers are free to postpone requests by
  746. not filling the dispatch queue unless @force
  747. is non-zero. Once dispatched, I/O schedulers
  748. are not allowed to manipulate the requests -
  749. they belong to generic dispatch queue.
  750. elevator_add_req_fn* called to add a new request into the scheduler
  751. elevator_former_req_fn
  752. elevator_latter_req_fn These return the request before or after the
  753. one specified in disk sort order. Used by the
  754. block layer to find merge possibilities.
  755. elevator_completed_req_fn called when a request is completed.
  756. elevator_may_queue_fn returns true if the scheduler wants to allow the
  757. current context to queue a new request even if
  758. it is over the queue limit. This must be used
  759. very carefully!!
  760. elevator_set_req_fn
  761. elevator_put_req_fn Must be used to allocate and free any elevator
  762. specific storage for a request.
  763. elevator_activate_req_fn Called when device driver first sees a request.
  764. I/O schedulers can use this callback to
  765. determine when actual execution of a request
  766. starts.
  767. elevator_deactivate_req_fn Called when device driver decides to delay
  768. a request by requeueing it.
  769. elevator_init_fn*
  770. elevator_exit_fn Allocate and free any elevator specific storage
  771. for a queue.
  772. 4.2 Request flows seen by I/O schedulers
  773. All requests seen by I/O schedulers strictly follow one of the following three
  774. flows.
  775. set_req_fn ->
  776. i. add_req_fn -> (merged_fn ->)* -> dispatch_fn -> activate_req_fn ->
  777. (deactivate_req_fn -> activate_req_fn ->)* -> completed_req_fn
  778. ii. add_req_fn -> (merged_fn ->)* -> merge_req_fn
  779. iii. [none]
  780. -> put_req_fn
  781. 4.3 I/O scheduler implementation
  782. The generic i/o scheduler algorithm attempts to sort/merge/batch requests for
  783. optimal disk scan and request servicing performance (based on generic
  784. principles and device capabilities), optimized for:
  785. i. improved throughput
  786. ii. improved latency
  787. iii. better utilization of h/w & CPU time
  788. Characteristics:
  789. i. Binary tree
  790. AS and deadline i/o schedulers use red black binary trees for disk position
  791. sorting and searching, and a fifo linked list for time-based searching. This
  792. gives good scalability and good availability of information. Requests are
  793. almost always dispatched in disk sort order, so a cache is kept of the next
  794. request in sort order to prevent binary tree lookups.
  795. This arrangement is not a generic block layer characteristic however, so
  796. elevators may implement queues as they please.
  797. ii. Merge hash
  798. AS and deadline use a hash table indexed by the last sector of a request. This
  799. enables merging code to quickly look up "back merge" candidates, even when
  800. multiple I/O streams are being performed at once on one disk.
  801. "Front merges", a new request being merged at the front of an existing request,
  802. are far less common than "back merges" due to the nature of most I/O patterns.
  803. Front merges are handled by the binary trees in AS and deadline schedulers.
  804. iii. Plugging the queue to batch requests in anticipation of opportunities for
  805. merge/sort optimizations
  806. Plugging is an approach that the current i/o scheduling algorithm resorts to so
  807. that it collects up enough requests in the queue to be able to take
  808. advantage of the sorting/merging logic in the elevator. If the
  809. queue is empty when a request comes in, then it plugs the request queue
  810. (sort of like plugging the bath tub of a vessel to get fluid to build up)
  811. till it fills up with a few more requests, before starting to service
  812. the requests. This provides an opportunity to merge/sort the requests before
  813. passing them down to the device. There are various conditions when the queue is
  814. unplugged (to open up the flow again), either through a scheduled task or
  815. could be on demand. For example wait_on_buffer sets the unplugging going
  816. through sync_buffer() running blk_run_address_space(mapping). Or the caller
  817. can do it explicity through blk_unplug(bdev). So in the read case,
  818. the queue gets explicitly unplugged as part of waiting for completion on that
  819. buffer.
  820. Aside:
  821. This is kind of controversial territory, as it's not clear if plugging is
  822. always the right thing to do. Devices typically have their own queues,
  823. and allowing a big queue to build up in software, while letting the device be
  824. idle for a while may not always make sense. The trick is to handle the fine
  825. balance between when to plug and when to open up. Also now that we have
  826. multi-page bios being queued in one shot, we may not need to wait to merge
  827. a big request from the broken up pieces coming by.
  828. 4.4 I/O contexts
  829. I/O contexts provide a dynamically allocated per process data area. They may
  830. be used in I/O schedulers, and in the block layer (could be used for IO statis,
  831. priorities for example). See *io_context in block/ll_rw_blk.c, and as-iosched.c
  832. for an example of usage in an i/o scheduler.
  833. 5. Scalability related changes
  834. 5.1 Granular Locking: io_request_lock replaced by a per-queue lock
  835. The global io_request_lock has been removed as of 2.5, to avoid
  836. the scalability bottleneck it was causing, and has been replaced by more
  837. granular locking. The request queue structure has a pointer to the
  838. lock to be used for that queue. As a result, locking can now be
  839. per-queue, with a provision for sharing a lock across queues if
  840. necessary (e.g the scsi layer sets the queue lock pointers to the
  841. corresponding adapter lock, which results in a per host locking
  842. granularity). The locking semantics are the same, i.e. locking is
  843. still imposed by the block layer, grabbing the lock before
  844. request_fn execution which it means that lots of older drivers
  845. should still be SMP safe. Drivers are free to drop the queue
  846. lock themselves, if required. Drivers that explicitly used the
  847. io_request_lock for serialization need to be modified accordingly.
  848. Usually it's as easy as adding a global lock:
  849. static DEFINE_SPINLOCK(my_driver_lock);
  850. and passing the address to that lock to blk_init_queue().
  851. 5.2 64 bit sector numbers (sector_t prepares for 64 bit support)
  852. The sector number used in the bio structure has been changed to sector_t,
  853. which could be defined as 64 bit in preparation for 64 bit sector support.
  854. 6. Other Changes/Implications
  855. 6.1 Partition re-mapping handled by the generic block layer
  856. In 2.5 some of the gendisk/partition related code has been reorganized.
  857. Now the generic block layer performs partition-remapping early and thus
  858. provides drivers with a sector number relative to whole device, rather than
  859. having to take partition number into account in order to arrive at the true
  860. sector number. The routine blk_partition_remap() is invoked by
  861. generic_make_request even before invoking the queue specific make_request_fn,
  862. so the i/o scheduler also gets to operate on whole disk sector numbers. This
  863. should typically not require changes to block drivers, it just never gets
  864. to invoke its own partition sector offset calculations since all bios
  865. sent are offset from the beginning of the device.
  866. 7. A Few Tips on Migration of older drivers
  867. Old-style drivers that just use CURRENT and ignores clustered requests,
  868. may not need much change. The generic layer will automatically handle
  869. clustered requests, multi-page bios, etc for the driver.
  870. For a low performance driver or hardware that is PIO driven or just doesn't
  871. support scatter-gather changes should be minimal too.
  872. The following are some points to keep in mind when converting old drivers
  873. to bio.
  874. Drivers should use elv_next_request to pick up requests and are no longer
  875. supposed to handle looping directly over the request list.
  876. (struct request->queue has been removed)
  877. Now end_that_request_first takes an additional number_of_sectors argument.
  878. It used to handle always just the first buffer_head in a request, now
  879. it will loop and handle as many sectors (on a bio-segment granularity)
  880. as specified.
  881. Now bh->b_end_io is replaced by bio->bi_end_io, but most of the time the
  882. right thing to use is bio_endio(bio) instead.
  883. If the driver is dropping the io_request_lock from its request_fn strategy,
  884. then it just needs to replace that with q->queue_lock instead.
  885. As described in Sec 1.1, drivers can set max sector size, max segment size
  886. etc per queue now. Drivers that used to define their own merge functions i
  887. to handle things like this can now just use the blk_queue_* functions at
  888. blk_init_queue time.
  889. Drivers no longer have to map a {partition, sector offset} into the
  890. correct absolute location anymore, this is done by the block layer, so
  891. where a driver received a request ala this before:
  892. rq->rq_dev = mk_kdev(3, 5); /* /dev/hda5 */
  893. rq->sector = 0; /* first sector on hda5 */
  894. it will now see
  895. rq->rq_dev = mk_kdev(3, 0); /* /dev/hda */
  896. rq->sector = 123128; /* offset from start of disk */
  897. As mentioned, there is no virtual mapping of a bio. For DMA, this is
  898. not a problem as the driver probably never will need a virtual mapping.
  899. Instead it needs a bus mapping (dma_map_page for a single segment or
  900. use dma_map_sg for scatter gather) to be able to ship it to the driver. For
  901. PIO drivers (or drivers that need to revert to PIO transfer once in a
  902. while (IDE for example)), where the CPU is doing the actual data
  903. transfer a virtual mapping is needed. If the driver supports highmem I/O,
  904. (Sec 1.1, (ii) ) it needs to use __bio_kmap_atomic and bio_kmap_irq to
  905. temporarily map a bio into the virtual address space.
  906. 8. Prior/Related/Impacted patches
  907. 8.1. Earlier kiobuf patches (sct/axboe/chait/hch/mkp)
  908. - orig kiobuf & raw i/o patches (now in 2.4 tree)
  909. - direct kiobuf based i/o to devices (no intermediate bh's)
  910. - page i/o using kiobuf
  911. - kiobuf splitting for lvm (mkp)
  912. - elevator support for kiobuf request merging (axboe)
  913. 8.2. Zero-copy networking (Dave Miller)
  914. 8.3. SGI XFS - pagebuf patches - use of kiobufs
  915. 8.4. Multi-page pioent patch for bio (Christoph Hellwig)
  916. 8.5. Direct i/o implementation (Andrea Arcangeli) since 2.4.10-pre11
  917. 8.6. Async i/o implementation patch (Ben LaHaise)
  918. 8.7. EVMS layering design (IBM EVMS team)
  919. 8.8. Larger page cache size patch (Ben LaHaise) and
  920. Large page size (Daniel Phillips)
  921. => larger contiguous physical memory buffers
  922. 8.9. VM reservations patch (Ben LaHaise)
  923. 8.10. Write clustering patches ? (Marcelo/Quintela/Riel ?)
  924. 8.11. Block device in page cache patch (Andrea Archangeli) - now in 2.4.10+
  925. 8.12. Multiple block-size transfers for faster raw i/o (Shailabh Nagar,
  926. Badari)
  927. 8.13 Priority based i/o scheduler - prepatches (Arjan van de Ven)
  928. 8.14 IDE Taskfile i/o patch (Andre Hedrick)
  929. 8.15 Multi-page writeout and readahead patches (Andrew Morton)
  930. 8.16 Direct i/o patches for 2.5 using kvec and bio (Badari Pulavarthy)
  931. 9. Other References:
  932. 9.1 The Splice I/O Model - Larry McVoy (and subsequent discussions on lkml,
  933. and Linus' comments - Jan 2001)
  934. 9.2 Discussions about kiobuf and bh design on lkml between sct, linus, alan
  935. et al - Feb-March 2001 (many of the initial thoughts that led to bio were
  936. brought up in this discussion thread)
  937. 9.3 Discussions on mempool on lkml - Dec 2001.