1What:		/sys/block/<disk>/alignment_offset
2Date:		April 2009
3Contact:	Martin K. Petersen <martin.petersen@oracle.com>
4Description:
5		Storage devices may report a physical block size that is
6		bigger than the logical block size (for instance a drive
7		with 4KB physical sectors exposing 512-byte logical
8		blocks to the operating system).  This parameter
9		indicates how many bytes the beginning of the device is
10		offset from the disk's natural alignment.
11
12
13What:		/sys/block/<disk>/discard_alignment
14Date:		May 2011
15Contact:	Martin K. Petersen <martin.petersen@oracle.com>
16Description:
17		Devices that support discard functionality may
18		internally allocate space in units that are bigger than
19		the exported logical block size. The discard_alignment
20		parameter indicates how many bytes the beginning of the
21		device is offset from the internal allocation unit's
22		natural alignment.
23
24
25What:		/sys/block/<disk>/diskseq
26Date:		February 2021
27Contact:	Matteo Croce <mcroce@microsoft.com>
28Description:
29		The /sys/block/<disk>/diskseq files reports the disk
30		sequence number, which is a monotonically increasing
31		number assigned to every drive.
32		Some devices, like the loop device, refresh such number
33		every time the backing file is changed.
34		The value type is 64 bit unsigned.
35
36
37What:		/sys/block/<disk>/inflight
38Date:		October 2009
39Contact:	Jens Axboe <axboe@kernel.dk>, Nikanth Karthikesan <knikanth@suse.de>
40Description:
41		Reports the number of I/O requests currently in progress
42		(pending / in flight) in a device driver. This can be less
43		than the number of requests queued in the block device queue.
44		The report contains 2 fields: one for read requests
45		and one for write requests.
46		The value type is unsigned int.
47		Cf. Documentation/block/stat.rst which contains a single value for
48		requests in flight.
49		This is related to /sys/block/<disk>/queue/nr_requests
50		and for SCSI device also its queue_depth.
51
52
53What:		/sys/block/<disk>/integrity/device_is_integrity_capable
54Date:		July 2014
55Contact:	Martin K. Petersen <martin.petersen@oracle.com>
56Description:
57		Indicates whether a storage device is capable of storing
58		integrity metadata. Set if the device is T10 PI-capable.
59
60
61What:		/sys/block/<disk>/integrity/format
62Date:		June 2008
63Contact:	Martin K. Petersen <martin.petersen@oracle.com>
64Description:
65		Metadata format for integrity capable block device.
66		E.g. T10-DIF-TYPE1-CRC.
67
68
69What:		/sys/block/<disk>/integrity/protection_interval_bytes
70Date:		July 2015
71Contact:	Martin K. Petersen <martin.petersen@oracle.com>
72Description:
73		Describes the number of data bytes which are protected
74		by one integrity tuple. Typically the device's logical
75		block size.
76
77
78What:		/sys/block/<disk>/integrity/read_verify
79Date:		June 2008
80Contact:	Martin K. Petersen <martin.petersen@oracle.com>
81Description:
82		Indicates whether the block layer should verify the
83		integrity of read requests serviced by devices that
84		support sending integrity metadata.
85
86
87What:		/sys/block/<disk>/integrity/tag_size
88Date:		June 2008
89Contact:	Martin K. Petersen <martin.petersen@oracle.com>
90Description:
91		Number of bytes of integrity tag space available per
92		512 bytes of data.
93
94
95What:		/sys/block/<disk>/integrity/write_generate
96Date:		June 2008
97Contact:	Martin K. Petersen <martin.petersen@oracle.com>
98Description:
99		Indicates whether the block layer should automatically
100		generate checksums for write requests bound for
101		devices that support receiving integrity metadata.
102
103
104What:		/sys/block/<disk>/<partition>/alignment_offset
105Date:		April 2009
106Contact:	Martin K. Petersen <martin.petersen@oracle.com>
107Description:
108		Storage devices may report a physical block size that is
109		bigger than the logical block size (for instance a drive
110		with 4KB physical sectors exposing 512-byte logical
111		blocks to the operating system).  This parameter
112		indicates how many bytes the beginning of the partition
113		is offset from the disk's natural alignment.
114
115
116What:		/sys/block/<disk>/<partition>/discard_alignment
117Date:		May 2011
118Contact:	Martin K. Petersen <martin.petersen@oracle.com>
119Description:
120		Devices that support discard functionality may
121		internally allocate space in units that are bigger than
122		the exported logical block size. The discard_alignment
123		parameter indicates how many bytes the beginning of the
124		partition is offset from the internal allocation unit's
125		natural alignment.
126
127
128What:		/sys/block/<disk>/<partition>/stat
129Date:		February 2008
130Contact:	Jerome Marchand <jmarchan@redhat.com>
131Description:
132		The /sys/block/<disk>/<partition>/stat files display the
133		I/O statistics of partition <partition>. The format is the
134		same as the format of /sys/block/<disk>/stat.
135
136
137What:		/sys/block/<disk>/queue/add_random
138Date:		June 2010
139Contact:	linux-block@vger.kernel.org
140Description:
141		[RW] This file allows to turn off the disk entropy contribution.
142		Default value of this file is '1'(on).
143
144
145What:		/sys/block/<disk>/queue/chunk_sectors
146Date:		September 2016
147Contact:	Hannes Reinecke <hare@suse.com>
148Description:
149		[RO] chunk_sectors has different meaning depending on the type
150		of the disk. For a RAID device (dm-raid), chunk_sectors
151		indicates the size in 512B sectors of the RAID volume stripe
152		segment. For a zoned block device, either host-aware or
153		host-managed, chunk_sectors indicates the size in 512B sectors
154		of the zones of the device, with the eventual exception of the
155		last zone of the device which may be smaller.
156
157
158What:		/sys/block/<disk>/queue/dax
159Date:		June 2016
160Contact:	linux-block@vger.kernel.org
161Description:
162		[RO] This file indicates whether the device supports Direct
163		Access (DAX), used by CPU-addressable storage to bypass the
164		pagecache.  It shows '1' if true, '0' if not.
165
166
167What:		/sys/block/<disk>/queue/discard_granularity
168Date:		May 2011
169Contact:	Martin K. Petersen <martin.petersen@oracle.com>
170Description:
171		[RO] Devices that support discard functionality may internally
172		allocate space using units that are bigger than the logical
173		block size. The discard_granularity parameter indicates the size
174		of the internal allocation unit in bytes if reported by the
175		device. Otherwise the discard_granularity will be set to match
176		the device's physical block size. A discard_granularity of 0
177		means that the device does not support discard functionality.
178
179
180What:		/sys/block/<disk>/queue/discard_max_bytes
181Date:		May 2011
182Contact:	Martin K. Petersen <martin.petersen@oracle.com>
183Description:
184		[RW] While discard_max_hw_bytes is the hardware limit for the
185		device, this setting is the software limit. Some devices exhibit
186		large latencies when large discards are issued, setting this
187		value lower will make Linux issue smaller discards and
188		potentially help reduce latencies induced by large discard
189		operations.
190
191
192What:		/sys/block/<disk>/queue/discard_max_hw_bytes
193Date:		July 2015
194Contact:	linux-block@vger.kernel.org
195Description:
196		[RO] Devices that support discard functionality may have
197		internal limits on the number of bytes that can be trimmed or
198		unmapped in a single operation.  The `discard_max_hw_bytes`
199		parameter is set by the device driver to the maximum number of
200		bytes that can be discarded in a single operation.  Discard
201		requests issued to the device must not exceed this limit.  A
202		`discard_max_hw_bytes` value of 0 means that the device does not
203		support discard functionality.
204
205
206What:		/sys/block/<disk>/queue/discard_zeroes_data
207Date:		May 2011
208Contact:	Martin K. Petersen <martin.petersen@oracle.com>
209Description:
210		[RO] Will always return 0.  Don't rely on any specific behavior
211		for discards, and don't read this file.
212
213
214What:		/sys/block/<disk>/queue/fua
215Date:		May 2018
216Contact:	linux-block@vger.kernel.org
217Description:
218		[RO] Whether or not the block driver supports the FUA flag for
219		write requests.  FUA stands for Force Unit Access. If the FUA
220		flag is set that means that write requests must bypass the
221		volatile cache of the storage device.
222
223
224What:		/sys/block/<disk>/queue/hw_sector_size
225Date:		January 2008
226Contact:	linux-block@vger.kernel.org
227Description:
228		[RO] This is the hardware sector size of the device, in bytes.
229
230
231What:		/sys/block/<disk>/queue/independent_access_ranges/
232Date:		October 2021
233Contact:	linux-block@vger.kernel.org
234Description:
235		[RO] The presence of this sub-directory of the
236		/sys/block/xxx/queue/ directory indicates that the device is
237		capable of executing requests targeting different sector ranges
238		in parallel. For instance, single LUN multi-actuator hard-disks
239		will have an independent_access_ranges directory if the device
240		correctly advertizes the sector ranges of its actuators.
241
242		The independent_access_ranges directory contains one directory
243		per access range, with each range described using the sector
244		(RO) attribute file to indicate the first sector of the range
245		and the nr_sectors (RO) attribute file to indicate the total
246		number of sectors in the range starting from the first sector of
247		the range.  For example, a dual-actuator hard-disk will have the
248		following independent_access_ranges entries.::
249
250			$ tree /sys/block/<disk>/queue/independent_access_ranges/
251			/sys/block/<disk>/queue/independent_access_ranges/
252			|-- 0
253			|   |-- nr_sectors
254			|   `-- sector
255			`-- 1
256			    |-- nr_sectors
257			    `-- sector
258
259		The sector and nr_sectors attributes use 512B sector unit,
260		regardless of the actual block size of the device. Independent
261		access ranges do not overlap and include all sectors within the
262		device capacity. The access ranges are numbered in increasing
263		order of the range start sector, that is, the sector attribute
264		of range 0 always has the value 0.
265
266
267What:		/sys/block/<disk>/queue/io_poll
268Date:		November 2015
269Contact:	linux-block@vger.kernel.org
270Description:
271		[RW] When read, this file shows whether polling is enabled (1)
272		or disabled (0).  Writing '0' to this file will disable polling
273		for this device.  Writing any non-zero value will enable this
274		feature.
275
276
277What:		/sys/block/<disk>/queue/io_poll_delay
278Date:		November 2016
279Contact:	linux-block@vger.kernel.org
280Description:
281		[RW] If polling is enabled, this controls what kind of polling
282		will be performed. It defaults to -1, which is classic polling.
283		In this mode, the CPU will repeatedly ask for completions
284		without giving up any time.  If set to 0, a hybrid polling mode
285		is used, where the kernel will attempt to make an educated guess
286		at when the IO will complete. Based on this guess, the kernel
287		will put the process issuing IO to sleep for an amount of time,
288		before entering a classic poll loop. This mode might be a little
289		slower than pure classic polling, but it will be more efficient.
290		If set to a value larger than 0, the kernel will put the process
291		issuing IO to sleep for this amount of microseconds before
292		entering classic polling.
293
294
295What:		/sys/block/<disk>/queue/io_timeout
296Date:		November 2018
297Contact:	Weiping Zhang <zhangweiping@didiglobal.com>
298Description:
299		[RW] io_timeout is the request timeout in milliseconds. If a
300		request does not complete in this time then the block driver
301		timeout handler is invoked. That timeout handler can decide to
302		retry the request, to fail it or to start a device recovery
303		strategy.
304
305
306What:		/sys/block/<disk>/queue/iostats
307Date:		January 2009
308Contact:	linux-block@vger.kernel.org
309Description:
310		[RW] This file is used to control (on/off) the iostats
311		accounting of the disk.
312
313
314What:		/sys/block/<disk>/queue/logical_block_size
315Date:		May 2009
316Contact:	Martin K. Petersen <martin.petersen@oracle.com>
317Description:
318		[RO] This is the smallest unit the storage device can address.
319		It is typically 512 bytes.
320
321
322What:		/sys/block/<disk>/queue/max_active_zones
323Date:		July 2020
324Contact:	Niklas Cassel <niklas.cassel@wdc.com>
325Description:
326		[RO] For zoned block devices (zoned attribute indicating
327		"host-managed" or "host-aware"), the sum of zones belonging to
328		any of the zone states: EXPLICIT OPEN, IMPLICIT OPEN or CLOSED,
329		is limited by this value. If this value is 0, there is no limit.
330
331		If the host attempts to exceed this limit, the driver should
332		report this error with BLK_STS_ZONE_ACTIVE_RESOURCE, which user
333		space may see as the EOVERFLOW errno.
334
335
336What:		/sys/block/<disk>/queue/max_discard_segments
337Date:		February 2017
338Contact:	linux-block@vger.kernel.org
339Description:
340		[RO] The maximum number of DMA scatter/gather entries in a
341		discard request.
342
343
344What:		/sys/block/<disk>/queue/max_hw_sectors_kb
345Date:		September 2004
346Contact:	linux-block@vger.kernel.org
347Description:
348		[RO] This is the maximum number of kilobytes supported in a
349		single data transfer.
350
351
352What:		/sys/block/<disk>/queue/max_integrity_segments
353Date:		September 2010
354Contact:	linux-block@vger.kernel.org
355Description:
356		[RO] Maximum number of elements in a DMA scatter/gather list
357		with integrity data that will be submitted by the block layer
358		core to the associated block driver.
359
360
361What:		/sys/block/<disk>/queue/max_open_zones
362Date:		July 2020
363Contact:	Niklas Cassel <niklas.cassel@wdc.com>
364Description:
365		[RO] For zoned block devices (zoned attribute indicating
366		"host-managed" or "host-aware"), the sum of zones belonging to
367		any of the zone states: EXPLICIT OPEN or IMPLICIT OPEN, is
368		limited by this value. If this value is 0, there is no limit.
369
370
371What:		/sys/block/<disk>/queue/max_sectors_kb
372Date:		September 2004
373Contact:	linux-block@vger.kernel.org
374Description:
375		[RW] This is the maximum number of kilobytes that the block
376		layer will allow for a filesystem request. Must be smaller than
377		or equal to the maximum size allowed by the hardware.
378
379
380What:		/sys/block/<disk>/queue/max_segment_size
381Date:		March 2010
382Contact:	linux-block@vger.kernel.org
383Description:
384		[RO] Maximum size in bytes of a single element in a DMA
385		scatter/gather list.
386
387
388What:		/sys/block/<disk>/queue/max_segments
389Date:		March 2010
390Contact:	linux-block@vger.kernel.org
391Description:
392		[RO] Maximum number of elements in a DMA scatter/gather list
393		that is submitted to the associated block driver.
394
395
396What:		/sys/block/<disk>/queue/minimum_io_size
397Date:		April 2009
398Contact:	Martin K. Petersen <martin.petersen@oracle.com>
399Description:
400		[RO] Storage devices may report a granularity or preferred
401		minimum I/O size which is the smallest request the device can
402		perform without incurring a performance penalty.  For disk
403		drives this is often the physical block size.  For RAID arrays
404		it is often the stripe chunk size.  A properly aligned multiple
405		of minimum_io_size is the preferred request size for workloads
406		where a high number of I/O operations is desired.
407
408
409What:		/sys/block/<disk>/queue/nomerges
410Date:		January 2010
411Contact:	linux-block@vger.kernel.org
412Description:
413		[RW] Standard I/O elevator operations include attempts to merge
414		contiguous I/Os. For known random I/O loads these attempts will
415		always fail and result in extra cycles being spent in the
416		kernel. This allows one to turn off this behavior on one of two
417		ways: When set to 1, complex merge checks are disabled, but the
418		simple one-shot merges with the previous I/O request are
419		enabled. When set to 2, all merge tries are disabled. The
420		default value is 0 - which enables all types of merge tries.
421
422
423What:		/sys/block/<disk>/queue/nr_requests
424Date:		July 2003
425Contact:	linux-block@vger.kernel.org
426Description:
427		[RW] This controls how many requests may be allocated in the
428		block layer for read or write requests. Note that the total
429		allocated number may be twice this amount, since it applies only
430		to reads or writes (not the accumulated sum).
431
432		To avoid priority inversion through request starvation, a
433		request queue maintains a separate request pool per each cgroup
434		when CONFIG_BLK_CGROUP is enabled, and this parameter applies to
435		each such per-block-cgroup request pool.  IOW, if there are N
436		block cgroups, each request queue may have up to N request
437		pools, each independently regulated by nr_requests.
438
439
440What:		/sys/block/<disk>/queue/nr_zones
441Date:		November 2018
442Contact:	Damien Le Moal <damien.lemoal@wdc.com>
443Description:
444		[RO] nr_zones indicates the total number of zones of a zoned
445		block device ("host-aware" or "host-managed" zone model). For
446		regular block devices, the value is always 0.
447
448
449What:		/sys/block/<disk>/queue/optimal_io_size
450Date:		April 2009
451Contact:	Martin K. Petersen <martin.petersen@oracle.com>
452Description:
453		[RO] Storage devices may report an optimal I/O size, which is
454		the device's preferred unit for sustained I/O.  This is rarely
455		reported for disk drives.  For RAID arrays it is usually the
456		stripe width or the internal track size.  A properly aligned
457		multiple of optimal_io_size is the preferred request size for
458		workloads where sustained throughput is desired.  If no optimal
459		I/O size is reported this file contains 0.
460
461
462What:		/sys/block/<disk>/queue/physical_block_size
463Date:		May 2009
464Contact:	Martin K. Petersen <martin.petersen@oracle.com>
465Description:
466		[RO] This is the smallest unit a physical storage device can
467		write atomically.  It is usually the same as the logical block
468		size but may be bigger.  One example is SATA drives with 4KB
469		sectors that expose a 512-byte logical block size to the
470		operating system.  For stacked block devices the
471		physical_block_size variable contains the maximum
472		physical_block_size of the component devices.
473
474
475What:		/sys/block/<disk>/queue/read_ahead_kb
476Date:		May 2004
477Contact:	linux-block@vger.kernel.org
478Description:
479		[RW] Maximum number of kilobytes to read-ahead for filesystems
480		on this block device.
481
482
483What:		/sys/block/<disk>/queue/rotational
484Date:		January 2009
485Contact:	linux-block@vger.kernel.org
486Description:
487		[RW] This file is used to stat if the device is of rotational
488		type or non-rotational type.
489
490
491What:		/sys/block/<disk>/queue/rq_affinity
492Date:		September 2008
493Contact:	linux-block@vger.kernel.org
494Description:
495		[RW] If this option is '1', the block layer will migrate request
496		completions to the cpu "group" that originally submitted the
497		request. For some workloads this provides a significant
498		reduction in CPU cycles due to caching effects.
499
500		For storage configurations that need to maximize distribution of
501		completion processing setting this option to '2' forces the
502		completion to run on the requesting cpu (bypassing the "group"
503		aggregation logic).
504
505
506What:		/sys/block/<disk>/queue/scheduler
507Date:		October 2004
508Contact:	linux-block@vger.kernel.org
509Description:
510		[RW] When read, this file will display the current and available
511		IO schedulers for this block device. The currently active IO
512		scheduler will be enclosed in [] brackets. Writing an IO
513		scheduler name to this file will switch control of this block
514		device to that new IO scheduler. Note that writing an IO
515		scheduler name to this file will attempt to load that IO
516		scheduler module, if it isn't already present in the system.
517
518
519What:		/sys/block/<disk>/queue/stable_writes
520Date:		September 2020
521Contact:	linux-block@vger.kernel.org
522Description:
523		[RW] This file will contain '1' if memory must not be modified
524		while it is being used in a write request to this device.  When
525		this is the case and the kernel is performing writeback of a
526		page, the kernel will wait for writeback to complete before
527		allowing the page to be modified again, rather than allowing
528		immediate modification as is normally the case.  This
529		restriction arises when the device accesses the memory multiple
530		times where the same data must be seen every time -- for
531		example, once to calculate a checksum and once to actually write
532		the data.  If no such restriction exists, this file will contain
533		'0'.  This file is writable for testing purposes.
534
535
536What:		/sys/block/<disk>/queue/throttle_sample_time
537Date:		March 2017
538Contact:	linux-block@vger.kernel.org
539Description:
540		[RW] This is the time window that blk-throttle samples data, in
541		millisecond.  blk-throttle makes decision based on the
542		samplings. Lower time means cgroups have more smooth throughput,
543		but higher CPU overhead. This exists only when
544		CONFIG_BLK_DEV_THROTTLING_LOW is enabled.
545
546
547What:		/sys/block/<disk>/queue/virt_boundary_mask
548Date:		April 2021
549Contact:	linux-block@vger.kernel.org
550Description:
551		[RO] This file shows the I/O segment memory alignment mask for
552		the block device.  I/O requests to this device will be split
553		between segments wherever either the memory address of the end
554		of the previous segment or the memory address of the beginning
555		of the current segment is not aligned to virt_boundary_mask + 1
556		bytes.
557
558
559What:		/sys/block/<disk>/queue/wbt_lat_usec
560Date:		November 2016
561Contact:	linux-block@vger.kernel.org
562Description:
563		[RW] If the device is registered for writeback throttling, then
564		this file shows the target minimum read latency. If this latency
565		is exceeded in a given window of time (see wb_window_usec), then
566		the writeback throttling will start scaling back writes. Writing
567		a value of '0' to this file disables the feature. Writing a
568		value of '-1' to this file resets the value to the default
569		setting.
570
571
572What:		/sys/block/<disk>/queue/write_cache
573Date:		April 2016
574Contact:	linux-block@vger.kernel.org
575Description:
576		[RW] When read, this file will display whether the device has
577		write back caching enabled or not. It will return "write back"
578		for the former case, and "write through" for the latter. Writing
579		to this file can change the kernels view of the device, but it
580		doesn't alter the device state. This means that it might not be
581		safe to toggle the setting from "write back" to "write through",
582		since that will also eliminate cache flushes issued by the
583		kernel.
584
585
586What:		/sys/block/<disk>/queue/write_same_max_bytes
587Date:		January 2012
588Contact:	Martin K. Petersen <martin.petersen@oracle.com>
589Description:
590		[RO] Some devices support a write same operation in which a
591		single data block can be written to a range of several
592		contiguous blocks on storage. This can be used to wipe areas on
593		disk or to initialize drives in a RAID configuration.
594		write_same_max_bytes indicates how many bytes can be written in
595		a single write same command. If write_same_max_bytes is 0, write
596		same is not supported by the device.
597
598
599What:		/sys/block/<disk>/queue/write_zeroes_max_bytes
600Date:		November 2016
601Contact:	Chaitanya Kulkarni <chaitanya.kulkarni@wdc.com>
602Description:
603		[RO] Devices that support write zeroes operation in which a
604		single request can be issued to zero out the range of contiguous
605		blocks on storage without having any payload in the request.
606		This can be used to optimize writing zeroes to the devices.
607		write_zeroes_max_bytes indicates how many bytes can be written
608		in a single write zeroes command. If write_zeroes_max_bytes is
609		0, write zeroes is not supported by the device.
610
611
612What:		/sys/block/<disk>/queue/zone_append_max_bytes
613Date:		May 2020
614Contact:	linux-block@vger.kernel.org
615Description:
616		[RO] This is the maximum number of bytes that can be written to
617		a sequential zone of a zoned block device using a zone append
618		write operation (REQ_OP_ZONE_APPEND). This value is always 0 for
619		regular block devices.
620
621
622What:		/sys/block/<disk>/queue/zone_write_granularity
623Date:		January 2021
624Contact:	linux-block@vger.kernel.org
625Description:
626		[RO] This indicates the alignment constraint, in bytes, for
627		write operations in sequential zones of zoned block devices
628		(devices with a zoned attributed that reports "host-managed" or
629		"host-aware"). This value is always 0 for regular block devices.
630
631
632What:		/sys/block/<disk>/queue/zoned
633Date:		September 2016
634Contact:	Damien Le Moal <damien.lemoal@wdc.com>
635Description:
636		[RO] zoned indicates if the device is a zoned block device and
637		the zone model of the device if it is indeed zoned.  The
638		possible values indicated by zoned are "none" for regular block
639		devices and "host-aware" or "host-managed" for zoned block
640		devices. The characteristics of host-aware and host-managed
641		zoned block devices are described in the ZBC (Zoned Block
642		Commands) and ZAC (Zoned Device ATA Command Set) standards.
643		These standards also define the "drive-managed" zone model.
644		However, since drive-managed zoned block devices do not support
645		zone commands, they will be treated as regular block devices and
646		zoned will report "none".
647
648
649What:		/sys/block/<disk>/stat
650Date:		February 2008
651Contact:	Jerome Marchand <jmarchan@redhat.com>
652Description:
653		The /sys/block/<disk>/stat files displays the I/O
654		statistics of disk <disk>. They contain 11 fields:
655
656		==  ==============================================
657		 1  reads completed successfully
658		 2  reads merged
659		 3  sectors read
660		 4  time spent reading (ms)
661		 5  writes completed
662		 6  writes merged
663		 7  sectors written
664		 8  time spent writing (ms)
665		 9  I/Os currently in progress
666		10  time spent doing I/Os (ms)
667		11  weighted time spent doing I/Os (ms)
668		12  discards completed
669		13  discards merged
670		14  sectors discarded
671		15  time spent discarding (ms)
672		16  flush requests completed
673		17  time spent flushing (ms)
674		==  ==============================================
675
676		For more details refer Documentation/admin-guide/iostats.rst
677