1========= 2Workqueue 3========= 4 5:Date: September, 2010 6:Author: Tejun Heo <tj@kernel.org> 7:Author: Florian Mickler <florian@mickler.org> 8 9 10Introduction 11============ 12 13There are many cases where an asynchronous process execution context 14is needed and the workqueue (wq) API is the most commonly used 15mechanism for such cases. 16 17When such an asynchronous execution context is needed, a work item 18describing which function to execute is put on a queue. An 19independent thread serves as the asynchronous execution context. The 20queue is called workqueue and the thread is called worker. 21 22While there are work items on the workqueue the worker executes the 23functions associated with the work items one after the other. When 24there is no work item left on the workqueue the worker becomes idle. 25When a new work item gets queued, the worker begins executing again. 26 27 28Why Concurrency Managed Workqueue? 29================================== 30 31In the original wq implementation, a multi threaded (MT) wq had one 32worker thread per CPU and a single threaded (ST) wq had one worker 33thread system-wide. A single MT wq needed to keep around the same 34number of workers as the number of CPUs. The kernel grew a lot of MT 35wq users over the years and with the number of CPU cores continuously 36rising, some systems saturated the default 32k PID space just booting 37up. 38 39Although MT wq wasted a lot of resource, the level of concurrency 40provided was unsatisfactory. The limitation was common to both ST and 41MT wq albeit less severe on MT. Each wq maintained its own separate 42worker pool. An MT wq could provide only one execution context per CPU 43while an ST wq one for the whole system. Work items had to compete for 44those very limited execution contexts leading to various problems 45including proneness to deadlocks around the single execution context. 46 47The tension between the provided level of concurrency and resource 48usage also forced its users to make unnecessary tradeoffs like libata 49choosing to use ST wq for polling PIOs and accepting an unnecessary 50limitation that no two polling PIOs can progress at the same time. As 51MT wq don't provide much better concurrency, users which require 52higher level of concurrency, like async or fscache, had to implement 53their own thread pool. 54 55Concurrency Managed Workqueue (cmwq) is a reimplementation of wq with 56focus on the following goals. 57 58* Maintain compatibility with the original workqueue API. 59 60* Use per-CPU unified worker pools shared by all wq to provide 61 flexible level of concurrency on demand without wasting a lot of 62 resource. 63 64* Automatically regulate worker pool and level of concurrency so that 65 the API users don't need to worry about such details. 66 67 68The Design 69========== 70 71In order to ease the asynchronous execution of functions a new 72abstraction, the work item, is introduced. 73 74A work item is a simple struct that holds a pointer to the function 75that is to be executed asynchronously. Whenever a driver or subsystem 76wants a function to be executed asynchronously it has to set up a work 77item pointing to that function and queue that work item on a 78workqueue. 79 80Special purpose threads, called worker threads, execute the functions 81off of the queue, one after the other. If no work is queued, the 82worker threads become idle. These worker threads are managed in so 83called worker-pools. 84 85The cmwq design differentiates between the user-facing workqueues that 86subsystems and drivers queue work items on and the backend mechanism 87which manages worker-pools and processes the queued work items. 88 89There are two worker-pools, one for normal work items and the other 90for high priority ones, for each possible CPU and some extra 91worker-pools to serve work items queued on unbound workqueues - the 92number of these backing pools is dynamic. 93 94Subsystems and drivers can create and queue work items through special 95workqueue API functions as they see fit. They can influence some 96aspects of the way the work items are executed by setting flags on the 97workqueue they are putting the work item on. These flags include 98things like CPU locality, concurrency limits, priority and more. To 99get a detailed overview refer to the API description of 100``alloc_workqueue()`` below. 101 102When a work item is queued to a workqueue, the target worker-pool is 103determined according to the queue parameters and workqueue attributes 104and appended on the shared worklist of the worker-pool. For example, 105unless specifically overridden, a work item of a bound workqueue will 106be queued on the worklist of either normal or highpri worker-pool that 107is associated to the CPU the issuer is running on. 108 109For any worker pool implementation, managing the concurrency level 110(how many execution contexts are active) is an important issue. cmwq 111tries to keep the concurrency at a minimal but sufficient level. 112Minimal to save resources and sufficient in that the system is used at 113its full capacity. 114 115Each worker-pool bound to an actual CPU implements concurrency 116management by hooking into the scheduler. The worker-pool is notified 117whenever an active worker wakes up or sleeps and keeps track of the 118number of the currently runnable workers. Generally, work items are 119not expected to hog a CPU and consume many cycles. That means 120maintaining just enough concurrency to prevent work processing from 121stalling should be optimal. As long as there are one or more runnable 122workers on the CPU, the worker-pool doesn't start execution of a new 123work, but, when the last running worker goes to sleep, it immediately 124schedules a new worker so that the CPU doesn't sit idle while there 125are pending work items. This allows using a minimal number of workers 126without losing execution bandwidth. 127 128Keeping idle workers around doesn't cost other than the memory space 129for kthreads, so cmwq holds onto idle ones for a while before killing 130them. 131 132For unbound workqueues, the number of backing pools is dynamic. 133Unbound workqueue can be assigned custom attributes using 134``apply_workqueue_attrs()`` and workqueue will automatically create 135backing worker pools matching the attributes. The responsibility of 136regulating concurrency level is on the users. There is also a flag to 137mark a bound wq to ignore the concurrency management. Please refer to 138the API section for details. 139 140Forward progress guarantee relies on that workers can be created when 141more execution contexts are necessary, which in turn is guaranteed 142through the use of rescue workers. All work items which might be used 143on code paths that handle memory reclaim are required to be queued on 144wq's that have a rescue-worker reserved for execution under memory 145pressure. Else it is possible that the worker-pool deadlocks waiting 146for execution contexts to free up. 147 148 149Application Programming Interface (API) 150======================================= 151 152``alloc_workqueue()`` allocates a wq. The original 153``create_*workqueue()`` functions are deprecated and scheduled for 154removal. ``alloc_workqueue()`` takes three arguments - ``@name``, 155``@flags`` and ``@max_active``. ``@name`` is the name of the wq and 156also used as the name of the rescuer thread if there is one. 157 158A wq no longer manages execution resources but serves as a domain for 159forward progress guarantee, flush and work item attributes. ``@flags`` 160and ``@max_active`` control how work items are assigned execution 161resources, scheduled and executed. 162 163 164``flags`` 165--------- 166 167``WQ_UNBOUND`` 168 Work items queued to an unbound wq are served by the special 169 worker-pools which host workers which are not bound to any 170 specific CPU. This makes the wq behave as a simple execution 171 context provider without concurrency management. The unbound 172 worker-pools try to start execution of work items as soon as 173 possible. Unbound wq sacrifices locality but is useful for 174 the following cases. 175 176 * Wide fluctuation in the concurrency level requirement is 177 expected and using bound wq may end up creating large number 178 of mostly unused workers across different CPUs as the issuer 179 hops through different CPUs. 180 181 * Long running CPU intensive workloads which can be better 182 managed by the system scheduler. 183 184``WQ_FREEZABLE`` 185 A freezable wq participates in the freeze phase of the system 186 suspend operations. Work items on the wq are drained and no 187 new work item starts execution until thawed. 188 189``WQ_MEM_RECLAIM`` 190 All wq which might be used in the memory reclaim paths **MUST** 191 have this flag set. The wq is guaranteed to have at least one 192 execution context regardless of memory pressure. 193 194``WQ_HIGHPRI`` 195 Work items of a highpri wq are queued to the highpri 196 worker-pool of the target cpu. Highpri worker-pools are 197 served by worker threads with elevated nice level. 198 199 Note that normal and highpri worker-pools don't interact with 200 each other. Each maintains its separate pool of workers and 201 implements concurrency management among its workers. 202 203``WQ_CPU_INTENSIVE`` 204 Work items of a CPU intensive wq do not contribute to the 205 concurrency level. In other words, runnable CPU intensive 206 work items will not prevent other work items in the same 207 worker-pool from starting execution. This is useful for bound 208 work items which are expected to hog CPU cycles so that their 209 execution is regulated by the system scheduler. 210 211 Although CPU intensive work items don't contribute to the 212 concurrency level, start of their executions is still 213 regulated by the concurrency management and runnable 214 non-CPU-intensive work items can delay execution of CPU 215 intensive work items. 216 217 This flag is meaningless for unbound wq. 218 219 220``max_active`` 221-------------- 222 223``@max_active`` determines the maximum number of execution contexts per 224CPU which can be assigned to the work items of a wq. For example, with 225``@max_active`` of 16, at most 16 work items of the wq can be executing 226at the same time per CPU. This is always a per-CPU attribute, even for 227unbound workqueues. 228 229The maximum limit for ``@max_active`` is 512 and the default value used 230when 0 is specified is 256. These values are chosen sufficiently high 231such that they are not the limiting factor while providing protection in 232runaway cases. 233 234The number of active work items of a wq is usually regulated by the 235users of the wq, more specifically, by how many work items the users 236may queue at the same time. Unless there is a specific need for 237throttling the number of active work items, specifying '0' is 238recommended. 239 240Some users depend on the strict execution ordering of ST wq. The 241combination of ``@max_active`` of 1 and ``WQ_UNBOUND`` used to 242achieve this behavior. Work items on such wq were always queued to the 243unbound worker-pools and only one work item could be active at any given 244time thus achieving the same ordering property as ST wq. 245 246In the current implementation the above configuration only guarantees 247ST behavior within a given NUMA node. Instead ``alloc_ordered_queue()`` should 248be used to achieve system-wide ST behavior. 249 250 251Example Execution Scenarios 252=========================== 253 254The following example execution scenarios try to illustrate how cmwq 255behave under different configurations. 256 257 Work items w0, w1, w2 are queued to a bound wq q0 on the same CPU. 258 w0 burns CPU for 5ms then sleeps for 10ms then burns CPU for 5ms 259 again before finishing. w1 and w2 burn CPU for 5ms then sleep for 260 10ms. 261 262Ignoring all other tasks, works and processing overhead, and assuming 263simple FIFO scheduling, the following is one highly simplified version 264of possible sequences of events with the original wq. :: 265 266 TIME IN MSECS EVENT 267 0 w0 starts and burns CPU 268 5 w0 sleeps 269 15 w0 wakes up and burns CPU 270 20 w0 finishes 271 20 w1 starts and burns CPU 272 25 w1 sleeps 273 35 w1 wakes up and finishes 274 35 w2 starts and burns CPU 275 40 w2 sleeps 276 50 w2 wakes up and finishes 277 278And with cmwq with ``@max_active`` >= 3, :: 279 280 TIME IN MSECS EVENT 281 0 w0 starts and burns CPU 282 5 w0 sleeps 283 5 w1 starts and burns CPU 284 10 w1 sleeps 285 10 w2 starts and burns CPU 286 15 w2 sleeps 287 15 w0 wakes up and burns CPU 288 20 w0 finishes 289 20 w1 wakes up and finishes 290 25 w2 wakes up and finishes 291 292If ``@max_active`` == 2, :: 293 294 TIME IN MSECS EVENT 295 0 w0 starts and burns CPU 296 5 w0 sleeps 297 5 w1 starts and burns CPU 298 10 w1 sleeps 299 15 w0 wakes up and burns CPU 300 20 w0 finishes 301 20 w1 wakes up and finishes 302 20 w2 starts and burns CPU 303 25 w2 sleeps 304 35 w2 wakes up and finishes 305 306Now, let's assume w1 and w2 are queued to a different wq q1 which has 307``WQ_CPU_INTENSIVE`` set, :: 308 309 TIME IN MSECS EVENT 310 0 w0 starts and burns CPU 311 5 w0 sleeps 312 5 w1 and w2 start and burn CPU 313 10 w1 sleeps 314 15 w2 sleeps 315 15 w0 wakes up and burns CPU 316 20 w0 finishes 317 20 w1 wakes up and finishes 318 25 w2 wakes up and finishes 319 320 321Guidelines 322========== 323 324* Do not forget to use ``WQ_MEM_RECLAIM`` if a wq may process work 325 items which are used during memory reclaim. Each wq with 326 ``WQ_MEM_RECLAIM`` set has an execution context reserved for it. If 327 there is dependency among multiple work items used during memory 328 reclaim, they should be queued to separate wq each with 329 ``WQ_MEM_RECLAIM``. 330 331* Unless strict ordering is required, there is no need to use ST wq. 332 333* Unless there is a specific need, using 0 for @max_active is 334 recommended. In most use cases, concurrency level usually stays 335 well under the default limit. 336 337* A wq serves as a domain for forward progress guarantee 338 (``WQ_MEM_RECLAIM``, flush and work item attributes. Work items 339 which are not involved in memory reclaim and don't need to be 340 flushed as a part of a group of work items, and don't require any 341 special attribute, can use one of the system wq. There is no 342 difference in execution characteristics between using a dedicated wq 343 and a system wq. 344 345* Unless work items are expected to consume a huge amount of CPU 346 cycles, using a bound wq is usually beneficial due to the increased 347 level of locality in wq operations and work item execution. 348 349 350Affinity Scopes 351=============== 352 353An unbound workqueue groups CPUs according to its affinity scope to improve 354cache locality. For example, if a workqueue is using the default affinity 355scope of "cache", it will group CPUs according to last level cache 356boundaries. A work item queued on the workqueue will be assigned to a worker 357on one of the CPUs which share the last level cache with the issuing CPU. 358Once started, the worker may or may not be allowed to move outside the scope 359depending on the ``affinity_strict`` setting of the scope. 360 361Workqueue currently supports the following affinity scopes. 362 363``default`` 364 Use the scope in module parameter ``workqueue.default_affinity_scope`` 365 which is always set to one of the scopes below. 366 367``cpu`` 368 CPUs are not grouped. A work item issued on one CPU is processed by a 369 worker on the same CPU. This makes unbound workqueues behave as per-cpu 370 workqueues without concurrency management. 371 372``smt`` 373 CPUs are grouped according to SMT boundaries. This usually means that the 374 logical threads of each physical CPU core are grouped together. 375 376``cache`` 377 CPUs are grouped according to cache boundaries. Which specific cache 378 boundary is used is determined by the arch code. L3 is used in a lot of 379 cases. This is the default affinity scope. 380 381``numa`` 382 CPUs are grouped according to NUMA bounaries. 383 384``system`` 385 All CPUs are put in the same group. Workqueue makes no effort to process a 386 work item on a CPU close to the issuing CPU. 387 388The default affinity scope can be changed with the module parameter 389``workqueue.default_affinity_scope`` and a specific workqueue's affinity 390scope can be changed using ``apply_workqueue_attrs()``. 391 392If ``WQ_SYSFS`` is set, the workqueue will have the following affinity scope 393related interface files under its ``/sys/devices/virtual/WQ_NAME/`` 394directory. 395 396``affinity_scope`` 397 Read to see the current affinity scope. Write to change. 398 399 When default is the current scope, reading this file will also show the 400 current effective scope in parentheses, for example, ``default (cache)``. 401 402``affinity_strict`` 403 0 by default indicating that affinity scopes are not strict. When a work 404 item starts execution, workqueue makes a best-effort attempt to ensure 405 that the worker is inside its affinity scope, which is called 406 repatriation. Once started, the scheduler is free to move the worker 407 anywhere in the system as it sees fit. This enables benefiting from scope 408 locality while still being able to utilize other CPUs if necessary and 409 available. 410 411 If set to 1, all workers of the scope are guaranteed always to be in the 412 scope. This may be useful when crossing affinity scopes has other 413 implications, for example, in terms of power consumption or workload 414 isolation. Strict NUMA scope can also be used to match the workqueue 415 behavior of older kernels. 416 417 418Affinity Scopes and Performance 419=============================== 420 421It'd be ideal if an unbound workqueue's behavior is optimal for vast 422majority of use cases without further tuning. Unfortunately, in the current 423kernel, there exists a pronounced trade-off between locality and utilization 424necessitating explicit configurations when workqueues are heavily used. 425 426Higher locality leads to higher efficiency where more work is performed for 427the same number of consumed CPU cycles. However, higher locality may also 428cause lower overall system utilization if the work items are not spread 429enough across the affinity scopes by the issuers. The following performance 430testing with dm-crypt clearly illustrates this trade-off. 431 432The tests are run on a CPU with 12-cores/24-threads split across four L3 433caches (AMD Ryzen 9 3900x). CPU clock boost is turned off for consistency. 434``/dev/dm-0`` is a dm-crypt device created on NVME SSD (Samsung 990 PRO) and 435opened with ``cryptsetup`` with default settings. 436 437 438Scenario 1: Enough issuers and work spread across the machine 439------------------------------------------------------------- 440 441The command used: :: 442 443 $ fio --filename=/dev/dm-0 --direct=1 --rw=randrw --bs=32k --ioengine=libaio \ 444 --iodepth=64 --runtime=60 --numjobs=24 --time_based --group_reporting \ 445 --name=iops-test-job --verify=sha512 446 447There are 24 issuers, each issuing 64 IOs concurrently. ``--verify=sha512`` 448makes ``fio`` generate and read back the content each time which makes 449execution locality matter between the issuer and ``kcryptd``. The followings 450are the read bandwidths and CPU utilizations depending on different affinity 451scope settings on ``kcryptd`` measured over five runs. Bandwidths are in 452MiBps, and CPU util in percents. 453 454.. list-table:: 455 :widths: 16 20 20 456 :header-rows: 1 457 458 * - Affinity 459 - Bandwidth (MiBps) 460 - CPU util (%) 461 462 * - system 463 - 1159.40 ±1.34 464 - 99.31 ±0.02 465 466 * - cache 467 - 1166.40 ±0.89 468 - 99.34 ±0.01 469 470 * - cache (strict) 471 - 1166.00 ±0.71 472 - 99.35 ±0.01 473 474With enough issuers spread across the system, there is no downside to 475"cache", strict or otherwise. All three configurations saturate the whole 476machine but the cache-affine ones outperform by 0.6% thanks to improved 477locality. 478 479 480Scenario 2: Fewer issuers, enough work for saturation 481----------------------------------------------------- 482 483The command used: :: 484 485 $ fio --filename=/dev/dm-0 --direct=1 --rw=randrw --bs=32k \ 486 --ioengine=libaio --iodepth=64 --runtime=60 --numjobs=8 \ 487 --time_based --group_reporting --name=iops-test-job --verify=sha512 488 489The only difference from the previous scenario is ``--numjobs=8``. There are 490a third of the issuers but is still enough total work to saturate the 491system. 492 493.. list-table:: 494 :widths: 16 20 20 495 :header-rows: 1 496 497 * - Affinity 498 - Bandwidth (MiBps) 499 - CPU util (%) 500 501 * - system 502 - 1155.40 ±0.89 503 - 97.41 ±0.05 504 505 * - cache 506 - 1154.40 ±1.14 507 - 96.15 ±0.09 508 509 * - cache (strict) 510 - 1112.00 ±4.64 511 - 93.26 ±0.35 512 513This is more than enough work to saturate the system. Both "system" and 514"cache" are nearly saturating the machine but not fully. "cache" is using 515less CPU but the better efficiency puts it at the same bandwidth as 516"system". 517 518Eight issuers moving around over four L3 cache scope still allow "cache 519(strict)" to mostly saturate the machine but the loss of work conservation 520is now starting to hurt with 3.7% bandwidth loss. 521 522 523Scenario 3: Even fewer issuers, not enough work to saturate 524----------------------------------------------------------- 525 526The command used: :: 527 528 $ fio --filename=/dev/dm-0 --direct=1 --rw=randrw --bs=32k \ 529 --ioengine=libaio --iodepth=64 --runtime=60 --numjobs=4 \ 530 --time_based --group_reporting --name=iops-test-job --verify=sha512 531 532Again, the only difference is ``--numjobs=4``. With the number of issuers 533reduced to four, there now isn't enough work to saturate the whole system 534and the bandwidth becomes dependent on completion latencies. 535 536.. list-table:: 537 :widths: 16 20 20 538 :header-rows: 1 539 540 * - Affinity 541 - Bandwidth (MiBps) 542 - CPU util (%) 543 544 * - system 545 - 993.60 ±1.82 546 - 75.49 ±0.06 547 548 * - cache 549 - 973.40 ±1.52 550 - 74.90 ±0.07 551 552 * - cache (strict) 553 - 828.20 ±4.49 554 - 66.84 ±0.29 555 556Now, the tradeoff between locality and utilization is clearer. "cache" shows 5572% bandwidth loss compared to "system" and "cache (struct)" whopping 20%. 558 559 560Conclusion and Recommendations 561------------------------------ 562 563In the above experiments, the efficiency advantage of the "cache" affinity 564scope over "system" is, while consistent and noticeable, small. However, the 565impact is dependent on the distances between the scopes and may be more 566pronounced in processors with more complex topologies. 567 568While the loss of work-conservation in certain scenarios hurts, it is a lot 569better than "cache (strict)" and maximizing workqueue utilization is 570unlikely to be the common case anyway. As such, "cache" is the default 571affinity scope for unbound pools. 572 573* As there is no one option which is great for most cases, workqueue usages 574 that may consume a significant amount of CPU are recommended to configure 575 the workqueues using ``apply_workqueue_attrs()`` and/or enable 576 ``WQ_SYSFS``. 577 578* An unbound workqueue with strict "cpu" affinity scope behaves the same as 579 ``WQ_CPU_INTENSIVE`` per-cpu workqueue. There is no real advanage to the 580 latter and an unbound workqueue provides a lot more flexibility. 581 582* Affinity scopes are introduced in Linux v6.5. To emulate the previous 583 behavior, use strict "numa" affinity scope. 584 585* The loss of work-conservation in non-strict affinity scopes is likely 586 originating from the scheduler. There is no theoretical reason why the 587 kernel wouldn't be able to do the right thing and maintain 588 work-conservation in most cases. As such, it is possible that future 589 scheduler improvements may make most of these tunables unnecessary. 590 591 592Examining Configuration 593======================= 594 595Use tools/workqueue/wq_dump.py to examine unbound CPU affinity 596configuration, worker pools and how workqueues map to the pools: :: 597 598 $ tools/workqueue/wq_dump.py 599 Affinity Scopes 600 =============== 601 wq_unbound_cpumask=0000000f 602 603 CPU 604 nr_pods 4 605 pod_cpus [0]=00000001 [1]=00000002 [2]=00000004 [3]=00000008 606 pod_node [0]=0 [1]=0 [2]=1 [3]=1 607 cpu_pod [0]=0 [1]=1 [2]=2 [3]=3 608 609 SMT 610 nr_pods 4 611 pod_cpus [0]=00000001 [1]=00000002 [2]=00000004 [3]=00000008 612 pod_node [0]=0 [1]=0 [2]=1 [3]=1 613 cpu_pod [0]=0 [1]=1 [2]=2 [3]=3 614 615 CACHE (default) 616 nr_pods 2 617 pod_cpus [0]=00000003 [1]=0000000c 618 pod_node [0]=0 [1]=1 619 cpu_pod [0]=0 [1]=0 [2]=1 [3]=1 620 621 NUMA 622 nr_pods 2 623 pod_cpus [0]=00000003 [1]=0000000c 624 pod_node [0]=0 [1]=1 625 cpu_pod [0]=0 [1]=0 [2]=1 [3]=1 626 627 SYSTEM 628 nr_pods 1 629 pod_cpus [0]=0000000f 630 pod_node [0]=-1 631 cpu_pod [0]=0 [1]=0 [2]=0 [3]=0 632 633 Worker Pools 634 ============ 635 pool[00] ref= 1 nice= 0 idle/workers= 4/ 4 cpu= 0 636 pool[01] ref= 1 nice=-20 idle/workers= 2/ 2 cpu= 0 637 pool[02] ref= 1 nice= 0 idle/workers= 4/ 4 cpu= 1 638 pool[03] ref= 1 nice=-20 idle/workers= 2/ 2 cpu= 1 639 pool[04] ref= 1 nice= 0 idle/workers= 4/ 4 cpu= 2 640 pool[05] ref= 1 nice=-20 idle/workers= 2/ 2 cpu= 2 641 pool[06] ref= 1 nice= 0 idle/workers= 3/ 3 cpu= 3 642 pool[07] ref= 1 nice=-20 idle/workers= 2/ 2 cpu= 3 643 pool[08] ref=42 nice= 0 idle/workers= 6/ 6 cpus=0000000f 644 pool[09] ref=28 nice= 0 idle/workers= 3/ 3 cpus=00000003 645 pool[10] ref=28 nice= 0 idle/workers= 17/ 17 cpus=0000000c 646 pool[11] ref= 1 nice=-20 idle/workers= 1/ 1 cpus=0000000f 647 pool[12] ref= 2 nice=-20 idle/workers= 1/ 1 cpus=00000003 648 pool[13] ref= 2 nice=-20 idle/workers= 1/ 1 cpus=0000000c 649 650 Workqueue CPU -> pool 651 ===================== 652 [ workqueue \ CPU 0 1 2 3 dfl] 653 events percpu 0 2 4 6 654 events_highpri percpu 1 3 5 7 655 events_long percpu 0 2 4 6 656 events_unbound unbound 9 9 10 10 8 657 events_freezable percpu 0 2 4 6 658 events_power_efficient percpu 0 2 4 6 659 events_freezable_power_ percpu 0 2 4 6 660 rcu_gp percpu 0 2 4 6 661 rcu_par_gp percpu 0 2 4 6 662 slub_flushwq percpu 0 2 4 6 663 netns ordered 8 8 8 8 8 664 ... 665 666See the command's help message for more info. 667 668 669Monitoring 670========== 671 672Use tools/workqueue/wq_monitor.py to monitor workqueue operations: :: 673 674 $ tools/workqueue/wq_monitor.py events 675 total infl CPUtime CPUhog CMW/RPR mayday rescued 676 events 18545 0 6.1 0 5 - - 677 events_highpri 8 0 0.0 0 0 - - 678 events_long 3 0 0.0 0 0 - - 679 events_unbound 38306 0 0.1 - 7 - - 680 events_freezable 0 0 0.0 0 0 - - 681 events_power_efficient 29598 0 0.2 0 0 - - 682 events_freezable_power_ 10 0 0.0 0 0 - - 683 sock_diag_events 0 0 0.0 0 0 - - 684 685 total infl CPUtime CPUhog CMW/RPR mayday rescued 686 events 18548 0 6.1 0 5 - - 687 events_highpri 8 0 0.0 0 0 - - 688 events_long 3 0 0.0 0 0 - - 689 events_unbound 38322 0 0.1 - 7 - - 690 events_freezable 0 0 0.0 0 0 - - 691 events_power_efficient 29603 0 0.2 0 0 - - 692 events_freezable_power_ 10 0 0.0 0 0 - - 693 sock_diag_events 0 0 0.0 0 0 - - 694 695 ... 696 697See the command's help message for more info. 698 699 700Debugging 701========= 702 703Because the work functions are executed by generic worker threads 704there are a few tricks needed to shed some light on misbehaving 705workqueue users. 706 707Worker threads show up in the process list as: :: 708 709 root 5671 0.0 0.0 0 0 ? S 12:07 0:00 [kworker/0:1] 710 root 5672 0.0 0.0 0 0 ? S 12:07 0:00 [kworker/1:2] 711 root 5673 0.0 0.0 0 0 ? S 12:12 0:00 [kworker/0:0] 712 root 5674 0.0 0.0 0 0 ? S 12:13 0:00 [kworker/1:0] 713 714If kworkers are going crazy (using too much cpu), there are two types 715of possible problems: 716 717 1. Something being scheduled in rapid succession 718 2. A single work item that consumes lots of cpu cycles 719 720The first one can be tracked using tracing: :: 721 722 $ echo workqueue:workqueue_queue_work > /sys/kernel/tracing/set_event 723 $ cat /sys/kernel/tracing/trace_pipe > out.txt 724 (wait a few secs) 725 ^C 726 727If something is busy looping on work queueing, it would be dominating 728the output and the offender can be determined with the work item 729function. 730 731For the second type of problems it should be possible to just check 732the stack trace of the offending worker thread. :: 733 734 $ cat /proc/THE_OFFENDING_KWORKER/stack 735 736The work item's function should be trivially visible in the stack 737trace. 738 739 740Non-reentrance Conditions 741========================= 742 743Workqueue guarantees that a work item cannot be re-entrant if the following 744conditions hold after a work item gets queued: 745 746 1. The work function hasn't been changed. 747 2. No one queues the work item to another workqueue. 748 3. The work item hasn't been reinitiated. 749 750In other words, if the above conditions hold, the work item is guaranteed to be 751executed by at most one worker system-wide at any given time. 752 753Note that requeuing the work item (to the same queue) in the self function 754doesn't break these conditions, so it's safe to do. Otherwise, caution is 755required when breaking the conditions inside a work function. 756 757 758Kernel Inline Documentations Reference 759====================================== 760 761.. kernel-doc:: include/linux/workqueue.h 762 763.. kernel-doc:: kernel/workqueue.c 764