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1// SPDX-License-Identifier: GPL-2.0-only
2/*
3 * kernel/workqueue.c - generic async execution with shared worker pool
4 *
5 * Copyright (C) 2002 Ingo Molnar
6 *
7 * Derived from the taskqueue/keventd code by:
8 * David Woodhouse <dwmw2@infradead.org>
9 * Andrew Morton
10 * Kai Petzke <wpp@marie.physik.tu-berlin.de>
11 * Theodore Ts'o <tytso@mit.edu>
12 *
13 * Made to use alloc_percpu by Christoph Lameter.
14 *
15 * Copyright (C) 2010 SUSE Linux Products GmbH
16 * Copyright (C) 2010 Tejun Heo <tj@kernel.org>
17 *
18 * This is the generic async execution mechanism. Work items as are
19 * executed in process context. The worker pool is shared and
20 * automatically managed. There are two worker pools for each CPU (one for
21 * normal work items and the other for high priority ones) and some extra
22 * pools for workqueues which are not bound to any specific CPU - the
23 * number of these backing pools is dynamic.
24 *
25 * Please read Documentation/core-api/workqueue.rst for details.
26 */
27
28#include <linux/export.h>
29#include <linux/kernel.h>
30#include <linux/sched.h>
31#include <linux/init.h>
32#include <linux/signal.h>
33#include <linux/completion.h>
34#include <linux/workqueue.h>
35#include <linux/slab.h>
36#include <linux/cpu.h>
37#include <linux/notifier.h>
38#include <linux/kthread.h>
39#include <linux/hardirq.h>
40#include <linux/mempolicy.h>
41#include <linux/freezer.h>
42#include <linux/debug_locks.h>
43#include <linux/lockdep.h>
44#include <linux/idr.h>
45#include <linux/jhash.h>
46#include <linux/hashtable.h>
47#include <linux/rculist.h>
48#include <linux/nodemask.h>
49#include <linux/moduleparam.h>
50#include <linux/uaccess.h>
51#include <linux/sched/isolation.h>
52#include <linux/nmi.h>
53
54#include "workqueue_internal.h"
55
56enum {
57 /*
58 * worker_pool flags
59 *
60 * A bound pool is either associated or disassociated with its CPU.
61 * While associated (!DISASSOCIATED), all workers are bound to the
62 * CPU and none has %WORKER_UNBOUND set and concurrency management
63 * is in effect.
64 *
65 * While DISASSOCIATED, the cpu may be offline and all workers have
66 * %WORKER_UNBOUND set and concurrency management disabled, and may
67 * be executing on any CPU. The pool behaves as an unbound one.
68 *
69 * Note that DISASSOCIATED should be flipped only while holding
70 * wq_pool_attach_mutex to avoid changing binding state while
71 * worker_attach_to_pool() is in progress.
72 */
73 POOL_MANAGER_ACTIVE = 1 << 0, /* being managed */
74 POOL_DISASSOCIATED = 1 << 2, /* cpu can't serve workers */
75
76 /* worker flags */
77 WORKER_DIE = 1 << 1, /* die die die */
78 WORKER_IDLE = 1 << 2, /* is idle */
79 WORKER_PREP = 1 << 3, /* preparing to run works */
80 WORKER_CPU_INTENSIVE = 1 << 6, /* cpu intensive */
81 WORKER_UNBOUND = 1 << 7, /* worker is unbound */
82 WORKER_REBOUND = 1 << 8, /* worker was rebound */
83
84 WORKER_NOT_RUNNING = WORKER_PREP | WORKER_CPU_INTENSIVE |
85 WORKER_UNBOUND | WORKER_REBOUND,
86
87 NR_STD_WORKER_POOLS = 2, /* # standard pools per cpu */
88
89 UNBOUND_POOL_HASH_ORDER = 6, /* hashed by pool->attrs */
90 BUSY_WORKER_HASH_ORDER = 6, /* 64 pointers */
91
92 MAX_IDLE_WORKERS_RATIO = 4, /* 1/4 of busy can be idle */
93 IDLE_WORKER_TIMEOUT = 300 * HZ, /* keep idle ones for 5 mins */
94
95 MAYDAY_INITIAL_TIMEOUT = HZ / 100 >= 2 ? HZ / 100 : 2,
96 /* call for help after 10ms
97 (min two ticks) */
98 MAYDAY_INTERVAL = HZ / 10, /* and then every 100ms */
99 CREATE_COOLDOWN = HZ, /* time to breath after fail */
100
101 /*
102 * Rescue workers are used only on emergencies and shared by
103 * all cpus. Give MIN_NICE.
104 */
105 RESCUER_NICE_LEVEL = MIN_NICE,
106 HIGHPRI_NICE_LEVEL = MIN_NICE,
107
108 WQ_NAME_LEN = 24,
109};
110
111/*
112 * Structure fields follow one of the following exclusion rules.
113 *
114 * I: Modifiable by initialization/destruction paths and read-only for
115 * everyone else.
116 *
117 * P: Preemption protected. Disabling preemption is enough and should
118 * only be modified and accessed from the local cpu.
119 *
120 * L: pool->lock protected. Access with pool->lock held.
121 *
122 * X: During normal operation, modification requires pool->lock and should
123 * be done only from local cpu. Either disabling preemption on local
124 * cpu or grabbing pool->lock is enough for read access. If
125 * POOL_DISASSOCIATED is set, it's identical to L.
126 *
127 * A: wq_pool_attach_mutex protected.
128 *
129 * PL: wq_pool_mutex protected.
130 *
131 * PR: wq_pool_mutex protected for writes. RCU protected for reads.
132 *
133 * PW: wq_pool_mutex and wq->mutex protected for writes. Either for reads.
134 *
135 * PWR: wq_pool_mutex and wq->mutex protected for writes. Either or
136 * RCU for reads.
137 *
138 * WQ: wq->mutex protected.
139 *
140 * WR: wq->mutex protected for writes. RCU protected for reads.
141 *
142 * MD: wq_mayday_lock protected.
143 */
144
145/* struct worker is defined in workqueue_internal.h */
146
147struct worker_pool {
148 spinlock_t lock; /* the pool lock */
149 int cpu; /* I: the associated cpu */
150 int node; /* I: the associated node ID */
151 int id; /* I: pool ID */
152 unsigned int flags; /* X: flags */
153
154 unsigned long watchdog_ts; /* L: watchdog timestamp */
155
156 struct list_head worklist; /* L: list of pending works */
157
158 int nr_workers; /* L: total number of workers */
159 int nr_idle; /* L: currently idle workers */
160
161 struct list_head idle_list; /* X: list of idle workers */
162 struct timer_list idle_timer; /* L: worker idle timeout */
163 struct timer_list mayday_timer; /* L: SOS timer for workers */
164
165 /* a workers is either on busy_hash or idle_list, or the manager */
166 DECLARE_HASHTABLE(busy_hash, BUSY_WORKER_HASH_ORDER);
167 /* L: hash of busy workers */
168
169 struct worker *manager; /* L: purely informational */
170 struct list_head workers; /* A: attached workers */
171 struct completion *detach_completion; /* all workers detached */
172
173 struct ida worker_ida; /* worker IDs for task name */
174
175 struct workqueue_attrs *attrs; /* I: worker attributes */
176 struct hlist_node hash_node; /* PL: unbound_pool_hash node */
177 int refcnt; /* PL: refcnt for unbound pools */
178
179 /*
180 * The current concurrency level. As it's likely to be accessed
181 * from other CPUs during try_to_wake_up(), put it in a separate
182 * cacheline.
183 */
184 atomic_t nr_running ____cacheline_aligned_in_smp;
185
186 /*
187 * Destruction of pool is RCU protected to allow dereferences
188 * from get_work_pool().
189 */
190 struct rcu_head rcu;
191} ____cacheline_aligned_in_smp;
192
193/*
194 * The per-pool workqueue. While queued, the lower WORK_STRUCT_FLAG_BITS
195 * of work_struct->data are used for flags and the remaining high bits
196 * point to the pwq; thus, pwqs need to be aligned at two's power of the
197 * number of flag bits.
198 */
199struct pool_workqueue {
200 struct worker_pool *pool; /* I: the associated pool */
201 struct workqueue_struct *wq; /* I: the owning workqueue */
202 int work_color; /* L: current color */
203 int flush_color; /* L: flushing color */
204 int refcnt; /* L: reference count */
205 int nr_in_flight[WORK_NR_COLORS];
206 /* L: nr of in_flight works */
207 int nr_active; /* L: nr of active works */
208 int max_active; /* L: max active works */
209 struct list_head delayed_works; /* L: delayed works */
210 struct list_head pwqs_node; /* WR: node on wq->pwqs */
211 struct list_head mayday_node; /* MD: node on wq->maydays */
212
213 /*
214 * Release of unbound pwq is punted to system_wq. See put_pwq()
215 * and pwq_unbound_release_workfn() for details. pool_workqueue
216 * itself is also RCU protected so that the first pwq can be
217 * determined without grabbing wq->mutex.
218 */
219 struct work_struct unbound_release_work;
220 struct rcu_head rcu;
221} __aligned(1 << WORK_STRUCT_FLAG_BITS);
222
223/*
224 * Structure used to wait for workqueue flush.
225 */
226struct wq_flusher {
227 struct list_head list; /* WQ: list of flushers */
228 int flush_color; /* WQ: flush color waiting for */
229 struct completion done; /* flush completion */
230};
231
232struct wq_device;
233
234/*
235 * The externally visible workqueue. It relays the issued work items to
236 * the appropriate worker_pool through its pool_workqueues.
237 */
238struct workqueue_struct {
239 struct list_head pwqs; /* WR: all pwqs of this wq */
240 struct list_head list; /* PR: list of all workqueues */
241
242 struct mutex mutex; /* protects this wq */
243 int work_color; /* WQ: current work color */
244 int flush_color; /* WQ: current flush color */
245 atomic_t nr_pwqs_to_flush; /* flush in progress */
246 struct wq_flusher *first_flusher; /* WQ: first flusher */
247 struct list_head flusher_queue; /* WQ: flush waiters */
248 struct list_head flusher_overflow; /* WQ: flush overflow list */
249
250 struct list_head maydays; /* MD: pwqs requesting rescue */
251 struct worker *rescuer; /* I: rescue worker */
252
253 int nr_drainers; /* WQ: drain in progress */
254 int saved_max_active; /* WQ: saved pwq max_active */
255
256 struct workqueue_attrs *unbound_attrs; /* PW: only for unbound wqs */
257 struct pool_workqueue *dfl_pwq; /* PW: only for unbound wqs */
258
259#ifdef CONFIG_SYSFS
260 struct wq_device *wq_dev; /* I: for sysfs interface */
261#endif
262#ifdef CONFIG_LOCKDEP
263 char *lock_name;
264 struct lock_class_key key;
265 struct lockdep_map lockdep_map;
266#endif
267 char name[WQ_NAME_LEN]; /* I: workqueue name */
268
269 /*
270 * Destruction of workqueue_struct is RCU protected to allow walking
271 * the workqueues list without grabbing wq_pool_mutex.
272 * This is used to dump all workqueues from sysrq.
273 */
274 struct rcu_head rcu;
275
276 /* hot fields used during command issue, aligned to cacheline */
277 unsigned int flags ____cacheline_aligned; /* WQ: WQ_* flags */
278 struct pool_workqueue __percpu *cpu_pwqs; /* I: per-cpu pwqs */
279 struct pool_workqueue __rcu *numa_pwq_tbl[]; /* PWR: unbound pwqs indexed by node */
280};
281
282static struct kmem_cache *pwq_cache;
283
284static cpumask_var_t *wq_numa_possible_cpumask;
285 /* possible CPUs of each node */
286
287static bool wq_disable_numa;
288module_param_named(disable_numa, wq_disable_numa, bool, 0444);
289
290/* see the comment above the definition of WQ_POWER_EFFICIENT */
291static bool wq_power_efficient = IS_ENABLED(CONFIG_WQ_POWER_EFFICIENT_DEFAULT);
292module_param_named(power_efficient, wq_power_efficient, bool, 0444);
293
294static bool wq_online; /* can kworkers be created yet? */
295
296static bool wq_numa_enabled; /* unbound NUMA affinity enabled */
297
298/* buf for wq_update_unbound_numa_attrs(), protected by CPU hotplug exclusion */
299static struct workqueue_attrs *wq_update_unbound_numa_attrs_buf;
300
301static DEFINE_MUTEX(wq_pool_mutex); /* protects pools and workqueues list */
302static DEFINE_MUTEX(wq_pool_attach_mutex); /* protects worker attach/detach */
303static DEFINE_SPINLOCK(wq_mayday_lock); /* protects wq->maydays list */
304static DECLARE_WAIT_QUEUE_HEAD(wq_manager_wait); /* wait for manager to go away */
305
306static LIST_HEAD(workqueues); /* PR: list of all workqueues */
307static bool workqueue_freezing; /* PL: have wqs started freezing? */
308
309/* PL: allowable cpus for unbound wqs and work items */
310static cpumask_var_t wq_unbound_cpumask;
311
312/* CPU where unbound work was last round robin scheduled from this CPU */
313static DEFINE_PER_CPU(int, wq_rr_cpu_last);
314
315/*
316 * Local execution of unbound work items is no longer guaranteed. The
317 * following always forces round-robin CPU selection on unbound work items
318 * to uncover usages which depend on it.
319 */
320#ifdef CONFIG_DEBUG_WQ_FORCE_RR_CPU
321static bool wq_debug_force_rr_cpu = true;
322#else
323static bool wq_debug_force_rr_cpu = false;
324#endif
325module_param_named(debug_force_rr_cpu, wq_debug_force_rr_cpu, bool, 0644);
326
327/* the per-cpu worker pools */
328static DEFINE_PER_CPU_SHARED_ALIGNED(struct worker_pool [NR_STD_WORKER_POOLS], cpu_worker_pools);
329
330static DEFINE_IDR(worker_pool_idr); /* PR: idr of all pools */
331
332/* PL: hash of all unbound pools keyed by pool->attrs */
333static DEFINE_HASHTABLE(unbound_pool_hash, UNBOUND_POOL_HASH_ORDER);
334
335/* I: attributes used when instantiating standard unbound pools on demand */
336static struct workqueue_attrs *unbound_std_wq_attrs[NR_STD_WORKER_POOLS];
337
338/* I: attributes used when instantiating ordered pools on demand */
339static struct workqueue_attrs *ordered_wq_attrs[NR_STD_WORKER_POOLS];
340
341struct workqueue_struct *system_wq __read_mostly;
342EXPORT_SYMBOL(system_wq);
343struct workqueue_struct *system_highpri_wq __read_mostly;
344EXPORT_SYMBOL_GPL(system_highpri_wq);
345struct workqueue_struct *system_long_wq __read_mostly;
346EXPORT_SYMBOL_GPL(system_long_wq);
347struct workqueue_struct *system_unbound_wq __read_mostly;
348EXPORT_SYMBOL_GPL(system_unbound_wq);
349struct workqueue_struct *system_freezable_wq __read_mostly;
350EXPORT_SYMBOL_GPL(system_freezable_wq);
351struct workqueue_struct *system_power_efficient_wq __read_mostly;
352EXPORT_SYMBOL_GPL(system_power_efficient_wq);
353struct workqueue_struct *system_freezable_power_efficient_wq __read_mostly;
354EXPORT_SYMBOL_GPL(system_freezable_power_efficient_wq);
355
356static int worker_thread(void *__worker);
357static void workqueue_sysfs_unregister(struct workqueue_struct *wq);
358
359#define CREATE_TRACE_POINTS
360#include <trace/events/workqueue.h>
361
362#define assert_rcu_or_pool_mutex() \
363 RCU_LOCKDEP_WARN(!rcu_read_lock_held() && \
364 !lockdep_is_held(&wq_pool_mutex), \
365 "RCU or wq_pool_mutex should be held")
366
367#define assert_rcu_or_wq_mutex(wq) \
368 RCU_LOCKDEP_WARN(!rcu_read_lock_held() && \
369 !lockdep_is_held(&wq->mutex), \
370 "RCU or wq->mutex should be held")
371
372#define assert_rcu_or_wq_mutex_or_pool_mutex(wq) \
373 RCU_LOCKDEP_WARN(!rcu_read_lock_held() && \
374 !lockdep_is_held(&wq->mutex) && \
375 !lockdep_is_held(&wq_pool_mutex), \
376 "RCU, wq->mutex or wq_pool_mutex should be held")
377
378#define for_each_cpu_worker_pool(pool, cpu) \
379 for ((pool) = &per_cpu(cpu_worker_pools, cpu)[0]; \
380 (pool) < &per_cpu(cpu_worker_pools, cpu)[NR_STD_WORKER_POOLS]; \
381 (pool)++)
382
383/**
384 * for_each_pool - iterate through all worker_pools in the system
385 * @pool: iteration cursor
386 * @pi: integer used for iteration
387 *
388 * This must be called either with wq_pool_mutex held or RCU read
389 * locked. If the pool needs to be used beyond the locking in effect, the
390 * caller is responsible for guaranteeing that the pool stays online.
391 *
392 * The if/else clause exists only for the lockdep assertion and can be
393 * ignored.
394 */
395#define for_each_pool(pool, pi) \
396 idr_for_each_entry(&worker_pool_idr, pool, pi) \
397 if (({ assert_rcu_or_pool_mutex(); false; })) { } \
398 else
399
400/**
401 * for_each_pool_worker - iterate through all workers of a worker_pool
402 * @worker: iteration cursor
403 * @pool: worker_pool to iterate workers of
404 *
405 * This must be called with wq_pool_attach_mutex.
406 *
407 * The if/else clause exists only for the lockdep assertion and can be
408 * ignored.
409 */
410#define for_each_pool_worker(worker, pool) \
411 list_for_each_entry((worker), &(pool)->workers, node) \
412 if (({ lockdep_assert_held(&wq_pool_attach_mutex); false; })) { } \
413 else
414
415/**
416 * for_each_pwq - iterate through all pool_workqueues of the specified workqueue
417 * @pwq: iteration cursor
418 * @wq: the target workqueue
419 *
420 * This must be called either with wq->mutex held or RCU read locked.
421 * If the pwq needs to be used beyond the locking in effect, the caller is
422 * responsible for guaranteeing that the pwq stays online.
423 *
424 * The if/else clause exists only for the lockdep assertion and can be
425 * ignored.
426 */
427#define for_each_pwq(pwq, wq) \
428 list_for_each_entry_rcu((pwq), &(wq)->pwqs, pwqs_node) \
429 if (({ assert_rcu_or_wq_mutex(wq); false; })) { } \
430 else
431
432#ifdef CONFIG_DEBUG_OBJECTS_WORK
433
434static struct debug_obj_descr work_debug_descr;
435
436static void *work_debug_hint(void *addr)
437{
438 return ((struct work_struct *) addr)->func;
439}
440
441static bool work_is_static_object(void *addr)
442{
443 struct work_struct *work = addr;
444
445 return test_bit(WORK_STRUCT_STATIC_BIT, work_data_bits(work));
446}
447
448/*
449 * fixup_init is called when:
450 * - an active object is initialized
451 */
452static bool work_fixup_init(void *addr, enum debug_obj_state state)
453{
454 struct work_struct *work = addr;
455
456 switch (state) {
457 case ODEBUG_STATE_ACTIVE:
458 cancel_work_sync(work);
459 debug_object_init(work, &work_debug_descr);
460 return true;
461 default:
462 return false;
463 }
464}
465
466/*
467 * fixup_free is called when:
468 * - an active object is freed
469 */
470static bool work_fixup_free(void *addr, enum debug_obj_state state)
471{
472 struct work_struct *work = addr;
473
474 switch (state) {
475 case ODEBUG_STATE_ACTIVE:
476 cancel_work_sync(work);
477 debug_object_free(work, &work_debug_descr);
478 return true;
479 default:
480 return false;
481 }
482}
483
484static struct debug_obj_descr work_debug_descr = {
485 .name = "work_struct",
486 .debug_hint = work_debug_hint,
487 .is_static_object = work_is_static_object,
488 .fixup_init = work_fixup_init,
489 .fixup_free = work_fixup_free,
490};
491
492static inline void debug_work_activate(struct work_struct *work)
493{
494 debug_object_activate(work, &work_debug_descr);
495}
496
497static inline void debug_work_deactivate(struct work_struct *work)
498{
499 debug_object_deactivate(work, &work_debug_descr);
500}
501
502void __init_work(struct work_struct *work, int onstack)
503{
504 if (onstack)
505 debug_object_init_on_stack(work, &work_debug_descr);
506 else
507 debug_object_init(work, &work_debug_descr);
508}
509EXPORT_SYMBOL_GPL(__init_work);
510
511void destroy_work_on_stack(struct work_struct *work)
512{
513 debug_object_free(work, &work_debug_descr);
514}
515EXPORT_SYMBOL_GPL(destroy_work_on_stack);
516
517void destroy_delayed_work_on_stack(struct delayed_work *work)
518{
519 destroy_timer_on_stack(&work->timer);
520 debug_object_free(&work->work, &work_debug_descr);
521}
522EXPORT_SYMBOL_GPL(destroy_delayed_work_on_stack);
523
524#else
525static inline void debug_work_activate(struct work_struct *work) { }
526static inline void debug_work_deactivate(struct work_struct *work) { }
527#endif
528
529/**
530 * worker_pool_assign_id - allocate ID and assing it to @pool
531 * @pool: the pool pointer of interest
532 *
533 * Returns 0 if ID in [0, WORK_OFFQ_POOL_NONE) is allocated and assigned
534 * successfully, -errno on failure.
535 */
536static int worker_pool_assign_id(struct worker_pool *pool)
537{
538 int ret;
539
540 lockdep_assert_held(&wq_pool_mutex);
541
542 ret = idr_alloc(&worker_pool_idr, pool, 0, WORK_OFFQ_POOL_NONE,
543 GFP_KERNEL);
544 if (ret >= 0) {
545 pool->id = ret;
546 return 0;
547 }
548 return ret;
549}
550
551/**
552 * unbound_pwq_by_node - return the unbound pool_workqueue for the given node
553 * @wq: the target workqueue
554 * @node: the node ID
555 *
556 * This must be called with any of wq_pool_mutex, wq->mutex or RCU
557 * read locked.
558 * If the pwq needs to be used beyond the locking in effect, the caller is
559 * responsible for guaranteeing that the pwq stays online.
560 *
561 * Return: The unbound pool_workqueue for @node.
562 */
563static struct pool_workqueue *unbound_pwq_by_node(struct workqueue_struct *wq,
564 int node)
565{
566 assert_rcu_or_wq_mutex_or_pool_mutex(wq);
567
568 /*
569 * XXX: @node can be NUMA_NO_NODE if CPU goes offline while a
570 * delayed item is pending. The plan is to keep CPU -> NODE
571 * mapping valid and stable across CPU on/offlines. Once that
572 * happens, this workaround can be removed.
573 */
574 if (unlikely(node == NUMA_NO_NODE))
575 return wq->dfl_pwq;
576
577 return rcu_dereference_raw(wq->numa_pwq_tbl[node]);
578}
579
580static unsigned int work_color_to_flags(int color)
581{
582 return color << WORK_STRUCT_COLOR_SHIFT;
583}
584
585static int get_work_color(struct work_struct *work)
586{
587 return (*work_data_bits(work) >> WORK_STRUCT_COLOR_SHIFT) &
588 ((1 << WORK_STRUCT_COLOR_BITS) - 1);
589}
590
591static int work_next_color(int color)
592{
593 return (color + 1) % WORK_NR_COLORS;
594}
595
596/*
597 * While queued, %WORK_STRUCT_PWQ is set and non flag bits of a work's data
598 * contain the pointer to the queued pwq. Once execution starts, the flag
599 * is cleared and the high bits contain OFFQ flags and pool ID.
600 *
601 * set_work_pwq(), set_work_pool_and_clear_pending(), mark_work_canceling()
602 * and clear_work_data() can be used to set the pwq, pool or clear
603 * work->data. These functions should only be called while the work is
604 * owned - ie. while the PENDING bit is set.
605 *
606 * get_work_pool() and get_work_pwq() can be used to obtain the pool or pwq
607 * corresponding to a work. Pool is available once the work has been
608 * queued anywhere after initialization until it is sync canceled. pwq is
609 * available only while the work item is queued.
610 *
611 * %WORK_OFFQ_CANCELING is used to mark a work item which is being
612 * canceled. While being canceled, a work item may have its PENDING set
613 * but stay off timer and worklist for arbitrarily long and nobody should
614 * try to steal the PENDING bit.
615 */
616static inline void set_work_data(struct work_struct *work, unsigned long data,
617 unsigned long flags)
618{
619 WARN_ON_ONCE(!work_pending(work));
620 atomic_long_set(&work->data, data | flags | work_static(work));
621}
622
623static void set_work_pwq(struct work_struct *work, struct pool_workqueue *pwq,
624 unsigned long extra_flags)
625{
626 set_work_data(work, (unsigned long)pwq,
627 WORK_STRUCT_PENDING | WORK_STRUCT_PWQ | extra_flags);
628}
629
630static void set_work_pool_and_keep_pending(struct work_struct *work,
631 int pool_id)
632{
633 set_work_data(work, (unsigned long)pool_id << WORK_OFFQ_POOL_SHIFT,
634 WORK_STRUCT_PENDING);
635}
636
637static void set_work_pool_and_clear_pending(struct work_struct *work,
638 int pool_id)
639{
640 /*
641 * The following wmb is paired with the implied mb in
642 * test_and_set_bit(PENDING) and ensures all updates to @work made
643 * here are visible to and precede any updates by the next PENDING
644 * owner.
645 */
646 smp_wmb();
647 set_work_data(work, (unsigned long)pool_id << WORK_OFFQ_POOL_SHIFT, 0);
648 /*
649 * The following mb guarantees that previous clear of a PENDING bit
650 * will not be reordered with any speculative LOADS or STORES from
651 * work->current_func, which is executed afterwards. This possible
652 * reordering can lead to a missed execution on attempt to queue
653 * the same @work. E.g. consider this case:
654 *
655 * CPU#0 CPU#1
656 * ---------------------------- --------------------------------
657 *
658 * 1 STORE event_indicated
659 * 2 queue_work_on() {
660 * 3 test_and_set_bit(PENDING)
661 * 4 } set_..._and_clear_pending() {
662 * 5 set_work_data() # clear bit
663 * 6 smp_mb()
664 * 7 work->current_func() {
665 * 8 LOAD event_indicated
666 * }
667 *
668 * Without an explicit full barrier speculative LOAD on line 8 can
669 * be executed before CPU#0 does STORE on line 1. If that happens,
670 * CPU#0 observes the PENDING bit is still set and new execution of
671 * a @work is not queued in a hope, that CPU#1 will eventually
672 * finish the queued @work. Meanwhile CPU#1 does not see
673 * event_indicated is set, because speculative LOAD was executed
674 * before actual STORE.
675 */
676 smp_mb();
677}
678
679static void clear_work_data(struct work_struct *work)
680{
681 smp_wmb(); /* see set_work_pool_and_clear_pending() */
682 set_work_data(work, WORK_STRUCT_NO_POOL, 0);
683}
684
685static struct pool_workqueue *get_work_pwq(struct work_struct *work)
686{
687 unsigned long data = atomic_long_read(&work->data);
688
689 if (data & WORK_STRUCT_PWQ)
690 return (void *)(data & WORK_STRUCT_WQ_DATA_MASK);
691 else
692 return NULL;
693}
694
695/**
696 * get_work_pool - return the worker_pool a given work was associated with
697 * @work: the work item of interest
698 *
699 * Pools are created and destroyed under wq_pool_mutex, and allows read
700 * access under RCU read lock. As such, this function should be
701 * called under wq_pool_mutex or inside of a rcu_read_lock() region.
702 *
703 * All fields of the returned pool are accessible as long as the above
704 * mentioned locking is in effect. If the returned pool needs to be used
705 * beyond the critical section, the caller is responsible for ensuring the
706 * returned pool is and stays online.
707 *
708 * Return: The worker_pool @work was last associated with. %NULL if none.
709 */
710static struct worker_pool *get_work_pool(struct work_struct *work)
711{
712 unsigned long data = atomic_long_read(&work->data);
713 int pool_id;
714
715 assert_rcu_or_pool_mutex();
716
717 if (data & WORK_STRUCT_PWQ)
718 return ((struct pool_workqueue *)
719 (data & WORK_STRUCT_WQ_DATA_MASK))->pool;
720
721 pool_id = data >> WORK_OFFQ_POOL_SHIFT;
722 if (pool_id == WORK_OFFQ_POOL_NONE)
723 return NULL;
724
725 return idr_find(&worker_pool_idr, pool_id);
726}
727
728/**
729 * get_work_pool_id - return the worker pool ID a given work is associated with
730 * @work: the work item of interest
731 *
732 * Return: The worker_pool ID @work was last associated with.
733 * %WORK_OFFQ_POOL_NONE if none.
734 */
735static int get_work_pool_id(struct work_struct *work)
736{
737 unsigned long data = atomic_long_read(&work->data);
738
739 if (data & WORK_STRUCT_PWQ)
740 return ((struct pool_workqueue *)
741 (data & WORK_STRUCT_WQ_DATA_MASK))->pool->id;
742
743 return data >> WORK_OFFQ_POOL_SHIFT;
744}
745
746static void mark_work_canceling(struct work_struct *work)
747{
748 unsigned long pool_id = get_work_pool_id(work);
749
750 pool_id <<= WORK_OFFQ_POOL_SHIFT;
751 set_work_data(work, pool_id | WORK_OFFQ_CANCELING, WORK_STRUCT_PENDING);
752}
753
754static bool work_is_canceling(struct work_struct *work)
755{
756 unsigned long data = atomic_long_read(&work->data);
757
758 return !(data & WORK_STRUCT_PWQ) && (data & WORK_OFFQ_CANCELING);
759}
760
761/*
762 * Policy functions. These define the policies on how the global worker
763 * pools are managed. Unless noted otherwise, these functions assume that
764 * they're being called with pool->lock held.
765 */
766
767static bool __need_more_worker(struct worker_pool *pool)
768{
769 return !atomic_read(&pool->nr_running);
770}
771
772/*
773 * Need to wake up a worker? Called from anything but currently
774 * running workers.
775 *
776 * Note that, because unbound workers never contribute to nr_running, this
777 * function will always return %true for unbound pools as long as the
778 * worklist isn't empty.
779 */
780static bool need_more_worker(struct worker_pool *pool)
781{
782 return !list_empty(&pool->worklist) && __need_more_worker(pool);
783}
784
785/* Can I start working? Called from busy but !running workers. */
786static bool may_start_working(struct worker_pool *pool)
787{
788 return pool->nr_idle;
789}
790
791/* Do I need to keep working? Called from currently running workers. */
792static bool keep_working(struct worker_pool *pool)
793{
794 return !list_empty(&pool->worklist) &&
795 atomic_read(&pool->nr_running) <= 1;
796}
797
798/* Do we need a new worker? Called from manager. */
799static bool need_to_create_worker(struct worker_pool *pool)
800{
801 return need_more_worker(pool) && !may_start_working(pool);
802}
803
804/* Do we have too many workers and should some go away? */
805static bool too_many_workers(struct worker_pool *pool)
806{
807 bool managing = pool->flags & POOL_MANAGER_ACTIVE;
808 int nr_idle = pool->nr_idle + managing; /* manager is considered idle */
809 int nr_busy = pool->nr_workers - nr_idle;
810
811 return nr_idle > 2 && (nr_idle - 2) * MAX_IDLE_WORKERS_RATIO >= nr_busy;
812}
813
814/*
815 * Wake up functions.
816 */
817
818/* Return the first idle worker. Safe with preemption disabled */
819static struct worker *first_idle_worker(struct worker_pool *pool)
820{
821 if (unlikely(list_empty(&pool->idle_list)))
822 return NULL;
823
824 return list_first_entry(&pool->idle_list, struct worker, entry);
825}
826
827/**
828 * wake_up_worker - wake up an idle worker
829 * @pool: worker pool to wake worker from
830 *
831 * Wake up the first idle worker of @pool.
832 *
833 * CONTEXT:
834 * spin_lock_irq(pool->lock).
835 */
836static void wake_up_worker(struct worker_pool *pool)
837{
838 struct worker *worker = first_idle_worker(pool);
839
840 if (likely(worker))
841 wake_up_process(worker->task);
842}
843
844/**
845 * wq_worker_running - a worker is running again
846 * @task: task waking up
847 *
848 * This function is called when a worker returns from schedule()
849 */
850void wq_worker_running(struct task_struct *task)
851{
852 struct worker *worker = kthread_data(task);
853
854 if (!worker->sleeping)
855 return;
856 if (!(worker->flags & WORKER_NOT_RUNNING))
857 atomic_inc(&worker->pool->nr_running);
858 worker->sleeping = 0;
859}
860
861/**
862 * wq_worker_sleeping - a worker is going to sleep
863 * @task: task going to sleep
864 *
865 * This function is called from schedule() when a busy worker is
866 * going to sleep.
867 */
868void wq_worker_sleeping(struct task_struct *task)
869{
870 struct worker *next, *worker = kthread_data(task);
871 struct worker_pool *pool;
872
873 /*
874 * Rescuers, which may not have all the fields set up like normal
875 * workers, also reach here, let's not access anything before
876 * checking NOT_RUNNING.
877 */
878 if (worker->flags & WORKER_NOT_RUNNING)
879 return;
880
881 pool = worker->pool;
882
883 if (WARN_ON_ONCE(worker->sleeping))
884 return;
885
886 worker->sleeping = 1;
887 spin_lock_irq(&pool->lock);
888
889 /*
890 * The counterpart of the following dec_and_test, implied mb,
891 * worklist not empty test sequence is in insert_work().
892 * Please read comment there.
893 *
894 * NOT_RUNNING is clear. This means that we're bound to and
895 * running on the local cpu w/ rq lock held and preemption
896 * disabled, which in turn means that none else could be
897 * manipulating idle_list, so dereferencing idle_list without pool
898 * lock is safe.
899 */
900 if (atomic_dec_and_test(&pool->nr_running) &&
901 !list_empty(&pool->worklist)) {
902 next = first_idle_worker(pool);
903 if (next)
904 wake_up_process(next->task);
905 }
906 spin_unlock_irq(&pool->lock);
907}
908
909/**
910 * wq_worker_last_func - retrieve worker's last work function
911 * @task: Task to retrieve last work function of.
912 *
913 * Determine the last function a worker executed. This is called from
914 * the scheduler to get a worker's last known identity.
915 *
916 * CONTEXT:
917 * spin_lock_irq(rq->lock)
918 *
919 * This function is called during schedule() when a kworker is going
920 * to sleep. It's used by psi to identify aggregation workers during
921 * dequeuing, to allow periodic aggregation to shut-off when that
922 * worker is the last task in the system or cgroup to go to sleep.
923 *
924 * As this function doesn't involve any workqueue-related locking, it
925 * only returns stable values when called from inside the scheduler's
926 * queuing and dequeuing paths, when @task, which must be a kworker,
927 * is guaranteed to not be processing any works.
928 *
929 * Return:
930 * The last work function %current executed as a worker, NULL if it
931 * hasn't executed any work yet.
932 */
933work_func_t wq_worker_last_func(struct task_struct *task)
934{
935 struct worker *worker = kthread_data(task);
936
937 return worker->last_func;
938}
939
940/**
941 * worker_set_flags - set worker flags and adjust nr_running accordingly
942 * @worker: self
943 * @flags: flags to set
944 *
945 * Set @flags in @worker->flags and adjust nr_running accordingly.
946 *
947 * CONTEXT:
948 * spin_lock_irq(pool->lock)
949 */
950static inline void worker_set_flags(struct worker *worker, unsigned int flags)
951{
952 struct worker_pool *pool = worker->pool;
953
954 WARN_ON_ONCE(worker->task != current);
955
956 /* If transitioning into NOT_RUNNING, adjust nr_running. */
957 if ((flags & WORKER_NOT_RUNNING) &&
958 !(worker->flags & WORKER_NOT_RUNNING)) {
959 atomic_dec(&pool->nr_running);
960 }
961
962 worker->flags |= flags;
963}
964
965/**
966 * worker_clr_flags - clear worker flags and adjust nr_running accordingly
967 * @worker: self
968 * @flags: flags to clear
969 *
970 * Clear @flags in @worker->flags and adjust nr_running accordingly.
971 *
972 * CONTEXT:
973 * spin_lock_irq(pool->lock)
974 */
975static inline void worker_clr_flags(struct worker *worker, unsigned int flags)
976{
977 struct worker_pool *pool = worker->pool;
978 unsigned int oflags = worker->flags;
979
980 WARN_ON_ONCE(worker->task != current);
981
982 worker->flags &= ~flags;
983
984 /*
985 * If transitioning out of NOT_RUNNING, increment nr_running. Note
986 * that the nested NOT_RUNNING is not a noop. NOT_RUNNING is mask
987 * of multiple flags, not a single flag.
988 */
989 if ((flags & WORKER_NOT_RUNNING) && (oflags & WORKER_NOT_RUNNING))
990 if (!(worker->flags & WORKER_NOT_RUNNING))
991 atomic_inc(&pool->nr_running);
992}
993
994/**
995 * find_worker_executing_work - find worker which is executing a work
996 * @pool: pool of interest
997 * @work: work to find worker for
998 *
999 * Find a worker which is executing @work on @pool by searching
1000 * @pool->busy_hash which is keyed by the address of @work. For a worker
1001 * to match, its current execution should match the address of @work and
1002 * its work function. This is to avoid unwanted dependency between
1003 * unrelated work executions through a work item being recycled while still
1004 * being executed.
1005 *
1006 * This is a bit tricky. A work item may be freed once its execution
1007 * starts and nothing prevents the freed area from being recycled for
1008 * another work item. If the same work item address ends up being reused
1009 * before the original execution finishes, workqueue will identify the
1010 * recycled work item as currently executing and make it wait until the
1011 * current execution finishes, introducing an unwanted dependency.
1012 *
1013 * This function checks the work item address and work function to avoid
1014 * false positives. Note that this isn't complete as one may construct a
1015 * work function which can introduce dependency onto itself through a
1016 * recycled work item. Well, if somebody wants to shoot oneself in the
1017 * foot that badly, there's only so much we can do, and if such deadlock
1018 * actually occurs, it should be easy to locate the culprit work function.
1019 *
1020 * CONTEXT:
1021 * spin_lock_irq(pool->lock).
1022 *
1023 * Return:
1024 * Pointer to worker which is executing @work if found, %NULL
1025 * otherwise.
1026 */
1027static struct worker *find_worker_executing_work(struct worker_pool *pool,
1028 struct work_struct *work)
1029{
1030 struct worker *worker;
1031
1032 hash_for_each_possible(pool->busy_hash, worker, hentry,
1033 (unsigned long)work)
1034 if (worker->current_work == work &&
1035 worker->current_func == work->func)
1036 return worker;
1037
1038 return NULL;
1039}
1040
1041/**
1042 * move_linked_works - move linked works to a list
1043 * @work: start of series of works to be scheduled
1044 * @head: target list to append @work to
1045 * @nextp: out parameter for nested worklist walking
1046 *
1047 * Schedule linked works starting from @work to @head. Work series to
1048 * be scheduled starts at @work and includes any consecutive work with
1049 * WORK_STRUCT_LINKED set in its predecessor.
1050 *
1051 * If @nextp is not NULL, it's updated to point to the next work of
1052 * the last scheduled work. This allows move_linked_works() to be
1053 * nested inside outer list_for_each_entry_safe().
1054 *
1055 * CONTEXT:
1056 * spin_lock_irq(pool->lock).
1057 */
1058static void move_linked_works(struct work_struct *work, struct list_head *head,
1059 struct work_struct **nextp)
1060{
1061 struct work_struct *n;
1062
1063 /*
1064 * Linked worklist will always end before the end of the list,
1065 * use NULL for list head.
1066 */
1067 list_for_each_entry_safe_from(work, n, NULL, entry) {
1068 list_move_tail(&work->entry, head);
1069 if (!(*work_data_bits(work) & WORK_STRUCT_LINKED))
1070 break;
1071 }
1072
1073 /*
1074 * If we're already inside safe list traversal and have moved
1075 * multiple works to the scheduled queue, the next position
1076 * needs to be updated.
1077 */
1078 if (nextp)
1079 *nextp = n;
1080}
1081
1082/**
1083 * get_pwq - get an extra reference on the specified pool_workqueue
1084 * @pwq: pool_workqueue to get
1085 *
1086 * Obtain an extra reference on @pwq. The caller should guarantee that
1087 * @pwq has positive refcnt and be holding the matching pool->lock.
1088 */
1089static void get_pwq(struct pool_workqueue *pwq)
1090{
1091 lockdep_assert_held(&pwq->pool->lock);
1092 WARN_ON_ONCE(pwq->refcnt <= 0);
1093 pwq->refcnt++;
1094}
1095
1096/**
1097 * put_pwq - put a pool_workqueue reference
1098 * @pwq: pool_workqueue to put
1099 *
1100 * Drop a reference of @pwq. If its refcnt reaches zero, schedule its
1101 * destruction. The caller should be holding the matching pool->lock.
1102 */
1103static void put_pwq(struct pool_workqueue *pwq)
1104{
1105 lockdep_assert_held(&pwq->pool->lock);
1106 if (likely(--pwq->refcnt))
1107 return;
1108 if (WARN_ON_ONCE(!(pwq->wq->flags & WQ_UNBOUND)))
1109 return;
1110 /*
1111 * @pwq can't be released under pool->lock, bounce to
1112 * pwq_unbound_release_workfn(). This never recurses on the same
1113 * pool->lock as this path is taken only for unbound workqueues and
1114 * the release work item is scheduled on a per-cpu workqueue. To
1115 * avoid lockdep warning, unbound pool->locks are given lockdep
1116 * subclass of 1 in get_unbound_pool().
1117 */
1118 schedule_work(&pwq->unbound_release_work);
1119}
1120
1121/**
1122 * put_pwq_unlocked - put_pwq() with surrounding pool lock/unlock
1123 * @pwq: pool_workqueue to put (can be %NULL)
1124 *
1125 * put_pwq() with locking. This function also allows %NULL @pwq.
1126 */
1127static void put_pwq_unlocked(struct pool_workqueue *pwq)
1128{
1129 if (pwq) {
1130 /*
1131 * As both pwqs and pools are RCU protected, the
1132 * following lock operations are safe.
1133 */
1134 spin_lock_irq(&pwq->pool->lock);
1135 put_pwq(pwq);
1136 spin_unlock_irq(&pwq->pool->lock);
1137 }
1138}
1139
1140static void pwq_activate_delayed_work(struct work_struct *work)
1141{
1142 struct pool_workqueue *pwq = get_work_pwq(work);
1143
1144 trace_workqueue_activate_work(work);
1145 if (list_empty(&pwq->pool->worklist))
1146 pwq->pool->watchdog_ts = jiffies;
1147 move_linked_works(work, &pwq->pool->worklist, NULL);
1148 __clear_bit(WORK_STRUCT_DELAYED_BIT, work_data_bits(work));
1149 pwq->nr_active++;
1150}
1151
1152static void pwq_activate_first_delayed(struct pool_workqueue *pwq)
1153{
1154 struct work_struct *work = list_first_entry(&pwq->delayed_works,
1155 struct work_struct, entry);
1156
1157 pwq_activate_delayed_work(work);
1158}
1159
1160/**
1161 * pwq_dec_nr_in_flight - decrement pwq's nr_in_flight
1162 * @pwq: pwq of interest
1163 * @color: color of work which left the queue
1164 *
1165 * A work either has completed or is removed from pending queue,
1166 * decrement nr_in_flight of its pwq and handle workqueue flushing.
1167 *
1168 * CONTEXT:
1169 * spin_lock_irq(pool->lock).
1170 */
1171static void pwq_dec_nr_in_flight(struct pool_workqueue *pwq, int color)
1172{
1173 /* uncolored work items don't participate in flushing or nr_active */
1174 if (color == WORK_NO_COLOR)
1175 goto out_put;
1176
1177 pwq->nr_in_flight[color]--;
1178
1179 pwq->nr_active--;
1180 if (!list_empty(&pwq->delayed_works)) {
1181 /* one down, submit a delayed one */
1182 if (pwq->nr_active < pwq->max_active)
1183 pwq_activate_first_delayed(pwq);
1184 }
1185
1186 /* is flush in progress and are we at the flushing tip? */
1187 if (likely(pwq->flush_color != color))
1188 goto out_put;
1189
1190 /* are there still in-flight works? */
1191 if (pwq->nr_in_flight[color])
1192 goto out_put;
1193
1194 /* this pwq is done, clear flush_color */
1195 pwq->flush_color = -1;
1196
1197 /*
1198 * If this was the last pwq, wake up the first flusher. It
1199 * will handle the rest.
1200 */
1201 if (atomic_dec_and_test(&pwq->wq->nr_pwqs_to_flush))
1202 complete(&pwq->wq->first_flusher->done);
1203out_put:
1204 put_pwq(pwq);
1205}
1206
1207/**
1208 * try_to_grab_pending - steal work item from worklist and disable irq
1209 * @work: work item to steal
1210 * @is_dwork: @work is a delayed_work
1211 * @flags: place to store irq state
1212 *
1213 * Try to grab PENDING bit of @work. This function can handle @work in any
1214 * stable state - idle, on timer or on worklist.
1215 *
1216 * Return:
1217 * 1 if @work was pending and we successfully stole PENDING
1218 * 0 if @work was idle and we claimed PENDING
1219 * -EAGAIN if PENDING couldn't be grabbed at the moment, safe to busy-retry
1220 * -ENOENT if someone else is canceling @work, this state may persist
1221 * for arbitrarily long
1222 *
1223 * Note:
1224 * On >= 0 return, the caller owns @work's PENDING bit. To avoid getting
1225 * interrupted while holding PENDING and @work off queue, irq must be
1226 * disabled on entry. This, combined with delayed_work->timer being
1227 * irqsafe, ensures that we return -EAGAIN for finite short period of time.
1228 *
1229 * On successful return, >= 0, irq is disabled and the caller is
1230 * responsible for releasing it using local_irq_restore(*@flags).
1231 *
1232 * This function is safe to call from any context including IRQ handler.
1233 */
1234static int try_to_grab_pending(struct work_struct *work, bool is_dwork,
1235 unsigned long *flags)
1236{
1237 struct worker_pool *pool;
1238 struct pool_workqueue *pwq;
1239
1240 local_irq_save(*flags);
1241
1242 /* try to steal the timer if it exists */
1243 if (is_dwork) {
1244 struct delayed_work *dwork = to_delayed_work(work);
1245
1246 /*
1247 * dwork->timer is irqsafe. If del_timer() fails, it's
1248 * guaranteed that the timer is not queued anywhere and not
1249 * running on the local CPU.
1250 */
1251 if (likely(del_timer(&dwork->timer)))
1252 return 1;
1253 }
1254
1255 /* try to claim PENDING the normal way */
1256 if (!test_and_set_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(work)))
1257 return 0;
1258
1259 rcu_read_lock();
1260 /*
1261 * The queueing is in progress, or it is already queued. Try to
1262 * steal it from ->worklist without clearing WORK_STRUCT_PENDING.
1263 */
1264 pool = get_work_pool(work);
1265 if (!pool)
1266 goto fail;
1267
1268 spin_lock(&pool->lock);
1269 /*
1270 * work->data is guaranteed to point to pwq only while the work
1271 * item is queued on pwq->wq, and both updating work->data to point
1272 * to pwq on queueing and to pool on dequeueing are done under
1273 * pwq->pool->lock. This in turn guarantees that, if work->data
1274 * points to pwq which is associated with a locked pool, the work
1275 * item is currently queued on that pool.
1276 */
1277 pwq = get_work_pwq(work);
1278 if (pwq && pwq->pool == pool) {
1279 debug_work_deactivate(work);
1280
1281 /*
1282 * A delayed work item cannot be grabbed directly because
1283 * it might have linked NO_COLOR work items which, if left
1284 * on the delayed_list, will confuse pwq->nr_active
1285 * management later on and cause stall. Make sure the work
1286 * item is activated before grabbing.
1287 */
1288 if (*work_data_bits(work) & WORK_STRUCT_DELAYED)
1289 pwq_activate_delayed_work(work);
1290
1291 list_del_init(&work->entry);
1292 pwq_dec_nr_in_flight(pwq, get_work_color(work));
1293
1294 /* work->data points to pwq iff queued, point to pool */
1295 set_work_pool_and_keep_pending(work, pool->id);
1296
1297 spin_unlock(&pool->lock);
1298 rcu_read_unlock();
1299 return 1;
1300 }
1301 spin_unlock(&pool->lock);
1302fail:
1303 rcu_read_unlock();
1304 local_irq_restore(*flags);
1305 if (work_is_canceling(work))
1306 return -ENOENT;
1307 cpu_relax();
1308 return -EAGAIN;
1309}
1310
1311/**
1312 * insert_work - insert a work into a pool
1313 * @pwq: pwq @work belongs to
1314 * @work: work to insert
1315 * @head: insertion point
1316 * @extra_flags: extra WORK_STRUCT_* flags to set
1317 *
1318 * Insert @work which belongs to @pwq after @head. @extra_flags is or'd to
1319 * work_struct flags.
1320 *
1321 * CONTEXT:
1322 * spin_lock_irq(pool->lock).
1323 */
1324static void insert_work(struct pool_workqueue *pwq, struct work_struct *work,
1325 struct list_head *head, unsigned int extra_flags)
1326{
1327 struct worker_pool *pool = pwq->pool;
1328
1329 /* we own @work, set data and link */
1330 set_work_pwq(work, pwq, extra_flags);
1331 list_add_tail(&work->entry, head);
1332 get_pwq(pwq);
1333
1334 /*
1335 * Ensure either wq_worker_sleeping() sees the above
1336 * list_add_tail() or we see zero nr_running to avoid workers lying
1337 * around lazily while there are works to be processed.
1338 */
1339 smp_mb();
1340
1341 if (__need_more_worker(pool))
1342 wake_up_worker(pool);
1343}
1344
1345/*
1346 * Test whether @work is being queued from another work executing on the
1347 * same workqueue.
1348 */
1349static bool is_chained_work(struct workqueue_struct *wq)
1350{
1351 struct worker *worker;
1352
1353 worker = current_wq_worker();
1354 /*
1355 * Return %true iff I'm a worker executing a work item on @wq. If
1356 * I'm @worker, it's safe to dereference it without locking.
1357 */
1358 return worker && worker->current_pwq->wq == wq;
1359}
1360
1361/*
1362 * When queueing an unbound work item to a wq, prefer local CPU if allowed
1363 * by wq_unbound_cpumask. Otherwise, round robin among the allowed ones to
1364 * avoid perturbing sensitive tasks.
1365 */
1366static int wq_select_unbound_cpu(int cpu)
1367{
1368 static bool printed_dbg_warning;
1369 int new_cpu;
1370
1371 if (likely(!wq_debug_force_rr_cpu)) {
1372 if (cpumask_test_cpu(cpu, wq_unbound_cpumask))
1373 return cpu;
1374 } else if (!printed_dbg_warning) {
1375 pr_warn("workqueue: round-robin CPU selection forced, expect performance impact\n");
1376 printed_dbg_warning = true;
1377 }
1378
1379 if (cpumask_empty(wq_unbound_cpumask))
1380 return cpu;
1381
1382 new_cpu = __this_cpu_read(wq_rr_cpu_last);
1383 new_cpu = cpumask_next_and(new_cpu, wq_unbound_cpumask, cpu_online_mask);
1384 if (unlikely(new_cpu >= nr_cpu_ids)) {
1385 new_cpu = cpumask_first_and(wq_unbound_cpumask, cpu_online_mask);
1386 if (unlikely(new_cpu >= nr_cpu_ids))
1387 return cpu;
1388 }
1389 __this_cpu_write(wq_rr_cpu_last, new_cpu);
1390
1391 return new_cpu;
1392}
1393
1394static void __queue_work(int cpu, struct workqueue_struct *wq,
1395 struct work_struct *work)
1396{
1397 struct pool_workqueue *pwq;
1398 struct worker_pool *last_pool;
1399 struct list_head *worklist;
1400 unsigned int work_flags;
1401 unsigned int req_cpu = cpu;
1402
1403 /*
1404 * While a work item is PENDING && off queue, a task trying to
1405 * steal the PENDING will busy-loop waiting for it to either get
1406 * queued or lose PENDING. Grabbing PENDING and queueing should
1407 * happen with IRQ disabled.
1408 */
1409 lockdep_assert_irqs_disabled();
1410
1411 debug_work_activate(work);
1412
1413 /* if draining, only works from the same workqueue are allowed */
1414 if (unlikely(wq->flags & __WQ_DRAINING) &&
1415 WARN_ON_ONCE(!is_chained_work(wq)))
1416 return;
1417 rcu_read_lock();
1418retry:
1419 if (req_cpu == WORK_CPU_UNBOUND)
1420 cpu = wq_select_unbound_cpu(raw_smp_processor_id());
1421
1422 /* pwq which will be used unless @work is executing elsewhere */
1423 if (!(wq->flags & WQ_UNBOUND))
1424 pwq = per_cpu_ptr(wq->cpu_pwqs, cpu);
1425 else
1426 pwq = unbound_pwq_by_node(wq, cpu_to_node(cpu));
1427
1428 /*
1429 * If @work was previously on a different pool, it might still be
1430 * running there, in which case the work needs to be queued on that
1431 * pool to guarantee non-reentrancy.
1432 */
1433 last_pool = get_work_pool(work);
1434 if (last_pool && last_pool != pwq->pool) {
1435 struct worker *worker;
1436
1437 spin_lock(&last_pool->lock);
1438
1439 worker = find_worker_executing_work(last_pool, work);
1440
1441 if (worker && worker->current_pwq->wq == wq) {
1442 pwq = worker->current_pwq;
1443 } else {
1444 /* meh... not running there, queue here */
1445 spin_unlock(&last_pool->lock);
1446 spin_lock(&pwq->pool->lock);
1447 }
1448 } else {
1449 spin_lock(&pwq->pool->lock);
1450 }
1451
1452 /*
1453 * pwq is determined and locked. For unbound pools, we could have
1454 * raced with pwq release and it could already be dead. If its
1455 * refcnt is zero, repeat pwq selection. Note that pwqs never die
1456 * without another pwq replacing it in the numa_pwq_tbl or while
1457 * work items are executing on it, so the retrying is guaranteed to
1458 * make forward-progress.
1459 */
1460 if (unlikely(!pwq->refcnt)) {
1461 if (wq->flags & WQ_UNBOUND) {
1462 spin_unlock(&pwq->pool->lock);
1463 cpu_relax();
1464 goto retry;
1465 }
1466 /* oops */
1467 WARN_ONCE(true, "workqueue: per-cpu pwq for %s on cpu%d has 0 refcnt",
1468 wq->name, cpu);
1469 }
1470
1471 /* pwq determined, queue */
1472 trace_workqueue_queue_work(req_cpu, pwq, work);
1473
1474 if (WARN_ON(!list_empty(&work->entry)))
1475 goto out;
1476
1477 pwq->nr_in_flight[pwq->work_color]++;
1478 work_flags = work_color_to_flags(pwq->work_color);
1479
1480 if (likely(pwq->nr_active < pwq->max_active)) {
1481 trace_workqueue_activate_work(work);
1482 pwq->nr_active++;
1483 worklist = &pwq->pool->worklist;
1484 if (list_empty(worklist))
1485 pwq->pool->watchdog_ts = jiffies;
1486 } else {
1487 work_flags |= WORK_STRUCT_DELAYED;
1488 worklist = &pwq->delayed_works;
1489 }
1490
1491 insert_work(pwq, work, worklist, work_flags);
1492
1493out:
1494 spin_unlock(&pwq->pool->lock);
1495 rcu_read_unlock();
1496}
1497
1498/**
1499 * queue_work_on - queue work on specific cpu
1500 * @cpu: CPU number to execute work on
1501 * @wq: workqueue to use
1502 * @work: work to queue
1503 *
1504 * We queue the work to a specific CPU, the caller must ensure it
1505 * can't go away.
1506 *
1507 * Return: %false if @work was already on a queue, %true otherwise.
1508 */
1509bool queue_work_on(int cpu, struct workqueue_struct *wq,
1510 struct work_struct *work)
1511{
1512 bool ret = false;
1513 unsigned long flags;
1514
1515 local_irq_save(flags);
1516
1517 if (!test_and_set_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(work))) {
1518 __queue_work(cpu, wq, work);
1519 ret = true;
1520 }
1521
1522 local_irq_restore(flags);
1523 return ret;
1524}
1525EXPORT_SYMBOL(queue_work_on);
1526
1527/**
1528 * workqueue_select_cpu_near - Select a CPU based on NUMA node
1529 * @node: NUMA node ID that we want to select a CPU from
1530 *
1531 * This function will attempt to find a "random" cpu available on a given
1532 * node. If there are no CPUs available on the given node it will return
1533 * WORK_CPU_UNBOUND indicating that we should just schedule to any
1534 * available CPU if we need to schedule this work.
1535 */
1536static int workqueue_select_cpu_near(int node)
1537{
1538 int cpu;
1539
1540 /* No point in doing this if NUMA isn't enabled for workqueues */
1541 if (!wq_numa_enabled)
1542 return WORK_CPU_UNBOUND;
1543
1544 /* Delay binding to CPU if node is not valid or online */
1545 if (node < 0 || node >= MAX_NUMNODES || !node_online(node))
1546 return WORK_CPU_UNBOUND;
1547
1548 /* Use local node/cpu if we are already there */
1549 cpu = raw_smp_processor_id();
1550 if (node == cpu_to_node(cpu))
1551 return cpu;
1552
1553 /* Use "random" otherwise know as "first" online CPU of node */
1554 cpu = cpumask_any_and(cpumask_of_node(node), cpu_online_mask);
1555
1556 /* If CPU is valid return that, otherwise just defer */
1557 return cpu < nr_cpu_ids ? cpu : WORK_CPU_UNBOUND;
1558}
1559
1560/**
1561 * queue_work_node - queue work on a "random" cpu for a given NUMA node
1562 * @node: NUMA node that we are targeting the work for
1563 * @wq: workqueue to use
1564 * @work: work to queue
1565 *
1566 * We queue the work to a "random" CPU within a given NUMA node. The basic
1567 * idea here is to provide a way to somehow associate work with a given
1568 * NUMA node.
1569 *
1570 * This function will only make a best effort attempt at getting this onto
1571 * the right NUMA node. If no node is requested or the requested node is
1572 * offline then we just fall back to standard queue_work behavior.
1573 *
1574 * Currently the "random" CPU ends up being the first available CPU in the
1575 * intersection of cpu_online_mask and the cpumask of the node, unless we
1576 * are running on the node. In that case we just use the current CPU.
1577 *
1578 * Return: %false if @work was already on a queue, %true otherwise.
1579 */
1580bool queue_work_node(int node, struct workqueue_struct *wq,
1581 struct work_struct *work)
1582{
1583 unsigned long flags;
1584 bool ret = false;
1585
1586 /*
1587 * This current implementation is specific to unbound workqueues.
1588 * Specifically we only return the first available CPU for a given
1589 * node instead of cycling through individual CPUs within the node.
1590 *
1591 * If this is used with a per-cpu workqueue then the logic in
1592 * workqueue_select_cpu_near would need to be updated to allow for
1593 * some round robin type logic.
1594 */
1595 WARN_ON_ONCE(!(wq->flags & WQ_UNBOUND));
1596
1597 local_irq_save(flags);
1598
1599 if (!test_and_set_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(work))) {
1600 int cpu = workqueue_select_cpu_near(node);
1601
1602 __queue_work(cpu, wq, work);
1603 ret = true;
1604 }
1605
1606 local_irq_restore(flags);
1607 return ret;
1608}
1609EXPORT_SYMBOL_GPL(queue_work_node);
1610
1611void delayed_work_timer_fn(struct timer_list *t)
1612{
1613 struct delayed_work *dwork = from_timer(dwork, t, timer);
1614
1615 /* should have been called from irqsafe timer with irq already off */
1616 __queue_work(dwork->cpu, dwork->wq, &dwork->work);
1617}
1618EXPORT_SYMBOL(delayed_work_timer_fn);
1619
1620static void __queue_delayed_work(int cpu, struct workqueue_struct *wq,
1621 struct delayed_work *dwork, unsigned long delay)
1622{
1623 struct timer_list *timer = &dwork->timer;
1624 struct work_struct *work = &dwork->work;
1625
1626 WARN_ON_ONCE(!wq);
1627 WARN_ON_ONCE(timer->function != delayed_work_timer_fn);
1628 WARN_ON_ONCE(timer_pending(timer));
1629 WARN_ON_ONCE(!list_empty(&work->entry));
1630
1631 /*
1632 * If @delay is 0, queue @dwork->work immediately. This is for
1633 * both optimization and correctness. The earliest @timer can
1634 * expire is on the closest next tick and delayed_work users depend
1635 * on that there's no such delay when @delay is 0.
1636 */
1637 if (!delay) {
1638 __queue_work(cpu, wq, &dwork->work);
1639 return;
1640 }
1641
1642 dwork->wq = wq;
1643 dwork->cpu = cpu;
1644 timer->expires = jiffies + delay;
1645
1646 if (unlikely(cpu != WORK_CPU_UNBOUND))
1647 add_timer_on(timer, cpu);
1648 else
1649 add_timer(timer);
1650}
1651
1652/**
1653 * queue_delayed_work_on - queue work on specific CPU after delay
1654 * @cpu: CPU number to execute work on
1655 * @wq: workqueue to use
1656 * @dwork: work to queue
1657 * @delay: number of jiffies to wait before queueing
1658 *
1659 * Return: %false if @work was already on a queue, %true otherwise. If
1660 * @delay is zero and @dwork is idle, it will be scheduled for immediate
1661 * execution.
1662 */
1663bool queue_delayed_work_on(int cpu, struct workqueue_struct *wq,
1664 struct delayed_work *dwork, unsigned long delay)
1665{
1666 struct work_struct *work = &dwork->work;
1667 bool ret = false;
1668 unsigned long flags;
1669
1670 /* read the comment in __queue_work() */
1671 local_irq_save(flags);
1672
1673 if (!test_and_set_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(work))) {
1674 __queue_delayed_work(cpu, wq, dwork, delay);
1675 ret = true;
1676 }
1677
1678 local_irq_restore(flags);
1679 return ret;
1680}
1681EXPORT_SYMBOL(queue_delayed_work_on);
1682
1683/**
1684 * mod_delayed_work_on - modify delay of or queue a delayed work on specific CPU
1685 * @cpu: CPU number to execute work on
1686 * @wq: workqueue to use
1687 * @dwork: work to queue
1688 * @delay: number of jiffies to wait before queueing
1689 *
1690 * If @dwork is idle, equivalent to queue_delayed_work_on(); otherwise,
1691 * modify @dwork's timer so that it expires after @delay. If @delay is
1692 * zero, @work is guaranteed to be scheduled immediately regardless of its
1693 * current state.
1694 *
1695 * Return: %false if @dwork was idle and queued, %true if @dwork was
1696 * pending and its timer was modified.
1697 *
1698 * This function is safe to call from any context including IRQ handler.
1699 * See try_to_grab_pending() for details.
1700 */
1701bool mod_delayed_work_on(int cpu, struct workqueue_struct *wq,
1702 struct delayed_work *dwork, unsigned long delay)
1703{
1704 unsigned long flags;
1705 int ret;
1706
1707 do {
1708 ret = try_to_grab_pending(&dwork->work, true, &flags);
1709 } while (unlikely(ret == -EAGAIN));
1710
1711 if (likely(ret >= 0)) {
1712 __queue_delayed_work(cpu, wq, dwork, delay);
1713 local_irq_restore(flags);
1714 }
1715
1716 /* -ENOENT from try_to_grab_pending() becomes %true */
1717 return ret;
1718}
1719EXPORT_SYMBOL_GPL(mod_delayed_work_on);
1720
1721static void rcu_work_rcufn(struct rcu_head *rcu)
1722{
1723 struct rcu_work *rwork = container_of(rcu, struct rcu_work, rcu);
1724
1725 /* read the comment in __queue_work() */
1726 local_irq_disable();
1727 __queue_work(WORK_CPU_UNBOUND, rwork->wq, &rwork->work);
1728 local_irq_enable();
1729}
1730
1731/**
1732 * queue_rcu_work - queue work after a RCU grace period
1733 * @wq: workqueue to use
1734 * @rwork: work to queue
1735 *
1736 * Return: %false if @rwork was already pending, %true otherwise. Note
1737 * that a full RCU grace period is guaranteed only after a %true return.
1738 * While @rwork is guaranteed to be executed after a %false return, the
1739 * execution may happen before a full RCU grace period has passed.
1740 */
1741bool queue_rcu_work(struct workqueue_struct *wq, struct rcu_work *rwork)
1742{
1743 struct work_struct *work = &rwork->work;
1744
1745 if (!test_and_set_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(work))) {
1746 rwork->wq = wq;
1747 call_rcu(&rwork->rcu, rcu_work_rcufn);
1748 return true;
1749 }
1750
1751 return false;
1752}
1753EXPORT_SYMBOL(queue_rcu_work);
1754
1755/**
1756 * worker_enter_idle - enter idle state
1757 * @worker: worker which is entering idle state
1758 *
1759 * @worker is entering idle state. Update stats and idle timer if
1760 * necessary.
1761 *
1762 * LOCKING:
1763 * spin_lock_irq(pool->lock).
1764 */
1765static void worker_enter_idle(struct worker *worker)
1766{
1767 struct worker_pool *pool = worker->pool;
1768
1769 if (WARN_ON_ONCE(worker->flags & WORKER_IDLE) ||
1770 WARN_ON_ONCE(!list_empty(&worker->entry) &&
1771 (worker->hentry.next || worker->hentry.pprev)))
1772 return;
1773
1774 /* can't use worker_set_flags(), also called from create_worker() */
1775 worker->flags |= WORKER_IDLE;
1776 pool->nr_idle++;
1777 worker->last_active = jiffies;
1778
1779 /* idle_list is LIFO */
1780 list_add(&worker->entry, &pool->idle_list);
1781
1782 if (too_many_workers(pool) && !timer_pending(&pool->idle_timer))
1783 mod_timer(&pool->idle_timer, jiffies + IDLE_WORKER_TIMEOUT);
1784
1785 /*
1786 * Sanity check nr_running. Because unbind_workers() releases
1787 * pool->lock between setting %WORKER_UNBOUND and zapping
1788 * nr_running, the warning may trigger spuriously. Check iff
1789 * unbind is not in progress.
1790 */
1791 WARN_ON_ONCE(!(pool->flags & POOL_DISASSOCIATED) &&
1792 pool->nr_workers == pool->nr_idle &&
1793 atomic_read(&pool->nr_running));
1794}
1795
1796/**
1797 * worker_leave_idle - leave idle state
1798 * @worker: worker which is leaving idle state
1799 *
1800 * @worker is leaving idle state. Update stats.
1801 *
1802 * LOCKING:
1803 * spin_lock_irq(pool->lock).
1804 */
1805static void worker_leave_idle(struct worker *worker)
1806{
1807 struct worker_pool *pool = worker->pool;
1808
1809 if (WARN_ON_ONCE(!(worker->flags & WORKER_IDLE)))
1810 return;
1811 worker_clr_flags(worker, WORKER_IDLE);
1812 pool->nr_idle--;
1813 list_del_init(&worker->entry);
1814}
1815
1816static struct worker *alloc_worker(int node)
1817{
1818 struct worker *worker;
1819
1820 worker = kzalloc_node(sizeof(*worker), GFP_KERNEL, node);
1821 if (worker) {
1822 INIT_LIST_HEAD(&worker->entry);
1823 INIT_LIST_HEAD(&worker->scheduled);
1824 INIT_LIST_HEAD(&worker->node);
1825 /* on creation a worker is in !idle && prep state */
1826 worker->flags = WORKER_PREP;
1827 }
1828 return worker;
1829}
1830
1831/**
1832 * worker_attach_to_pool() - attach a worker to a pool
1833 * @worker: worker to be attached
1834 * @pool: the target pool
1835 *
1836 * Attach @worker to @pool. Once attached, the %WORKER_UNBOUND flag and
1837 * cpu-binding of @worker are kept coordinated with the pool across
1838 * cpu-[un]hotplugs.
1839 */
1840static void worker_attach_to_pool(struct worker *worker,
1841 struct worker_pool *pool)
1842{
1843 mutex_lock(&wq_pool_attach_mutex);
1844
1845 /*
1846 * set_cpus_allowed_ptr() will fail if the cpumask doesn't have any
1847 * online CPUs. It'll be re-applied when any of the CPUs come up.
1848 */
1849 set_cpus_allowed_ptr(worker->task, pool->attrs->cpumask);
1850
1851 /*
1852 * The wq_pool_attach_mutex ensures %POOL_DISASSOCIATED remains
1853 * stable across this function. See the comments above the flag
1854 * definition for details.
1855 */
1856 if (pool->flags & POOL_DISASSOCIATED)
1857 worker->flags |= WORKER_UNBOUND;
1858
1859 list_add_tail(&worker->node, &pool->workers);
1860 worker->pool = pool;
1861
1862 mutex_unlock(&wq_pool_attach_mutex);
1863}
1864
1865/**
1866 * worker_detach_from_pool() - detach a worker from its pool
1867 * @worker: worker which is attached to its pool
1868 *
1869 * Undo the attaching which had been done in worker_attach_to_pool(). The
1870 * caller worker shouldn't access to the pool after detached except it has
1871 * other reference to the pool.
1872 */
1873static void worker_detach_from_pool(struct worker *worker)
1874{
1875 struct worker_pool *pool = worker->pool;
1876 struct completion *detach_completion = NULL;
1877
1878 mutex_lock(&wq_pool_attach_mutex);
1879
1880 list_del(&worker->node);
1881 worker->pool = NULL;
1882
1883 if (list_empty(&pool->workers))
1884 detach_completion = pool->detach_completion;
1885 mutex_unlock(&wq_pool_attach_mutex);
1886
1887 /* clear leftover flags without pool->lock after it is detached */
1888 worker->flags &= ~(WORKER_UNBOUND | WORKER_REBOUND);
1889
1890 if (detach_completion)
1891 complete(detach_completion);
1892}
1893
1894/**
1895 * create_worker - create a new workqueue worker
1896 * @pool: pool the new worker will belong to
1897 *
1898 * Create and start a new worker which is attached to @pool.
1899 *
1900 * CONTEXT:
1901 * Might sleep. Does GFP_KERNEL allocations.
1902 *
1903 * Return:
1904 * Pointer to the newly created worker.
1905 */
1906static struct worker *create_worker(struct worker_pool *pool)
1907{
1908 struct worker *worker = NULL;
1909 int id = -1;
1910 char id_buf[16];
1911
1912 /* ID is needed to determine kthread name */
1913 id = ida_simple_get(&pool->worker_ida, 0, 0, GFP_KERNEL);
1914 if (id < 0)
1915 goto fail;
1916
1917 worker = alloc_worker(pool->node);
1918 if (!worker)
1919 goto fail;
1920
1921 worker->id = id;
1922
1923 if (pool->cpu >= 0)
1924 snprintf(id_buf, sizeof(id_buf), "%d:%d%s", pool->cpu, id,
1925 pool->attrs->nice < 0 ? "H" : "");
1926 else
1927 snprintf(id_buf, sizeof(id_buf), "u%d:%d", pool->id, id);
1928
1929 worker->task = kthread_create_on_node(worker_thread, worker, pool->node,
1930 "kworker/%s", id_buf);
1931 if (IS_ERR(worker->task))
1932 goto fail;
1933
1934 set_user_nice(worker->task, pool->attrs->nice);
1935 kthread_bind_mask(worker->task, pool->attrs->cpumask);
1936
1937 /* successful, attach the worker to the pool */
1938 worker_attach_to_pool(worker, pool);
1939
1940 /* start the newly created worker */
1941 spin_lock_irq(&pool->lock);
1942 worker->pool->nr_workers++;
1943 worker_enter_idle(worker);
1944 wake_up_process(worker->task);
1945 spin_unlock_irq(&pool->lock);
1946
1947 return worker;
1948
1949fail:
1950 if (id >= 0)
1951 ida_simple_remove(&pool->worker_ida, id);
1952 kfree(worker);
1953 return NULL;
1954}
1955
1956/**
1957 * destroy_worker - destroy a workqueue worker
1958 * @worker: worker to be destroyed
1959 *
1960 * Destroy @worker and adjust @pool stats accordingly. The worker should
1961 * be idle.
1962 *
1963 * CONTEXT:
1964 * spin_lock_irq(pool->lock).
1965 */
1966static void destroy_worker(struct worker *worker)
1967{
1968 struct worker_pool *pool = worker->pool;
1969
1970 lockdep_assert_held(&pool->lock);
1971
1972 /* sanity check frenzy */
1973 if (WARN_ON(worker->current_work) ||
1974 WARN_ON(!list_empty(&worker->scheduled)) ||
1975 WARN_ON(!(worker->flags & WORKER_IDLE)))
1976 return;
1977
1978 pool->nr_workers--;
1979 pool->nr_idle--;
1980
1981 list_del_init(&worker->entry);
1982 worker->flags |= WORKER_DIE;
1983 wake_up_process(worker->task);
1984}
1985
1986static void idle_worker_timeout(struct timer_list *t)
1987{
1988 struct worker_pool *pool = from_timer(pool, t, idle_timer);
1989
1990 spin_lock_irq(&pool->lock);
1991
1992 while (too_many_workers(pool)) {
1993 struct worker *worker;
1994 unsigned long expires;
1995
1996 /* idle_list is kept in LIFO order, check the last one */
1997 worker = list_entry(pool->idle_list.prev, struct worker, entry);
1998 expires = worker->last_active + IDLE_WORKER_TIMEOUT;
1999
2000 if (time_before(jiffies, expires)) {
2001 mod_timer(&pool->idle_timer, expires);
2002 break;
2003 }
2004
2005 destroy_worker(worker);
2006 }
2007
2008 spin_unlock_irq(&pool->lock);
2009}
2010
2011static void send_mayday(struct work_struct *work)
2012{
2013 struct pool_workqueue *pwq = get_work_pwq(work);
2014 struct workqueue_struct *wq = pwq->wq;
2015
2016 lockdep_assert_held(&wq_mayday_lock);
2017
2018 if (!wq->rescuer)
2019 return;
2020
2021 /* mayday mayday mayday */
2022 if (list_empty(&pwq->mayday_node)) {
2023 /*
2024 * If @pwq is for an unbound wq, its base ref may be put at
2025 * any time due to an attribute change. Pin @pwq until the
2026 * rescuer is done with it.
2027 */
2028 get_pwq(pwq);
2029 list_add_tail(&pwq->mayday_node, &wq->maydays);
2030 wake_up_process(wq->rescuer->task);
2031 }
2032}
2033
2034static void pool_mayday_timeout(struct timer_list *t)
2035{
2036 struct worker_pool *pool = from_timer(pool, t, mayday_timer);
2037 struct work_struct *work;
2038
2039 spin_lock_irq(&pool->lock);
2040 spin_lock(&wq_mayday_lock); /* for wq->maydays */
2041
2042 if (need_to_create_worker(pool)) {
2043 /*
2044 * We've been trying to create a new worker but
2045 * haven't been successful. We might be hitting an
2046 * allocation deadlock. Send distress signals to
2047 * rescuers.
2048 */
2049 list_for_each_entry(work, &pool->worklist, entry)
2050 send_mayday(work);
2051 }
2052
2053 spin_unlock(&wq_mayday_lock);
2054 spin_unlock_irq(&pool->lock);
2055
2056 mod_timer(&pool->mayday_timer, jiffies + MAYDAY_INTERVAL);
2057}
2058
2059/**
2060 * maybe_create_worker - create a new worker if necessary
2061 * @pool: pool to create a new worker for
2062 *
2063 * Create a new worker for @pool if necessary. @pool is guaranteed to
2064 * have at least one idle worker on return from this function. If
2065 * creating a new worker takes longer than MAYDAY_INTERVAL, mayday is
2066 * sent to all rescuers with works scheduled on @pool to resolve
2067 * possible allocation deadlock.
2068 *
2069 * On return, need_to_create_worker() is guaranteed to be %false and
2070 * may_start_working() %true.
2071 *
2072 * LOCKING:
2073 * spin_lock_irq(pool->lock) which may be released and regrabbed
2074 * multiple times. Does GFP_KERNEL allocations. Called only from
2075 * manager.
2076 */
2077static void maybe_create_worker(struct worker_pool *pool)
2078__releases(&pool->lock)
2079__acquires(&pool->lock)
2080{
2081restart:
2082 spin_unlock_irq(&pool->lock);
2083
2084 /* if we don't make progress in MAYDAY_INITIAL_TIMEOUT, call for help */
2085 mod_timer(&pool->mayday_timer, jiffies + MAYDAY_INITIAL_TIMEOUT);
2086
2087 while (true) {
2088 if (create_worker(pool) || !need_to_create_worker(pool))
2089 break;
2090
2091 schedule_timeout_interruptible(CREATE_COOLDOWN);
2092
2093 if (!need_to_create_worker(pool))
2094 break;
2095 }
2096
2097 del_timer_sync(&pool->mayday_timer);
2098 spin_lock_irq(&pool->lock);
2099 /*
2100 * This is necessary even after a new worker was just successfully
2101 * created as @pool->lock was dropped and the new worker might have
2102 * already become busy.
2103 */
2104 if (need_to_create_worker(pool))
2105 goto restart;
2106}
2107
2108/**
2109 * manage_workers - manage worker pool
2110 * @worker: self
2111 *
2112 * Assume the manager role and manage the worker pool @worker belongs
2113 * to. At any given time, there can be only zero or one manager per
2114 * pool. The exclusion is handled automatically by this function.
2115 *
2116 * The caller can safely start processing works on false return. On
2117 * true return, it's guaranteed that need_to_create_worker() is false
2118 * and may_start_working() is true.
2119 *
2120 * CONTEXT:
2121 * spin_lock_irq(pool->lock) which may be released and regrabbed
2122 * multiple times. Does GFP_KERNEL allocations.
2123 *
2124 * Return:
2125 * %false if the pool doesn't need management and the caller can safely
2126 * start processing works, %true if management function was performed and
2127 * the conditions that the caller verified before calling the function may
2128 * no longer be true.
2129 */
2130static bool manage_workers(struct worker *worker)
2131{
2132 struct worker_pool *pool = worker->pool;
2133
2134 if (pool->flags & POOL_MANAGER_ACTIVE)
2135 return false;
2136
2137 pool->flags |= POOL_MANAGER_ACTIVE;
2138 pool->manager = worker;
2139
2140 maybe_create_worker(pool);
2141
2142 pool->manager = NULL;
2143 pool->flags &= ~POOL_MANAGER_ACTIVE;
2144 wake_up(&wq_manager_wait);
2145 return true;
2146}
2147
2148/**
2149 * process_one_work - process single work
2150 * @worker: self
2151 * @work: work to process
2152 *
2153 * Process @work. This function contains all the logics necessary to
2154 * process a single work including synchronization against and
2155 * interaction with other workers on the same cpu, queueing and
2156 * flushing. As long as context requirement is met, any worker can
2157 * call this function to process a work.
2158 *
2159 * CONTEXT:
2160 * spin_lock_irq(pool->lock) which is released and regrabbed.
2161 */
2162static void process_one_work(struct worker *worker, struct work_struct *work)
2163__releases(&pool->lock)
2164__acquires(&pool->lock)
2165{
2166 struct pool_workqueue *pwq = get_work_pwq(work);
2167 struct worker_pool *pool = worker->pool;
2168 bool cpu_intensive = pwq->wq->flags & WQ_CPU_INTENSIVE;
2169 int work_color;
2170 struct worker *collision;
2171#ifdef CONFIG_LOCKDEP
2172 /*
2173 * It is permissible to free the struct work_struct from
2174 * inside the function that is called from it, this we need to
2175 * take into account for lockdep too. To avoid bogus "held
2176 * lock freed" warnings as well as problems when looking into
2177 * work->lockdep_map, make a copy and use that here.
2178 */
2179 struct lockdep_map lockdep_map;
2180
2181 lockdep_copy_map(&lockdep_map, &work->lockdep_map);
2182#endif
2183 /* ensure we're on the correct CPU */
2184 WARN_ON_ONCE(!(pool->flags & POOL_DISASSOCIATED) &&
2185 raw_smp_processor_id() != pool->cpu);
2186
2187 /*
2188 * A single work shouldn't be executed concurrently by
2189 * multiple workers on a single cpu. Check whether anyone is
2190 * already processing the work. If so, defer the work to the
2191 * currently executing one.
2192 */
2193 collision = find_worker_executing_work(pool, work);
2194 if (unlikely(collision)) {
2195 move_linked_works(work, &collision->scheduled, NULL);
2196 return;
2197 }
2198
2199 /* claim and dequeue */
2200 debug_work_deactivate(work);
2201 hash_add(pool->busy_hash, &worker->hentry, (unsigned long)work);
2202 worker->current_work = work;
2203 worker->current_func = work->func;
2204 worker->current_pwq = pwq;
2205 work_color = get_work_color(work);
2206
2207 /*
2208 * Record wq name for cmdline and debug reporting, may get
2209 * overridden through set_worker_desc().
2210 */
2211 strscpy(worker->desc, pwq->wq->name, WORKER_DESC_LEN);
2212
2213 list_del_init(&work->entry);
2214
2215 /*
2216 * CPU intensive works don't participate in concurrency management.
2217 * They're the scheduler's responsibility. This takes @worker out
2218 * of concurrency management and the next code block will chain
2219 * execution of the pending work items.
2220 */
2221 if (unlikely(cpu_intensive))
2222 worker_set_flags(worker, WORKER_CPU_INTENSIVE);
2223
2224 /*
2225 * Wake up another worker if necessary. The condition is always
2226 * false for normal per-cpu workers since nr_running would always
2227 * be >= 1 at this point. This is used to chain execution of the
2228 * pending work items for WORKER_NOT_RUNNING workers such as the
2229 * UNBOUND and CPU_INTENSIVE ones.
2230 */
2231 if (need_more_worker(pool))
2232 wake_up_worker(pool);
2233
2234 /*
2235 * Record the last pool and clear PENDING which should be the last
2236 * update to @work. Also, do this inside @pool->lock so that
2237 * PENDING and queued state changes happen together while IRQ is
2238 * disabled.
2239 */
2240 set_work_pool_and_clear_pending(work, pool->id);
2241
2242 spin_unlock_irq(&pool->lock);
2243
2244 lock_map_acquire(&pwq->wq->lockdep_map);
2245 lock_map_acquire(&lockdep_map);
2246 /*
2247 * Strictly speaking we should mark the invariant state without holding
2248 * any locks, that is, before these two lock_map_acquire()'s.
2249 *
2250 * However, that would result in:
2251 *
2252 * A(W1)
2253 * WFC(C)
2254 * A(W1)
2255 * C(C)
2256 *
2257 * Which would create W1->C->W1 dependencies, even though there is no
2258 * actual deadlock possible. There are two solutions, using a
2259 * read-recursive acquire on the work(queue) 'locks', but this will then
2260 * hit the lockdep limitation on recursive locks, or simply discard
2261 * these locks.
2262 *
2263 * AFAICT there is no possible deadlock scenario between the
2264 * flush_work() and complete() primitives (except for single-threaded
2265 * workqueues), so hiding them isn't a problem.
2266 */
2267 lockdep_invariant_state(true);
2268 trace_workqueue_execute_start(work);
2269 worker->current_func(work);
2270 /*
2271 * While we must be careful to not use "work" after this, the trace
2272 * point will only record its address.
2273 */
2274 trace_workqueue_execute_end(work);
2275 lock_map_release(&lockdep_map);
2276 lock_map_release(&pwq->wq->lockdep_map);
2277
2278 if (unlikely(in_atomic() || lockdep_depth(current) > 0)) {
2279 pr_err("BUG: workqueue leaked lock or atomic: %s/0x%08x/%d\n"
2280 " last function: %ps\n",
2281 current->comm, preempt_count(), task_pid_nr(current),
2282 worker->current_func);
2283 debug_show_held_locks(current);
2284 dump_stack();
2285 }
2286
2287 /*
2288 * The following prevents a kworker from hogging CPU on !PREEMPT
2289 * kernels, where a requeueing work item waiting for something to
2290 * happen could deadlock with stop_machine as such work item could
2291 * indefinitely requeue itself while all other CPUs are trapped in
2292 * stop_machine. At the same time, report a quiescent RCU state so
2293 * the same condition doesn't freeze RCU.
2294 */
2295 cond_resched();
2296
2297 spin_lock_irq(&pool->lock);
2298
2299 /* clear cpu intensive status */
2300 if (unlikely(cpu_intensive))
2301 worker_clr_flags(worker, WORKER_CPU_INTENSIVE);
2302
2303 /* tag the worker for identification in schedule() */
2304 worker->last_func = worker->current_func;
2305
2306 /* we're done with it, release */
2307 hash_del(&worker->hentry);
2308 worker->current_work = NULL;
2309 worker->current_func = NULL;
2310 worker->current_pwq = NULL;
2311 pwq_dec_nr_in_flight(pwq, work_color);
2312}
2313
2314/**
2315 * process_scheduled_works - process scheduled works
2316 * @worker: self
2317 *
2318 * Process all scheduled works. Please note that the scheduled list
2319 * may change while processing a work, so this function repeatedly
2320 * fetches a work from the top and executes it.
2321 *
2322 * CONTEXT:
2323 * spin_lock_irq(pool->lock) which may be released and regrabbed
2324 * multiple times.
2325 */
2326static void process_scheduled_works(struct worker *worker)
2327{
2328 while (!list_empty(&worker->scheduled)) {
2329 struct work_struct *work = list_first_entry(&worker->scheduled,
2330 struct work_struct, entry);
2331 process_one_work(worker, work);
2332 }
2333}
2334
2335static void set_pf_worker(bool val)
2336{
2337 mutex_lock(&wq_pool_attach_mutex);
2338 if (val)
2339 current->flags |= PF_WQ_WORKER;
2340 else
2341 current->flags &= ~PF_WQ_WORKER;
2342 mutex_unlock(&wq_pool_attach_mutex);
2343}
2344
2345/**
2346 * worker_thread - the worker thread function
2347 * @__worker: self
2348 *
2349 * The worker thread function. All workers belong to a worker_pool -
2350 * either a per-cpu one or dynamic unbound one. These workers process all
2351 * work items regardless of their specific target workqueue. The only
2352 * exception is work items which belong to workqueues with a rescuer which
2353 * will be explained in rescuer_thread().
2354 *
2355 * Return: 0
2356 */
2357static int worker_thread(void *__worker)
2358{
2359 struct worker *worker = __worker;
2360 struct worker_pool *pool = worker->pool;
2361
2362 /* tell the scheduler that this is a workqueue worker */
2363 set_pf_worker(true);
2364woke_up:
2365 spin_lock_irq(&pool->lock);
2366
2367 /* am I supposed to die? */
2368 if (unlikely(worker->flags & WORKER_DIE)) {
2369 spin_unlock_irq(&pool->lock);
2370 WARN_ON_ONCE(!list_empty(&worker->entry));
2371 set_pf_worker(false);
2372
2373 set_task_comm(worker->task, "kworker/dying");
2374 ida_simple_remove(&pool->worker_ida, worker->id);
2375 worker_detach_from_pool(worker);
2376 kfree(worker);
2377 return 0;
2378 }
2379
2380 worker_leave_idle(worker);
2381recheck:
2382 /* no more worker necessary? */
2383 if (!need_more_worker(pool))
2384 goto sleep;
2385
2386 /* do we need to manage? */
2387 if (unlikely(!may_start_working(pool)) && manage_workers(worker))
2388 goto recheck;
2389
2390 /*
2391 * ->scheduled list can only be filled while a worker is
2392 * preparing to process a work or actually processing it.
2393 * Make sure nobody diddled with it while I was sleeping.
2394 */
2395 WARN_ON_ONCE(!list_empty(&worker->scheduled));
2396
2397 /*
2398 * Finish PREP stage. We're guaranteed to have at least one idle
2399 * worker or that someone else has already assumed the manager
2400 * role. This is where @worker starts participating in concurrency
2401 * management if applicable and concurrency management is restored
2402 * after being rebound. See rebind_workers() for details.
2403 */
2404 worker_clr_flags(worker, WORKER_PREP | WORKER_REBOUND);
2405
2406 do {
2407 struct work_struct *work =
2408 list_first_entry(&pool->worklist,
2409 struct work_struct, entry);
2410
2411 pool->watchdog_ts = jiffies;
2412
2413 if (likely(!(*work_data_bits(work) & WORK_STRUCT_LINKED))) {
2414 /* optimization path, not strictly necessary */
2415 process_one_work(worker, work);
2416 if (unlikely(!list_empty(&worker->scheduled)))
2417 process_scheduled_works(worker);
2418 } else {
2419 move_linked_works(work, &worker->scheduled, NULL);
2420 process_scheduled_works(worker);
2421 }
2422 } while (keep_working(pool));
2423
2424 worker_set_flags(worker, WORKER_PREP);
2425sleep:
2426 /*
2427 * pool->lock is held and there's no work to process and no need to
2428 * manage, sleep. Workers are woken up only while holding
2429 * pool->lock or from local cpu, so setting the current state
2430 * before releasing pool->lock is enough to prevent losing any
2431 * event.
2432 */
2433 worker_enter_idle(worker);
2434 __set_current_state(TASK_IDLE);
2435 spin_unlock_irq(&pool->lock);
2436 schedule();
2437 goto woke_up;
2438}
2439
2440/**
2441 * rescuer_thread - the rescuer thread function
2442 * @__rescuer: self
2443 *
2444 * Workqueue rescuer thread function. There's one rescuer for each
2445 * workqueue which has WQ_MEM_RECLAIM set.
2446 *
2447 * Regular work processing on a pool may block trying to create a new
2448 * worker which uses GFP_KERNEL allocation which has slight chance of
2449 * developing into deadlock if some works currently on the same queue
2450 * need to be processed to satisfy the GFP_KERNEL allocation. This is
2451 * the problem rescuer solves.
2452 *
2453 * When such condition is possible, the pool summons rescuers of all
2454 * workqueues which have works queued on the pool and let them process
2455 * those works so that forward progress can be guaranteed.
2456 *
2457 * This should happen rarely.
2458 *
2459 * Return: 0
2460 */
2461static int rescuer_thread(void *__rescuer)
2462{
2463 struct worker *rescuer = __rescuer;
2464 struct workqueue_struct *wq = rescuer->rescue_wq;
2465 struct list_head *scheduled = &rescuer->scheduled;
2466 bool should_stop;
2467
2468 set_user_nice(current, RESCUER_NICE_LEVEL);
2469
2470 /*
2471 * Mark rescuer as worker too. As WORKER_PREP is never cleared, it
2472 * doesn't participate in concurrency management.
2473 */
2474 set_pf_worker(true);
2475repeat:
2476 set_current_state(TASK_IDLE);
2477
2478 /*
2479 * By the time the rescuer is requested to stop, the workqueue
2480 * shouldn't have any work pending, but @wq->maydays may still have
2481 * pwq(s) queued. This can happen by non-rescuer workers consuming
2482 * all the work items before the rescuer got to them. Go through
2483 * @wq->maydays processing before acting on should_stop so that the
2484 * list is always empty on exit.
2485 */
2486 should_stop = kthread_should_stop();
2487
2488 /* see whether any pwq is asking for help */
2489 spin_lock_irq(&wq_mayday_lock);
2490
2491 while (!list_empty(&wq->maydays)) {
2492 struct pool_workqueue *pwq = list_first_entry(&wq->maydays,
2493 struct pool_workqueue, mayday_node);
2494 struct worker_pool *pool = pwq->pool;
2495 struct work_struct *work, *n;
2496 bool first = true;
2497
2498 __set_current_state(TASK_RUNNING);
2499 list_del_init(&pwq->mayday_node);
2500
2501 spin_unlock_irq(&wq_mayday_lock);
2502
2503 worker_attach_to_pool(rescuer, pool);
2504
2505 spin_lock_irq(&pool->lock);
2506
2507 /*
2508 * Slurp in all works issued via this workqueue and
2509 * process'em.
2510 */
2511 WARN_ON_ONCE(!list_empty(scheduled));
2512 list_for_each_entry_safe(work, n, &pool->worklist, entry) {
2513 if (get_work_pwq(work) == pwq) {
2514 if (first)
2515 pool->watchdog_ts = jiffies;
2516 move_linked_works(work, scheduled, &n);
2517 }
2518 first = false;
2519 }
2520
2521 if (!list_empty(scheduled)) {
2522 process_scheduled_works(rescuer);
2523
2524 /*
2525 * The above execution of rescued work items could
2526 * have created more to rescue through
2527 * pwq_activate_first_delayed() or chained
2528 * queueing. Let's put @pwq back on mayday list so
2529 * that such back-to-back work items, which may be
2530 * being used to relieve memory pressure, don't
2531 * incur MAYDAY_INTERVAL delay inbetween.
2532 */
2533 if (need_to_create_worker(pool)) {
2534 spin_lock(&wq_mayday_lock);
2535 get_pwq(pwq);
2536 list_move_tail(&pwq->mayday_node, &wq->maydays);
2537 spin_unlock(&wq_mayday_lock);
2538 }
2539 }
2540
2541 /*
2542 * Put the reference grabbed by send_mayday(). @pool won't
2543 * go away while we're still attached to it.
2544 */
2545 put_pwq(pwq);
2546
2547 /*
2548 * Leave this pool. If need_more_worker() is %true, notify a
2549 * regular worker; otherwise, we end up with 0 concurrency
2550 * and stalling the execution.
2551 */
2552 if (need_more_worker(pool))
2553 wake_up_worker(pool);
2554
2555 spin_unlock_irq(&pool->lock);
2556
2557 worker_detach_from_pool(rescuer);
2558
2559 spin_lock_irq(&wq_mayday_lock);
2560 }
2561
2562 spin_unlock_irq(&wq_mayday_lock);
2563
2564 if (should_stop) {
2565 __set_current_state(TASK_RUNNING);
2566 set_pf_worker(false);
2567 return 0;
2568 }
2569
2570 /* rescuers should never participate in concurrency management */
2571 WARN_ON_ONCE(!(rescuer->flags & WORKER_NOT_RUNNING));
2572 schedule();
2573 goto repeat;
2574}
2575
2576/**
2577 * check_flush_dependency - check for flush dependency sanity
2578 * @target_wq: workqueue being flushed
2579 * @target_work: work item being flushed (NULL for workqueue flushes)
2580 *
2581 * %current is trying to flush the whole @target_wq or @target_work on it.
2582 * If @target_wq doesn't have %WQ_MEM_RECLAIM, verify that %current is not
2583 * reclaiming memory or running on a workqueue which doesn't have
2584 * %WQ_MEM_RECLAIM as that can break forward-progress guarantee leading to
2585 * a deadlock.
2586 */
2587static void check_flush_dependency(struct workqueue_struct *target_wq,
2588 struct work_struct *target_work)
2589{
2590 work_func_t target_func = target_work ? target_work->func : NULL;
2591 struct worker *worker;
2592
2593 if (target_wq->flags & WQ_MEM_RECLAIM)
2594 return;
2595
2596 worker = current_wq_worker();
2597
2598 WARN_ONCE(current->flags & PF_MEMALLOC,
2599 "workqueue: PF_MEMALLOC task %d(%s) is flushing !WQ_MEM_RECLAIM %s:%ps",
2600 current->pid, current->comm, target_wq->name, target_func);
2601 WARN_ONCE(worker && ((worker->current_pwq->wq->flags &
2602 (WQ_MEM_RECLAIM | __WQ_LEGACY)) == WQ_MEM_RECLAIM),
2603 "workqueue: WQ_MEM_RECLAIM %s:%ps is flushing !WQ_MEM_RECLAIM %s:%ps",
2604 worker->current_pwq->wq->name, worker->current_func,
2605 target_wq->name, target_func);
2606}
2607
2608struct wq_barrier {
2609 struct work_struct work;
2610 struct completion done;
2611 struct task_struct *task; /* purely informational */
2612};
2613
2614static void wq_barrier_func(struct work_struct *work)
2615{
2616 struct wq_barrier *barr = container_of(work, struct wq_barrier, work);
2617 complete(&barr->done);
2618}
2619
2620/**
2621 * insert_wq_barrier - insert a barrier work
2622 * @pwq: pwq to insert barrier into
2623 * @barr: wq_barrier to insert
2624 * @target: target work to attach @barr to
2625 * @worker: worker currently executing @target, NULL if @target is not executing
2626 *
2627 * @barr is linked to @target such that @barr is completed only after
2628 * @target finishes execution. Please note that the ordering
2629 * guarantee is observed only with respect to @target and on the local
2630 * cpu.
2631 *
2632 * Currently, a queued barrier can't be canceled. This is because
2633 * try_to_grab_pending() can't determine whether the work to be
2634 * grabbed is at the head of the queue and thus can't clear LINKED
2635 * flag of the previous work while there must be a valid next work
2636 * after a work with LINKED flag set.
2637 *
2638 * Note that when @worker is non-NULL, @target may be modified
2639 * underneath us, so we can't reliably determine pwq from @target.
2640 *
2641 * CONTEXT:
2642 * spin_lock_irq(pool->lock).
2643 */
2644static void insert_wq_barrier(struct pool_workqueue *pwq,
2645 struct wq_barrier *barr,
2646 struct work_struct *target, struct worker *worker)
2647{
2648 struct list_head *head;
2649 unsigned int linked = 0;
2650
2651 /*
2652 * debugobject calls are safe here even with pool->lock locked
2653 * as we know for sure that this will not trigger any of the
2654 * checks and call back into the fixup functions where we
2655 * might deadlock.
2656 */
2657 INIT_WORK_ONSTACK(&barr->work, wq_barrier_func);
2658 __set_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(&barr->work));
2659
2660 init_completion_map(&barr->done, &target->lockdep_map);
2661
2662 barr->task = current;
2663
2664 /*
2665 * If @target is currently being executed, schedule the
2666 * barrier to the worker; otherwise, put it after @target.
2667 */
2668 if (worker)
2669 head = worker->scheduled.next;
2670 else {
2671 unsigned long *bits = work_data_bits(target);
2672
2673 head = target->entry.next;
2674 /* there can already be other linked works, inherit and set */
2675 linked = *bits & WORK_STRUCT_LINKED;
2676 __set_bit(WORK_STRUCT_LINKED_BIT, bits);
2677 }
2678
2679 debug_work_activate(&barr->work);
2680 insert_work(pwq, &barr->work, head,
2681 work_color_to_flags(WORK_NO_COLOR) | linked);
2682}
2683
2684/**
2685 * flush_workqueue_prep_pwqs - prepare pwqs for workqueue flushing
2686 * @wq: workqueue being flushed
2687 * @flush_color: new flush color, < 0 for no-op
2688 * @work_color: new work color, < 0 for no-op
2689 *
2690 * Prepare pwqs for workqueue flushing.
2691 *
2692 * If @flush_color is non-negative, flush_color on all pwqs should be
2693 * -1. If no pwq has in-flight commands at the specified color, all
2694 * pwq->flush_color's stay at -1 and %false is returned. If any pwq
2695 * has in flight commands, its pwq->flush_color is set to
2696 * @flush_color, @wq->nr_pwqs_to_flush is updated accordingly, pwq
2697 * wakeup logic is armed and %true is returned.
2698 *
2699 * The caller should have initialized @wq->first_flusher prior to
2700 * calling this function with non-negative @flush_color. If
2701 * @flush_color is negative, no flush color update is done and %false
2702 * is returned.
2703 *
2704 * If @work_color is non-negative, all pwqs should have the same
2705 * work_color which is previous to @work_color and all will be
2706 * advanced to @work_color.
2707 *
2708 * CONTEXT:
2709 * mutex_lock(wq->mutex).
2710 *
2711 * Return:
2712 * %true if @flush_color >= 0 and there's something to flush. %false
2713 * otherwise.
2714 */
2715static bool flush_workqueue_prep_pwqs(struct workqueue_struct *wq,
2716 int flush_color, int work_color)
2717{
2718 bool wait = false;
2719 struct pool_workqueue *pwq;
2720
2721 if (flush_color >= 0) {
2722 WARN_ON_ONCE(atomic_read(&wq->nr_pwqs_to_flush));
2723 atomic_set(&wq->nr_pwqs_to_flush, 1);
2724 }
2725
2726 for_each_pwq(pwq, wq) {
2727 struct worker_pool *pool = pwq->pool;
2728
2729 spin_lock_irq(&pool->lock);
2730
2731 if (flush_color >= 0) {
2732 WARN_ON_ONCE(pwq->flush_color != -1);
2733
2734 if (pwq->nr_in_flight[flush_color]) {
2735 pwq->flush_color = flush_color;
2736 atomic_inc(&wq->nr_pwqs_to_flush);
2737 wait = true;
2738 }
2739 }
2740
2741 if (work_color >= 0) {
2742 WARN_ON_ONCE(work_color != work_next_color(pwq->work_color));
2743 pwq->work_color = work_color;
2744 }
2745
2746 spin_unlock_irq(&pool->lock);
2747 }
2748
2749 if (flush_color >= 0 && atomic_dec_and_test(&wq->nr_pwqs_to_flush))
2750 complete(&wq->first_flusher->done);
2751
2752 return wait;
2753}
2754
2755/**
2756 * flush_workqueue - ensure that any scheduled work has run to completion.
2757 * @wq: workqueue to flush
2758 *
2759 * This function sleeps until all work items which were queued on entry
2760 * have finished execution, but it is not livelocked by new incoming ones.
2761 */
2762void flush_workqueue(struct workqueue_struct *wq)
2763{
2764 struct wq_flusher this_flusher = {
2765 .list = LIST_HEAD_INIT(this_flusher.list),
2766 .flush_color = -1,
2767 .done = COMPLETION_INITIALIZER_ONSTACK_MAP(this_flusher.done, wq->lockdep_map),
2768 };
2769 int next_color;
2770
2771 if (WARN_ON(!wq_online))
2772 return;
2773
2774 lock_map_acquire(&wq->lockdep_map);
2775 lock_map_release(&wq->lockdep_map);
2776
2777 mutex_lock(&wq->mutex);
2778
2779 /*
2780 * Start-to-wait phase
2781 */
2782 next_color = work_next_color(wq->work_color);
2783
2784 if (next_color != wq->flush_color) {
2785 /*
2786 * Color space is not full. The current work_color
2787 * becomes our flush_color and work_color is advanced
2788 * by one.
2789 */
2790 WARN_ON_ONCE(!list_empty(&wq->flusher_overflow));
2791 this_flusher.flush_color = wq->work_color;
2792 wq->work_color = next_color;
2793
2794 if (!wq->first_flusher) {
2795 /* no flush in progress, become the first flusher */
2796 WARN_ON_ONCE(wq->flush_color != this_flusher.flush_color);
2797
2798 wq->first_flusher = &this_flusher;
2799
2800 if (!flush_workqueue_prep_pwqs(wq, wq->flush_color,
2801 wq->work_color)) {
2802 /* nothing to flush, done */
2803 wq->flush_color = next_color;
2804 wq->first_flusher = NULL;
2805 goto out_unlock;
2806 }
2807 } else {
2808 /* wait in queue */
2809 WARN_ON_ONCE(wq->flush_color == this_flusher.flush_color);
2810 list_add_tail(&this_flusher.list, &wq->flusher_queue);
2811 flush_workqueue_prep_pwqs(wq, -1, wq->work_color);
2812 }
2813 } else {
2814 /*
2815 * Oops, color space is full, wait on overflow queue.
2816 * The next flush completion will assign us
2817 * flush_color and transfer to flusher_queue.
2818 */
2819 list_add_tail(&this_flusher.list, &wq->flusher_overflow);
2820 }
2821
2822 check_flush_dependency(wq, NULL);
2823
2824 mutex_unlock(&wq->mutex);
2825
2826 wait_for_completion(&this_flusher.done);
2827
2828 /*
2829 * Wake-up-and-cascade phase
2830 *
2831 * First flushers are responsible for cascading flushes and
2832 * handling overflow. Non-first flushers can simply return.
2833 */
2834 if (wq->first_flusher != &this_flusher)
2835 return;
2836
2837 mutex_lock(&wq->mutex);
2838
2839 /* we might have raced, check again with mutex held */
2840 if (wq->first_flusher != &this_flusher)
2841 goto out_unlock;
2842
2843 wq->first_flusher = NULL;
2844
2845 WARN_ON_ONCE(!list_empty(&this_flusher.list));
2846 WARN_ON_ONCE(wq->flush_color != this_flusher.flush_color);
2847
2848 while (true) {
2849 struct wq_flusher *next, *tmp;
2850
2851 /* complete all the flushers sharing the current flush color */
2852 list_for_each_entry_safe(next, tmp, &wq->flusher_queue, list) {
2853 if (next->flush_color != wq->flush_color)
2854 break;
2855 list_del_init(&next->list);
2856 complete(&next->done);
2857 }
2858
2859 WARN_ON_ONCE(!list_empty(&wq->flusher_overflow) &&
2860 wq->flush_color != work_next_color(wq->work_color));
2861
2862 /* this flush_color is finished, advance by one */
2863 wq->flush_color = work_next_color(wq->flush_color);
2864
2865 /* one color has been freed, handle overflow queue */
2866 if (!list_empty(&wq->flusher_overflow)) {
2867 /*
2868 * Assign the same color to all overflowed
2869 * flushers, advance work_color and append to
2870 * flusher_queue. This is the start-to-wait
2871 * phase for these overflowed flushers.
2872 */
2873 list_for_each_entry(tmp, &wq->flusher_overflow, list)
2874 tmp->flush_color = wq->work_color;
2875
2876 wq->work_color = work_next_color(wq->work_color);
2877
2878 list_splice_tail_init(&wq->flusher_overflow,
2879 &wq->flusher_queue);
2880 flush_workqueue_prep_pwqs(wq, -1, wq->work_color);
2881 }
2882
2883 if (list_empty(&wq->flusher_queue)) {
2884 WARN_ON_ONCE(wq->flush_color != wq->work_color);
2885 break;
2886 }
2887
2888 /*
2889 * Need to flush more colors. Make the next flusher
2890 * the new first flusher and arm pwqs.
2891 */
2892 WARN_ON_ONCE(wq->flush_color == wq->work_color);
2893 WARN_ON_ONCE(wq->flush_color != next->flush_color);
2894
2895 list_del_init(&next->list);
2896 wq->first_flusher = next;
2897
2898 if (flush_workqueue_prep_pwqs(wq, wq->flush_color, -1))
2899 break;
2900
2901 /*
2902 * Meh... this color is already done, clear first
2903 * flusher and repeat cascading.
2904 */
2905 wq->first_flusher = NULL;
2906 }
2907
2908out_unlock:
2909 mutex_unlock(&wq->mutex);
2910}
2911EXPORT_SYMBOL(flush_workqueue);
2912
2913/**
2914 * drain_workqueue - drain a workqueue
2915 * @wq: workqueue to drain
2916 *
2917 * Wait until the workqueue becomes empty. While draining is in progress,
2918 * only chain queueing is allowed. IOW, only currently pending or running
2919 * work items on @wq can queue further work items on it. @wq is flushed
2920 * repeatedly until it becomes empty. The number of flushing is determined
2921 * by the depth of chaining and should be relatively short. Whine if it
2922 * takes too long.
2923 */
2924void drain_workqueue(struct workqueue_struct *wq)
2925{
2926 unsigned int flush_cnt = 0;
2927 struct pool_workqueue *pwq;
2928
2929 /*
2930 * __queue_work() needs to test whether there are drainers, is much
2931 * hotter than drain_workqueue() and already looks at @wq->flags.
2932 * Use __WQ_DRAINING so that queue doesn't have to check nr_drainers.
2933 */
2934 mutex_lock(&wq->mutex);
2935 if (!wq->nr_drainers++)
2936 wq->flags |= __WQ_DRAINING;
2937 mutex_unlock(&wq->mutex);
2938reflush:
2939 flush_workqueue(wq);
2940
2941 mutex_lock(&wq->mutex);
2942
2943 for_each_pwq(pwq, wq) {
2944 bool drained;
2945
2946 spin_lock_irq(&pwq->pool->lock);
2947 drained = !pwq->nr_active && list_empty(&pwq->delayed_works);
2948 spin_unlock_irq(&pwq->pool->lock);
2949
2950 if (drained)
2951 continue;
2952
2953 if (++flush_cnt == 10 ||
2954 (flush_cnt % 100 == 0 && flush_cnt <= 1000))
2955 pr_warn("workqueue %s: drain_workqueue() isn't complete after %u tries\n",
2956 wq->name, flush_cnt);
2957
2958 mutex_unlock(&wq->mutex);
2959 goto reflush;
2960 }
2961
2962 if (!--wq->nr_drainers)
2963 wq->flags &= ~__WQ_DRAINING;
2964 mutex_unlock(&wq->mutex);
2965}
2966EXPORT_SYMBOL_GPL(drain_workqueue);
2967
2968static bool start_flush_work(struct work_struct *work, struct wq_barrier *barr,
2969 bool from_cancel)
2970{
2971 struct worker *worker = NULL;
2972 struct worker_pool *pool;
2973 struct pool_workqueue *pwq;
2974
2975 might_sleep();
2976
2977 rcu_read_lock();
2978 pool = get_work_pool(work);
2979 if (!pool) {
2980 rcu_read_unlock();
2981 return false;
2982 }
2983
2984 spin_lock_irq(&pool->lock);
2985 /* see the comment in try_to_grab_pending() with the same code */
2986 pwq = get_work_pwq(work);
2987 if (pwq) {
2988 if (unlikely(pwq->pool != pool))
2989 goto already_gone;
2990 } else {
2991 worker = find_worker_executing_work(pool, work);
2992 if (!worker)
2993 goto already_gone;
2994 pwq = worker->current_pwq;
2995 }
2996
2997 check_flush_dependency(pwq->wq, work);
2998
2999 insert_wq_barrier(pwq, barr, work, worker);
3000 spin_unlock_irq(&pool->lock);
3001
3002 /*
3003 * Force a lock recursion deadlock when using flush_work() inside a
3004 * single-threaded or rescuer equipped workqueue.
3005 *
3006 * For single threaded workqueues the deadlock happens when the work
3007 * is after the work issuing the flush_work(). For rescuer equipped
3008 * workqueues the deadlock happens when the rescuer stalls, blocking
3009 * forward progress.
3010 */
3011 if (!from_cancel &&
3012 (pwq->wq->saved_max_active == 1 || pwq->wq->rescuer)) {
3013 lock_map_acquire(&pwq->wq->lockdep_map);
3014 lock_map_release(&pwq->wq->lockdep_map);
3015 }
3016 rcu_read_unlock();
3017 return true;
3018already_gone:
3019 spin_unlock_irq(&pool->lock);
3020 rcu_read_unlock();
3021 return false;
3022}
3023
3024static bool __flush_work(struct work_struct *work, bool from_cancel)
3025{
3026 struct wq_barrier barr;
3027
3028 if (WARN_ON(!wq_online))
3029 return false;
3030
3031 if (WARN_ON(!work->func))
3032 return false;
3033
3034 if (!from_cancel) {
3035 lock_map_acquire(&work->lockdep_map);
3036 lock_map_release(&work->lockdep_map);
3037 }
3038
3039 if (start_flush_work(work, &barr, from_cancel)) {
3040 wait_for_completion(&barr.done);
3041 destroy_work_on_stack(&barr.work);
3042 return true;
3043 } else {
3044 return false;
3045 }
3046}
3047
3048/**
3049 * flush_work - wait for a work to finish executing the last queueing instance
3050 * @work: the work to flush
3051 *
3052 * Wait until @work has finished execution. @work is guaranteed to be idle
3053 * on return if it hasn't been requeued since flush started.
3054 *
3055 * Return:
3056 * %true if flush_work() waited for the work to finish execution,
3057 * %false if it was already idle.
3058 */
3059bool flush_work(struct work_struct *work)
3060{
3061 return __flush_work(work, false);
3062}
3063EXPORT_SYMBOL_GPL(flush_work);
3064
3065struct cwt_wait {
3066 wait_queue_entry_t wait;
3067 struct work_struct *work;
3068};
3069
3070static int cwt_wakefn(wait_queue_entry_t *wait, unsigned mode, int sync, void *key)
3071{
3072 struct cwt_wait *cwait = container_of(wait, struct cwt_wait, wait);
3073
3074 if (cwait->work != key)
3075 return 0;
3076 return autoremove_wake_function(wait, mode, sync, key);
3077}
3078
3079static bool __cancel_work_timer(struct work_struct *work, bool is_dwork)
3080{
3081 static DECLARE_WAIT_QUEUE_HEAD(cancel_waitq);
3082 unsigned long flags;
3083 int ret;
3084
3085 do {
3086 ret = try_to_grab_pending(work, is_dwork, &flags);
3087 /*
3088 * If someone else is already canceling, wait for it to
3089 * finish. flush_work() doesn't work for PREEMPT_NONE
3090 * because we may get scheduled between @work's completion
3091 * and the other canceling task resuming and clearing
3092 * CANCELING - flush_work() will return false immediately
3093 * as @work is no longer busy, try_to_grab_pending() will
3094 * return -ENOENT as @work is still being canceled and the
3095 * other canceling task won't be able to clear CANCELING as
3096 * we're hogging the CPU.
3097 *
3098 * Let's wait for completion using a waitqueue. As this
3099 * may lead to the thundering herd problem, use a custom
3100 * wake function which matches @work along with exclusive
3101 * wait and wakeup.
3102 */
3103 if (unlikely(ret == -ENOENT)) {
3104 struct cwt_wait cwait;
3105
3106 init_wait(&cwait.wait);
3107 cwait.wait.func = cwt_wakefn;
3108 cwait.work = work;
3109
3110 prepare_to_wait_exclusive(&cancel_waitq, &cwait.wait,
3111 TASK_UNINTERRUPTIBLE);
3112 if (work_is_canceling(work))
3113 schedule();
3114 finish_wait(&cancel_waitq, &cwait.wait);
3115 }
3116 } while (unlikely(ret < 0));
3117
3118 /* tell other tasks trying to grab @work to back off */
3119 mark_work_canceling(work);
3120 local_irq_restore(flags);
3121
3122 /*
3123 * This allows canceling during early boot. We know that @work
3124 * isn't executing.
3125 */
3126 if (wq_online)
3127 __flush_work(work, true);
3128
3129 clear_work_data(work);
3130
3131 /*
3132 * Paired with prepare_to_wait() above so that either
3133 * waitqueue_active() is visible here or !work_is_canceling() is
3134 * visible there.
3135 */
3136 smp_mb();
3137 if (waitqueue_active(&cancel_waitq))
3138 __wake_up(&cancel_waitq, TASK_NORMAL, 1, work);
3139
3140 return ret;
3141}
3142
3143/**
3144 * cancel_work_sync - cancel a work and wait for it to finish
3145 * @work: the work to cancel
3146 *
3147 * Cancel @work and wait for its execution to finish. This function
3148 * can be used even if the work re-queues itself or migrates to
3149 * another workqueue. On return from this function, @work is
3150 * guaranteed to be not pending or executing on any CPU.
3151 *
3152 * cancel_work_sync(&delayed_work->work) must not be used for
3153 * delayed_work's. Use cancel_delayed_work_sync() instead.
3154 *
3155 * The caller must ensure that the workqueue on which @work was last
3156 * queued can't be destroyed before this function returns.
3157 *
3158 * Return:
3159 * %true if @work was pending, %false otherwise.
3160 */
3161bool cancel_work_sync(struct work_struct *work)
3162{
3163 return __cancel_work_timer(work, false);
3164}
3165EXPORT_SYMBOL_GPL(cancel_work_sync);
3166
3167/**
3168 * flush_delayed_work - wait for a dwork to finish executing the last queueing
3169 * @dwork: the delayed work to flush
3170 *
3171 * Delayed timer is cancelled and the pending work is queued for
3172 * immediate execution. Like flush_work(), this function only
3173 * considers the last queueing instance of @dwork.
3174 *
3175 * Return:
3176 * %true if flush_work() waited for the work to finish execution,
3177 * %false if it was already idle.
3178 */
3179bool flush_delayed_work(struct delayed_work *dwork)
3180{
3181 local_irq_disable();
3182 if (del_timer_sync(&dwork->timer))
3183 __queue_work(dwork->cpu, dwork->wq, &dwork->work);
3184 local_irq_enable();
3185 return flush_work(&dwork->work);
3186}
3187EXPORT_SYMBOL(flush_delayed_work);
3188
3189/**
3190 * flush_rcu_work - wait for a rwork to finish executing the last queueing
3191 * @rwork: the rcu work to flush
3192 *
3193 * Return:
3194 * %true if flush_rcu_work() waited for the work to finish execution,
3195 * %false if it was already idle.
3196 */
3197bool flush_rcu_work(struct rcu_work *rwork)
3198{
3199 if (test_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(&rwork->work))) {
3200 rcu_barrier();
3201 flush_work(&rwork->work);
3202 return true;
3203 } else {
3204 return flush_work(&rwork->work);
3205 }
3206}
3207EXPORT_SYMBOL(flush_rcu_work);
3208
3209static bool __cancel_work(struct work_struct *work, bool is_dwork)
3210{
3211 unsigned long flags;
3212 int ret;
3213
3214 do {
3215 ret = try_to_grab_pending(work, is_dwork, &flags);
3216 } while (unlikely(ret == -EAGAIN));
3217
3218 if (unlikely(ret < 0))
3219 return false;
3220
3221 set_work_pool_and_clear_pending(work, get_work_pool_id(work));
3222 local_irq_restore(flags);
3223 return ret;
3224}
3225
3226/**
3227 * cancel_delayed_work - cancel a delayed work
3228 * @dwork: delayed_work to cancel
3229 *
3230 * Kill off a pending delayed_work.
3231 *
3232 * Return: %true if @dwork was pending and canceled; %false if it wasn't
3233 * pending.
3234 *
3235 * Note:
3236 * The work callback function may still be running on return, unless
3237 * it returns %true and the work doesn't re-arm itself. Explicitly flush or
3238 * use cancel_delayed_work_sync() to wait on it.
3239 *
3240 * This function is safe to call from any context including IRQ handler.
3241 */
3242bool cancel_delayed_work(struct delayed_work *dwork)
3243{
3244 return __cancel_work(&dwork->work, true);
3245}
3246EXPORT_SYMBOL(cancel_delayed_work);
3247
3248/**
3249 * cancel_delayed_work_sync - cancel a delayed work and wait for it to finish
3250 * @dwork: the delayed work cancel
3251 *
3252 * This is cancel_work_sync() for delayed works.
3253 *
3254 * Return:
3255 * %true if @dwork was pending, %false otherwise.
3256 */
3257bool cancel_delayed_work_sync(struct delayed_work *dwork)
3258{
3259 return __cancel_work_timer(&dwork->work, true);
3260}
3261EXPORT_SYMBOL(cancel_delayed_work_sync);
3262
3263/**
3264 * schedule_on_each_cpu - execute a function synchronously on each online CPU
3265 * @func: the function to call
3266 *
3267 * schedule_on_each_cpu() executes @func on each online CPU using the
3268 * system workqueue and blocks until all CPUs have completed.
3269 * schedule_on_each_cpu() is very slow.
3270 *
3271 * Return:
3272 * 0 on success, -errno on failure.
3273 */
3274int schedule_on_each_cpu(work_func_t func)
3275{
3276 int cpu;
3277 struct work_struct __percpu *works;
3278
3279 works = alloc_percpu(struct work_struct);
3280 if (!works)
3281 return -ENOMEM;
3282
3283 get_online_cpus();
3284
3285 for_each_online_cpu(cpu) {
3286 struct work_struct *work = per_cpu_ptr(works, cpu);
3287
3288 INIT_WORK(work, func);
3289 schedule_work_on(cpu, work);
3290 }
3291
3292 for_each_online_cpu(cpu)
3293 flush_work(per_cpu_ptr(works, cpu));
3294
3295 put_online_cpus();
3296 free_percpu(works);
3297 return 0;
3298}
3299
3300/**
3301 * execute_in_process_context - reliably execute the routine with user context
3302 * @fn: the function to execute
3303 * @ew: guaranteed storage for the execute work structure (must
3304 * be available when the work executes)
3305 *
3306 * Executes the function immediately if process context is available,
3307 * otherwise schedules the function for delayed execution.
3308 *
3309 * Return: 0 - function was executed
3310 * 1 - function was scheduled for execution
3311 */
3312int execute_in_process_context(work_func_t fn, struct execute_work *ew)
3313{
3314 if (!in_interrupt()) {
3315 fn(&ew->work);
3316 return 0;
3317 }
3318
3319 INIT_WORK(&ew->work, fn);
3320 schedule_work(&ew->work);
3321
3322 return 1;
3323}
3324EXPORT_SYMBOL_GPL(execute_in_process_context);
3325
3326/**
3327 * free_workqueue_attrs - free a workqueue_attrs
3328 * @attrs: workqueue_attrs to free
3329 *
3330 * Undo alloc_workqueue_attrs().
3331 */
3332void free_workqueue_attrs(struct workqueue_attrs *attrs)
3333{
3334 if (attrs) {
3335 free_cpumask_var(attrs->cpumask);
3336 kfree(attrs);
3337 }
3338}
3339
3340/**
3341 * alloc_workqueue_attrs - allocate a workqueue_attrs
3342 *
3343 * Allocate a new workqueue_attrs, initialize with default settings and
3344 * return it.
3345 *
3346 * Return: The allocated new workqueue_attr on success. %NULL on failure.
3347 */
3348struct workqueue_attrs *alloc_workqueue_attrs(void)
3349{
3350 struct workqueue_attrs *attrs;
3351
3352 attrs = kzalloc(sizeof(*attrs), GFP_KERNEL);
3353 if (!attrs)
3354 goto fail;
3355 if (!alloc_cpumask_var(&attrs->cpumask, GFP_KERNEL))
3356 goto fail;
3357
3358 cpumask_copy(attrs->cpumask, cpu_possible_mask);
3359 return attrs;
3360fail:
3361 free_workqueue_attrs(attrs);
3362 return NULL;
3363}
3364
3365static void copy_workqueue_attrs(struct workqueue_attrs *to,
3366 const struct workqueue_attrs *from)
3367{
3368 to->nice = from->nice;
3369 cpumask_copy(to->cpumask, from->cpumask);
3370 /*
3371 * Unlike hash and equality test, this function doesn't ignore
3372 * ->no_numa as it is used for both pool and wq attrs. Instead,
3373 * get_unbound_pool() explicitly clears ->no_numa after copying.
3374 */
3375 to->no_numa = from->no_numa;
3376}
3377
3378/* hash value of the content of @attr */
3379static u32 wqattrs_hash(const struct workqueue_attrs *attrs)
3380{
3381 u32 hash = 0;
3382
3383 hash = jhash_1word(attrs->nice, hash);
3384 hash = jhash(cpumask_bits(attrs->cpumask),
3385 BITS_TO_LONGS(nr_cpumask_bits) * sizeof(long), hash);
3386 return hash;
3387}
3388
3389/* content equality test */
3390static bool wqattrs_equal(const struct workqueue_attrs *a,
3391 const struct workqueue_attrs *b)
3392{
3393 if (a->nice != b->nice)
3394 return false;
3395 if (!cpumask_equal(a->cpumask, b->cpumask))
3396 return false;
3397 return true;
3398}
3399
3400/**
3401 * init_worker_pool - initialize a newly zalloc'd worker_pool
3402 * @pool: worker_pool to initialize
3403 *
3404 * Initialize a newly zalloc'd @pool. It also allocates @pool->attrs.
3405 *
3406 * Return: 0 on success, -errno on failure. Even on failure, all fields
3407 * inside @pool proper are initialized and put_unbound_pool() can be called
3408 * on @pool safely to release it.
3409 */
3410static int init_worker_pool(struct worker_pool *pool)
3411{
3412 spin_lock_init(&pool->lock);
3413 pool->id = -1;
3414 pool->cpu = -1;
3415 pool->node = NUMA_NO_NODE;
3416 pool->flags |= POOL_DISASSOCIATED;
3417 pool->watchdog_ts = jiffies;
3418 INIT_LIST_HEAD(&pool->worklist);
3419 INIT_LIST_HEAD(&pool->idle_list);
3420 hash_init(pool->busy_hash);
3421
3422 timer_setup(&pool->idle_timer, idle_worker_timeout, TIMER_DEFERRABLE);
3423
3424 timer_setup(&pool->mayday_timer, pool_mayday_timeout, 0);
3425
3426 INIT_LIST_HEAD(&pool->workers);
3427
3428 ida_init(&pool->worker_ida);
3429 INIT_HLIST_NODE(&pool->hash_node);
3430 pool->refcnt = 1;
3431
3432 /* shouldn't fail above this point */
3433 pool->attrs = alloc_workqueue_attrs();
3434 if (!pool->attrs)
3435 return -ENOMEM;
3436 return 0;
3437}
3438
3439#ifdef CONFIG_LOCKDEP
3440static void wq_init_lockdep(struct workqueue_struct *wq)
3441{
3442 char *lock_name;
3443
3444 lockdep_register_key(&wq->key);
3445 lock_name = kasprintf(GFP_KERNEL, "%s%s", "(wq_completion)", wq->name);
3446 if (!lock_name)
3447 lock_name = wq->name;
3448
3449 wq->lock_name = lock_name;
3450 lockdep_init_map(&wq->lockdep_map, lock_name, &wq->key, 0);
3451}
3452
3453static void wq_unregister_lockdep(struct workqueue_struct *wq)
3454{
3455 lockdep_unregister_key(&wq->key);
3456}
3457
3458static void wq_free_lockdep(struct workqueue_struct *wq)
3459{
3460 if (wq->lock_name != wq->name)
3461 kfree(wq->lock_name);
3462}
3463#else
3464static void wq_init_lockdep(struct workqueue_struct *wq)
3465{
3466}
3467
3468static void wq_unregister_lockdep(struct workqueue_struct *wq)
3469{
3470}
3471
3472static void wq_free_lockdep(struct workqueue_struct *wq)
3473{
3474}
3475#endif
3476
3477static void rcu_free_wq(struct rcu_head *rcu)
3478{
3479 struct workqueue_struct *wq =
3480 container_of(rcu, struct workqueue_struct, rcu);
3481
3482 wq_free_lockdep(wq);
3483
3484 if (!(wq->flags & WQ_UNBOUND))
3485 free_percpu(wq->cpu_pwqs);
3486 else
3487 free_workqueue_attrs(wq->unbound_attrs);
3488
3489 kfree(wq->rescuer);
3490 kfree(wq);
3491}
3492
3493static void rcu_free_pool(struct rcu_head *rcu)
3494{
3495 struct worker_pool *pool = container_of(rcu, struct worker_pool, rcu);
3496
3497 ida_destroy(&pool->worker_ida);
3498 free_workqueue_attrs(pool->attrs);
3499 kfree(pool);
3500}
3501
3502/**
3503 * put_unbound_pool - put a worker_pool
3504 * @pool: worker_pool to put
3505 *
3506 * Put @pool. If its refcnt reaches zero, it gets destroyed in RCU
3507 * safe manner. get_unbound_pool() calls this function on its failure path
3508 * and this function should be able to release pools which went through,
3509 * successfully or not, init_worker_pool().
3510 *
3511 * Should be called with wq_pool_mutex held.
3512 */
3513static void put_unbound_pool(struct worker_pool *pool)
3514{
3515 DECLARE_COMPLETION_ONSTACK(detach_completion);
3516 struct worker *worker;
3517
3518 lockdep_assert_held(&wq_pool_mutex);
3519
3520 if (--pool->refcnt)
3521 return;
3522
3523 /* sanity checks */
3524 if (WARN_ON(!(pool->cpu < 0)) ||
3525 WARN_ON(!list_empty(&pool->worklist)))
3526 return;
3527
3528 /* release id and unhash */
3529 if (pool->id >= 0)
3530 idr_remove(&worker_pool_idr, pool->id);
3531 hash_del(&pool->hash_node);
3532
3533 /*
3534 * Become the manager and destroy all workers. This prevents
3535 * @pool's workers from blocking on attach_mutex. We're the last
3536 * manager and @pool gets freed with the flag set.
3537 */
3538 spin_lock_irq(&pool->lock);
3539 wait_event_lock_irq(wq_manager_wait,
3540 !(pool->flags & POOL_MANAGER_ACTIVE), pool->lock);
3541 pool->flags |= POOL_MANAGER_ACTIVE;
3542
3543 while ((worker = first_idle_worker(pool)))
3544 destroy_worker(worker);
3545 WARN_ON(pool->nr_workers || pool->nr_idle);
3546 spin_unlock_irq(&pool->lock);
3547
3548 mutex_lock(&wq_pool_attach_mutex);
3549 if (!list_empty(&pool->workers))
3550 pool->detach_completion = &detach_completion;
3551 mutex_unlock(&wq_pool_attach_mutex);
3552
3553 if (pool->detach_completion)
3554 wait_for_completion(pool->detach_completion);
3555
3556 /* shut down the timers */
3557 del_timer_sync(&pool->idle_timer);
3558 del_timer_sync(&pool->mayday_timer);
3559
3560 /* RCU protected to allow dereferences from get_work_pool() */
3561 call_rcu(&pool->rcu, rcu_free_pool);
3562}
3563
3564/**
3565 * get_unbound_pool - get a worker_pool with the specified attributes
3566 * @attrs: the attributes of the worker_pool to get
3567 *
3568 * Obtain a worker_pool which has the same attributes as @attrs, bump the
3569 * reference count and return it. If there already is a matching
3570 * worker_pool, it will be used; otherwise, this function attempts to
3571 * create a new one.
3572 *
3573 * Should be called with wq_pool_mutex held.
3574 *
3575 * Return: On success, a worker_pool with the same attributes as @attrs.
3576 * On failure, %NULL.
3577 */
3578static struct worker_pool *get_unbound_pool(const struct workqueue_attrs *attrs)
3579{
3580 u32 hash = wqattrs_hash(attrs);
3581 struct worker_pool *pool;
3582 int node;
3583 int target_node = NUMA_NO_NODE;
3584
3585 lockdep_assert_held(&wq_pool_mutex);
3586
3587 /* do we already have a matching pool? */
3588 hash_for_each_possible(unbound_pool_hash, pool, hash_node, hash) {
3589 if (wqattrs_equal(pool->attrs, attrs)) {
3590 pool->refcnt++;
3591 return pool;
3592 }
3593 }
3594
3595 /* if cpumask is contained inside a NUMA node, we belong to that node */
3596 if (wq_numa_enabled) {
3597 for_each_node(node) {
3598 if (cpumask_subset(attrs->cpumask,
3599 wq_numa_possible_cpumask[node])) {
3600 target_node = node;
3601 break;
3602 }
3603 }
3604 }
3605
3606 /* nope, create a new one */
3607 pool = kzalloc_node(sizeof(*pool), GFP_KERNEL, target_node);
3608 if (!pool || init_worker_pool(pool) < 0)
3609 goto fail;
3610
3611 lockdep_set_subclass(&pool->lock, 1); /* see put_pwq() */
3612 copy_workqueue_attrs(pool->attrs, attrs);
3613 pool->node = target_node;
3614
3615 /*
3616 * no_numa isn't a worker_pool attribute, always clear it. See
3617 * 'struct workqueue_attrs' comments for detail.
3618 */
3619 pool->attrs->no_numa = false;
3620
3621 if (worker_pool_assign_id(pool) < 0)
3622 goto fail;
3623
3624 /* create and start the initial worker */
3625 if (wq_online && !create_worker(pool))
3626 goto fail;
3627
3628 /* install */
3629 hash_add(unbound_pool_hash, &pool->hash_node, hash);
3630
3631 return pool;
3632fail:
3633 if (pool)
3634 put_unbound_pool(pool);
3635 return NULL;
3636}
3637
3638static void rcu_free_pwq(struct rcu_head *rcu)
3639{
3640 kmem_cache_free(pwq_cache,
3641 container_of(rcu, struct pool_workqueue, rcu));
3642}
3643
3644/*
3645 * Scheduled on system_wq by put_pwq() when an unbound pwq hits zero refcnt
3646 * and needs to be destroyed.
3647 */
3648static void pwq_unbound_release_workfn(struct work_struct *work)
3649{
3650 struct pool_workqueue *pwq = container_of(work, struct pool_workqueue,
3651 unbound_release_work);
3652 struct workqueue_struct *wq = pwq->wq;
3653 struct worker_pool *pool = pwq->pool;
3654 bool is_last;
3655
3656 if (WARN_ON_ONCE(!(wq->flags & WQ_UNBOUND)))
3657 return;
3658
3659 mutex_lock(&wq->mutex);
3660 list_del_rcu(&pwq->pwqs_node);
3661 is_last = list_empty(&wq->pwqs);
3662 mutex_unlock(&wq->mutex);
3663
3664 mutex_lock(&wq_pool_mutex);
3665 put_unbound_pool(pool);
3666 mutex_unlock(&wq_pool_mutex);
3667
3668 call_rcu(&pwq->rcu, rcu_free_pwq);
3669
3670 /*
3671 * If we're the last pwq going away, @wq is already dead and no one
3672 * is gonna access it anymore. Schedule RCU free.
3673 */
3674 if (is_last) {
3675 wq_unregister_lockdep(wq);
3676 call_rcu(&wq->rcu, rcu_free_wq);
3677 }
3678}
3679
3680/**
3681 * pwq_adjust_max_active - update a pwq's max_active to the current setting
3682 * @pwq: target pool_workqueue
3683 *
3684 * If @pwq isn't freezing, set @pwq->max_active to the associated
3685 * workqueue's saved_max_active and activate delayed work items
3686 * accordingly. If @pwq is freezing, clear @pwq->max_active to zero.
3687 */
3688static void pwq_adjust_max_active(struct pool_workqueue *pwq)
3689{
3690 struct workqueue_struct *wq = pwq->wq;
3691 bool freezable = wq->flags & WQ_FREEZABLE;
3692 unsigned long flags;
3693
3694 /* for @wq->saved_max_active */
3695 lockdep_assert_held(&wq->mutex);
3696
3697 /* fast exit for non-freezable wqs */
3698 if (!freezable && pwq->max_active == wq->saved_max_active)
3699 return;
3700
3701 /* this function can be called during early boot w/ irq disabled */
3702 spin_lock_irqsave(&pwq->pool->lock, flags);
3703
3704 /*
3705 * During [un]freezing, the caller is responsible for ensuring that
3706 * this function is called at least once after @workqueue_freezing
3707 * is updated and visible.
3708 */
3709 if (!freezable || !workqueue_freezing) {
3710 pwq->max_active = wq->saved_max_active;
3711
3712 while (!list_empty(&pwq->delayed_works) &&
3713 pwq->nr_active < pwq->max_active)
3714 pwq_activate_first_delayed(pwq);
3715
3716 /*
3717 * Need to kick a worker after thawed or an unbound wq's
3718 * max_active is bumped. It's a slow path. Do it always.
3719 */
3720 wake_up_worker(pwq->pool);
3721 } else {
3722 pwq->max_active = 0;
3723 }
3724
3725 spin_unlock_irqrestore(&pwq->pool->lock, flags);
3726}
3727
3728/* initialize newly alloced @pwq which is associated with @wq and @pool */
3729static void init_pwq(struct pool_workqueue *pwq, struct workqueue_struct *wq,
3730 struct worker_pool *pool)
3731{
3732 BUG_ON((unsigned long)pwq & WORK_STRUCT_FLAG_MASK);
3733
3734 memset(pwq, 0, sizeof(*pwq));
3735
3736 pwq->pool = pool;
3737 pwq->wq = wq;
3738 pwq->flush_color = -1;
3739 pwq->refcnt = 1;
3740 INIT_LIST_HEAD(&pwq->delayed_works);
3741 INIT_LIST_HEAD(&pwq->pwqs_node);
3742 INIT_LIST_HEAD(&pwq->mayday_node);
3743 INIT_WORK(&pwq->unbound_release_work, pwq_unbound_release_workfn);
3744}
3745
3746/* sync @pwq with the current state of its associated wq and link it */
3747static void link_pwq(struct pool_workqueue *pwq)
3748{
3749 struct workqueue_struct *wq = pwq->wq;
3750
3751 lockdep_assert_held(&wq->mutex);
3752
3753 /* may be called multiple times, ignore if already linked */
3754 if (!list_empty(&pwq->pwqs_node))
3755 return;
3756
3757 /* set the matching work_color */
3758 pwq->work_color = wq->work_color;
3759
3760 /* sync max_active to the current setting */
3761 pwq_adjust_max_active(pwq);
3762
3763 /* link in @pwq */
3764 list_add_rcu(&pwq->pwqs_node, &wq->pwqs);
3765}
3766
3767/* obtain a pool matching @attr and create a pwq associating the pool and @wq */
3768static struct pool_workqueue *alloc_unbound_pwq(struct workqueue_struct *wq,
3769 const struct workqueue_attrs *attrs)
3770{
3771 struct worker_pool *pool;
3772 struct pool_workqueue *pwq;
3773
3774 lockdep_assert_held(&wq_pool_mutex);
3775
3776 pool = get_unbound_pool(attrs);
3777 if (!pool)
3778 return NULL;
3779
3780 pwq = kmem_cache_alloc_node(pwq_cache, GFP_KERNEL, pool->node);
3781 if (!pwq) {
3782 put_unbound_pool(pool);
3783 return NULL;
3784 }
3785
3786 init_pwq(pwq, wq, pool);
3787 return pwq;
3788}
3789
3790/**
3791 * wq_calc_node_cpumask - calculate a wq_attrs' cpumask for the specified node
3792 * @attrs: the wq_attrs of the default pwq of the target workqueue
3793 * @node: the target NUMA node
3794 * @cpu_going_down: if >= 0, the CPU to consider as offline
3795 * @cpumask: outarg, the resulting cpumask
3796 *
3797 * Calculate the cpumask a workqueue with @attrs should use on @node. If
3798 * @cpu_going_down is >= 0, that cpu is considered offline during
3799 * calculation. The result is stored in @cpumask.
3800 *
3801 * If NUMA affinity is not enabled, @attrs->cpumask is always used. If
3802 * enabled and @node has online CPUs requested by @attrs, the returned
3803 * cpumask is the intersection of the possible CPUs of @node and
3804 * @attrs->cpumask.
3805 *
3806 * The caller is responsible for ensuring that the cpumask of @node stays
3807 * stable.
3808 *
3809 * Return: %true if the resulting @cpumask is different from @attrs->cpumask,
3810 * %false if equal.
3811 */
3812static bool wq_calc_node_cpumask(const struct workqueue_attrs *attrs, int node,
3813 int cpu_going_down, cpumask_t *cpumask)
3814{
3815 if (!wq_numa_enabled || attrs->no_numa)
3816 goto use_dfl;
3817
3818 /* does @node have any online CPUs @attrs wants? */
3819 cpumask_and(cpumask, cpumask_of_node(node), attrs->cpumask);
3820 if (cpu_going_down >= 0)
3821 cpumask_clear_cpu(cpu_going_down, cpumask);
3822
3823 if (cpumask_empty(cpumask))
3824 goto use_dfl;
3825
3826 /* yeap, return possible CPUs in @node that @attrs wants */
3827 cpumask_and(cpumask, attrs->cpumask, wq_numa_possible_cpumask[node]);
3828
3829 if (cpumask_empty(cpumask)) {
3830 pr_warn_once("WARNING: workqueue cpumask: online intersect > "
3831 "possible intersect\n");
3832 return false;
3833 }
3834
3835 return !cpumask_equal(cpumask, attrs->cpumask);
3836
3837use_dfl:
3838 cpumask_copy(cpumask, attrs->cpumask);
3839 return false;
3840}
3841
3842/* install @pwq into @wq's numa_pwq_tbl[] for @node and return the old pwq */
3843static struct pool_workqueue *numa_pwq_tbl_install(struct workqueue_struct *wq,
3844 int node,
3845 struct pool_workqueue *pwq)
3846{
3847 struct pool_workqueue *old_pwq;
3848
3849 lockdep_assert_held(&wq_pool_mutex);
3850 lockdep_assert_held(&wq->mutex);
3851
3852 /* link_pwq() can handle duplicate calls */
3853 link_pwq(pwq);
3854
3855 old_pwq = rcu_access_pointer(wq->numa_pwq_tbl[node]);
3856 rcu_assign_pointer(wq->numa_pwq_tbl[node], pwq);
3857 return old_pwq;
3858}
3859
3860/* context to store the prepared attrs & pwqs before applying */
3861struct apply_wqattrs_ctx {
3862 struct workqueue_struct *wq; /* target workqueue */
3863 struct workqueue_attrs *attrs; /* attrs to apply */
3864 struct list_head list; /* queued for batching commit */
3865 struct pool_workqueue *dfl_pwq;
3866 struct pool_workqueue *pwq_tbl[];
3867};
3868
3869/* free the resources after success or abort */
3870static void apply_wqattrs_cleanup(struct apply_wqattrs_ctx *ctx)
3871{
3872 if (ctx) {
3873 int node;
3874
3875 for_each_node(node)
3876 put_pwq_unlocked(ctx->pwq_tbl[node]);
3877 put_pwq_unlocked(ctx->dfl_pwq);
3878
3879 free_workqueue_attrs(ctx->attrs);
3880
3881 kfree(ctx);
3882 }
3883}
3884
3885/* allocate the attrs and pwqs for later installation */
3886static struct apply_wqattrs_ctx *
3887apply_wqattrs_prepare(struct workqueue_struct *wq,
3888 const struct workqueue_attrs *attrs)
3889{
3890 struct apply_wqattrs_ctx *ctx;
3891 struct workqueue_attrs *new_attrs, *tmp_attrs;
3892 int node;
3893
3894 lockdep_assert_held(&wq_pool_mutex);
3895
3896 ctx = kzalloc(struct_size(ctx, pwq_tbl, nr_node_ids), GFP_KERNEL);
3897
3898 new_attrs = alloc_workqueue_attrs();
3899 tmp_attrs = alloc_workqueue_attrs();
3900 if (!ctx || !new_attrs || !tmp_attrs)
3901 goto out_free;
3902
3903 /*
3904 * Calculate the attrs of the default pwq.
3905 * If the user configured cpumask doesn't overlap with the
3906 * wq_unbound_cpumask, we fallback to the wq_unbound_cpumask.
3907 */
3908 copy_workqueue_attrs(new_attrs, attrs);
3909 cpumask_and(new_attrs->cpumask, new_attrs->cpumask, wq_unbound_cpumask);
3910 if (unlikely(cpumask_empty(new_attrs->cpumask)))
3911 cpumask_copy(new_attrs->cpumask, wq_unbound_cpumask);
3912
3913 /*
3914 * We may create multiple pwqs with differing cpumasks. Make a
3915 * copy of @new_attrs which will be modified and used to obtain
3916 * pools.
3917 */
3918 copy_workqueue_attrs(tmp_attrs, new_attrs);
3919
3920 /*
3921 * If something goes wrong during CPU up/down, we'll fall back to
3922 * the default pwq covering whole @attrs->cpumask. Always create
3923 * it even if we don't use it immediately.
3924 */
3925 ctx->dfl_pwq = alloc_unbound_pwq(wq, new_attrs);
3926 if (!ctx->dfl_pwq)
3927 goto out_free;
3928
3929 for_each_node(node) {
3930 if (wq_calc_node_cpumask(new_attrs, node, -1, tmp_attrs->cpumask)) {
3931 ctx->pwq_tbl[node] = alloc_unbound_pwq(wq, tmp_attrs);
3932 if (!ctx->pwq_tbl[node])
3933 goto out_free;
3934 } else {
3935 ctx->dfl_pwq->refcnt++;
3936 ctx->pwq_tbl[node] = ctx->dfl_pwq;
3937 }
3938 }
3939
3940 /* save the user configured attrs and sanitize it. */
3941 copy_workqueue_attrs(new_attrs, attrs);
3942 cpumask_and(new_attrs->cpumask, new_attrs->cpumask, cpu_possible_mask);
3943 ctx->attrs = new_attrs;
3944
3945 ctx->wq = wq;
3946 free_workqueue_attrs(tmp_attrs);
3947 return ctx;
3948
3949out_free:
3950 free_workqueue_attrs(tmp_attrs);
3951 free_workqueue_attrs(new_attrs);
3952 apply_wqattrs_cleanup(ctx);
3953 return NULL;
3954}
3955
3956/* set attrs and install prepared pwqs, @ctx points to old pwqs on return */
3957static void apply_wqattrs_commit(struct apply_wqattrs_ctx *ctx)
3958{
3959 int node;
3960
3961 /* all pwqs have been created successfully, let's install'em */
3962 mutex_lock(&ctx->wq->mutex);
3963
3964 copy_workqueue_attrs(ctx->wq->unbound_attrs, ctx->attrs);
3965
3966 /* save the previous pwq and install the new one */
3967 for_each_node(node)
3968 ctx->pwq_tbl[node] = numa_pwq_tbl_install(ctx->wq, node,
3969 ctx->pwq_tbl[node]);
3970
3971 /* @dfl_pwq might not have been used, ensure it's linked */
3972 link_pwq(ctx->dfl_pwq);
3973 swap(ctx->wq->dfl_pwq, ctx->dfl_pwq);
3974
3975 mutex_unlock(&ctx->wq->mutex);
3976}
3977
3978static void apply_wqattrs_lock(void)
3979{
3980 /* CPUs should stay stable across pwq creations and installations */
3981 get_online_cpus();
3982 mutex_lock(&wq_pool_mutex);
3983}
3984
3985static void apply_wqattrs_unlock(void)
3986{
3987 mutex_unlock(&wq_pool_mutex);
3988 put_online_cpus();
3989}
3990
3991static int apply_workqueue_attrs_locked(struct workqueue_struct *wq,
3992 const struct workqueue_attrs *attrs)
3993{
3994 struct apply_wqattrs_ctx *ctx;
3995
3996 /* only unbound workqueues can change attributes */
3997 if (WARN_ON(!(wq->flags & WQ_UNBOUND)))
3998 return -EINVAL;
3999
4000 /* creating multiple pwqs breaks ordering guarantee */
4001 if (!list_empty(&wq->pwqs)) {
4002 if (WARN_ON(wq->flags & __WQ_ORDERED_EXPLICIT))
4003 return -EINVAL;
4004
4005 wq->flags &= ~__WQ_ORDERED;
4006 }
4007
4008 ctx = apply_wqattrs_prepare(wq, attrs);
4009 if (!ctx)
4010 return -ENOMEM;
4011
4012 /* the ctx has been prepared successfully, let's commit it */
4013 apply_wqattrs_commit(ctx);
4014 apply_wqattrs_cleanup(ctx);
4015
4016 return 0;
4017}
4018
4019/**
4020 * apply_workqueue_attrs - apply new workqueue_attrs to an unbound workqueue
4021 * @wq: the target workqueue
4022 * @attrs: the workqueue_attrs to apply, allocated with alloc_workqueue_attrs()
4023 *
4024 * Apply @attrs to an unbound workqueue @wq. Unless disabled, on NUMA
4025 * machines, this function maps a separate pwq to each NUMA node with
4026 * possibles CPUs in @attrs->cpumask so that work items are affine to the
4027 * NUMA node it was issued on. Older pwqs are released as in-flight work
4028 * items finish. Note that a work item which repeatedly requeues itself
4029 * back-to-back will stay on its current pwq.
4030 *
4031 * Performs GFP_KERNEL allocations.
4032 *
4033 * Assumes caller has CPU hotplug read exclusion, i.e. get_online_cpus().
4034 *
4035 * Return: 0 on success and -errno on failure.
4036 */
4037int apply_workqueue_attrs(struct workqueue_struct *wq,
4038 const struct workqueue_attrs *attrs)
4039{
4040 int ret;
4041
4042 lockdep_assert_cpus_held();
4043
4044 mutex_lock(&wq_pool_mutex);
4045 ret = apply_workqueue_attrs_locked(wq, attrs);
4046 mutex_unlock(&wq_pool_mutex);
4047
4048 return ret;
4049}
4050
4051/**
4052 * wq_update_unbound_numa - update NUMA affinity of a wq for CPU hot[un]plug
4053 * @wq: the target workqueue
4054 * @cpu: the CPU coming up or going down
4055 * @online: whether @cpu is coming up or going down
4056 *
4057 * This function is to be called from %CPU_DOWN_PREPARE, %CPU_ONLINE and
4058 * %CPU_DOWN_FAILED. @cpu is being hot[un]plugged, update NUMA affinity of
4059 * @wq accordingly.
4060 *
4061 * If NUMA affinity can't be adjusted due to memory allocation failure, it
4062 * falls back to @wq->dfl_pwq which may not be optimal but is always
4063 * correct.
4064 *
4065 * Note that when the last allowed CPU of a NUMA node goes offline for a
4066 * workqueue with a cpumask spanning multiple nodes, the workers which were
4067 * already executing the work items for the workqueue will lose their CPU
4068 * affinity and may execute on any CPU. This is similar to how per-cpu
4069 * workqueues behave on CPU_DOWN. If a workqueue user wants strict
4070 * affinity, it's the user's responsibility to flush the work item from
4071 * CPU_DOWN_PREPARE.
4072 */
4073static void wq_update_unbound_numa(struct workqueue_struct *wq, int cpu,
4074 bool online)
4075{
4076 int node = cpu_to_node(cpu);
4077 int cpu_off = online ? -1 : cpu;
4078 struct pool_workqueue *old_pwq = NULL, *pwq;
4079 struct workqueue_attrs *target_attrs;
4080 cpumask_t *cpumask;
4081
4082 lockdep_assert_held(&wq_pool_mutex);
4083
4084 if (!wq_numa_enabled || !(wq->flags & WQ_UNBOUND) ||
4085 wq->unbound_attrs->no_numa)
4086 return;
4087
4088 /*
4089 * We don't wanna alloc/free wq_attrs for each wq for each CPU.
4090 * Let's use a preallocated one. The following buf is protected by
4091 * CPU hotplug exclusion.
4092 */
4093 target_attrs = wq_update_unbound_numa_attrs_buf;
4094 cpumask = target_attrs->cpumask;
4095
4096 copy_workqueue_attrs(target_attrs, wq->unbound_attrs);
4097 pwq = unbound_pwq_by_node(wq, node);
4098
4099 /*
4100 * Let's determine what needs to be done. If the target cpumask is
4101 * different from the default pwq's, we need to compare it to @pwq's
4102 * and create a new one if they don't match. If the target cpumask
4103 * equals the default pwq's, the default pwq should be used.
4104 */
4105 if (wq_calc_node_cpumask(wq->dfl_pwq->pool->attrs, node, cpu_off, cpumask)) {
4106 if (cpumask_equal(cpumask, pwq->pool->attrs->cpumask))
4107 return;
4108 } else {
4109 goto use_dfl_pwq;
4110 }
4111
4112 /* create a new pwq */
4113 pwq = alloc_unbound_pwq(wq, target_attrs);
4114 if (!pwq) {
4115 pr_warn("workqueue: allocation failed while updating NUMA affinity of \"%s\"\n",
4116 wq->name);
4117 goto use_dfl_pwq;
4118 }
4119
4120 /* Install the new pwq. */
4121 mutex_lock(&wq->mutex);
4122 old_pwq = numa_pwq_tbl_install(wq, node, pwq);
4123 goto out_unlock;
4124
4125use_dfl_pwq:
4126 mutex_lock(&wq->mutex);
4127 spin_lock_irq(&wq->dfl_pwq->pool->lock);
4128 get_pwq(wq->dfl_pwq);
4129 spin_unlock_irq(&wq->dfl_pwq->pool->lock);
4130 old_pwq = numa_pwq_tbl_install(wq, node, wq->dfl_pwq);
4131out_unlock:
4132 mutex_unlock(&wq->mutex);
4133 put_pwq_unlocked(old_pwq);
4134}
4135
4136static int alloc_and_link_pwqs(struct workqueue_struct *wq)
4137{
4138 bool highpri = wq->flags & WQ_HIGHPRI;
4139 int cpu, ret;
4140
4141 if (!(wq->flags & WQ_UNBOUND)) {
4142 wq->cpu_pwqs = alloc_percpu(struct pool_workqueue);
4143 if (!wq->cpu_pwqs)
4144 return -ENOMEM;
4145
4146 for_each_possible_cpu(cpu) {
4147 struct pool_workqueue *pwq =
4148 per_cpu_ptr(wq->cpu_pwqs, cpu);
4149 struct worker_pool *cpu_pools =
4150 per_cpu(cpu_worker_pools, cpu);
4151
4152 init_pwq(pwq, wq, &cpu_pools[highpri]);
4153
4154 mutex_lock(&wq->mutex);
4155 link_pwq(pwq);
4156 mutex_unlock(&wq->mutex);
4157 }
4158 return 0;
4159 }
4160
4161 get_online_cpus();
4162 if (wq->flags & __WQ_ORDERED) {
4163 ret = apply_workqueue_attrs(wq, ordered_wq_attrs[highpri]);
4164 /* there should only be single pwq for ordering guarantee */
4165 WARN(!ret && (wq->pwqs.next != &wq->dfl_pwq->pwqs_node ||
4166 wq->pwqs.prev != &wq->dfl_pwq->pwqs_node),
4167 "ordering guarantee broken for workqueue %s\n", wq->name);
4168 } else {
4169 ret = apply_workqueue_attrs(wq, unbound_std_wq_attrs[highpri]);
4170 }
4171 put_online_cpus();
4172
4173 return ret;
4174}
4175
4176static int wq_clamp_max_active(int max_active, unsigned int flags,
4177 const char *name)
4178{
4179 int lim = flags & WQ_UNBOUND ? WQ_UNBOUND_MAX_ACTIVE : WQ_MAX_ACTIVE;
4180
4181 if (max_active < 1 || max_active > lim)
4182 pr_warn("workqueue: max_active %d requested for %s is out of range, clamping between %d and %d\n",
4183 max_active, name, 1, lim);
4184
4185 return clamp_val(max_active, 1, lim);
4186}
4187
4188/*
4189 * Workqueues which may be used during memory reclaim should have a rescuer
4190 * to guarantee forward progress.
4191 */
4192static int init_rescuer(struct workqueue_struct *wq)
4193{
4194 struct worker *rescuer;
4195 int ret;
4196
4197 if (!(wq->flags & WQ_MEM_RECLAIM))
4198 return 0;
4199
4200 rescuer = alloc_worker(NUMA_NO_NODE);
4201 if (!rescuer)
4202 return -ENOMEM;
4203
4204 rescuer->rescue_wq = wq;
4205 rescuer->task = kthread_create(rescuer_thread, rescuer, "%s", wq->name);
4206 ret = PTR_ERR_OR_ZERO(rescuer->task);
4207 if (ret) {
4208 kfree(rescuer);
4209 return ret;
4210 }
4211
4212 wq->rescuer = rescuer;
4213 kthread_bind_mask(rescuer->task, cpu_possible_mask);
4214 wake_up_process(rescuer->task);
4215
4216 return 0;
4217}
4218
4219__printf(1, 4)
4220struct workqueue_struct *alloc_workqueue(const char *fmt,
4221 unsigned int flags,
4222 int max_active, ...)
4223{
4224 size_t tbl_size = 0;
4225 va_list args;
4226 struct workqueue_struct *wq;
4227 struct pool_workqueue *pwq;
4228
4229 /*
4230 * Unbound && max_active == 1 used to imply ordered, which is no
4231 * longer the case on NUMA machines due to per-node pools. While
4232 * alloc_ordered_workqueue() is the right way to create an ordered
4233 * workqueue, keep the previous behavior to avoid subtle breakages
4234 * on NUMA.
4235 */
4236 if ((flags & WQ_UNBOUND) && max_active == 1)
4237 flags |= __WQ_ORDERED;
4238
4239 /* see the comment above the definition of WQ_POWER_EFFICIENT */
4240 if ((flags & WQ_POWER_EFFICIENT) && wq_power_efficient)
4241 flags |= WQ_UNBOUND;
4242
4243 /* allocate wq and format name */
4244 if (flags & WQ_UNBOUND)
4245 tbl_size = nr_node_ids * sizeof(wq->numa_pwq_tbl[0]);
4246
4247 wq = kzalloc(sizeof(*wq) + tbl_size, GFP_KERNEL);
4248 if (!wq)
4249 return NULL;
4250
4251 if (flags & WQ_UNBOUND) {
4252 wq->unbound_attrs = alloc_workqueue_attrs();
4253 if (!wq->unbound_attrs)
4254 goto err_free_wq;
4255 }
4256
4257 va_start(args, max_active);
4258 vsnprintf(wq->name, sizeof(wq->name), fmt, args);
4259 va_end(args);
4260
4261 max_active = max_active ?: WQ_DFL_ACTIVE;
4262 max_active = wq_clamp_max_active(max_active, flags, wq->name);
4263
4264 /* init wq */
4265 wq->flags = flags;
4266 wq->saved_max_active = max_active;
4267 mutex_init(&wq->mutex);
4268 atomic_set(&wq->nr_pwqs_to_flush, 0);
4269 INIT_LIST_HEAD(&wq->pwqs);
4270 INIT_LIST_HEAD(&wq->flusher_queue);
4271 INIT_LIST_HEAD(&wq->flusher_overflow);
4272 INIT_LIST_HEAD(&wq->maydays);
4273
4274 wq_init_lockdep(wq);
4275 INIT_LIST_HEAD(&wq->list);
4276
4277 if (alloc_and_link_pwqs(wq) < 0)
4278 goto err_unreg_lockdep;
4279
4280 if (wq_online && init_rescuer(wq) < 0)
4281 goto err_destroy;
4282
4283 if ((wq->flags & WQ_SYSFS) && workqueue_sysfs_register(wq))
4284 goto err_destroy;
4285
4286 /*
4287 * wq_pool_mutex protects global freeze state and workqueues list.
4288 * Grab it, adjust max_active and add the new @wq to workqueues
4289 * list.
4290 */
4291 mutex_lock(&wq_pool_mutex);
4292
4293 mutex_lock(&wq->mutex);
4294 for_each_pwq(pwq, wq)
4295 pwq_adjust_max_active(pwq);
4296 mutex_unlock(&wq->mutex);
4297
4298 list_add_tail_rcu(&wq->list, &workqueues);
4299
4300 mutex_unlock(&wq_pool_mutex);
4301
4302 return wq;
4303
4304err_unreg_lockdep:
4305 wq_unregister_lockdep(wq);
4306 wq_free_lockdep(wq);
4307err_free_wq:
4308 free_workqueue_attrs(wq->unbound_attrs);
4309 kfree(wq);
4310 return NULL;
4311err_destroy:
4312 destroy_workqueue(wq);
4313 return NULL;
4314}
4315EXPORT_SYMBOL_GPL(alloc_workqueue);
4316
4317/**
4318 * destroy_workqueue - safely terminate a workqueue
4319 * @wq: target workqueue
4320 *
4321 * Safely destroy a workqueue. All work currently pending will be done first.
4322 */
4323void destroy_workqueue(struct workqueue_struct *wq)
4324{
4325 struct pool_workqueue *pwq;
4326 int node;
4327
4328 /* drain it before proceeding with destruction */
4329 drain_workqueue(wq);
4330
4331 /* sanity checks */
4332 mutex_lock(&wq->mutex);
4333 for_each_pwq(pwq, wq) {
4334 int i;
4335
4336 for (i = 0; i < WORK_NR_COLORS; i++) {
4337 if (WARN_ON(pwq->nr_in_flight[i])) {
4338 mutex_unlock(&wq->mutex);
4339 show_workqueue_state();
4340 return;
4341 }
4342 }
4343
4344 if (WARN_ON((pwq != wq->dfl_pwq) && (pwq->refcnt > 1)) ||
4345 WARN_ON(pwq->nr_active) ||
4346 WARN_ON(!list_empty(&pwq->delayed_works))) {
4347 mutex_unlock(&wq->mutex);
4348 show_workqueue_state();
4349 return;
4350 }
4351 }
4352 mutex_unlock(&wq->mutex);
4353
4354 /*
4355 * wq list is used to freeze wq, remove from list after
4356 * flushing is complete in case freeze races us.
4357 */
4358 mutex_lock(&wq_pool_mutex);
4359 list_del_rcu(&wq->list);
4360 mutex_unlock(&wq_pool_mutex);
4361
4362 workqueue_sysfs_unregister(wq);
4363
4364 if (wq->rescuer)
4365 kthread_stop(wq->rescuer->task);
4366
4367 if (!(wq->flags & WQ_UNBOUND)) {
4368 wq_unregister_lockdep(wq);
4369 /*
4370 * The base ref is never dropped on per-cpu pwqs. Directly
4371 * schedule RCU free.
4372 */
4373 call_rcu(&wq->rcu, rcu_free_wq);
4374 } else {
4375 /*
4376 * We're the sole accessor of @wq at this point. Directly
4377 * access numa_pwq_tbl[] and dfl_pwq to put the base refs.
4378 * @wq will be freed when the last pwq is released.
4379 */
4380 for_each_node(node) {
4381 pwq = rcu_access_pointer(wq->numa_pwq_tbl[node]);
4382 RCU_INIT_POINTER(wq->numa_pwq_tbl[node], NULL);
4383 put_pwq_unlocked(pwq);
4384 }
4385
4386 /*
4387 * Put dfl_pwq. @wq may be freed any time after dfl_pwq is
4388 * put. Don't access it afterwards.
4389 */
4390 pwq = wq->dfl_pwq;
4391 wq->dfl_pwq = NULL;
4392 put_pwq_unlocked(pwq);
4393 }
4394}
4395EXPORT_SYMBOL_GPL(destroy_workqueue);
4396
4397/**
4398 * workqueue_set_max_active - adjust max_active of a workqueue
4399 * @wq: target workqueue
4400 * @max_active: new max_active value.
4401 *
4402 * Set max_active of @wq to @max_active.
4403 *
4404 * CONTEXT:
4405 * Don't call from IRQ context.
4406 */
4407void workqueue_set_max_active(struct workqueue_struct *wq, int max_active)
4408{
4409 struct pool_workqueue *pwq;
4410
4411 /* disallow meddling with max_active for ordered workqueues */
4412 if (WARN_ON(wq->flags & __WQ_ORDERED_EXPLICIT))
4413 return;
4414
4415 max_active = wq_clamp_max_active(max_active, wq->flags, wq->name);
4416
4417 mutex_lock(&wq->mutex);
4418
4419 wq->flags &= ~__WQ_ORDERED;
4420 wq->saved_max_active = max_active;
4421
4422 for_each_pwq(pwq, wq)
4423 pwq_adjust_max_active(pwq);
4424
4425 mutex_unlock(&wq->mutex);
4426}
4427EXPORT_SYMBOL_GPL(workqueue_set_max_active);
4428
4429/**
4430 * current_work - retrieve %current task's work struct
4431 *
4432 * Determine if %current task is a workqueue worker and what it's working on.
4433 * Useful to find out the context that the %current task is running in.
4434 *
4435 * Return: work struct if %current task is a workqueue worker, %NULL otherwise.
4436 */
4437struct work_struct *current_work(void)
4438{
4439 struct worker *worker = current_wq_worker();
4440
4441 return worker ? worker->current_work : NULL;
4442}
4443EXPORT_SYMBOL(current_work);
4444
4445/**
4446 * current_is_workqueue_rescuer - is %current workqueue rescuer?
4447 *
4448 * Determine whether %current is a workqueue rescuer. Can be used from
4449 * work functions to determine whether it's being run off the rescuer task.
4450 *
4451 * Return: %true if %current is a workqueue rescuer. %false otherwise.
4452 */
4453bool current_is_workqueue_rescuer(void)
4454{
4455 struct worker *worker = current_wq_worker();
4456
4457 return worker && worker->rescue_wq;
4458}
4459
4460/**
4461 * workqueue_congested - test whether a workqueue is congested
4462 * @cpu: CPU in question
4463 * @wq: target workqueue
4464 *
4465 * Test whether @wq's cpu workqueue for @cpu is congested. There is
4466 * no synchronization around this function and the test result is
4467 * unreliable and only useful as advisory hints or for debugging.
4468 *
4469 * If @cpu is WORK_CPU_UNBOUND, the test is performed on the local CPU.
4470 * Note that both per-cpu and unbound workqueues may be associated with
4471 * multiple pool_workqueues which have separate congested states. A
4472 * workqueue being congested on one CPU doesn't mean the workqueue is also
4473 * contested on other CPUs / NUMA nodes.
4474 *
4475 * Return:
4476 * %true if congested, %false otherwise.
4477 */
4478bool workqueue_congested(int cpu, struct workqueue_struct *wq)
4479{
4480 struct pool_workqueue *pwq;
4481 bool ret;
4482
4483 rcu_read_lock();
4484 preempt_disable();
4485
4486 if (cpu == WORK_CPU_UNBOUND)
4487 cpu = smp_processor_id();
4488
4489 if (!(wq->flags & WQ_UNBOUND))
4490 pwq = per_cpu_ptr(wq->cpu_pwqs, cpu);
4491 else
4492 pwq = unbound_pwq_by_node(wq, cpu_to_node(cpu));
4493
4494 ret = !list_empty(&pwq->delayed_works);
4495 preempt_enable();
4496 rcu_read_unlock();
4497
4498 return ret;
4499}
4500EXPORT_SYMBOL_GPL(workqueue_congested);
4501
4502/**
4503 * work_busy - test whether a work is currently pending or running
4504 * @work: the work to be tested
4505 *
4506 * Test whether @work is currently pending or running. There is no
4507 * synchronization around this function and the test result is
4508 * unreliable and only useful as advisory hints or for debugging.
4509 *
4510 * Return:
4511 * OR'd bitmask of WORK_BUSY_* bits.
4512 */
4513unsigned int work_busy(struct work_struct *work)
4514{
4515 struct worker_pool *pool;
4516 unsigned long flags;
4517 unsigned int ret = 0;
4518
4519 if (work_pending(work))
4520 ret |= WORK_BUSY_PENDING;
4521
4522 rcu_read_lock();
4523 pool = get_work_pool(work);
4524 if (pool) {
4525 spin_lock_irqsave(&pool->lock, flags);
4526 if (find_worker_executing_work(pool, work))
4527 ret |= WORK_BUSY_RUNNING;
4528 spin_unlock_irqrestore(&pool->lock, flags);
4529 }
4530 rcu_read_unlock();
4531
4532 return ret;
4533}
4534EXPORT_SYMBOL_GPL(work_busy);
4535
4536/**
4537 * set_worker_desc - set description for the current work item
4538 * @fmt: printf-style format string
4539 * @...: arguments for the format string
4540 *
4541 * This function can be called by a running work function to describe what
4542 * the work item is about. If the worker task gets dumped, this
4543 * information will be printed out together to help debugging. The
4544 * description can be at most WORKER_DESC_LEN including the trailing '\0'.
4545 */
4546void set_worker_desc(const char *fmt, ...)
4547{
4548 struct worker *worker = current_wq_worker();
4549 va_list args;
4550
4551 if (worker) {
4552 va_start(args, fmt);
4553 vsnprintf(worker->desc, sizeof(worker->desc), fmt, args);
4554 va_end(args);
4555 }
4556}
4557EXPORT_SYMBOL_GPL(set_worker_desc);
4558
4559/**
4560 * print_worker_info - print out worker information and description
4561 * @log_lvl: the log level to use when printing
4562 * @task: target task
4563 *
4564 * If @task is a worker and currently executing a work item, print out the
4565 * name of the workqueue being serviced and worker description set with
4566 * set_worker_desc() by the currently executing work item.
4567 *
4568 * This function can be safely called on any task as long as the
4569 * task_struct itself is accessible. While safe, this function isn't
4570 * synchronized and may print out mixups or garbages of limited length.
4571 */
4572void print_worker_info(const char *log_lvl, struct task_struct *task)
4573{
4574 work_func_t *fn = NULL;
4575 char name[WQ_NAME_LEN] = { };
4576 char desc[WORKER_DESC_LEN] = { };
4577 struct pool_workqueue *pwq = NULL;
4578 struct workqueue_struct *wq = NULL;
4579 struct worker *worker;
4580
4581 if (!(task->flags & PF_WQ_WORKER))
4582 return;
4583
4584 /*
4585 * This function is called without any synchronization and @task
4586 * could be in any state. Be careful with dereferences.
4587 */
4588 worker = kthread_probe_data(task);
4589
4590 /*
4591 * Carefully copy the associated workqueue's workfn, name and desc.
4592 * Keep the original last '\0' in case the original is garbage.
4593 */
4594 probe_kernel_read(&fn, &worker->current_func, sizeof(fn));
4595 probe_kernel_read(&pwq, &worker->current_pwq, sizeof(pwq));
4596 probe_kernel_read(&wq, &pwq->wq, sizeof(wq));
4597 probe_kernel_read(name, wq->name, sizeof(name) - 1);
4598 probe_kernel_read(desc, worker->desc, sizeof(desc) - 1);
4599
4600 if (fn || name[0] || desc[0]) {
4601 printk("%sWorkqueue: %s %ps", log_lvl, name, fn);
4602 if (strcmp(name, desc))
4603 pr_cont(" (%s)", desc);
4604 pr_cont("\n");
4605 }
4606}
4607
4608static void pr_cont_pool_info(struct worker_pool *pool)
4609{
4610 pr_cont(" cpus=%*pbl", nr_cpumask_bits, pool->attrs->cpumask);
4611 if (pool->node != NUMA_NO_NODE)
4612 pr_cont(" node=%d", pool->node);
4613 pr_cont(" flags=0x%x nice=%d", pool->flags, pool->attrs->nice);
4614}
4615
4616static void pr_cont_work(bool comma, struct work_struct *work)
4617{
4618 if (work->func == wq_barrier_func) {
4619 struct wq_barrier *barr;
4620
4621 barr = container_of(work, struct wq_barrier, work);
4622
4623 pr_cont("%s BAR(%d)", comma ? "," : "",
4624 task_pid_nr(barr->task));
4625 } else {
4626 pr_cont("%s %ps", comma ? "," : "", work->func);
4627 }
4628}
4629
4630static void show_pwq(struct pool_workqueue *pwq)
4631{
4632 struct worker_pool *pool = pwq->pool;
4633 struct work_struct *work;
4634 struct worker *worker;
4635 bool has_in_flight = false, has_pending = false;
4636 int bkt;
4637
4638 pr_info(" pwq %d:", pool->id);
4639 pr_cont_pool_info(pool);
4640
4641 pr_cont(" active=%d/%d%s\n", pwq->nr_active, pwq->max_active,
4642 !list_empty(&pwq->mayday_node) ? " MAYDAY" : "");
4643
4644 hash_for_each(pool->busy_hash, bkt, worker, hentry) {
4645 if (worker->current_pwq == pwq) {
4646 has_in_flight = true;
4647 break;
4648 }
4649 }
4650 if (has_in_flight) {
4651 bool comma = false;
4652
4653 pr_info(" in-flight:");
4654 hash_for_each(pool->busy_hash, bkt, worker, hentry) {
4655 if (worker->current_pwq != pwq)
4656 continue;
4657
4658 pr_cont("%s %d%s:%ps", comma ? "," : "",
4659 task_pid_nr(worker->task),
4660 worker == pwq->wq->rescuer ? "(RESCUER)" : "",
4661 worker->current_func);
4662 list_for_each_entry(work, &worker->scheduled, entry)
4663 pr_cont_work(false, work);
4664 comma = true;
4665 }
4666 pr_cont("\n");
4667 }
4668
4669 list_for_each_entry(work, &pool->worklist, entry) {
4670 if (get_work_pwq(work) == pwq) {
4671 has_pending = true;
4672 break;
4673 }
4674 }
4675 if (has_pending) {
4676 bool comma = false;
4677
4678 pr_info(" pending:");
4679 list_for_each_entry(work, &pool->worklist, entry) {
4680 if (get_work_pwq(work) != pwq)
4681 continue;
4682
4683 pr_cont_work(comma, work);
4684 comma = !(*work_data_bits(work) & WORK_STRUCT_LINKED);
4685 }
4686 pr_cont("\n");
4687 }
4688
4689 if (!list_empty(&pwq->delayed_works)) {
4690 bool comma = false;
4691
4692 pr_info(" delayed:");
4693 list_for_each_entry(work, &pwq->delayed_works, entry) {
4694 pr_cont_work(comma, work);
4695 comma = !(*work_data_bits(work) & WORK_STRUCT_LINKED);
4696 }
4697 pr_cont("\n");
4698 }
4699}
4700
4701/**
4702 * show_workqueue_state - dump workqueue state
4703 *
4704 * Called from a sysrq handler or try_to_freeze_tasks() and prints out
4705 * all busy workqueues and pools.
4706 */
4707void show_workqueue_state(void)
4708{
4709 struct workqueue_struct *wq;
4710 struct worker_pool *pool;
4711 unsigned long flags;
4712 int pi;
4713
4714 rcu_read_lock();
4715
4716 pr_info("Showing busy workqueues and worker pools:\n");
4717
4718 list_for_each_entry_rcu(wq, &workqueues, list) {
4719 struct pool_workqueue *pwq;
4720 bool idle = true;
4721
4722 for_each_pwq(pwq, wq) {
4723 if (pwq->nr_active || !list_empty(&pwq->delayed_works)) {
4724 idle = false;
4725 break;
4726 }
4727 }
4728 if (idle)
4729 continue;
4730
4731 pr_info("workqueue %s: flags=0x%x\n", wq->name, wq->flags);
4732
4733 for_each_pwq(pwq, wq) {
4734 spin_lock_irqsave(&pwq->pool->lock, flags);
4735 if (pwq->nr_active || !list_empty(&pwq->delayed_works))
4736 show_pwq(pwq);
4737 spin_unlock_irqrestore(&pwq->pool->lock, flags);
4738 /*
4739 * We could be printing a lot from atomic context, e.g.
4740 * sysrq-t -> show_workqueue_state(). Avoid triggering
4741 * hard lockup.
4742 */
4743 touch_nmi_watchdog();
4744 }
4745 }
4746
4747 for_each_pool(pool, pi) {
4748 struct worker *worker;
4749 bool first = true;
4750
4751 spin_lock_irqsave(&pool->lock, flags);
4752 if (pool->nr_workers == pool->nr_idle)
4753 goto next_pool;
4754
4755 pr_info("pool %d:", pool->id);
4756 pr_cont_pool_info(pool);
4757 pr_cont(" hung=%us workers=%d",
4758 jiffies_to_msecs(jiffies - pool->watchdog_ts) / 1000,
4759 pool->nr_workers);
4760 if (pool->manager)
4761 pr_cont(" manager: %d",
4762 task_pid_nr(pool->manager->task));
4763 list_for_each_entry(worker, &pool->idle_list, entry) {
4764 pr_cont(" %s%d", first ? "idle: " : "",
4765 task_pid_nr(worker->task));
4766 first = false;
4767 }
4768 pr_cont("\n");
4769 next_pool:
4770 spin_unlock_irqrestore(&pool->lock, flags);
4771 /*
4772 * We could be printing a lot from atomic context, e.g.
4773 * sysrq-t -> show_workqueue_state(). Avoid triggering
4774 * hard lockup.
4775 */
4776 touch_nmi_watchdog();
4777 }
4778
4779 rcu_read_unlock();
4780}
4781
4782/* used to show worker information through /proc/PID/{comm,stat,status} */
4783void wq_worker_comm(char *buf, size_t size, struct task_struct *task)
4784{
4785 int off;
4786
4787 /* always show the actual comm */
4788 off = strscpy(buf, task->comm, size);
4789 if (off < 0)
4790 return;
4791
4792 /* stabilize PF_WQ_WORKER and worker pool association */
4793 mutex_lock(&wq_pool_attach_mutex);
4794
4795 if (task->flags & PF_WQ_WORKER) {
4796 struct worker *worker = kthread_data(task);
4797 struct worker_pool *pool = worker->pool;
4798
4799 if (pool) {
4800 spin_lock_irq(&pool->lock);
4801 /*
4802 * ->desc tracks information (wq name or
4803 * set_worker_desc()) for the latest execution. If
4804 * current, prepend '+', otherwise '-'.
4805 */
4806 if (worker->desc[0] != '\0') {
4807 if (worker->current_work)
4808 scnprintf(buf + off, size - off, "+%s",
4809 worker->desc);
4810 else
4811 scnprintf(buf + off, size - off, "-%s",
4812 worker->desc);
4813 }
4814 spin_unlock_irq(&pool->lock);
4815 }
4816 }
4817
4818 mutex_unlock(&wq_pool_attach_mutex);
4819}
4820
4821#ifdef CONFIG_SMP
4822
4823/*
4824 * CPU hotplug.
4825 *
4826 * There are two challenges in supporting CPU hotplug. Firstly, there
4827 * are a lot of assumptions on strong associations among work, pwq and
4828 * pool which make migrating pending and scheduled works very
4829 * difficult to implement without impacting hot paths. Secondly,
4830 * worker pools serve mix of short, long and very long running works making
4831 * blocked draining impractical.
4832 *
4833 * This is solved by allowing the pools to be disassociated from the CPU
4834 * running as an unbound one and allowing it to be reattached later if the
4835 * cpu comes back online.
4836 */
4837
4838static void unbind_workers(int cpu)
4839{
4840 struct worker_pool *pool;
4841 struct worker *worker;
4842
4843 for_each_cpu_worker_pool(pool, cpu) {
4844 mutex_lock(&wq_pool_attach_mutex);
4845 spin_lock_irq(&pool->lock);
4846
4847 /*
4848 * We've blocked all attach/detach operations. Make all workers
4849 * unbound and set DISASSOCIATED. Before this, all workers
4850 * except for the ones which are still executing works from
4851 * before the last CPU down must be on the cpu. After
4852 * this, they may become diasporas.
4853 */
4854 for_each_pool_worker(worker, pool)
4855 worker->flags |= WORKER_UNBOUND;
4856
4857 pool->flags |= POOL_DISASSOCIATED;
4858
4859 spin_unlock_irq(&pool->lock);
4860 mutex_unlock(&wq_pool_attach_mutex);
4861
4862 /*
4863 * Call schedule() so that we cross rq->lock and thus can
4864 * guarantee sched callbacks see the %WORKER_UNBOUND flag.
4865 * This is necessary as scheduler callbacks may be invoked
4866 * from other cpus.
4867 */
4868 schedule();
4869
4870 /*
4871 * Sched callbacks are disabled now. Zap nr_running.
4872 * After this, nr_running stays zero and need_more_worker()
4873 * and keep_working() are always true as long as the
4874 * worklist is not empty. This pool now behaves as an
4875 * unbound (in terms of concurrency management) pool which
4876 * are served by workers tied to the pool.
4877 */
4878 atomic_set(&pool->nr_running, 0);
4879
4880 /*
4881 * With concurrency management just turned off, a busy
4882 * worker blocking could lead to lengthy stalls. Kick off
4883 * unbound chain execution of currently pending work items.
4884 */
4885 spin_lock_irq(&pool->lock);
4886 wake_up_worker(pool);
4887 spin_unlock_irq(&pool->lock);
4888 }
4889}
4890
4891/**
4892 * rebind_workers - rebind all workers of a pool to the associated CPU
4893 * @pool: pool of interest
4894 *
4895 * @pool->cpu is coming online. Rebind all workers to the CPU.
4896 */
4897static void rebind_workers(struct worker_pool *pool)
4898{
4899 struct worker *worker;
4900
4901 lockdep_assert_held(&wq_pool_attach_mutex);
4902
4903 /*
4904 * Restore CPU affinity of all workers. As all idle workers should
4905 * be on the run-queue of the associated CPU before any local
4906 * wake-ups for concurrency management happen, restore CPU affinity
4907 * of all workers first and then clear UNBOUND. As we're called
4908 * from CPU_ONLINE, the following shouldn't fail.
4909 */
4910 for_each_pool_worker(worker, pool)
4911 WARN_ON_ONCE(set_cpus_allowed_ptr(worker->task,
4912 pool->attrs->cpumask) < 0);
4913
4914 spin_lock_irq(&pool->lock);
4915
4916 pool->flags &= ~POOL_DISASSOCIATED;
4917
4918 for_each_pool_worker(worker, pool) {
4919 unsigned int worker_flags = worker->flags;
4920
4921 /*
4922 * A bound idle worker should actually be on the runqueue
4923 * of the associated CPU for local wake-ups targeting it to
4924 * work. Kick all idle workers so that they migrate to the
4925 * associated CPU. Doing this in the same loop as
4926 * replacing UNBOUND with REBOUND is safe as no worker will
4927 * be bound before @pool->lock is released.
4928 */
4929 if (worker_flags & WORKER_IDLE)
4930 wake_up_process(worker->task);
4931
4932 /*
4933 * We want to clear UNBOUND but can't directly call
4934 * worker_clr_flags() or adjust nr_running. Atomically
4935 * replace UNBOUND with another NOT_RUNNING flag REBOUND.
4936 * @worker will clear REBOUND using worker_clr_flags() when
4937 * it initiates the next execution cycle thus restoring
4938 * concurrency management. Note that when or whether
4939 * @worker clears REBOUND doesn't affect correctness.
4940 *
4941 * WRITE_ONCE() is necessary because @worker->flags may be
4942 * tested without holding any lock in
4943 * wq_worker_running(). Without it, NOT_RUNNING test may
4944 * fail incorrectly leading to premature concurrency
4945 * management operations.
4946 */
4947 WARN_ON_ONCE(!(worker_flags & WORKER_UNBOUND));
4948 worker_flags |= WORKER_REBOUND;
4949 worker_flags &= ~WORKER_UNBOUND;
4950 WRITE_ONCE(worker->flags, worker_flags);
4951 }
4952
4953 spin_unlock_irq(&pool->lock);
4954}
4955
4956/**
4957 * restore_unbound_workers_cpumask - restore cpumask of unbound workers
4958 * @pool: unbound pool of interest
4959 * @cpu: the CPU which is coming up
4960 *
4961 * An unbound pool may end up with a cpumask which doesn't have any online
4962 * CPUs. When a worker of such pool get scheduled, the scheduler resets
4963 * its cpus_allowed. If @cpu is in @pool's cpumask which didn't have any
4964 * online CPU before, cpus_allowed of all its workers should be restored.
4965 */
4966static void restore_unbound_workers_cpumask(struct worker_pool *pool, int cpu)
4967{
4968 static cpumask_t cpumask;
4969 struct worker *worker;
4970
4971 lockdep_assert_held(&wq_pool_attach_mutex);
4972
4973 /* is @cpu allowed for @pool? */
4974 if (!cpumask_test_cpu(cpu, pool->attrs->cpumask))
4975 return;
4976
4977 cpumask_and(&cpumask, pool->attrs->cpumask, cpu_online_mask);
4978
4979 /* as we're called from CPU_ONLINE, the following shouldn't fail */
4980 for_each_pool_worker(worker, pool)
4981 WARN_ON_ONCE(set_cpus_allowed_ptr(worker->task, &cpumask) < 0);
4982}
4983
4984int workqueue_prepare_cpu(unsigned int cpu)
4985{
4986 struct worker_pool *pool;
4987
4988 for_each_cpu_worker_pool(pool, cpu) {
4989 if (pool->nr_workers)
4990 continue;
4991 if (!create_worker(pool))
4992 return -ENOMEM;
4993 }
4994 return 0;
4995}
4996
4997int workqueue_online_cpu(unsigned int cpu)
4998{
4999 struct worker_pool *pool;
5000 struct workqueue_struct *wq;
5001 int pi;
5002
5003 mutex_lock(&wq_pool_mutex);
5004
5005 for_each_pool(pool, pi) {
5006 mutex_lock(&wq_pool_attach_mutex);
5007
5008 if (pool->cpu == cpu)
5009 rebind_workers(pool);
5010 else if (pool->cpu < 0)
5011 restore_unbound_workers_cpumask(pool, cpu);
5012
5013 mutex_unlock(&wq_pool_attach_mutex);
5014 }
5015
5016 /* update NUMA affinity of unbound workqueues */
5017 list_for_each_entry(wq, &workqueues, list)
5018 wq_update_unbound_numa(wq, cpu, true);
5019
5020 mutex_unlock(&wq_pool_mutex);
5021 return 0;
5022}
5023
5024int workqueue_offline_cpu(unsigned int cpu)
5025{
5026 struct workqueue_struct *wq;
5027
5028 /* unbinding per-cpu workers should happen on the local CPU */
5029 if (WARN_ON(cpu != smp_processor_id()))
5030 return -1;
5031
5032 unbind_workers(cpu);
5033
5034 /* update NUMA affinity of unbound workqueues */
5035 mutex_lock(&wq_pool_mutex);
5036 list_for_each_entry(wq, &workqueues, list)
5037 wq_update_unbound_numa(wq, cpu, false);
5038 mutex_unlock(&wq_pool_mutex);
5039
5040 return 0;
5041}
5042
5043struct work_for_cpu {
5044 struct work_struct work;
5045 long (*fn)(void *);
5046 void *arg;
5047 long ret;
5048};
5049
5050static void work_for_cpu_fn(struct work_struct *work)
5051{
5052 struct work_for_cpu *wfc = container_of(work, struct work_for_cpu, work);
5053
5054 wfc->ret = wfc->fn(wfc->arg);
5055}
5056
5057/**
5058 * work_on_cpu - run a function in thread context on a particular cpu
5059 * @cpu: the cpu to run on
5060 * @fn: the function to run
5061 * @arg: the function arg
5062 *
5063 * It is up to the caller to ensure that the cpu doesn't go offline.
5064 * The caller must not hold any locks which would prevent @fn from completing.
5065 *
5066 * Return: The value @fn returns.
5067 */
5068long work_on_cpu(int cpu, long (*fn)(void *), void *arg)
5069{
5070 struct work_for_cpu wfc = { .fn = fn, .arg = arg };
5071
5072 INIT_WORK_ONSTACK(&wfc.work, work_for_cpu_fn);
5073 schedule_work_on(cpu, &wfc.work);
5074 flush_work(&wfc.work);
5075 destroy_work_on_stack(&wfc.work);
5076 return wfc.ret;
5077}
5078EXPORT_SYMBOL_GPL(work_on_cpu);
5079
5080/**
5081 * work_on_cpu_safe - run a function in thread context on a particular cpu
5082 * @cpu: the cpu to run on
5083 * @fn: the function to run
5084 * @arg: the function argument
5085 *
5086 * Disables CPU hotplug and calls work_on_cpu(). The caller must not hold
5087 * any locks which would prevent @fn from completing.
5088 *
5089 * Return: The value @fn returns.
5090 */
5091long work_on_cpu_safe(int cpu, long (*fn)(void *), void *arg)
5092{
5093 long ret = -ENODEV;
5094
5095 get_online_cpus();
5096 if (cpu_online(cpu))
5097 ret = work_on_cpu(cpu, fn, arg);
5098 put_online_cpus();
5099 return ret;
5100}
5101EXPORT_SYMBOL_GPL(work_on_cpu_safe);
5102#endif /* CONFIG_SMP */
5103
5104#ifdef CONFIG_FREEZER
5105
5106/**
5107 * freeze_workqueues_begin - begin freezing workqueues
5108 *
5109 * Start freezing workqueues. After this function returns, all freezable
5110 * workqueues will queue new works to their delayed_works list instead of
5111 * pool->worklist.
5112 *
5113 * CONTEXT:
5114 * Grabs and releases wq_pool_mutex, wq->mutex and pool->lock's.
5115 */
5116void freeze_workqueues_begin(void)
5117{
5118 struct workqueue_struct *wq;
5119 struct pool_workqueue *pwq;
5120
5121 mutex_lock(&wq_pool_mutex);
5122
5123 WARN_ON_ONCE(workqueue_freezing);
5124 workqueue_freezing = true;
5125
5126 list_for_each_entry(wq, &workqueues, list) {
5127 mutex_lock(&wq->mutex);
5128 for_each_pwq(pwq, wq)
5129 pwq_adjust_max_active(pwq);
5130 mutex_unlock(&wq->mutex);
5131 }
5132
5133 mutex_unlock(&wq_pool_mutex);
5134}
5135
5136/**
5137 * freeze_workqueues_busy - are freezable workqueues still busy?
5138 *
5139 * Check whether freezing is complete. This function must be called
5140 * between freeze_workqueues_begin() and thaw_workqueues().
5141 *
5142 * CONTEXT:
5143 * Grabs and releases wq_pool_mutex.
5144 *
5145 * Return:
5146 * %true if some freezable workqueues are still busy. %false if freezing
5147 * is complete.
5148 */
5149bool freeze_workqueues_busy(void)
5150{
5151 bool busy = false;
5152 struct workqueue_struct *wq;
5153 struct pool_workqueue *pwq;
5154
5155 mutex_lock(&wq_pool_mutex);
5156
5157 WARN_ON_ONCE(!workqueue_freezing);
5158
5159 list_for_each_entry(wq, &workqueues, list) {
5160 if (!(wq->flags & WQ_FREEZABLE))
5161 continue;
5162 /*
5163 * nr_active is monotonically decreasing. It's safe
5164 * to peek without lock.
5165 */
5166 rcu_read_lock();
5167 for_each_pwq(pwq, wq) {
5168 WARN_ON_ONCE(pwq->nr_active < 0);
5169 if (pwq->nr_active) {
5170 busy = true;
5171 rcu_read_unlock();
5172 goto out_unlock;
5173 }
5174 }
5175 rcu_read_unlock();
5176 }
5177out_unlock:
5178 mutex_unlock(&wq_pool_mutex);
5179 return busy;
5180}
5181
5182/**
5183 * thaw_workqueues - thaw workqueues
5184 *
5185 * Thaw workqueues. Normal queueing is restored and all collected
5186 * frozen works are transferred to their respective pool worklists.
5187 *
5188 * CONTEXT:
5189 * Grabs and releases wq_pool_mutex, wq->mutex and pool->lock's.
5190 */
5191void thaw_workqueues(void)
5192{
5193 struct workqueue_struct *wq;
5194 struct pool_workqueue *pwq;
5195
5196 mutex_lock(&wq_pool_mutex);
5197
5198 if (!workqueue_freezing)
5199 goto out_unlock;
5200
5201 workqueue_freezing = false;
5202
5203 /* restore max_active and repopulate worklist */
5204 list_for_each_entry(wq, &workqueues, list) {
5205 mutex_lock(&wq->mutex);
5206 for_each_pwq(pwq, wq)
5207 pwq_adjust_max_active(pwq);
5208 mutex_unlock(&wq->mutex);
5209 }
5210
5211out_unlock:
5212 mutex_unlock(&wq_pool_mutex);
5213}
5214#endif /* CONFIG_FREEZER */
5215
5216static int workqueue_apply_unbound_cpumask(void)
5217{
5218 LIST_HEAD(ctxs);
5219 int ret = 0;
5220 struct workqueue_struct *wq;
5221 struct apply_wqattrs_ctx *ctx, *n;
5222
5223 lockdep_assert_held(&wq_pool_mutex);
5224
5225 list_for_each_entry(wq, &workqueues, list) {
5226 if (!(wq->flags & WQ_UNBOUND))
5227 continue;
5228 /* creating multiple pwqs breaks ordering guarantee */
5229 if (wq->flags & __WQ_ORDERED)
5230 continue;
5231
5232 ctx = apply_wqattrs_prepare(wq, wq->unbound_attrs);
5233 if (!ctx) {
5234 ret = -ENOMEM;
5235 break;
5236 }
5237
5238 list_add_tail(&ctx->list, &ctxs);
5239 }
5240
5241 list_for_each_entry_safe(ctx, n, &ctxs, list) {
5242 if (!ret)
5243 apply_wqattrs_commit(ctx);
5244 apply_wqattrs_cleanup(ctx);
5245 }
5246
5247 return ret;
5248}
5249
5250/**
5251 * workqueue_set_unbound_cpumask - Set the low-level unbound cpumask
5252 * @cpumask: the cpumask to set
5253 *
5254 * The low-level workqueues cpumask is a global cpumask that limits
5255 * the affinity of all unbound workqueues. This function check the @cpumask
5256 * and apply it to all unbound workqueues and updates all pwqs of them.
5257 *
5258 * Retun: 0 - Success
5259 * -EINVAL - Invalid @cpumask
5260 * -ENOMEM - Failed to allocate memory for attrs or pwqs.
5261 */
5262int workqueue_set_unbound_cpumask(cpumask_var_t cpumask)
5263{
5264 int ret = -EINVAL;
5265 cpumask_var_t saved_cpumask;
5266
5267 if (!zalloc_cpumask_var(&saved_cpumask, GFP_KERNEL))
5268 return -ENOMEM;
5269
5270 /*
5271 * Not excluding isolated cpus on purpose.
5272 * If the user wishes to include them, we allow that.
5273 */
5274 cpumask_and(cpumask, cpumask, cpu_possible_mask);
5275 if (!cpumask_empty(cpumask)) {
5276 apply_wqattrs_lock();
5277
5278 /* save the old wq_unbound_cpumask. */
5279 cpumask_copy(saved_cpumask, wq_unbound_cpumask);
5280
5281 /* update wq_unbound_cpumask at first and apply it to wqs. */
5282 cpumask_copy(wq_unbound_cpumask, cpumask);
5283 ret = workqueue_apply_unbound_cpumask();
5284
5285 /* restore the wq_unbound_cpumask when failed. */
5286 if (ret < 0)
5287 cpumask_copy(wq_unbound_cpumask, saved_cpumask);
5288
5289 apply_wqattrs_unlock();
5290 }
5291
5292 free_cpumask_var(saved_cpumask);
5293 return ret;
5294}
5295
5296#ifdef CONFIG_SYSFS
5297/*
5298 * Workqueues with WQ_SYSFS flag set is visible to userland via
5299 * /sys/bus/workqueue/devices/WQ_NAME. All visible workqueues have the
5300 * following attributes.
5301 *
5302 * per_cpu RO bool : whether the workqueue is per-cpu or unbound
5303 * max_active RW int : maximum number of in-flight work items
5304 *
5305 * Unbound workqueues have the following extra attributes.
5306 *
5307 * pool_ids RO int : the associated pool IDs for each node
5308 * nice RW int : nice value of the workers
5309 * cpumask RW mask : bitmask of allowed CPUs for the workers
5310 * numa RW bool : whether enable NUMA affinity
5311 */
5312struct wq_device {
5313 struct workqueue_struct *wq;
5314 struct device dev;
5315};
5316
5317static struct workqueue_struct *dev_to_wq(struct device *dev)
5318{
5319 struct wq_device *wq_dev = container_of(dev, struct wq_device, dev);
5320
5321 return wq_dev->wq;
5322}
5323
5324static ssize_t per_cpu_show(struct device *dev, struct device_attribute *attr,
5325 char *buf)
5326{
5327 struct workqueue_struct *wq = dev_to_wq(dev);
5328
5329 return scnprintf(buf, PAGE_SIZE, "%d\n", (bool)!(wq->flags & WQ_UNBOUND));
5330}
5331static DEVICE_ATTR_RO(per_cpu);
5332
5333static ssize_t max_active_show(struct device *dev,
5334 struct device_attribute *attr, char *buf)
5335{
5336 struct workqueue_struct *wq = dev_to_wq(dev);
5337
5338 return scnprintf(buf, PAGE_SIZE, "%d\n", wq->saved_max_active);
5339}
5340
5341static ssize_t max_active_store(struct device *dev,
5342 struct device_attribute *attr, const char *buf,
5343 size_t count)
5344{
5345 struct workqueue_struct *wq = dev_to_wq(dev);
5346 int val;
5347
5348 if (sscanf(buf, "%d", &val) != 1 || val <= 0)
5349 return -EINVAL;
5350
5351 workqueue_set_max_active(wq, val);
5352 return count;
5353}
5354static DEVICE_ATTR_RW(max_active);
5355
5356static struct attribute *wq_sysfs_attrs[] = {
5357 &dev_attr_per_cpu.attr,
5358 &dev_attr_max_active.attr,
5359 NULL,
5360};
5361ATTRIBUTE_GROUPS(wq_sysfs);
5362
5363static ssize_t wq_pool_ids_show(struct device *dev,
5364 struct device_attribute *attr, char *buf)
5365{
5366 struct workqueue_struct *wq = dev_to_wq(dev);
5367 const char *delim = "";
5368 int node, written = 0;
5369
5370 get_online_cpus();
5371 rcu_read_lock();
5372 for_each_node(node) {
5373 written += scnprintf(buf + written, PAGE_SIZE - written,
5374 "%s%d:%d", delim, node,
5375 unbound_pwq_by_node(wq, node)->pool->id);
5376 delim = " ";
5377 }
5378 written += scnprintf(buf + written, PAGE_SIZE - written, "\n");
5379 rcu_read_unlock();
5380 put_online_cpus();
5381
5382 return written;
5383}
5384
5385static ssize_t wq_nice_show(struct device *dev, struct device_attribute *attr,
5386 char *buf)
5387{
5388 struct workqueue_struct *wq = dev_to_wq(dev);
5389 int written;
5390
5391 mutex_lock(&wq->mutex);
5392 written = scnprintf(buf, PAGE_SIZE, "%d\n", wq->unbound_attrs->nice);
5393 mutex_unlock(&wq->mutex);
5394
5395 return written;
5396}
5397
5398/* prepare workqueue_attrs for sysfs store operations */
5399static struct workqueue_attrs *wq_sysfs_prep_attrs(struct workqueue_struct *wq)
5400{
5401 struct workqueue_attrs *attrs;
5402
5403 lockdep_assert_held(&wq_pool_mutex);
5404
5405 attrs = alloc_workqueue_attrs();
5406 if (!attrs)
5407 return NULL;
5408
5409 copy_workqueue_attrs(attrs, wq->unbound_attrs);
5410 return attrs;
5411}
5412
5413static ssize_t wq_nice_store(struct device *dev, struct device_attribute *attr,
5414 const char *buf, size_t count)
5415{
5416 struct workqueue_struct *wq = dev_to_wq(dev);
5417 struct workqueue_attrs *attrs;
5418 int ret = -ENOMEM;
5419
5420 apply_wqattrs_lock();
5421
5422 attrs = wq_sysfs_prep_attrs(wq);
5423 if (!attrs)
5424 goto out_unlock;
5425
5426 if (sscanf(buf, "%d", &attrs->nice) == 1 &&
5427 attrs->nice >= MIN_NICE && attrs->nice <= MAX_NICE)
5428 ret = apply_workqueue_attrs_locked(wq, attrs);
5429 else
5430 ret = -EINVAL;
5431
5432out_unlock:
5433 apply_wqattrs_unlock();
5434 free_workqueue_attrs(attrs);
5435 return ret ?: count;
5436}
5437
5438static ssize_t wq_cpumask_show(struct device *dev,
5439 struct device_attribute *attr, char *buf)
5440{
5441 struct workqueue_struct *wq = dev_to_wq(dev);
5442 int written;
5443
5444 mutex_lock(&wq->mutex);
5445 written = scnprintf(buf, PAGE_SIZE, "%*pb\n",
5446 cpumask_pr_args(wq->unbound_attrs->cpumask));
5447 mutex_unlock(&wq->mutex);
5448 return written;
5449}
5450
5451static ssize_t wq_cpumask_store(struct device *dev,
5452 struct device_attribute *attr,
5453 const char *buf, size_t count)
5454{
5455 struct workqueue_struct *wq = dev_to_wq(dev);
5456 struct workqueue_attrs *attrs;
5457 int ret = -ENOMEM;
5458
5459 apply_wqattrs_lock();
5460
5461 attrs = wq_sysfs_prep_attrs(wq);
5462 if (!attrs)
5463 goto out_unlock;
5464
5465 ret = cpumask_parse(buf, attrs->cpumask);
5466 if (!ret)
5467 ret = apply_workqueue_attrs_locked(wq, attrs);
5468
5469out_unlock:
5470 apply_wqattrs_unlock();
5471 free_workqueue_attrs(attrs);
5472 return ret ?: count;
5473}
5474
5475static ssize_t wq_numa_show(struct device *dev, struct device_attribute *attr,
5476 char *buf)
5477{
5478 struct workqueue_struct *wq = dev_to_wq(dev);
5479 int written;
5480
5481 mutex_lock(&wq->mutex);
5482 written = scnprintf(buf, PAGE_SIZE, "%d\n",
5483 !wq->unbound_attrs->no_numa);
5484 mutex_unlock(&wq->mutex);
5485
5486 return written;
5487}
5488
5489static ssize_t wq_numa_store(struct device *dev, struct device_attribute *attr,
5490 const char *buf, size_t count)
5491{
5492 struct workqueue_struct *wq = dev_to_wq(dev);
5493 struct workqueue_attrs *attrs;
5494 int v, ret = -ENOMEM;
5495
5496 apply_wqattrs_lock();
5497
5498 attrs = wq_sysfs_prep_attrs(wq);
5499 if (!attrs)
5500 goto out_unlock;
5501
5502 ret = -EINVAL;
5503 if (sscanf(buf, "%d", &v) == 1) {
5504 attrs->no_numa = !v;
5505 ret = apply_workqueue_attrs_locked(wq, attrs);
5506 }
5507
5508out_unlock:
5509 apply_wqattrs_unlock();
5510 free_workqueue_attrs(attrs);
5511 return ret ?: count;
5512}
5513
5514static struct device_attribute wq_sysfs_unbound_attrs[] = {
5515 __ATTR(pool_ids, 0444, wq_pool_ids_show, NULL),
5516 __ATTR(nice, 0644, wq_nice_show, wq_nice_store),
5517 __ATTR(cpumask, 0644, wq_cpumask_show, wq_cpumask_store),
5518 __ATTR(numa, 0644, wq_numa_show, wq_numa_store),
5519 __ATTR_NULL,
5520};
5521
5522static struct bus_type wq_subsys = {
5523 .name = "workqueue",
5524 .dev_groups = wq_sysfs_groups,
5525};
5526
5527static ssize_t wq_unbound_cpumask_show(struct device *dev,
5528 struct device_attribute *attr, char *buf)
5529{
5530 int written;
5531
5532 mutex_lock(&wq_pool_mutex);
5533 written = scnprintf(buf, PAGE_SIZE, "%*pb\n",
5534 cpumask_pr_args(wq_unbound_cpumask));
5535 mutex_unlock(&wq_pool_mutex);
5536
5537 return written;
5538}
5539
5540static ssize_t wq_unbound_cpumask_store(struct device *dev,
5541 struct device_attribute *attr, const char *buf, size_t count)
5542{
5543 cpumask_var_t cpumask;
5544 int ret;
5545
5546 if (!zalloc_cpumask_var(&cpumask, GFP_KERNEL))
5547 return -ENOMEM;
5548
5549 ret = cpumask_parse(buf, cpumask);
5550 if (!ret)
5551 ret = workqueue_set_unbound_cpumask(cpumask);
5552
5553 free_cpumask_var(cpumask);
5554 return ret ? ret : count;
5555}
5556
5557static struct device_attribute wq_sysfs_cpumask_attr =
5558 __ATTR(cpumask, 0644, wq_unbound_cpumask_show,
5559 wq_unbound_cpumask_store);
5560
5561static int __init wq_sysfs_init(void)
5562{
5563 int err;
5564
5565 err = subsys_virtual_register(&wq_subsys, NULL);
5566 if (err)
5567 return err;
5568
5569 return device_create_file(wq_subsys.dev_root, &wq_sysfs_cpumask_attr);
5570}
5571core_initcall(wq_sysfs_init);
5572
5573static void wq_device_release(struct device *dev)
5574{
5575 struct wq_device *wq_dev = container_of(dev, struct wq_device, dev);
5576
5577 kfree(wq_dev);
5578}
5579
5580/**
5581 * workqueue_sysfs_register - make a workqueue visible in sysfs
5582 * @wq: the workqueue to register
5583 *
5584 * Expose @wq in sysfs under /sys/bus/workqueue/devices.
5585 * alloc_workqueue*() automatically calls this function if WQ_SYSFS is set
5586 * which is the preferred method.
5587 *
5588 * Workqueue user should use this function directly iff it wants to apply
5589 * workqueue_attrs before making the workqueue visible in sysfs; otherwise,
5590 * apply_workqueue_attrs() may race against userland updating the
5591 * attributes.
5592 *
5593 * Return: 0 on success, -errno on failure.
5594 */
5595int workqueue_sysfs_register(struct workqueue_struct *wq)
5596{
5597 struct wq_device *wq_dev;
5598 int ret;
5599
5600 /*
5601 * Adjusting max_active or creating new pwqs by applying
5602 * attributes breaks ordering guarantee. Disallow exposing ordered
5603 * workqueues.
5604 */
5605 if (WARN_ON(wq->flags & __WQ_ORDERED_EXPLICIT))
5606 return -EINVAL;
5607
5608 wq->wq_dev = wq_dev = kzalloc(sizeof(*wq_dev), GFP_KERNEL);
5609 if (!wq_dev)
5610 return -ENOMEM;
5611
5612 wq_dev->wq = wq;
5613 wq_dev->dev.bus = &wq_subsys;
5614 wq_dev->dev.release = wq_device_release;
5615 dev_set_name(&wq_dev->dev, "%s", wq->name);
5616
5617 /*
5618 * unbound_attrs are created separately. Suppress uevent until
5619 * everything is ready.
5620 */
5621 dev_set_uevent_suppress(&wq_dev->dev, true);
5622
5623 ret = device_register(&wq_dev->dev);
5624 if (ret) {
5625 put_device(&wq_dev->dev);
5626 wq->wq_dev = NULL;
5627 return ret;
5628 }
5629
5630 if (wq->flags & WQ_UNBOUND) {
5631 struct device_attribute *attr;
5632
5633 for (attr = wq_sysfs_unbound_attrs; attr->attr.name; attr++) {
5634 ret = device_create_file(&wq_dev->dev, attr);
5635 if (ret) {
5636 device_unregister(&wq_dev->dev);
5637 wq->wq_dev = NULL;
5638 return ret;
5639 }
5640 }
5641 }
5642
5643 dev_set_uevent_suppress(&wq_dev->dev, false);
5644 kobject_uevent(&wq_dev->dev.kobj, KOBJ_ADD);
5645 return 0;
5646}
5647
5648/**
5649 * workqueue_sysfs_unregister - undo workqueue_sysfs_register()
5650 * @wq: the workqueue to unregister
5651 *
5652 * If @wq is registered to sysfs by workqueue_sysfs_register(), unregister.
5653 */
5654static void workqueue_sysfs_unregister(struct workqueue_struct *wq)
5655{
5656 struct wq_device *wq_dev = wq->wq_dev;
5657
5658 if (!wq->wq_dev)
5659 return;
5660
5661 wq->wq_dev = NULL;
5662 device_unregister(&wq_dev->dev);
5663}
5664#else /* CONFIG_SYSFS */
5665static void workqueue_sysfs_unregister(struct workqueue_struct *wq) { }
5666#endif /* CONFIG_SYSFS */
5667
5668/*
5669 * Workqueue watchdog.
5670 *
5671 * Stall may be caused by various bugs - missing WQ_MEM_RECLAIM, illegal
5672 * flush dependency, a concurrency managed work item which stays RUNNING
5673 * indefinitely. Workqueue stalls can be very difficult to debug as the
5674 * usual warning mechanisms don't trigger and internal workqueue state is
5675 * largely opaque.
5676 *
5677 * Workqueue watchdog monitors all worker pools periodically and dumps
5678 * state if some pools failed to make forward progress for a while where
5679 * forward progress is defined as the first item on ->worklist changing.
5680 *
5681 * This mechanism is controlled through the kernel parameter
5682 * "workqueue.watchdog_thresh" which can be updated at runtime through the
5683 * corresponding sysfs parameter file.
5684 */
5685#ifdef CONFIG_WQ_WATCHDOG
5686
5687static unsigned long wq_watchdog_thresh = 30;
5688static struct timer_list wq_watchdog_timer;
5689
5690static unsigned long wq_watchdog_touched = INITIAL_JIFFIES;
5691static DEFINE_PER_CPU(unsigned long, wq_watchdog_touched_cpu) = INITIAL_JIFFIES;
5692
5693static void wq_watchdog_reset_touched(void)
5694{
5695 int cpu;
5696
5697 wq_watchdog_touched = jiffies;
5698 for_each_possible_cpu(cpu)
5699 per_cpu(wq_watchdog_touched_cpu, cpu) = jiffies;
5700}
5701
5702static void wq_watchdog_timer_fn(struct timer_list *unused)
5703{
5704 unsigned long thresh = READ_ONCE(wq_watchdog_thresh) * HZ;
5705 bool lockup_detected = false;
5706 struct worker_pool *pool;
5707 int pi;
5708
5709 if (!thresh)
5710 return;
5711
5712 rcu_read_lock();
5713
5714 for_each_pool(pool, pi) {
5715 unsigned long pool_ts, touched, ts;
5716
5717 if (list_empty(&pool->worklist))
5718 continue;
5719
5720 /* get the latest of pool and touched timestamps */
5721 pool_ts = READ_ONCE(pool->watchdog_ts);
5722 touched = READ_ONCE(wq_watchdog_touched);
5723
5724 if (time_after(pool_ts, touched))
5725 ts = pool_ts;
5726 else
5727 ts = touched;
5728
5729 if (pool->cpu >= 0) {
5730 unsigned long cpu_touched =
5731 READ_ONCE(per_cpu(wq_watchdog_touched_cpu,
5732 pool->cpu));
5733 if (time_after(cpu_touched, ts))
5734 ts = cpu_touched;
5735 }
5736
5737 /* did we stall? */
5738 if (time_after(jiffies, ts + thresh)) {
5739 lockup_detected = true;
5740 pr_emerg("BUG: workqueue lockup - pool");
5741 pr_cont_pool_info(pool);
5742 pr_cont(" stuck for %us!\n",
5743 jiffies_to_msecs(jiffies - pool_ts) / 1000);
5744 }
5745 }
5746
5747 rcu_read_unlock();
5748
5749 if (lockup_detected)
5750 show_workqueue_state();
5751
5752 wq_watchdog_reset_touched();
5753 mod_timer(&wq_watchdog_timer, jiffies + thresh);
5754}
5755
5756notrace void wq_watchdog_touch(int cpu)
5757{
5758 if (cpu >= 0)
5759 per_cpu(wq_watchdog_touched_cpu, cpu) = jiffies;
5760 else
5761 wq_watchdog_touched = jiffies;
5762}
5763
5764static void wq_watchdog_set_thresh(unsigned long thresh)
5765{
5766 wq_watchdog_thresh = 0;
5767 del_timer_sync(&wq_watchdog_timer);
5768
5769 if (thresh) {
5770 wq_watchdog_thresh = thresh;
5771 wq_watchdog_reset_touched();
5772 mod_timer(&wq_watchdog_timer, jiffies + thresh * HZ);
5773 }
5774}
5775
5776static int wq_watchdog_param_set_thresh(const char *val,
5777 const struct kernel_param *kp)
5778{
5779 unsigned long thresh;
5780 int ret;
5781
5782 ret = kstrtoul(val, 0, &thresh);
5783 if (ret)
5784 return ret;
5785
5786 if (system_wq)
5787 wq_watchdog_set_thresh(thresh);
5788 else
5789 wq_watchdog_thresh = thresh;
5790
5791 return 0;
5792}
5793
5794static const struct kernel_param_ops wq_watchdog_thresh_ops = {
5795 .set = wq_watchdog_param_set_thresh,
5796 .get = param_get_ulong,
5797};
5798
5799module_param_cb(watchdog_thresh, &wq_watchdog_thresh_ops, &wq_watchdog_thresh,
5800 0644);
5801
5802static void wq_watchdog_init(void)
5803{
5804 timer_setup(&wq_watchdog_timer, wq_watchdog_timer_fn, TIMER_DEFERRABLE);
5805 wq_watchdog_set_thresh(wq_watchdog_thresh);
5806}
5807
5808#else /* CONFIG_WQ_WATCHDOG */
5809
5810static inline void wq_watchdog_init(void) { }
5811
5812#endif /* CONFIG_WQ_WATCHDOG */
5813
5814static void __init wq_numa_init(void)
5815{
5816 cpumask_var_t *tbl;
5817 int node, cpu;
5818
5819 if (num_possible_nodes() <= 1)
5820 return;
5821
5822 if (wq_disable_numa) {
5823 pr_info("workqueue: NUMA affinity support disabled\n");
5824 return;
5825 }
5826
5827 wq_update_unbound_numa_attrs_buf = alloc_workqueue_attrs();
5828 BUG_ON(!wq_update_unbound_numa_attrs_buf);
5829
5830 /*
5831 * We want masks of possible CPUs of each node which isn't readily
5832 * available. Build one from cpu_to_node() which should have been
5833 * fully initialized by now.
5834 */
5835 tbl = kcalloc(nr_node_ids, sizeof(tbl[0]), GFP_KERNEL);
5836 BUG_ON(!tbl);
5837
5838 for_each_node(node)
5839 BUG_ON(!zalloc_cpumask_var_node(&tbl[node], GFP_KERNEL,
5840 node_online(node) ? node : NUMA_NO_NODE));
5841
5842 for_each_possible_cpu(cpu) {
5843 node = cpu_to_node(cpu);
5844 if (WARN_ON(node == NUMA_NO_NODE)) {
5845 pr_warn("workqueue: NUMA node mapping not available for cpu%d, disabling NUMA support\n", cpu);
5846 /* happens iff arch is bonkers, let's just proceed */
5847 return;
5848 }
5849 cpumask_set_cpu(cpu, tbl[node]);
5850 }
5851
5852 wq_numa_possible_cpumask = tbl;
5853 wq_numa_enabled = true;
5854}
5855
5856/**
5857 * workqueue_init_early - early init for workqueue subsystem
5858 *
5859 * This is the first half of two-staged workqueue subsystem initialization
5860 * and invoked as soon as the bare basics - memory allocation, cpumasks and
5861 * idr are up. It sets up all the data structures and system workqueues
5862 * and allows early boot code to create workqueues and queue/cancel work
5863 * items. Actual work item execution starts only after kthreads can be
5864 * created and scheduled right before early initcalls.
5865 */
5866int __init workqueue_init_early(void)
5867{
5868 int std_nice[NR_STD_WORKER_POOLS] = { 0, HIGHPRI_NICE_LEVEL };
5869 int hk_flags = HK_FLAG_DOMAIN | HK_FLAG_WQ;
5870 int i, cpu;
5871
5872 WARN_ON(__alignof__(struct pool_workqueue) < __alignof__(long long));
5873
5874 BUG_ON(!alloc_cpumask_var(&wq_unbound_cpumask, GFP_KERNEL));
5875 cpumask_copy(wq_unbound_cpumask, housekeeping_cpumask(hk_flags));
5876
5877 pwq_cache = KMEM_CACHE(pool_workqueue, SLAB_PANIC);
5878
5879 /* initialize CPU pools */
5880 for_each_possible_cpu(cpu) {
5881 struct worker_pool *pool;
5882
5883 i = 0;
5884 for_each_cpu_worker_pool(pool, cpu) {
5885 BUG_ON(init_worker_pool(pool));
5886 pool->cpu = cpu;
5887 cpumask_copy(pool->attrs->cpumask, cpumask_of(cpu));
5888 pool->attrs->nice = std_nice[i++];
5889 pool->node = cpu_to_node(cpu);
5890
5891 /* alloc pool ID */
5892 mutex_lock(&wq_pool_mutex);
5893 BUG_ON(worker_pool_assign_id(pool));
5894 mutex_unlock(&wq_pool_mutex);
5895 }
5896 }
5897
5898 /* create default unbound and ordered wq attrs */
5899 for (i = 0; i < NR_STD_WORKER_POOLS; i++) {
5900 struct workqueue_attrs *attrs;
5901
5902 BUG_ON(!(attrs = alloc_workqueue_attrs()));
5903 attrs->nice = std_nice[i];
5904 unbound_std_wq_attrs[i] = attrs;
5905
5906 /*
5907 * An ordered wq should have only one pwq as ordering is
5908 * guaranteed by max_active which is enforced by pwqs.
5909 * Turn off NUMA so that dfl_pwq is used for all nodes.
5910 */
5911 BUG_ON(!(attrs = alloc_workqueue_attrs()));
5912 attrs->nice = std_nice[i];
5913 attrs->no_numa = true;
5914 ordered_wq_attrs[i] = attrs;
5915 }
5916
5917 system_wq = alloc_workqueue("events", 0, 0);
5918 system_highpri_wq = alloc_workqueue("events_highpri", WQ_HIGHPRI, 0);
5919 system_long_wq = alloc_workqueue("events_long", 0, 0);
5920 system_unbound_wq = alloc_workqueue("events_unbound", WQ_UNBOUND,
5921 WQ_UNBOUND_MAX_ACTIVE);
5922 system_freezable_wq = alloc_workqueue("events_freezable",
5923 WQ_FREEZABLE, 0);
5924 system_power_efficient_wq = alloc_workqueue("events_power_efficient",
5925 WQ_POWER_EFFICIENT, 0);
5926 system_freezable_power_efficient_wq = alloc_workqueue("events_freezable_power_efficient",
5927 WQ_FREEZABLE | WQ_POWER_EFFICIENT,
5928 0);
5929 BUG_ON(!system_wq || !system_highpri_wq || !system_long_wq ||
5930 !system_unbound_wq || !system_freezable_wq ||
5931 !system_power_efficient_wq ||
5932 !system_freezable_power_efficient_wq);
5933
5934 return 0;
5935}
5936
5937/**
5938 * workqueue_init - bring workqueue subsystem fully online
5939 *
5940 * This is the latter half of two-staged workqueue subsystem initialization
5941 * and invoked as soon as kthreads can be created and scheduled.
5942 * Workqueues have been created and work items queued on them, but there
5943 * are no kworkers executing the work items yet. Populate the worker pools
5944 * with the initial workers and enable future kworker creations.
5945 */
5946int __init workqueue_init(void)
5947{
5948 struct workqueue_struct *wq;
5949 struct worker_pool *pool;
5950 int cpu, bkt;
5951
5952 /*
5953 * It'd be simpler to initialize NUMA in workqueue_init_early() but
5954 * CPU to node mapping may not be available that early on some
5955 * archs such as power and arm64. As per-cpu pools created
5956 * previously could be missing node hint and unbound pools NUMA
5957 * affinity, fix them up.
5958 *
5959 * Also, while iterating workqueues, create rescuers if requested.
5960 */
5961 wq_numa_init();
5962
5963 mutex_lock(&wq_pool_mutex);
5964
5965 for_each_possible_cpu(cpu) {
5966 for_each_cpu_worker_pool(pool, cpu) {
5967 pool->node = cpu_to_node(cpu);
5968 }
5969 }
5970
5971 list_for_each_entry(wq, &workqueues, list) {
5972 wq_update_unbound_numa(wq, smp_processor_id(), true);
5973 WARN(init_rescuer(wq),
5974 "workqueue: failed to create early rescuer for %s",
5975 wq->name);
5976 }
5977
5978 mutex_unlock(&wq_pool_mutex);
5979
5980 /* create the initial workers */
5981 for_each_online_cpu(cpu) {
5982 for_each_cpu_worker_pool(pool, cpu) {
5983 pool->flags &= ~POOL_DISASSOCIATED;
5984 BUG_ON(!create_worker(pool));
5985 }
5986 }
5987
5988 hash_for_each(unbound_pool_hash, bkt, pool, hash_node)
5989 BUG_ON(!create_worker(pool));
5990
5991 wq_online = true;
5992 wq_watchdog_init();
5993
5994 return 0;
5995}
1// SPDX-License-Identifier: GPL-2.0-only
2/*
3 * kernel/workqueue.c - generic async execution with shared worker pool
4 *
5 * Copyright (C) 2002 Ingo Molnar
6 *
7 * Derived from the taskqueue/keventd code by:
8 * David Woodhouse <dwmw2@infradead.org>
9 * Andrew Morton
10 * Kai Petzke <wpp@marie.physik.tu-berlin.de>
11 * Theodore Ts'o <tytso@mit.edu>
12 *
13 * Made to use alloc_percpu by Christoph Lameter.
14 *
15 * Copyright (C) 2010 SUSE Linux Products GmbH
16 * Copyright (C) 2010 Tejun Heo <tj@kernel.org>
17 *
18 * This is the generic async execution mechanism. Work items as are
19 * executed in process context. The worker pool is shared and
20 * automatically managed. There are two worker pools for each CPU (one for
21 * normal work items and the other for high priority ones) and some extra
22 * pools for workqueues which are not bound to any specific CPU - the
23 * number of these backing pools is dynamic.
24 *
25 * Please read Documentation/core-api/workqueue.rst for details.
26 */
27
28#include <linux/export.h>
29#include <linux/kernel.h>
30#include <linux/sched.h>
31#include <linux/init.h>
32#include <linux/interrupt.h>
33#include <linux/signal.h>
34#include <linux/completion.h>
35#include <linux/workqueue.h>
36#include <linux/slab.h>
37#include <linux/cpu.h>
38#include <linux/notifier.h>
39#include <linux/kthread.h>
40#include <linux/hardirq.h>
41#include <linux/mempolicy.h>
42#include <linux/freezer.h>
43#include <linux/debug_locks.h>
44#include <linux/lockdep.h>
45#include <linux/idr.h>
46#include <linux/jhash.h>
47#include <linux/hashtable.h>
48#include <linux/rculist.h>
49#include <linux/nodemask.h>
50#include <linux/moduleparam.h>
51#include <linux/uaccess.h>
52#include <linux/sched/isolation.h>
53#include <linux/sched/debug.h>
54#include <linux/nmi.h>
55#include <linux/kvm_para.h>
56#include <linux/delay.h>
57#include <linux/irq_work.h>
58
59#include "workqueue_internal.h"
60
61enum worker_pool_flags {
62 /*
63 * worker_pool flags
64 *
65 * A bound pool is either associated or disassociated with its CPU.
66 * While associated (!DISASSOCIATED), all workers are bound to the
67 * CPU and none has %WORKER_UNBOUND set and concurrency management
68 * is in effect.
69 *
70 * While DISASSOCIATED, the cpu may be offline and all workers have
71 * %WORKER_UNBOUND set and concurrency management disabled, and may
72 * be executing on any CPU. The pool behaves as an unbound one.
73 *
74 * Note that DISASSOCIATED should be flipped only while holding
75 * wq_pool_attach_mutex to avoid changing binding state while
76 * worker_attach_to_pool() is in progress.
77 *
78 * As there can only be one concurrent BH execution context per CPU, a
79 * BH pool is per-CPU and always DISASSOCIATED.
80 */
81 POOL_BH = 1 << 0, /* is a BH pool */
82 POOL_MANAGER_ACTIVE = 1 << 1, /* being managed */
83 POOL_DISASSOCIATED = 1 << 2, /* cpu can't serve workers */
84 POOL_BH_DRAINING = 1 << 3, /* draining after CPU offline */
85};
86
87enum worker_flags {
88 /* worker flags */
89 WORKER_DIE = 1 << 1, /* die die die */
90 WORKER_IDLE = 1 << 2, /* is idle */
91 WORKER_PREP = 1 << 3, /* preparing to run works */
92 WORKER_CPU_INTENSIVE = 1 << 6, /* cpu intensive */
93 WORKER_UNBOUND = 1 << 7, /* worker is unbound */
94 WORKER_REBOUND = 1 << 8, /* worker was rebound */
95
96 WORKER_NOT_RUNNING = WORKER_PREP | WORKER_CPU_INTENSIVE |
97 WORKER_UNBOUND | WORKER_REBOUND,
98};
99
100enum work_cancel_flags {
101 WORK_CANCEL_DELAYED = 1 << 0, /* canceling a delayed_work */
102};
103
104enum wq_internal_consts {
105 NR_STD_WORKER_POOLS = 2, /* # standard pools per cpu */
106
107 UNBOUND_POOL_HASH_ORDER = 6, /* hashed by pool->attrs */
108 BUSY_WORKER_HASH_ORDER = 6, /* 64 pointers */
109
110 MAX_IDLE_WORKERS_RATIO = 4, /* 1/4 of busy can be idle */
111 IDLE_WORKER_TIMEOUT = 300 * HZ, /* keep idle ones for 5 mins */
112
113 MAYDAY_INITIAL_TIMEOUT = HZ / 100 >= 2 ? HZ / 100 : 2,
114 /* call for help after 10ms
115 (min two ticks) */
116 MAYDAY_INTERVAL = HZ / 10, /* and then every 100ms */
117 CREATE_COOLDOWN = HZ, /* time to breath after fail */
118
119 /*
120 * Rescue workers are used only on emergencies and shared by
121 * all cpus. Give MIN_NICE.
122 */
123 RESCUER_NICE_LEVEL = MIN_NICE,
124 HIGHPRI_NICE_LEVEL = MIN_NICE,
125
126 WQ_NAME_LEN = 32,
127};
128
129/*
130 * We don't want to trap softirq for too long. See MAX_SOFTIRQ_TIME and
131 * MAX_SOFTIRQ_RESTART in kernel/softirq.c. These are macros because
132 * msecs_to_jiffies() can't be an initializer.
133 */
134#define BH_WORKER_JIFFIES msecs_to_jiffies(2)
135#define BH_WORKER_RESTARTS 10
136
137/*
138 * Structure fields follow one of the following exclusion rules.
139 *
140 * I: Modifiable by initialization/destruction paths and read-only for
141 * everyone else.
142 *
143 * P: Preemption protected. Disabling preemption is enough and should
144 * only be modified and accessed from the local cpu.
145 *
146 * L: pool->lock protected. Access with pool->lock held.
147 *
148 * LN: pool->lock and wq_node_nr_active->lock protected for writes. Either for
149 * reads.
150 *
151 * K: Only modified by worker while holding pool->lock. Can be safely read by
152 * self, while holding pool->lock or from IRQ context if %current is the
153 * kworker.
154 *
155 * S: Only modified by worker self.
156 *
157 * A: wq_pool_attach_mutex protected.
158 *
159 * PL: wq_pool_mutex protected.
160 *
161 * PR: wq_pool_mutex protected for writes. RCU protected for reads.
162 *
163 * PW: wq_pool_mutex and wq->mutex protected for writes. Either for reads.
164 *
165 * PWR: wq_pool_mutex and wq->mutex protected for writes. Either or
166 * RCU for reads.
167 *
168 * WQ: wq->mutex protected.
169 *
170 * WR: wq->mutex protected for writes. RCU protected for reads.
171 *
172 * WO: wq->mutex protected for writes. Updated with WRITE_ONCE() and can be read
173 * with READ_ONCE() without locking.
174 *
175 * MD: wq_mayday_lock protected.
176 *
177 * WD: Used internally by the watchdog.
178 */
179
180/* struct worker is defined in workqueue_internal.h */
181
182struct worker_pool {
183 raw_spinlock_t lock; /* the pool lock */
184 int cpu; /* I: the associated cpu */
185 int node; /* I: the associated node ID */
186 int id; /* I: pool ID */
187 unsigned int flags; /* L: flags */
188
189 unsigned long watchdog_ts; /* L: watchdog timestamp */
190 bool cpu_stall; /* WD: stalled cpu bound pool */
191
192 /*
193 * The counter is incremented in a process context on the associated CPU
194 * w/ preemption disabled, and decremented or reset in the same context
195 * but w/ pool->lock held. The readers grab pool->lock and are
196 * guaranteed to see if the counter reached zero.
197 */
198 int nr_running;
199
200 struct list_head worklist; /* L: list of pending works */
201
202 int nr_workers; /* L: total number of workers */
203 int nr_idle; /* L: currently idle workers */
204
205 struct list_head idle_list; /* L: list of idle workers */
206 struct timer_list idle_timer; /* L: worker idle timeout */
207 struct work_struct idle_cull_work; /* L: worker idle cleanup */
208
209 struct timer_list mayday_timer; /* L: SOS timer for workers */
210
211 /* a workers is either on busy_hash or idle_list, or the manager */
212 DECLARE_HASHTABLE(busy_hash, BUSY_WORKER_HASH_ORDER);
213 /* L: hash of busy workers */
214
215 struct worker *manager; /* L: purely informational */
216 struct list_head workers; /* A: attached workers */
217 struct list_head dying_workers; /* A: workers about to die */
218 struct completion *detach_completion; /* all workers detached */
219
220 struct ida worker_ida; /* worker IDs for task name */
221
222 struct workqueue_attrs *attrs; /* I: worker attributes */
223 struct hlist_node hash_node; /* PL: unbound_pool_hash node */
224 int refcnt; /* PL: refcnt for unbound pools */
225
226 /*
227 * Destruction of pool is RCU protected to allow dereferences
228 * from get_work_pool().
229 */
230 struct rcu_head rcu;
231};
232
233/*
234 * Per-pool_workqueue statistics. These can be monitored using
235 * tools/workqueue/wq_monitor.py.
236 */
237enum pool_workqueue_stats {
238 PWQ_STAT_STARTED, /* work items started execution */
239 PWQ_STAT_COMPLETED, /* work items completed execution */
240 PWQ_STAT_CPU_TIME, /* total CPU time consumed */
241 PWQ_STAT_CPU_INTENSIVE, /* wq_cpu_intensive_thresh_us violations */
242 PWQ_STAT_CM_WAKEUP, /* concurrency-management worker wakeups */
243 PWQ_STAT_REPATRIATED, /* unbound workers brought back into scope */
244 PWQ_STAT_MAYDAY, /* maydays to rescuer */
245 PWQ_STAT_RESCUED, /* linked work items executed by rescuer */
246
247 PWQ_NR_STATS,
248};
249
250/*
251 * The per-pool workqueue. While queued, bits below WORK_PWQ_SHIFT
252 * of work_struct->data are used for flags and the remaining high bits
253 * point to the pwq; thus, pwqs need to be aligned at two's power of the
254 * number of flag bits.
255 */
256struct pool_workqueue {
257 struct worker_pool *pool; /* I: the associated pool */
258 struct workqueue_struct *wq; /* I: the owning workqueue */
259 int work_color; /* L: current color */
260 int flush_color; /* L: flushing color */
261 int refcnt; /* L: reference count */
262 int nr_in_flight[WORK_NR_COLORS];
263 /* L: nr of in_flight works */
264 bool plugged; /* L: execution suspended */
265
266 /*
267 * nr_active management and WORK_STRUCT_INACTIVE:
268 *
269 * When pwq->nr_active >= max_active, new work item is queued to
270 * pwq->inactive_works instead of pool->worklist and marked with
271 * WORK_STRUCT_INACTIVE.
272 *
273 * All work items marked with WORK_STRUCT_INACTIVE do not participate in
274 * nr_active and all work items in pwq->inactive_works are marked with
275 * WORK_STRUCT_INACTIVE. But not all WORK_STRUCT_INACTIVE work items are
276 * in pwq->inactive_works. Some of them are ready to run in
277 * pool->worklist or worker->scheduled. Those work itmes are only struct
278 * wq_barrier which is used for flush_work() and should not participate
279 * in nr_active. For non-barrier work item, it is marked with
280 * WORK_STRUCT_INACTIVE iff it is in pwq->inactive_works.
281 */
282 int nr_active; /* L: nr of active works */
283 struct list_head inactive_works; /* L: inactive works */
284 struct list_head pending_node; /* LN: node on wq_node_nr_active->pending_pwqs */
285 struct list_head pwqs_node; /* WR: node on wq->pwqs */
286 struct list_head mayday_node; /* MD: node on wq->maydays */
287
288 u64 stats[PWQ_NR_STATS];
289
290 /*
291 * Release of unbound pwq is punted to a kthread_worker. See put_pwq()
292 * and pwq_release_workfn() for details. pool_workqueue itself is also
293 * RCU protected so that the first pwq can be determined without
294 * grabbing wq->mutex.
295 */
296 struct kthread_work release_work;
297 struct rcu_head rcu;
298} __aligned(1 << WORK_STRUCT_PWQ_SHIFT);
299
300/*
301 * Structure used to wait for workqueue flush.
302 */
303struct wq_flusher {
304 struct list_head list; /* WQ: list of flushers */
305 int flush_color; /* WQ: flush color waiting for */
306 struct completion done; /* flush completion */
307};
308
309struct wq_device;
310
311/*
312 * Unlike in a per-cpu workqueue where max_active limits its concurrency level
313 * on each CPU, in an unbound workqueue, max_active applies to the whole system.
314 * As sharing a single nr_active across multiple sockets can be very expensive,
315 * the counting and enforcement is per NUMA node.
316 *
317 * The following struct is used to enforce per-node max_active. When a pwq wants
318 * to start executing a work item, it should increment ->nr using
319 * tryinc_node_nr_active(). If acquisition fails due to ->nr already being over
320 * ->max, the pwq is queued on ->pending_pwqs. As in-flight work items finish
321 * and decrement ->nr, node_activate_pending_pwq() activates the pending pwqs in
322 * round-robin order.
323 */
324struct wq_node_nr_active {
325 int max; /* per-node max_active */
326 atomic_t nr; /* per-node nr_active */
327 raw_spinlock_t lock; /* nests inside pool locks */
328 struct list_head pending_pwqs; /* LN: pwqs with inactive works */
329};
330
331/*
332 * The externally visible workqueue. It relays the issued work items to
333 * the appropriate worker_pool through its pool_workqueues.
334 */
335struct workqueue_struct {
336 struct list_head pwqs; /* WR: all pwqs of this wq */
337 struct list_head list; /* PR: list of all workqueues */
338
339 struct mutex mutex; /* protects this wq */
340 int work_color; /* WQ: current work color */
341 int flush_color; /* WQ: current flush color */
342 atomic_t nr_pwqs_to_flush; /* flush in progress */
343 struct wq_flusher *first_flusher; /* WQ: first flusher */
344 struct list_head flusher_queue; /* WQ: flush waiters */
345 struct list_head flusher_overflow; /* WQ: flush overflow list */
346
347 struct list_head maydays; /* MD: pwqs requesting rescue */
348 struct worker *rescuer; /* MD: rescue worker */
349
350 int nr_drainers; /* WQ: drain in progress */
351
352 /* See alloc_workqueue() function comment for info on min/max_active */
353 int max_active; /* WO: max active works */
354 int min_active; /* WO: min active works */
355 int saved_max_active; /* WQ: saved max_active */
356 int saved_min_active; /* WQ: saved min_active */
357
358 struct workqueue_attrs *unbound_attrs; /* PW: only for unbound wqs */
359 struct pool_workqueue __rcu *dfl_pwq; /* PW: only for unbound wqs */
360
361#ifdef CONFIG_SYSFS
362 struct wq_device *wq_dev; /* I: for sysfs interface */
363#endif
364#ifdef CONFIG_LOCKDEP
365 char *lock_name;
366 struct lock_class_key key;
367 struct lockdep_map lockdep_map;
368#endif
369 char name[WQ_NAME_LEN]; /* I: workqueue name */
370
371 /*
372 * Destruction of workqueue_struct is RCU protected to allow walking
373 * the workqueues list without grabbing wq_pool_mutex.
374 * This is used to dump all workqueues from sysrq.
375 */
376 struct rcu_head rcu;
377
378 /* hot fields used during command issue, aligned to cacheline */
379 unsigned int flags ____cacheline_aligned; /* WQ: WQ_* flags */
380 struct pool_workqueue __percpu __rcu **cpu_pwq; /* I: per-cpu pwqs */
381 struct wq_node_nr_active *node_nr_active[]; /* I: per-node nr_active */
382};
383
384/*
385 * Each pod type describes how CPUs should be grouped for unbound workqueues.
386 * See the comment above workqueue_attrs->affn_scope.
387 */
388struct wq_pod_type {
389 int nr_pods; /* number of pods */
390 cpumask_var_t *pod_cpus; /* pod -> cpus */
391 int *pod_node; /* pod -> node */
392 int *cpu_pod; /* cpu -> pod */
393};
394
395static const char *wq_affn_names[WQ_AFFN_NR_TYPES] = {
396 [WQ_AFFN_DFL] = "default",
397 [WQ_AFFN_CPU] = "cpu",
398 [WQ_AFFN_SMT] = "smt",
399 [WQ_AFFN_CACHE] = "cache",
400 [WQ_AFFN_NUMA] = "numa",
401 [WQ_AFFN_SYSTEM] = "system",
402};
403
404/*
405 * Per-cpu work items which run for longer than the following threshold are
406 * automatically considered CPU intensive and excluded from concurrency
407 * management to prevent them from noticeably delaying other per-cpu work items.
408 * ULONG_MAX indicates that the user hasn't overridden it with a boot parameter.
409 * The actual value is initialized in wq_cpu_intensive_thresh_init().
410 */
411static unsigned long wq_cpu_intensive_thresh_us = ULONG_MAX;
412module_param_named(cpu_intensive_thresh_us, wq_cpu_intensive_thresh_us, ulong, 0644);
413#ifdef CONFIG_WQ_CPU_INTENSIVE_REPORT
414static unsigned int wq_cpu_intensive_warning_thresh = 4;
415module_param_named(cpu_intensive_warning_thresh, wq_cpu_intensive_warning_thresh, uint, 0644);
416#endif
417
418/* see the comment above the definition of WQ_POWER_EFFICIENT */
419static bool wq_power_efficient = IS_ENABLED(CONFIG_WQ_POWER_EFFICIENT_DEFAULT);
420module_param_named(power_efficient, wq_power_efficient, bool, 0444);
421
422static bool wq_online; /* can kworkers be created yet? */
423static bool wq_topo_initialized __read_mostly = false;
424
425static struct kmem_cache *pwq_cache;
426
427static struct wq_pod_type wq_pod_types[WQ_AFFN_NR_TYPES];
428static enum wq_affn_scope wq_affn_dfl = WQ_AFFN_CACHE;
429
430/* buf for wq_update_unbound_pod_attrs(), protected by CPU hotplug exclusion */
431static struct workqueue_attrs *wq_update_pod_attrs_buf;
432
433static DEFINE_MUTEX(wq_pool_mutex); /* protects pools and workqueues list */
434static DEFINE_MUTEX(wq_pool_attach_mutex); /* protects worker attach/detach */
435static DEFINE_RAW_SPINLOCK(wq_mayday_lock); /* protects wq->maydays list */
436/* wait for manager to go away */
437static struct rcuwait manager_wait = __RCUWAIT_INITIALIZER(manager_wait);
438
439static LIST_HEAD(workqueues); /* PR: list of all workqueues */
440static bool workqueue_freezing; /* PL: have wqs started freezing? */
441
442/* PL&A: allowable cpus for unbound wqs and work items */
443static cpumask_var_t wq_unbound_cpumask;
444
445/* PL: user requested unbound cpumask via sysfs */
446static cpumask_var_t wq_requested_unbound_cpumask;
447
448/* PL: isolated cpumask to be excluded from unbound cpumask */
449static cpumask_var_t wq_isolated_cpumask;
450
451/* for further constrain wq_unbound_cpumask by cmdline parameter*/
452static struct cpumask wq_cmdline_cpumask __initdata;
453
454/* CPU where unbound work was last round robin scheduled from this CPU */
455static DEFINE_PER_CPU(int, wq_rr_cpu_last);
456
457/*
458 * Local execution of unbound work items is no longer guaranteed. The
459 * following always forces round-robin CPU selection on unbound work items
460 * to uncover usages which depend on it.
461 */
462#ifdef CONFIG_DEBUG_WQ_FORCE_RR_CPU
463static bool wq_debug_force_rr_cpu = true;
464#else
465static bool wq_debug_force_rr_cpu = false;
466#endif
467module_param_named(debug_force_rr_cpu, wq_debug_force_rr_cpu, bool, 0644);
468
469/* to raise softirq for the BH worker pools on other CPUs */
470static DEFINE_PER_CPU_SHARED_ALIGNED(struct irq_work [NR_STD_WORKER_POOLS],
471 bh_pool_irq_works);
472
473/* the BH worker pools */
474static DEFINE_PER_CPU_SHARED_ALIGNED(struct worker_pool [NR_STD_WORKER_POOLS],
475 bh_worker_pools);
476
477/* the per-cpu worker pools */
478static DEFINE_PER_CPU_SHARED_ALIGNED(struct worker_pool [NR_STD_WORKER_POOLS],
479 cpu_worker_pools);
480
481static DEFINE_IDR(worker_pool_idr); /* PR: idr of all pools */
482
483/* PL: hash of all unbound pools keyed by pool->attrs */
484static DEFINE_HASHTABLE(unbound_pool_hash, UNBOUND_POOL_HASH_ORDER);
485
486/* I: attributes used when instantiating standard unbound pools on demand */
487static struct workqueue_attrs *unbound_std_wq_attrs[NR_STD_WORKER_POOLS];
488
489/* I: attributes used when instantiating ordered pools on demand */
490static struct workqueue_attrs *ordered_wq_attrs[NR_STD_WORKER_POOLS];
491
492/*
493 * Used to synchronize multiple cancel_sync attempts on the same work item. See
494 * work_grab_pending() and __cancel_work_sync().
495 */
496static DECLARE_WAIT_QUEUE_HEAD(wq_cancel_waitq);
497
498/*
499 * I: kthread_worker to release pwq's. pwq release needs to be bounced to a
500 * process context while holding a pool lock. Bounce to a dedicated kthread
501 * worker to avoid A-A deadlocks.
502 */
503static struct kthread_worker *pwq_release_worker __ro_after_init;
504
505struct workqueue_struct *system_wq __ro_after_init;
506EXPORT_SYMBOL(system_wq);
507struct workqueue_struct *system_highpri_wq __ro_after_init;
508EXPORT_SYMBOL_GPL(system_highpri_wq);
509struct workqueue_struct *system_long_wq __ro_after_init;
510EXPORT_SYMBOL_GPL(system_long_wq);
511struct workqueue_struct *system_unbound_wq __ro_after_init;
512EXPORT_SYMBOL_GPL(system_unbound_wq);
513struct workqueue_struct *system_freezable_wq __ro_after_init;
514EXPORT_SYMBOL_GPL(system_freezable_wq);
515struct workqueue_struct *system_power_efficient_wq __ro_after_init;
516EXPORT_SYMBOL_GPL(system_power_efficient_wq);
517struct workqueue_struct *system_freezable_power_efficient_wq __ro_after_init;
518EXPORT_SYMBOL_GPL(system_freezable_power_efficient_wq);
519struct workqueue_struct *system_bh_wq;
520EXPORT_SYMBOL_GPL(system_bh_wq);
521struct workqueue_struct *system_bh_highpri_wq;
522EXPORT_SYMBOL_GPL(system_bh_highpri_wq);
523
524static int worker_thread(void *__worker);
525static void workqueue_sysfs_unregister(struct workqueue_struct *wq);
526static void show_pwq(struct pool_workqueue *pwq);
527static void show_one_worker_pool(struct worker_pool *pool);
528
529#define CREATE_TRACE_POINTS
530#include <trace/events/workqueue.h>
531
532#define assert_rcu_or_pool_mutex() \
533 RCU_LOCKDEP_WARN(!rcu_read_lock_any_held() && \
534 !lockdep_is_held(&wq_pool_mutex), \
535 "RCU or wq_pool_mutex should be held")
536
537#define assert_rcu_or_wq_mutex_or_pool_mutex(wq) \
538 RCU_LOCKDEP_WARN(!rcu_read_lock_any_held() && \
539 !lockdep_is_held(&wq->mutex) && \
540 !lockdep_is_held(&wq_pool_mutex), \
541 "RCU, wq->mutex or wq_pool_mutex should be held")
542
543#define for_each_bh_worker_pool(pool, cpu) \
544 for ((pool) = &per_cpu(bh_worker_pools, cpu)[0]; \
545 (pool) < &per_cpu(bh_worker_pools, cpu)[NR_STD_WORKER_POOLS]; \
546 (pool)++)
547
548#define for_each_cpu_worker_pool(pool, cpu) \
549 for ((pool) = &per_cpu(cpu_worker_pools, cpu)[0]; \
550 (pool) < &per_cpu(cpu_worker_pools, cpu)[NR_STD_WORKER_POOLS]; \
551 (pool)++)
552
553/**
554 * for_each_pool - iterate through all worker_pools in the system
555 * @pool: iteration cursor
556 * @pi: integer used for iteration
557 *
558 * This must be called either with wq_pool_mutex held or RCU read
559 * locked. If the pool needs to be used beyond the locking in effect, the
560 * caller is responsible for guaranteeing that the pool stays online.
561 *
562 * The if/else clause exists only for the lockdep assertion and can be
563 * ignored.
564 */
565#define for_each_pool(pool, pi) \
566 idr_for_each_entry(&worker_pool_idr, pool, pi) \
567 if (({ assert_rcu_or_pool_mutex(); false; })) { } \
568 else
569
570/**
571 * for_each_pool_worker - iterate through all workers of a worker_pool
572 * @worker: iteration cursor
573 * @pool: worker_pool to iterate workers of
574 *
575 * This must be called with wq_pool_attach_mutex.
576 *
577 * The if/else clause exists only for the lockdep assertion and can be
578 * ignored.
579 */
580#define for_each_pool_worker(worker, pool) \
581 list_for_each_entry((worker), &(pool)->workers, node) \
582 if (({ lockdep_assert_held(&wq_pool_attach_mutex); false; })) { } \
583 else
584
585/**
586 * for_each_pwq - iterate through all pool_workqueues of the specified workqueue
587 * @pwq: iteration cursor
588 * @wq: the target workqueue
589 *
590 * This must be called either with wq->mutex held or RCU read locked.
591 * If the pwq needs to be used beyond the locking in effect, the caller is
592 * responsible for guaranteeing that the pwq stays online.
593 *
594 * The if/else clause exists only for the lockdep assertion and can be
595 * ignored.
596 */
597#define for_each_pwq(pwq, wq) \
598 list_for_each_entry_rcu((pwq), &(wq)->pwqs, pwqs_node, \
599 lockdep_is_held(&(wq->mutex)))
600
601#ifdef CONFIG_DEBUG_OBJECTS_WORK
602
603static const struct debug_obj_descr work_debug_descr;
604
605static void *work_debug_hint(void *addr)
606{
607 return ((struct work_struct *) addr)->func;
608}
609
610static bool work_is_static_object(void *addr)
611{
612 struct work_struct *work = addr;
613
614 return test_bit(WORK_STRUCT_STATIC_BIT, work_data_bits(work));
615}
616
617/*
618 * fixup_init is called when:
619 * - an active object is initialized
620 */
621static bool work_fixup_init(void *addr, enum debug_obj_state state)
622{
623 struct work_struct *work = addr;
624
625 switch (state) {
626 case ODEBUG_STATE_ACTIVE:
627 cancel_work_sync(work);
628 debug_object_init(work, &work_debug_descr);
629 return true;
630 default:
631 return false;
632 }
633}
634
635/*
636 * fixup_free is called when:
637 * - an active object is freed
638 */
639static bool work_fixup_free(void *addr, enum debug_obj_state state)
640{
641 struct work_struct *work = addr;
642
643 switch (state) {
644 case ODEBUG_STATE_ACTIVE:
645 cancel_work_sync(work);
646 debug_object_free(work, &work_debug_descr);
647 return true;
648 default:
649 return false;
650 }
651}
652
653static const struct debug_obj_descr work_debug_descr = {
654 .name = "work_struct",
655 .debug_hint = work_debug_hint,
656 .is_static_object = work_is_static_object,
657 .fixup_init = work_fixup_init,
658 .fixup_free = work_fixup_free,
659};
660
661static inline void debug_work_activate(struct work_struct *work)
662{
663 debug_object_activate(work, &work_debug_descr);
664}
665
666static inline void debug_work_deactivate(struct work_struct *work)
667{
668 debug_object_deactivate(work, &work_debug_descr);
669}
670
671void __init_work(struct work_struct *work, int onstack)
672{
673 if (onstack)
674 debug_object_init_on_stack(work, &work_debug_descr);
675 else
676 debug_object_init(work, &work_debug_descr);
677}
678EXPORT_SYMBOL_GPL(__init_work);
679
680void destroy_work_on_stack(struct work_struct *work)
681{
682 debug_object_free(work, &work_debug_descr);
683}
684EXPORT_SYMBOL_GPL(destroy_work_on_stack);
685
686void destroy_delayed_work_on_stack(struct delayed_work *work)
687{
688 destroy_timer_on_stack(&work->timer);
689 debug_object_free(&work->work, &work_debug_descr);
690}
691EXPORT_SYMBOL_GPL(destroy_delayed_work_on_stack);
692
693#else
694static inline void debug_work_activate(struct work_struct *work) { }
695static inline void debug_work_deactivate(struct work_struct *work) { }
696#endif
697
698/**
699 * worker_pool_assign_id - allocate ID and assign it to @pool
700 * @pool: the pool pointer of interest
701 *
702 * Returns 0 if ID in [0, WORK_OFFQ_POOL_NONE) is allocated and assigned
703 * successfully, -errno on failure.
704 */
705static int worker_pool_assign_id(struct worker_pool *pool)
706{
707 int ret;
708
709 lockdep_assert_held(&wq_pool_mutex);
710
711 ret = idr_alloc(&worker_pool_idr, pool, 0, WORK_OFFQ_POOL_NONE,
712 GFP_KERNEL);
713 if (ret >= 0) {
714 pool->id = ret;
715 return 0;
716 }
717 return ret;
718}
719
720static struct pool_workqueue __rcu **
721unbound_pwq_slot(struct workqueue_struct *wq, int cpu)
722{
723 if (cpu >= 0)
724 return per_cpu_ptr(wq->cpu_pwq, cpu);
725 else
726 return &wq->dfl_pwq;
727}
728
729/* @cpu < 0 for dfl_pwq */
730static struct pool_workqueue *unbound_pwq(struct workqueue_struct *wq, int cpu)
731{
732 return rcu_dereference_check(*unbound_pwq_slot(wq, cpu),
733 lockdep_is_held(&wq_pool_mutex) ||
734 lockdep_is_held(&wq->mutex));
735}
736
737/**
738 * unbound_effective_cpumask - effective cpumask of an unbound workqueue
739 * @wq: workqueue of interest
740 *
741 * @wq->unbound_attrs->cpumask contains the cpumask requested by the user which
742 * is masked with wq_unbound_cpumask to determine the effective cpumask. The
743 * default pwq is always mapped to the pool with the current effective cpumask.
744 */
745static struct cpumask *unbound_effective_cpumask(struct workqueue_struct *wq)
746{
747 return unbound_pwq(wq, -1)->pool->attrs->__pod_cpumask;
748}
749
750static unsigned int work_color_to_flags(int color)
751{
752 return color << WORK_STRUCT_COLOR_SHIFT;
753}
754
755static int get_work_color(unsigned long work_data)
756{
757 return (work_data >> WORK_STRUCT_COLOR_SHIFT) &
758 ((1 << WORK_STRUCT_COLOR_BITS) - 1);
759}
760
761static int work_next_color(int color)
762{
763 return (color + 1) % WORK_NR_COLORS;
764}
765
766/*
767 * While queued, %WORK_STRUCT_PWQ is set and non flag bits of a work's data
768 * contain the pointer to the queued pwq. Once execution starts, the flag
769 * is cleared and the high bits contain OFFQ flags and pool ID.
770 *
771 * set_work_pwq(), set_work_pool_and_clear_pending() and mark_work_canceling()
772 * can be used to set the pwq, pool or clear work->data. These functions should
773 * only be called while the work is owned - ie. while the PENDING bit is set.
774 *
775 * get_work_pool() and get_work_pwq() can be used to obtain the pool or pwq
776 * corresponding to a work. Pool is available once the work has been
777 * queued anywhere after initialization until it is sync canceled. pwq is
778 * available only while the work item is queued.
779 *
780 * %WORK_OFFQ_CANCELING is used to mark a work item which is being
781 * canceled. While being canceled, a work item may have its PENDING set
782 * but stay off timer and worklist for arbitrarily long and nobody should
783 * try to steal the PENDING bit.
784 */
785static inline void set_work_data(struct work_struct *work, unsigned long data)
786{
787 WARN_ON_ONCE(!work_pending(work));
788 atomic_long_set(&work->data, data | work_static(work));
789}
790
791static void set_work_pwq(struct work_struct *work, struct pool_workqueue *pwq,
792 unsigned long flags)
793{
794 set_work_data(work, (unsigned long)pwq | WORK_STRUCT_PENDING |
795 WORK_STRUCT_PWQ | flags);
796}
797
798static void set_work_pool_and_keep_pending(struct work_struct *work,
799 int pool_id, unsigned long flags)
800{
801 set_work_data(work, ((unsigned long)pool_id << WORK_OFFQ_POOL_SHIFT) |
802 WORK_STRUCT_PENDING | flags);
803}
804
805static void set_work_pool_and_clear_pending(struct work_struct *work,
806 int pool_id, unsigned long flags)
807{
808 /*
809 * The following wmb is paired with the implied mb in
810 * test_and_set_bit(PENDING) and ensures all updates to @work made
811 * here are visible to and precede any updates by the next PENDING
812 * owner.
813 */
814 smp_wmb();
815 set_work_data(work, ((unsigned long)pool_id << WORK_OFFQ_POOL_SHIFT) |
816 flags);
817 /*
818 * The following mb guarantees that previous clear of a PENDING bit
819 * will not be reordered with any speculative LOADS or STORES from
820 * work->current_func, which is executed afterwards. This possible
821 * reordering can lead to a missed execution on attempt to queue
822 * the same @work. E.g. consider this case:
823 *
824 * CPU#0 CPU#1
825 * ---------------------------- --------------------------------
826 *
827 * 1 STORE event_indicated
828 * 2 queue_work_on() {
829 * 3 test_and_set_bit(PENDING)
830 * 4 } set_..._and_clear_pending() {
831 * 5 set_work_data() # clear bit
832 * 6 smp_mb()
833 * 7 work->current_func() {
834 * 8 LOAD event_indicated
835 * }
836 *
837 * Without an explicit full barrier speculative LOAD on line 8 can
838 * be executed before CPU#0 does STORE on line 1. If that happens,
839 * CPU#0 observes the PENDING bit is still set and new execution of
840 * a @work is not queued in a hope, that CPU#1 will eventually
841 * finish the queued @work. Meanwhile CPU#1 does not see
842 * event_indicated is set, because speculative LOAD was executed
843 * before actual STORE.
844 */
845 smp_mb();
846}
847
848static inline struct pool_workqueue *work_struct_pwq(unsigned long data)
849{
850 return (struct pool_workqueue *)(data & WORK_STRUCT_PWQ_MASK);
851}
852
853static struct pool_workqueue *get_work_pwq(struct work_struct *work)
854{
855 unsigned long data = atomic_long_read(&work->data);
856
857 if (data & WORK_STRUCT_PWQ)
858 return work_struct_pwq(data);
859 else
860 return NULL;
861}
862
863/**
864 * get_work_pool - return the worker_pool a given work was associated with
865 * @work: the work item of interest
866 *
867 * Pools are created and destroyed under wq_pool_mutex, and allows read
868 * access under RCU read lock. As such, this function should be
869 * called under wq_pool_mutex or inside of a rcu_read_lock() region.
870 *
871 * All fields of the returned pool are accessible as long as the above
872 * mentioned locking is in effect. If the returned pool needs to be used
873 * beyond the critical section, the caller is responsible for ensuring the
874 * returned pool is and stays online.
875 *
876 * Return: The worker_pool @work was last associated with. %NULL if none.
877 */
878static struct worker_pool *get_work_pool(struct work_struct *work)
879{
880 unsigned long data = atomic_long_read(&work->data);
881 int pool_id;
882
883 assert_rcu_or_pool_mutex();
884
885 if (data & WORK_STRUCT_PWQ)
886 return work_struct_pwq(data)->pool;
887
888 pool_id = data >> WORK_OFFQ_POOL_SHIFT;
889 if (pool_id == WORK_OFFQ_POOL_NONE)
890 return NULL;
891
892 return idr_find(&worker_pool_idr, pool_id);
893}
894
895/**
896 * get_work_pool_id - return the worker pool ID a given work is associated with
897 * @work: the work item of interest
898 *
899 * Return: The worker_pool ID @work was last associated with.
900 * %WORK_OFFQ_POOL_NONE if none.
901 */
902static int get_work_pool_id(struct work_struct *work)
903{
904 unsigned long data = atomic_long_read(&work->data);
905
906 if (data & WORK_STRUCT_PWQ)
907 return work_struct_pwq(data)->pool->id;
908
909 return data >> WORK_OFFQ_POOL_SHIFT;
910}
911
912static void mark_work_canceling(struct work_struct *work)
913{
914 unsigned long pool_id = get_work_pool_id(work);
915
916 pool_id <<= WORK_OFFQ_POOL_SHIFT;
917 set_work_data(work, pool_id | WORK_STRUCT_PENDING | WORK_OFFQ_CANCELING);
918}
919
920static bool work_is_canceling(struct work_struct *work)
921{
922 unsigned long data = atomic_long_read(&work->data);
923
924 return !(data & WORK_STRUCT_PWQ) && (data & WORK_OFFQ_CANCELING);
925}
926
927/*
928 * Policy functions. These define the policies on how the global worker
929 * pools are managed. Unless noted otherwise, these functions assume that
930 * they're being called with pool->lock held.
931 */
932
933/*
934 * Need to wake up a worker? Called from anything but currently
935 * running workers.
936 *
937 * Note that, because unbound workers never contribute to nr_running, this
938 * function will always return %true for unbound pools as long as the
939 * worklist isn't empty.
940 */
941static bool need_more_worker(struct worker_pool *pool)
942{
943 return !list_empty(&pool->worklist) && !pool->nr_running;
944}
945
946/* Can I start working? Called from busy but !running workers. */
947static bool may_start_working(struct worker_pool *pool)
948{
949 return pool->nr_idle;
950}
951
952/* Do I need to keep working? Called from currently running workers. */
953static bool keep_working(struct worker_pool *pool)
954{
955 return !list_empty(&pool->worklist) && (pool->nr_running <= 1);
956}
957
958/* Do we need a new worker? Called from manager. */
959static bool need_to_create_worker(struct worker_pool *pool)
960{
961 return need_more_worker(pool) && !may_start_working(pool);
962}
963
964/* Do we have too many workers and should some go away? */
965static bool too_many_workers(struct worker_pool *pool)
966{
967 bool managing = pool->flags & POOL_MANAGER_ACTIVE;
968 int nr_idle = pool->nr_idle + managing; /* manager is considered idle */
969 int nr_busy = pool->nr_workers - nr_idle;
970
971 return nr_idle > 2 && (nr_idle - 2) * MAX_IDLE_WORKERS_RATIO >= nr_busy;
972}
973
974/**
975 * worker_set_flags - set worker flags and adjust nr_running accordingly
976 * @worker: self
977 * @flags: flags to set
978 *
979 * Set @flags in @worker->flags and adjust nr_running accordingly.
980 */
981static inline void worker_set_flags(struct worker *worker, unsigned int flags)
982{
983 struct worker_pool *pool = worker->pool;
984
985 lockdep_assert_held(&pool->lock);
986
987 /* If transitioning into NOT_RUNNING, adjust nr_running. */
988 if ((flags & WORKER_NOT_RUNNING) &&
989 !(worker->flags & WORKER_NOT_RUNNING)) {
990 pool->nr_running--;
991 }
992
993 worker->flags |= flags;
994}
995
996/**
997 * worker_clr_flags - clear worker flags and adjust nr_running accordingly
998 * @worker: self
999 * @flags: flags to clear
1000 *
1001 * Clear @flags in @worker->flags and adjust nr_running accordingly.
1002 */
1003static inline void worker_clr_flags(struct worker *worker, unsigned int flags)
1004{
1005 struct worker_pool *pool = worker->pool;
1006 unsigned int oflags = worker->flags;
1007
1008 lockdep_assert_held(&pool->lock);
1009
1010 worker->flags &= ~flags;
1011
1012 /*
1013 * If transitioning out of NOT_RUNNING, increment nr_running. Note
1014 * that the nested NOT_RUNNING is not a noop. NOT_RUNNING is mask
1015 * of multiple flags, not a single flag.
1016 */
1017 if ((flags & WORKER_NOT_RUNNING) && (oflags & WORKER_NOT_RUNNING))
1018 if (!(worker->flags & WORKER_NOT_RUNNING))
1019 pool->nr_running++;
1020}
1021
1022/* Return the first idle worker. Called with pool->lock held. */
1023static struct worker *first_idle_worker(struct worker_pool *pool)
1024{
1025 if (unlikely(list_empty(&pool->idle_list)))
1026 return NULL;
1027
1028 return list_first_entry(&pool->idle_list, struct worker, entry);
1029}
1030
1031/**
1032 * worker_enter_idle - enter idle state
1033 * @worker: worker which is entering idle state
1034 *
1035 * @worker is entering idle state. Update stats and idle timer if
1036 * necessary.
1037 *
1038 * LOCKING:
1039 * raw_spin_lock_irq(pool->lock).
1040 */
1041static void worker_enter_idle(struct worker *worker)
1042{
1043 struct worker_pool *pool = worker->pool;
1044
1045 if (WARN_ON_ONCE(worker->flags & WORKER_IDLE) ||
1046 WARN_ON_ONCE(!list_empty(&worker->entry) &&
1047 (worker->hentry.next || worker->hentry.pprev)))
1048 return;
1049
1050 /* can't use worker_set_flags(), also called from create_worker() */
1051 worker->flags |= WORKER_IDLE;
1052 pool->nr_idle++;
1053 worker->last_active = jiffies;
1054
1055 /* idle_list is LIFO */
1056 list_add(&worker->entry, &pool->idle_list);
1057
1058 if (too_many_workers(pool) && !timer_pending(&pool->idle_timer))
1059 mod_timer(&pool->idle_timer, jiffies + IDLE_WORKER_TIMEOUT);
1060
1061 /* Sanity check nr_running. */
1062 WARN_ON_ONCE(pool->nr_workers == pool->nr_idle && pool->nr_running);
1063}
1064
1065/**
1066 * worker_leave_idle - leave idle state
1067 * @worker: worker which is leaving idle state
1068 *
1069 * @worker is leaving idle state. Update stats.
1070 *
1071 * LOCKING:
1072 * raw_spin_lock_irq(pool->lock).
1073 */
1074static void worker_leave_idle(struct worker *worker)
1075{
1076 struct worker_pool *pool = worker->pool;
1077
1078 if (WARN_ON_ONCE(!(worker->flags & WORKER_IDLE)))
1079 return;
1080 worker_clr_flags(worker, WORKER_IDLE);
1081 pool->nr_idle--;
1082 list_del_init(&worker->entry);
1083}
1084
1085/**
1086 * find_worker_executing_work - find worker which is executing a work
1087 * @pool: pool of interest
1088 * @work: work to find worker for
1089 *
1090 * Find a worker which is executing @work on @pool by searching
1091 * @pool->busy_hash which is keyed by the address of @work. For a worker
1092 * to match, its current execution should match the address of @work and
1093 * its work function. This is to avoid unwanted dependency between
1094 * unrelated work executions through a work item being recycled while still
1095 * being executed.
1096 *
1097 * This is a bit tricky. A work item may be freed once its execution
1098 * starts and nothing prevents the freed area from being recycled for
1099 * another work item. If the same work item address ends up being reused
1100 * before the original execution finishes, workqueue will identify the
1101 * recycled work item as currently executing and make it wait until the
1102 * current execution finishes, introducing an unwanted dependency.
1103 *
1104 * This function checks the work item address and work function to avoid
1105 * false positives. Note that this isn't complete as one may construct a
1106 * work function which can introduce dependency onto itself through a
1107 * recycled work item. Well, if somebody wants to shoot oneself in the
1108 * foot that badly, there's only so much we can do, and if such deadlock
1109 * actually occurs, it should be easy to locate the culprit work function.
1110 *
1111 * CONTEXT:
1112 * raw_spin_lock_irq(pool->lock).
1113 *
1114 * Return:
1115 * Pointer to worker which is executing @work if found, %NULL
1116 * otherwise.
1117 */
1118static struct worker *find_worker_executing_work(struct worker_pool *pool,
1119 struct work_struct *work)
1120{
1121 struct worker *worker;
1122
1123 hash_for_each_possible(pool->busy_hash, worker, hentry,
1124 (unsigned long)work)
1125 if (worker->current_work == work &&
1126 worker->current_func == work->func)
1127 return worker;
1128
1129 return NULL;
1130}
1131
1132/**
1133 * move_linked_works - move linked works to a list
1134 * @work: start of series of works to be scheduled
1135 * @head: target list to append @work to
1136 * @nextp: out parameter for nested worklist walking
1137 *
1138 * Schedule linked works starting from @work to @head. Work series to be
1139 * scheduled starts at @work and includes any consecutive work with
1140 * WORK_STRUCT_LINKED set in its predecessor. See assign_work() for details on
1141 * @nextp.
1142 *
1143 * CONTEXT:
1144 * raw_spin_lock_irq(pool->lock).
1145 */
1146static void move_linked_works(struct work_struct *work, struct list_head *head,
1147 struct work_struct **nextp)
1148{
1149 struct work_struct *n;
1150
1151 /*
1152 * Linked worklist will always end before the end of the list,
1153 * use NULL for list head.
1154 */
1155 list_for_each_entry_safe_from(work, n, NULL, entry) {
1156 list_move_tail(&work->entry, head);
1157 if (!(*work_data_bits(work) & WORK_STRUCT_LINKED))
1158 break;
1159 }
1160
1161 /*
1162 * If we're already inside safe list traversal and have moved
1163 * multiple works to the scheduled queue, the next position
1164 * needs to be updated.
1165 */
1166 if (nextp)
1167 *nextp = n;
1168}
1169
1170/**
1171 * assign_work - assign a work item and its linked work items to a worker
1172 * @work: work to assign
1173 * @worker: worker to assign to
1174 * @nextp: out parameter for nested worklist walking
1175 *
1176 * Assign @work and its linked work items to @worker. If @work is already being
1177 * executed by another worker in the same pool, it'll be punted there.
1178 *
1179 * If @nextp is not NULL, it's updated to point to the next work of the last
1180 * scheduled work. This allows assign_work() to be nested inside
1181 * list_for_each_entry_safe().
1182 *
1183 * Returns %true if @work was successfully assigned to @worker. %false if @work
1184 * was punted to another worker already executing it.
1185 */
1186static bool assign_work(struct work_struct *work, struct worker *worker,
1187 struct work_struct **nextp)
1188{
1189 struct worker_pool *pool = worker->pool;
1190 struct worker *collision;
1191
1192 lockdep_assert_held(&pool->lock);
1193
1194 /*
1195 * A single work shouldn't be executed concurrently by multiple workers.
1196 * __queue_work() ensures that @work doesn't jump to a different pool
1197 * while still running in the previous pool. Here, we should ensure that
1198 * @work is not executed concurrently by multiple workers from the same
1199 * pool. Check whether anyone is already processing the work. If so,
1200 * defer the work to the currently executing one.
1201 */
1202 collision = find_worker_executing_work(pool, work);
1203 if (unlikely(collision)) {
1204 move_linked_works(work, &collision->scheduled, nextp);
1205 return false;
1206 }
1207
1208 move_linked_works(work, &worker->scheduled, nextp);
1209 return true;
1210}
1211
1212static struct irq_work *bh_pool_irq_work(struct worker_pool *pool)
1213{
1214 int high = pool->attrs->nice == HIGHPRI_NICE_LEVEL ? 1 : 0;
1215
1216 return &per_cpu(bh_pool_irq_works, pool->cpu)[high];
1217}
1218
1219static void kick_bh_pool(struct worker_pool *pool)
1220{
1221#ifdef CONFIG_SMP
1222 /* see drain_dead_softirq_workfn() for BH_DRAINING */
1223 if (unlikely(pool->cpu != smp_processor_id() &&
1224 !(pool->flags & POOL_BH_DRAINING))) {
1225 irq_work_queue_on(bh_pool_irq_work(pool), pool->cpu);
1226 return;
1227 }
1228#endif
1229 if (pool->attrs->nice == HIGHPRI_NICE_LEVEL)
1230 raise_softirq_irqoff(HI_SOFTIRQ);
1231 else
1232 raise_softirq_irqoff(TASKLET_SOFTIRQ);
1233}
1234
1235/**
1236 * kick_pool - wake up an idle worker if necessary
1237 * @pool: pool to kick
1238 *
1239 * @pool may have pending work items. Wake up worker if necessary. Returns
1240 * whether a worker was woken up.
1241 */
1242static bool kick_pool(struct worker_pool *pool)
1243{
1244 struct worker *worker = first_idle_worker(pool);
1245 struct task_struct *p;
1246
1247 lockdep_assert_held(&pool->lock);
1248
1249 if (!need_more_worker(pool) || !worker)
1250 return false;
1251
1252 if (pool->flags & POOL_BH) {
1253 kick_bh_pool(pool);
1254 return true;
1255 }
1256
1257 p = worker->task;
1258
1259#ifdef CONFIG_SMP
1260 /*
1261 * Idle @worker is about to execute @work and waking up provides an
1262 * opportunity to migrate @worker at a lower cost by setting the task's
1263 * wake_cpu field. Let's see if we want to move @worker to improve
1264 * execution locality.
1265 *
1266 * We're waking the worker that went idle the latest and there's some
1267 * chance that @worker is marked idle but hasn't gone off CPU yet. If
1268 * so, setting the wake_cpu won't do anything. As this is a best-effort
1269 * optimization and the race window is narrow, let's leave as-is for
1270 * now. If this becomes pronounced, we can skip over workers which are
1271 * still on cpu when picking an idle worker.
1272 *
1273 * If @pool has non-strict affinity, @worker might have ended up outside
1274 * its affinity scope. Repatriate.
1275 */
1276 if (!pool->attrs->affn_strict &&
1277 !cpumask_test_cpu(p->wake_cpu, pool->attrs->__pod_cpumask)) {
1278 struct work_struct *work = list_first_entry(&pool->worklist,
1279 struct work_struct, entry);
1280 int wake_cpu = cpumask_any_and_distribute(pool->attrs->__pod_cpumask,
1281 cpu_online_mask);
1282 if (wake_cpu < nr_cpu_ids) {
1283 p->wake_cpu = wake_cpu;
1284 get_work_pwq(work)->stats[PWQ_STAT_REPATRIATED]++;
1285 }
1286 }
1287#endif
1288 wake_up_process(p);
1289 return true;
1290}
1291
1292#ifdef CONFIG_WQ_CPU_INTENSIVE_REPORT
1293
1294/*
1295 * Concurrency-managed per-cpu work items that hog CPU for longer than
1296 * wq_cpu_intensive_thresh_us trigger the automatic CPU_INTENSIVE mechanism,
1297 * which prevents them from stalling other concurrency-managed work items. If a
1298 * work function keeps triggering this mechanism, it's likely that the work item
1299 * should be using an unbound workqueue instead.
1300 *
1301 * wq_cpu_intensive_report() tracks work functions which trigger such conditions
1302 * and report them so that they can be examined and converted to use unbound
1303 * workqueues as appropriate. To avoid flooding the console, each violating work
1304 * function is tracked and reported with exponential backoff.
1305 */
1306#define WCI_MAX_ENTS 128
1307
1308struct wci_ent {
1309 work_func_t func;
1310 atomic64_t cnt;
1311 struct hlist_node hash_node;
1312};
1313
1314static struct wci_ent wci_ents[WCI_MAX_ENTS];
1315static int wci_nr_ents;
1316static DEFINE_RAW_SPINLOCK(wci_lock);
1317static DEFINE_HASHTABLE(wci_hash, ilog2(WCI_MAX_ENTS));
1318
1319static struct wci_ent *wci_find_ent(work_func_t func)
1320{
1321 struct wci_ent *ent;
1322
1323 hash_for_each_possible_rcu(wci_hash, ent, hash_node,
1324 (unsigned long)func) {
1325 if (ent->func == func)
1326 return ent;
1327 }
1328 return NULL;
1329}
1330
1331static void wq_cpu_intensive_report(work_func_t func)
1332{
1333 struct wci_ent *ent;
1334
1335restart:
1336 ent = wci_find_ent(func);
1337 if (ent) {
1338 u64 cnt;
1339
1340 /*
1341 * Start reporting from the warning_thresh and back off
1342 * exponentially.
1343 */
1344 cnt = atomic64_inc_return_relaxed(&ent->cnt);
1345 if (wq_cpu_intensive_warning_thresh &&
1346 cnt >= wq_cpu_intensive_warning_thresh &&
1347 is_power_of_2(cnt + 1 - wq_cpu_intensive_warning_thresh))
1348 printk_deferred(KERN_WARNING "workqueue: %ps hogged CPU for >%luus %llu times, consider switching to WQ_UNBOUND\n",
1349 ent->func, wq_cpu_intensive_thresh_us,
1350 atomic64_read(&ent->cnt));
1351 return;
1352 }
1353
1354 /*
1355 * @func is a new violation. Allocate a new entry for it. If wcn_ents[]
1356 * is exhausted, something went really wrong and we probably made enough
1357 * noise already.
1358 */
1359 if (wci_nr_ents >= WCI_MAX_ENTS)
1360 return;
1361
1362 raw_spin_lock(&wci_lock);
1363
1364 if (wci_nr_ents >= WCI_MAX_ENTS) {
1365 raw_spin_unlock(&wci_lock);
1366 return;
1367 }
1368
1369 if (wci_find_ent(func)) {
1370 raw_spin_unlock(&wci_lock);
1371 goto restart;
1372 }
1373
1374 ent = &wci_ents[wci_nr_ents++];
1375 ent->func = func;
1376 atomic64_set(&ent->cnt, 0);
1377 hash_add_rcu(wci_hash, &ent->hash_node, (unsigned long)func);
1378
1379 raw_spin_unlock(&wci_lock);
1380
1381 goto restart;
1382}
1383
1384#else /* CONFIG_WQ_CPU_INTENSIVE_REPORT */
1385static void wq_cpu_intensive_report(work_func_t func) {}
1386#endif /* CONFIG_WQ_CPU_INTENSIVE_REPORT */
1387
1388/**
1389 * wq_worker_running - a worker is running again
1390 * @task: task waking up
1391 *
1392 * This function is called when a worker returns from schedule()
1393 */
1394void wq_worker_running(struct task_struct *task)
1395{
1396 struct worker *worker = kthread_data(task);
1397
1398 if (!READ_ONCE(worker->sleeping))
1399 return;
1400
1401 /*
1402 * If preempted by unbind_workers() between the WORKER_NOT_RUNNING check
1403 * and the nr_running increment below, we may ruin the nr_running reset
1404 * and leave with an unexpected pool->nr_running == 1 on the newly unbound
1405 * pool. Protect against such race.
1406 */
1407 preempt_disable();
1408 if (!(worker->flags & WORKER_NOT_RUNNING))
1409 worker->pool->nr_running++;
1410 preempt_enable();
1411
1412 /*
1413 * CPU intensive auto-detection cares about how long a work item hogged
1414 * CPU without sleeping. Reset the starting timestamp on wakeup.
1415 */
1416 worker->current_at = worker->task->se.sum_exec_runtime;
1417
1418 WRITE_ONCE(worker->sleeping, 0);
1419}
1420
1421/**
1422 * wq_worker_sleeping - a worker is going to sleep
1423 * @task: task going to sleep
1424 *
1425 * This function is called from schedule() when a busy worker is
1426 * going to sleep.
1427 */
1428void wq_worker_sleeping(struct task_struct *task)
1429{
1430 struct worker *worker = kthread_data(task);
1431 struct worker_pool *pool;
1432
1433 /*
1434 * Rescuers, which may not have all the fields set up like normal
1435 * workers, also reach here, let's not access anything before
1436 * checking NOT_RUNNING.
1437 */
1438 if (worker->flags & WORKER_NOT_RUNNING)
1439 return;
1440
1441 pool = worker->pool;
1442
1443 /* Return if preempted before wq_worker_running() was reached */
1444 if (READ_ONCE(worker->sleeping))
1445 return;
1446
1447 WRITE_ONCE(worker->sleeping, 1);
1448 raw_spin_lock_irq(&pool->lock);
1449
1450 /*
1451 * Recheck in case unbind_workers() preempted us. We don't
1452 * want to decrement nr_running after the worker is unbound
1453 * and nr_running has been reset.
1454 */
1455 if (worker->flags & WORKER_NOT_RUNNING) {
1456 raw_spin_unlock_irq(&pool->lock);
1457 return;
1458 }
1459
1460 pool->nr_running--;
1461 if (kick_pool(pool))
1462 worker->current_pwq->stats[PWQ_STAT_CM_WAKEUP]++;
1463
1464 raw_spin_unlock_irq(&pool->lock);
1465}
1466
1467/**
1468 * wq_worker_tick - a scheduler tick occurred while a kworker is running
1469 * @task: task currently running
1470 *
1471 * Called from scheduler_tick(). We're in the IRQ context and the current
1472 * worker's fields which follow the 'K' locking rule can be accessed safely.
1473 */
1474void wq_worker_tick(struct task_struct *task)
1475{
1476 struct worker *worker = kthread_data(task);
1477 struct pool_workqueue *pwq = worker->current_pwq;
1478 struct worker_pool *pool = worker->pool;
1479
1480 if (!pwq)
1481 return;
1482
1483 pwq->stats[PWQ_STAT_CPU_TIME] += TICK_USEC;
1484
1485 if (!wq_cpu_intensive_thresh_us)
1486 return;
1487
1488 /*
1489 * If the current worker is concurrency managed and hogged the CPU for
1490 * longer than wq_cpu_intensive_thresh_us, it's automatically marked
1491 * CPU_INTENSIVE to avoid stalling other concurrency-managed work items.
1492 *
1493 * Set @worker->sleeping means that @worker is in the process of
1494 * switching out voluntarily and won't be contributing to
1495 * @pool->nr_running until it wakes up. As wq_worker_sleeping() also
1496 * decrements ->nr_running, setting CPU_INTENSIVE here can lead to
1497 * double decrements. The task is releasing the CPU anyway. Let's skip.
1498 * We probably want to make this prettier in the future.
1499 */
1500 if ((worker->flags & WORKER_NOT_RUNNING) || READ_ONCE(worker->sleeping) ||
1501 worker->task->se.sum_exec_runtime - worker->current_at <
1502 wq_cpu_intensive_thresh_us * NSEC_PER_USEC)
1503 return;
1504
1505 raw_spin_lock(&pool->lock);
1506
1507 worker_set_flags(worker, WORKER_CPU_INTENSIVE);
1508 wq_cpu_intensive_report(worker->current_func);
1509 pwq->stats[PWQ_STAT_CPU_INTENSIVE]++;
1510
1511 if (kick_pool(pool))
1512 pwq->stats[PWQ_STAT_CM_WAKEUP]++;
1513
1514 raw_spin_unlock(&pool->lock);
1515}
1516
1517/**
1518 * wq_worker_last_func - retrieve worker's last work function
1519 * @task: Task to retrieve last work function of.
1520 *
1521 * Determine the last function a worker executed. This is called from
1522 * the scheduler to get a worker's last known identity.
1523 *
1524 * CONTEXT:
1525 * raw_spin_lock_irq(rq->lock)
1526 *
1527 * This function is called during schedule() when a kworker is going
1528 * to sleep. It's used by psi to identify aggregation workers during
1529 * dequeuing, to allow periodic aggregation to shut-off when that
1530 * worker is the last task in the system or cgroup to go to sleep.
1531 *
1532 * As this function doesn't involve any workqueue-related locking, it
1533 * only returns stable values when called from inside the scheduler's
1534 * queuing and dequeuing paths, when @task, which must be a kworker,
1535 * is guaranteed to not be processing any works.
1536 *
1537 * Return:
1538 * The last work function %current executed as a worker, NULL if it
1539 * hasn't executed any work yet.
1540 */
1541work_func_t wq_worker_last_func(struct task_struct *task)
1542{
1543 struct worker *worker = kthread_data(task);
1544
1545 return worker->last_func;
1546}
1547
1548/**
1549 * wq_node_nr_active - Determine wq_node_nr_active to use
1550 * @wq: workqueue of interest
1551 * @node: NUMA node, can be %NUMA_NO_NODE
1552 *
1553 * Determine wq_node_nr_active to use for @wq on @node. Returns:
1554 *
1555 * - %NULL for per-cpu workqueues as they don't need to use shared nr_active.
1556 *
1557 * - node_nr_active[nr_node_ids] if @node is %NUMA_NO_NODE.
1558 *
1559 * - Otherwise, node_nr_active[@node].
1560 */
1561static struct wq_node_nr_active *wq_node_nr_active(struct workqueue_struct *wq,
1562 int node)
1563{
1564 if (!(wq->flags & WQ_UNBOUND))
1565 return NULL;
1566
1567 if (node == NUMA_NO_NODE)
1568 node = nr_node_ids;
1569
1570 return wq->node_nr_active[node];
1571}
1572
1573/**
1574 * wq_update_node_max_active - Update per-node max_actives to use
1575 * @wq: workqueue to update
1576 * @off_cpu: CPU that's going down, -1 if a CPU is not going down
1577 *
1578 * Update @wq->node_nr_active[]->max. @wq must be unbound. max_active is
1579 * distributed among nodes according to the proportions of numbers of online
1580 * cpus. The result is always between @wq->min_active and max_active.
1581 */
1582static void wq_update_node_max_active(struct workqueue_struct *wq, int off_cpu)
1583{
1584 struct cpumask *effective = unbound_effective_cpumask(wq);
1585 int min_active = READ_ONCE(wq->min_active);
1586 int max_active = READ_ONCE(wq->max_active);
1587 int total_cpus, node;
1588
1589 lockdep_assert_held(&wq->mutex);
1590
1591 if (!wq_topo_initialized)
1592 return;
1593
1594 if (off_cpu >= 0 && !cpumask_test_cpu(off_cpu, effective))
1595 off_cpu = -1;
1596
1597 total_cpus = cpumask_weight_and(effective, cpu_online_mask);
1598 if (off_cpu >= 0)
1599 total_cpus--;
1600
1601 /* If all CPUs of the wq get offline, use the default values */
1602 if (unlikely(!total_cpus)) {
1603 for_each_node(node)
1604 wq_node_nr_active(wq, node)->max = min_active;
1605
1606 wq_node_nr_active(wq, NUMA_NO_NODE)->max = max_active;
1607 return;
1608 }
1609
1610 for_each_node(node) {
1611 int node_cpus;
1612
1613 node_cpus = cpumask_weight_and(effective, cpumask_of_node(node));
1614 if (off_cpu >= 0 && cpu_to_node(off_cpu) == node)
1615 node_cpus--;
1616
1617 wq_node_nr_active(wq, node)->max =
1618 clamp(DIV_ROUND_UP(max_active * node_cpus, total_cpus),
1619 min_active, max_active);
1620 }
1621
1622 wq_node_nr_active(wq, NUMA_NO_NODE)->max = max_active;
1623}
1624
1625/**
1626 * get_pwq - get an extra reference on the specified pool_workqueue
1627 * @pwq: pool_workqueue to get
1628 *
1629 * Obtain an extra reference on @pwq. The caller should guarantee that
1630 * @pwq has positive refcnt and be holding the matching pool->lock.
1631 */
1632static void get_pwq(struct pool_workqueue *pwq)
1633{
1634 lockdep_assert_held(&pwq->pool->lock);
1635 WARN_ON_ONCE(pwq->refcnt <= 0);
1636 pwq->refcnt++;
1637}
1638
1639/**
1640 * put_pwq - put a pool_workqueue reference
1641 * @pwq: pool_workqueue to put
1642 *
1643 * Drop a reference of @pwq. If its refcnt reaches zero, schedule its
1644 * destruction. The caller should be holding the matching pool->lock.
1645 */
1646static void put_pwq(struct pool_workqueue *pwq)
1647{
1648 lockdep_assert_held(&pwq->pool->lock);
1649 if (likely(--pwq->refcnt))
1650 return;
1651 /*
1652 * @pwq can't be released under pool->lock, bounce to a dedicated
1653 * kthread_worker to avoid A-A deadlocks.
1654 */
1655 kthread_queue_work(pwq_release_worker, &pwq->release_work);
1656}
1657
1658/**
1659 * put_pwq_unlocked - put_pwq() with surrounding pool lock/unlock
1660 * @pwq: pool_workqueue to put (can be %NULL)
1661 *
1662 * put_pwq() with locking. This function also allows %NULL @pwq.
1663 */
1664static void put_pwq_unlocked(struct pool_workqueue *pwq)
1665{
1666 if (pwq) {
1667 /*
1668 * As both pwqs and pools are RCU protected, the
1669 * following lock operations are safe.
1670 */
1671 raw_spin_lock_irq(&pwq->pool->lock);
1672 put_pwq(pwq);
1673 raw_spin_unlock_irq(&pwq->pool->lock);
1674 }
1675}
1676
1677static bool pwq_is_empty(struct pool_workqueue *pwq)
1678{
1679 return !pwq->nr_active && list_empty(&pwq->inactive_works);
1680}
1681
1682static void __pwq_activate_work(struct pool_workqueue *pwq,
1683 struct work_struct *work)
1684{
1685 unsigned long *wdb = work_data_bits(work);
1686
1687 WARN_ON_ONCE(!(*wdb & WORK_STRUCT_INACTIVE));
1688 trace_workqueue_activate_work(work);
1689 if (list_empty(&pwq->pool->worklist))
1690 pwq->pool->watchdog_ts = jiffies;
1691 move_linked_works(work, &pwq->pool->worklist, NULL);
1692 __clear_bit(WORK_STRUCT_INACTIVE_BIT, wdb);
1693}
1694
1695/**
1696 * pwq_activate_work - Activate a work item if inactive
1697 * @pwq: pool_workqueue @work belongs to
1698 * @work: work item to activate
1699 *
1700 * Returns %true if activated. %false if already active.
1701 */
1702static bool pwq_activate_work(struct pool_workqueue *pwq,
1703 struct work_struct *work)
1704{
1705 struct worker_pool *pool = pwq->pool;
1706 struct wq_node_nr_active *nna;
1707
1708 lockdep_assert_held(&pool->lock);
1709
1710 if (!(*work_data_bits(work) & WORK_STRUCT_INACTIVE))
1711 return false;
1712
1713 nna = wq_node_nr_active(pwq->wq, pool->node);
1714 if (nna)
1715 atomic_inc(&nna->nr);
1716
1717 pwq->nr_active++;
1718 __pwq_activate_work(pwq, work);
1719 return true;
1720}
1721
1722static bool tryinc_node_nr_active(struct wq_node_nr_active *nna)
1723{
1724 int max = READ_ONCE(nna->max);
1725
1726 while (true) {
1727 int old, tmp;
1728
1729 old = atomic_read(&nna->nr);
1730 if (old >= max)
1731 return false;
1732 tmp = atomic_cmpxchg_relaxed(&nna->nr, old, old + 1);
1733 if (tmp == old)
1734 return true;
1735 }
1736}
1737
1738/**
1739 * pwq_tryinc_nr_active - Try to increment nr_active for a pwq
1740 * @pwq: pool_workqueue of interest
1741 * @fill: max_active may have increased, try to increase concurrency level
1742 *
1743 * Try to increment nr_active for @pwq. Returns %true if an nr_active count is
1744 * successfully obtained. %false otherwise.
1745 */
1746static bool pwq_tryinc_nr_active(struct pool_workqueue *pwq, bool fill)
1747{
1748 struct workqueue_struct *wq = pwq->wq;
1749 struct worker_pool *pool = pwq->pool;
1750 struct wq_node_nr_active *nna = wq_node_nr_active(wq, pool->node);
1751 bool obtained = false;
1752
1753 lockdep_assert_held(&pool->lock);
1754
1755 if (!nna) {
1756 /* BH or per-cpu workqueue, pwq->nr_active is sufficient */
1757 obtained = pwq->nr_active < READ_ONCE(wq->max_active);
1758 goto out;
1759 }
1760
1761 if (unlikely(pwq->plugged))
1762 return false;
1763
1764 /*
1765 * Unbound workqueue uses per-node shared nr_active $nna. If @pwq is
1766 * already waiting on $nna, pwq_dec_nr_active() will maintain the
1767 * concurrency level. Don't jump the line.
1768 *
1769 * We need to ignore the pending test after max_active has increased as
1770 * pwq_dec_nr_active() can only maintain the concurrency level but not
1771 * increase it. This is indicated by @fill.
1772 */
1773 if (!list_empty(&pwq->pending_node) && likely(!fill))
1774 goto out;
1775
1776 obtained = tryinc_node_nr_active(nna);
1777 if (obtained)
1778 goto out;
1779
1780 /*
1781 * Lockless acquisition failed. Lock, add ourself to $nna->pending_pwqs
1782 * and try again. The smp_mb() is paired with the implied memory barrier
1783 * of atomic_dec_return() in pwq_dec_nr_active() to ensure that either
1784 * we see the decremented $nna->nr or they see non-empty
1785 * $nna->pending_pwqs.
1786 */
1787 raw_spin_lock(&nna->lock);
1788
1789 if (list_empty(&pwq->pending_node))
1790 list_add_tail(&pwq->pending_node, &nna->pending_pwqs);
1791 else if (likely(!fill))
1792 goto out_unlock;
1793
1794 smp_mb();
1795
1796 obtained = tryinc_node_nr_active(nna);
1797
1798 /*
1799 * If @fill, @pwq might have already been pending. Being spuriously
1800 * pending in cold paths doesn't affect anything. Let's leave it be.
1801 */
1802 if (obtained && likely(!fill))
1803 list_del_init(&pwq->pending_node);
1804
1805out_unlock:
1806 raw_spin_unlock(&nna->lock);
1807out:
1808 if (obtained)
1809 pwq->nr_active++;
1810 return obtained;
1811}
1812
1813/**
1814 * pwq_activate_first_inactive - Activate the first inactive work item on a pwq
1815 * @pwq: pool_workqueue of interest
1816 * @fill: max_active may have increased, try to increase concurrency level
1817 *
1818 * Activate the first inactive work item of @pwq if available and allowed by
1819 * max_active limit.
1820 *
1821 * Returns %true if an inactive work item has been activated. %false if no
1822 * inactive work item is found or max_active limit is reached.
1823 */
1824static bool pwq_activate_first_inactive(struct pool_workqueue *pwq, bool fill)
1825{
1826 struct work_struct *work =
1827 list_first_entry_or_null(&pwq->inactive_works,
1828 struct work_struct, entry);
1829
1830 if (work && pwq_tryinc_nr_active(pwq, fill)) {
1831 __pwq_activate_work(pwq, work);
1832 return true;
1833 } else {
1834 return false;
1835 }
1836}
1837
1838/**
1839 * unplug_oldest_pwq - unplug the oldest pool_workqueue
1840 * @wq: workqueue_struct where its oldest pwq is to be unplugged
1841 *
1842 * This function should only be called for ordered workqueues where only the
1843 * oldest pwq is unplugged, the others are plugged to suspend execution to
1844 * ensure proper work item ordering::
1845 *
1846 * dfl_pwq --------------+ [P] - plugged
1847 * |
1848 * v
1849 * pwqs -> A -> B [P] -> C [P] (newest)
1850 * | | |
1851 * 1 3 5
1852 * | | |
1853 * 2 4 6
1854 *
1855 * When the oldest pwq is drained and removed, this function should be called
1856 * to unplug the next oldest one to start its work item execution. Note that
1857 * pwq's are linked into wq->pwqs with the oldest first, so the first one in
1858 * the list is the oldest.
1859 */
1860static void unplug_oldest_pwq(struct workqueue_struct *wq)
1861{
1862 struct pool_workqueue *pwq;
1863
1864 lockdep_assert_held(&wq->mutex);
1865
1866 /* Caller should make sure that pwqs isn't empty before calling */
1867 pwq = list_first_entry_or_null(&wq->pwqs, struct pool_workqueue,
1868 pwqs_node);
1869 raw_spin_lock_irq(&pwq->pool->lock);
1870 if (pwq->plugged) {
1871 pwq->plugged = false;
1872 if (pwq_activate_first_inactive(pwq, true))
1873 kick_pool(pwq->pool);
1874 }
1875 raw_spin_unlock_irq(&pwq->pool->lock);
1876}
1877
1878/**
1879 * node_activate_pending_pwq - Activate a pending pwq on a wq_node_nr_active
1880 * @nna: wq_node_nr_active to activate a pending pwq for
1881 * @caller_pool: worker_pool the caller is locking
1882 *
1883 * Activate a pwq in @nna->pending_pwqs. Called with @caller_pool locked.
1884 * @caller_pool may be unlocked and relocked to lock other worker_pools.
1885 */
1886static void node_activate_pending_pwq(struct wq_node_nr_active *nna,
1887 struct worker_pool *caller_pool)
1888{
1889 struct worker_pool *locked_pool = caller_pool;
1890 struct pool_workqueue *pwq;
1891 struct work_struct *work;
1892
1893 lockdep_assert_held(&caller_pool->lock);
1894
1895 raw_spin_lock(&nna->lock);
1896retry:
1897 pwq = list_first_entry_or_null(&nna->pending_pwqs,
1898 struct pool_workqueue, pending_node);
1899 if (!pwq)
1900 goto out_unlock;
1901
1902 /*
1903 * If @pwq is for a different pool than @locked_pool, we need to lock
1904 * @pwq->pool->lock. Let's trylock first. If unsuccessful, do the unlock
1905 * / lock dance. For that, we also need to release @nna->lock as it's
1906 * nested inside pool locks.
1907 */
1908 if (pwq->pool != locked_pool) {
1909 raw_spin_unlock(&locked_pool->lock);
1910 locked_pool = pwq->pool;
1911 if (!raw_spin_trylock(&locked_pool->lock)) {
1912 raw_spin_unlock(&nna->lock);
1913 raw_spin_lock(&locked_pool->lock);
1914 raw_spin_lock(&nna->lock);
1915 goto retry;
1916 }
1917 }
1918
1919 /*
1920 * $pwq may not have any inactive work items due to e.g. cancellations.
1921 * Drop it from pending_pwqs and see if there's another one.
1922 */
1923 work = list_first_entry_or_null(&pwq->inactive_works,
1924 struct work_struct, entry);
1925 if (!work) {
1926 list_del_init(&pwq->pending_node);
1927 goto retry;
1928 }
1929
1930 /*
1931 * Acquire an nr_active count and activate the inactive work item. If
1932 * $pwq still has inactive work items, rotate it to the end of the
1933 * pending_pwqs so that we round-robin through them. This means that
1934 * inactive work items are not activated in queueing order which is fine
1935 * given that there has never been any ordering across different pwqs.
1936 */
1937 if (likely(tryinc_node_nr_active(nna))) {
1938 pwq->nr_active++;
1939 __pwq_activate_work(pwq, work);
1940
1941 if (list_empty(&pwq->inactive_works))
1942 list_del_init(&pwq->pending_node);
1943 else
1944 list_move_tail(&pwq->pending_node, &nna->pending_pwqs);
1945
1946 /* if activating a foreign pool, make sure it's running */
1947 if (pwq->pool != caller_pool)
1948 kick_pool(pwq->pool);
1949 }
1950
1951out_unlock:
1952 raw_spin_unlock(&nna->lock);
1953 if (locked_pool != caller_pool) {
1954 raw_spin_unlock(&locked_pool->lock);
1955 raw_spin_lock(&caller_pool->lock);
1956 }
1957}
1958
1959/**
1960 * pwq_dec_nr_active - Retire an active count
1961 * @pwq: pool_workqueue of interest
1962 *
1963 * Decrement @pwq's nr_active and try to activate the first inactive work item.
1964 * For unbound workqueues, this function may temporarily drop @pwq->pool->lock.
1965 */
1966static void pwq_dec_nr_active(struct pool_workqueue *pwq)
1967{
1968 struct worker_pool *pool = pwq->pool;
1969 struct wq_node_nr_active *nna = wq_node_nr_active(pwq->wq, pool->node);
1970
1971 lockdep_assert_held(&pool->lock);
1972
1973 /*
1974 * @pwq->nr_active should be decremented for both percpu and unbound
1975 * workqueues.
1976 */
1977 pwq->nr_active--;
1978
1979 /*
1980 * For a percpu workqueue, it's simple. Just need to kick the first
1981 * inactive work item on @pwq itself.
1982 */
1983 if (!nna) {
1984 pwq_activate_first_inactive(pwq, false);
1985 return;
1986 }
1987
1988 /*
1989 * If @pwq is for an unbound workqueue, it's more complicated because
1990 * multiple pwqs and pools may be sharing the nr_active count. When a
1991 * pwq needs to wait for an nr_active count, it puts itself on
1992 * $nna->pending_pwqs. The following atomic_dec_return()'s implied
1993 * memory barrier is paired with smp_mb() in pwq_tryinc_nr_active() to
1994 * guarantee that either we see non-empty pending_pwqs or they see
1995 * decremented $nna->nr.
1996 *
1997 * $nna->max may change as CPUs come online/offline and @pwq->wq's
1998 * max_active gets updated. However, it is guaranteed to be equal to or
1999 * larger than @pwq->wq->min_active which is above zero unless freezing.
2000 * This maintains the forward progress guarantee.
2001 */
2002 if (atomic_dec_return(&nna->nr) >= READ_ONCE(nna->max))
2003 return;
2004
2005 if (!list_empty(&nna->pending_pwqs))
2006 node_activate_pending_pwq(nna, pool);
2007}
2008
2009/**
2010 * pwq_dec_nr_in_flight - decrement pwq's nr_in_flight
2011 * @pwq: pwq of interest
2012 * @work_data: work_data of work which left the queue
2013 *
2014 * A work either has completed or is removed from pending queue,
2015 * decrement nr_in_flight of its pwq and handle workqueue flushing.
2016 *
2017 * NOTE:
2018 * For unbound workqueues, this function may temporarily drop @pwq->pool->lock
2019 * and thus should be called after all other state updates for the in-flight
2020 * work item is complete.
2021 *
2022 * CONTEXT:
2023 * raw_spin_lock_irq(pool->lock).
2024 */
2025static void pwq_dec_nr_in_flight(struct pool_workqueue *pwq, unsigned long work_data)
2026{
2027 int color = get_work_color(work_data);
2028
2029 if (!(work_data & WORK_STRUCT_INACTIVE))
2030 pwq_dec_nr_active(pwq);
2031
2032 pwq->nr_in_flight[color]--;
2033
2034 /* is flush in progress and are we at the flushing tip? */
2035 if (likely(pwq->flush_color != color))
2036 goto out_put;
2037
2038 /* are there still in-flight works? */
2039 if (pwq->nr_in_flight[color])
2040 goto out_put;
2041
2042 /* this pwq is done, clear flush_color */
2043 pwq->flush_color = -1;
2044
2045 /*
2046 * If this was the last pwq, wake up the first flusher. It
2047 * will handle the rest.
2048 */
2049 if (atomic_dec_and_test(&pwq->wq->nr_pwqs_to_flush))
2050 complete(&pwq->wq->first_flusher->done);
2051out_put:
2052 put_pwq(pwq);
2053}
2054
2055/**
2056 * try_to_grab_pending - steal work item from worklist and disable irq
2057 * @work: work item to steal
2058 * @cflags: %WORK_CANCEL_ flags
2059 * @irq_flags: place to store irq state
2060 *
2061 * Try to grab PENDING bit of @work. This function can handle @work in any
2062 * stable state - idle, on timer or on worklist.
2063 *
2064 * Return:
2065 *
2066 * ======== ================================================================
2067 * 1 if @work was pending and we successfully stole PENDING
2068 * 0 if @work was idle and we claimed PENDING
2069 * -EAGAIN if PENDING couldn't be grabbed at the moment, safe to busy-retry
2070 * -ENOENT if someone else is canceling @work, this state may persist
2071 * for arbitrarily long
2072 * ======== ================================================================
2073 *
2074 * Note:
2075 * On >= 0 return, the caller owns @work's PENDING bit. To avoid getting
2076 * interrupted while holding PENDING and @work off queue, irq must be
2077 * disabled on entry. This, combined with delayed_work->timer being
2078 * irqsafe, ensures that we return -EAGAIN for finite short period of time.
2079 *
2080 * On successful return, >= 0, irq is disabled and the caller is
2081 * responsible for releasing it using local_irq_restore(*@irq_flags).
2082 *
2083 * This function is safe to call from any context including IRQ handler.
2084 */
2085static int try_to_grab_pending(struct work_struct *work, u32 cflags,
2086 unsigned long *irq_flags)
2087{
2088 struct worker_pool *pool;
2089 struct pool_workqueue *pwq;
2090
2091 local_irq_save(*irq_flags);
2092
2093 /* try to steal the timer if it exists */
2094 if (cflags & WORK_CANCEL_DELAYED) {
2095 struct delayed_work *dwork = to_delayed_work(work);
2096
2097 /*
2098 * dwork->timer is irqsafe. If del_timer() fails, it's
2099 * guaranteed that the timer is not queued anywhere and not
2100 * running on the local CPU.
2101 */
2102 if (likely(del_timer(&dwork->timer)))
2103 return 1;
2104 }
2105
2106 /* try to claim PENDING the normal way */
2107 if (!test_and_set_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(work)))
2108 return 0;
2109
2110 rcu_read_lock();
2111 /*
2112 * The queueing is in progress, or it is already queued. Try to
2113 * steal it from ->worklist without clearing WORK_STRUCT_PENDING.
2114 */
2115 pool = get_work_pool(work);
2116 if (!pool)
2117 goto fail;
2118
2119 raw_spin_lock(&pool->lock);
2120 /*
2121 * work->data is guaranteed to point to pwq only while the work
2122 * item is queued on pwq->wq, and both updating work->data to point
2123 * to pwq on queueing and to pool on dequeueing are done under
2124 * pwq->pool->lock. This in turn guarantees that, if work->data
2125 * points to pwq which is associated with a locked pool, the work
2126 * item is currently queued on that pool.
2127 */
2128 pwq = get_work_pwq(work);
2129 if (pwq && pwq->pool == pool) {
2130 unsigned long work_data;
2131
2132 debug_work_deactivate(work);
2133
2134 /*
2135 * A cancelable inactive work item must be in the
2136 * pwq->inactive_works since a queued barrier can't be
2137 * canceled (see the comments in insert_wq_barrier()).
2138 *
2139 * An inactive work item cannot be grabbed directly because
2140 * it might have linked barrier work items which, if left
2141 * on the inactive_works list, will confuse pwq->nr_active
2142 * management later on and cause stall. Make sure the work
2143 * item is activated before grabbing.
2144 */
2145 pwq_activate_work(pwq, work);
2146
2147 list_del_init(&work->entry);
2148
2149 /*
2150 * work->data points to pwq iff queued. Let's point to pool. As
2151 * this destroys work->data needed by the next step, stash it.
2152 */
2153 work_data = *work_data_bits(work);
2154 set_work_pool_and_keep_pending(work, pool->id, 0);
2155
2156 /* must be the last step, see the function comment */
2157 pwq_dec_nr_in_flight(pwq, work_data);
2158
2159 raw_spin_unlock(&pool->lock);
2160 rcu_read_unlock();
2161 return 1;
2162 }
2163 raw_spin_unlock(&pool->lock);
2164fail:
2165 rcu_read_unlock();
2166 local_irq_restore(*irq_flags);
2167 if (work_is_canceling(work))
2168 return -ENOENT;
2169 cpu_relax();
2170 return -EAGAIN;
2171}
2172
2173struct cwt_wait {
2174 wait_queue_entry_t wait;
2175 struct work_struct *work;
2176};
2177
2178static int cwt_wakefn(wait_queue_entry_t *wait, unsigned mode, int sync, void *key)
2179{
2180 struct cwt_wait *cwait = container_of(wait, struct cwt_wait, wait);
2181
2182 if (cwait->work != key)
2183 return 0;
2184 return autoremove_wake_function(wait, mode, sync, key);
2185}
2186
2187/**
2188 * work_grab_pending - steal work item from worklist and disable irq
2189 * @work: work item to steal
2190 * @cflags: %WORK_CANCEL_ flags
2191 * @irq_flags: place to store IRQ state
2192 *
2193 * Grab PENDING bit of @work. @work can be in any stable state - idle, on timer
2194 * or on worklist.
2195 *
2196 * Must be called in process context. IRQ is disabled on return with IRQ state
2197 * stored in *@irq_flags. The caller is responsible for re-enabling it using
2198 * local_irq_restore().
2199 *
2200 * Returns %true if @work was pending. %false if idle.
2201 */
2202static bool work_grab_pending(struct work_struct *work, u32 cflags,
2203 unsigned long *irq_flags)
2204{
2205 struct cwt_wait cwait;
2206 int ret;
2207
2208 might_sleep();
2209repeat:
2210 ret = try_to_grab_pending(work, cflags, irq_flags);
2211 if (likely(ret >= 0))
2212 return ret;
2213 if (ret != -ENOENT)
2214 goto repeat;
2215
2216 /*
2217 * Someone is already canceling. Wait for it to finish. flush_work()
2218 * doesn't work for PREEMPT_NONE because we may get woken up between
2219 * @work's completion and the other canceling task resuming and clearing
2220 * CANCELING - flush_work() will return false immediately as @work is no
2221 * longer busy, try_to_grab_pending() will return -ENOENT as @work is
2222 * still being canceled and the other canceling task won't be able to
2223 * clear CANCELING as we're hogging the CPU.
2224 *
2225 * Let's wait for completion using a waitqueue. As this may lead to the
2226 * thundering herd problem, use a custom wake function which matches
2227 * @work along with exclusive wait and wakeup.
2228 */
2229 init_wait(&cwait.wait);
2230 cwait.wait.func = cwt_wakefn;
2231 cwait.work = work;
2232
2233 prepare_to_wait_exclusive(&wq_cancel_waitq, &cwait.wait,
2234 TASK_UNINTERRUPTIBLE);
2235 if (work_is_canceling(work))
2236 schedule();
2237 finish_wait(&wq_cancel_waitq, &cwait.wait);
2238
2239 goto repeat;
2240}
2241
2242/**
2243 * insert_work - insert a work into a pool
2244 * @pwq: pwq @work belongs to
2245 * @work: work to insert
2246 * @head: insertion point
2247 * @extra_flags: extra WORK_STRUCT_* flags to set
2248 *
2249 * Insert @work which belongs to @pwq after @head. @extra_flags is or'd to
2250 * work_struct flags.
2251 *
2252 * CONTEXT:
2253 * raw_spin_lock_irq(pool->lock).
2254 */
2255static void insert_work(struct pool_workqueue *pwq, struct work_struct *work,
2256 struct list_head *head, unsigned int extra_flags)
2257{
2258 debug_work_activate(work);
2259
2260 /* record the work call stack in order to print it in KASAN reports */
2261 kasan_record_aux_stack_noalloc(work);
2262
2263 /* we own @work, set data and link */
2264 set_work_pwq(work, pwq, extra_flags);
2265 list_add_tail(&work->entry, head);
2266 get_pwq(pwq);
2267}
2268
2269/*
2270 * Test whether @work is being queued from another work executing on the
2271 * same workqueue.
2272 */
2273static bool is_chained_work(struct workqueue_struct *wq)
2274{
2275 struct worker *worker;
2276
2277 worker = current_wq_worker();
2278 /*
2279 * Return %true iff I'm a worker executing a work item on @wq. If
2280 * I'm @worker, it's safe to dereference it without locking.
2281 */
2282 return worker && worker->current_pwq->wq == wq;
2283}
2284
2285/*
2286 * When queueing an unbound work item to a wq, prefer local CPU if allowed
2287 * by wq_unbound_cpumask. Otherwise, round robin among the allowed ones to
2288 * avoid perturbing sensitive tasks.
2289 */
2290static int wq_select_unbound_cpu(int cpu)
2291{
2292 int new_cpu;
2293
2294 if (likely(!wq_debug_force_rr_cpu)) {
2295 if (cpumask_test_cpu(cpu, wq_unbound_cpumask))
2296 return cpu;
2297 } else {
2298 pr_warn_once("workqueue: round-robin CPU selection forced, expect performance impact\n");
2299 }
2300
2301 new_cpu = __this_cpu_read(wq_rr_cpu_last);
2302 new_cpu = cpumask_next_and(new_cpu, wq_unbound_cpumask, cpu_online_mask);
2303 if (unlikely(new_cpu >= nr_cpu_ids)) {
2304 new_cpu = cpumask_first_and(wq_unbound_cpumask, cpu_online_mask);
2305 if (unlikely(new_cpu >= nr_cpu_ids))
2306 return cpu;
2307 }
2308 __this_cpu_write(wq_rr_cpu_last, new_cpu);
2309
2310 return new_cpu;
2311}
2312
2313static void __queue_work(int cpu, struct workqueue_struct *wq,
2314 struct work_struct *work)
2315{
2316 struct pool_workqueue *pwq;
2317 struct worker_pool *last_pool, *pool;
2318 unsigned int work_flags;
2319 unsigned int req_cpu = cpu;
2320
2321 /*
2322 * While a work item is PENDING && off queue, a task trying to
2323 * steal the PENDING will busy-loop waiting for it to either get
2324 * queued or lose PENDING. Grabbing PENDING and queueing should
2325 * happen with IRQ disabled.
2326 */
2327 lockdep_assert_irqs_disabled();
2328
2329 /*
2330 * For a draining wq, only works from the same workqueue are
2331 * allowed. The __WQ_DESTROYING helps to spot the issue that
2332 * queues a new work item to a wq after destroy_workqueue(wq).
2333 */
2334 if (unlikely(wq->flags & (__WQ_DESTROYING | __WQ_DRAINING) &&
2335 WARN_ON_ONCE(!is_chained_work(wq))))
2336 return;
2337 rcu_read_lock();
2338retry:
2339 /* pwq which will be used unless @work is executing elsewhere */
2340 if (req_cpu == WORK_CPU_UNBOUND) {
2341 if (wq->flags & WQ_UNBOUND)
2342 cpu = wq_select_unbound_cpu(raw_smp_processor_id());
2343 else
2344 cpu = raw_smp_processor_id();
2345 }
2346
2347 pwq = rcu_dereference(*per_cpu_ptr(wq->cpu_pwq, cpu));
2348 pool = pwq->pool;
2349
2350 /*
2351 * If @work was previously on a different pool, it might still be
2352 * running there, in which case the work needs to be queued on that
2353 * pool to guarantee non-reentrancy.
2354 */
2355 last_pool = get_work_pool(work);
2356 if (last_pool && last_pool != pool) {
2357 struct worker *worker;
2358
2359 raw_spin_lock(&last_pool->lock);
2360
2361 worker = find_worker_executing_work(last_pool, work);
2362
2363 if (worker && worker->current_pwq->wq == wq) {
2364 pwq = worker->current_pwq;
2365 pool = pwq->pool;
2366 WARN_ON_ONCE(pool != last_pool);
2367 } else {
2368 /* meh... not running there, queue here */
2369 raw_spin_unlock(&last_pool->lock);
2370 raw_spin_lock(&pool->lock);
2371 }
2372 } else {
2373 raw_spin_lock(&pool->lock);
2374 }
2375
2376 /*
2377 * pwq is determined and locked. For unbound pools, we could have raced
2378 * with pwq release and it could already be dead. If its refcnt is zero,
2379 * repeat pwq selection. Note that unbound pwqs never die without
2380 * another pwq replacing it in cpu_pwq or while work items are executing
2381 * on it, so the retrying is guaranteed to make forward-progress.
2382 */
2383 if (unlikely(!pwq->refcnt)) {
2384 if (wq->flags & WQ_UNBOUND) {
2385 raw_spin_unlock(&pool->lock);
2386 cpu_relax();
2387 goto retry;
2388 }
2389 /* oops */
2390 WARN_ONCE(true, "workqueue: per-cpu pwq for %s on cpu%d has 0 refcnt",
2391 wq->name, cpu);
2392 }
2393
2394 /* pwq determined, queue */
2395 trace_workqueue_queue_work(req_cpu, pwq, work);
2396
2397 if (WARN_ON(!list_empty(&work->entry)))
2398 goto out;
2399
2400 pwq->nr_in_flight[pwq->work_color]++;
2401 work_flags = work_color_to_flags(pwq->work_color);
2402
2403 /*
2404 * Limit the number of concurrently active work items to max_active.
2405 * @work must also queue behind existing inactive work items to maintain
2406 * ordering when max_active changes. See wq_adjust_max_active().
2407 */
2408 if (list_empty(&pwq->inactive_works) && pwq_tryinc_nr_active(pwq, false)) {
2409 if (list_empty(&pool->worklist))
2410 pool->watchdog_ts = jiffies;
2411
2412 trace_workqueue_activate_work(work);
2413 insert_work(pwq, work, &pool->worklist, work_flags);
2414 kick_pool(pool);
2415 } else {
2416 work_flags |= WORK_STRUCT_INACTIVE;
2417 insert_work(pwq, work, &pwq->inactive_works, work_flags);
2418 }
2419
2420out:
2421 raw_spin_unlock(&pool->lock);
2422 rcu_read_unlock();
2423}
2424
2425/**
2426 * queue_work_on - queue work on specific cpu
2427 * @cpu: CPU number to execute work on
2428 * @wq: workqueue to use
2429 * @work: work to queue
2430 *
2431 * We queue the work to a specific CPU, the caller must ensure it
2432 * can't go away. Callers that fail to ensure that the specified
2433 * CPU cannot go away will execute on a randomly chosen CPU.
2434 * But note well that callers specifying a CPU that never has been
2435 * online will get a splat.
2436 *
2437 * Return: %false if @work was already on a queue, %true otherwise.
2438 */
2439bool queue_work_on(int cpu, struct workqueue_struct *wq,
2440 struct work_struct *work)
2441{
2442 bool ret = false;
2443 unsigned long irq_flags;
2444
2445 local_irq_save(irq_flags);
2446
2447 if (!test_and_set_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(work))) {
2448 __queue_work(cpu, wq, work);
2449 ret = true;
2450 }
2451
2452 local_irq_restore(irq_flags);
2453 return ret;
2454}
2455EXPORT_SYMBOL(queue_work_on);
2456
2457/**
2458 * select_numa_node_cpu - Select a CPU based on NUMA node
2459 * @node: NUMA node ID that we want to select a CPU from
2460 *
2461 * This function will attempt to find a "random" cpu available on a given
2462 * node. If there are no CPUs available on the given node it will return
2463 * WORK_CPU_UNBOUND indicating that we should just schedule to any
2464 * available CPU if we need to schedule this work.
2465 */
2466static int select_numa_node_cpu(int node)
2467{
2468 int cpu;
2469
2470 /* Delay binding to CPU if node is not valid or online */
2471 if (node < 0 || node >= MAX_NUMNODES || !node_online(node))
2472 return WORK_CPU_UNBOUND;
2473
2474 /* Use local node/cpu if we are already there */
2475 cpu = raw_smp_processor_id();
2476 if (node == cpu_to_node(cpu))
2477 return cpu;
2478
2479 /* Use "random" otherwise know as "first" online CPU of node */
2480 cpu = cpumask_any_and(cpumask_of_node(node), cpu_online_mask);
2481
2482 /* If CPU is valid return that, otherwise just defer */
2483 return cpu < nr_cpu_ids ? cpu : WORK_CPU_UNBOUND;
2484}
2485
2486/**
2487 * queue_work_node - queue work on a "random" cpu for a given NUMA node
2488 * @node: NUMA node that we are targeting the work for
2489 * @wq: workqueue to use
2490 * @work: work to queue
2491 *
2492 * We queue the work to a "random" CPU within a given NUMA node. The basic
2493 * idea here is to provide a way to somehow associate work with a given
2494 * NUMA node.
2495 *
2496 * This function will only make a best effort attempt at getting this onto
2497 * the right NUMA node. If no node is requested or the requested node is
2498 * offline then we just fall back to standard queue_work behavior.
2499 *
2500 * Currently the "random" CPU ends up being the first available CPU in the
2501 * intersection of cpu_online_mask and the cpumask of the node, unless we
2502 * are running on the node. In that case we just use the current CPU.
2503 *
2504 * Return: %false if @work was already on a queue, %true otherwise.
2505 */
2506bool queue_work_node(int node, struct workqueue_struct *wq,
2507 struct work_struct *work)
2508{
2509 unsigned long irq_flags;
2510 bool ret = false;
2511
2512 /*
2513 * This current implementation is specific to unbound workqueues.
2514 * Specifically we only return the first available CPU for a given
2515 * node instead of cycling through individual CPUs within the node.
2516 *
2517 * If this is used with a per-cpu workqueue then the logic in
2518 * workqueue_select_cpu_near would need to be updated to allow for
2519 * some round robin type logic.
2520 */
2521 WARN_ON_ONCE(!(wq->flags & WQ_UNBOUND));
2522
2523 local_irq_save(irq_flags);
2524
2525 if (!test_and_set_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(work))) {
2526 int cpu = select_numa_node_cpu(node);
2527
2528 __queue_work(cpu, wq, work);
2529 ret = true;
2530 }
2531
2532 local_irq_restore(irq_flags);
2533 return ret;
2534}
2535EXPORT_SYMBOL_GPL(queue_work_node);
2536
2537void delayed_work_timer_fn(struct timer_list *t)
2538{
2539 struct delayed_work *dwork = from_timer(dwork, t, timer);
2540
2541 /* should have been called from irqsafe timer with irq already off */
2542 __queue_work(dwork->cpu, dwork->wq, &dwork->work);
2543}
2544EXPORT_SYMBOL(delayed_work_timer_fn);
2545
2546static void __queue_delayed_work(int cpu, struct workqueue_struct *wq,
2547 struct delayed_work *dwork, unsigned long delay)
2548{
2549 struct timer_list *timer = &dwork->timer;
2550 struct work_struct *work = &dwork->work;
2551
2552 WARN_ON_ONCE(!wq);
2553 WARN_ON_ONCE(timer->function != delayed_work_timer_fn);
2554 WARN_ON_ONCE(timer_pending(timer));
2555 WARN_ON_ONCE(!list_empty(&work->entry));
2556
2557 /*
2558 * If @delay is 0, queue @dwork->work immediately. This is for
2559 * both optimization and correctness. The earliest @timer can
2560 * expire is on the closest next tick and delayed_work users depend
2561 * on that there's no such delay when @delay is 0.
2562 */
2563 if (!delay) {
2564 __queue_work(cpu, wq, &dwork->work);
2565 return;
2566 }
2567
2568 dwork->wq = wq;
2569 dwork->cpu = cpu;
2570 timer->expires = jiffies + delay;
2571
2572 if (housekeeping_enabled(HK_TYPE_TIMER)) {
2573 /* If the current cpu is a housekeeping cpu, use it. */
2574 cpu = smp_processor_id();
2575 if (!housekeeping_test_cpu(cpu, HK_TYPE_TIMER))
2576 cpu = housekeeping_any_cpu(HK_TYPE_TIMER);
2577 add_timer_on(timer, cpu);
2578 } else {
2579 if (likely(cpu == WORK_CPU_UNBOUND))
2580 add_timer_global(timer);
2581 else
2582 add_timer_on(timer, cpu);
2583 }
2584}
2585
2586/**
2587 * queue_delayed_work_on - queue work on specific CPU after delay
2588 * @cpu: CPU number to execute work on
2589 * @wq: workqueue to use
2590 * @dwork: work to queue
2591 * @delay: number of jiffies to wait before queueing
2592 *
2593 * Return: %false if @work was already on a queue, %true otherwise. If
2594 * @delay is zero and @dwork is idle, it will be scheduled for immediate
2595 * execution.
2596 */
2597bool queue_delayed_work_on(int cpu, struct workqueue_struct *wq,
2598 struct delayed_work *dwork, unsigned long delay)
2599{
2600 struct work_struct *work = &dwork->work;
2601 bool ret = false;
2602 unsigned long irq_flags;
2603
2604 /* read the comment in __queue_work() */
2605 local_irq_save(irq_flags);
2606
2607 if (!test_and_set_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(work))) {
2608 __queue_delayed_work(cpu, wq, dwork, delay);
2609 ret = true;
2610 }
2611
2612 local_irq_restore(irq_flags);
2613 return ret;
2614}
2615EXPORT_SYMBOL(queue_delayed_work_on);
2616
2617/**
2618 * mod_delayed_work_on - modify delay of or queue a delayed work on specific CPU
2619 * @cpu: CPU number to execute work on
2620 * @wq: workqueue to use
2621 * @dwork: work to queue
2622 * @delay: number of jiffies to wait before queueing
2623 *
2624 * If @dwork is idle, equivalent to queue_delayed_work_on(); otherwise,
2625 * modify @dwork's timer so that it expires after @delay. If @delay is
2626 * zero, @work is guaranteed to be scheduled immediately regardless of its
2627 * current state.
2628 *
2629 * Return: %false if @dwork was idle and queued, %true if @dwork was
2630 * pending and its timer was modified.
2631 *
2632 * This function is safe to call from any context including IRQ handler.
2633 * See try_to_grab_pending() for details.
2634 */
2635bool mod_delayed_work_on(int cpu, struct workqueue_struct *wq,
2636 struct delayed_work *dwork, unsigned long delay)
2637{
2638 unsigned long irq_flags;
2639 int ret;
2640
2641 do {
2642 ret = try_to_grab_pending(&dwork->work, WORK_CANCEL_DELAYED,
2643 &irq_flags);
2644 } while (unlikely(ret == -EAGAIN));
2645
2646 if (likely(ret >= 0)) {
2647 __queue_delayed_work(cpu, wq, dwork, delay);
2648 local_irq_restore(irq_flags);
2649 }
2650
2651 /* -ENOENT from try_to_grab_pending() becomes %true */
2652 return ret;
2653}
2654EXPORT_SYMBOL_GPL(mod_delayed_work_on);
2655
2656static void rcu_work_rcufn(struct rcu_head *rcu)
2657{
2658 struct rcu_work *rwork = container_of(rcu, struct rcu_work, rcu);
2659
2660 /* read the comment in __queue_work() */
2661 local_irq_disable();
2662 __queue_work(WORK_CPU_UNBOUND, rwork->wq, &rwork->work);
2663 local_irq_enable();
2664}
2665
2666/**
2667 * queue_rcu_work - queue work after a RCU grace period
2668 * @wq: workqueue to use
2669 * @rwork: work to queue
2670 *
2671 * Return: %false if @rwork was already pending, %true otherwise. Note
2672 * that a full RCU grace period is guaranteed only after a %true return.
2673 * While @rwork is guaranteed to be executed after a %false return, the
2674 * execution may happen before a full RCU grace period has passed.
2675 */
2676bool queue_rcu_work(struct workqueue_struct *wq, struct rcu_work *rwork)
2677{
2678 struct work_struct *work = &rwork->work;
2679
2680 if (!test_and_set_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(work))) {
2681 rwork->wq = wq;
2682 call_rcu_hurry(&rwork->rcu, rcu_work_rcufn);
2683 return true;
2684 }
2685
2686 return false;
2687}
2688EXPORT_SYMBOL(queue_rcu_work);
2689
2690static struct worker *alloc_worker(int node)
2691{
2692 struct worker *worker;
2693
2694 worker = kzalloc_node(sizeof(*worker), GFP_KERNEL, node);
2695 if (worker) {
2696 INIT_LIST_HEAD(&worker->entry);
2697 INIT_LIST_HEAD(&worker->scheduled);
2698 INIT_LIST_HEAD(&worker->node);
2699 /* on creation a worker is in !idle && prep state */
2700 worker->flags = WORKER_PREP;
2701 }
2702 return worker;
2703}
2704
2705static cpumask_t *pool_allowed_cpus(struct worker_pool *pool)
2706{
2707 if (pool->cpu < 0 && pool->attrs->affn_strict)
2708 return pool->attrs->__pod_cpumask;
2709 else
2710 return pool->attrs->cpumask;
2711}
2712
2713/**
2714 * worker_attach_to_pool() - attach a worker to a pool
2715 * @worker: worker to be attached
2716 * @pool: the target pool
2717 *
2718 * Attach @worker to @pool. Once attached, the %WORKER_UNBOUND flag and
2719 * cpu-binding of @worker are kept coordinated with the pool across
2720 * cpu-[un]hotplugs.
2721 */
2722static void worker_attach_to_pool(struct worker *worker,
2723 struct worker_pool *pool)
2724{
2725 mutex_lock(&wq_pool_attach_mutex);
2726
2727 /*
2728 * The wq_pool_attach_mutex ensures %POOL_DISASSOCIATED remains stable
2729 * across this function. See the comments above the flag definition for
2730 * details. BH workers are, while per-CPU, always DISASSOCIATED.
2731 */
2732 if (pool->flags & POOL_DISASSOCIATED) {
2733 worker->flags |= WORKER_UNBOUND;
2734 } else {
2735 WARN_ON_ONCE(pool->flags & POOL_BH);
2736 kthread_set_per_cpu(worker->task, pool->cpu);
2737 }
2738
2739 if (worker->rescue_wq)
2740 set_cpus_allowed_ptr(worker->task, pool_allowed_cpus(pool));
2741
2742 list_add_tail(&worker->node, &pool->workers);
2743 worker->pool = pool;
2744
2745 mutex_unlock(&wq_pool_attach_mutex);
2746}
2747
2748/**
2749 * worker_detach_from_pool() - detach a worker from its pool
2750 * @worker: worker which is attached to its pool
2751 *
2752 * Undo the attaching which had been done in worker_attach_to_pool(). The
2753 * caller worker shouldn't access to the pool after detached except it has
2754 * other reference to the pool.
2755 */
2756static void worker_detach_from_pool(struct worker *worker)
2757{
2758 struct worker_pool *pool = worker->pool;
2759 struct completion *detach_completion = NULL;
2760
2761 /* there is one permanent BH worker per CPU which should never detach */
2762 WARN_ON_ONCE(pool->flags & POOL_BH);
2763
2764 mutex_lock(&wq_pool_attach_mutex);
2765
2766 kthread_set_per_cpu(worker->task, -1);
2767 list_del(&worker->node);
2768 worker->pool = NULL;
2769
2770 if (list_empty(&pool->workers) && list_empty(&pool->dying_workers))
2771 detach_completion = pool->detach_completion;
2772 mutex_unlock(&wq_pool_attach_mutex);
2773
2774 /* clear leftover flags without pool->lock after it is detached */
2775 worker->flags &= ~(WORKER_UNBOUND | WORKER_REBOUND);
2776
2777 if (detach_completion)
2778 complete(detach_completion);
2779}
2780
2781/**
2782 * create_worker - create a new workqueue worker
2783 * @pool: pool the new worker will belong to
2784 *
2785 * Create and start a new worker which is attached to @pool.
2786 *
2787 * CONTEXT:
2788 * Might sleep. Does GFP_KERNEL allocations.
2789 *
2790 * Return:
2791 * Pointer to the newly created worker.
2792 */
2793static struct worker *create_worker(struct worker_pool *pool)
2794{
2795 struct worker *worker;
2796 int id;
2797 char id_buf[23];
2798
2799 /* ID is needed to determine kthread name */
2800 id = ida_alloc(&pool->worker_ida, GFP_KERNEL);
2801 if (id < 0) {
2802 pr_err_once("workqueue: Failed to allocate a worker ID: %pe\n",
2803 ERR_PTR(id));
2804 return NULL;
2805 }
2806
2807 worker = alloc_worker(pool->node);
2808 if (!worker) {
2809 pr_err_once("workqueue: Failed to allocate a worker\n");
2810 goto fail;
2811 }
2812
2813 worker->id = id;
2814
2815 if (!(pool->flags & POOL_BH)) {
2816 if (pool->cpu >= 0)
2817 snprintf(id_buf, sizeof(id_buf), "%d:%d%s", pool->cpu, id,
2818 pool->attrs->nice < 0 ? "H" : "");
2819 else
2820 snprintf(id_buf, sizeof(id_buf), "u%d:%d", pool->id, id);
2821
2822 worker->task = kthread_create_on_node(worker_thread, worker,
2823 pool->node, "kworker/%s", id_buf);
2824 if (IS_ERR(worker->task)) {
2825 if (PTR_ERR(worker->task) == -EINTR) {
2826 pr_err("workqueue: Interrupted when creating a worker thread \"kworker/%s\"\n",
2827 id_buf);
2828 } else {
2829 pr_err_once("workqueue: Failed to create a worker thread: %pe",
2830 worker->task);
2831 }
2832 goto fail;
2833 }
2834
2835 set_user_nice(worker->task, pool->attrs->nice);
2836 kthread_bind_mask(worker->task, pool_allowed_cpus(pool));
2837 }
2838
2839 /* successful, attach the worker to the pool */
2840 worker_attach_to_pool(worker, pool);
2841
2842 /* start the newly created worker */
2843 raw_spin_lock_irq(&pool->lock);
2844
2845 worker->pool->nr_workers++;
2846 worker_enter_idle(worker);
2847
2848 /*
2849 * @worker is waiting on a completion in kthread() and will trigger hung
2850 * check if not woken up soon. As kick_pool() is noop if @pool is empty,
2851 * wake it up explicitly.
2852 */
2853 if (worker->task)
2854 wake_up_process(worker->task);
2855
2856 raw_spin_unlock_irq(&pool->lock);
2857
2858 return worker;
2859
2860fail:
2861 ida_free(&pool->worker_ida, id);
2862 kfree(worker);
2863 return NULL;
2864}
2865
2866static void unbind_worker(struct worker *worker)
2867{
2868 lockdep_assert_held(&wq_pool_attach_mutex);
2869
2870 kthread_set_per_cpu(worker->task, -1);
2871 if (cpumask_intersects(wq_unbound_cpumask, cpu_active_mask))
2872 WARN_ON_ONCE(set_cpus_allowed_ptr(worker->task, wq_unbound_cpumask) < 0);
2873 else
2874 WARN_ON_ONCE(set_cpus_allowed_ptr(worker->task, cpu_possible_mask) < 0);
2875}
2876
2877static void wake_dying_workers(struct list_head *cull_list)
2878{
2879 struct worker *worker, *tmp;
2880
2881 list_for_each_entry_safe(worker, tmp, cull_list, entry) {
2882 list_del_init(&worker->entry);
2883 unbind_worker(worker);
2884 /*
2885 * If the worker was somehow already running, then it had to be
2886 * in pool->idle_list when set_worker_dying() happened or we
2887 * wouldn't have gotten here.
2888 *
2889 * Thus, the worker must either have observed the WORKER_DIE
2890 * flag, or have set its state to TASK_IDLE. Either way, the
2891 * below will be observed by the worker and is safe to do
2892 * outside of pool->lock.
2893 */
2894 wake_up_process(worker->task);
2895 }
2896}
2897
2898/**
2899 * set_worker_dying - Tag a worker for destruction
2900 * @worker: worker to be destroyed
2901 * @list: transfer worker away from its pool->idle_list and into list
2902 *
2903 * Tag @worker for destruction and adjust @pool stats accordingly. The worker
2904 * should be idle.
2905 *
2906 * CONTEXT:
2907 * raw_spin_lock_irq(pool->lock).
2908 */
2909static void set_worker_dying(struct worker *worker, struct list_head *list)
2910{
2911 struct worker_pool *pool = worker->pool;
2912
2913 lockdep_assert_held(&pool->lock);
2914 lockdep_assert_held(&wq_pool_attach_mutex);
2915
2916 /* sanity check frenzy */
2917 if (WARN_ON(worker->current_work) ||
2918 WARN_ON(!list_empty(&worker->scheduled)) ||
2919 WARN_ON(!(worker->flags & WORKER_IDLE)))
2920 return;
2921
2922 pool->nr_workers--;
2923 pool->nr_idle--;
2924
2925 worker->flags |= WORKER_DIE;
2926
2927 list_move(&worker->entry, list);
2928 list_move(&worker->node, &pool->dying_workers);
2929}
2930
2931/**
2932 * idle_worker_timeout - check if some idle workers can now be deleted.
2933 * @t: The pool's idle_timer that just expired
2934 *
2935 * The timer is armed in worker_enter_idle(). Note that it isn't disarmed in
2936 * worker_leave_idle(), as a worker flicking between idle and active while its
2937 * pool is at the too_many_workers() tipping point would cause too much timer
2938 * housekeeping overhead. Since IDLE_WORKER_TIMEOUT is long enough, we just let
2939 * it expire and re-evaluate things from there.
2940 */
2941static void idle_worker_timeout(struct timer_list *t)
2942{
2943 struct worker_pool *pool = from_timer(pool, t, idle_timer);
2944 bool do_cull = false;
2945
2946 if (work_pending(&pool->idle_cull_work))
2947 return;
2948
2949 raw_spin_lock_irq(&pool->lock);
2950
2951 if (too_many_workers(pool)) {
2952 struct worker *worker;
2953 unsigned long expires;
2954
2955 /* idle_list is kept in LIFO order, check the last one */
2956 worker = list_entry(pool->idle_list.prev, struct worker, entry);
2957 expires = worker->last_active + IDLE_WORKER_TIMEOUT;
2958 do_cull = !time_before(jiffies, expires);
2959
2960 if (!do_cull)
2961 mod_timer(&pool->idle_timer, expires);
2962 }
2963 raw_spin_unlock_irq(&pool->lock);
2964
2965 if (do_cull)
2966 queue_work(system_unbound_wq, &pool->idle_cull_work);
2967}
2968
2969/**
2970 * idle_cull_fn - cull workers that have been idle for too long.
2971 * @work: the pool's work for handling these idle workers
2972 *
2973 * This goes through a pool's idle workers and gets rid of those that have been
2974 * idle for at least IDLE_WORKER_TIMEOUT seconds.
2975 *
2976 * We don't want to disturb isolated CPUs because of a pcpu kworker being
2977 * culled, so this also resets worker affinity. This requires a sleepable
2978 * context, hence the split between timer callback and work item.
2979 */
2980static void idle_cull_fn(struct work_struct *work)
2981{
2982 struct worker_pool *pool = container_of(work, struct worker_pool, idle_cull_work);
2983 LIST_HEAD(cull_list);
2984
2985 /*
2986 * Grabbing wq_pool_attach_mutex here ensures an already-running worker
2987 * cannot proceed beyong worker_detach_from_pool() in its self-destruct
2988 * path. This is required as a previously-preempted worker could run after
2989 * set_worker_dying() has happened but before wake_dying_workers() did.
2990 */
2991 mutex_lock(&wq_pool_attach_mutex);
2992 raw_spin_lock_irq(&pool->lock);
2993
2994 while (too_many_workers(pool)) {
2995 struct worker *worker;
2996 unsigned long expires;
2997
2998 worker = list_entry(pool->idle_list.prev, struct worker, entry);
2999 expires = worker->last_active + IDLE_WORKER_TIMEOUT;
3000
3001 if (time_before(jiffies, expires)) {
3002 mod_timer(&pool->idle_timer, expires);
3003 break;
3004 }
3005
3006 set_worker_dying(worker, &cull_list);
3007 }
3008
3009 raw_spin_unlock_irq(&pool->lock);
3010 wake_dying_workers(&cull_list);
3011 mutex_unlock(&wq_pool_attach_mutex);
3012}
3013
3014static void send_mayday(struct work_struct *work)
3015{
3016 struct pool_workqueue *pwq = get_work_pwq(work);
3017 struct workqueue_struct *wq = pwq->wq;
3018
3019 lockdep_assert_held(&wq_mayday_lock);
3020
3021 if (!wq->rescuer)
3022 return;
3023
3024 /* mayday mayday mayday */
3025 if (list_empty(&pwq->mayday_node)) {
3026 /*
3027 * If @pwq is for an unbound wq, its base ref may be put at
3028 * any time due to an attribute change. Pin @pwq until the
3029 * rescuer is done with it.
3030 */
3031 get_pwq(pwq);
3032 list_add_tail(&pwq->mayday_node, &wq->maydays);
3033 wake_up_process(wq->rescuer->task);
3034 pwq->stats[PWQ_STAT_MAYDAY]++;
3035 }
3036}
3037
3038static void pool_mayday_timeout(struct timer_list *t)
3039{
3040 struct worker_pool *pool = from_timer(pool, t, mayday_timer);
3041 struct work_struct *work;
3042
3043 raw_spin_lock_irq(&pool->lock);
3044 raw_spin_lock(&wq_mayday_lock); /* for wq->maydays */
3045
3046 if (need_to_create_worker(pool)) {
3047 /*
3048 * We've been trying to create a new worker but
3049 * haven't been successful. We might be hitting an
3050 * allocation deadlock. Send distress signals to
3051 * rescuers.
3052 */
3053 list_for_each_entry(work, &pool->worklist, entry)
3054 send_mayday(work);
3055 }
3056
3057 raw_spin_unlock(&wq_mayday_lock);
3058 raw_spin_unlock_irq(&pool->lock);
3059
3060 mod_timer(&pool->mayday_timer, jiffies + MAYDAY_INTERVAL);
3061}
3062
3063/**
3064 * maybe_create_worker - create a new worker if necessary
3065 * @pool: pool to create a new worker for
3066 *
3067 * Create a new worker for @pool if necessary. @pool is guaranteed to
3068 * have at least one idle worker on return from this function. If
3069 * creating a new worker takes longer than MAYDAY_INTERVAL, mayday is
3070 * sent to all rescuers with works scheduled on @pool to resolve
3071 * possible allocation deadlock.
3072 *
3073 * On return, need_to_create_worker() is guaranteed to be %false and
3074 * may_start_working() %true.
3075 *
3076 * LOCKING:
3077 * raw_spin_lock_irq(pool->lock) which may be released and regrabbed
3078 * multiple times. Does GFP_KERNEL allocations. Called only from
3079 * manager.
3080 */
3081static void maybe_create_worker(struct worker_pool *pool)
3082__releases(&pool->lock)
3083__acquires(&pool->lock)
3084{
3085restart:
3086 raw_spin_unlock_irq(&pool->lock);
3087
3088 /* if we don't make progress in MAYDAY_INITIAL_TIMEOUT, call for help */
3089 mod_timer(&pool->mayday_timer, jiffies + MAYDAY_INITIAL_TIMEOUT);
3090
3091 while (true) {
3092 if (create_worker(pool) || !need_to_create_worker(pool))
3093 break;
3094
3095 schedule_timeout_interruptible(CREATE_COOLDOWN);
3096
3097 if (!need_to_create_worker(pool))
3098 break;
3099 }
3100
3101 del_timer_sync(&pool->mayday_timer);
3102 raw_spin_lock_irq(&pool->lock);
3103 /*
3104 * This is necessary even after a new worker was just successfully
3105 * created as @pool->lock was dropped and the new worker might have
3106 * already become busy.
3107 */
3108 if (need_to_create_worker(pool))
3109 goto restart;
3110}
3111
3112/**
3113 * manage_workers - manage worker pool
3114 * @worker: self
3115 *
3116 * Assume the manager role and manage the worker pool @worker belongs
3117 * to. At any given time, there can be only zero or one manager per
3118 * pool. The exclusion is handled automatically by this function.
3119 *
3120 * The caller can safely start processing works on false return. On
3121 * true return, it's guaranteed that need_to_create_worker() is false
3122 * and may_start_working() is true.
3123 *
3124 * CONTEXT:
3125 * raw_spin_lock_irq(pool->lock) which may be released and regrabbed
3126 * multiple times. Does GFP_KERNEL allocations.
3127 *
3128 * Return:
3129 * %false if the pool doesn't need management and the caller can safely
3130 * start processing works, %true if management function was performed and
3131 * the conditions that the caller verified before calling the function may
3132 * no longer be true.
3133 */
3134static bool manage_workers(struct worker *worker)
3135{
3136 struct worker_pool *pool = worker->pool;
3137
3138 if (pool->flags & POOL_MANAGER_ACTIVE)
3139 return false;
3140
3141 pool->flags |= POOL_MANAGER_ACTIVE;
3142 pool->manager = worker;
3143
3144 maybe_create_worker(pool);
3145
3146 pool->manager = NULL;
3147 pool->flags &= ~POOL_MANAGER_ACTIVE;
3148 rcuwait_wake_up(&manager_wait);
3149 return true;
3150}
3151
3152/**
3153 * process_one_work - process single work
3154 * @worker: self
3155 * @work: work to process
3156 *
3157 * Process @work. This function contains all the logics necessary to
3158 * process a single work including synchronization against and
3159 * interaction with other workers on the same cpu, queueing and
3160 * flushing. As long as context requirement is met, any worker can
3161 * call this function to process a work.
3162 *
3163 * CONTEXT:
3164 * raw_spin_lock_irq(pool->lock) which is released and regrabbed.
3165 */
3166static void process_one_work(struct worker *worker, struct work_struct *work)
3167__releases(&pool->lock)
3168__acquires(&pool->lock)
3169{
3170 struct pool_workqueue *pwq = get_work_pwq(work);
3171 struct worker_pool *pool = worker->pool;
3172 unsigned long work_data;
3173 int lockdep_start_depth, rcu_start_depth;
3174 bool bh_draining = pool->flags & POOL_BH_DRAINING;
3175#ifdef CONFIG_LOCKDEP
3176 /*
3177 * It is permissible to free the struct work_struct from
3178 * inside the function that is called from it, this we need to
3179 * take into account for lockdep too. To avoid bogus "held
3180 * lock freed" warnings as well as problems when looking into
3181 * work->lockdep_map, make a copy and use that here.
3182 */
3183 struct lockdep_map lockdep_map;
3184
3185 lockdep_copy_map(&lockdep_map, &work->lockdep_map);
3186#endif
3187 /* ensure we're on the correct CPU */
3188 WARN_ON_ONCE(!(pool->flags & POOL_DISASSOCIATED) &&
3189 raw_smp_processor_id() != pool->cpu);
3190
3191 /* claim and dequeue */
3192 debug_work_deactivate(work);
3193 hash_add(pool->busy_hash, &worker->hentry, (unsigned long)work);
3194 worker->current_work = work;
3195 worker->current_func = work->func;
3196 worker->current_pwq = pwq;
3197 if (worker->task)
3198 worker->current_at = worker->task->se.sum_exec_runtime;
3199 work_data = *work_data_bits(work);
3200 worker->current_color = get_work_color(work_data);
3201
3202 /*
3203 * Record wq name for cmdline and debug reporting, may get
3204 * overridden through set_worker_desc().
3205 */
3206 strscpy(worker->desc, pwq->wq->name, WORKER_DESC_LEN);
3207
3208 list_del_init(&work->entry);
3209
3210 /*
3211 * CPU intensive works don't participate in concurrency management.
3212 * They're the scheduler's responsibility. This takes @worker out
3213 * of concurrency management and the next code block will chain
3214 * execution of the pending work items.
3215 */
3216 if (unlikely(pwq->wq->flags & WQ_CPU_INTENSIVE))
3217 worker_set_flags(worker, WORKER_CPU_INTENSIVE);
3218
3219 /*
3220 * Kick @pool if necessary. It's always noop for per-cpu worker pools
3221 * since nr_running would always be >= 1 at this point. This is used to
3222 * chain execution of the pending work items for WORKER_NOT_RUNNING
3223 * workers such as the UNBOUND and CPU_INTENSIVE ones.
3224 */
3225 kick_pool(pool);
3226
3227 /*
3228 * Record the last pool and clear PENDING which should be the last
3229 * update to @work. Also, do this inside @pool->lock so that
3230 * PENDING and queued state changes happen together while IRQ is
3231 * disabled.
3232 */
3233 set_work_pool_and_clear_pending(work, pool->id, 0);
3234
3235 pwq->stats[PWQ_STAT_STARTED]++;
3236 raw_spin_unlock_irq(&pool->lock);
3237
3238 rcu_start_depth = rcu_preempt_depth();
3239 lockdep_start_depth = lockdep_depth(current);
3240 /* see drain_dead_softirq_workfn() */
3241 if (!bh_draining)
3242 lock_map_acquire(&pwq->wq->lockdep_map);
3243 lock_map_acquire(&lockdep_map);
3244 /*
3245 * Strictly speaking we should mark the invariant state without holding
3246 * any locks, that is, before these two lock_map_acquire()'s.
3247 *
3248 * However, that would result in:
3249 *
3250 * A(W1)
3251 * WFC(C)
3252 * A(W1)
3253 * C(C)
3254 *
3255 * Which would create W1->C->W1 dependencies, even though there is no
3256 * actual deadlock possible. There are two solutions, using a
3257 * read-recursive acquire on the work(queue) 'locks', but this will then
3258 * hit the lockdep limitation on recursive locks, or simply discard
3259 * these locks.
3260 *
3261 * AFAICT there is no possible deadlock scenario between the
3262 * flush_work() and complete() primitives (except for single-threaded
3263 * workqueues), so hiding them isn't a problem.
3264 */
3265 lockdep_invariant_state(true);
3266 trace_workqueue_execute_start(work);
3267 worker->current_func(work);
3268 /*
3269 * While we must be careful to not use "work" after this, the trace
3270 * point will only record its address.
3271 */
3272 trace_workqueue_execute_end(work, worker->current_func);
3273 pwq->stats[PWQ_STAT_COMPLETED]++;
3274 lock_map_release(&lockdep_map);
3275 if (!bh_draining)
3276 lock_map_release(&pwq->wq->lockdep_map);
3277
3278 if (unlikely((worker->task && in_atomic()) ||
3279 lockdep_depth(current) != lockdep_start_depth ||
3280 rcu_preempt_depth() != rcu_start_depth)) {
3281 pr_err("BUG: workqueue leaked atomic, lock or RCU: %s[%d]\n"
3282 " preempt=0x%08x lock=%d->%d RCU=%d->%d workfn=%ps\n",
3283 current->comm, task_pid_nr(current), preempt_count(),
3284 lockdep_start_depth, lockdep_depth(current),
3285 rcu_start_depth, rcu_preempt_depth(),
3286 worker->current_func);
3287 debug_show_held_locks(current);
3288 dump_stack();
3289 }
3290
3291 /*
3292 * The following prevents a kworker from hogging CPU on !PREEMPTION
3293 * kernels, where a requeueing work item waiting for something to
3294 * happen could deadlock with stop_machine as such work item could
3295 * indefinitely requeue itself while all other CPUs are trapped in
3296 * stop_machine. At the same time, report a quiescent RCU state so
3297 * the same condition doesn't freeze RCU.
3298 */
3299 if (worker->task)
3300 cond_resched();
3301
3302 raw_spin_lock_irq(&pool->lock);
3303
3304 /*
3305 * In addition to %WQ_CPU_INTENSIVE, @worker may also have been marked
3306 * CPU intensive by wq_worker_tick() if @work hogged CPU longer than
3307 * wq_cpu_intensive_thresh_us. Clear it.
3308 */
3309 worker_clr_flags(worker, WORKER_CPU_INTENSIVE);
3310
3311 /* tag the worker for identification in schedule() */
3312 worker->last_func = worker->current_func;
3313
3314 /* we're done with it, release */
3315 hash_del(&worker->hentry);
3316 worker->current_work = NULL;
3317 worker->current_func = NULL;
3318 worker->current_pwq = NULL;
3319 worker->current_color = INT_MAX;
3320
3321 /* must be the last step, see the function comment */
3322 pwq_dec_nr_in_flight(pwq, work_data);
3323}
3324
3325/**
3326 * process_scheduled_works - process scheduled works
3327 * @worker: self
3328 *
3329 * Process all scheduled works. Please note that the scheduled list
3330 * may change while processing a work, so this function repeatedly
3331 * fetches a work from the top and executes it.
3332 *
3333 * CONTEXT:
3334 * raw_spin_lock_irq(pool->lock) which may be released and regrabbed
3335 * multiple times.
3336 */
3337static void process_scheduled_works(struct worker *worker)
3338{
3339 struct work_struct *work;
3340 bool first = true;
3341
3342 while ((work = list_first_entry_or_null(&worker->scheduled,
3343 struct work_struct, entry))) {
3344 if (first) {
3345 worker->pool->watchdog_ts = jiffies;
3346 first = false;
3347 }
3348 process_one_work(worker, work);
3349 }
3350}
3351
3352static void set_pf_worker(bool val)
3353{
3354 mutex_lock(&wq_pool_attach_mutex);
3355 if (val)
3356 current->flags |= PF_WQ_WORKER;
3357 else
3358 current->flags &= ~PF_WQ_WORKER;
3359 mutex_unlock(&wq_pool_attach_mutex);
3360}
3361
3362/**
3363 * worker_thread - the worker thread function
3364 * @__worker: self
3365 *
3366 * The worker thread function. All workers belong to a worker_pool -
3367 * either a per-cpu one or dynamic unbound one. These workers process all
3368 * work items regardless of their specific target workqueue. The only
3369 * exception is work items which belong to workqueues with a rescuer which
3370 * will be explained in rescuer_thread().
3371 *
3372 * Return: 0
3373 */
3374static int worker_thread(void *__worker)
3375{
3376 struct worker *worker = __worker;
3377 struct worker_pool *pool = worker->pool;
3378
3379 /* tell the scheduler that this is a workqueue worker */
3380 set_pf_worker(true);
3381woke_up:
3382 raw_spin_lock_irq(&pool->lock);
3383
3384 /* am I supposed to die? */
3385 if (unlikely(worker->flags & WORKER_DIE)) {
3386 raw_spin_unlock_irq(&pool->lock);
3387 set_pf_worker(false);
3388
3389 set_task_comm(worker->task, "kworker/dying");
3390 ida_free(&pool->worker_ida, worker->id);
3391 worker_detach_from_pool(worker);
3392 WARN_ON_ONCE(!list_empty(&worker->entry));
3393 kfree(worker);
3394 return 0;
3395 }
3396
3397 worker_leave_idle(worker);
3398recheck:
3399 /* no more worker necessary? */
3400 if (!need_more_worker(pool))
3401 goto sleep;
3402
3403 /* do we need to manage? */
3404 if (unlikely(!may_start_working(pool)) && manage_workers(worker))
3405 goto recheck;
3406
3407 /*
3408 * ->scheduled list can only be filled while a worker is
3409 * preparing to process a work or actually processing it.
3410 * Make sure nobody diddled with it while I was sleeping.
3411 */
3412 WARN_ON_ONCE(!list_empty(&worker->scheduled));
3413
3414 /*
3415 * Finish PREP stage. We're guaranteed to have at least one idle
3416 * worker or that someone else has already assumed the manager
3417 * role. This is where @worker starts participating in concurrency
3418 * management if applicable and concurrency management is restored
3419 * after being rebound. See rebind_workers() for details.
3420 */
3421 worker_clr_flags(worker, WORKER_PREP | WORKER_REBOUND);
3422
3423 do {
3424 struct work_struct *work =
3425 list_first_entry(&pool->worklist,
3426 struct work_struct, entry);
3427
3428 if (assign_work(work, worker, NULL))
3429 process_scheduled_works(worker);
3430 } while (keep_working(pool));
3431
3432 worker_set_flags(worker, WORKER_PREP);
3433sleep:
3434 /*
3435 * pool->lock is held and there's no work to process and no need to
3436 * manage, sleep. Workers are woken up only while holding
3437 * pool->lock or from local cpu, so setting the current state
3438 * before releasing pool->lock is enough to prevent losing any
3439 * event.
3440 */
3441 worker_enter_idle(worker);
3442 __set_current_state(TASK_IDLE);
3443 raw_spin_unlock_irq(&pool->lock);
3444 schedule();
3445 goto woke_up;
3446}
3447
3448/**
3449 * rescuer_thread - the rescuer thread function
3450 * @__rescuer: self
3451 *
3452 * Workqueue rescuer thread function. There's one rescuer for each
3453 * workqueue which has WQ_MEM_RECLAIM set.
3454 *
3455 * Regular work processing on a pool may block trying to create a new
3456 * worker which uses GFP_KERNEL allocation which has slight chance of
3457 * developing into deadlock if some works currently on the same queue
3458 * need to be processed to satisfy the GFP_KERNEL allocation. This is
3459 * the problem rescuer solves.
3460 *
3461 * When such condition is possible, the pool summons rescuers of all
3462 * workqueues which have works queued on the pool and let them process
3463 * those works so that forward progress can be guaranteed.
3464 *
3465 * This should happen rarely.
3466 *
3467 * Return: 0
3468 */
3469static int rescuer_thread(void *__rescuer)
3470{
3471 struct worker *rescuer = __rescuer;
3472 struct workqueue_struct *wq = rescuer->rescue_wq;
3473 bool should_stop;
3474
3475 set_user_nice(current, RESCUER_NICE_LEVEL);
3476
3477 /*
3478 * Mark rescuer as worker too. As WORKER_PREP is never cleared, it
3479 * doesn't participate in concurrency management.
3480 */
3481 set_pf_worker(true);
3482repeat:
3483 set_current_state(TASK_IDLE);
3484
3485 /*
3486 * By the time the rescuer is requested to stop, the workqueue
3487 * shouldn't have any work pending, but @wq->maydays may still have
3488 * pwq(s) queued. This can happen by non-rescuer workers consuming
3489 * all the work items before the rescuer got to them. Go through
3490 * @wq->maydays processing before acting on should_stop so that the
3491 * list is always empty on exit.
3492 */
3493 should_stop = kthread_should_stop();
3494
3495 /* see whether any pwq is asking for help */
3496 raw_spin_lock_irq(&wq_mayday_lock);
3497
3498 while (!list_empty(&wq->maydays)) {
3499 struct pool_workqueue *pwq = list_first_entry(&wq->maydays,
3500 struct pool_workqueue, mayday_node);
3501 struct worker_pool *pool = pwq->pool;
3502 struct work_struct *work, *n;
3503
3504 __set_current_state(TASK_RUNNING);
3505 list_del_init(&pwq->mayday_node);
3506
3507 raw_spin_unlock_irq(&wq_mayday_lock);
3508
3509 worker_attach_to_pool(rescuer, pool);
3510
3511 raw_spin_lock_irq(&pool->lock);
3512
3513 /*
3514 * Slurp in all works issued via this workqueue and
3515 * process'em.
3516 */
3517 WARN_ON_ONCE(!list_empty(&rescuer->scheduled));
3518 list_for_each_entry_safe(work, n, &pool->worklist, entry) {
3519 if (get_work_pwq(work) == pwq &&
3520 assign_work(work, rescuer, &n))
3521 pwq->stats[PWQ_STAT_RESCUED]++;
3522 }
3523
3524 if (!list_empty(&rescuer->scheduled)) {
3525 process_scheduled_works(rescuer);
3526
3527 /*
3528 * The above execution of rescued work items could
3529 * have created more to rescue through
3530 * pwq_activate_first_inactive() or chained
3531 * queueing. Let's put @pwq back on mayday list so
3532 * that such back-to-back work items, which may be
3533 * being used to relieve memory pressure, don't
3534 * incur MAYDAY_INTERVAL delay inbetween.
3535 */
3536 if (pwq->nr_active && need_to_create_worker(pool)) {
3537 raw_spin_lock(&wq_mayday_lock);
3538 /*
3539 * Queue iff we aren't racing destruction
3540 * and somebody else hasn't queued it already.
3541 */
3542 if (wq->rescuer && list_empty(&pwq->mayday_node)) {
3543 get_pwq(pwq);
3544 list_add_tail(&pwq->mayday_node, &wq->maydays);
3545 }
3546 raw_spin_unlock(&wq_mayday_lock);
3547 }
3548 }
3549
3550 /*
3551 * Put the reference grabbed by send_mayday(). @pool won't
3552 * go away while we're still attached to it.
3553 */
3554 put_pwq(pwq);
3555
3556 /*
3557 * Leave this pool. Notify regular workers; otherwise, we end up
3558 * with 0 concurrency and stalling the execution.
3559 */
3560 kick_pool(pool);
3561
3562 raw_spin_unlock_irq(&pool->lock);
3563
3564 worker_detach_from_pool(rescuer);
3565
3566 raw_spin_lock_irq(&wq_mayday_lock);
3567 }
3568
3569 raw_spin_unlock_irq(&wq_mayday_lock);
3570
3571 if (should_stop) {
3572 __set_current_state(TASK_RUNNING);
3573 set_pf_worker(false);
3574 return 0;
3575 }
3576
3577 /* rescuers should never participate in concurrency management */
3578 WARN_ON_ONCE(!(rescuer->flags & WORKER_NOT_RUNNING));
3579 schedule();
3580 goto repeat;
3581}
3582
3583static void bh_worker(struct worker *worker)
3584{
3585 struct worker_pool *pool = worker->pool;
3586 int nr_restarts = BH_WORKER_RESTARTS;
3587 unsigned long end = jiffies + BH_WORKER_JIFFIES;
3588
3589 raw_spin_lock_irq(&pool->lock);
3590 worker_leave_idle(worker);
3591
3592 /*
3593 * This function follows the structure of worker_thread(). See there for
3594 * explanations on each step.
3595 */
3596 if (!need_more_worker(pool))
3597 goto done;
3598
3599 WARN_ON_ONCE(!list_empty(&worker->scheduled));
3600 worker_clr_flags(worker, WORKER_PREP | WORKER_REBOUND);
3601
3602 do {
3603 struct work_struct *work =
3604 list_first_entry(&pool->worklist,
3605 struct work_struct, entry);
3606
3607 if (assign_work(work, worker, NULL))
3608 process_scheduled_works(worker);
3609 } while (keep_working(pool) &&
3610 --nr_restarts && time_before(jiffies, end));
3611
3612 worker_set_flags(worker, WORKER_PREP);
3613done:
3614 worker_enter_idle(worker);
3615 kick_pool(pool);
3616 raw_spin_unlock_irq(&pool->lock);
3617}
3618
3619/*
3620 * TODO: Convert all tasklet users to workqueue and use softirq directly.
3621 *
3622 * This is currently called from tasklet[_hi]action() and thus is also called
3623 * whenever there are tasklets to run. Let's do an early exit if there's nothing
3624 * queued. Once conversion from tasklet is complete, the need_more_worker() test
3625 * can be dropped.
3626 *
3627 * After full conversion, we'll add worker->softirq_action, directly use the
3628 * softirq action and obtain the worker pointer from the softirq_action pointer.
3629 */
3630void workqueue_softirq_action(bool highpri)
3631{
3632 struct worker_pool *pool =
3633 &per_cpu(bh_worker_pools, smp_processor_id())[highpri];
3634 if (need_more_worker(pool))
3635 bh_worker(list_first_entry(&pool->workers, struct worker, node));
3636}
3637
3638struct wq_drain_dead_softirq_work {
3639 struct work_struct work;
3640 struct worker_pool *pool;
3641 struct completion done;
3642};
3643
3644static void drain_dead_softirq_workfn(struct work_struct *work)
3645{
3646 struct wq_drain_dead_softirq_work *dead_work =
3647 container_of(work, struct wq_drain_dead_softirq_work, work);
3648 struct worker_pool *pool = dead_work->pool;
3649 bool repeat;
3650
3651 /*
3652 * @pool's CPU is dead and we want to execute its still pending work
3653 * items from this BH work item which is running on a different CPU. As
3654 * its CPU is dead, @pool can't be kicked and, as work execution path
3655 * will be nested, a lockdep annotation needs to be suppressed. Mark
3656 * @pool with %POOL_BH_DRAINING for the special treatments.
3657 */
3658 raw_spin_lock_irq(&pool->lock);
3659 pool->flags |= POOL_BH_DRAINING;
3660 raw_spin_unlock_irq(&pool->lock);
3661
3662 bh_worker(list_first_entry(&pool->workers, struct worker, node));
3663
3664 raw_spin_lock_irq(&pool->lock);
3665 pool->flags &= ~POOL_BH_DRAINING;
3666 repeat = need_more_worker(pool);
3667 raw_spin_unlock_irq(&pool->lock);
3668
3669 /*
3670 * bh_worker() might hit consecutive execution limit and bail. If there
3671 * still are pending work items, reschedule self and return so that we
3672 * don't hog this CPU's BH.
3673 */
3674 if (repeat) {
3675 if (pool->attrs->nice == HIGHPRI_NICE_LEVEL)
3676 queue_work(system_bh_highpri_wq, work);
3677 else
3678 queue_work(system_bh_wq, work);
3679 } else {
3680 complete(&dead_work->done);
3681 }
3682}
3683
3684/*
3685 * @cpu is dead. Drain the remaining BH work items on the current CPU. It's
3686 * possible to allocate dead_work per CPU and avoid flushing. However, then we
3687 * have to worry about draining overlapping with CPU coming back online or
3688 * nesting (one CPU's dead_work queued on another CPU which is also dead and so
3689 * on). Let's keep it simple and drain them synchronously. These are BH work
3690 * items which shouldn't be requeued on the same pool. Shouldn't take long.
3691 */
3692void workqueue_softirq_dead(unsigned int cpu)
3693{
3694 int i;
3695
3696 for (i = 0; i < NR_STD_WORKER_POOLS; i++) {
3697 struct worker_pool *pool = &per_cpu(bh_worker_pools, cpu)[i];
3698 struct wq_drain_dead_softirq_work dead_work;
3699
3700 if (!need_more_worker(pool))
3701 continue;
3702
3703 INIT_WORK(&dead_work.work, drain_dead_softirq_workfn);
3704 dead_work.pool = pool;
3705 init_completion(&dead_work.done);
3706
3707 if (pool->attrs->nice == HIGHPRI_NICE_LEVEL)
3708 queue_work(system_bh_highpri_wq, &dead_work.work);
3709 else
3710 queue_work(system_bh_wq, &dead_work.work);
3711
3712 wait_for_completion(&dead_work.done);
3713 }
3714}
3715
3716/**
3717 * check_flush_dependency - check for flush dependency sanity
3718 * @target_wq: workqueue being flushed
3719 * @target_work: work item being flushed (NULL for workqueue flushes)
3720 *
3721 * %current is trying to flush the whole @target_wq or @target_work on it.
3722 * If @target_wq doesn't have %WQ_MEM_RECLAIM, verify that %current is not
3723 * reclaiming memory or running on a workqueue which doesn't have
3724 * %WQ_MEM_RECLAIM as that can break forward-progress guarantee leading to
3725 * a deadlock.
3726 */
3727static void check_flush_dependency(struct workqueue_struct *target_wq,
3728 struct work_struct *target_work)
3729{
3730 work_func_t target_func = target_work ? target_work->func : NULL;
3731 struct worker *worker;
3732
3733 if (target_wq->flags & WQ_MEM_RECLAIM)
3734 return;
3735
3736 worker = current_wq_worker();
3737
3738 WARN_ONCE(current->flags & PF_MEMALLOC,
3739 "workqueue: PF_MEMALLOC task %d(%s) is flushing !WQ_MEM_RECLAIM %s:%ps",
3740 current->pid, current->comm, target_wq->name, target_func);
3741 WARN_ONCE(worker && ((worker->current_pwq->wq->flags &
3742 (WQ_MEM_RECLAIM | __WQ_LEGACY)) == WQ_MEM_RECLAIM),
3743 "workqueue: WQ_MEM_RECLAIM %s:%ps is flushing !WQ_MEM_RECLAIM %s:%ps",
3744 worker->current_pwq->wq->name, worker->current_func,
3745 target_wq->name, target_func);
3746}
3747
3748struct wq_barrier {
3749 struct work_struct work;
3750 struct completion done;
3751 struct task_struct *task; /* purely informational */
3752};
3753
3754static void wq_barrier_func(struct work_struct *work)
3755{
3756 struct wq_barrier *barr = container_of(work, struct wq_barrier, work);
3757 complete(&barr->done);
3758}
3759
3760/**
3761 * insert_wq_barrier - insert a barrier work
3762 * @pwq: pwq to insert barrier into
3763 * @barr: wq_barrier to insert
3764 * @target: target work to attach @barr to
3765 * @worker: worker currently executing @target, NULL if @target is not executing
3766 *
3767 * @barr is linked to @target such that @barr is completed only after
3768 * @target finishes execution. Please note that the ordering
3769 * guarantee is observed only with respect to @target and on the local
3770 * cpu.
3771 *
3772 * Currently, a queued barrier can't be canceled. This is because
3773 * try_to_grab_pending() can't determine whether the work to be
3774 * grabbed is at the head of the queue and thus can't clear LINKED
3775 * flag of the previous work while there must be a valid next work
3776 * after a work with LINKED flag set.
3777 *
3778 * Note that when @worker is non-NULL, @target may be modified
3779 * underneath us, so we can't reliably determine pwq from @target.
3780 *
3781 * CONTEXT:
3782 * raw_spin_lock_irq(pool->lock).
3783 */
3784static void insert_wq_barrier(struct pool_workqueue *pwq,
3785 struct wq_barrier *barr,
3786 struct work_struct *target, struct worker *worker)
3787{
3788 static __maybe_unused struct lock_class_key bh_key, thr_key;
3789 unsigned int work_flags = 0;
3790 unsigned int work_color;
3791 struct list_head *head;
3792
3793 /*
3794 * debugobject calls are safe here even with pool->lock locked
3795 * as we know for sure that this will not trigger any of the
3796 * checks and call back into the fixup functions where we
3797 * might deadlock.
3798 *
3799 * BH and threaded workqueues need separate lockdep keys to avoid
3800 * spuriously triggering "inconsistent {SOFTIRQ-ON-W} -> {IN-SOFTIRQ-W}
3801 * usage".
3802 */
3803 INIT_WORK_ONSTACK_KEY(&barr->work, wq_barrier_func,
3804 (pwq->wq->flags & WQ_BH) ? &bh_key : &thr_key);
3805 __set_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(&barr->work));
3806
3807 init_completion_map(&barr->done, &target->lockdep_map);
3808
3809 barr->task = current;
3810
3811 /* The barrier work item does not participate in nr_active. */
3812 work_flags |= WORK_STRUCT_INACTIVE;
3813
3814 /*
3815 * If @target is currently being executed, schedule the
3816 * barrier to the worker; otherwise, put it after @target.
3817 */
3818 if (worker) {
3819 head = worker->scheduled.next;
3820 work_color = worker->current_color;
3821 } else {
3822 unsigned long *bits = work_data_bits(target);
3823
3824 head = target->entry.next;
3825 /* there can already be other linked works, inherit and set */
3826 work_flags |= *bits & WORK_STRUCT_LINKED;
3827 work_color = get_work_color(*bits);
3828 __set_bit(WORK_STRUCT_LINKED_BIT, bits);
3829 }
3830
3831 pwq->nr_in_flight[work_color]++;
3832 work_flags |= work_color_to_flags(work_color);
3833
3834 insert_work(pwq, &barr->work, head, work_flags);
3835}
3836
3837/**
3838 * flush_workqueue_prep_pwqs - prepare pwqs for workqueue flushing
3839 * @wq: workqueue being flushed
3840 * @flush_color: new flush color, < 0 for no-op
3841 * @work_color: new work color, < 0 for no-op
3842 *
3843 * Prepare pwqs for workqueue flushing.
3844 *
3845 * If @flush_color is non-negative, flush_color on all pwqs should be
3846 * -1. If no pwq has in-flight commands at the specified color, all
3847 * pwq->flush_color's stay at -1 and %false is returned. If any pwq
3848 * has in flight commands, its pwq->flush_color is set to
3849 * @flush_color, @wq->nr_pwqs_to_flush is updated accordingly, pwq
3850 * wakeup logic is armed and %true is returned.
3851 *
3852 * The caller should have initialized @wq->first_flusher prior to
3853 * calling this function with non-negative @flush_color. If
3854 * @flush_color is negative, no flush color update is done and %false
3855 * is returned.
3856 *
3857 * If @work_color is non-negative, all pwqs should have the same
3858 * work_color which is previous to @work_color and all will be
3859 * advanced to @work_color.
3860 *
3861 * CONTEXT:
3862 * mutex_lock(wq->mutex).
3863 *
3864 * Return:
3865 * %true if @flush_color >= 0 and there's something to flush. %false
3866 * otherwise.
3867 */
3868static bool flush_workqueue_prep_pwqs(struct workqueue_struct *wq,
3869 int flush_color, int work_color)
3870{
3871 bool wait = false;
3872 struct pool_workqueue *pwq;
3873
3874 if (flush_color >= 0) {
3875 WARN_ON_ONCE(atomic_read(&wq->nr_pwqs_to_flush));
3876 atomic_set(&wq->nr_pwqs_to_flush, 1);
3877 }
3878
3879 for_each_pwq(pwq, wq) {
3880 struct worker_pool *pool = pwq->pool;
3881
3882 raw_spin_lock_irq(&pool->lock);
3883
3884 if (flush_color >= 0) {
3885 WARN_ON_ONCE(pwq->flush_color != -1);
3886
3887 if (pwq->nr_in_flight[flush_color]) {
3888 pwq->flush_color = flush_color;
3889 atomic_inc(&wq->nr_pwqs_to_flush);
3890 wait = true;
3891 }
3892 }
3893
3894 if (work_color >= 0) {
3895 WARN_ON_ONCE(work_color != work_next_color(pwq->work_color));
3896 pwq->work_color = work_color;
3897 }
3898
3899 raw_spin_unlock_irq(&pool->lock);
3900 }
3901
3902 if (flush_color >= 0 && atomic_dec_and_test(&wq->nr_pwqs_to_flush))
3903 complete(&wq->first_flusher->done);
3904
3905 return wait;
3906}
3907
3908static void touch_wq_lockdep_map(struct workqueue_struct *wq)
3909{
3910#ifdef CONFIG_LOCKDEP
3911 if (wq->flags & WQ_BH)
3912 local_bh_disable();
3913
3914 lock_map_acquire(&wq->lockdep_map);
3915 lock_map_release(&wq->lockdep_map);
3916
3917 if (wq->flags & WQ_BH)
3918 local_bh_enable();
3919#endif
3920}
3921
3922static void touch_work_lockdep_map(struct work_struct *work,
3923 struct workqueue_struct *wq)
3924{
3925#ifdef CONFIG_LOCKDEP
3926 if (wq->flags & WQ_BH)
3927 local_bh_disable();
3928
3929 lock_map_acquire(&work->lockdep_map);
3930 lock_map_release(&work->lockdep_map);
3931
3932 if (wq->flags & WQ_BH)
3933 local_bh_enable();
3934#endif
3935}
3936
3937/**
3938 * __flush_workqueue - ensure that any scheduled work has run to completion.
3939 * @wq: workqueue to flush
3940 *
3941 * This function sleeps until all work items which were queued on entry
3942 * have finished execution, but it is not livelocked by new incoming ones.
3943 */
3944void __flush_workqueue(struct workqueue_struct *wq)
3945{
3946 struct wq_flusher this_flusher = {
3947 .list = LIST_HEAD_INIT(this_flusher.list),
3948 .flush_color = -1,
3949 .done = COMPLETION_INITIALIZER_ONSTACK_MAP(this_flusher.done, wq->lockdep_map),
3950 };
3951 int next_color;
3952
3953 if (WARN_ON(!wq_online))
3954 return;
3955
3956 touch_wq_lockdep_map(wq);
3957
3958 mutex_lock(&wq->mutex);
3959
3960 /*
3961 * Start-to-wait phase
3962 */
3963 next_color = work_next_color(wq->work_color);
3964
3965 if (next_color != wq->flush_color) {
3966 /*
3967 * Color space is not full. The current work_color
3968 * becomes our flush_color and work_color is advanced
3969 * by one.
3970 */
3971 WARN_ON_ONCE(!list_empty(&wq->flusher_overflow));
3972 this_flusher.flush_color = wq->work_color;
3973 wq->work_color = next_color;
3974
3975 if (!wq->first_flusher) {
3976 /* no flush in progress, become the first flusher */
3977 WARN_ON_ONCE(wq->flush_color != this_flusher.flush_color);
3978
3979 wq->first_flusher = &this_flusher;
3980
3981 if (!flush_workqueue_prep_pwqs(wq, wq->flush_color,
3982 wq->work_color)) {
3983 /* nothing to flush, done */
3984 wq->flush_color = next_color;
3985 wq->first_flusher = NULL;
3986 goto out_unlock;
3987 }
3988 } else {
3989 /* wait in queue */
3990 WARN_ON_ONCE(wq->flush_color == this_flusher.flush_color);
3991 list_add_tail(&this_flusher.list, &wq->flusher_queue);
3992 flush_workqueue_prep_pwqs(wq, -1, wq->work_color);
3993 }
3994 } else {
3995 /*
3996 * Oops, color space is full, wait on overflow queue.
3997 * The next flush completion will assign us
3998 * flush_color and transfer to flusher_queue.
3999 */
4000 list_add_tail(&this_flusher.list, &wq->flusher_overflow);
4001 }
4002
4003 check_flush_dependency(wq, NULL);
4004
4005 mutex_unlock(&wq->mutex);
4006
4007 wait_for_completion(&this_flusher.done);
4008
4009 /*
4010 * Wake-up-and-cascade phase
4011 *
4012 * First flushers are responsible for cascading flushes and
4013 * handling overflow. Non-first flushers can simply return.
4014 */
4015 if (READ_ONCE(wq->first_flusher) != &this_flusher)
4016 return;
4017
4018 mutex_lock(&wq->mutex);
4019
4020 /* we might have raced, check again with mutex held */
4021 if (wq->first_flusher != &this_flusher)
4022 goto out_unlock;
4023
4024 WRITE_ONCE(wq->first_flusher, NULL);
4025
4026 WARN_ON_ONCE(!list_empty(&this_flusher.list));
4027 WARN_ON_ONCE(wq->flush_color != this_flusher.flush_color);
4028
4029 while (true) {
4030 struct wq_flusher *next, *tmp;
4031
4032 /* complete all the flushers sharing the current flush color */
4033 list_for_each_entry_safe(next, tmp, &wq->flusher_queue, list) {
4034 if (next->flush_color != wq->flush_color)
4035 break;
4036 list_del_init(&next->list);
4037 complete(&next->done);
4038 }
4039
4040 WARN_ON_ONCE(!list_empty(&wq->flusher_overflow) &&
4041 wq->flush_color != work_next_color(wq->work_color));
4042
4043 /* this flush_color is finished, advance by one */
4044 wq->flush_color = work_next_color(wq->flush_color);
4045
4046 /* one color has been freed, handle overflow queue */
4047 if (!list_empty(&wq->flusher_overflow)) {
4048 /*
4049 * Assign the same color to all overflowed
4050 * flushers, advance work_color and append to
4051 * flusher_queue. This is the start-to-wait
4052 * phase for these overflowed flushers.
4053 */
4054 list_for_each_entry(tmp, &wq->flusher_overflow, list)
4055 tmp->flush_color = wq->work_color;
4056
4057 wq->work_color = work_next_color(wq->work_color);
4058
4059 list_splice_tail_init(&wq->flusher_overflow,
4060 &wq->flusher_queue);
4061 flush_workqueue_prep_pwqs(wq, -1, wq->work_color);
4062 }
4063
4064 if (list_empty(&wq->flusher_queue)) {
4065 WARN_ON_ONCE(wq->flush_color != wq->work_color);
4066 break;
4067 }
4068
4069 /*
4070 * Need to flush more colors. Make the next flusher
4071 * the new first flusher and arm pwqs.
4072 */
4073 WARN_ON_ONCE(wq->flush_color == wq->work_color);
4074 WARN_ON_ONCE(wq->flush_color != next->flush_color);
4075
4076 list_del_init(&next->list);
4077 wq->first_flusher = next;
4078
4079 if (flush_workqueue_prep_pwqs(wq, wq->flush_color, -1))
4080 break;
4081
4082 /*
4083 * Meh... this color is already done, clear first
4084 * flusher and repeat cascading.
4085 */
4086 wq->first_flusher = NULL;
4087 }
4088
4089out_unlock:
4090 mutex_unlock(&wq->mutex);
4091}
4092EXPORT_SYMBOL(__flush_workqueue);
4093
4094/**
4095 * drain_workqueue - drain a workqueue
4096 * @wq: workqueue to drain
4097 *
4098 * Wait until the workqueue becomes empty. While draining is in progress,
4099 * only chain queueing is allowed. IOW, only currently pending or running
4100 * work items on @wq can queue further work items on it. @wq is flushed
4101 * repeatedly until it becomes empty. The number of flushing is determined
4102 * by the depth of chaining and should be relatively short. Whine if it
4103 * takes too long.
4104 */
4105void drain_workqueue(struct workqueue_struct *wq)
4106{
4107 unsigned int flush_cnt = 0;
4108 struct pool_workqueue *pwq;
4109
4110 /*
4111 * __queue_work() needs to test whether there are drainers, is much
4112 * hotter than drain_workqueue() and already looks at @wq->flags.
4113 * Use __WQ_DRAINING so that queue doesn't have to check nr_drainers.
4114 */
4115 mutex_lock(&wq->mutex);
4116 if (!wq->nr_drainers++)
4117 wq->flags |= __WQ_DRAINING;
4118 mutex_unlock(&wq->mutex);
4119reflush:
4120 __flush_workqueue(wq);
4121
4122 mutex_lock(&wq->mutex);
4123
4124 for_each_pwq(pwq, wq) {
4125 bool drained;
4126
4127 raw_spin_lock_irq(&pwq->pool->lock);
4128 drained = pwq_is_empty(pwq);
4129 raw_spin_unlock_irq(&pwq->pool->lock);
4130
4131 if (drained)
4132 continue;
4133
4134 if (++flush_cnt == 10 ||
4135 (flush_cnt % 100 == 0 && flush_cnt <= 1000))
4136 pr_warn("workqueue %s: %s() isn't complete after %u tries\n",
4137 wq->name, __func__, flush_cnt);
4138
4139 mutex_unlock(&wq->mutex);
4140 goto reflush;
4141 }
4142
4143 if (!--wq->nr_drainers)
4144 wq->flags &= ~__WQ_DRAINING;
4145 mutex_unlock(&wq->mutex);
4146}
4147EXPORT_SYMBOL_GPL(drain_workqueue);
4148
4149static bool start_flush_work(struct work_struct *work, struct wq_barrier *barr,
4150 bool from_cancel)
4151{
4152 struct worker *worker = NULL;
4153 struct worker_pool *pool;
4154 struct pool_workqueue *pwq;
4155 struct workqueue_struct *wq;
4156
4157 might_sleep();
4158
4159 rcu_read_lock();
4160 pool = get_work_pool(work);
4161 if (!pool) {
4162 rcu_read_unlock();
4163 return false;
4164 }
4165
4166 raw_spin_lock_irq(&pool->lock);
4167 /* see the comment in try_to_grab_pending() with the same code */
4168 pwq = get_work_pwq(work);
4169 if (pwq) {
4170 if (unlikely(pwq->pool != pool))
4171 goto already_gone;
4172 } else {
4173 worker = find_worker_executing_work(pool, work);
4174 if (!worker)
4175 goto already_gone;
4176 pwq = worker->current_pwq;
4177 }
4178
4179 wq = pwq->wq;
4180 check_flush_dependency(wq, work);
4181
4182 insert_wq_barrier(pwq, barr, work, worker);
4183 raw_spin_unlock_irq(&pool->lock);
4184
4185 touch_work_lockdep_map(work, wq);
4186
4187 /*
4188 * Force a lock recursion deadlock when using flush_work() inside a
4189 * single-threaded or rescuer equipped workqueue.
4190 *
4191 * For single threaded workqueues the deadlock happens when the work
4192 * is after the work issuing the flush_work(). For rescuer equipped
4193 * workqueues the deadlock happens when the rescuer stalls, blocking
4194 * forward progress.
4195 */
4196 if (!from_cancel && (wq->saved_max_active == 1 || wq->rescuer))
4197 touch_wq_lockdep_map(wq);
4198
4199 rcu_read_unlock();
4200 return true;
4201already_gone:
4202 raw_spin_unlock_irq(&pool->lock);
4203 rcu_read_unlock();
4204 return false;
4205}
4206
4207static bool __flush_work(struct work_struct *work, bool from_cancel)
4208{
4209 struct wq_barrier barr;
4210
4211 if (WARN_ON(!wq_online))
4212 return false;
4213
4214 if (WARN_ON(!work->func))
4215 return false;
4216
4217 if (start_flush_work(work, &barr, from_cancel)) {
4218 wait_for_completion(&barr.done);
4219 destroy_work_on_stack(&barr.work);
4220 return true;
4221 } else {
4222 return false;
4223 }
4224}
4225
4226/**
4227 * flush_work - wait for a work to finish executing the last queueing instance
4228 * @work: the work to flush
4229 *
4230 * Wait until @work has finished execution. @work is guaranteed to be idle
4231 * on return if it hasn't been requeued since flush started.
4232 *
4233 * Return:
4234 * %true if flush_work() waited for the work to finish execution,
4235 * %false if it was already idle.
4236 */
4237bool flush_work(struct work_struct *work)
4238{
4239 return __flush_work(work, false);
4240}
4241EXPORT_SYMBOL_GPL(flush_work);
4242
4243/**
4244 * flush_delayed_work - wait for a dwork to finish executing the last queueing
4245 * @dwork: the delayed work to flush
4246 *
4247 * Delayed timer is cancelled and the pending work is queued for
4248 * immediate execution. Like flush_work(), this function only
4249 * considers the last queueing instance of @dwork.
4250 *
4251 * Return:
4252 * %true if flush_work() waited for the work to finish execution,
4253 * %false if it was already idle.
4254 */
4255bool flush_delayed_work(struct delayed_work *dwork)
4256{
4257 local_irq_disable();
4258 if (del_timer_sync(&dwork->timer))
4259 __queue_work(dwork->cpu, dwork->wq, &dwork->work);
4260 local_irq_enable();
4261 return flush_work(&dwork->work);
4262}
4263EXPORT_SYMBOL(flush_delayed_work);
4264
4265/**
4266 * flush_rcu_work - wait for a rwork to finish executing the last queueing
4267 * @rwork: the rcu work to flush
4268 *
4269 * Return:
4270 * %true if flush_rcu_work() waited for the work to finish execution,
4271 * %false if it was already idle.
4272 */
4273bool flush_rcu_work(struct rcu_work *rwork)
4274{
4275 if (test_bit(WORK_STRUCT_PENDING_BIT, work_data_bits(&rwork->work))) {
4276 rcu_barrier();
4277 flush_work(&rwork->work);
4278 return true;
4279 } else {
4280 return flush_work(&rwork->work);
4281 }
4282}
4283EXPORT_SYMBOL(flush_rcu_work);
4284
4285static bool __cancel_work(struct work_struct *work, u32 cflags)
4286{
4287 unsigned long irq_flags;
4288 int ret;
4289
4290 do {
4291 ret = try_to_grab_pending(work, cflags, &irq_flags);
4292 } while (unlikely(ret == -EAGAIN));
4293
4294 if (unlikely(ret < 0))
4295 return false;
4296
4297 set_work_pool_and_clear_pending(work, get_work_pool_id(work), 0);
4298 local_irq_restore(irq_flags);
4299 return ret;
4300}
4301
4302static bool __cancel_work_sync(struct work_struct *work, u32 cflags)
4303{
4304 unsigned long irq_flags;
4305 bool ret;
4306
4307 /* claim @work and tell other tasks trying to grab @work to back off */
4308 ret = work_grab_pending(work, cflags, &irq_flags);
4309 mark_work_canceling(work);
4310 local_irq_restore(irq_flags);
4311
4312 /*
4313 * Skip __flush_work() during early boot when we know that @work isn't
4314 * executing. This allows canceling during early boot.
4315 */
4316 if (wq_online)
4317 __flush_work(work, true);
4318
4319 /*
4320 * smp_mb() at the end of set_work_pool_and_clear_pending() is paired
4321 * with prepare_to_wait() above so that either waitqueue_active() is
4322 * visible here or !work_is_canceling() is visible there.
4323 */
4324 set_work_pool_and_clear_pending(work, WORK_OFFQ_POOL_NONE, 0);
4325
4326 if (waitqueue_active(&wq_cancel_waitq))
4327 __wake_up(&wq_cancel_waitq, TASK_NORMAL, 1, work);
4328
4329 return ret;
4330}
4331
4332/*
4333 * See cancel_delayed_work()
4334 */
4335bool cancel_work(struct work_struct *work)
4336{
4337 return __cancel_work(work, 0);
4338}
4339EXPORT_SYMBOL(cancel_work);
4340
4341/**
4342 * cancel_work_sync - cancel a work and wait for it to finish
4343 * @work: the work to cancel
4344 *
4345 * Cancel @work and wait for its execution to finish. This function
4346 * can be used even if the work re-queues itself or migrates to
4347 * another workqueue. On return from this function, @work is
4348 * guaranteed to be not pending or executing on any CPU.
4349 *
4350 * cancel_work_sync(&delayed_work->work) must not be used for
4351 * delayed_work's. Use cancel_delayed_work_sync() instead.
4352 *
4353 * The caller must ensure that the workqueue on which @work was last
4354 * queued can't be destroyed before this function returns.
4355 *
4356 * Return:
4357 * %true if @work was pending, %false otherwise.
4358 */
4359bool cancel_work_sync(struct work_struct *work)
4360{
4361 return __cancel_work_sync(work, 0);
4362}
4363EXPORT_SYMBOL_GPL(cancel_work_sync);
4364
4365/**
4366 * cancel_delayed_work - cancel a delayed work
4367 * @dwork: delayed_work to cancel
4368 *
4369 * Kill off a pending delayed_work.
4370 *
4371 * Return: %true if @dwork was pending and canceled; %false if it wasn't
4372 * pending.
4373 *
4374 * Note:
4375 * The work callback function may still be running on return, unless
4376 * it returns %true and the work doesn't re-arm itself. Explicitly flush or
4377 * use cancel_delayed_work_sync() to wait on it.
4378 *
4379 * This function is safe to call from any context including IRQ handler.
4380 */
4381bool cancel_delayed_work(struct delayed_work *dwork)
4382{
4383 return __cancel_work(&dwork->work, WORK_CANCEL_DELAYED);
4384}
4385EXPORT_SYMBOL(cancel_delayed_work);
4386
4387/**
4388 * cancel_delayed_work_sync - cancel a delayed work and wait for it to finish
4389 * @dwork: the delayed work cancel
4390 *
4391 * This is cancel_work_sync() for delayed works.
4392 *
4393 * Return:
4394 * %true if @dwork was pending, %false otherwise.
4395 */
4396bool cancel_delayed_work_sync(struct delayed_work *dwork)
4397{
4398 return __cancel_work_sync(&dwork->work, WORK_CANCEL_DELAYED);
4399}
4400EXPORT_SYMBOL(cancel_delayed_work_sync);
4401
4402/**
4403 * schedule_on_each_cpu - execute a function synchronously on each online CPU
4404 * @func: the function to call
4405 *
4406 * schedule_on_each_cpu() executes @func on each online CPU using the
4407 * system workqueue and blocks until all CPUs have completed.
4408 * schedule_on_each_cpu() is very slow.
4409 *
4410 * Return:
4411 * 0 on success, -errno on failure.
4412 */
4413int schedule_on_each_cpu(work_func_t func)
4414{
4415 int cpu;
4416 struct work_struct __percpu *works;
4417
4418 works = alloc_percpu(struct work_struct);
4419 if (!works)
4420 return -ENOMEM;
4421
4422 cpus_read_lock();
4423
4424 for_each_online_cpu(cpu) {
4425 struct work_struct *work = per_cpu_ptr(works, cpu);
4426
4427 INIT_WORK(work, func);
4428 schedule_work_on(cpu, work);
4429 }
4430
4431 for_each_online_cpu(cpu)
4432 flush_work(per_cpu_ptr(works, cpu));
4433
4434 cpus_read_unlock();
4435 free_percpu(works);
4436 return 0;
4437}
4438
4439/**
4440 * execute_in_process_context - reliably execute the routine with user context
4441 * @fn: the function to execute
4442 * @ew: guaranteed storage for the execute work structure (must
4443 * be available when the work executes)
4444 *
4445 * Executes the function immediately if process context is available,
4446 * otherwise schedules the function for delayed execution.
4447 *
4448 * Return: 0 - function was executed
4449 * 1 - function was scheduled for execution
4450 */
4451int execute_in_process_context(work_func_t fn, struct execute_work *ew)
4452{
4453 if (!in_interrupt()) {
4454 fn(&ew->work);
4455 return 0;
4456 }
4457
4458 INIT_WORK(&ew->work, fn);
4459 schedule_work(&ew->work);
4460
4461 return 1;
4462}
4463EXPORT_SYMBOL_GPL(execute_in_process_context);
4464
4465/**
4466 * free_workqueue_attrs - free a workqueue_attrs
4467 * @attrs: workqueue_attrs to free
4468 *
4469 * Undo alloc_workqueue_attrs().
4470 */
4471void free_workqueue_attrs(struct workqueue_attrs *attrs)
4472{
4473 if (attrs) {
4474 free_cpumask_var(attrs->cpumask);
4475 free_cpumask_var(attrs->__pod_cpumask);
4476 kfree(attrs);
4477 }
4478}
4479
4480/**
4481 * alloc_workqueue_attrs - allocate a workqueue_attrs
4482 *
4483 * Allocate a new workqueue_attrs, initialize with default settings and
4484 * return it.
4485 *
4486 * Return: The allocated new workqueue_attr on success. %NULL on failure.
4487 */
4488struct workqueue_attrs *alloc_workqueue_attrs(void)
4489{
4490 struct workqueue_attrs *attrs;
4491
4492 attrs = kzalloc(sizeof(*attrs), GFP_KERNEL);
4493 if (!attrs)
4494 goto fail;
4495 if (!alloc_cpumask_var(&attrs->cpumask, GFP_KERNEL))
4496 goto fail;
4497 if (!alloc_cpumask_var(&attrs->__pod_cpumask, GFP_KERNEL))
4498 goto fail;
4499
4500 cpumask_copy(attrs->cpumask, cpu_possible_mask);
4501 attrs->affn_scope = WQ_AFFN_DFL;
4502 return attrs;
4503fail:
4504 free_workqueue_attrs(attrs);
4505 return NULL;
4506}
4507
4508static void copy_workqueue_attrs(struct workqueue_attrs *to,
4509 const struct workqueue_attrs *from)
4510{
4511 to->nice = from->nice;
4512 cpumask_copy(to->cpumask, from->cpumask);
4513 cpumask_copy(to->__pod_cpumask, from->__pod_cpumask);
4514 to->affn_strict = from->affn_strict;
4515
4516 /*
4517 * Unlike hash and equality test, copying shouldn't ignore wq-only
4518 * fields as copying is used for both pool and wq attrs. Instead,
4519 * get_unbound_pool() explicitly clears the fields.
4520 */
4521 to->affn_scope = from->affn_scope;
4522 to->ordered = from->ordered;
4523}
4524
4525/*
4526 * Some attrs fields are workqueue-only. Clear them for worker_pool's. See the
4527 * comments in 'struct workqueue_attrs' definition.
4528 */
4529static void wqattrs_clear_for_pool(struct workqueue_attrs *attrs)
4530{
4531 attrs->affn_scope = WQ_AFFN_NR_TYPES;
4532 attrs->ordered = false;
4533}
4534
4535/* hash value of the content of @attr */
4536static u32 wqattrs_hash(const struct workqueue_attrs *attrs)
4537{
4538 u32 hash = 0;
4539
4540 hash = jhash_1word(attrs->nice, hash);
4541 hash = jhash(cpumask_bits(attrs->cpumask),
4542 BITS_TO_LONGS(nr_cpumask_bits) * sizeof(long), hash);
4543 hash = jhash(cpumask_bits(attrs->__pod_cpumask),
4544 BITS_TO_LONGS(nr_cpumask_bits) * sizeof(long), hash);
4545 hash = jhash_1word(attrs->affn_strict, hash);
4546 return hash;
4547}
4548
4549/* content equality test */
4550static bool wqattrs_equal(const struct workqueue_attrs *a,
4551 const struct workqueue_attrs *b)
4552{
4553 if (a->nice != b->nice)
4554 return false;
4555 if (!cpumask_equal(a->cpumask, b->cpumask))
4556 return false;
4557 if (!cpumask_equal(a->__pod_cpumask, b->__pod_cpumask))
4558 return false;
4559 if (a->affn_strict != b->affn_strict)
4560 return false;
4561 return true;
4562}
4563
4564/* Update @attrs with actually available CPUs */
4565static void wqattrs_actualize_cpumask(struct workqueue_attrs *attrs,
4566 const cpumask_t *unbound_cpumask)
4567{
4568 /*
4569 * Calculate the effective CPU mask of @attrs given @unbound_cpumask. If
4570 * @attrs->cpumask doesn't overlap with @unbound_cpumask, we fallback to
4571 * @unbound_cpumask.
4572 */
4573 cpumask_and(attrs->cpumask, attrs->cpumask, unbound_cpumask);
4574 if (unlikely(cpumask_empty(attrs->cpumask)))
4575 cpumask_copy(attrs->cpumask, unbound_cpumask);
4576}
4577
4578/* find wq_pod_type to use for @attrs */
4579static const struct wq_pod_type *
4580wqattrs_pod_type(const struct workqueue_attrs *attrs)
4581{
4582 enum wq_affn_scope scope;
4583 struct wq_pod_type *pt;
4584
4585 /* to synchronize access to wq_affn_dfl */
4586 lockdep_assert_held(&wq_pool_mutex);
4587
4588 if (attrs->affn_scope == WQ_AFFN_DFL)
4589 scope = wq_affn_dfl;
4590 else
4591 scope = attrs->affn_scope;
4592
4593 pt = &wq_pod_types[scope];
4594
4595 if (!WARN_ON_ONCE(attrs->affn_scope == WQ_AFFN_NR_TYPES) &&
4596 likely(pt->nr_pods))
4597 return pt;
4598
4599 /*
4600 * Before workqueue_init_topology(), only SYSTEM is available which is
4601 * initialized in workqueue_init_early().
4602 */
4603 pt = &wq_pod_types[WQ_AFFN_SYSTEM];
4604 BUG_ON(!pt->nr_pods);
4605 return pt;
4606}
4607
4608/**
4609 * init_worker_pool - initialize a newly zalloc'd worker_pool
4610 * @pool: worker_pool to initialize
4611 *
4612 * Initialize a newly zalloc'd @pool. It also allocates @pool->attrs.
4613 *
4614 * Return: 0 on success, -errno on failure. Even on failure, all fields
4615 * inside @pool proper are initialized and put_unbound_pool() can be called
4616 * on @pool safely to release it.
4617 */
4618static int init_worker_pool(struct worker_pool *pool)
4619{
4620 raw_spin_lock_init(&pool->lock);
4621 pool->id = -1;
4622 pool->cpu = -1;
4623 pool->node = NUMA_NO_NODE;
4624 pool->flags |= POOL_DISASSOCIATED;
4625 pool->watchdog_ts = jiffies;
4626 INIT_LIST_HEAD(&pool->worklist);
4627 INIT_LIST_HEAD(&pool->idle_list);
4628 hash_init(pool->busy_hash);
4629
4630 timer_setup(&pool->idle_timer, idle_worker_timeout, TIMER_DEFERRABLE);
4631 INIT_WORK(&pool->idle_cull_work, idle_cull_fn);
4632
4633 timer_setup(&pool->mayday_timer, pool_mayday_timeout, 0);
4634
4635 INIT_LIST_HEAD(&pool->workers);
4636 INIT_LIST_HEAD(&pool->dying_workers);
4637
4638 ida_init(&pool->worker_ida);
4639 INIT_HLIST_NODE(&pool->hash_node);
4640 pool->refcnt = 1;
4641
4642 /* shouldn't fail above this point */
4643 pool->attrs = alloc_workqueue_attrs();
4644 if (!pool->attrs)
4645 return -ENOMEM;
4646
4647 wqattrs_clear_for_pool(pool->attrs);
4648
4649 return 0;
4650}
4651
4652#ifdef CONFIG_LOCKDEP
4653static void wq_init_lockdep(struct workqueue_struct *wq)
4654{
4655 char *lock_name;
4656
4657 lockdep_register_key(&wq->key);
4658 lock_name = kasprintf(GFP_KERNEL, "%s%s", "(wq_completion)", wq->name);
4659 if (!lock_name)
4660 lock_name = wq->name;
4661
4662 wq->lock_name = lock_name;
4663 lockdep_init_map(&wq->lockdep_map, lock_name, &wq->key, 0);
4664}
4665
4666static void wq_unregister_lockdep(struct workqueue_struct *wq)
4667{
4668 lockdep_unregister_key(&wq->key);
4669}
4670
4671static void wq_free_lockdep(struct workqueue_struct *wq)
4672{
4673 if (wq->lock_name != wq->name)
4674 kfree(wq->lock_name);
4675}
4676#else
4677static void wq_init_lockdep(struct workqueue_struct *wq)
4678{
4679}
4680
4681static void wq_unregister_lockdep(struct workqueue_struct *wq)
4682{
4683}
4684
4685static void wq_free_lockdep(struct workqueue_struct *wq)
4686{
4687}
4688#endif
4689
4690static void free_node_nr_active(struct wq_node_nr_active **nna_ar)
4691{
4692 int node;
4693
4694 for_each_node(node) {
4695 kfree(nna_ar[node]);
4696 nna_ar[node] = NULL;
4697 }
4698
4699 kfree(nna_ar[nr_node_ids]);
4700 nna_ar[nr_node_ids] = NULL;
4701}
4702
4703static void init_node_nr_active(struct wq_node_nr_active *nna)
4704{
4705 nna->max = WQ_DFL_MIN_ACTIVE;
4706 atomic_set(&nna->nr, 0);
4707 raw_spin_lock_init(&nna->lock);
4708 INIT_LIST_HEAD(&nna->pending_pwqs);
4709}
4710
4711/*
4712 * Each node's nr_active counter will be accessed mostly from its own node and
4713 * should be allocated in the node.
4714 */
4715static int alloc_node_nr_active(struct wq_node_nr_active **nna_ar)
4716{
4717 struct wq_node_nr_active *nna;
4718 int node;
4719
4720 for_each_node(node) {
4721 nna = kzalloc_node(sizeof(*nna), GFP_KERNEL, node);
4722 if (!nna)
4723 goto err_free;
4724 init_node_nr_active(nna);
4725 nna_ar[node] = nna;
4726 }
4727
4728 /* [nr_node_ids] is used as the fallback */
4729 nna = kzalloc_node(sizeof(*nna), GFP_KERNEL, NUMA_NO_NODE);
4730 if (!nna)
4731 goto err_free;
4732 init_node_nr_active(nna);
4733 nna_ar[nr_node_ids] = nna;
4734
4735 return 0;
4736
4737err_free:
4738 free_node_nr_active(nna_ar);
4739 return -ENOMEM;
4740}
4741
4742static void rcu_free_wq(struct rcu_head *rcu)
4743{
4744 struct workqueue_struct *wq =
4745 container_of(rcu, struct workqueue_struct, rcu);
4746
4747 if (wq->flags & WQ_UNBOUND)
4748 free_node_nr_active(wq->node_nr_active);
4749
4750 wq_free_lockdep(wq);
4751 free_percpu(wq->cpu_pwq);
4752 free_workqueue_attrs(wq->unbound_attrs);
4753 kfree(wq);
4754}
4755
4756static void rcu_free_pool(struct rcu_head *rcu)
4757{
4758 struct worker_pool *pool = container_of(rcu, struct worker_pool, rcu);
4759
4760 ida_destroy(&pool->worker_ida);
4761 free_workqueue_attrs(pool->attrs);
4762 kfree(pool);
4763}
4764
4765/**
4766 * put_unbound_pool - put a worker_pool
4767 * @pool: worker_pool to put
4768 *
4769 * Put @pool. If its refcnt reaches zero, it gets destroyed in RCU
4770 * safe manner. get_unbound_pool() calls this function on its failure path
4771 * and this function should be able to release pools which went through,
4772 * successfully or not, init_worker_pool().
4773 *
4774 * Should be called with wq_pool_mutex held.
4775 */
4776static void put_unbound_pool(struct worker_pool *pool)
4777{
4778 DECLARE_COMPLETION_ONSTACK(detach_completion);
4779 struct worker *worker;
4780 LIST_HEAD(cull_list);
4781
4782 lockdep_assert_held(&wq_pool_mutex);
4783
4784 if (--pool->refcnt)
4785 return;
4786
4787 /* sanity checks */
4788 if (WARN_ON(!(pool->cpu < 0)) ||
4789 WARN_ON(!list_empty(&pool->worklist)))
4790 return;
4791
4792 /* release id and unhash */
4793 if (pool->id >= 0)
4794 idr_remove(&worker_pool_idr, pool->id);
4795 hash_del(&pool->hash_node);
4796
4797 /*
4798 * Become the manager and destroy all workers. This prevents
4799 * @pool's workers from blocking on attach_mutex. We're the last
4800 * manager and @pool gets freed with the flag set.
4801 *
4802 * Having a concurrent manager is quite unlikely to happen as we can
4803 * only get here with
4804 * pwq->refcnt == pool->refcnt == 0
4805 * which implies no work queued to the pool, which implies no worker can
4806 * become the manager. However a worker could have taken the role of
4807 * manager before the refcnts dropped to 0, since maybe_create_worker()
4808 * drops pool->lock
4809 */
4810 while (true) {
4811 rcuwait_wait_event(&manager_wait,
4812 !(pool->flags & POOL_MANAGER_ACTIVE),
4813 TASK_UNINTERRUPTIBLE);
4814
4815 mutex_lock(&wq_pool_attach_mutex);
4816 raw_spin_lock_irq(&pool->lock);
4817 if (!(pool->flags & POOL_MANAGER_ACTIVE)) {
4818 pool->flags |= POOL_MANAGER_ACTIVE;
4819 break;
4820 }
4821 raw_spin_unlock_irq(&pool->lock);
4822 mutex_unlock(&wq_pool_attach_mutex);
4823 }
4824
4825 while ((worker = first_idle_worker(pool)))
4826 set_worker_dying(worker, &cull_list);
4827 WARN_ON(pool->nr_workers || pool->nr_idle);
4828 raw_spin_unlock_irq(&pool->lock);
4829
4830 wake_dying_workers(&cull_list);
4831
4832 if (!list_empty(&pool->workers) || !list_empty(&pool->dying_workers))
4833 pool->detach_completion = &detach_completion;
4834 mutex_unlock(&wq_pool_attach_mutex);
4835
4836 if (pool->detach_completion)
4837 wait_for_completion(pool->detach_completion);
4838
4839 /* shut down the timers */
4840 del_timer_sync(&pool->idle_timer);
4841 cancel_work_sync(&pool->idle_cull_work);
4842 del_timer_sync(&pool->mayday_timer);
4843
4844 /* RCU protected to allow dereferences from get_work_pool() */
4845 call_rcu(&pool->rcu, rcu_free_pool);
4846}
4847
4848/**
4849 * get_unbound_pool - get a worker_pool with the specified attributes
4850 * @attrs: the attributes of the worker_pool to get
4851 *
4852 * Obtain a worker_pool which has the same attributes as @attrs, bump the
4853 * reference count and return it. If there already is a matching
4854 * worker_pool, it will be used; otherwise, this function attempts to
4855 * create a new one.
4856 *
4857 * Should be called with wq_pool_mutex held.
4858 *
4859 * Return: On success, a worker_pool with the same attributes as @attrs.
4860 * On failure, %NULL.
4861 */
4862static struct worker_pool *get_unbound_pool(const struct workqueue_attrs *attrs)
4863{
4864 struct wq_pod_type *pt = &wq_pod_types[WQ_AFFN_NUMA];
4865 u32 hash = wqattrs_hash(attrs);
4866 struct worker_pool *pool;
4867 int pod, node = NUMA_NO_NODE;
4868
4869 lockdep_assert_held(&wq_pool_mutex);
4870
4871 /* do we already have a matching pool? */
4872 hash_for_each_possible(unbound_pool_hash, pool, hash_node, hash) {
4873 if (wqattrs_equal(pool->attrs, attrs)) {
4874 pool->refcnt++;
4875 return pool;
4876 }
4877 }
4878
4879 /* If __pod_cpumask is contained inside a NUMA pod, that's our node */
4880 for (pod = 0; pod < pt->nr_pods; pod++) {
4881 if (cpumask_subset(attrs->__pod_cpumask, pt->pod_cpus[pod])) {
4882 node = pt->pod_node[pod];
4883 break;
4884 }
4885 }
4886
4887 /* nope, create a new one */
4888 pool = kzalloc_node(sizeof(*pool), GFP_KERNEL, node);
4889 if (!pool || init_worker_pool(pool) < 0)
4890 goto fail;
4891
4892 pool->node = node;
4893 copy_workqueue_attrs(pool->attrs, attrs);
4894 wqattrs_clear_for_pool(pool->attrs);
4895
4896 if (worker_pool_assign_id(pool) < 0)
4897 goto fail;
4898
4899 /* create and start the initial worker */
4900 if (wq_online && !create_worker(pool))
4901 goto fail;
4902
4903 /* install */
4904 hash_add(unbound_pool_hash, &pool->hash_node, hash);
4905
4906 return pool;
4907fail:
4908 if (pool)
4909 put_unbound_pool(pool);
4910 return NULL;
4911}
4912
4913static void rcu_free_pwq(struct rcu_head *rcu)
4914{
4915 kmem_cache_free(pwq_cache,
4916 container_of(rcu, struct pool_workqueue, rcu));
4917}
4918
4919/*
4920 * Scheduled on pwq_release_worker by put_pwq() when an unbound pwq hits zero
4921 * refcnt and needs to be destroyed.
4922 */
4923static void pwq_release_workfn(struct kthread_work *work)
4924{
4925 struct pool_workqueue *pwq = container_of(work, struct pool_workqueue,
4926 release_work);
4927 struct workqueue_struct *wq = pwq->wq;
4928 struct worker_pool *pool = pwq->pool;
4929 bool is_last = false;
4930
4931 /*
4932 * When @pwq is not linked, it doesn't hold any reference to the
4933 * @wq, and @wq is invalid to access.
4934 */
4935 if (!list_empty(&pwq->pwqs_node)) {
4936 mutex_lock(&wq->mutex);
4937 list_del_rcu(&pwq->pwqs_node);
4938 is_last = list_empty(&wq->pwqs);
4939
4940 /*
4941 * For ordered workqueue with a plugged dfl_pwq, restart it now.
4942 */
4943 if (!is_last && (wq->flags & __WQ_ORDERED))
4944 unplug_oldest_pwq(wq);
4945
4946 mutex_unlock(&wq->mutex);
4947 }
4948
4949 if (wq->flags & WQ_UNBOUND) {
4950 mutex_lock(&wq_pool_mutex);
4951 put_unbound_pool(pool);
4952 mutex_unlock(&wq_pool_mutex);
4953 }
4954
4955 if (!list_empty(&pwq->pending_node)) {
4956 struct wq_node_nr_active *nna =
4957 wq_node_nr_active(pwq->wq, pwq->pool->node);
4958
4959 raw_spin_lock_irq(&nna->lock);
4960 list_del_init(&pwq->pending_node);
4961 raw_spin_unlock_irq(&nna->lock);
4962 }
4963
4964 call_rcu(&pwq->rcu, rcu_free_pwq);
4965
4966 /*
4967 * If we're the last pwq going away, @wq is already dead and no one
4968 * is gonna access it anymore. Schedule RCU free.
4969 */
4970 if (is_last) {
4971 wq_unregister_lockdep(wq);
4972 call_rcu(&wq->rcu, rcu_free_wq);
4973 }
4974}
4975
4976/* initialize newly allocated @pwq which is associated with @wq and @pool */
4977static void init_pwq(struct pool_workqueue *pwq, struct workqueue_struct *wq,
4978 struct worker_pool *pool)
4979{
4980 BUG_ON((unsigned long)pwq & ~WORK_STRUCT_PWQ_MASK);
4981
4982 memset(pwq, 0, sizeof(*pwq));
4983
4984 pwq->pool = pool;
4985 pwq->wq = wq;
4986 pwq->flush_color = -1;
4987 pwq->refcnt = 1;
4988 INIT_LIST_HEAD(&pwq->inactive_works);
4989 INIT_LIST_HEAD(&pwq->pending_node);
4990 INIT_LIST_HEAD(&pwq->pwqs_node);
4991 INIT_LIST_HEAD(&pwq->mayday_node);
4992 kthread_init_work(&pwq->release_work, pwq_release_workfn);
4993}
4994
4995/* sync @pwq with the current state of its associated wq and link it */
4996static void link_pwq(struct pool_workqueue *pwq)
4997{
4998 struct workqueue_struct *wq = pwq->wq;
4999
5000 lockdep_assert_held(&wq->mutex);
5001
5002 /* may be called multiple times, ignore if already linked */
5003 if (!list_empty(&pwq->pwqs_node))
5004 return;
5005
5006 /* set the matching work_color */
5007 pwq->work_color = wq->work_color;
5008
5009 /* link in @pwq */
5010 list_add_tail_rcu(&pwq->pwqs_node, &wq->pwqs);
5011}
5012
5013/* obtain a pool matching @attr and create a pwq associating the pool and @wq */
5014static struct pool_workqueue *alloc_unbound_pwq(struct workqueue_struct *wq,
5015 const struct workqueue_attrs *attrs)
5016{
5017 struct worker_pool *pool;
5018 struct pool_workqueue *pwq;
5019
5020 lockdep_assert_held(&wq_pool_mutex);
5021
5022 pool = get_unbound_pool(attrs);
5023 if (!pool)
5024 return NULL;
5025
5026 pwq = kmem_cache_alloc_node(pwq_cache, GFP_KERNEL, pool->node);
5027 if (!pwq) {
5028 put_unbound_pool(pool);
5029 return NULL;
5030 }
5031
5032 init_pwq(pwq, wq, pool);
5033 return pwq;
5034}
5035
5036/**
5037 * wq_calc_pod_cpumask - calculate a wq_attrs' cpumask for a pod
5038 * @attrs: the wq_attrs of the default pwq of the target workqueue
5039 * @cpu: the target CPU
5040 * @cpu_going_down: if >= 0, the CPU to consider as offline
5041 *
5042 * Calculate the cpumask a workqueue with @attrs should use on @pod. If
5043 * @cpu_going_down is >= 0, that cpu is considered offline during calculation.
5044 * The result is stored in @attrs->__pod_cpumask.
5045 *
5046 * If pod affinity is not enabled, @attrs->cpumask is always used. If enabled
5047 * and @pod has online CPUs requested by @attrs, the returned cpumask is the
5048 * intersection of the possible CPUs of @pod and @attrs->cpumask.
5049 *
5050 * The caller is responsible for ensuring that the cpumask of @pod stays stable.
5051 */
5052static void wq_calc_pod_cpumask(struct workqueue_attrs *attrs, int cpu,
5053 int cpu_going_down)
5054{
5055 const struct wq_pod_type *pt = wqattrs_pod_type(attrs);
5056 int pod = pt->cpu_pod[cpu];
5057
5058 /* does @pod have any online CPUs @attrs wants? */
5059 cpumask_and(attrs->__pod_cpumask, pt->pod_cpus[pod], attrs->cpumask);
5060 cpumask_and(attrs->__pod_cpumask, attrs->__pod_cpumask, cpu_online_mask);
5061 if (cpu_going_down >= 0)
5062 cpumask_clear_cpu(cpu_going_down, attrs->__pod_cpumask);
5063
5064 if (cpumask_empty(attrs->__pod_cpumask)) {
5065 cpumask_copy(attrs->__pod_cpumask, attrs->cpumask);
5066 return;
5067 }
5068
5069 /* yeap, return possible CPUs in @pod that @attrs wants */
5070 cpumask_and(attrs->__pod_cpumask, attrs->cpumask, pt->pod_cpus[pod]);
5071
5072 if (cpumask_empty(attrs->__pod_cpumask))
5073 pr_warn_once("WARNING: workqueue cpumask: online intersect > "
5074 "possible intersect\n");
5075}
5076
5077/* install @pwq into @wq and return the old pwq, @cpu < 0 for dfl_pwq */
5078static struct pool_workqueue *install_unbound_pwq(struct workqueue_struct *wq,
5079 int cpu, struct pool_workqueue *pwq)
5080{
5081 struct pool_workqueue __rcu **slot = unbound_pwq_slot(wq, cpu);
5082 struct pool_workqueue *old_pwq;
5083
5084 lockdep_assert_held(&wq_pool_mutex);
5085 lockdep_assert_held(&wq->mutex);
5086
5087 /* link_pwq() can handle duplicate calls */
5088 link_pwq(pwq);
5089
5090 old_pwq = rcu_access_pointer(*slot);
5091 rcu_assign_pointer(*slot, pwq);
5092 return old_pwq;
5093}
5094
5095/* context to store the prepared attrs & pwqs before applying */
5096struct apply_wqattrs_ctx {
5097 struct workqueue_struct *wq; /* target workqueue */
5098 struct workqueue_attrs *attrs; /* attrs to apply */
5099 struct list_head list; /* queued for batching commit */
5100 struct pool_workqueue *dfl_pwq;
5101 struct pool_workqueue *pwq_tbl[];
5102};
5103
5104/* free the resources after success or abort */
5105static void apply_wqattrs_cleanup(struct apply_wqattrs_ctx *ctx)
5106{
5107 if (ctx) {
5108 int cpu;
5109
5110 for_each_possible_cpu(cpu)
5111 put_pwq_unlocked(ctx->pwq_tbl[cpu]);
5112 put_pwq_unlocked(ctx->dfl_pwq);
5113
5114 free_workqueue_attrs(ctx->attrs);
5115
5116 kfree(ctx);
5117 }
5118}
5119
5120/* allocate the attrs and pwqs for later installation */
5121static struct apply_wqattrs_ctx *
5122apply_wqattrs_prepare(struct workqueue_struct *wq,
5123 const struct workqueue_attrs *attrs,
5124 const cpumask_var_t unbound_cpumask)
5125{
5126 struct apply_wqattrs_ctx *ctx;
5127 struct workqueue_attrs *new_attrs;
5128 int cpu;
5129
5130 lockdep_assert_held(&wq_pool_mutex);
5131
5132 if (WARN_ON(attrs->affn_scope < 0 ||
5133 attrs->affn_scope >= WQ_AFFN_NR_TYPES))
5134 return ERR_PTR(-EINVAL);
5135
5136 ctx = kzalloc(struct_size(ctx, pwq_tbl, nr_cpu_ids), GFP_KERNEL);
5137
5138 new_attrs = alloc_workqueue_attrs();
5139 if (!ctx || !new_attrs)
5140 goto out_free;
5141
5142 /*
5143 * If something goes wrong during CPU up/down, we'll fall back to
5144 * the default pwq covering whole @attrs->cpumask. Always create
5145 * it even if we don't use it immediately.
5146 */
5147 copy_workqueue_attrs(new_attrs, attrs);
5148 wqattrs_actualize_cpumask(new_attrs, unbound_cpumask);
5149 cpumask_copy(new_attrs->__pod_cpumask, new_attrs->cpumask);
5150 ctx->dfl_pwq = alloc_unbound_pwq(wq, new_attrs);
5151 if (!ctx->dfl_pwq)
5152 goto out_free;
5153
5154 for_each_possible_cpu(cpu) {
5155 if (new_attrs->ordered) {
5156 ctx->dfl_pwq->refcnt++;
5157 ctx->pwq_tbl[cpu] = ctx->dfl_pwq;
5158 } else {
5159 wq_calc_pod_cpumask(new_attrs, cpu, -1);
5160 ctx->pwq_tbl[cpu] = alloc_unbound_pwq(wq, new_attrs);
5161 if (!ctx->pwq_tbl[cpu])
5162 goto out_free;
5163 }
5164 }
5165
5166 /* save the user configured attrs and sanitize it. */
5167 copy_workqueue_attrs(new_attrs, attrs);
5168 cpumask_and(new_attrs->cpumask, new_attrs->cpumask, cpu_possible_mask);
5169 cpumask_copy(new_attrs->__pod_cpumask, new_attrs->cpumask);
5170 ctx->attrs = new_attrs;
5171
5172 /*
5173 * For initialized ordered workqueues, there should only be one pwq
5174 * (dfl_pwq). Set the plugged flag of ctx->dfl_pwq to suspend execution
5175 * of newly queued work items until execution of older work items in
5176 * the old pwq's have completed.
5177 */
5178 if ((wq->flags & __WQ_ORDERED) && !list_empty(&wq->pwqs))
5179 ctx->dfl_pwq->plugged = true;
5180
5181 ctx->wq = wq;
5182 return ctx;
5183
5184out_free:
5185 free_workqueue_attrs(new_attrs);
5186 apply_wqattrs_cleanup(ctx);
5187 return ERR_PTR(-ENOMEM);
5188}
5189
5190/* set attrs and install prepared pwqs, @ctx points to old pwqs on return */
5191static void apply_wqattrs_commit(struct apply_wqattrs_ctx *ctx)
5192{
5193 int cpu;
5194
5195 /* all pwqs have been created successfully, let's install'em */
5196 mutex_lock(&ctx->wq->mutex);
5197
5198 copy_workqueue_attrs(ctx->wq->unbound_attrs, ctx->attrs);
5199
5200 /* save the previous pwqs and install the new ones */
5201 for_each_possible_cpu(cpu)
5202 ctx->pwq_tbl[cpu] = install_unbound_pwq(ctx->wq, cpu,
5203 ctx->pwq_tbl[cpu]);
5204 ctx->dfl_pwq = install_unbound_pwq(ctx->wq, -1, ctx->dfl_pwq);
5205
5206 /* update node_nr_active->max */
5207 wq_update_node_max_active(ctx->wq, -1);
5208
5209 /* rescuer needs to respect wq cpumask changes */
5210 if (ctx->wq->rescuer)
5211 set_cpus_allowed_ptr(ctx->wq->rescuer->task,
5212 unbound_effective_cpumask(ctx->wq));
5213
5214 mutex_unlock(&ctx->wq->mutex);
5215}
5216
5217static int apply_workqueue_attrs_locked(struct workqueue_struct *wq,
5218 const struct workqueue_attrs *attrs)
5219{
5220 struct apply_wqattrs_ctx *ctx;
5221
5222 /* only unbound workqueues can change attributes */
5223 if (WARN_ON(!(wq->flags & WQ_UNBOUND)))
5224 return -EINVAL;
5225
5226 ctx = apply_wqattrs_prepare(wq, attrs, wq_unbound_cpumask);
5227 if (IS_ERR(ctx))
5228 return PTR_ERR(ctx);
5229
5230 /* the ctx has been prepared successfully, let's commit it */
5231 apply_wqattrs_commit(ctx);
5232 apply_wqattrs_cleanup(ctx);
5233
5234 return 0;
5235}
5236
5237/**
5238 * apply_workqueue_attrs - apply new workqueue_attrs to an unbound workqueue
5239 * @wq: the target workqueue
5240 * @attrs: the workqueue_attrs to apply, allocated with alloc_workqueue_attrs()
5241 *
5242 * Apply @attrs to an unbound workqueue @wq. Unless disabled, this function maps
5243 * a separate pwq to each CPU pod with possibles CPUs in @attrs->cpumask so that
5244 * work items are affine to the pod it was issued on. Older pwqs are released as
5245 * in-flight work items finish. Note that a work item which repeatedly requeues
5246 * itself back-to-back will stay on its current pwq.
5247 *
5248 * Performs GFP_KERNEL allocations.
5249 *
5250 * Assumes caller has CPU hotplug read exclusion, i.e. cpus_read_lock().
5251 *
5252 * Return: 0 on success and -errno on failure.
5253 */
5254int apply_workqueue_attrs(struct workqueue_struct *wq,
5255 const struct workqueue_attrs *attrs)
5256{
5257 int ret;
5258
5259 lockdep_assert_cpus_held();
5260
5261 mutex_lock(&wq_pool_mutex);
5262 ret = apply_workqueue_attrs_locked(wq, attrs);
5263 mutex_unlock(&wq_pool_mutex);
5264
5265 return ret;
5266}
5267
5268/**
5269 * wq_update_pod - update pod affinity of a wq for CPU hot[un]plug
5270 * @wq: the target workqueue
5271 * @cpu: the CPU to update pool association for
5272 * @hotplug_cpu: the CPU coming up or going down
5273 * @online: whether @cpu is coming up or going down
5274 *
5275 * This function is to be called from %CPU_DOWN_PREPARE, %CPU_ONLINE and
5276 * %CPU_DOWN_FAILED. @cpu is being hot[un]plugged, update pod affinity of
5277 * @wq accordingly.
5278 *
5279 *
5280 * If pod affinity can't be adjusted due to memory allocation failure, it falls
5281 * back to @wq->dfl_pwq which may not be optimal but is always correct.
5282 *
5283 * Note that when the last allowed CPU of a pod goes offline for a workqueue
5284 * with a cpumask spanning multiple pods, the workers which were already
5285 * executing the work items for the workqueue will lose their CPU affinity and
5286 * may execute on any CPU. This is similar to how per-cpu workqueues behave on
5287 * CPU_DOWN. If a workqueue user wants strict affinity, it's the user's
5288 * responsibility to flush the work item from CPU_DOWN_PREPARE.
5289 */
5290static void wq_update_pod(struct workqueue_struct *wq, int cpu,
5291 int hotplug_cpu, bool online)
5292{
5293 int off_cpu = online ? -1 : hotplug_cpu;
5294 struct pool_workqueue *old_pwq = NULL, *pwq;
5295 struct workqueue_attrs *target_attrs;
5296
5297 lockdep_assert_held(&wq_pool_mutex);
5298
5299 if (!(wq->flags & WQ_UNBOUND) || wq->unbound_attrs->ordered)
5300 return;
5301
5302 /*
5303 * We don't wanna alloc/free wq_attrs for each wq for each CPU.
5304 * Let's use a preallocated one. The following buf is protected by
5305 * CPU hotplug exclusion.
5306 */
5307 target_attrs = wq_update_pod_attrs_buf;
5308
5309 copy_workqueue_attrs(target_attrs, wq->unbound_attrs);
5310 wqattrs_actualize_cpumask(target_attrs, wq_unbound_cpumask);
5311
5312 /* nothing to do if the target cpumask matches the current pwq */
5313 wq_calc_pod_cpumask(target_attrs, cpu, off_cpu);
5314 if (wqattrs_equal(target_attrs, unbound_pwq(wq, cpu)->pool->attrs))
5315 return;
5316
5317 /* create a new pwq */
5318 pwq = alloc_unbound_pwq(wq, target_attrs);
5319 if (!pwq) {
5320 pr_warn("workqueue: allocation failed while updating CPU pod affinity of \"%s\"\n",
5321 wq->name);
5322 goto use_dfl_pwq;
5323 }
5324
5325 /* Install the new pwq. */
5326 mutex_lock(&wq->mutex);
5327 old_pwq = install_unbound_pwq(wq, cpu, pwq);
5328 goto out_unlock;
5329
5330use_dfl_pwq:
5331 mutex_lock(&wq->mutex);
5332 pwq = unbound_pwq(wq, -1);
5333 raw_spin_lock_irq(&pwq->pool->lock);
5334 get_pwq(pwq);
5335 raw_spin_unlock_irq(&pwq->pool->lock);
5336 old_pwq = install_unbound_pwq(wq, cpu, pwq);
5337out_unlock:
5338 mutex_unlock(&wq->mutex);
5339 put_pwq_unlocked(old_pwq);
5340}
5341
5342static int alloc_and_link_pwqs(struct workqueue_struct *wq)
5343{
5344 bool highpri = wq->flags & WQ_HIGHPRI;
5345 int cpu, ret;
5346
5347 wq->cpu_pwq = alloc_percpu(struct pool_workqueue *);
5348 if (!wq->cpu_pwq)
5349 goto enomem;
5350
5351 if (!(wq->flags & WQ_UNBOUND)) {
5352 for_each_possible_cpu(cpu) {
5353 struct pool_workqueue **pwq_p;
5354 struct worker_pool __percpu *pools;
5355 struct worker_pool *pool;
5356
5357 if (wq->flags & WQ_BH)
5358 pools = bh_worker_pools;
5359 else
5360 pools = cpu_worker_pools;
5361
5362 pool = &(per_cpu_ptr(pools, cpu)[highpri]);
5363 pwq_p = per_cpu_ptr(wq->cpu_pwq, cpu);
5364
5365 *pwq_p = kmem_cache_alloc_node(pwq_cache, GFP_KERNEL,
5366 pool->node);
5367 if (!*pwq_p)
5368 goto enomem;
5369
5370 init_pwq(*pwq_p, wq, pool);
5371
5372 mutex_lock(&wq->mutex);
5373 link_pwq(*pwq_p);
5374 mutex_unlock(&wq->mutex);
5375 }
5376 return 0;
5377 }
5378
5379 cpus_read_lock();
5380 if (wq->flags & __WQ_ORDERED) {
5381 struct pool_workqueue *dfl_pwq;
5382
5383 ret = apply_workqueue_attrs(wq, ordered_wq_attrs[highpri]);
5384 /* there should only be single pwq for ordering guarantee */
5385 dfl_pwq = rcu_access_pointer(wq->dfl_pwq);
5386 WARN(!ret && (wq->pwqs.next != &dfl_pwq->pwqs_node ||
5387 wq->pwqs.prev != &dfl_pwq->pwqs_node),
5388 "ordering guarantee broken for workqueue %s\n", wq->name);
5389 } else {
5390 ret = apply_workqueue_attrs(wq, unbound_std_wq_attrs[highpri]);
5391 }
5392 cpus_read_unlock();
5393
5394 /* for unbound pwq, flush the pwq_release_worker ensures that the
5395 * pwq_release_workfn() completes before calling kfree(wq).
5396 */
5397 if (ret)
5398 kthread_flush_worker(pwq_release_worker);
5399
5400 return ret;
5401
5402enomem:
5403 if (wq->cpu_pwq) {
5404 for_each_possible_cpu(cpu) {
5405 struct pool_workqueue *pwq = *per_cpu_ptr(wq->cpu_pwq, cpu);
5406
5407 if (pwq)
5408 kmem_cache_free(pwq_cache, pwq);
5409 }
5410 free_percpu(wq->cpu_pwq);
5411 wq->cpu_pwq = NULL;
5412 }
5413 return -ENOMEM;
5414}
5415
5416static int wq_clamp_max_active(int max_active, unsigned int flags,
5417 const char *name)
5418{
5419 if (max_active < 1 || max_active > WQ_MAX_ACTIVE)
5420 pr_warn("workqueue: max_active %d requested for %s is out of range, clamping between %d and %d\n",
5421 max_active, name, 1, WQ_MAX_ACTIVE);
5422
5423 return clamp_val(max_active, 1, WQ_MAX_ACTIVE);
5424}
5425
5426/*
5427 * Workqueues which may be used during memory reclaim should have a rescuer
5428 * to guarantee forward progress.
5429 */
5430static int init_rescuer(struct workqueue_struct *wq)
5431{
5432 struct worker *rescuer;
5433 int ret;
5434
5435 if (!(wq->flags & WQ_MEM_RECLAIM))
5436 return 0;
5437
5438 rescuer = alloc_worker(NUMA_NO_NODE);
5439 if (!rescuer) {
5440 pr_err("workqueue: Failed to allocate a rescuer for wq \"%s\"\n",
5441 wq->name);
5442 return -ENOMEM;
5443 }
5444
5445 rescuer->rescue_wq = wq;
5446 rescuer->task = kthread_create(rescuer_thread, rescuer, "kworker/R-%s", wq->name);
5447 if (IS_ERR(rescuer->task)) {
5448 ret = PTR_ERR(rescuer->task);
5449 pr_err("workqueue: Failed to create a rescuer kthread for wq \"%s\": %pe",
5450 wq->name, ERR_PTR(ret));
5451 kfree(rescuer);
5452 return ret;
5453 }
5454
5455 wq->rescuer = rescuer;
5456 if (wq->flags & WQ_UNBOUND)
5457 kthread_bind_mask(rescuer->task, wq_unbound_cpumask);
5458 else
5459 kthread_bind_mask(rescuer->task, cpu_possible_mask);
5460 wake_up_process(rescuer->task);
5461
5462 return 0;
5463}
5464
5465/**
5466 * wq_adjust_max_active - update a wq's max_active to the current setting
5467 * @wq: target workqueue
5468 *
5469 * If @wq isn't freezing, set @wq->max_active to the saved_max_active and
5470 * activate inactive work items accordingly. If @wq is freezing, clear
5471 * @wq->max_active to zero.
5472 */
5473static void wq_adjust_max_active(struct workqueue_struct *wq)
5474{
5475 bool activated;
5476 int new_max, new_min;
5477
5478 lockdep_assert_held(&wq->mutex);
5479
5480 if ((wq->flags & WQ_FREEZABLE) && workqueue_freezing) {
5481 new_max = 0;
5482 new_min = 0;
5483 } else {
5484 new_max = wq->saved_max_active;
5485 new_min = wq->saved_min_active;
5486 }
5487
5488 if (wq->max_active == new_max && wq->min_active == new_min)
5489 return;
5490
5491 /*
5492 * Update @wq->max/min_active and then kick inactive work items if more
5493 * active work items are allowed. This doesn't break work item ordering
5494 * because new work items are always queued behind existing inactive
5495 * work items if there are any.
5496 */
5497 WRITE_ONCE(wq->max_active, new_max);
5498 WRITE_ONCE(wq->min_active, new_min);
5499
5500 if (wq->flags & WQ_UNBOUND)
5501 wq_update_node_max_active(wq, -1);
5502
5503 if (new_max == 0)
5504 return;
5505
5506 /*
5507 * Round-robin through pwq's activating the first inactive work item
5508 * until max_active is filled.
5509 */
5510 do {
5511 struct pool_workqueue *pwq;
5512
5513 activated = false;
5514 for_each_pwq(pwq, wq) {
5515 unsigned long irq_flags;
5516
5517 /* can be called during early boot w/ irq disabled */
5518 raw_spin_lock_irqsave(&pwq->pool->lock, irq_flags);
5519 if (pwq_activate_first_inactive(pwq, true)) {
5520 activated = true;
5521 kick_pool(pwq->pool);
5522 }
5523 raw_spin_unlock_irqrestore(&pwq->pool->lock, irq_flags);
5524 }
5525 } while (activated);
5526}
5527
5528__printf(1, 4)
5529struct workqueue_struct *alloc_workqueue(const char *fmt,
5530 unsigned int flags,
5531 int max_active, ...)
5532{
5533 va_list args;
5534 struct workqueue_struct *wq;
5535 size_t wq_size;
5536 int name_len;
5537
5538 if (flags & WQ_BH) {
5539 if (WARN_ON_ONCE(flags & ~__WQ_BH_ALLOWS))
5540 return NULL;
5541 if (WARN_ON_ONCE(max_active))
5542 return NULL;
5543 }
5544
5545 /* see the comment above the definition of WQ_POWER_EFFICIENT */
5546 if ((flags & WQ_POWER_EFFICIENT) && wq_power_efficient)
5547 flags |= WQ_UNBOUND;
5548
5549 /* allocate wq and format name */
5550 if (flags & WQ_UNBOUND)
5551 wq_size = struct_size(wq, node_nr_active, nr_node_ids + 1);
5552 else
5553 wq_size = sizeof(*wq);
5554
5555 wq = kzalloc(wq_size, GFP_KERNEL);
5556 if (!wq)
5557 return NULL;
5558
5559 if (flags & WQ_UNBOUND) {
5560 wq->unbound_attrs = alloc_workqueue_attrs();
5561 if (!wq->unbound_attrs)
5562 goto err_free_wq;
5563 }
5564
5565 va_start(args, max_active);
5566 name_len = vsnprintf(wq->name, sizeof(wq->name), fmt, args);
5567 va_end(args);
5568
5569 if (name_len >= WQ_NAME_LEN)
5570 pr_warn_once("workqueue: name exceeds WQ_NAME_LEN. Truncating to: %s\n",
5571 wq->name);
5572
5573 if (flags & WQ_BH) {
5574 /*
5575 * BH workqueues always share a single execution context per CPU
5576 * and don't impose any max_active limit.
5577 */
5578 max_active = INT_MAX;
5579 } else {
5580 max_active = max_active ?: WQ_DFL_ACTIVE;
5581 max_active = wq_clamp_max_active(max_active, flags, wq->name);
5582 }
5583
5584 /* init wq */
5585 wq->flags = flags;
5586 wq->max_active = max_active;
5587 wq->min_active = min(max_active, WQ_DFL_MIN_ACTIVE);
5588 wq->saved_max_active = wq->max_active;
5589 wq->saved_min_active = wq->min_active;
5590 mutex_init(&wq->mutex);
5591 atomic_set(&wq->nr_pwqs_to_flush, 0);
5592 INIT_LIST_HEAD(&wq->pwqs);
5593 INIT_LIST_HEAD(&wq->flusher_queue);
5594 INIT_LIST_HEAD(&wq->flusher_overflow);
5595 INIT_LIST_HEAD(&wq->maydays);
5596
5597 wq_init_lockdep(wq);
5598 INIT_LIST_HEAD(&wq->list);
5599
5600 if (flags & WQ_UNBOUND) {
5601 if (alloc_node_nr_active(wq->node_nr_active) < 0)
5602 goto err_unreg_lockdep;
5603 }
5604
5605 if (alloc_and_link_pwqs(wq) < 0)
5606 goto err_free_node_nr_active;
5607
5608 if (wq_online && init_rescuer(wq) < 0)
5609 goto err_destroy;
5610
5611 if ((wq->flags & WQ_SYSFS) && workqueue_sysfs_register(wq))
5612 goto err_destroy;
5613
5614 /*
5615 * wq_pool_mutex protects global freeze state and workqueues list.
5616 * Grab it, adjust max_active and add the new @wq to workqueues
5617 * list.
5618 */
5619 mutex_lock(&wq_pool_mutex);
5620
5621 mutex_lock(&wq->mutex);
5622 wq_adjust_max_active(wq);
5623 mutex_unlock(&wq->mutex);
5624
5625 list_add_tail_rcu(&wq->list, &workqueues);
5626
5627 mutex_unlock(&wq_pool_mutex);
5628
5629 return wq;
5630
5631err_free_node_nr_active:
5632 if (wq->flags & WQ_UNBOUND)
5633 free_node_nr_active(wq->node_nr_active);
5634err_unreg_lockdep:
5635 wq_unregister_lockdep(wq);
5636 wq_free_lockdep(wq);
5637err_free_wq:
5638 free_workqueue_attrs(wq->unbound_attrs);
5639 kfree(wq);
5640 return NULL;
5641err_destroy:
5642 destroy_workqueue(wq);
5643 return NULL;
5644}
5645EXPORT_SYMBOL_GPL(alloc_workqueue);
5646
5647static bool pwq_busy(struct pool_workqueue *pwq)
5648{
5649 int i;
5650
5651 for (i = 0; i < WORK_NR_COLORS; i++)
5652 if (pwq->nr_in_flight[i])
5653 return true;
5654
5655 if ((pwq != rcu_access_pointer(pwq->wq->dfl_pwq)) && (pwq->refcnt > 1))
5656 return true;
5657 if (!pwq_is_empty(pwq))
5658 return true;
5659
5660 return false;
5661}
5662
5663/**
5664 * destroy_workqueue - safely terminate a workqueue
5665 * @wq: target workqueue
5666 *
5667 * Safely destroy a workqueue. All work currently pending will be done first.
5668 */
5669void destroy_workqueue(struct workqueue_struct *wq)
5670{
5671 struct pool_workqueue *pwq;
5672 int cpu;
5673
5674 /*
5675 * Remove it from sysfs first so that sanity check failure doesn't
5676 * lead to sysfs name conflicts.
5677 */
5678 workqueue_sysfs_unregister(wq);
5679
5680 /* mark the workqueue destruction is in progress */
5681 mutex_lock(&wq->mutex);
5682 wq->flags |= __WQ_DESTROYING;
5683 mutex_unlock(&wq->mutex);
5684
5685 /* drain it before proceeding with destruction */
5686 drain_workqueue(wq);
5687
5688 /* kill rescuer, if sanity checks fail, leave it w/o rescuer */
5689 if (wq->rescuer) {
5690 struct worker *rescuer = wq->rescuer;
5691
5692 /* this prevents new queueing */
5693 raw_spin_lock_irq(&wq_mayday_lock);
5694 wq->rescuer = NULL;
5695 raw_spin_unlock_irq(&wq_mayday_lock);
5696
5697 /* rescuer will empty maydays list before exiting */
5698 kthread_stop(rescuer->task);
5699 kfree(rescuer);
5700 }
5701
5702 /*
5703 * Sanity checks - grab all the locks so that we wait for all
5704 * in-flight operations which may do put_pwq().
5705 */
5706 mutex_lock(&wq_pool_mutex);
5707 mutex_lock(&wq->mutex);
5708 for_each_pwq(pwq, wq) {
5709 raw_spin_lock_irq(&pwq->pool->lock);
5710 if (WARN_ON(pwq_busy(pwq))) {
5711 pr_warn("%s: %s has the following busy pwq\n",
5712 __func__, wq->name);
5713 show_pwq(pwq);
5714 raw_spin_unlock_irq(&pwq->pool->lock);
5715 mutex_unlock(&wq->mutex);
5716 mutex_unlock(&wq_pool_mutex);
5717 show_one_workqueue(wq);
5718 return;
5719 }
5720 raw_spin_unlock_irq(&pwq->pool->lock);
5721 }
5722 mutex_unlock(&wq->mutex);
5723
5724 /*
5725 * wq list is used to freeze wq, remove from list after
5726 * flushing is complete in case freeze races us.
5727 */
5728 list_del_rcu(&wq->list);
5729 mutex_unlock(&wq_pool_mutex);
5730
5731 /*
5732 * We're the sole accessor of @wq. Directly access cpu_pwq and dfl_pwq
5733 * to put the base refs. @wq will be auto-destroyed from the last
5734 * pwq_put. RCU read lock prevents @wq from going away from under us.
5735 */
5736 rcu_read_lock();
5737
5738 for_each_possible_cpu(cpu) {
5739 put_pwq_unlocked(unbound_pwq(wq, cpu));
5740 RCU_INIT_POINTER(*unbound_pwq_slot(wq, cpu), NULL);
5741 }
5742
5743 put_pwq_unlocked(unbound_pwq(wq, -1));
5744 RCU_INIT_POINTER(*unbound_pwq_slot(wq, -1), NULL);
5745
5746 rcu_read_unlock();
5747}
5748EXPORT_SYMBOL_GPL(destroy_workqueue);
5749
5750/**
5751 * workqueue_set_max_active - adjust max_active of a workqueue
5752 * @wq: target workqueue
5753 * @max_active: new max_active value.
5754 *
5755 * Set max_active of @wq to @max_active. See the alloc_workqueue() function
5756 * comment.
5757 *
5758 * CONTEXT:
5759 * Don't call from IRQ context.
5760 */
5761void workqueue_set_max_active(struct workqueue_struct *wq, int max_active)
5762{
5763 /* max_active doesn't mean anything for BH workqueues */
5764 if (WARN_ON(wq->flags & WQ_BH))
5765 return;
5766 /* disallow meddling with max_active for ordered workqueues */
5767 if (WARN_ON(wq->flags & __WQ_ORDERED))
5768 return;
5769
5770 max_active = wq_clamp_max_active(max_active, wq->flags, wq->name);
5771
5772 mutex_lock(&wq->mutex);
5773
5774 wq->saved_max_active = max_active;
5775 if (wq->flags & WQ_UNBOUND)
5776 wq->saved_min_active = min(wq->saved_min_active, max_active);
5777
5778 wq_adjust_max_active(wq);
5779
5780 mutex_unlock(&wq->mutex);
5781}
5782EXPORT_SYMBOL_GPL(workqueue_set_max_active);
5783
5784/**
5785 * workqueue_set_min_active - adjust min_active of an unbound workqueue
5786 * @wq: target unbound workqueue
5787 * @min_active: new min_active value
5788 *
5789 * Set min_active of an unbound workqueue. Unlike other types of workqueues, an
5790 * unbound workqueue is not guaranteed to be able to process max_active
5791 * interdependent work items. Instead, an unbound workqueue is guaranteed to be
5792 * able to process min_active number of interdependent work items which is
5793 * %WQ_DFL_MIN_ACTIVE by default.
5794 *
5795 * Use this function to adjust the min_active value between 0 and the current
5796 * max_active.
5797 */
5798void workqueue_set_min_active(struct workqueue_struct *wq, int min_active)
5799{
5800 /* min_active is only meaningful for non-ordered unbound workqueues */
5801 if (WARN_ON((wq->flags & (WQ_BH | WQ_UNBOUND | __WQ_ORDERED)) !=
5802 WQ_UNBOUND))
5803 return;
5804
5805 mutex_lock(&wq->mutex);
5806 wq->saved_min_active = clamp(min_active, 0, wq->saved_max_active);
5807 wq_adjust_max_active(wq);
5808 mutex_unlock(&wq->mutex);
5809}
5810
5811/**
5812 * current_work - retrieve %current task's work struct
5813 *
5814 * Determine if %current task is a workqueue worker and what it's working on.
5815 * Useful to find out the context that the %current task is running in.
5816 *
5817 * Return: work struct if %current task is a workqueue worker, %NULL otherwise.
5818 */
5819struct work_struct *current_work(void)
5820{
5821 struct worker *worker = current_wq_worker();
5822
5823 return worker ? worker->current_work : NULL;
5824}
5825EXPORT_SYMBOL(current_work);
5826
5827/**
5828 * current_is_workqueue_rescuer - is %current workqueue rescuer?
5829 *
5830 * Determine whether %current is a workqueue rescuer. Can be used from
5831 * work functions to determine whether it's being run off the rescuer task.
5832 *
5833 * Return: %true if %current is a workqueue rescuer. %false otherwise.
5834 */
5835bool current_is_workqueue_rescuer(void)
5836{
5837 struct worker *worker = current_wq_worker();
5838
5839 return worker && worker->rescue_wq;
5840}
5841
5842/**
5843 * workqueue_congested - test whether a workqueue is congested
5844 * @cpu: CPU in question
5845 * @wq: target workqueue
5846 *
5847 * Test whether @wq's cpu workqueue for @cpu is congested. There is
5848 * no synchronization around this function and the test result is
5849 * unreliable and only useful as advisory hints or for debugging.
5850 *
5851 * If @cpu is WORK_CPU_UNBOUND, the test is performed on the local CPU.
5852 *
5853 * With the exception of ordered workqueues, all workqueues have per-cpu
5854 * pool_workqueues, each with its own congested state. A workqueue being
5855 * congested on one CPU doesn't mean that the workqueue is contested on any
5856 * other CPUs.
5857 *
5858 * Return:
5859 * %true if congested, %false otherwise.
5860 */
5861bool workqueue_congested(int cpu, struct workqueue_struct *wq)
5862{
5863 struct pool_workqueue *pwq;
5864 bool ret;
5865
5866 rcu_read_lock();
5867 preempt_disable();
5868
5869 if (cpu == WORK_CPU_UNBOUND)
5870 cpu = smp_processor_id();
5871
5872 pwq = *per_cpu_ptr(wq->cpu_pwq, cpu);
5873 ret = !list_empty(&pwq->inactive_works);
5874
5875 preempt_enable();
5876 rcu_read_unlock();
5877
5878 return ret;
5879}
5880EXPORT_SYMBOL_GPL(workqueue_congested);
5881
5882/**
5883 * work_busy - test whether a work is currently pending or running
5884 * @work: the work to be tested
5885 *
5886 * Test whether @work is currently pending or running. There is no
5887 * synchronization around this function and the test result is
5888 * unreliable and only useful as advisory hints or for debugging.
5889 *
5890 * Return:
5891 * OR'd bitmask of WORK_BUSY_* bits.
5892 */
5893unsigned int work_busy(struct work_struct *work)
5894{
5895 struct worker_pool *pool;
5896 unsigned long irq_flags;
5897 unsigned int ret = 0;
5898
5899 if (work_pending(work))
5900 ret |= WORK_BUSY_PENDING;
5901
5902 rcu_read_lock();
5903 pool = get_work_pool(work);
5904 if (pool) {
5905 raw_spin_lock_irqsave(&pool->lock, irq_flags);
5906 if (find_worker_executing_work(pool, work))
5907 ret |= WORK_BUSY_RUNNING;
5908 raw_spin_unlock_irqrestore(&pool->lock, irq_flags);
5909 }
5910 rcu_read_unlock();
5911
5912 return ret;
5913}
5914EXPORT_SYMBOL_GPL(work_busy);
5915
5916/**
5917 * set_worker_desc - set description for the current work item
5918 * @fmt: printf-style format string
5919 * @...: arguments for the format string
5920 *
5921 * This function can be called by a running work function to describe what
5922 * the work item is about. If the worker task gets dumped, this
5923 * information will be printed out together to help debugging. The
5924 * description can be at most WORKER_DESC_LEN including the trailing '\0'.
5925 */
5926void set_worker_desc(const char *fmt, ...)
5927{
5928 struct worker *worker = current_wq_worker();
5929 va_list args;
5930
5931 if (worker) {
5932 va_start(args, fmt);
5933 vsnprintf(worker->desc, sizeof(worker->desc), fmt, args);
5934 va_end(args);
5935 }
5936}
5937EXPORT_SYMBOL_GPL(set_worker_desc);
5938
5939/**
5940 * print_worker_info - print out worker information and description
5941 * @log_lvl: the log level to use when printing
5942 * @task: target task
5943 *
5944 * If @task is a worker and currently executing a work item, print out the
5945 * name of the workqueue being serviced and worker description set with
5946 * set_worker_desc() by the currently executing work item.
5947 *
5948 * This function can be safely called on any task as long as the
5949 * task_struct itself is accessible. While safe, this function isn't
5950 * synchronized and may print out mixups or garbages of limited length.
5951 */
5952void print_worker_info(const char *log_lvl, struct task_struct *task)
5953{
5954 work_func_t *fn = NULL;
5955 char name[WQ_NAME_LEN] = { };
5956 char desc[WORKER_DESC_LEN] = { };
5957 struct pool_workqueue *pwq = NULL;
5958 struct workqueue_struct *wq = NULL;
5959 struct worker *worker;
5960
5961 if (!(task->flags & PF_WQ_WORKER))
5962 return;
5963
5964 /*
5965 * This function is called without any synchronization and @task
5966 * could be in any state. Be careful with dereferences.
5967 */
5968 worker = kthread_probe_data(task);
5969
5970 /*
5971 * Carefully copy the associated workqueue's workfn, name and desc.
5972 * Keep the original last '\0' in case the original is garbage.
5973 */
5974 copy_from_kernel_nofault(&fn, &worker->current_func, sizeof(fn));
5975 copy_from_kernel_nofault(&pwq, &worker->current_pwq, sizeof(pwq));
5976 copy_from_kernel_nofault(&wq, &pwq->wq, sizeof(wq));
5977 copy_from_kernel_nofault(name, wq->name, sizeof(name) - 1);
5978 copy_from_kernel_nofault(desc, worker->desc, sizeof(desc) - 1);
5979
5980 if (fn || name[0] || desc[0]) {
5981 printk("%sWorkqueue: %s %ps", log_lvl, name, fn);
5982 if (strcmp(name, desc))
5983 pr_cont(" (%s)", desc);
5984 pr_cont("\n");
5985 }
5986}
5987
5988static void pr_cont_pool_info(struct worker_pool *pool)
5989{
5990 pr_cont(" cpus=%*pbl", nr_cpumask_bits, pool->attrs->cpumask);
5991 if (pool->node != NUMA_NO_NODE)
5992 pr_cont(" node=%d", pool->node);
5993 pr_cont(" flags=0x%x", pool->flags);
5994 if (pool->flags & POOL_BH)
5995 pr_cont(" bh%s",
5996 pool->attrs->nice == HIGHPRI_NICE_LEVEL ? "-hi" : "");
5997 else
5998 pr_cont(" nice=%d", pool->attrs->nice);
5999}
6000
6001static void pr_cont_worker_id(struct worker *worker)
6002{
6003 struct worker_pool *pool = worker->pool;
6004
6005 if (pool->flags & WQ_BH)
6006 pr_cont("bh%s",
6007 pool->attrs->nice == HIGHPRI_NICE_LEVEL ? "-hi" : "");
6008 else
6009 pr_cont("%d%s", task_pid_nr(worker->task),
6010 worker->rescue_wq ? "(RESCUER)" : "");
6011}
6012
6013struct pr_cont_work_struct {
6014 bool comma;
6015 work_func_t func;
6016 long ctr;
6017};
6018
6019static void pr_cont_work_flush(bool comma, work_func_t func, struct pr_cont_work_struct *pcwsp)
6020{
6021 if (!pcwsp->ctr)
6022 goto out_record;
6023 if (func == pcwsp->func) {
6024 pcwsp->ctr++;
6025 return;
6026 }
6027 if (pcwsp->ctr == 1)
6028 pr_cont("%s %ps", pcwsp->comma ? "," : "", pcwsp->func);
6029 else
6030 pr_cont("%s %ld*%ps", pcwsp->comma ? "," : "", pcwsp->ctr, pcwsp->func);
6031 pcwsp->ctr = 0;
6032out_record:
6033 if ((long)func == -1L)
6034 return;
6035 pcwsp->comma = comma;
6036 pcwsp->func = func;
6037 pcwsp->ctr = 1;
6038}
6039
6040static void pr_cont_work(bool comma, struct work_struct *work, struct pr_cont_work_struct *pcwsp)
6041{
6042 if (work->func == wq_barrier_func) {
6043 struct wq_barrier *barr;
6044
6045 barr = container_of(work, struct wq_barrier, work);
6046
6047 pr_cont_work_flush(comma, (work_func_t)-1, pcwsp);
6048 pr_cont("%s BAR(%d)", comma ? "," : "",
6049 task_pid_nr(barr->task));
6050 } else {
6051 if (!comma)
6052 pr_cont_work_flush(comma, (work_func_t)-1, pcwsp);
6053 pr_cont_work_flush(comma, work->func, pcwsp);
6054 }
6055}
6056
6057static void show_pwq(struct pool_workqueue *pwq)
6058{
6059 struct pr_cont_work_struct pcws = { .ctr = 0, };
6060 struct worker_pool *pool = pwq->pool;
6061 struct work_struct *work;
6062 struct worker *worker;
6063 bool has_in_flight = false, has_pending = false;
6064 int bkt;
6065
6066 pr_info(" pwq %d:", pool->id);
6067 pr_cont_pool_info(pool);
6068
6069 pr_cont(" active=%d refcnt=%d%s\n",
6070 pwq->nr_active, pwq->refcnt,
6071 !list_empty(&pwq->mayday_node) ? " MAYDAY" : "");
6072
6073 hash_for_each(pool->busy_hash, bkt, worker, hentry) {
6074 if (worker->current_pwq == pwq) {
6075 has_in_flight = true;
6076 break;
6077 }
6078 }
6079 if (has_in_flight) {
6080 bool comma = false;
6081
6082 pr_info(" in-flight:");
6083 hash_for_each(pool->busy_hash, bkt, worker, hentry) {
6084 if (worker->current_pwq != pwq)
6085 continue;
6086
6087 pr_cont(" %s", comma ? "," : "");
6088 pr_cont_worker_id(worker);
6089 pr_cont(":%ps", worker->current_func);
6090 list_for_each_entry(work, &worker->scheduled, entry)
6091 pr_cont_work(false, work, &pcws);
6092 pr_cont_work_flush(comma, (work_func_t)-1L, &pcws);
6093 comma = true;
6094 }
6095 pr_cont("\n");
6096 }
6097
6098 list_for_each_entry(work, &pool->worklist, entry) {
6099 if (get_work_pwq(work) == pwq) {
6100 has_pending = true;
6101 break;
6102 }
6103 }
6104 if (has_pending) {
6105 bool comma = false;
6106
6107 pr_info(" pending:");
6108 list_for_each_entry(work, &pool->worklist, entry) {
6109 if (get_work_pwq(work) != pwq)
6110 continue;
6111
6112 pr_cont_work(comma, work, &pcws);
6113 comma = !(*work_data_bits(work) & WORK_STRUCT_LINKED);
6114 }
6115 pr_cont_work_flush(comma, (work_func_t)-1L, &pcws);
6116 pr_cont("\n");
6117 }
6118
6119 if (!list_empty(&pwq->inactive_works)) {
6120 bool comma = false;
6121
6122 pr_info(" inactive:");
6123 list_for_each_entry(work, &pwq->inactive_works, entry) {
6124 pr_cont_work(comma, work, &pcws);
6125 comma = !(*work_data_bits(work) & WORK_STRUCT_LINKED);
6126 }
6127 pr_cont_work_flush(comma, (work_func_t)-1L, &pcws);
6128 pr_cont("\n");
6129 }
6130}
6131
6132/**
6133 * show_one_workqueue - dump state of specified workqueue
6134 * @wq: workqueue whose state will be printed
6135 */
6136void show_one_workqueue(struct workqueue_struct *wq)
6137{
6138 struct pool_workqueue *pwq;
6139 bool idle = true;
6140 unsigned long irq_flags;
6141
6142 for_each_pwq(pwq, wq) {
6143 if (!pwq_is_empty(pwq)) {
6144 idle = false;
6145 break;
6146 }
6147 }
6148 if (idle) /* Nothing to print for idle workqueue */
6149 return;
6150
6151 pr_info("workqueue %s: flags=0x%x\n", wq->name, wq->flags);
6152
6153 for_each_pwq(pwq, wq) {
6154 raw_spin_lock_irqsave(&pwq->pool->lock, irq_flags);
6155 if (!pwq_is_empty(pwq)) {
6156 /*
6157 * Defer printing to avoid deadlocks in console
6158 * drivers that queue work while holding locks
6159 * also taken in their write paths.
6160 */
6161 printk_deferred_enter();
6162 show_pwq(pwq);
6163 printk_deferred_exit();
6164 }
6165 raw_spin_unlock_irqrestore(&pwq->pool->lock, irq_flags);
6166 /*
6167 * We could be printing a lot from atomic context, e.g.
6168 * sysrq-t -> show_all_workqueues(). Avoid triggering
6169 * hard lockup.
6170 */
6171 touch_nmi_watchdog();
6172 }
6173
6174}
6175
6176/**
6177 * show_one_worker_pool - dump state of specified worker pool
6178 * @pool: worker pool whose state will be printed
6179 */
6180static void show_one_worker_pool(struct worker_pool *pool)
6181{
6182 struct worker *worker;
6183 bool first = true;
6184 unsigned long irq_flags;
6185 unsigned long hung = 0;
6186
6187 raw_spin_lock_irqsave(&pool->lock, irq_flags);
6188 if (pool->nr_workers == pool->nr_idle)
6189 goto next_pool;
6190
6191 /* How long the first pending work is waiting for a worker. */
6192 if (!list_empty(&pool->worklist))
6193 hung = jiffies_to_msecs(jiffies - pool->watchdog_ts) / 1000;
6194
6195 /*
6196 * Defer printing to avoid deadlocks in console drivers that
6197 * queue work while holding locks also taken in their write
6198 * paths.
6199 */
6200 printk_deferred_enter();
6201 pr_info("pool %d:", pool->id);
6202 pr_cont_pool_info(pool);
6203 pr_cont(" hung=%lus workers=%d", hung, pool->nr_workers);
6204 if (pool->manager)
6205 pr_cont(" manager: %d",
6206 task_pid_nr(pool->manager->task));
6207 list_for_each_entry(worker, &pool->idle_list, entry) {
6208 pr_cont(" %s", first ? "idle: " : "");
6209 pr_cont_worker_id(worker);
6210 first = false;
6211 }
6212 pr_cont("\n");
6213 printk_deferred_exit();
6214next_pool:
6215 raw_spin_unlock_irqrestore(&pool->lock, irq_flags);
6216 /*
6217 * We could be printing a lot from atomic context, e.g.
6218 * sysrq-t -> show_all_workqueues(). Avoid triggering
6219 * hard lockup.
6220 */
6221 touch_nmi_watchdog();
6222
6223}
6224
6225/**
6226 * show_all_workqueues - dump workqueue state
6227 *
6228 * Called from a sysrq handler and prints out all busy workqueues and pools.
6229 */
6230void show_all_workqueues(void)
6231{
6232 struct workqueue_struct *wq;
6233 struct worker_pool *pool;
6234 int pi;
6235
6236 rcu_read_lock();
6237
6238 pr_info("Showing busy workqueues and worker pools:\n");
6239
6240 list_for_each_entry_rcu(wq, &workqueues, list)
6241 show_one_workqueue(wq);
6242
6243 for_each_pool(pool, pi)
6244 show_one_worker_pool(pool);
6245
6246 rcu_read_unlock();
6247}
6248
6249/**
6250 * show_freezable_workqueues - dump freezable workqueue state
6251 *
6252 * Called from try_to_freeze_tasks() and prints out all freezable workqueues
6253 * still busy.
6254 */
6255void show_freezable_workqueues(void)
6256{
6257 struct workqueue_struct *wq;
6258
6259 rcu_read_lock();
6260
6261 pr_info("Showing freezable workqueues that are still busy:\n");
6262
6263 list_for_each_entry_rcu(wq, &workqueues, list) {
6264 if (!(wq->flags & WQ_FREEZABLE))
6265 continue;
6266 show_one_workqueue(wq);
6267 }
6268
6269 rcu_read_unlock();
6270}
6271
6272/* used to show worker information through /proc/PID/{comm,stat,status} */
6273void wq_worker_comm(char *buf, size_t size, struct task_struct *task)
6274{
6275 int off;
6276
6277 /* always show the actual comm */
6278 off = strscpy(buf, task->comm, size);
6279 if (off < 0)
6280 return;
6281
6282 /* stabilize PF_WQ_WORKER and worker pool association */
6283 mutex_lock(&wq_pool_attach_mutex);
6284
6285 if (task->flags & PF_WQ_WORKER) {
6286 struct worker *worker = kthread_data(task);
6287 struct worker_pool *pool = worker->pool;
6288
6289 if (pool) {
6290 raw_spin_lock_irq(&pool->lock);
6291 /*
6292 * ->desc tracks information (wq name or
6293 * set_worker_desc()) for the latest execution. If
6294 * current, prepend '+', otherwise '-'.
6295 */
6296 if (worker->desc[0] != '\0') {
6297 if (worker->current_work)
6298 scnprintf(buf + off, size - off, "+%s",
6299 worker->desc);
6300 else
6301 scnprintf(buf + off, size - off, "-%s",
6302 worker->desc);
6303 }
6304 raw_spin_unlock_irq(&pool->lock);
6305 }
6306 }
6307
6308 mutex_unlock(&wq_pool_attach_mutex);
6309}
6310
6311#ifdef CONFIG_SMP
6312
6313/*
6314 * CPU hotplug.
6315 *
6316 * There are two challenges in supporting CPU hotplug. Firstly, there
6317 * are a lot of assumptions on strong associations among work, pwq and
6318 * pool which make migrating pending and scheduled works very
6319 * difficult to implement without impacting hot paths. Secondly,
6320 * worker pools serve mix of short, long and very long running works making
6321 * blocked draining impractical.
6322 *
6323 * This is solved by allowing the pools to be disassociated from the CPU
6324 * running as an unbound one and allowing it to be reattached later if the
6325 * cpu comes back online.
6326 */
6327
6328static void unbind_workers(int cpu)
6329{
6330 struct worker_pool *pool;
6331 struct worker *worker;
6332
6333 for_each_cpu_worker_pool(pool, cpu) {
6334 mutex_lock(&wq_pool_attach_mutex);
6335 raw_spin_lock_irq(&pool->lock);
6336
6337 /*
6338 * We've blocked all attach/detach operations. Make all workers
6339 * unbound and set DISASSOCIATED. Before this, all workers
6340 * must be on the cpu. After this, they may become diasporas.
6341 * And the preemption disabled section in their sched callbacks
6342 * are guaranteed to see WORKER_UNBOUND since the code here
6343 * is on the same cpu.
6344 */
6345 for_each_pool_worker(worker, pool)
6346 worker->flags |= WORKER_UNBOUND;
6347
6348 pool->flags |= POOL_DISASSOCIATED;
6349
6350 /*
6351 * The handling of nr_running in sched callbacks are disabled
6352 * now. Zap nr_running. After this, nr_running stays zero and
6353 * need_more_worker() and keep_working() are always true as
6354 * long as the worklist is not empty. This pool now behaves as
6355 * an unbound (in terms of concurrency management) pool which
6356 * are served by workers tied to the pool.
6357 */
6358 pool->nr_running = 0;
6359
6360 /*
6361 * With concurrency management just turned off, a busy
6362 * worker blocking could lead to lengthy stalls. Kick off
6363 * unbound chain execution of currently pending work items.
6364 */
6365 kick_pool(pool);
6366
6367 raw_spin_unlock_irq(&pool->lock);
6368
6369 for_each_pool_worker(worker, pool)
6370 unbind_worker(worker);
6371
6372 mutex_unlock(&wq_pool_attach_mutex);
6373 }
6374}
6375
6376/**
6377 * rebind_workers - rebind all workers of a pool to the associated CPU
6378 * @pool: pool of interest
6379 *
6380 * @pool->cpu is coming online. Rebind all workers to the CPU.
6381 */
6382static void rebind_workers(struct worker_pool *pool)
6383{
6384 struct worker *worker;
6385
6386 lockdep_assert_held(&wq_pool_attach_mutex);
6387
6388 /*
6389 * Restore CPU affinity of all workers. As all idle workers should
6390 * be on the run-queue of the associated CPU before any local
6391 * wake-ups for concurrency management happen, restore CPU affinity
6392 * of all workers first and then clear UNBOUND. As we're called
6393 * from CPU_ONLINE, the following shouldn't fail.
6394 */
6395 for_each_pool_worker(worker, pool) {
6396 kthread_set_per_cpu(worker->task, pool->cpu);
6397 WARN_ON_ONCE(set_cpus_allowed_ptr(worker->task,
6398 pool_allowed_cpus(pool)) < 0);
6399 }
6400
6401 raw_spin_lock_irq(&pool->lock);
6402
6403 pool->flags &= ~POOL_DISASSOCIATED;
6404
6405 for_each_pool_worker(worker, pool) {
6406 unsigned int worker_flags = worker->flags;
6407
6408 /*
6409 * We want to clear UNBOUND but can't directly call
6410 * worker_clr_flags() or adjust nr_running. Atomically
6411 * replace UNBOUND with another NOT_RUNNING flag REBOUND.
6412 * @worker will clear REBOUND using worker_clr_flags() when
6413 * it initiates the next execution cycle thus restoring
6414 * concurrency management. Note that when or whether
6415 * @worker clears REBOUND doesn't affect correctness.
6416 *
6417 * WRITE_ONCE() is necessary because @worker->flags may be
6418 * tested without holding any lock in
6419 * wq_worker_running(). Without it, NOT_RUNNING test may
6420 * fail incorrectly leading to premature concurrency
6421 * management operations.
6422 */
6423 WARN_ON_ONCE(!(worker_flags & WORKER_UNBOUND));
6424 worker_flags |= WORKER_REBOUND;
6425 worker_flags &= ~WORKER_UNBOUND;
6426 WRITE_ONCE(worker->flags, worker_flags);
6427 }
6428
6429 raw_spin_unlock_irq(&pool->lock);
6430}
6431
6432/**
6433 * restore_unbound_workers_cpumask - restore cpumask of unbound workers
6434 * @pool: unbound pool of interest
6435 * @cpu: the CPU which is coming up
6436 *
6437 * An unbound pool may end up with a cpumask which doesn't have any online
6438 * CPUs. When a worker of such pool get scheduled, the scheduler resets
6439 * its cpus_allowed. If @cpu is in @pool's cpumask which didn't have any
6440 * online CPU before, cpus_allowed of all its workers should be restored.
6441 */
6442static void restore_unbound_workers_cpumask(struct worker_pool *pool, int cpu)
6443{
6444 static cpumask_t cpumask;
6445 struct worker *worker;
6446
6447 lockdep_assert_held(&wq_pool_attach_mutex);
6448
6449 /* is @cpu allowed for @pool? */
6450 if (!cpumask_test_cpu(cpu, pool->attrs->cpumask))
6451 return;
6452
6453 cpumask_and(&cpumask, pool->attrs->cpumask, cpu_online_mask);
6454
6455 /* as we're called from CPU_ONLINE, the following shouldn't fail */
6456 for_each_pool_worker(worker, pool)
6457 WARN_ON_ONCE(set_cpus_allowed_ptr(worker->task, &cpumask) < 0);
6458}
6459
6460int workqueue_prepare_cpu(unsigned int cpu)
6461{
6462 struct worker_pool *pool;
6463
6464 for_each_cpu_worker_pool(pool, cpu) {
6465 if (pool->nr_workers)
6466 continue;
6467 if (!create_worker(pool))
6468 return -ENOMEM;
6469 }
6470 return 0;
6471}
6472
6473int workqueue_online_cpu(unsigned int cpu)
6474{
6475 struct worker_pool *pool;
6476 struct workqueue_struct *wq;
6477 int pi;
6478
6479 mutex_lock(&wq_pool_mutex);
6480
6481 for_each_pool(pool, pi) {
6482 /* BH pools aren't affected by hotplug */
6483 if (pool->flags & POOL_BH)
6484 continue;
6485
6486 mutex_lock(&wq_pool_attach_mutex);
6487 if (pool->cpu == cpu)
6488 rebind_workers(pool);
6489 else if (pool->cpu < 0)
6490 restore_unbound_workers_cpumask(pool, cpu);
6491 mutex_unlock(&wq_pool_attach_mutex);
6492 }
6493
6494 /* update pod affinity of unbound workqueues */
6495 list_for_each_entry(wq, &workqueues, list) {
6496 struct workqueue_attrs *attrs = wq->unbound_attrs;
6497
6498 if (attrs) {
6499 const struct wq_pod_type *pt = wqattrs_pod_type(attrs);
6500 int tcpu;
6501
6502 for_each_cpu(tcpu, pt->pod_cpus[pt->cpu_pod[cpu]])
6503 wq_update_pod(wq, tcpu, cpu, true);
6504
6505 mutex_lock(&wq->mutex);
6506 wq_update_node_max_active(wq, -1);
6507 mutex_unlock(&wq->mutex);
6508 }
6509 }
6510
6511 mutex_unlock(&wq_pool_mutex);
6512 return 0;
6513}
6514
6515int workqueue_offline_cpu(unsigned int cpu)
6516{
6517 struct workqueue_struct *wq;
6518
6519 /* unbinding per-cpu workers should happen on the local CPU */
6520 if (WARN_ON(cpu != smp_processor_id()))
6521 return -1;
6522
6523 unbind_workers(cpu);
6524
6525 /* update pod affinity of unbound workqueues */
6526 mutex_lock(&wq_pool_mutex);
6527 list_for_each_entry(wq, &workqueues, list) {
6528 struct workqueue_attrs *attrs = wq->unbound_attrs;
6529
6530 if (attrs) {
6531 const struct wq_pod_type *pt = wqattrs_pod_type(attrs);
6532 int tcpu;
6533
6534 for_each_cpu(tcpu, pt->pod_cpus[pt->cpu_pod[cpu]])
6535 wq_update_pod(wq, tcpu, cpu, false);
6536
6537 mutex_lock(&wq->mutex);
6538 wq_update_node_max_active(wq, cpu);
6539 mutex_unlock(&wq->mutex);
6540 }
6541 }
6542 mutex_unlock(&wq_pool_mutex);
6543
6544 return 0;
6545}
6546
6547struct work_for_cpu {
6548 struct work_struct work;
6549 long (*fn)(void *);
6550 void *arg;
6551 long ret;
6552};
6553
6554static void work_for_cpu_fn(struct work_struct *work)
6555{
6556 struct work_for_cpu *wfc = container_of(work, struct work_for_cpu, work);
6557
6558 wfc->ret = wfc->fn(wfc->arg);
6559}
6560
6561/**
6562 * work_on_cpu_key - run a function in thread context on a particular cpu
6563 * @cpu: the cpu to run on
6564 * @fn: the function to run
6565 * @arg: the function arg
6566 * @key: The lock class key for lock debugging purposes
6567 *
6568 * It is up to the caller to ensure that the cpu doesn't go offline.
6569 * The caller must not hold any locks which would prevent @fn from completing.
6570 *
6571 * Return: The value @fn returns.
6572 */
6573long work_on_cpu_key(int cpu, long (*fn)(void *),
6574 void *arg, struct lock_class_key *key)
6575{
6576 struct work_for_cpu wfc = { .fn = fn, .arg = arg };
6577
6578 INIT_WORK_ONSTACK_KEY(&wfc.work, work_for_cpu_fn, key);
6579 schedule_work_on(cpu, &wfc.work);
6580 flush_work(&wfc.work);
6581 destroy_work_on_stack(&wfc.work);
6582 return wfc.ret;
6583}
6584EXPORT_SYMBOL_GPL(work_on_cpu_key);
6585
6586/**
6587 * work_on_cpu_safe_key - run a function in thread context on a particular cpu
6588 * @cpu: the cpu to run on
6589 * @fn: the function to run
6590 * @arg: the function argument
6591 * @key: The lock class key for lock debugging purposes
6592 *
6593 * Disables CPU hotplug and calls work_on_cpu(). The caller must not hold
6594 * any locks which would prevent @fn from completing.
6595 *
6596 * Return: The value @fn returns.
6597 */
6598long work_on_cpu_safe_key(int cpu, long (*fn)(void *),
6599 void *arg, struct lock_class_key *key)
6600{
6601 long ret = -ENODEV;
6602
6603 cpus_read_lock();
6604 if (cpu_online(cpu))
6605 ret = work_on_cpu_key(cpu, fn, arg, key);
6606 cpus_read_unlock();
6607 return ret;
6608}
6609EXPORT_SYMBOL_GPL(work_on_cpu_safe_key);
6610#endif /* CONFIG_SMP */
6611
6612#ifdef CONFIG_FREEZER
6613
6614/**
6615 * freeze_workqueues_begin - begin freezing workqueues
6616 *
6617 * Start freezing workqueues. After this function returns, all freezable
6618 * workqueues will queue new works to their inactive_works list instead of
6619 * pool->worklist.
6620 *
6621 * CONTEXT:
6622 * Grabs and releases wq_pool_mutex, wq->mutex and pool->lock's.
6623 */
6624void freeze_workqueues_begin(void)
6625{
6626 struct workqueue_struct *wq;
6627
6628 mutex_lock(&wq_pool_mutex);
6629
6630 WARN_ON_ONCE(workqueue_freezing);
6631 workqueue_freezing = true;
6632
6633 list_for_each_entry(wq, &workqueues, list) {
6634 mutex_lock(&wq->mutex);
6635 wq_adjust_max_active(wq);
6636 mutex_unlock(&wq->mutex);
6637 }
6638
6639 mutex_unlock(&wq_pool_mutex);
6640}
6641
6642/**
6643 * freeze_workqueues_busy - are freezable workqueues still busy?
6644 *
6645 * Check whether freezing is complete. This function must be called
6646 * between freeze_workqueues_begin() and thaw_workqueues().
6647 *
6648 * CONTEXT:
6649 * Grabs and releases wq_pool_mutex.
6650 *
6651 * Return:
6652 * %true if some freezable workqueues are still busy. %false if freezing
6653 * is complete.
6654 */
6655bool freeze_workqueues_busy(void)
6656{
6657 bool busy = false;
6658 struct workqueue_struct *wq;
6659 struct pool_workqueue *pwq;
6660
6661 mutex_lock(&wq_pool_mutex);
6662
6663 WARN_ON_ONCE(!workqueue_freezing);
6664
6665 list_for_each_entry(wq, &workqueues, list) {
6666 if (!(wq->flags & WQ_FREEZABLE))
6667 continue;
6668 /*
6669 * nr_active is monotonically decreasing. It's safe
6670 * to peek without lock.
6671 */
6672 rcu_read_lock();
6673 for_each_pwq(pwq, wq) {
6674 WARN_ON_ONCE(pwq->nr_active < 0);
6675 if (pwq->nr_active) {
6676 busy = true;
6677 rcu_read_unlock();
6678 goto out_unlock;
6679 }
6680 }
6681 rcu_read_unlock();
6682 }
6683out_unlock:
6684 mutex_unlock(&wq_pool_mutex);
6685 return busy;
6686}
6687
6688/**
6689 * thaw_workqueues - thaw workqueues
6690 *
6691 * Thaw workqueues. Normal queueing is restored and all collected
6692 * frozen works are transferred to their respective pool worklists.
6693 *
6694 * CONTEXT:
6695 * Grabs and releases wq_pool_mutex, wq->mutex and pool->lock's.
6696 */
6697void thaw_workqueues(void)
6698{
6699 struct workqueue_struct *wq;
6700
6701 mutex_lock(&wq_pool_mutex);
6702
6703 if (!workqueue_freezing)
6704 goto out_unlock;
6705
6706 workqueue_freezing = false;
6707
6708 /* restore max_active and repopulate worklist */
6709 list_for_each_entry(wq, &workqueues, list) {
6710 mutex_lock(&wq->mutex);
6711 wq_adjust_max_active(wq);
6712 mutex_unlock(&wq->mutex);
6713 }
6714
6715out_unlock:
6716 mutex_unlock(&wq_pool_mutex);
6717}
6718#endif /* CONFIG_FREEZER */
6719
6720static int workqueue_apply_unbound_cpumask(const cpumask_var_t unbound_cpumask)
6721{
6722 LIST_HEAD(ctxs);
6723 int ret = 0;
6724 struct workqueue_struct *wq;
6725 struct apply_wqattrs_ctx *ctx, *n;
6726
6727 lockdep_assert_held(&wq_pool_mutex);
6728
6729 list_for_each_entry(wq, &workqueues, list) {
6730 if (!(wq->flags & WQ_UNBOUND) || (wq->flags & __WQ_DESTROYING))
6731 continue;
6732
6733 ctx = apply_wqattrs_prepare(wq, wq->unbound_attrs, unbound_cpumask);
6734 if (IS_ERR(ctx)) {
6735 ret = PTR_ERR(ctx);
6736 break;
6737 }
6738
6739 list_add_tail(&ctx->list, &ctxs);
6740 }
6741
6742 list_for_each_entry_safe(ctx, n, &ctxs, list) {
6743 if (!ret)
6744 apply_wqattrs_commit(ctx);
6745 apply_wqattrs_cleanup(ctx);
6746 }
6747
6748 if (!ret) {
6749 mutex_lock(&wq_pool_attach_mutex);
6750 cpumask_copy(wq_unbound_cpumask, unbound_cpumask);
6751 mutex_unlock(&wq_pool_attach_mutex);
6752 }
6753 return ret;
6754}
6755
6756/**
6757 * workqueue_unbound_exclude_cpumask - Exclude given CPUs from unbound cpumask
6758 * @exclude_cpumask: the cpumask to be excluded from wq_unbound_cpumask
6759 *
6760 * This function can be called from cpuset code to provide a set of isolated
6761 * CPUs that should be excluded from wq_unbound_cpumask. The caller must hold
6762 * either cpus_read_lock or cpus_write_lock.
6763 */
6764int workqueue_unbound_exclude_cpumask(cpumask_var_t exclude_cpumask)
6765{
6766 cpumask_var_t cpumask;
6767 int ret = 0;
6768
6769 if (!zalloc_cpumask_var(&cpumask, GFP_KERNEL))
6770 return -ENOMEM;
6771
6772 lockdep_assert_cpus_held();
6773 mutex_lock(&wq_pool_mutex);
6774
6775 /* Save the current isolated cpumask & export it via sysfs */
6776 cpumask_copy(wq_isolated_cpumask, exclude_cpumask);
6777
6778 /*
6779 * If the operation fails, it will fall back to
6780 * wq_requested_unbound_cpumask which is initially set to
6781 * (HK_TYPE_WQ ∩ HK_TYPE_DOMAIN) house keeping mask and rewritten
6782 * by any subsequent write to workqueue/cpumask sysfs file.
6783 */
6784 if (!cpumask_andnot(cpumask, wq_requested_unbound_cpumask, exclude_cpumask))
6785 cpumask_copy(cpumask, wq_requested_unbound_cpumask);
6786 if (!cpumask_equal(cpumask, wq_unbound_cpumask))
6787 ret = workqueue_apply_unbound_cpumask(cpumask);
6788
6789 mutex_unlock(&wq_pool_mutex);
6790 free_cpumask_var(cpumask);
6791 return ret;
6792}
6793
6794static int parse_affn_scope(const char *val)
6795{
6796 int i;
6797
6798 for (i = 0; i < ARRAY_SIZE(wq_affn_names); i++) {
6799 if (!strncasecmp(val, wq_affn_names[i], strlen(wq_affn_names[i])))
6800 return i;
6801 }
6802 return -EINVAL;
6803}
6804
6805static int wq_affn_dfl_set(const char *val, const struct kernel_param *kp)
6806{
6807 struct workqueue_struct *wq;
6808 int affn, cpu;
6809
6810 affn = parse_affn_scope(val);
6811 if (affn < 0)
6812 return affn;
6813 if (affn == WQ_AFFN_DFL)
6814 return -EINVAL;
6815
6816 cpus_read_lock();
6817 mutex_lock(&wq_pool_mutex);
6818
6819 wq_affn_dfl = affn;
6820
6821 list_for_each_entry(wq, &workqueues, list) {
6822 for_each_online_cpu(cpu) {
6823 wq_update_pod(wq, cpu, cpu, true);
6824 }
6825 }
6826
6827 mutex_unlock(&wq_pool_mutex);
6828 cpus_read_unlock();
6829
6830 return 0;
6831}
6832
6833static int wq_affn_dfl_get(char *buffer, const struct kernel_param *kp)
6834{
6835 return scnprintf(buffer, PAGE_SIZE, "%s\n", wq_affn_names[wq_affn_dfl]);
6836}
6837
6838static const struct kernel_param_ops wq_affn_dfl_ops = {
6839 .set = wq_affn_dfl_set,
6840 .get = wq_affn_dfl_get,
6841};
6842
6843module_param_cb(default_affinity_scope, &wq_affn_dfl_ops, NULL, 0644);
6844
6845#ifdef CONFIG_SYSFS
6846/*
6847 * Workqueues with WQ_SYSFS flag set is visible to userland via
6848 * /sys/bus/workqueue/devices/WQ_NAME. All visible workqueues have the
6849 * following attributes.
6850 *
6851 * per_cpu RO bool : whether the workqueue is per-cpu or unbound
6852 * max_active RW int : maximum number of in-flight work items
6853 *
6854 * Unbound workqueues have the following extra attributes.
6855 *
6856 * nice RW int : nice value of the workers
6857 * cpumask RW mask : bitmask of allowed CPUs for the workers
6858 * affinity_scope RW str : worker CPU affinity scope (cache, numa, none)
6859 * affinity_strict RW bool : worker CPU affinity is strict
6860 */
6861struct wq_device {
6862 struct workqueue_struct *wq;
6863 struct device dev;
6864};
6865
6866static struct workqueue_struct *dev_to_wq(struct device *dev)
6867{
6868 struct wq_device *wq_dev = container_of(dev, struct wq_device, dev);
6869
6870 return wq_dev->wq;
6871}
6872
6873static ssize_t per_cpu_show(struct device *dev, struct device_attribute *attr,
6874 char *buf)
6875{
6876 struct workqueue_struct *wq = dev_to_wq(dev);
6877
6878 return scnprintf(buf, PAGE_SIZE, "%d\n", (bool)!(wq->flags & WQ_UNBOUND));
6879}
6880static DEVICE_ATTR_RO(per_cpu);
6881
6882static ssize_t max_active_show(struct device *dev,
6883 struct device_attribute *attr, char *buf)
6884{
6885 struct workqueue_struct *wq = dev_to_wq(dev);
6886
6887 return scnprintf(buf, PAGE_SIZE, "%d\n", wq->saved_max_active);
6888}
6889
6890static ssize_t max_active_store(struct device *dev,
6891 struct device_attribute *attr, const char *buf,
6892 size_t count)
6893{
6894 struct workqueue_struct *wq = dev_to_wq(dev);
6895 int val;
6896
6897 if (sscanf(buf, "%d", &val) != 1 || val <= 0)
6898 return -EINVAL;
6899
6900 workqueue_set_max_active(wq, val);
6901 return count;
6902}
6903static DEVICE_ATTR_RW(max_active);
6904
6905static struct attribute *wq_sysfs_attrs[] = {
6906 &dev_attr_per_cpu.attr,
6907 &dev_attr_max_active.attr,
6908 NULL,
6909};
6910ATTRIBUTE_GROUPS(wq_sysfs);
6911
6912static void apply_wqattrs_lock(void)
6913{
6914 /* CPUs should stay stable across pwq creations and installations */
6915 cpus_read_lock();
6916 mutex_lock(&wq_pool_mutex);
6917}
6918
6919static void apply_wqattrs_unlock(void)
6920{
6921 mutex_unlock(&wq_pool_mutex);
6922 cpus_read_unlock();
6923}
6924
6925static ssize_t wq_nice_show(struct device *dev, struct device_attribute *attr,
6926 char *buf)
6927{
6928 struct workqueue_struct *wq = dev_to_wq(dev);
6929 int written;
6930
6931 mutex_lock(&wq->mutex);
6932 written = scnprintf(buf, PAGE_SIZE, "%d\n", wq->unbound_attrs->nice);
6933 mutex_unlock(&wq->mutex);
6934
6935 return written;
6936}
6937
6938/* prepare workqueue_attrs for sysfs store operations */
6939static struct workqueue_attrs *wq_sysfs_prep_attrs(struct workqueue_struct *wq)
6940{
6941 struct workqueue_attrs *attrs;
6942
6943 lockdep_assert_held(&wq_pool_mutex);
6944
6945 attrs = alloc_workqueue_attrs();
6946 if (!attrs)
6947 return NULL;
6948
6949 copy_workqueue_attrs(attrs, wq->unbound_attrs);
6950 return attrs;
6951}
6952
6953static ssize_t wq_nice_store(struct device *dev, struct device_attribute *attr,
6954 const char *buf, size_t count)
6955{
6956 struct workqueue_struct *wq = dev_to_wq(dev);
6957 struct workqueue_attrs *attrs;
6958 int ret = -ENOMEM;
6959
6960 apply_wqattrs_lock();
6961
6962 attrs = wq_sysfs_prep_attrs(wq);
6963 if (!attrs)
6964 goto out_unlock;
6965
6966 if (sscanf(buf, "%d", &attrs->nice) == 1 &&
6967 attrs->nice >= MIN_NICE && attrs->nice <= MAX_NICE)
6968 ret = apply_workqueue_attrs_locked(wq, attrs);
6969 else
6970 ret = -EINVAL;
6971
6972out_unlock:
6973 apply_wqattrs_unlock();
6974 free_workqueue_attrs(attrs);
6975 return ret ?: count;
6976}
6977
6978static ssize_t wq_cpumask_show(struct device *dev,
6979 struct device_attribute *attr, char *buf)
6980{
6981 struct workqueue_struct *wq = dev_to_wq(dev);
6982 int written;
6983
6984 mutex_lock(&wq->mutex);
6985 written = scnprintf(buf, PAGE_SIZE, "%*pb\n",
6986 cpumask_pr_args(wq->unbound_attrs->cpumask));
6987 mutex_unlock(&wq->mutex);
6988 return written;
6989}
6990
6991static ssize_t wq_cpumask_store(struct device *dev,
6992 struct device_attribute *attr,
6993 const char *buf, size_t count)
6994{
6995 struct workqueue_struct *wq = dev_to_wq(dev);
6996 struct workqueue_attrs *attrs;
6997 int ret = -ENOMEM;
6998
6999 apply_wqattrs_lock();
7000
7001 attrs = wq_sysfs_prep_attrs(wq);
7002 if (!attrs)
7003 goto out_unlock;
7004
7005 ret = cpumask_parse(buf, attrs->cpumask);
7006 if (!ret)
7007 ret = apply_workqueue_attrs_locked(wq, attrs);
7008
7009out_unlock:
7010 apply_wqattrs_unlock();
7011 free_workqueue_attrs(attrs);
7012 return ret ?: count;
7013}
7014
7015static ssize_t wq_affn_scope_show(struct device *dev,
7016 struct device_attribute *attr, char *buf)
7017{
7018 struct workqueue_struct *wq = dev_to_wq(dev);
7019 int written;
7020
7021 mutex_lock(&wq->mutex);
7022 if (wq->unbound_attrs->affn_scope == WQ_AFFN_DFL)
7023 written = scnprintf(buf, PAGE_SIZE, "%s (%s)\n",
7024 wq_affn_names[WQ_AFFN_DFL],
7025 wq_affn_names[wq_affn_dfl]);
7026 else
7027 written = scnprintf(buf, PAGE_SIZE, "%s\n",
7028 wq_affn_names[wq->unbound_attrs->affn_scope]);
7029 mutex_unlock(&wq->mutex);
7030
7031 return written;
7032}
7033
7034static ssize_t wq_affn_scope_store(struct device *dev,
7035 struct device_attribute *attr,
7036 const char *buf, size_t count)
7037{
7038 struct workqueue_struct *wq = dev_to_wq(dev);
7039 struct workqueue_attrs *attrs;
7040 int affn, ret = -ENOMEM;
7041
7042 affn = parse_affn_scope(buf);
7043 if (affn < 0)
7044 return affn;
7045
7046 apply_wqattrs_lock();
7047 attrs = wq_sysfs_prep_attrs(wq);
7048 if (attrs) {
7049 attrs->affn_scope = affn;
7050 ret = apply_workqueue_attrs_locked(wq, attrs);
7051 }
7052 apply_wqattrs_unlock();
7053 free_workqueue_attrs(attrs);
7054 return ret ?: count;
7055}
7056
7057static ssize_t wq_affinity_strict_show(struct device *dev,
7058 struct device_attribute *attr, char *buf)
7059{
7060 struct workqueue_struct *wq = dev_to_wq(dev);
7061
7062 return scnprintf(buf, PAGE_SIZE, "%d\n",
7063 wq->unbound_attrs->affn_strict);
7064}
7065
7066static ssize_t wq_affinity_strict_store(struct device *dev,
7067 struct device_attribute *attr,
7068 const char *buf, size_t count)
7069{
7070 struct workqueue_struct *wq = dev_to_wq(dev);
7071 struct workqueue_attrs *attrs;
7072 int v, ret = -ENOMEM;
7073
7074 if (sscanf(buf, "%d", &v) != 1)
7075 return -EINVAL;
7076
7077 apply_wqattrs_lock();
7078 attrs = wq_sysfs_prep_attrs(wq);
7079 if (attrs) {
7080 attrs->affn_strict = (bool)v;
7081 ret = apply_workqueue_attrs_locked(wq, attrs);
7082 }
7083 apply_wqattrs_unlock();
7084 free_workqueue_attrs(attrs);
7085 return ret ?: count;
7086}
7087
7088static struct device_attribute wq_sysfs_unbound_attrs[] = {
7089 __ATTR(nice, 0644, wq_nice_show, wq_nice_store),
7090 __ATTR(cpumask, 0644, wq_cpumask_show, wq_cpumask_store),
7091 __ATTR(affinity_scope, 0644, wq_affn_scope_show, wq_affn_scope_store),
7092 __ATTR(affinity_strict, 0644, wq_affinity_strict_show, wq_affinity_strict_store),
7093 __ATTR_NULL,
7094};
7095
7096static const struct bus_type wq_subsys = {
7097 .name = "workqueue",
7098 .dev_groups = wq_sysfs_groups,
7099};
7100
7101/**
7102 * workqueue_set_unbound_cpumask - Set the low-level unbound cpumask
7103 * @cpumask: the cpumask to set
7104 *
7105 * The low-level workqueues cpumask is a global cpumask that limits
7106 * the affinity of all unbound workqueues. This function check the @cpumask
7107 * and apply it to all unbound workqueues and updates all pwqs of them.
7108 *
7109 * Return: 0 - Success
7110 * -EINVAL - Invalid @cpumask
7111 * -ENOMEM - Failed to allocate memory for attrs or pwqs.
7112 */
7113static int workqueue_set_unbound_cpumask(cpumask_var_t cpumask)
7114{
7115 int ret = -EINVAL;
7116
7117 /*
7118 * Not excluding isolated cpus on purpose.
7119 * If the user wishes to include them, we allow that.
7120 */
7121 cpumask_and(cpumask, cpumask, cpu_possible_mask);
7122 if (!cpumask_empty(cpumask)) {
7123 apply_wqattrs_lock();
7124 cpumask_copy(wq_requested_unbound_cpumask, cpumask);
7125 if (cpumask_equal(cpumask, wq_unbound_cpumask)) {
7126 ret = 0;
7127 goto out_unlock;
7128 }
7129
7130 ret = workqueue_apply_unbound_cpumask(cpumask);
7131
7132out_unlock:
7133 apply_wqattrs_unlock();
7134 }
7135
7136 return ret;
7137}
7138
7139static ssize_t __wq_cpumask_show(struct device *dev,
7140 struct device_attribute *attr, char *buf, cpumask_var_t mask)
7141{
7142 int written;
7143
7144 mutex_lock(&wq_pool_mutex);
7145 written = scnprintf(buf, PAGE_SIZE, "%*pb\n", cpumask_pr_args(mask));
7146 mutex_unlock(&wq_pool_mutex);
7147
7148 return written;
7149}
7150
7151static ssize_t wq_unbound_cpumask_show(struct device *dev,
7152 struct device_attribute *attr, char *buf)
7153{
7154 return __wq_cpumask_show(dev, attr, buf, wq_unbound_cpumask);
7155}
7156
7157static ssize_t wq_requested_cpumask_show(struct device *dev,
7158 struct device_attribute *attr, char *buf)
7159{
7160 return __wq_cpumask_show(dev, attr, buf, wq_requested_unbound_cpumask);
7161}
7162
7163static ssize_t wq_isolated_cpumask_show(struct device *dev,
7164 struct device_attribute *attr, char *buf)
7165{
7166 return __wq_cpumask_show(dev, attr, buf, wq_isolated_cpumask);
7167}
7168
7169static ssize_t wq_unbound_cpumask_store(struct device *dev,
7170 struct device_attribute *attr, const char *buf, size_t count)
7171{
7172 cpumask_var_t cpumask;
7173 int ret;
7174
7175 if (!zalloc_cpumask_var(&cpumask, GFP_KERNEL))
7176 return -ENOMEM;
7177
7178 ret = cpumask_parse(buf, cpumask);
7179 if (!ret)
7180 ret = workqueue_set_unbound_cpumask(cpumask);
7181
7182 free_cpumask_var(cpumask);
7183 return ret ? ret : count;
7184}
7185
7186static struct device_attribute wq_sysfs_cpumask_attrs[] = {
7187 __ATTR(cpumask, 0644, wq_unbound_cpumask_show,
7188 wq_unbound_cpumask_store),
7189 __ATTR(cpumask_requested, 0444, wq_requested_cpumask_show, NULL),
7190 __ATTR(cpumask_isolated, 0444, wq_isolated_cpumask_show, NULL),
7191 __ATTR_NULL,
7192};
7193
7194static int __init wq_sysfs_init(void)
7195{
7196 struct device *dev_root;
7197 int err;
7198
7199 err = subsys_virtual_register(&wq_subsys, NULL);
7200 if (err)
7201 return err;
7202
7203 dev_root = bus_get_dev_root(&wq_subsys);
7204 if (dev_root) {
7205 struct device_attribute *attr;
7206
7207 for (attr = wq_sysfs_cpumask_attrs; attr->attr.name; attr++) {
7208 err = device_create_file(dev_root, attr);
7209 if (err)
7210 break;
7211 }
7212 put_device(dev_root);
7213 }
7214 return err;
7215}
7216core_initcall(wq_sysfs_init);
7217
7218static void wq_device_release(struct device *dev)
7219{
7220 struct wq_device *wq_dev = container_of(dev, struct wq_device, dev);
7221
7222 kfree(wq_dev);
7223}
7224
7225/**
7226 * workqueue_sysfs_register - make a workqueue visible in sysfs
7227 * @wq: the workqueue to register
7228 *
7229 * Expose @wq in sysfs under /sys/bus/workqueue/devices.
7230 * alloc_workqueue*() automatically calls this function if WQ_SYSFS is set
7231 * which is the preferred method.
7232 *
7233 * Workqueue user should use this function directly iff it wants to apply
7234 * workqueue_attrs before making the workqueue visible in sysfs; otherwise,
7235 * apply_workqueue_attrs() may race against userland updating the
7236 * attributes.
7237 *
7238 * Return: 0 on success, -errno on failure.
7239 */
7240int workqueue_sysfs_register(struct workqueue_struct *wq)
7241{
7242 struct wq_device *wq_dev;
7243 int ret;
7244
7245 /*
7246 * Adjusting max_active breaks ordering guarantee. Disallow exposing
7247 * ordered workqueues.
7248 */
7249 if (WARN_ON(wq->flags & __WQ_ORDERED))
7250 return -EINVAL;
7251
7252 wq->wq_dev = wq_dev = kzalloc(sizeof(*wq_dev), GFP_KERNEL);
7253 if (!wq_dev)
7254 return -ENOMEM;
7255
7256 wq_dev->wq = wq;
7257 wq_dev->dev.bus = &wq_subsys;
7258 wq_dev->dev.release = wq_device_release;
7259 dev_set_name(&wq_dev->dev, "%s", wq->name);
7260
7261 /*
7262 * unbound_attrs are created separately. Suppress uevent until
7263 * everything is ready.
7264 */
7265 dev_set_uevent_suppress(&wq_dev->dev, true);
7266
7267 ret = device_register(&wq_dev->dev);
7268 if (ret) {
7269 put_device(&wq_dev->dev);
7270 wq->wq_dev = NULL;
7271 return ret;
7272 }
7273
7274 if (wq->flags & WQ_UNBOUND) {
7275 struct device_attribute *attr;
7276
7277 for (attr = wq_sysfs_unbound_attrs; attr->attr.name; attr++) {
7278 ret = device_create_file(&wq_dev->dev, attr);
7279 if (ret) {
7280 device_unregister(&wq_dev->dev);
7281 wq->wq_dev = NULL;
7282 return ret;
7283 }
7284 }
7285 }
7286
7287 dev_set_uevent_suppress(&wq_dev->dev, false);
7288 kobject_uevent(&wq_dev->dev.kobj, KOBJ_ADD);
7289 return 0;
7290}
7291
7292/**
7293 * workqueue_sysfs_unregister - undo workqueue_sysfs_register()
7294 * @wq: the workqueue to unregister
7295 *
7296 * If @wq is registered to sysfs by workqueue_sysfs_register(), unregister.
7297 */
7298static void workqueue_sysfs_unregister(struct workqueue_struct *wq)
7299{
7300 struct wq_device *wq_dev = wq->wq_dev;
7301
7302 if (!wq->wq_dev)
7303 return;
7304
7305 wq->wq_dev = NULL;
7306 device_unregister(&wq_dev->dev);
7307}
7308#else /* CONFIG_SYSFS */
7309static void workqueue_sysfs_unregister(struct workqueue_struct *wq) { }
7310#endif /* CONFIG_SYSFS */
7311
7312/*
7313 * Workqueue watchdog.
7314 *
7315 * Stall may be caused by various bugs - missing WQ_MEM_RECLAIM, illegal
7316 * flush dependency, a concurrency managed work item which stays RUNNING
7317 * indefinitely. Workqueue stalls can be very difficult to debug as the
7318 * usual warning mechanisms don't trigger and internal workqueue state is
7319 * largely opaque.
7320 *
7321 * Workqueue watchdog monitors all worker pools periodically and dumps
7322 * state if some pools failed to make forward progress for a while where
7323 * forward progress is defined as the first item on ->worklist changing.
7324 *
7325 * This mechanism is controlled through the kernel parameter
7326 * "workqueue.watchdog_thresh" which can be updated at runtime through the
7327 * corresponding sysfs parameter file.
7328 */
7329#ifdef CONFIG_WQ_WATCHDOG
7330
7331static unsigned long wq_watchdog_thresh = 30;
7332static struct timer_list wq_watchdog_timer;
7333
7334static unsigned long wq_watchdog_touched = INITIAL_JIFFIES;
7335static DEFINE_PER_CPU(unsigned long, wq_watchdog_touched_cpu) = INITIAL_JIFFIES;
7336
7337/*
7338 * Show workers that might prevent the processing of pending work items.
7339 * The only candidates are CPU-bound workers in the running state.
7340 * Pending work items should be handled by another idle worker
7341 * in all other situations.
7342 */
7343static void show_cpu_pool_hog(struct worker_pool *pool)
7344{
7345 struct worker *worker;
7346 unsigned long irq_flags;
7347 int bkt;
7348
7349 raw_spin_lock_irqsave(&pool->lock, irq_flags);
7350
7351 hash_for_each(pool->busy_hash, bkt, worker, hentry) {
7352 if (task_is_running(worker->task)) {
7353 /*
7354 * Defer printing to avoid deadlocks in console
7355 * drivers that queue work while holding locks
7356 * also taken in their write paths.
7357 */
7358 printk_deferred_enter();
7359
7360 pr_info("pool %d:\n", pool->id);
7361 sched_show_task(worker->task);
7362
7363 printk_deferred_exit();
7364 }
7365 }
7366
7367 raw_spin_unlock_irqrestore(&pool->lock, irq_flags);
7368}
7369
7370static void show_cpu_pools_hogs(void)
7371{
7372 struct worker_pool *pool;
7373 int pi;
7374
7375 pr_info("Showing backtraces of running workers in stalled CPU-bound worker pools:\n");
7376
7377 rcu_read_lock();
7378
7379 for_each_pool(pool, pi) {
7380 if (pool->cpu_stall)
7381 show_cpu_pool_hog(pool);
7382
7383 }
7384
7385 rcu_read_unlock();
7386}
7387
7388static void wq_watchdog_reset_touched(void)
7389{
7390 int cpu;
7391
7392 wq_watchdog_touched = jiffies;
7393 for_each_possible_cpu(cpu)
7394 per_cpu(wq_watchdog_touched_cpu, cpu) = jiffies;
7395}
7396
7397static void wq_watchdog_timer_fn(struct timer_list *unused)
7398{
7399 unsigned long thresh = READ_ONCE(wq_watchdog_thresh) * HZ;
7400 bool lockup_detected = false;
7401 bool cpu_pool_stall = false;
7402 unsigned long now = jiffies;
7403 struct worker_pool *pool;
7404 int pi;
7405
7406 if (!thresh)
7407 return;
7408
7409 rcu_read_lock();
7410
7411 for_each_pool(pool, pi) {
7412 unsigned long pool_ts, touched, ts;
7413
7414 pool->cpu_stall = false;
7415 if (list_empty(&pool->worklist))
7416 continue;
7417
7418 /*
7419 * If a virtual machine is stopped by the host it can look to
7420 * the watchdog like a stall.
7421 */
7422 kvm_check_and_clear_guest_paused();
7423
7424 /* get the latest of pool and touched timestamps */
7425 if (pool->cpu >= 0)
7426 touched = READ_ONCE(per_cpu(wq_watchdog_touched_cpu, pool->cpu));
7427 else
7428 touched = READ_ONCE(wq_watchdog_touched);
7429 pool_ts = READ_ONCE(pool->watchdog_ts);
7430
7431 if (time_after(pool_ts, touched))
7432 ts = pool_ts;
7433 else
7434 ts = touched;
7435
7436 /* did we stall? */
7437 if (time_after(now, ts + thresh)) {
7438 lockup_detected = true;
7439 if (pool->cpu >= 0 && !(pool->flags & POOL_BH)) {
7440 pool->cpu_stall = true;
7441 cpu_pool_stall = true;
7442 }
7443 pr_emerg("BUG: workqueue lockup - pool");
7444 pr_cont_pool_info(pool);
7445 pr_cont(" stuck for %us!\n",
7446 jiffies_to_msecs(now - pool_ts) / 1000);
7447 }
7448
7449
7450 }
7451
7452 rcu_read_unlock();
7453
7454 if (lockup_detected)
7455 show_all_workqueues();
7456
7457 if (cpu_pool_stall)
7458 show_cpu_pools_hogs();
7459
7460 wq_watchdog_reset_touched();
7461 mod_timer(&wq_watchdog_timer, jiffies + thresh);
7462}
7463
7464notrace void wq_watchdog_touch(int cpu)
7465{
7466 if (cpu >= 0)
7467 per_cpu(wq_watchdog_touched_cpu, cpu) = jiffies;
7468
7469 wq_watchdog_touched = jiffies;
7470}
7471
7472static void wq_watchdog_set_thresh(unsigned long thresh)
7473{
7474 wq_watchdog_thresh = 0;
7475 del_timer_sync(&wq_watchdog_timer);
7476
7477 if (thresh) {
7478 wq_watchdog_thresh = thresh;
7479 wq_watchdog_reset_touched();
7480 mod_timer(&wq_watchdog_timer, jiffies + thresh * HZ);
7481 }
7482}
7483
7484static int wq_watchdog_param_set_thresh(const char *val,
7485 const struct kernel_param *kp)
7486{
7487 unsigned long thresh;
7488 int ret;
7489
7490 ret = kstrtoul(val, 0, &thresh);
7491 if (ret)
7492 return ret;
7493
7494 if (system_wq)
7495 wq_watchdog_set_thresh(thresh);
7496 else
7497 wq_watchdog_thresh = thresh;
7498
7499 return 0;
7500}
7501
7502static const struct kernel_param_ops wq_watchdog_thresh_ops = {
7503 .set = wq_watchdog_param_set_thresh,
7504 .get = param_get_ulong,
7505};
7506
7507module_param_cb(watchdog_thresh, &wq_watchdog_thresh_ops, &wq_watchdog_thresh,
7508 0644);
7509
7510static void wq_watchdog_init(void)
7511{
7512 timer_setup(&wq_watchdog_timer, wq_watchdog_timer_fn, TIMER_DEFERRABLE);
7513 wq_watchdog_set_thresh(wq_watchdog_thresh);
7514}
7515
7516#else /* CONFIG_WQ_WATCHDOG */
7517
7518static inline void wq_watchdog_init(void) { }
7519
7520#endif /* CONFIG_WQ_WATCHDOG */
7521
7522static void bh_pool_kick_normal(struct irq_work *irq_work)
7523{
7524 raise_softirq_irqoff(TASKLET_SOFTIRQ);
7525}
7526
7527static void bh_pool_kick_highpri(struct irq_work *irq_work)
7528{
7529 raise_softirq_irqoff(HI_SOFTIRQ);
7530}
7531
7532static void __init restrict_unbound_cpumask(const char *name, const struct cpumask *mask)
7533{
7534 if (!cpumask_intersects(wq_unbound_cpumask, mask)) {
7535 pr_warn("workqueue: Restricting unbound_cpumask (%*pb) with %s (%*pb) leaves no CPU, ignoring\n",
7536 cpumask_pr_args(wq_unbound_cpumask), name, cpumask_pr_args(mask));
7537 return;
7538 }
7539
7540 cpumask_and(wq_unbound_cpumask, wq_unbound_cpumask, mask);
7541}
7542
7543static void __init init_cpu_worker_pool(struct worker_pool *pool, int cpu, int nice)
7544{
7545 BUG_ON(init_worker_pool(pool));
7546 pool->cpu = cpu;
7547 cpumask_copy(pool->attrs->cpumask, cpumask_of(cpu));
7548 cpumask_copy(pool->attrs->__pod_cpumask, cpumask_of(cpu));
7549 pool->attrs->nice = nice;
7550 pool->attrs->affn_strict = true;
7551 pool->node = cpu_to_node(cpu);
7552
7553 /* alloc pool ID */
7554 mutex_lock(&wq_pool_mutex);
7555 BUG_ON(worker_pool_assign_id(pool));
7556 mutex_unlock(&wq_pool_mutex);
7557}
7558
7559/**
7560 * workqueue_init_early - early init for workqueue subsystem
7561 *
7562 * This is the first step of three-staged workqueue subsystem initialization and
7563 * invoked as soon as the bare basics - memory allocation, cpumasks and idr are
7564 * up. It sets up all the data structures and system workqueues and allows early
7565 * boot code to create workqueues and queue/cancel work items. Actual work item
7566 * execution starts only after kthreads can be created and scheduled right
7567 * before early initcalls.
7568 */
7569void __init workqueue_init_early(void)
7570{
7571 struct wq_pod_type *pt = &wq_pod_types[WQ_AFFN_SYSTEM];
7572 int std_nice[NR_STD_WORKER_POOLS] = { 0, HIGHPRI_NICE_LEVEL };
7573 void (*irq_work_fns[2])(struct irq_work *) = { bh_pool_kick_normal,
7574 bh_pool_kick_highpri };
7575 int i, cpu;
7576
7577 BUILD_BUG_ON(__alignof__(struct pool_workqueue) < __alignof__(long long));
7578
7579 BUG_ON(!alloc_cpumask_var(&wq_unbound_cpumask, GFP_KERNEL));
7580 BUG_ON(!alloc_cpumask_var(&wq_requested_unbound_cpumask, GFP_KERNEL));
7581 BUG_ON(!zalloc_cpumask_var(&wq_isolated_cpumask, GFP_KERNEL));
7582
7583 cpumask_copy(wq_unbound_cpumask, cpu_possible_mask);
7584 restrict_unbound_cpumask("HK_TYPE_WQ", housekeeping_cpumask(HK_TYPE_WQ));
7585 restrict_unbound_cpumask("HK_TYPE_DOMAIN", housekeeping_cpumask(HK_TYPE_DOMAIN));
7586 if (!cpumask_empty(&wq_cmdline_cpumask))
7587 restrict_unbound_cpumask("workqueue.unbound_cpus", &wq_cmdline_cpumask);
7588
7589 cpumask_copy(wq_requested_unbound_cpumask, wq_unbound_cpumask);
7590
7591 pwq_cache = KMEM_CACHE(pool_workqueue, SLAB_PANIC);
7592
7593 wq_update_pod_attrs_buf = alloc_workqueue_attrs();
7594 BUG_ON(!wq_update_pod_attrs_buf);
7595
7596 /*
7597 * If nohz_full is enabled, set power efficient workqueue as unbound.
7598 * This allows workqueue items to be moved to HK CPUs.
7599 */
7600 if (housekeeping_enabled(HK_TYPE_TICK))
7601 wq_power_efficient = true;
7602
7603 /* initialize WQ_AFFN_SYSTEM pods */
7604 pt->pod_cpus = kcalloc(1, sizeof(pt->pod_cpus[0]), GFP_KERNEL);
7605 pt->pod_node = kcalloc(1, sizeof(pt->pod_node[0]), GFP_KERNEL);
7606 pt->cpu_pod = kcalloc(nr_cpu_ids, sizeof(pt->cpu_pod[0]), GFP_KERNEL);
7607 BUG_ON(!pt->pod_cpus || !pt->pod_node || !pt->cpu_pod);
7608
7609 BUG_ON(!zalloc_cpumask_var_node(&pt->pod_cpus[0], GFP_KERNEL, NUMA_NO_NODE));
7610
7611 pt->nr_pods = 1;
7612 cpumask_copy(pt->pod_cpus[0], cpu_possible_mask);
7613 pt->pod_node[0] = NUMA_NO_NODE;
7614 pt->cpu_pod[0] = 0;
7615
7616 /* initialize BH and CPU pools */
7617 for_each_possible_cpu(cpu) {
7618 struct worker_pool *pool;
7619
7620 i = 0;
7621 for_each_bh_worker_pool(pool, cpu) {
7622 init_cpu_worker_pool(pool, cpu, std_nice[i]);
7623 pool->flags |= POOL_BH;
7624 init_irq_work(bh_pool_irq_work(pool), irq_work_fns[i]);
7625 i++;
7626 }
7627
7628 i = 0;
7629 for_each_cpu_worker_pool(pool, cpu)
7630 init_cpu_worker_pool(pool, cpu, std_nice[i++]);
7631 }
7632
7633 /* create default unbound and ordered wq attrs */
7634 for (i = 0; i < NR_STD_WORKER_POOLS; i++) {
7635 struct workqueue_attrs *attrs;
7636
7637 BUG_ON(!(attrs = alloc_workqueue_attrs()));
7638 attrs->nice = std_nice[i];
7639 unbound_std_wq_attrs[i] = attrs;
7640
7641 /*
7642 * An ordered wq should have only one pwq as ordering is
7643 * guaranteed by max_active which is enforced by pwqs.
7644 */
7645 BUG_ON(!(attrs = alloc_workqueue_attrs()));
7646 attrs->nice = std_nice[i];
7647 attrs->ordered = true;
7648 ordered_wq_attrs[i] = attrs;
7649 }
7650
7651 system_wq = alloc_workqueue("events", 0, 0);
7652 system_highpri_wq = alloc_workqueue("events_highpri", WQ_HIGHPRI, 0);
7653 system_long_wq = alloc_workqueue("events_long", 0, 0);
7654 system_unbound_wq = alloc_workqueue("events_unbound", WQ_UNBOUND,
7655 WQ_MAX_ACTIVE);
7656 system_freezable_wq = alloc_workqueue("events_freezable",
7657 WQ_FREEZABLE, 0);
7658 system_power_efficient_wq = alloc_workqueue("events_power_efficient",
7659 WQ_POWER_EFFICIENT, 0);
7660 system_freezable_power_efficient_wq = alloc_workqueue("events_freezable_pwr_efficient",
7661 WQ_FREEZABLE | WQ_POWER_EFFICIENT,
7662 0);
7663 system_bh_wq = alloc_workqueue("events_bh", WQ_BH, 0);
7664 system_bh_highpri_wq = alloc_workqueue("events_bh_highpri",
7665 WQ_BH | WQ_HIGHPRI, 0);
7666 BUG_ON(!system_wq || !system_highpri_wq || !system_long_wq ||
7667 !system_unbound_wq || !system_freezable_wq ||
7668 !system_power_efficient_wq ||
7669 !system_freezable_power_efficient_wq ||
7670 !system_bh_wq || !system_bh_highpri_wq);
7671}
7672
7673static void __init wq_cpu_intensive_thresh_init(void)
7674{
7675 unsigned long thresh;
7676 unsigned long bogo;
7677
7678 pwq_release_worker = kthread_create_worker(0, "pool_workqueue_release");
7679 BUG_ON(IS_ERR(pwq_release_worker));
7680
7681 /* if the user set it to a specific value, keep it */
7682 if (wq_cpu_intensive_thresh_us != ULONG_MAX)
7683 return;
7684
7685 /*
7686 * The default of 10ms is derived from the fact that most modern (as of
7687 * 2023) processors can do a lot in 10ms and that it's just below what
7688 * most consider human-perceivable. However, the kernel also runs on a
7689 * lot slower CPUs including microcontrollers where the threshold is way
7690 * too low.
7691 *
7692 * Let's scale up the threshold upto 1 second if BogoMips is below 4000.
7693 * This is by no means accurate but it doesn't have to be. The mechanism
7694 * is still useful even when the threshold is fully scaled up. Also, as
7695 * the reports would usually be applicable to everyone, some machines
7696 * operating on longer thresholds won't significantly diminish their
7697 * usefulness.
7698 */
7699 thresh = 10 * USEC_PER_MSEC;
7700
7701 /* see init/calibrate.c for lpj -> BogoMIPS calculation */
7702 bogo = max_t(unsigned long, loops_per_jiffy / 500000 * HZ, 1);
7703 if (bogo < 4000)
7704 thresh = min_t(unsigned long, thresh * 4000 / bogo, USEC_PER_SEC);
7705
7706 pr_debug("wq_cpu_intensive_thresh: lpj=%lu BogoMIPS=%lu thresh_us=%lu\n",
7707 loops_per_jiffy, bogo, thresh);
7708
7709 wq_cpu_intensive_thresh_us = thresh;
7710}
7711
7712/**
7713 * workqueue_init - bring workqueue subsystem fully online
7714 *
7715 * This is the second step of three-staged workqueue subsystem initialization
7716 * and invoked as soon as kthreads can be created and scheduled. Workqueues have
7717 * been created and work items queued on them, but there are no kworkers
7718 * executing the work items yet. Populate the worker pools with the initial
7719 * workers and enable future kworker creations.
7720 */
7721void __init workqueue_init(void)
7722{
7723 struct workqueue_struct *wq;
7724 struct worker_pool *pool;
7725 int cpu, bkt;
7726
7727 wq_cpu_intensive_thresh_init();
7728
7729 mutex_lock(&wq_pool_mutex);
7730
7731 /*
7732 * Per-cpu pools created earlier could be missing node hint. Fix them
7733 * up. Also, create a rescuer for workqueues that requested it.
7734 */
7735 for_each_possible_cpu(cpu) {
7736 for_each_bh_worker_pool(pool, cpu)
7737 pool->node = cpu_to_node(cpu);
7738 for_each_cpu_worker_pool(pool, cpu)
7739 pool->node = cpu_to_node(cpu);
7740 }
7741
7742 list_for_each_entry(wq, &workqueues, list) {
7743 WARN(init_rescuer(wq),
7744 "workqueue: failed to create early rescuer for %s",
7745 wq->name);
7746 }
7747
7748 mutex_unlock(&wq_pool_mutex);
7749
7750 /*
7751 * Create the initial workers. A BH pool has one pseudo worker that
7752 * represents the shared BH execution context and thus doesn't get
7753 * affected by hotplug events. Create the BH pseudo workers for all
7754 * possible CPUs here.
7755 */
7756 for_each_possible_cpu(cpu)
7757 for_each_bh_worker_pool(pool, cpu)
7758 BUG_ON(!create_worker(pool));
7759
7760 for_each_online_cpu(cpu) {
7761 for_each_cpu_worker_pool(pool, cpu) {
7762 pool->flags &= ~POOL_DISASSOCIATED;
7763 BUG_ON(!create_worker(pool));
7764 }
7765 }
7766
7767 hash_for_each(unbound_pool_hash, bkt, pool, hash_node)
7768 BUG_ON(!create_worker(pool));
7769
7770 wq_online = true;
7771 wq_watchdog_init();
7772}
7773
7774/*
7775 * Initialize @pt by first initializing @pt->cpu_pod[] with pod IDs according to
7776 * @cpu_shares_pod(). Each subset of CPUs that share a pod is assigned a unique
7777 * and consecutive pod ID. The rest of @pt is initialized accordingly.
7778 */
7779static void __init init_pod_type(struct wq_pod_type *pt,
7780 bool (*cpus_share_pod)(int, int))
7781{
7782 int cur, pre, cpu, pod;
7783
7784 pt->nr_pods = 0;
7785
7786 /* init @pt->cpu_pod[] according to @cpus_share_pod() */
7787 pt->cpu_pod = kcalloc(nr_cpu_ids, sizeof(pt->cpu_pod[0]), GFP_KERNEL);
7788 BUG_ON(!pt->cpu_pod);
7789
7790 for_each_possible_cpu(cur) {
7791 for_each_possible_cpu(pre) {
7792 if (pre >= cur) {
7793 pt->cpu_pod[cur] = pt->nr_pods++;
7794 break;
7795 }
7796 if (cpus_share_pod(cur, pre)) {
7797 pt->cpu_pod[cur] = pt->cpu_pod[pre];
7798 break;
7799 }
7800 }
7801 }
7802
7803 /* init the rest to match @pt->cpu_pod[] */
7804 pt->pod_cpus = kcalloc(pt->nr_pods, sizeof(pt->pod_cpus[0]), GFP_KERNEL);
7805 pt->pod_node = kcalloc(pt->nr_pods, sizeof(pt->pod_node[0]), GFP_KERNEL);
7806 BUG_ON(!pt->pod_cpus || !pt->pod_node);
7807
7808 for (pod = 0; pod < pt->nr_pods; pod++)
7809 BUG_ON(!zalloc_cpumask_var(&pt->pod_cpus[pod], GFP_KERNEL));
7810
7811 for_each_possible_cpu(cpu) {
7812 cpumask_set_cpu(cpu, pt->pod_cpus[pt->cpu_pod[cpu]]);
7813 pt->pod_node[pt->cpu_pod[cpu]] = cpu_to_node(cpu);
7814 }
7815}
7816
7817static bool __init cpus_dont_share(int cpu0, int cpu1)
7818{
7819 return false;
7820}
7821
7822static bool __init cpus_share_smt(int cpu0, int cpu1)
7823{
7824#ifdef CONFIG_SCHED_SMT
7825 return cpumask_test_cpu(cpu0, cpu_smt_mask(cpu1));
7826#else
7827 return false;
7828#endif
7829}
7830
7831static bool __init cpus_share_numa(int cpu0, int cpu1)
7832{
7833 return cpu_to_node(cpu0) == cpu_to_node(cpu1);
7834}
7835
7836/**
7837 * workqueue_init_topology - initialize CPU pods for unbound workqueues
7838 *
7839 * This is the third step of three-staged workqueue subsystem initialization and
7840 * invoked after SMP and topology information are fully initialized. It
7841 * initializes the unbound CPU pods accordingly.
7842 */
7843void __init workqueue_init_topology(void)
7844{
7845 struct workqueue_struct *wq;
7846 int cpu;
7847
7848 init_pod_type(&wq_pod_types[WQ_AFFN_CPU], cpus_dont_share);
7849 init_pod_type(&wq_pod_types[WQ_AFFN_SMT], cpus_share_smt);
7850 init_pod_type(&wq_pod_types[WQ_AFFN_CACHE], cpus_share_cache);
7851 init_pod_type(&wq_pod_types[WQ_AFFN_NUMA], cpus_share_numa);
7852
7853 wq_topo_initialized = true;
7854
7855 mutex_lock(&wq_pool_mutex);
7856
7857 /*
7858 * Workqueues allocated earlier would have all CPUs sharing the default
7859 * worker pool. Explicitly call wq_update_pod() on all workqueue and CPU
7860 * combinations to apply per-pod sharing.
7861 */
7862 list_for_each_entry(wq, &workqueues, list) {
7863 for_each_online_cpu(cpu)
7864 wq_update_pod(wq, cpu, cpu, true);
7865 if (wq->flags & WQ_UNBOUND) {
7866 mutex_lock(&wq->mutex);
7867 wq_update_node_max_active(wq, -1);
7868 mutex_unlock(&wq->mutex);
7869 }
7870 }
7871
7872 mutex_unlock(&wq_pool_mutex);
7873}
7874
7875void __warn_flushing_systemwide_wq(void)
7876{
7877 pr_warn("WARNING: Flushing system-wide workqueues will be prohibited in near future.\n");
7878 dump_stack();
7879}
7880EXPORT_SYMBOL(__warn_flushing_systemwide_wq);
7881
7882static int __init workqueue_unbound_cpus_setup(char *str)
7883{
7884 if (cpulist_parse(str, &wq_cmdline_cpumask) < 0) {
7885 cpumask_clear(&wq_cmdline_cpumask);
7886 pr_warn("workqueue.unbound_cpus: incorrect CPU range, using default\n");
7887 }
7888
7889 return 1;
7890}
7891__setup("workqueue.unbound_cpus=", workqueue_unbound_cpus_setup);