forked from Minki/linux
6e736be7f2
Ignoring copy_io() during fork, io_context can be allocated from two places - current_io_context() and set_task_ioprio(). The former is always called from local task while the latter can be called from different task. The synchornization between them are peculiar and dubious. * current_io_context() doesn't grab task_lock() and assumes that if it saw %NULL ->io_context, it would stay that way until allocation and assignment is complete. It has smp_wmb() between alloc/init and assignment. * set_task_ioprio() grabs task_lock() for assignment and does smp_read_barrier_depends() between "ioc = task->io_context" and "if (ioc)". Unfortunately, this doesn't achieve anything - the latter is not a dependent load of the former. ie, if ioc itself were being dereferenced "ioc->xxx", it would mean something (not sure what tho) but as the code currently stands, the dependent read barrier is noop. As only one of the the two test-assignment sequences is task_lock() protected, the task_lock() can't do much about race between the two. Nothing prevents current_io_context() and set_task_ioprio() allocating its own ioc for the same task and overwriting the other's. Also, set_task_ioprio() can race with exiting task and create a new ioc after exit_io_context() is finished. ioc get/put doesn't have any reason to be complex. The only hot path is accessing the existing ioc of %current, which is simple to achieve given that ->io_context is never destroyed as long as the task is alive. All other paths can happily go through task_lock() like all other task sub structures without impacting anything. This patch updates ioc get/put so that it becomes more conventional. * alloc_io_context() is replaced with get_task_io_context(). This is the only interface which can acquire access to ioc of another task. On return, the caller has an explicit reference to the object which should be put using put_io_context() afterwards. * The functionality of current_io_context() remains the same but when creating a new ioc, it shares the code path with get_task_io_context() and always goes through task_lock(). * get_io_context() now means incrementing ref on an ioc which the caller already has access to (be that an explicit refcnt or implicit %current one). * PF_EXITING inhibits creation of new io_context and once exit_io_context() is finished, it's guaranteed that both ioc acquisition functions return %NULL. * All users are updated. Most are trivial but smp_read_barrier_depends() removal from cfq_get_io_context() needs a bit of explanation. I suppose the original intention was to ensure ioc->ioprio is visible when set_task_ioprio() allocates new io_context and installs it; however, this wouldn't have worked because set_task_ioprio() doesn't have wmb between init and install. There are other problems with this which will be fixed in another patch. * While at it, use NUMA_NO_NODE instead of -1 for wildcard node specification. -v2: Vivek spotted contamination from debug patch. Removed. Signed-off-by: Tejun Heo <tj@kernel.org> Cc: Vivek Goyal <vgoyal@redhat.com> Signed-off-by: Jens Axboe <axboe@kernel.dk>
214 lines
6.4 KiB
C
214 lines
6.4 KiB
C
#ifndef BLK_INTERNAL_H
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#define BLK_INTERNAL_H
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#include <linux/idr.h>
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/* Amount of time in which a process may batch requests */
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#define BLK_BATCH_TIME (HZ/50UL)
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/* Number of requests a "batching" process may submit */
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#define BLK_BATCH_REQ 32
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extern struct kmem_cache *blk_requestq_cachep;
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extern struct kobj_type blk_queue_ktype;
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extern struct ida blk_queue_ida;
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void init_request_from_bio(struct request *req, struct bio *bio);
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void blk_rq_bio_prep(struct request_queue *q, struct request *rq,
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struct bio *bio);
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int blk_rq_append_bio(struct request_queue *q, struct request *rq,
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struct bio *bio);
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void blk_drain_queue(struct request_queue *q, bool drain_all);
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void blk_dequeue_request(struct request *rq);
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void __blk_queue_free_tags(struct request_queue *q);
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bool __blk_end_bidi_request(struct request *rq, int error,
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unsigned int nr_bytes, unsigned int bidi_bytes);
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void blk_rq_timed_out_timer(unsigned long data);
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void blk_delete_timer(struct request *);
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void blk_add_timer(struct request *);
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void __generic_unplug_device(struct request_queue *);
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/*
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* Internal atomic flags for request handling
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*/
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enum rq_atomic_flags {
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REQ_ATOM_COMPLETE = 0,
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};
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/*
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* EH timer and IO completion will both attempt to 'grab' the request, make
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* sure that only one of them succeeds
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*/
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static inline int blk_mark_rq_complete(struct request *rq)
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{
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return test_and_set_bit(REQ_ATOM_COMPLETE, &rq->atomic_flags);
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}
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static inline void blk_clear_rq_complete(struct request *rq)
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{
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clear_bit(REQ_ATOM_COMPLETE, &rq->atomic_flags);
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}
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/*
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* Internal elevator interface
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*/
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#define ELV_ON_HASH(rq) (!hlist_unhashed(&(rq)->hash))
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void blk_insert_flush(struct request *rq);
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void blk_abort_flushes(struct request_queue *q);
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static inline struct request *__elv_next_request(struct request_queue *q)
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{
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struct request *rq;
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while (1) {
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if (!list_empty(&q->queue_head)) {
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rq = list_entry_rq(q->queue_head.next);
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return rq;
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}
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/*
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* Flush request is running and flush request isn't queueable
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* in the drive, we can hold the queue till flush request is
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* finished. Even we don't do this, driver can't dispatch next
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* requests and will requeue them. And this can improve
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* throughput too. For example, we have request flush1, write1,
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* flush 2. flush1 is dispatched, then queue is hold, write1
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* isn't inserted to queue. After flush1 is finished, flush2
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* will be dispatched. Since disk cache is already clean,
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* flush2 will be finished very soon, so looks like flush2 is
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* folded to flush1.
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* Since the queue is hold, a flag is set to indicate the queue
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* should be restarted later. Please see flush_end_io() for
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* details.
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*/
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if (q->flush_pending_idx != q->flush_running_idx &&
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!queue_flush_queueable(q)) {
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q->flush_queue_delayed = 1;
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return NULL;
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}
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if (unlikely(blk_queue_dead(q)) ||
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!q->elevator->ops->elevator_dispatch_fn(q, 0))
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return NULL;
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}
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}
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static inline void elv_activate_rq(struct request_queue *q, struct request *rq)
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{
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struct elevator_queue *e = q->elevator;
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if (e->ops->elevator_activate_req_fn)
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e->ops->elevator_activate_req_fn(q, rq);
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}
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static inline void elv_deactivate_rq(struct request_queue *q, struct request *rq)
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{
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struct elevator_queue *e = q->elevator;
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if (e->ops->elevator_deactivate_req_fn)
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e->ops->elevator_deactivate_req_fn(q, rq);
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}
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#ifdef CONFIG_FAIL_IO_TIMEOUT
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int blk_should_fake_timeout(struct request_queue *);
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ssize_t part_timeout_show(struct device *, struct device_attribute *, char *);
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ssize_t part_timeout_store(struct device *, struct device_attribute *,
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const char *, size_t);
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#else
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static inline int blk_should_fake_timeout(struct request_queue *q)
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{
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return 0;
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}
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#endif
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void get_io_context(struct io_context *ioc);
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struct io_context *current_io_context(gfp_t gfp_flags, int node);
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int ll_back_merge_fn(struct request_queue *q, struct request *req,
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struct bio *bio);
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int ll_front_merge_fn(struct request_queue *q, struct request *req,
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struct bio *bio);
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int attempt_back_merge(struct request_queue *q, struct request *rq);
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int attempt_front_merge(struct request_queue *q, struct request *rq);
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int blk_attempt_req_merge(struct request_queue *q, struct request *rq,
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struct request *next);
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void blk_recalc_rq_segments(struct request *rq);
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void blk_rq_set_mixed_merge(struct request *rq);
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void blk_queue_congestion_threshold(struct request_queue *q);
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int blk_dev_init(void);
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void elv_quiesce_start(struct request_queue *q);
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void elv_quiesce_end(struct request_queue *q);
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/*
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* Return the threshold (number of used requests) at which the queue is
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* considered to be congested. It include a little hysteresis to keep the
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* context switch rate down.
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*/
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static inline int queue_congestion_on_threshold(struct request_queue *q)
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{
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return q->nr_congestion_on;
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}
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/*
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* The threshold at which a queue is considered to be uncongested
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*/
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static inline int queue_congestion_off_threshold(struct request_queue *q)
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{
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return q->nr_congestion_off;
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}
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static inline int blk_cpu_to_group(int cpu)
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{
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int group = NR_CPUS;
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#ifdef CONFIG_SCHED_MC
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const struct cpumask *mask = cpu_coregroup_mask(cpu);
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group = cpumask_first(mask);
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#elif defined(CONFIG_SCHED_SMT)
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group = cpumask_first(topology_thread_cpumask(cpu));
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#else
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return cpu;
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#endif
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if (likely(group < NR_CPUS))
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return group;
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return cpu;
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}
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/*
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* Contribute to IO statistics IFF:
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*
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* a) it's attached to a gendisk, and
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* b) the queue had IO stats enabled when this request was started, and
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* c) it's a file system request or a discard request
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*/
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static inline int blk_do_io_stat(struct request *rq)
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{
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return rq->rq_disk &&
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(rq->cmd_flags & REQ_IO_STAT) &&
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(rq->cmd_type == REQ_TYPE_FS ||
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(rq->cmd_flags & REQ_DISCARD));
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}
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#ifdef CONFIG_BLK_DEV_THROTTLING
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extern bool blk_throtl_bio(struct request_queue *q, struct bio *bio);
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extern void blk_throtl_drain(struct request_queue *q);
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extern int blk_throtl_init(struct request_queue *q);
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extern void blk_throtl_exit(struct request_queue *q);
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extern void blk_throtl_release(struct request_queue *q);
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#else /* CONFIG_BLK_DEV_THROTTLING */
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static inline bool blk_throtl_bio(struct request_queue *q, struct bio *bio)
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{
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return false;
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}
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static inline void blk_throtl_drain(struct request_queue *q) { }
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static inline int blk_throtl_init(struct request_queue *q) { return 0; }
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static inline void blk_throtl_exit(struct request_queue *q) { }
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static inline void blk_throtl_release(struct request_queue *q) { }
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#endif /* CONFIG_BLK_DEV_THROTTLING */
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#endif /* BLK_INTERNAL_H */
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