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1 /*
2 * Copyright © 2008-2015 Intel Corporation
3 *
4 * Permission is hereby granted, free of charge, to any person obtaining a
5 * copy of this software and associated documentation files (the "Software"),
6 * to deal in the Software without restriction, including without limitation
7 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
8 * and/or sell copies of the Software, and to permit persons to whom the
9 * Software is furnished to do so, subject to the following conditions:
10 *
11 * The above copyright notice and this permission notice (including the next
12 * paragraph) shall be included in all copies or substantial portions of the
13 * Software.
14 *
15 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
16 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
17 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
18 * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
19 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
20 * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
21 * IN THE SOFTWARE.
22 *
23 */
25 #ifndef I915_GEM_REQUEST_H
26 #define I915_GEM_REQUEST_H
28 #include <linux/dma-fence.h>
41 u32 seqno;
42 };
47 };
55 #define I915_DEPENDENCY_ALLOC BIT(0)
56 };
58 /* Requests exist in a complex web of interdependencies. Each request
59 * has to wait for some other request to complete before it is ready to be run
60 * (e.g. we have to wait until the pixels have been rendering into a texture
61 * before we can copy from it). We track the readiness of a request in terms
62 * of fences, but we also need to keep the dependency tree for the lifetime
63 * of the request (beyond the life of an individual fence). We use the tree
64 * at various points to reorder the requests whilst keeping the requests
65 * in order with respect to their various dependencies.
66 */
72 #define I915_PRIORITY_MAX 1024
73 #define I915_PRIORITY_MIN (-I915_PRIORITY_MAX)
74 };
76 /**
77 * Request queue structure.
78 *
79 * The request queue allows us to note sequence numbers that have been emitted
80 * and may be associated with active buffers to be retired.
81 *
82 * By keeping this list, we can avoid having to do questionable sequence
83 * number comparisons on buffer last_read|write_seqno. It also allows an
84 * emission time to be associated with the request for tracking how far ahead
85 * of the GPU the submission is.
86 *
87 * When modifying this structure be very aware that we perform a lockless
88 * RCU lookup of it that may race against reallocation of the struct
89 * from the slab freelist. We intentionally do not zero the structure on
90 * allocation so that the lookup can use the dangling pointers (and is
91 * cogniscent that those pointers may be wrong). Instead, everything that
92 * needs to be initialised must be done so explicitly.
93 *
94 * The requests are reference counted.
95 */
98 spinlock_t lock;
100 /** On Which ring this request was generated */
103 /**
104 * Context and ring buffer related to this request
105 * Contexts are refcounted, so when this request is associated with a
106 * context, we must increment the context's refcount, to guarantee that
107 * it persists while any request is linked to it. Requests themselves
108 * are also refcounted, so the request will only be freed when the last
109 * reference to it is dismissed, and the code in
110 * i915_gem_request_free() will then decrement the refcount on the
111 * context.
112 */
119 /* Fences for the various phases in the request's lifetime.
120 *
121 * The submit fence is used to await upon all of the request's
122 * dependencies. When it is signaled, the request is ready to run.
123 * It is used by the driver to then queue the request for execution.
124 */
126 wait_queue_t submitq;
127 wait_queue_head_t execute;
129 /* A list of everyone we wait upon, and everyone who waits upon us.
130 * Even though we will not be submitted to the hardware before the
131 * submit fence is signaled (it waits for all external events as well
132 * as our own requests), the scheduler still needs to know the
133 * dependency tree for the lifetime of the request (from execbuf
134 * to retirement), i.e. bidirectional dependency information for the
135 * request not tied to individual fences.
136 */
140 /** GEM sequence number associated with this request on the
141 * global execution timeline. It is zero when the request is not
142 * on the HW queue (i.e. not on the engine timeline list).
143 * Its value is guarded by the timeline spinlock.
144 */
145 u32 global_seqno;
147 /** Position in the ring of the start of the request */
148 u32 head;
150 /**
151 * Position in the ring of the start of the postfix.
152 * This is required to calculate the maximum available ring space
153 * without overwriting the postfix.
154 */
155 u32 postfix;
157 /** Position in the ring of the end of the whole request */
158 u32 tail;
160 /** Position in the ring of the end of any workarounds after the tail */
161 u32 wa_tail;
163 /** Preallocate space in the ring for the emitting the request */
164 u32 reserved_space;
166 /** Batch buffer related to this request if any (used for
167 * error state dump only).
168 */
172 /** Time at which this request was emitted, in jiffies. */
175 /** engine->request_list entry for this request */
178 /** ring->request_list entry for this request */
182 /** file_priv list entry for this request */
184 };
189 {
191 }
200 {
201 /* We assume that NULL fence/request are interoperable */
205 }
209 {
211 }
215 {
217 }
221 {
223 }
227 {
235 }
237 /**
238 * i915_gem_request_global_seqno - report the current global seqno
239 * @request - the request
240 *
241 * A request is assigned a global seqno only when it is on the hardware
242 * execution queue. The global seqno can be used to maintain a list of
243 * requests on the same engine in retirement order, for example for
244 * constructing a priority queue for waiting. Prior to its execution, or
245 * if it is subsequently removed in the event of preemption, its global
246 * seqno is zero. As both insertion and removal from the execution queue
247 * may operate in IRQ context, it is not guarded by the usual struct_mutex
248 * BKL. Instead those relying on the global seqno must be prepared for its
249 * value to change between reads. Only when the request is complete can
250 * the global seqno be stable (due to the memory barriers on submitting
251 * the commands to the hardware to write the breadcrumb, if the HWS shows
252 * that it has passed the global seqno and the global seqno is unchanged
253 * after the read, it is indeed complete).
254 */
255 static u32
257 {
259 }
261 int
269 #define i915_add_request(req) \
270 __i915_add_request(req, false)
279 #define NO_WAITBOOST ERR_PTR(-1)
280 #define IS_RPS_CLIENT(p) (!IS_ERR(p))
281 #define IS_RPS_USER(p) (!IS_ERR_OR_NULL(p))
287 #define I915_WAIT_INTERRUPTIBLE BIT(0)
293 /**
294 * Returns true if seq1 is later than seq2.
295 */
297 {
299 }
303 {
307 }
311 {
312 u32 seqno;
319 }
323 {
327 }
331 {
332 u32 seqno;
339 }
345 {
346 u32 seqno;
354 }
356 /* We treat requests as fences. This is not be to confused with our
357 * "fence registers" but pipeline synchronisation objects ala GL_ARB_sync.
358 * We use the fences to synchronize access from the CPU with activity on the
359 * GPU, for example, we should not rewrite an object's PTE whilst the GPU
360 * is reading them. We also track fences at a higher level to provide
361 * implicit synchronisation around GEM objects, e.g. set-domain will wait
362 * for outstanding GPU rendering before marking the object ready for CPU
363 * access, or a pageflip will wait until the GPU is complete before showing
364 * the frame on the scanout.
365 *
366 * In order to use a fence, the object must track the fence it needs to
367 * serialise with. For example, GEM objects want to track both read and
368 * write access so that we can perform concurrent read operations between
369 * the CPU and GPU engines, as well as waiting for all rendering to
370 * complete, or waiting for the last GPU user of a "fence register". The
371 * object then embeds a #i915_gem_active to track the most recent (in
372 * retirement order) request relevant for the desired mode of access.
373 * The #i915_gem_active is updated with i915_gem_active_set() to track the
374 * most recent fence request, typically this is done as part of
375 * i915_vma_move_to_active().
376 *
377 * When the #i915_gem_active completes (is retired), it will
378 * signal its completion to the owner through a callback as well as mark
379 * itself as idle (i915_gem_active.request == NULL). The owner
380 * can then perform any action, such as delayed freeing of an active
381 * resource including itself.
382 */
391 i915_gem_retire_fn retire;
392 };
397 /**
398 * init_request_active - prepares the activity tracker for use
399 * @active - the active tracker
400 * @func - a callback when then the tracker is retired (becomes idle),
401 * can be NULL
402 *
403 * init_request_active() prepares the embedded @active struct for use as
404 * an activity tracker, that is for tracking the last known active request
405 * associated with it. When the last request becomes idle, when it is retired
406 * after completion, the optional callback @func is invoked.
407 */
410 i915_gem_retire_fn retire)
411 {
414 }
416 /**
417 * i915_gem_active_set - updates the tracker to watch the current request
418 * @active - the active tracker
419 * @request - the request to watch
420 *
421 * i915_gem_active_set() watches the given @request for completion. Whilst
422 * that @request is busy, the @active reports busy. When that @request is
423 * retired, the @active tracker is updated to report idle.
424 */
428 {
431 }
433 /**
434 * i915_gem_active_set_retire_fn - updates the retirement callback
435 * @active - the active tracker
436 * @fn - the routine called when the request is retired
437 * @mutex - struct_mutex used to guard retirements
438 *
439 * i915_gem_active_set_retire_fn() updates the function pointer that
440 * is called when the final request associated with the @active tracker
441 * is retired.
442 */
445 i915_gem_retire_fn fn,
447 {
450 }
454 {
455 /* Inside the error capture (running with the driver in an unknown
456 * state), we want to bend the rules slightly (a lot).
457 *
458 * Work is in progress to make it safer, in the meantime this keeps
459 * the known issue from spamming the logs.
460 */
462 }
464 /**
465 * i915_gem_active_raw - return the active request
466 * @active - the active tracker
467 *
468 * i915_gem_active_raw() returns the current request being tracked, or NULL.
469 * It does not obtain a reference on the request for the caller, so the caller
470 * must hold struct_mutex.
471 */
474 {
477 }
479 /**
480 * i915_gem_active_peek - report the active request being monitored
481 * @active - the active tracker
482 *
483 * i915_gem_active_peek() returns the current request being tracked if
484 * still active, or NULL. It does not obtain a reference on the request
485 * for the caller, so the caller must hold struct_mutex.
486 */
489 {
497 }
499 /**
500 * i915_gem_active_get - return a reference to the active request
501 * @active - the active tracker
502 *
503 * i915_gem_active_get() returns a reference to the active request, or NULL
504 * if the active tracker is idle. The caller must hold struct_mutex.
505 */
508 {
510 }
512 /**
513 * __i915_gem_active_get_rcu - return a reference to the active request
514 * @active - the active tracker
515 *
516 * __i915_gem_active_get() returns a reference to the active request, or NULL
517 * if the active tracker is idle. The caller must hold the RCU read lock, but
518 * the returned pointer is safe to use outside of RCU.
519 */
522 {
523 /* Performing a lockless retrieval of the active request is super
524 * tricky. SLAB_DESTROY_BY_RCU merely guarantees that the backing
525 * slab of request objects will not be freed whilst we hold the
526 * RCU read lock. It does not guarantee that the request itself
527 * will not be freed and then *reused*. Viz,
528 *
529 * Thread A Thread B
530 *
531 * req = active.request
532 * retire(req) -> free(req);
533 * (req is now first on the slab freelist)
534 * active.request = NULL
535 *
536 * req = new submission on a new object
537 * ref(req)
538 *
539 * To prevent the request from being reused whilst the caller
540 * uses it, we take a reference like normal. Whilst acquiring
541 * the reference we check that it is not in a destroyed state
542 * (refcnt == 0). That prevents the request being reallocated
543 * whilst the caller holds on to it. To check that the request
544 * was not reallocated as we acquired the reference we have to
545 * check that our request remains the active request across
546 * the lookup, in the same manner as a seqlock. The visibility
547 * of the pointer versus the reference counting is controlled
548 * by using RCU barriers (rcu_dereference and rcu_assign_pointer).
549 *
550 * In the middle of all that, we inspect whether the request is
551 * complete. Retiring is lazy so the request may be completed long
552 * before the active tracker is updated. Querying whether the
553 * request is complete is far cheaper (as it involves no locked
554 * instructions setting cachelines to exclusive) than acquiring
555 * the reference, so we do it first. The RCU read lock ensures the
556 * pointer dereference is valid, but does not ensure that the
557 * seqno nor HWS is the right one! However, if the request was
558 * reallocated, that means the active tracker's request was complete.
559 * If the new request is also complete, then both are and we can
560 * just report the active tracker is idle. If the new request is
561 * incomplete, then we acquire a reference on it and check that
562 * it remained the active request.
563 *
564 * It is then imperative that we do not zero the request on
565 * reallocation, so that we can chase the dangling pointers!
566 * See i915_gem_request_alloc().
567 */
575 /* An especially silly compiler could decide to recompute the
576 * result of i915_gem_request_completed, more specifically
577 * re-emit the load for request->fence.seqno. A race would catch
578 * a later seqno value, which could flip the result from true to
579 * false. Which means part of the instructions below might not
580 * be executed, while later on instructions are executed. Due to
581 * barriers within the refcounting the inconsistency can't reach
582 * past the call to i915_gem_request_get_rcu, but not executing
583 * that while still executing i915_gem_request_put() creates
584 * havoc enough. Prevent this with a compiler barrier.
585 */
590 /* What stops the following rcu_access_pointer() from occurring
591 * before the above i915_gem_request_get_rcu()? If we were
592 * to read the value before pausing to get the reference to
593 * the request, we may not notice a change in the active
594 * tracker.
595 *
596 * The rcu_access_pointer() is a mere compiler barrier, which
597 * means both the CPU and compiler are free to perform the
598 * memory read without constraint. The compiler only has to
599 * ensure that any operations after the rcu_access_pointer()
600 * occur afterwards in program order. This means the read may
601 * be performed earlier by an out-of-order CPU, or adventurous
602 * compiler.
603 *
604 * The atomic operation at the heart of
605 * i915_gem_request_get_rcu(), see dma_fence_get_rcu(), is
606 * atomic_inc_not_zero() which is only a full memory barrier
607 * when successful. That is, if i915_gem_request_get_rcu()
608 * returns the request (and so with the reference counted
609 * incremented) then the following read for rcu_access_pointer()
610 * must occur after the atomic operation and so confirm
611 * that this request is the one currently being tracked.
612 *
613 * The corresponding write barrier is part of
614 * rcu_assign_pointer().
615 */
621 }
623 /**
624 * i915_gem_active_get_unlocked - return a reference to the active request
625 * @active - the active tracker
626 *
627 * i915_gem_active_get_unlocked() returns a reference to the active request,
628 * or NULL if the active tracker is idle. The reference is obtained under RCU,
629 * so no locking is required by the caller.
630 *
631 * The reference should be freed with i915_gem_request_put().
632 */
635 {
643 }
645 /**
646 * i915_gem_active_isset - report whether the active tracker is assigned
647 * @active - the active tracker
648 *
649 * i915_gem_active_isset() returns true if the active tracker is currently
650 * assigned to a request. Due to the lazy retiring, that request may be idle
651 * and this may report stale information.
652 */
655 {
657 }
659 /**
660 * i915_gem_active_wait - waits until the request is completed
661 * @active - the active request on which to wait
662 * @flags - how to wait
663 * @timeout - how long to wait at most
664 * @rps - userspace client to charge for a waitboost
665 *
666 * i915_gem_active_wait() waits until the request is completed before
667 * returning, without requiring any locks to be held. Note that it does not
668 * retire any requests before returning.
669 *
670 * This function relies on RCU in order to acquire the reference to the active
671 * request without holding any locks. See __i915_gem_active_get_rcu() for the
672 * glory details on how that is managed. Once the reference is acquired, we
673 * can then wait upon the request, and afterwards release our reference,
674 * free of any locking.
675 *
676 * This function wraps i915_wait_request(), see it for the full details on
677 * the arguments.
678 *
679 * Returns 0 if successful, or a negative error code.
680 */
683 {
691 }
694 }
696 /**
697 * i915_gem_active_retire - waits until the request is retired
698 * @active - the active request on which to wait
699 *
700 * i915_gem_active_retire() waits until the request is completed,
701 * and then ensures that at least the retirement handler for this
702 * @active tracker is called before returning. If the @active
703 * tracker is idle, the function returns immediately.
704 */
708 {
718 MAX_SCHEDULE_TIMEOUT);
728 }
730 #define for_each_active(mask, idx) \
731 for (; mask ? idx = ffs(mask) - 1, 1 : 0; mask &= ~BIT(idx))