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 */
24
25 #include <linux/dma-fence-array.h>
26 #include <linux/dma-fence-chain.h>
27 #include <linux/irq_work.h>
28 #include <linux/prefetch.h>
29 #include <linux/sched.h>
30 #include <linux/sched/clock.h>
31 #include <linux/sched/signal.h>
32
33 #include "gem/i915_gem_context.h"
34 #include "gt/intel_breadcrumbs.h"
35 #include "gt/intel_context.h"
36 #include "gt/intel_ring.h"
37 #include "gt/intel_rps.h"
38
39 #include "i915_active.h"
40 #include "i915_drv.h"
41 #include "i915_globals.h"
42 #include "i915_trace.h"
43 #include "intel_pm.h"
44
45 struct execute_cb {
46 struct irq_work work;
47 struct i915_sw_fence *fence;
48 void (*hook)(struct i915_request *rq, struct dma_fence *signal);
49 struct i915_request *signal;
50 };
51
52 static struct i915_global_request {
53 struct i915_global base;
54 struct kmem_cache *slab_requests;
55 struct kmem_cache *slab_execute_cbs;
56 } global;
57
i915_fence_get_driver_name(struct dma_fence * fence)58 static const char *i915_fence_get_driver_name(struct dma_fence *fence)
59 {
60 return dev_name(to_request(fence)->engine->i915->drm.dev);
61 }
62
i915_fence_get_timeline_name(struct dma_fence * fence)63 static const char *i915_fence_get_timeline_name(struct dma_fence *fence)
64 {
65 const struct i915_gem_context *ctx;
66
67 /*
68 * The timeline struct (as part of the ppgtt underneath a context)
69 * may be freed when the request is no longer in use by the GPU.
70 * We could extend the life of a context to beyond that of all
71 * fences, possibly keeping the hw resource around indefinitely,
72 * or we just give them a false name. Since
73 * dma_fence_ops.get_timeline_name is a debug feature, the occasional
74 * lie seems justifiable.
75 */
76 if (test_bit(DMA_FENCE_FLAG_SIGNALED_BIT, &fence->flags))
77 return "signaled";
78
79 ctx = i915_request_gem_context(to_request(fence));
80 if (!ctx)
81 return "[" DRIVER_NAME "]";
82
83 return ctx->name;
84 }
85
i915_fence_signaled(struct dma_fence * fence)86 static bool i915_fence_signaled(struct dma_fence *fence)
87 {
88 return i915_request_completed(to_request(fence));
89 }
90
i915_fence_enable_signaling(struct dma_fence * fence)91 static bool i915_fence_enable_signaling(struct dma_fence *fence)
92 {
93 return i915_request_enable_breadcrumb(to_request(fence));
94 }
95
i915_fence_wait(struct dma_fence * fence,bool interruptible,signed long timeout)96 static signed long i915_fence_wait(struct dma_fence *fence,
97 bool interruptible,
98 signed long timeout)
99 {
100 return i915_request_wait(to_request(fence),
101 interruptible | I915_WAIT_PRIORITY,
102 timeout);
103 }
104
i915_request_slab_cache(void)105 struct kmem_cache *i915_request_slab_cache(void)
106 {
107 return global.slab_requests;
108 }
109
i915_fence_release(struct dma_fence * fence)110 static void i915_fence_release(struct dma_fence *fence)
111 {
112 struct i915_request *rq = to_request(fence);
113
114 /*
115 * The request is put onto a RCU freelist (i.e. the address
116 * is immediately reused), mark the fences as being freed now.
117 * Otherwise the debugobjects for the fences are only marked as
118 * freed when the slab cache itself is freed, and so we would get
119 * caught trying to reuse dead objects.
120 */
121 i915_sw_fence_fini(&rq->submit);
122 i915_sw_fence_fini(&rq->semaphore);
123
124 /*
125 * Keep one request on each engine for reserved use under mempressure
126 *
127 * We do not hold a reference to the engine here and so have to be
128 * very careful in what rq->engine we poke. The virtual engine is
129 * referenced via the rq->context and we released that ref during
130 * i915_request_retire(), ergo we must not dereference a virtual
131 * engine here. Not that we would want to, as the only consumer of
132 * the reserved engine->request_pool is the power management parking,
133 * which must-not-fail, and that is only run on the physical engines.
134 *
135 * Since the request must have been executed to be have completed,
136 * we know that it will have been processed by the HW and will
137 * not be unsubmitted again, so rq->engine and rq->execution_mask
138 * at this point is stable. rq->execution_mask will be a single
139 * bit if the last and _only_ engine it could execution on was a
140 * physical engine, if it's multiple bits then it started on and
141 * could still be on a virtual engine. Thus if the mask is not a
142 * power-of-two we assume that rq->engine may still be a virtual
143 * engine and so a dangling invalid pointer that we cannot dereference
144 *
145 * For example, consider the flow of a bonded request through a virtual
146 * engine. The request is created with a wide engine mask (all engines
147 * that we might execute on). On processing the bond, the request mask
148 * is reduced to one or more engines. If the request is subsequently
149 * bound to a single engine, it will then be constrained to only
150 * execute on that engine and never returned to the virtual engine
151 * after timeslicing away, see __unwind_incomplete_requests(). Thus we
152 * know that if the rq->execution_mask is a single bit, rq->engine
153 * can be a physical engine with the exact corresponding mask.
154 */
155 if (is_power_of_2(rq->execution_mask) &&
156 !cmpxchg(&rq->engine->request_pool, NULL, rq))
157 return;
158
159 kmem_cache_free(global.slab_requests, rq);
160 }
161
162 const struct dma_fence_ops i915_fence_ops = {
163 .get_driver_name = i915_fence_get_driver_name,
164 .get_timeline_name = i915_fence_get_timeline_name,
165 .enable_signaling = i915_fence_enable_signaling,
166 .signaled = i915_fence_signaled,
167 .wait = i915_fence_wait,
168 .release = i915_fence_release,
169 };
170
irq_execute_cb(struct irq_work * wrk)171 static void irq_execute_cb(struct irq_work *wrk)
172 {
173 struct execute_cb *cb = container_of(wrk, typeof(*cb), work);
174
175 i915_sw_fence_complete(cb->fence);
176 kmem_cache_free(global.slab_execute_cbs, cb);
177 }
178
irq_execute_cb_hook(struct irq_work * wrk)179 static void irq_execute_cb_hook(struct irq_work *wrk)
180 {
181 struct execute_cb *cb = container_of(wrk, typeof(*cb), work);
182
183 cb->hook(container_of(cb->fence, struct i915_request, submit),
184 &cb->signal->fence);
185 i915_request_put(cb->signal);
186
187 irq_execute_cb(wrk);
188 }
189
190 static __always_inline void
__notify_execute_cb(struct i915_request * rq,bool (* fn)(struct irq_work * wrk))191 __notify_execute_cb(struct i915_request *rq, bool (*fn)(struct irq_work *wrk))
192 {
193 struct execute_cb *cb, *cn;
194
195 if (llist_empty(&rq->execute_cb))
196 return;
197
198 llist_for_each_entry_safe(cb, cn,
199 llist_del_all(&rq->execute_cb),
200 work.llnode)
201 fn(&cb->work);
202 }
203
__notify_execute_cb_irq(struct i915_request * rq)204 static void __notify_execute_cb_irq(struct i915_request *rq)
205 {
206 __notify_execute_cb(rq, irq_work_queue);
207 }
208
irq_work_imm(struct irq_work * wrk)209 static bool irq_work_imm(struct irq_work *wrk)
210 {
211 wrk->func(wrk);
212 return false;
213 }
214
__notify_execute_cb_imm(struct i915_request * rq)215 static void __notify_execute_cb_imm(struct i915_request *rq)
216 {
217 __notify_execute_cb(rq, irq_work_imm);
218 }
219
free_capture_list(struct i915_request * request)220 static void free_capture_list(struct i915_request *request)
221 {
222 struct i915_capture_list *capture;
223
224 capture = fetch_and_zero(&request->capture_list);
225 while (capture) {
226 struct i915_capture_list *next = capture->next;
227
228 kfree(capture);
229 capture = next;
230 }
231 }
232
__i915_request_fill(struct i915_request * rq,u8 val)233 static void __i915_request_fill(struct i915_request *rq, u8 val)
234 {
235 void *vaddr = rq->ring->vaddr;
236 u32 head;
237
238 head = rq->infix;
239 if (rq->postfix < head) {
240 memset(vaddr + head, val, rq->ring->size - head);
241 head = 0;
242 }
243 memset(vaddr + head, val, rq->postfix - head);
244 }
245
remove_from_engine(struct i915_request * rq)246 static void remove_from_engine(struct i915_request *rq)
247 {
248 struct intel_engine_cs *engine, *locked;
249
250 /*
251 * Virtual engines complicate acquiring the engine timeline lock,
252 * as their rq->engine pointer is not stable until under that
253 * engine lock. The simple ploy we use is to take the lock then
254 * check that the rq still belongs to the newly locked engine.
255 */
256 locked = READ_ONCE(rq->engine);
257 spin_lock_irq(&locked->active.lock);
258 while (unlikely(locked != (engine = READ_ONCE(rq->engine)))) {
259 spin_unlock(&locked->active.lock);
260 spin_lock(&engine->active.lock);
261 locked = engine;
262 }
263 list_del_init(&rq->sched.link);
264
265 clear_bit(I915_FENCE_FLAG_PQUEUE, &rq->fence.flags);
266 clear_bit(I915_FENCE_FLAG_HOLD, &rq->fence.flags);
267
268 /* Prevent further __await_execution() registering a cb, then flush */
269 set_bit(I915_FENCE_FLAG_ACTIVE, &rq->fence.flags);
270
271 spin_unlock_irq(&locked->active.lock);
272
273 __notify_execute_cb_imm(rq);
274 }
275
i915_request_retire(struct i915_request * rq)276 bool i915_request_retire(struct i915_request *rq)
277 {
278 if (!i915_request_completed(rq))
279 return false;
280
281 RQ_TRACE(rq, "\n");
282
283 GEM_BUG_ON(!i915_sw_fence_signaled(&rq->submit));
284 trace_i915_request_retire(rq);
285 i915_request_mark_complete(rq);
286
287 /*
288 * We know the GPU must have read the request to have
289 * sent us the seqno + interrupt, so use the position
290 * of tail of the request to update the last known position
291 * of the GPU head.
292 *
293 * Note this requires that we are always called in request
294 * completion order.
295 */
296 GEM_BUG_ON(!list_is_first(&rq->link,
297 &i915_request_timeline(rq)->requests));
298 if (IS_ENABLED(CONFIG_DRM_I915_DEBUG_GEM))
299 /* Poison before we release our space in the ring */
300 __i915_request_fill(rq, POISON_FREE);
301 rq->ring->head = rq->postfix;
302
303 if (!i915_request_signaled(rq)) {
304 spin_lock_irq(&rq->lock);
305 dma_fence_signal_locked(&rq->fence);
306 spin_unlock_irq(&rq->lock);
307 }
308
309 if (i915_request_has_waitboost(rq)) {
310 GEM_BUG_ON(!atomic_read(&rq->engine->gt->rps.num_waiters));
311 atomic_dec(&rq->engine->gt->rps.num_waiters);
312 }
313
314 /*
315 * We only loosely track inflight requests across preemption,
316 * and so we may find ourselves attempting to retire a _completed_
317 * request that we have removed from the HW and put back on a run
318 * queue.
319 *
320 * As we set I915_FENCE_FLAG_ACTIVE on the request, this should be
321 * after removing the breadcrumb and signaling it, so that we do not
322 * inadvertently attach the breadcrumb to a completed request.
323 */
324 remove_from_engine(rq);
325 GEM_BUG_ON(!llist_empty(&rq->execute_cb));
326
327 __list_del_entry(&rq->link); /* poison neither prev/next (RCU walks) */
328
329 intel_context_exit(rq->context);
330 intel_context_unpin(rq->context);
331
332 free_capture_list(rq);
333 i915_sched_node_fini(&rq->sched);
334 i915_request_put(rq);
335
336 return true;
337 }
338
i915_request_retire_upto(struct i915_request * rq)339 void i915_request_retire_upto(struct i915_request *rq)
340 {
341 struct intel_timeline * const tl = i915_request_timeline(rq);
342 struct i915_request *tmp;
343
344 RQ_TRACE(rq, "\n");
345
346 GEM_BUG_ON(!i915_request_completed(rq));
347
348 do {
349 tmp = list_first_entry(&tl->requests, typeof(*tmp), link);
350 } while (i915_request_retire(tmp) && tmp != rq);
351 }
352
353 static struct i915_request * const *
__engine_active(struct intel_engine_cs * engine)354 __engine_active(struct intel_engine_cs *engine)
355 {
356 return READ_ONCE(engine->execlists.active);
357 }
358
__request_in_flight(const struct i915_request * signal)359 static bool __request_in_flight(const struct i915_request *signal)
360 {
361 struct i915_request * const *port, *rq;
362 bool inflight = false;
363
364 if (!i915_request_is_ready(signal))
365 return false;
366
367 /*
368 * Even if we have unwound the request, it may still be on
369 * the GPU (preempt-to-busy). If that request is inside an
370 * unpreemptible critical section, it will not be removed. Some
371 * GPU functions may even be stuck waiting for the paired request
372 * (__await_execution) to be submitted and cannot be preempted
373 * until the bond is executing.
374 *
375 * As we know that there are always preemption points between
376 * requests, we know that only the currently executing request
377 * may be still active even though we have cleared the flag.
378 * However, we can't rely on our tracking of ELSP[0] to know
379 * which request is currently active and so maybe stuck, as
380 * the tracking maybe an event behind. Instead assume that
381 * if the context is still inflight, then it is still active
382 * even if the active flag has been cleared.
383 *
384 * To further complicate matters, if there a pending promotion, the HW
385 * may either perform a context switch to the second inflight execlists,
386 * or it may switch to the pending set of execlists. In the case of the
387 * latter, it may send the ACK and we process the event copying the
388 * pending[] over top of inflight[], _overwriting_ our *active. Since
389 * this implies the HW is arbitrating and not struck in *active, we do
390 * not worry about complete accuracy, but we do require no read/write
391 * tearing of the pointer [the read of the pointer must be valid, even
392 * as the array is being overwritten, for which we require the writes
393 * to avoid tearing.]
394 *
395 * Note that the read of *execlists->active may race with the promotion
396 * of execlists->pending[] to execlists->inflight[], overwritting
397 * the value at *execlists->active. This is fine. The promotion implies
398 * that we received an ACK from the HW, and so the context is not
399 * stuck -- if we do not see ourselves in *active, the inflight status
400 * is valid. If instead we see ourselves being copied into *active,
401 * we are inflight and may signal the callback.
402 */
403 if (!intel_context_inflight(signal->context))
404 return false;
405
406 rcu_read_lock();
407 for (port = __engine_active(signal->engine);
408 (rq = READ_ONCE(*port)); /* may race with promotion of pending[] */
409 port++) {
410 if (rq->context == signal->context) {
411 inflight = i915_seqno_passed(rq->fence.seqno,
412 signal->fence.seqno);
413 break;
414 }
415 }
416 rcu_read_unlock();
417
418 return inflight;
419 }
420
421 static int
__await_execution(struct i915_request * rq,struct i915_request * signal,void (* hook)(struct i915_request * rq,struct dma_fence * signal),gfp_t gfp)422 __await_execution(struct i915_request *rq,
423 struct i915_request *signal,
424 void (*hook)(struct i915_request *rq,
425 struct dma_fence *signal),
426 gfp_t gfp)
427 {
428 struct execute_cb *cb;
429
430 if (i915_request_is_active(signal)) {
431 if (hook)
432 hook(rq, &signal->fence);
433 return 0;
434 }
435
436 cb = kmem_cache_alloc(global.slab_execute_cbs, gfp);
437 if (!cb)
438 return -ENOMEM;
439
440 cb->fence = &rq->submit;
441 i915_sw_fence_await(cb->fence);
442 init_irq_work(&cb->work, irq_execute_cb);
443
444 if (hook) {
445 cb->hook = hook;
446 cb->signal = i915_request_get(signal);
447 cb->work.func = irq_execute_cb_hook;
448 }
449
450 /*
451 * Register the callback first, then see if the signaler is already
452 * active. This ensures that if we race with the
453 * __notify_execute_cb from i915_request_submit() and we are not
454 * included in that list, we get a second bite of the cherry and
455 * execute it ourselves. After this point, a future
456 * i915_request_submit() will notify us.
457 *
458 * In i915_request_retire() we set the ACTIVE bit on a completed
459 * request (then flush the execute_cb). So by registering the
460 * callback first, then checking the ACTIVE bit, we serialise with
461 * the completed/retired request.
462 */
463 if (llist_add(&cb->work.llnode, &signal->execute_cb)) {
464 if (i915_request_is_active(signal) ||
465 __request_in_flight(signal))
466 __notify_execute_cb_imm(signal);
467 }
468
469 return 0;
470 }
471
fatal_error(int error)472 static bool fatal_error(int error)
473 {
474 switch (error) {
475 case 0: /* not an error! */
476 case -EAGAIN: /* innocent victim of a GT reset (__i915_request_reset) */
477 case -ETIMEDOUT: /* waiting for Godot (timer_i915_sw_fence_wake) */
478 return false;
479 default:
480 return true;
481 }
482 }
483
__i915_request_skip(struct i915_request * rq)484 void __i915_request_skip(struct i915_request *rq)
485 {
486 GEM_BUG_ON(!fatal_error(rq->fence.error));
487
488 if (rq->infix == rq->postfix)
489 return;
490
491 /*
492 * As this request likely depends on state from the lost
493 * context, clear out all the user operations leaving the
494 * breadcrumb at the end (so we get the fence notifications).
495 */
496 __i915_request_fill(rq, 0);
497 rq->infix = rq->postfix;
498 }
499
i915_request_set_error_once(struct i915_request * rq,int error)500 void i915_request_set_error_once(struct i915_request *rq, int error)
501 {
502 int old;
503
504 GEM_BUG_ON(!IS_ERR_VALUE((long)error));
505
506 if (i915_request_signaled(rq))
507 return;
508
509 old = READ_ONCE(rq->fence.error);
510 do {
511 if (fatal_error(old))
512 return;
513 } while (!try_cmpxchg(&rq->fence.error, &old, error));
514 }
515
__i915_request_submit(struct i915_request * request)516 bool __i915_request_submit(struct i915_request *request)
517 {
518 struct intel_engine_cs *engine = request->engine;
519 bool result = false;
520
521 RQ_TRACE(request, "\n");
522
523 GEM_BUG_ON(!irqs_disabled());
524 lockdep_assert_held(&engine->active.lock);
525
526 /*
527 * With the advent of preempt-to-busy, we frequently encounter
528 * requests that we have unsubmitted from HW, but left running
529 * until the next ack and so have completed in the meantime. On
530 * resubmission of that completed request, we can skip
531 * updating the payload, and execlists can even skip submitting
532 * the request.
533 *
534 * We must remove the request from the caller's priority queue,
535 * and the caller must only call us when the request is in their
536 * priority queue, under the active.lock. This ensures that the
537 * request has *not* yet been retired and we can safely move
538 * the request into the engine->active.list where it will be
539 * dropped upon retiring. (Otherwise if resubmit a *retired*
540 * request, this would be a horrible use-after-free.)
541 */
542 if (i915_request_completed(request))
543 goto xfer;
544
545 if (unlikely(intel_context_is_closed(request->context) &&
546 !intel_engine_has_heartbeat(engine)))
547 intel_context_set_banned(request->context);
548
549 if (unlikely(intel_context_is_banned(request->context)))
550 i915_request_set_error_once(request, -EIO);
551
552 if (unlikely(fatal_error(request->fence.error)))
553 __i915_request_skip(request);
554
555 /*
556 * Are we using semaphores when the gpu is already saturated?
557 *
558 * Using semaphores incurs a cost in having the GPU poll a
559 * memory location, busywaiting for it to change. The continual
560 * memory reads can have a noticeable impact on the rest of the
561 * system with the extra bus traffic, stalling the cpu as it too
562 * tries to access memory across the bus (perf stat -e bus-cycles).
563 *
564 * If we installed a semaphore on this request and we only submit
565 * the request after the signaler completed, that indicates the
566 * system is overloaded and using semaphores at this time only
567 * increases the amount of work we are doing. If so, we disable
568 * further use of semaphores until we are idle again, whence we
569 * optimistically try again.
570 */
571 if (request->sched.semaphores &&
572 i915_sw_fence_signaled(&request->semaphore))
573 engine->saturated |= request->sched.semaphores;
574
575 engine->emit_fini_breadcrumb(request,
576 request->ring->vaddr + request->postfix);
577
578 trace_i915_request_execute(request);
579 engine->serial++;
580 result = true;
581
582 xfer:
583 if (!test_and_set_bit(I915_FENCE_FLAG_ACTIVE, &request->fence.flags)) {
584 list_move_tail(&request->sched.link, &engine->active.requests);
585 clear_bit(I915_FENCE_FLAG_PQUEUE, &request->fence.flags);
586 }
587
588 /*
589 * XXX Rollback bonded-execution on __i915_request_unsubmit()?
590 *
591 * In the future, perhaps when we have an active time-slicing scheduler,
592 * it will be interesting to unsubmit parallel execution and remove
593 * busywaits from the GPU until their master is restarted. This is
594 * quite hairy, we have to carefully rollback the fence and do a
595 * preempt-to-idle cycle on the target engine, all the while the
596 * master execute_cb may refire.
597 */
598 __notify_execute_cb_irq(request);
599
600 /* We may be recursing from the signal callback of another i915 fence */
601 if (test_bit(DMA_FENCE_FLAG_ENABLE_SIGNAL_BIT, &request->fence.flags))
602 i915_request_enable_breadcrumb(request);
603
604 return result;
605 }
606
i915_request_submit(struct i915_request * request)607 void i915_request_submit(struct i915_request *request)
608 {
609 struct intel_engine_cs *engine = request->engine;
610 unsigned long flags;
611
612 /* Will be called from irq-context when using foreign fences. */
613 spin_lock_irqsave(&engine->active.lock, flags);
614
615 __i915_request_submit(request);
616
617 spin_unlock_irqrestore(&engine->active.lock, flags);
618 }
619
__i915_request_unsubmit(struct i915_request * request)620 void __i915_request_unsubmit(struct i915_request *request)
621 {
622 struct intel_engine_cs *engine = request->engine;
623
624 /*
625 * Only unwind in reverse order, required so that the per-context list
626 * is kept in seqno/ring order.
627 */
628 RQ_TRACE(request, "\n");
629
630 GEM_BUG_ON(!irqs_disabled());
631 lockdep_assert_held(&engine->active.lock);
632
633 /*
634 * Before we remove this breadcrumb from the signal list, we have
635 * to ensure that a concurrent dma_fence_enable_signaling() does not
636 * attach itself. We first mark the request as no longer active and
637 * make sure that is visible to other cores, and then remove the
638 * breadcrumb if attached.
639 */
640 GEM_BUG_ON(!test_bit(I915_FENCE_FLAG_ACTIVE, &request->fence.flags));
641 clear_bit_unlock(I915_FENCE_FLAG_ACTIVE, &request->fence.flags);
642 if (test_bit(DMA_FENCE_FLAG_ENABLE_SIGNAL_BIT, &request->fence.flags))
643 i915_request_cancel_breadcrumb(request);
644
645 /* We've already spun, don't charge on resubmitting. */
646 if (request->sched.semaphores && i915_request_started(request))
647 request->sched.semaphores = 0;
648
649 /*
650 * We don't need to wake_up any waiters on request->execute, they
651 * will get woken by any other event or us re-adding this request
652 * to the engine timeline (__i915_request_submit()). The waiters
653 * should be quite adapt at finding that the request now has a new
654 * global_seqno to the one they went to sleep on.
655 */
656 }
657
i915_request_unsubmit(struct i915_request * request)658 void i915_request_unsubmit(struct i915_request *request)
659 {
660 struct intel_engine_cs *engine = request->engine;
661 unsigned long flags;
662
663 /* Will be called from irq-context when using foreign fences. */
664 spin_lock_irqsave(&engine->active.lock, flags);
665
666 __i915_request_unsubmit(request);
667
668 spin_unlock_irqrestore(&engine->active.lock, flags);
669 }
670
671 static int __i915_sw_fence_call
submit_notify(struct i915_sw_fence * fence,enum i915_sw_fence_notify state)672 submit_notify(struct i915_sw_fence *fence, enum i915_sw_fence_notify state)
673 {
674 struct i915_request *request =
675 container_of(fence, typeof(*request), submit);
676
677 switch (state) {
678 case FENCE_COMPLETE:
679 trace_i915_request_submit(request);
680
681 if (unlikely(fence->error))
682 i915_request_set_error_once(request, fence->error);
683
684 /*
685 * We need to serialize use of the submit_request() callback
686 * with its hotplugging performed during an emergency
687 * i915_gem_set_wedged(). We use the RCU mechanism to mark the
688 * critical section in order to force i915_gem_set_wedged() to
689 * wait until the submit_request() is completed before
690 * proceeding.
691 */
692 rcu_read_lock();
693 request->engine->submit_request(request);
694 rcu_read_unlock();
695 break;
696
697 case FENCE_FREE:
698 i915_request_put(request);
699 break;
700 }
701
702 return NOTIFY_DONE;
703 }
704
705 static int __i915_sw_fence_call
semaphore_notify(struct i915_sw_fence * fence,enum i915_sw_fence_notify state)706 semaphore_notify(struct i915_sw_fence *fence, enum i915_sw_fence_notify state)
707 {
708 struct i915_request *rq = container_of(fence, typeof(*rq), semaphore);
709
710 switch (state) {
711 case FENCE_COMPLETE:
712 break;
713
714 case FENCE_FREE:
715 i915_request_put(rq);
716 break;
717 }
718
719 return NOTIFY_DONE;
720 }
721
retire_requests(struct intel_timeline * tl)722 static void retire_requests(struct intel_timeline *tl)
723 {
724 struct i915_request *rq, *rn;
725
726 list_for_each_entry_safe(rq, rn, &tl->requests, link)
727 if (!i915_request_retire(rq))
728 break;
729 }
730
731 static noinline struct i915_request *
request_alloc_slow(struct intel_timeline * tl,struct i915_request ** rsvd,gfp_t gfp)732 request_alloc_slow(struct intel_timeline *tl,
733 struct i915_request **rsvd,
734 gfp_t gfp)
735 {
736 struct i915_request *rq;
737
738 /* If we cannot wait, dip into our reserves */
739 if (!gfpflags_allow_blocking(gfp)) {
740 rq = xchg(rsvd, NULL);
741 if (!rq) /* Use the normal failure path for one final WARN */
742 goto out;
743
744 return rq;
745 }
746
747 if (list_empty(&tl->requests))
748 goto out;
749
750 /* Move our oldest request to the slab-cache (if not in use!) */
751 rq = list_first_entry(&tl->requests, typeof(*rq), link);
752 i915_request_retire(rq);
753
754 rq = kmem_cache_alloc(global.slab_requests,
755 gfp | __GFP_RETRY_MAYFAIL | __GFP_NOWARN);
756 if (rq)
757 return rq;
758
759 /* Ratelimit ourselves to prevent oom from malicious clients */
760 rq = list_last_entry(&tl->requests, typeof(*rq), link);
761 cond_synchronize_rcu(rq->rcustate);
762
763 /* Retire our old requests in the hope that we free some */
764 retire_requests(tl);
765
766 out:
767 return kmem_cache_alloc(global.slab_requests, gfp);
768 }
769
__i915_request_ctor(void * arg)770 static void __i915_request_ctor(void *arg)
771 {
772 struct i915_request *rq = arg;
773
774 spin_lock_init(&rq->lock);
775 i915_sched_node_init(&rq->sched);
776 i915_sw_fence_init(&rq->submit, submit_notify);
777 i915_sw_fence_init(&rq->semaphore, semaphore_notify);
778
779 dma_fence_init(&rq->fence, &i915_fence_ops, &rq->lock, 0, 0);
780
781 rq->capture_list = NULL;
782
783 init_llist_head(&rq->execute_cb);
784 }
785
786 struct i915_request *
__i915_request_create(struct intel_context * ce,gfp_t gfp)787 __i915_request_create(struct intel_context *ce, gfp_t gfp)
788 {
789 struct intel_timeline *tl = ce->timeline;
790 struct i915_request *rq;
791 u32 seqno;
792 int ret;
793
794 might_sleep_if(gfpflags_allow_blocking(gfp));
795
796 /* Check that the caller provided an already pinned context */
797 __intel_context_pin(ce);
798
799 /*
800 * Beware: Dragons be flying overhead.
801 *
802 * We use RCU to look up requests in flight. The lookups may
803 * race with the request being allocated from the slab freelist.
804 * That is the request we are writing to here, may be in the process
805 * of being read by __i915_active_request_get_rcu(). As such,
806 * we have to be very careful when overwriting the contents. During
807 * the RCU lookup, we change chase the request->engine pointer,
808 * read the request->global_seqno and increment the reference count.
809 *
810 * The reference count is incremented atomically. If it is zero,
811 * the lookup knows the request is unallocated and complete. Otherwise,
812 * it is either still in use, or has been reallocated and reset
813 * with dma_fence_init(). This increment is safe for release as we
814 * check that the request we have a reference to and matches the active
815 * request.
816 *
817 * Before we increment the refcount, we chase the request->engine
818 * pointer. We must not call kmem_cache_zalloc() or else we set
819 * that pointer to NULL and cause a crash during the lookup. If
820 * we see the request is completed (based on the value of the
821 * old engine and seqno), the lookup is complete and reports NULL.
822 * If we decide the request is not completed (new engine or seqno),
823 * then we grab a reference and double check that it is still the
824 * active request - which it won't be and restart the lookup.
825 *
826 * Do not use kmem_cache_zalloc() here!
827 */
828 rq = kmem_cache_alloc(global.slab_requests,
829 gfp | __GFP_RETRY_MAYFAIL | __GFP_NOWARN);
830 if (unlikely(!rq)) {
831 rq = request_alloc_slow(tl, &ce->engine->request_pool, gfp);
832 if (!rq) {
833 ret = -ENOMEM;
834 goto err_unreserve;
835 }
836 }
837
838 rq->context = ce;
839 rq->engine = ce->engine;
840 rq->ring = ce->ring;
841 rq->execution_mask = ce->engine->mask;
842
843 kref_init(&rq->fence.refcount);
844 rq->fence.flags = 0;
845 rq->fence.error = 0;
846 INIT_LIST_HEAD(&rq->fence.cb_list);
847
848 ret = intel_timeline_get_seqno(tl, rq, &seqno);
849 if (ret)
850 goto err_free;
851
852 rq->fence.context = tl->fence_context;
853 rq->fence.seqno = seqno;
854
855 RCU_INIT_POINTER(rq->timeline, tl);
856 RCU_INIT_POINTER(rq->hwsp_cacheline, tl->hwsp_cacheline);
857 rq->hwsp_seqno = tl->hwsp_seqno;
858 GEM_BUG_ON(i915_request_completed(rq));
859
860 rq->rcustate = get_state_synchronize_rcu(); /* acts as smp_mb() */
861
862 /* We bump the ref for the fence chain */
863 i915_sw_fence_reinit(&i915_request_get(rq)->submit);
864 i915_sw_fence_reinit(&i915_request_get(rq)->semaphore);
865
866 i915_sched_node_reinit(&rq->sched);
867
868 /* No zalloc, everything must be cleared after use */
869 rq->batch = NULL;
870 GEM_BUG_ON(rq->capture_list);
871 GEM_BUG_ON(!llist_empty(&rq->execute_cb));
872
873 /*
874 * Reserve space in the ring buffer for all the commands required to
875 * eventually emit this request. This is to guarantee that the
876 * i915_request_add() call can't fail. Note that the reserve may need
877 * to be redone if the request is not actually submitted straight
878 * away, e.g. because a GPU scheduler has deferred it.
879 *
880 * Note that due to how we add reserved_space to intel_ring_begin()
881 * we need to double our request to ensure that if we need to wrap
882 * around inside i915_request_add() there is sufficient space at
883 * the beginning of the ring as well.
884 */
885 rq->reserved_space =
886 2 * rq->engine->emit_fini_breadcrumb_dw * sizeof(u32);
887
888 /*
889 * Record the position of the start of the request so that
890 * should we detect the updated seqno part-way through the
891 * GPU processing the request, we never over-estimate the
892 * position of the head.
893 */
894 rq->head = rq->ring->emit;
895
896 ret = rq->engine->request_alloc(rq);
897 if (ret)
898 goto err_unwind;
899
900 rq->infix = rq->ring->emit; /* end of header; start of user payload */
901
902 intel_context_mark_active(ce);
903 list_add_tail_rcu(&rq->link, &tl->requests);
904
905 return rq;
906
907 err_unwind:
908 ce->ring->emit = rq->head;
909
910 /* Make sure we didn't add ourselves to external state before freeing */
911 GEM_BUG_ON(!list_empty(&rq->sched.signalers_list));
912 GEM_BUG_ON(!list_empty(&rq->sched.waiters_list));
913
914 err_free:
915 kmem_cache_free(global.slab_requests, rq);
916 err_unreserve:
917 intel_context_unpin(ce);
918 return ERR_PTR(ret);
919 }
920
921 struct i915_request *
i915_request_create(struct intel_context * ce)922 i915_request_create(struct intel_context *ce)
923 {
924 struct i915_request *rq;
925 struct intel_timeline *tl;
926
927 tl = intel_context_timeline_lock(ce);
928 if (IS_ERR(tl))
929 return ERR_CAST(tl);
930
931 /* Move our oldest request to the slab-cache (if not in use!) */
932 rq = list_first_entry(&tl->requests, typeof(*rq), link);
933 if (!list_is_last(&rq->link, &tl->requests))
934 i915_request_retire(rq);
935
936 intel_context_enter(ce);
937 rq = __i915_request_create(ce, GFP_KERNEL);
938 intel_context_exit(ce); /* active reference transferred to request */
939 if (IS_ERR(rq))
940 goto err_unlock;
941
942 /* Check that we do not interrupt ourselves with a new request */
943 rq->cookie = lockdep_pin_lock(&tl->mutex);
944
945 return rq;
946
947 err_unlock:
948 intel_context_timeline_unlock(tl);
949 return rq;
950 }
951
952 static int
i915_request_await_start(struct i915_request * rq,struct i915_request * signal)953 i915_request_await_start(struct i915_request *rq, struct i915_request *signal)
954 {
955 struct dma_fence *fence;
956 int err;
957
958 if (i915_request_timeline(rq) == rcu_access_pointer(signal->timeline))
959 return 0;
960
961 if (i915_request_started(signal))
962 return 0;
963
964 fence = NULL;
965 rcu_read_lock();
966 spin_lock_irq(&signal->lock);
967 do {
968 struct list_head *pos = READ_ONCE(signal->link.prev);
969 struct i915_request *prev;
970
971 /* Confirm signal has not been retired, the link is valid */
972 if (unlikely(i915_request_started(signal)))
973 break;
974
975 /* Is signal the earliest request on its timeline? */
976 if (pos == &rcu_dereference(signal->timeline)->requests)
977 break;
978
979 /*
980 * Peek at the request before us in the timeline. That
981 * request will only be valid before it is retired, so
982 * after acquiring a reference to it, confirm that it is
983 * still part of the signaler's timeline.
984 */
985 prev = list_entry(pos, typeof(*prev), link);
986 if (!i915_request_get_rcu(prev))
987 break;
988
989 /* After the strong barrier, confirm prev is still attached */
990 if (unlikely(READ_ONCE(prev->link.next) != &signal->link)) {
991 i915_request_put(prev);
992 break;
993 }
994
995 fence = &prev->fence;
996 } while (0);
997 spin_unlock_irq(&signal->lock);
998 rcu_read_unlock();
999 if (!fence)
1000 return 0;
1001
1002 err = 0;
1003 if (!intel_timeline_sync_is_later(i915_request_timeline(rq), fence))
1004 err = i915_sw_fence_await_dma_fence(&rq->submit,
1005 fence, 0,
1006 I915_FENCE_GFP);
1007 dma_fence_put(fence);
1008
1009 return err;
1010 }
1011
1012 static intel_engine_mask_t
already_busywaiting(struct i915_request * rq)1013 already_busywaiting(struct i915_request *rq)
1014 {
1015 /*
1016 * Polling a semaphore causes bus traffic, delaying other users of
1017 * both the GPU and CPU. We want to limit the impact on others,
1018 * while taking advantage of early submission to reduce GPU
1019 * latency. Therefore we restrict ourselves to not using more
1020 * than one semaphore from each source, and not using a semaphore
1021 * if we have detected the engine is saturated (i.e. would not be
1022 * submitted early and cause bus traffic reading an already passed
1023 * semaphore).
1024 *
1025 * See the are-we-too-late? check in __i915_request_submit().
1026 */
1027 return rq->sched.semaphores | READ_ONCE(rq->engine->saturated);
1028 }
1029
1030 static int
__emit_semaphore_wait(struct i915_request * to,struct i915_request * from,u32 seqno)1031 __emit_semaphore_wait(struct i915_request *to,
1032 struct i915_request *from,
1033 u32 seqno)
1034 {
1035 const int has_token = INTEL_GEN(to->engine->i915) >= 12;
1036 u32 hwsp_offset;
1037 int len, err;
1038 u32 *cs;
1039
1040 GEM_BUG_ON(INTEL_GEN(to->engine->i915) < 8);
1041 GEM_BUG_ON(i915_request_has_initial_breadcrumb(to));
1042
1043 /* We need to pin the signaler's HWSP until we are finished reading. */
1044 err = intel_timeline_read_hwsp(from, to, &hwsp_offset);
1045 if (err)
1046 return err;
1047
1048 len = 4;
1049 if (has_token)
1050 len += 2;
1051
1052 cs = intel_ring_begin(to, len);
1053 if (IS_ERR(cs))
1054 return PTR_ERR(cs);
1055
1056 /*
1057 * Using greater-than-or-equal here means we have to worry
1058 * about seqno wraparound. To side step that issue, we swap
1059 * the timeline HWSP upon wrapping, so that everyone listening
1060 * for the old (pre-wrap) values do not see the much smaller
1061 * (post-wrap) values than they were expecting (and so wait
1062 * forever).
1063 */
1064 *cs++ = (MI_SEMAPHORE_WAIT |
1065 MI_SEMAPHORE_GLOBAL_GTT |
1066 MI_SEMAPHORE_POLL |
1067 MI_SEMAPHORE_SAD_GTE_SDD) +
1068 has_token;
1069 *cs++ = seqno;
1070 *cs++ = hwsp_offset;
1071 *cs++ = 0;
1072 if (has_token) {
1073 *cs++ = 0;
1074 *cs++ = MI_NOOP;
1075 }
1076
1077 intel_ring_advance(to, cs);
1078 return 0;
1079 }
1080
1081 static int
emit_semaphore_wait(struct i915_request * to,struct i915_request * from,gfp_t gfp)1082 emit_semaphore_wait(struct i915_request *to,
1083 struct i915_request *from,
1084 gfp_t gfp)
1085 {
1086 const intel_engine_mask_t mask = READ_ONCE(from->engine)->mask;
1087 struct i915_sw_fence *wait = &to->submit;
1088
1089 if (!intel_context_use_semaphores(to->context))
1090 goto await_fence;
1091
1092 if (i915_request_has_initial_breadcrumb(to))
1093 goto await_fence;
1094
1095 if (!rcu_access_pointer(from->hwsp_cacheline))
1096 goto await_fence;
1097
1098 /*
1099 * If this or its dependents are waiting on an external fence
1100 * that may fail catastrophically, then we want to avoid using
1101 * sempahores as they bypass the fence signaling metadata, and we
1102 * lose the fence->error propagation.
1103 */
1104 if (from->sched.flags & I915_SCHED_HAS_EXTERNAL_CHAIN)
1105 goto await_fence;
1106
1107 /* Just emit the first semaphore we see as request space is limited. */
1108 if (already_busywaiting(to) & mask)
1109 goto await_fence;
1110
1111 if (i915_request_await_start(to, from) < 0)
1112 goto await_fence;
1113
1114 /* Only submit our spinner after the signaler is running! */
1115 if (__await_execution(to, from, NULL, gfp))
1116 goto await_fence;
1117
1118 if (__emit_semaphore_wait(to, from, from->fence.seqno))
1119 goto await_fence;
1120
1121 to->sched.semaphores |= mask;
1122 wait = &to->semaphore;
1123
1124 await_fence:
1125 return i915_sw_fence_await_dma_fence(wait,
1126 &from->fence, 0,
1127 I915_FENCE_GFP);
1128 }
1129
intel_timeline_sync_has_start(struct intel_timeline * tl,struct dma_fence * fence)1130 static bool intel_timeline_sync_has_start(struct intel_timeline *tl,
1131 struct dma_fence *fence)
1132 {
1133 return __intel_timeline_sync_is_later(tl,
1134 fence->context,
1135 fence->seqno - 1);
1136 }
1137
intel_timeline_sync_set_start(struct intel_timeline * tl,const struct dma_fence * fence)1138 static int intel_timeline_sync_set_start(struct intel_timeline *tl,
1139 const struct dma_fence *fence)
1140 {
1141 return __intel_timeline_sync_set(tl, fence->context, fence->seqno - 1);
1142 }
1143
1144 static int
__i915_request_await_execution(struct i915_request * to,struct i915_request * from,void (* hook)(struct i915_request * rq,struct dma_fence * signal))1145 __i915_request_await_execution(struct i915_request *to,
1146 struct i915_request *from,
1147 void (*hook)(struct i915_request *rq,
1148 struct dma_fence *signal))
1149 {
1150 int err;
1151
1152 GEM_BUG_ON(intel_context_is_barrier(from->context));
1153
1154 /* Submit both requests at the same time */
1155 err = __await_execution(to, from, hook, I915_FENCE_GFP);
1156 if (err)
1157 return err;
1158
1159 /* Squash repeated depenendices to the same timelines */
1160 if (intel_timeline_sync_has_start(i915_request_timeline(to),
1161 &from->fence))
1162 return 0;
1163
1164 /*
1165 * Wait until the start of this request.
1166 *
1167 * The execution cb fires when we submit the request to HW. But in
1168 * many cases this may be long before the request itself is ready to
1169 * run (consider that we submit 2 requests for the same context, where
1170 * the request of interest is behind an indefinite spinner). So we hook
1171 * up to both to reduce our queues and keep the execution lag minimised
1172 * in the worst case, though we hope that the await_start is elided.
1173 */
1174 err = i915_request_await_start(to, from);
1175 if (err < 0)
1176 return err;
1177
1178 /*
1179 * Ensure both start together [after all semaphores in signal]
1180 *
1181 * Now that we are queued to the HW at roughly the same time (thanks
1182 * to the execute cb) and are ready to run at roughly the same time
1183 * (thanks to the await start), our signaler may still be indefinitely
1184 * delayed by waiting on a semaphore from a remote engine. If our
1185 * signaler depends on a semaphore, so indirectly do we, and we do not
1186 * want to start our payload until our signaler also starts theirs.
1187 * So we wait.
1188 *
1189 * However, there is also a second condition for which we need to wait
1190 * for the precise start of the signaler. Consider that the signaler
1191 * was submitted in a chain of requests following another context
1192 * (with just an ordinary intra-engine fence dependency between the
1193 * two). In this case the signaler is queued to HW, but not for
1194 * immediate execution, and so we must wait until it reaches the
1195 * active slot.
1196 */
1197 if (intel_engine_has_semaphores(to->engine) &&
1198 !i915_request_has_initial_breadcrumb(to)) {
1199 err = __emit_semaphore_wait(to, from, from->fence.seqno - 1);
1200 if (err < 0)
1201 return err;
1202 }
1203
1204 /* Couple the dependency tree for PI on this exposed to->fence */
1205 if (to->engine->schedule) {
1206 err = i915_sched_node_add_dependency(&to->sched,
1207 &from->sched,
1208 I915_DEPENDENCY_WEAK);
1209 if (err < 0)
1210 return err;
1211 }
1212
1213 return intel_timeline_sync_set_start(i915_request_timeline(to),
1214 &from->fence);
1215 }
1216
mark_external(struct i915_request * rq)1217 static void mark_external(struct i915_request *rq)
1218 {
1219 /*
1220 * The downside of using semaphores is that we lose metadata passing
1221 * along the signaling chain. This is particularly nasty when we
1222 * need to pass along a fatal error such as EFAULT or EDEADLK. For
1223 * fatal errors we want to scrub the request before it is executed,
1224 * which means that we cannot preload the request onto HW and have
1225 * it wait upon a semaphore.
1226 */
1227 rq->sched.flags |= I915_SCHED_HAS_EXTERNAL_CHAIN;
1228 }
1229
1230 static int
__i915_request_await_external(struct i915_request * rq,struct dma_fence * fence)1231 __i915_request_await_external(struct i915_request *rq, struct dma_fence *fence)
1232 {
1233 mark_external(rq);
1234 return i915_sw_fence_await_dma_fence(&rq->submit, fence,
1235 i915_fence_context_timeout(rq->engine->i915,
1236 fence->context),
1237 I915_FENCE_GFP);
1238 }
1239
1240 static int
i915_request_await_external(struct i915_request * rq,struct dma_fence * fence)1241 i915_request_await_external(struct i915_request *rq, struct dma_fence *fence)
1242 {
1243 struct dma_fence *iter;
1244 int err = 0;
1245
1246 if (!to_dma_fence_chain(fence))
1247 return __i915_request_await_external(rq, fence);
1248
1249 dma_fence_chain_for_each(iter, fence) {
1250 struct dma_fence_chain *chain = to_dma_fence_chain(iter);
1251
1252 if (!dma_fence_is_i915(chain->fence)) {
1253 err = __i915_request_await_external(rq, iter);
1254 break;
1255 }
1256
1257 err = i915_request_await_dma_fence(rq, chain->fence);
1258 if (err < 0)
1259 break;
1260 }
1261
1262 dma_fence_put(iter);
1263 return err;
1264 }
1265
1266 int
i915_request_await_execution(struct i915_request * rq,struct dma_fence * fence,void (* hook)(struct i915_request * rq,struct dma_fence * signal))1267 i915_request_await_execution(struct i915_request *rq,
1268 struct dma_fence *fence,
1269 void (*hook)(struct i915_request *rq,
1270 struct dma_fence *signal))
1271 {
1272 struct dma_fence **child = &fence;
1273 unsigned int nchild = 1;
1274 int ret;
1275
1276 if (dma_fence_is_array(fence)) {
1277 struct dma_fence_array *array = to_dma_fence_array(fence);
1278
1279 /* XXX Error for signal-on-any fence arrays */
1280
1281 child = array->fences;
1282 nchild = array->num_fences;
1283 GEM_BUG_ON(!nchild);
1284 }
1285
1286 do {
1287 fence = *child++;
1288 if (test_bit(DMA_FENCE_FLAG_SIGNALED_BIT, &fence->flags)) {
1289 i915_sw_fence_set_error_once(&rq->submit, fence->error);
1290 continue;
1291 }
1292
1293 if (fence->context == rq->fence.context)
1294 continue;
1295
1296 /*
1297 * We don't squash repeated fence dependencies here as we
1298 * want to run our callback in all cases.
1299 */
1300
1301 if (dma_fence_is_i915(fence))
1302 ret = __i915_request_await_execution(rq,
1303 to_request(fence),
1304 hook);
1305 else
1306 ret = i915_request_await_external(rq, fence);
1307 if (ret < 0)
1308 return ret;
1309 } while (--nchild);
1310
1311 return 0;
1312 }
1313
1314 static int
await_request_submit(struct i915_request * to,struct i915_request * from)1315 await_request_submit(struct i915_request *to, struct i915_request *from)
1316 {
1317 /*
1318 * If we are waiting on a virtual engine, then it may be
1319 * constrained to execute on a single engine *prior* to submission.
1320 * When it is submitted, it will be first submitted to the virtual
1321 * engine and then passed to the physical engine. We cannot allow
1322 * the waiter to be submitted immediately to the physical engine
1323 * as it may then bypass the virtual request.
1324 */
1325 if (to->engine == READ_ONCE(from->engine))
1326 return i915_sw_fence_await_sw_fence_gfp(&to->submit,
1327 &from->submit,
1328 I915_FENCE_GFP);
1329 else
1330 return __i915_request_await_execution(to, from, NULL);
1331 }
1332
1333 static int
i915_request_await_request(struct i915_request * to,struct i915_request * from)1334 i915_request_await_request(struct i915_request *to, struct i915_request *from)
1335 {
1336 int ret;
1337
1338 GEM_BUG_ON(to == from);
1339 GEM_BUG_ON(to->timeline == from->timeline);
1340
1341 if (i915_request_completed(from)) {
1342 i915_sw_fence_set_error_once(&to->submit, from->fence.error);
1343 return 0;
1344 }
1345
1346 if (to->engine->schedule) {
1347 ret = i915_sched_node_add_dependency(&to->sched,
1348 &from->sched,
1349 I915_DEPENDENCY_EXTERNAL);
1350 if (ret < 0)
1351 return ret;
1352 }
1353
1354 if (is_power_of_2(to->execution_mask | READ_ONCE(from->execution_mask)))
1355 ret = await_request_submit(to, from);
1356 else
1357 ret = emit_semaphore_wait(to, from, I915_FENCE_GFP);
1358 if (ret < 0)
1359 return ret;
1360
1361 return 0;
1362 }
1363
1364 int
i915_request_await_dma_fence(struct i915_request * rq,struct dma_fence * fence)1365 i915_request_await_dma_fence(struct i915_request *rq, struct dma_fence *fence)
1366 {
1367 struct dma_fence **child = &fence;
1368 unsigned int nchild = 1;
1369 int ret;
1370
1371 /*
1372 * Note that if the fence-array was created in signal-on-any mode,
1373 * we should *not* decompose it into its individual fences. However,
1374 * we don't currently store which mode the fence-array is operating
1375 * in. Fortunately, the only user of signal-on-any is private to
1376 * amdgpu and we should not see any incoming fence-array from
1377 * sync-file being in signal-on-any mode.
1378 */
1379 if (dma_fence_is_array(fence)) {
1380 struct dma_fence_array *array = to_dma_fence_array(fence);
1381
1382 child = array->fences;
1383 nchild = array->num_fences;
1384 GEM_BUG_ON(!nchild);
1385 }
1386
1387 do {
1388 fence = *child++;
1389 if (test_bit(DMA_FENCE_FLAG_SIGNALED_BIT, &fence->flags)) {
1390 i915_sw_fence_set_error_once(&rq->submit, fence->error);
1391 continue;
1392 }
1393
1394 /*
1395 * Requests on the same timeline are explicitly ordered, along
1396 * with their dependencies, by i915_request_add() which ensures
1397 * that requests are submitted in-order through each ring.
1398 */
1399 if (fence->context == rq->fence.context)
1400 continue;
1401
1402 /* Squash repeated waits to the same timelines */
1403 if (fence->context &&
1404 intel_timeline_sync_is_later(i915_request_timeline(rq),
1405 fence))
1406 continue;
1407
1408 if (dma_fence_is_i915(fence))
1409 ret = i915_request_await_request(rq, to_request(fence));
1410 else
1411 ret = i915_request_await_external(rq, fence);
1412 if (ret < 0)
1413 return ret;
1414
1415 /* Record the latest fence used against each timeline */
1416 if (fence->context)
1417 intel_timeline_sync_set(i915_request_timeline(rq),
1418 fence);
1419 } while (--nchild);
1420
1421 return 0;
1422 }
1423
1424 /**
1425 * i915_request_await_object - set this request to (async) wait upon a bo
1426 * @to: request we are wishing to use
1427 * @obj: object which may be in use on another ring.
1428 * @write: whether the wait is on behalf of a writer
1429 *
1430 * This code is meant to abstract object synchronization with the GPU.
1431 * Conceptually we serialise writes between engines inside the GPU.
1432 * We only allow one engine to write into a buffer at any time, but
1433 * multiple readers. To ensure each has a coherent view of memory, we must:
1434 *
1435 * - If there is an outstanding write request to the object, the new
1436 * request must wait for it to complete (either CPU or in hw, requests
1437 * on the same ring will be naturally ordered).
1438 *
1439 * - If we are a write request (pending_write_domain is set), the new
1440 * request must wait for outstanding read requests to complete.
1441 *
1442 * Returns 0 if successful, else propagates up the lower layer error.
1443 */
1444 int
i915_request_await_object(struct i915_request * to,struct drm_i915_gem_object * obj,bool write)1445 i915_request_await_object(struct i915_request *to,
1446 struct drm_i915_gem_object *obj,
1447 bool write)
1448 {
1449 struct dma_fence *excl;
1450 int ret = 0;
1451
1452 if (write) {
1453 struct dma_fence **shared;
1454 unsigned int count, i;
1455
1456 ret = dma_resv_get_fences_rcu(obj->base.resv,
1457 &excl, &count, &shared);
1458 if (ret)
1459 return ret;
1460
1461 for (i = 0; i < count; i++) {
1462 ret = i915_request_await_dma_fence(to, shared[i]);
1463 if (ret)
1464 break;
1465
1466 dma_fence_put(shared[i]);
1467 }
1468
1469 for (; i < count; i++)
1470 dma_fence_put(shared[i]);
1471 kfree(shared);
1472 } else {
1473 excl = dma_resv_get_excl_rcu(obj->base.resv);
1474 }
1475
1476 if (excl) {
1477 if (ret == 0)
1478 ret = i915_request_await_dma_fence(to, excl);
1479
1480 dma_fence_put(excl);
1481 }
1482
1483 return ret;
1484 }
1485
1486 static struct i915_request *
__i915_request_add_to_timeline(struct i915_request * rq)1487 __i915_request_add_to_timeline(struct i915_request *rq)
1488 {
1489 struct intel_timeline *timeline = i915_request_timeline(rq);
1490 struct i915_request *prev;
1491
1492 /*
1493 * Dependency tracking and request ordering along the timeline
1494 * is special cased so that we can eliminate redundant ordering
1495 * operations while building the request (we know that the timeline
1496 * itself is ordered, and here we guarantee it).
1497 *
1498 * As we know we will need to emit tracking along the timeline,
1499 * we embed the hooks into our request struct -- at the cost of
1500 * having to have specialised no-allocation interfaces (which will
1501 * be beneficial elsewhere).
1502 *
1503 * A second benefit to open-coding i915_request_await_request is
1504 * that we can apply a slight variant of the rules specialised
1505 * for timelines that jump between engines (such as virtual engines).
1506 * If we consider the case of virtual engine, we must emit a dma-fence
1507 * to prevent scheduling of the second request until the first is
1508 * complete (to maximise our greedy late load balancing) and this
1509 * precludes optimising to use semaphores serialisation of a single
1510 * timeline across engines.
1511 */
1512 prev = to_request(__i915_active_fence_set(&timeline->last_request,
1513 &rq->fence));
1514 if (prev && !i915_request_completed(prev)) {
1515 /*
1516 * The requests are supposed to be kept in order. However,
1517 * we need to be wary in case the timeline->last_request
1518 * is used as a barrier for external modification to this
1519 * context.
1520 */
1521 GEM_BUG_ON(prev->context == rq->context &&
1522 i915_seqno_passed(prev->fence.seqno,
1523 rq->fence.seqno));
1524
1525 if (is_power_of_2(READ_ONCE(prev->engine)->mask | rq->engine->mask))
1526 i915_sw_fence_await_sw_fence(&rq->submit,
1527 &prev->submit,
1528 &rq->submitq);
1529 else
1530 __i915_sw_fence_await_dma_fence(&rq->submit,
1531 &prev->fence,
1532 &rq->dmaq);
1533 if (rq->engine->schedule)
1534 __i915_sched_node_add_dependency(&rq->sched,
1535 &prev->sched,
1536 &rq->dep,
1537 0);
1538 }
1539
1540 /*
1541 * Make sure that no request gazumped us - if it was allocated after
1542 * our i915_request_alloc() and called __i915_request_add() before
1543 * us, the timeline will hold its seqno which is later than ours.
1544 */
1545 GEM_BUG_ON(timeline->seqno != rq->fence.seqno);
1546
1547 return prev;
1548 }
1549
1550 /*
1551 * NB: This function is not allowed to fail. Doing so would mean the the
1552 * request is not being tracked for completion but the work itself is
1553 * going to happen on the hardware. This would be a Bad Thing(tm).
1554 */
__i915_request_commit(struct i915_request * rq)1555 struct i915_request *__i915_request_commit(struct i915_request *rq)
1556 {
1557 struct intel_engine_cs *engine = rq->engine;
1558 struct intel_ring *ring = rq->ring;
1559 u32 *cs;
1560
1561 RQ_TRACE(rq, "\n");
1562
1563 /*
1564 * To ensure that this call will not fail, space for its emissions
1565 * should already have been reserved in the ring buffer. Let the ring
1566 * know that it is time to use that space up.
1567 */
1568 GEM_BUG_ON(rq->reserved_space > ring->space);
1569 rq->reserved_space = 0;
1570 rq->emitted_jiffies = jiffies;
1571
1572 /*
1573 * Record the position of the start of the breadcrumb so that
1574 * should we detect the updated seqno part-way through the
1575 * GPU processing the request, we never over-estimate the
1576 * position of the ring's HEAD.
1577 */
1578 cs = intel_ring_begin(rq, engine->emit_fini_breadcrumb_dw);
1579 GEM_BUG_ON(IS_ERR(cs));
1580 rq->postfix = intel_ring_offset(rq, cs);
1581
1582 return __i915_request_add_to_timeline(rq);
1583 }
1584
__i915_request_queue(struct i915_request * rq,const struct i915_sched_attr * attr)1585 void __i915_request_queue(struct i915_request *rq,
1586 const struct i915_sched_attr *attr)
1587 {
1588 /*
1589 * Let the backend know a new request has arrived that may need
1590 * to adjust the existing execution schedule due to a high priority
1591 * request - i.e. we may want to preempt the current request in order
1592 * to run a high priority dependency chain *before* we can execute this
1593 * request.
1594 *
1595 * This is called before the request is ready to run so that we can
1596 * decide whether to preempt the entire chain so that it is ready to
1597 * run at the earliest possible convenience.
1598 */
1599 if (attr && rq->engine->schedule)
1600 rq->engine->schedule(rq, attr);
1601 i915_sw_fence_commit(&rq->semaphore);
1602 i915_sw_fence_commit(&rq->submit);
1603 }
1604
i915_request_add(struct i915_request * rq)1605 void i915_request_add(struct i915_request *rq)
1606 {
1607 struct intel_timeline * const tl = i915_request_timeline(rq);
1608 struct i915_sched_attr attr = {};
1609 struct i915_gem_context *ctx;
1610
1611 lockdep_assert_held(&tl->mutex);
1612 lockdep_unpin_lock(&tl->mutex, rq->cookie);
1613
1614 trace_i915_request_add(rq);
1615 __i915_request_commit(rq);
1616
1617 /* XXX placeholder for selftests */
1618 rcu_read_lock();
1619 ctx = rcu_dereference(rq->context->gem_context);
1620 if (ctx)
1621 attr = ctx->sched;
1622 rcu_read_unlock();
1623
1624 __i915_request_queue(rq, &attr);
1625
1626 mutex_unlock(&tl->mutex);
1627 }
1628
local_clock_ns(unsigned int * cpu)1629 static unsigned long local_clock_ns(unsigned int *cpu)
1630 {
1631 unsigned long t;
1632
1633 /*
1634 * Cheaply and approximately convert from nanoseconds to microseconds.
1635 * The result and subsequent calculations are also defined in the same
1636 * approximate microseconds units. The principal source of timing
1637 * error here is from the simple truncation.
1638 *
1639 * Note that local_clock() is only defined wrt to the current CPU;
1640 * the comparisons are no longer valid if we switch CPUs. Instead of
1641 * blocking preemption for the entire busywait, we can detect the CPU
1642 * switch and use that as indicator of system load and a reason to
1643 * stop busywaiting, see busywait_stop().
1644 */
1645 *cpu = get_cpu();
1646 t = local_clock();
1647 put_cpu();
1648
1649 return t;
1650 }
1651
busywait_stop(unsigned long timeout,unsigned int cpu)1652 static bool busywait_stop(unsigned long timeout, unsigned int cpu)
1653 {
1654 unsigned int this_cpu;
1655
1656 if (time_after(local_clock_ns(&this_cpu), timeout))
1657 return true;
1658
1659 return this_cpu != cpu;
1660 }
1661
__i915_spin_request(struct i915_request * const rq,int state)1662 static bool __i915_spin_request(struct i915_request * const rq, int state)
1663 {
1664 unsigned long timeout_ns;
1665 unsigned int cpu;
1666
1667 /*
1668 * Only wait for the request if we know it is likely to complete.
1669 *
1670 * We don't track the timestamps around requests, nor the average
1671 * request length, so we do not have a good indicator that this
1672 * request will complete within the timeout. What we do know is the
1673 * order in which requests are executed by the context and so we can
1674 * tell if the request has been started. If the request is not even
1675 * running yet, it is a fair assumption that it will not complete
1676 * within our relatively short timeout.
1677 */
1678 if (!i915_request_is_running(rq))
1679 return false;
1680
1681 /*
1682 * When waiting for high frequency requests, e.g. during synchronous
1683 * rendering split between the CPU and GPU, the finite amount of time
1684 * required to set up the irq and wait upon it limits the response
1685 * rate. By busywaiting on the request completion for a short while we
1686 * can service the high frequency waits as quick as possible. However,
1687 * if it is a slow request, we want to sleep as quickly as possible.
1688 * The tradeoff between waiting and sleeping is roughly the time it
1689 * takes to sleep on a request, on the order of a microsecond.
1690 */
1691
1692 timeout_ns = READ_ONCE(rq->engine->props.max_busywait_duration_ns);
1693 timeout_ns += local_clock_ns(&cpu);
1694 do {
1695 if (dma_fence_is_signaled(&rq->fence))
1696 return true;
1697
1698 if (signal_pending_state(state, current))
1699 break;
1700
1701 if (busywait_stop(timeout_ns, cpu))
1702 break;
1703
1704 cpu_relax();
1705 } while (!need_resched());
1706
1707 return false;
1708 }
1709
1710 struct request_wait {
1711 struct dma_fence_cb cb;
1712 struct task_struct *tsk;
1713 };
1714
request_wait_wake(struct dma_fence * fence,struct dma_fence_cb * cb)1715 static void request_wait_wake(struct dma_fence *fence, struct dma_fence_cb *cb)
1716 {
1717 struct request_wait *wait = container_of(cb, typeof(*wait), cb);
1718
1719 wake_up_process(fetch_and_zero(&wait->tsk));
1720 }
1721
1722 /**
1723 * i915_request_wait - wait until execution of request has finished
1724 * @rq: the request to wait upon
1725 * @flags: how to wait
1726 * @timeout: how long to wait in jiffies
1727 *
1728 * i915_request_wait() waits for the request to be completed, for a
1729 * maximum of @timeout jiffies (with MAX_SCHEDULE_TIMEOUT implying an
1730 * unbounded wait).
1731 *
1732 * Returns the remaining time (in jiffies) if the request completed, which may
1733 * be zero or -ETIME if the request is unfinished after the timeout expires.
1734 * May return -EINTR is called with I915_WAIT_INTERRUPTIBLE and a signal is
1735 * pending before the request completes.
1736 */
i915_request_wait(struct i915_request * rq,unsigned int flags,long timeout)1737 long i915_request_wait(struct i915_request *rq,
1738 unsigned int flags,
1739 long timeout)
1740 {
1741 const int state = flags & I915_WAIT_INTERRUPTIBLE ?
1742 TASK_INTERRUPTIBLE : TASK_UNINTERRUPTIBLE;
1743 struct request_wait wait;
1744
1745 might_sleep();
1746 GEM_BUG_ON(timeout < 0);
1747
1748 if (dma_fence_is_signaled(&rq->fence))
1749 return timeout;
1750
1751 if (!timeout)
1752 return -ETIME;
1753
1754 trace_i915_request_wait_begin(rq, flags);
1755
1756 /*
1757 * We must never wait on the GPU while holding a lock as we
1758 * may need to perform a GPU reset. So while we don't need to
1759 * serialise wait/reset with an explicit lock, we do want
1760 * lockdep to detect potential dependency cycles.
1761 */
1762 mutex_acquire(&rq->engine->gt->reset.mutex.dep_map, 0, 0, _THIS_IP_);
1763
1764 /*
1765 * Optimistic spin before touching IRQs.
1766 *
1767 * We may use a rather large value here to offset the penalty of
1768 * switching away from the active task. Frequently, the client will
1769 * wait upon an old swapbuffer to throttle itself to remain within a
1770 * frame of the gpu. If the client is running in lockstep with the gpu,
1771 * then it should not be waiting long at all, and a sleep now will incur
1772 * extra scheduler latency in producing the next frame. To try to
1773 * avoid adding the cost of enabling/disabling the interrupt to the
1774 * short wait, we first spin to see if the request would have completed
1775 * in the time taken to setup the interrupt.
1776 *
1777 * We need upto 5us to enable the irq, and upto 20us to hide the
1778 * scheduler latency of a context switch, ignoring the secondary
1779 * impacts from a context switch such as cache eviction.
1780 *
1781 * The scheme used for low-latency IO is called "hybrid interrupt
1782 * polling". The suggestion there is to sleep until just before you
1783 * expect to be woken by the device interrupt and then poll for its
1784 * completion. That requires having a good predictor for the request
1785 * duration, which we currently lack.
1786 */
1787 if (IS_ACTIVE(CONFIG_DRM_I915_MAX_REQUEST_BUSYWAIT) &&
1788 __i915_spin_request(rq, state))
1789 goto out;
1790
1791 /*
1792 * This client is about to stall waiting for the GPU. In many cases
1793 * this is undesirable and limits the throughput of the system, as
1794 * many clients cannot continue processing user input/output whilst
1795 * blocked. RPS autotuning may take tens of milliseconds to respond
1796 * to the GPU load and thus incurs additional latency for the client.
1797 * We can circumvent that by promoting the GPU frequency to maximum
1798 * before we sleep. This makes the GPU throttle up much more quickly
1799 * (good for benchmarks and user experience, e.g. window animations),
1800 * but at a cost of spending more power processing the workload
1801 * (bad for battery).
1802 */
1803 if (flags & I915_WAIT_PRIORITY && !i915_request_started(rq))
1804 intel_rps_boost(rq);
1805
1806 wait.tsk = current;
1807 if (dma_fence_add_callback(&rq->fence, &wait.cb, request_wait_wake))
1808 goto out;
1809
1810 /*
1811 * Flush the submission tasklet, but only if it may help this request.
1812 *
1813 * We sometimes experience some latency between the HW interrupts and
1814 * tasklet execution (mostly due to ksoftirqd latency, but it can also
1815 * be due to lazy CS events), so lets run the tasklet manually if there
1816 * is a chance it may submit this request. If the request is not ready
1817 * to run, as it is waiting for other fences to be signaled, flushing
1818 * the tasklet is busy work without any advantage for this client.
1819 *
1820 * If the HW is being lazy, this is the last chance before we go to
1821 * sleep to catch any pending events. We will check periodically in
1822 * the heartbeat to flush the submission tasklets as a last resort
1823 * for unhappy HW.
1824 */
1825 if (i915_request_is_ready(rq))
1826 intel_engine_flush_submission(rq->engine);
1827
1828 for (;;) {
1829 set_current_state(state);
1830
1831 if (dma_fence_is_signaled(&rq->fence))
1832 break;
1833
1834 if (signal_pending_state(state, current)) {
1835 timeout = -ERESTARTSYS;
1836 break;
1837 }
1838
1839 if (!timeout) {
1840 timeout = -ETIME;
1841 break;
1842 }
1843
1844 timeout = io_schedule_timeout(timeout);
1845 }
1846 __set_current_state(TASK_RUNNING);
1847
1848 if (READ_ONCE(wait.tsk))
1849 dma_fence_remove_callback(&rq->fence, &wait.cb);
1850 GEM_BUG_ON(!list_empty(&wait.cb.node));
1851
1852 out:
1853 mutex_release(&rq->engine->gt->reset.mutex.dep_map, _THIS_IP_);
1854 trace_i915_request_wait_end(rq);
1855 return timeout;
1856 }
1857
1858 #if IS_ENABLED(CONFIG_DRM_I915_SELFTEST)
1859 #include "selftests/mock_request.c"
1860 #include "selftests/i915_request.c"
1861 #endif
1862
i915_global_request_shrink(void)1863 static void i915_global_request_shrink(void)
1864 {
1865 kmem_cache_shrink(global.slab_execute_cbs);
1866 kmem_cache_shrink(global.slab_requests);
1867 }
1868
i915_global_request_exit(void)1869 static void i915_global_request_exit(void)
1870 {
1871 kmem_cache_destroy(global.slab_execute_cbs);
1872 kmem_cache_destroy(global.slab_requests);
1873 }
1874
1875 static struct i915_global_request global = { {
1876 .shrink = i915_global_request_shrink,
1877 .exit = i915_global_request_exit,
1878 } };
1879
i915_global_request_init(void)1880 int __init i915_global_request_init(void)
1881 {
1882 global.slab_requests =
1883 kmem_cache_create("i915_request",
1884 sizeof(struct i915_request),
1885 __alignof__(struct i915_request),
1886 SLAB_HWCACHE_ALIGN |
1887 SLAB_RECLAIM_ACCOUNT |
1888 SLAB_TYPESAFE_BY_RCU,
1889 __i915_request_ctor);
1890 if (!global.slab_requests)
1891 return -ENOMEM;
1892
1893 global.slab_execute_cbs = KMEM_CACHE(execute_cb,
1894 SLAB_HWCACHE_ALIGN |
1895 SLAB_RECLAIM_ACCOUNT |
1896 SLAB_TYPESAFE_BY_RCU);
1897 if (!global.slab_execute_cbs)
1898 goto err_requests;
1899
1900 i915_global_register(&global.base);
1901 return 0;
1902
1903 err_requests:
1904 kmem_cache_destroy(global.slab_requests);
1905 return -ENOMEM;
1906 }
1907