/* * Copyright © 2016 Intel Corporation * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS * IN THE SOFTWARE. * */ #include #include #include #include "gem/i915_gem_internal.h" #include "gem/i915_gem_pm.h" #include "gem/selftests/mock_context.h" #include "gt/intel_engine_heartbeat.h" #include "gt/intel_engine_pm.h" #include "gt/intel_engine_user.h" #include "gt/intel_gt.h" #include "gt/intel_gt_clock_utils.h" #include "gt/intel_gt_requests.h" #include "gt/selftest_engine_heartbeat.h" #include "i915_random.h" #include "i915_selftest.h" #include "igt_flush_test.h" #include "igt_live_test.h" #include "igt_spinner.h" #include "lib_sw_fence.h" #include "mock_drm.h" #include "mock_gem_device.h" static unsigned int num_uabi_engines(struct drm_i915_private *i915) { struct intel_engine_cs *engine; unsigned int count; count = 0; for_each_uabi_engine(engine, i915) count++; return count; } static struct intel_engine_cs *rcs0(struct drm_i915_private *i915) { return intel_engine_lookup_user(i915, I915_ENGINE_CLASS_RENDER, 0); } static int igt_add_request(void *arg) { struct drm_i915_private *i915 = arg; struct i915_request *request; /* Basic preliminary test to create a request and let it loose! */ request = mock_request(rcs0(i915)->kernel_context, HZ / 10); if (!request) return -ENOMEM; i915_request_add(request); return 0; } static int igt_wait_request(void *arg) { const long T = HZ / 4; struct drm_i915_private *i915 = arg; struct i915_request *request; int err = -EINVAL; /* Submit a request, then wait upon it */ request = mock_request(rcs0(i915)->kernel_context, T); if (!request) return -ENOMEM; i915_request_get(request); if (i915_request_wait(request, 0, 0) != -ETIME) { pr_err("request wait (busy query) succeeded (expected timeout before submit!)\n"); goto out_request; } if (i915_request_wait(request, 0, T) != -ETIME) { pr_err("request wait succeeded (expected timeout before submit!)\n"); goto out_request; } if (i915_request_completed(request)) { pr_err("request completed before submit!!\n"); goto out_request; } i915_request_add(request); if (i915_request_wait(request, 0, 0) != -ETIME) { pr_err("request wait (busy query) succeeded (expected timeout after submit!)\n"); goto out_request; } if (i915_request_completed(request)) { pr_err("request completed immediately!\n"); goto out_request; } if (i915_request_wait(request, 0, T / 2) != -ETIME) { pr_err("request wait succeeded (expected timeout!)\n"); goto out_request; } if (i915_request_wait(request, 0, T) == -ETIME) { pr_err("request wait timed out!\n"); goto out_request; } if (!i915_request_completed(request)) { pr_err("request not complete after waiting!\n"); goto out_request; } if (i915_request_wait(request, 0, T) == -ETIME) { pr_err("request wait timed out when already complete!\n"); goto out_request; } err = 0; out_request: i915_request_put(request); mock_device_flush(i915); return err; } static int igt_fence_wait(void *arg) { const long T = HZ / 4; struct drm_i915_private *i915 = arg; struct i915_request *request; int err = -EINVAL; /* Submit a request, treat it as a fence and wait upon it */ request = mock_request(rcs0(i915)->kernel_context, T); if (!request) return -ENOMEM; if (dma_fence_wait_timeout(&request->fence, false, T) != -ETIME) { pr_err("fence wait success before submit (expected timeout)!\n"); goto out; } i915_request_add(request); if (dma_fence_is_signaled(&request->fence)) { pr_err("fence signaled immediately!\n"); goto out; } if (dma_fence_wait_timeout(&request->fence, false, T / 2) != -ETIME) { pr_err("fence wait success after submit (expected timeout)!\n"); goto out; } if (dma_fence_wait_timeout(&request->fence, false, T) <= 0) { pr_err("fence wait timed out (expected success)!\n"); goto out; } if (!dma_fence_is_signaled(&request->fence)) { pr_err("fence unsignaled after waiting!\n"); goto out; } if (dma_fence_wait_timeout(&request->fence, false, T) <= 0) { pr_err("fence wait timed out when complete (expected success)!\n"); goto out; } err = 0; out: mock_device_flush(i915); return err; } static int igt_request_rewind(void *arg) { struct drm_i915_private *i915 = arg; struct i915_request *request, *vip; struct i915_gem_context *ctx[2]; struct intel_context *ce; int err = -EINVAL; ctx[0] = mock_context(i915, "A"); if (!ctx[0]) { err = -ENOMEM; goto err_ctx_0; } ce = i915_gem_context_get_engine(ctx[0], RCS0); GEM_BUG_ON(IS_ERR(ce)); request = mock_request(ce, 2 * HZ); intel_context_put(ce); if (!request) { err = -ENOMEM; goto err_context_0; } i915_request_get(request); i915_request_add(request); ctx[1] = mock_context(i915, "B"); if (!ctx[1]) { err = -ENOMEM; goto err_ctx_1; } ce = i915_gem_context_get_engine(ctx[1], RCS0); GEM_BUG_ON(IS_ERR(ce)); vip = mock_request(ce, 0); intel_context_put(ce); if (!vip) { err = -ENOMEM; goto err_context_1; } /* Simulate preemption by manual reordering */ if (!mock_cancel_request(request)) { pr_err("failed to cancel request (already executed)!\n"); i915_request_add(vip); goto err_context_1; } i915_request_get(vip); i915_request_add(vip); rcu_read_lock(); request->engine->submit_request(request); rcu_read_unlock(); if (i915_request_wait(vip, 0, HZ) == -ETIME) { pr_err("timed out waiting for high priority request\n"); goto err; } if (i915_request_completed(request)) { pr_err("low priority request already completed\n"); goto err; } err = 0; err: i915_request_put(vip); err_context_1: mock_context_close(ctx[1]); err_ctx_1: i915_request_put(request); err_context_0: mock_context_close(ctx[0]); err_ctx_0: mock_device_flush(i915); return err; } struct smoketest { struct intel_engine_cs *engine; struct i915_gem_context **contexts; atomic_long_t num_waits, num_fences; int ncontexts, max_batch; struct i915_request *(*request_alloc)(struct intel_context *ce); }; static struct i915_request * __mock_request_alloc(struct intel_context *ce) { return mock_request(ce, 0); } static struct i915_request * __live_request_alloc(struct intel_context *ce) { return intel_context_create_request(ce); } struct smoke_thread { struct kthread_worker *worker; struct kthread_work work; struct smoketest *t; bool stop; int result; }; static void __igt_breadcrumbs_smoketest(struct kthread_work *work) { struct smoke_thread *thread = container_of(work, typeof(*thread), work); struct smoketest *t = thread->t; const unsigned int max_batch = min(t->ncontexts, t->max_batch) - 1; const unsigned int total = 4 * t->ncontexts + 1; unsigned int num_waits = 0, num_fences = 0; struct i915_request **requests; I915_RND_STATE(prng); unsigned int *order; int err = 0; /* * A very simple test to catch the most egregious of list handling bugs. * * At its heart, we simply create oodles of requests running across * multiple kthreads and enable signaling on them, for the sole purpose * of stressing our breadcrumb handling. The only inspection we do is * that the fences were marked as signaled. */ requests = kcalloc(total, sizeof(*requests), GFP_KERNEL); if (!requests) { thread->result = -ENOMEM; return; } order = i915_random_order(total, &prng); if (!order) { err = -ENOMEM; goto out_requests; } while (!READ_ONCE(thread->stop)) { struct i915_sw_fence *submit, *wait; unsigned int n, count; submit = heap_fence_create(GFP_KERNEL); if (!submit) { err = -ENOMEM; break; } wait = heap_fence_create(GFP_KERNEL); if (!wait) { i915_sw_fence_commit(submit); heap_fence_put(submit); err = -ENOMEM; break; } i915_random_reorder(order, total, &prng); count = 1 + i915_prandom_u32_max_state(max_batch, &prng); for (n = 0; n < count; n++) { struct i915_gem_context *ctx = t->contexts[order[n] % t->ncontexts]; struct i915_request *rq; struct intel_context *ce; ce = i915_gem_context_get_engine(ctx, t->engine->legacy_idx); GEM_BUG_ON(IS_ERR(ce)); rq = t->request_alloc(ce); intel_context_put(ce); if (IS_ERR(rq)) { err = PTR_ERR(rq); count = n; break; } err = i915_sw_fence_await_sw_fence_gfp(&rq->submit, submit, GFP_KERNEL); requests[n] = i915_request_get(rq); i915_request_add(rq); if (err >= 0) err = i915_sw_fence_await_dma_fence(wait, &rq->fence, 0, GFP_KERNEL); if (err < 0) { i915_request_put(rq); count = n; break; } } i915_sw_fence_commit(submit); i915_sw_fence_commit(wait); if (!wait_event_timeout(wait->wait, i915_sw_fence_done(wait), 5 * HZ)) { struct i915_request *rq = requests[count - 1]; pr_err("waiting for %d/%d fences (last %llx:%lld) on %s timed out!\n", atomic_read(&wait->pending), count, rq->fence.context, rq->fence.seqno, t->engine->name); GEM_TRACE_DUMP(); intel_gt_set_wedged(t->engine->gt); GEM_BUG_ON(!i915_request_completed(rq)); i915_sw_fence_wait(wait); err = -EIO; } for (n = 0; n < count; n++) { struct i915_request *rq = requests[n]; if (!test_bit(DMA_FENCE_FLAG_SIGNALED_BIT, &rq->fence.flags)) { pr_err("%llu:%llu was not signaled!\n", rq->fence.context, rq->fence.seqno); err = -EINVAL; } i915_request_put(rq); } heap_fence_put(wait); heap_fence_put(submit); if (err < 0) break; num_fences += count; num_waits++; cond_resched(); } atomic_long_add(num_fences, &t->num_fences); atomic_long_add(num_waits, &t->num_waits); kfree(order); out_requests: kfree(requests); thread->result = err; } static int mock_breadcrumbs_smoketest(void *arg) { struct drm_i915_private *i915 = arg; struct smoketest t = { .engine = rcs0(i915), .ncontexts = 1024, .max_batch = 1024, .request_alloc = __mock_request_alloc }; unsigned int ncpus = num_online_cpus(); struct smoke_thread *threads; unsigned int n; int ret = 0; /* * Smoketest our breadcrumb/signal handling for requests across multiple * threads. A very simple test to only catch the most egregious of bugs. * See __igt_breadcrumbs_smoketest(); */ threads = kcalloc(ncpus, sizeof(*threads), GFP_KERNEL); if (!threads) return -ENOMEM; t.contexts = kcalloc(t.ncontexts, sizeof(*t.contexts), GFP_KERNEL); if (!t.contexts) { ret = -ENOMEM; goto out_threads; } for (n = 0; n < t.ncontexts; n++) { t.contexts[n] = mock_context(t.engine->i915, "mock"); if (!t.contexts[n]) { ret = -ENOMEM; goto out_contexts; } } for (n = 0; n < ncpus; n++) { struct kthread_worker *worker; worker = kthread_create_worker(0, "igt/%d", n); if (IS_ERR(worker)) { ret = PTR_ERR(worker); ncpus = n; break; } threads[n].worker = worker; threads[n].t = &t; threads[n].stop = false; threads[n].result = 0; kthread_init_work(&threads[n].work, __igt_breadcrumbs_smoketest); kthread_queue_work(worker, &threads[n].work); } msleep(jiffies_to_msecs(i915_selftest.timeout_jiffies)); for (n = 0; n < ncpus; n++) { int err; WRITE_ONCE(threads[n].stop, true); kthread_flush_work(&threads[n].work); err = READ_ONCE(threads[n].result); if (err < 0 && !ret) ret = err; kthread_destroy_worker(threads[n].worker); } pr_info("Completed %lu waits for %lu fence across %d cpus\n", atomic_long_read(&t.num_waits), atomic_long_read(&t.num_fences), ncpus); out_contexts: for (n = 0; n < t.ncontexts; n++) { if (!t.contexts[n]) break; mock_context_close(t.contexts[n]); } kfree(t.contexts); out_threads: kfree(threads); return ret; } int i915_request_mock_selftests(void) { static const struct i915_subtest tests[] = { SUBTEST(igt_add_request), SUBTEST(igt_wait_request), SUBTEST(igt_fence_wait), SUBTEST(igt_request_rewind), SUBTEST(mock_breadcrumbs_smoketest), }; struct drm_i915_private *i915; intel_wakeref_t wakeref; int err = 0; i915 = mock_gem_device(); if (!i915) return -ENOMEM; with_intel_runtime_pm(&i915->runtime_pm, wakeref) err = i915_subtests(tests, i915); mock_destroy_device(i915); return err; } static int live_nop_request(void *arg) { struct drm_i915_private *i915 = arg; struct intel_engine_cs *engine; struct igt_live_test t; int err = -ENODEV; /* * Submit various sized batches of empty requests, to each engine * (individually), and wait for the batch to complete. We can check * the overhead of submitting requests to the hardware. */ for_each_uabi_engine(engine, i915) { unsigned long n, prime; IGT_TIMEOUT(end_time); ktime_t times[2] = {}; err = igt_live_test_begin(&t, i915, __func__, engine->name); if (err) return err; intel_engine_pm_get(engine); for_each_prime_number_from(prime, 1, 8192) { struct i915_request *request = NULL; times[1] = ktime_get_raw(); for (n = 0; n < prime; n++) { i915_request_put(request); request = i915_request_create(engine->kernel_context); if (IS_ERR(request)) return PTR_ERR(request); /* * This space is left intentionally blank. * * We do not actually want to perform any * action with this request, we just want * to measure the latency in allocation * and submission of our breadcrumbs - * ensuring that the bare request is sufficient * for the system to work (i.e. proper HEAD * tracking of the rings, interrupt handling, * etc). It also gives us the lowest bounds * for latency. */ i915_request_get(request); i915_request_add(request); } i915_request_wait(request, 0, MAX_SCHEDULE_TIMEOUT); i915_request_put(request); times[1] = ktime_sub(ktime_get_raw(), times[1]); if (prime == 1) times[0] = times[1]; if (__igt_timeout(end_time, NULL)) break; } intel_engine_pm_put(engine); err = igt_live_test_end(&t); if (err) return err; pr_info("Request latencies on %s: 1 = %lluns, %lu = %lluns\n", engine->name, ktime_to_ns(times[0]), prime, div64_u64(ktime_to_ns(times[1]), prime)); } return err; } static int __cancel_inactive(struct intel_engine_cs *engine) { struct intel_context *ce; struct igt_spinner spin; struct i915_request *rq; int err = 0; if (igt_spinner_init(&spin, engine->gt)) return -ENOMEM; ce = intel_context_create(engine); if (IS_ERR(ce)) { err = PTR_ERR(ce); goto out_spin; } rq = igt_spinner_create_request(&spin, ce, MI_ARB_CHECK); if (IS_ERR(rq)) { err = PTR_ERR(rq); goto out_ce; } pr_debug("%s: Cancelling inactive request\n", engine->name); i915_request_cancel(rq, -EINTR); i915_request_get(rq); i915_request_add(rq); if (i915_request_wait(rq, 0, HZ / 5) < 0) { struct drm_printer p = drm_info_printer(engine->i915->drm.dev); pr_err("%s: Failed to cancel inactive request\n", engine->name); intel_engine_dump(engine, &p, "%s\n", engine->name); err = -ETIME; goto out_rq; } if (rq->fence.error != -EINTR) { pr_err("%s: fence not cancelled (%u)\n", engine->name, rq->fence.error); err = -EINVAL; } out_rq: i915_request_put(rq); out_ce: intel_context_put(ce); out_spin: igt_spinner_fini(&spin); if (err) pr_err("%s: %s error %d\n", __func__, engine->name, err); return err; } static int __cancel_active(struct intel_engine_cs *engine) { struct intel_context *ce; struct igt_spinner spin; struct i915_request *rq; int err = 0; if (igt_spinner_init(&spin, engine->gt)) return -ENOMEM; ce = intel_context_create(engine); if (IS_ERR(ce)) { err = PTR_ERR(ce); goto out_spin; } rq = igt_spinner_create_request(&spin, ce, MI_ARB_CHECK); if (IS_ERR(rq)) { err = PTR_ERR(rq); goto out_ce; } pr_debug("%s: Cancelling active request\n", engine->name); i915_request_get(rq); i915_request_add(rq); if (!igt_wait_for_spinner(&spin, rq)) { struct drm_printer p = drm_info_printer(engine->i915->drm.dev); pr_err("Failed to start spinner on %s\n", engine->name); intel_engine_dump(engine, &p, "%s\n", engine->name); err = -ETIME; goto out_rq; } i915_request_cancel(rq, -EINTR); if (i915_request_wait(rq, 0, HZ / 5) < 0) { struct drm_printer p = drm_info_printer(engine->i915->drm.dev); pr_err("%s: Failed to cancel active request\n", engine->name); intel_engine_dump(engine, &p, "%s\n", engine->name); err = -ETIME; goto out_rq; } if (rq->fence.error != -EINTR) { pr_err("%s: fence not cancelled (%u)\n", engine->name, rq->fence.error); err = -EINVAL; } out_rq: i915_request_put(rq); out_ce: intel_context_put(ce); out_spin: igt_spinner_fini(&spin); if (err) pr_err("%s: %s error %d\n", __func__, engine->name, err); return err; } static int __cancel_completed(struct intel_engine_cs *engine) { struct intel_context *ce; struct igt_spinner spin; struct i915_request *rq; int err = 0; if (igt_spinner_init(&spin, engine->gt)) return -ENOMEM; ce = intel_context_create(engine); if (IS_ERR(ce)) { err = PTR_ERR(ce); goto out_spin; } rq = igt_spinner_create_request(&spin, ce, MI_ARB_CHECK); if (IS_ERR(rq)) { err = PTR_ERR(rq); goto out_ce; } igt_spinner_end(&spin); i915_request_get(rq); i915_request_add(rq); if (i915_request_wait(rq, 0, HZ / 5) < 0) { err = -ETIME; goto out_rq; } pr_debug("%s: Cancelling completed request\n", engine->name); i915_request_cancel(rq, -EINTR); if (rq->fence.error) { pr_err("%s: fence not cancelled (%u)\n", engine->name, rq->fence.error); err = -EINVAL; } out_rq: i915_request_put(rq); out_ce: intel_context_put(ce); out_spin: igt_spinner_fini(&spin); if (err) pr_err("%s: %s error %d\n", __func__, engine->name, err); return err; } /* * Test to prove a non-preemptable request can be cancelled and a subsequent * request on the same context can successfully complete after cancellation. * * Testing methodology is to create a non-preemptible request and submit it, * wait for spinner to start, create a NOP request and submit it, cancel the * spinner, wait for spinner to complete and verify it failed with an error, * finally wait for NOP request to complete verify it succeeded without an * error. Preemption timeout also reduced / restored so test runs in a timely * maner. */ static int __cancel_reset(struct drm_i915_private *i915, struct intel_engine_cs *engine) { struct intel_context *ce; struct igt_spinner spin; struct i915_request *rq, *nop; unsigned long preempt_timeout_ms; int err = 0; if (!CONFIG_DRM_I915_PREEMPT_TIMEOUT || !intel_has_reset_engine(engine->gt)) return 0; preempt_timeout_ms = engine->props.preempt_timeout_ms; engine->props.preempt_timeout_ms = 100; if (igt_spinner_init(&spin, engine->gt)) goto out_restore; ce = intel_context_create(engine); if (IS_ERR(ce)) { err = PTR_ERR(ce); goto out_spin; } rq = igt_spinner_create_request(&spin, ce, MI_NOOP); if (IS_ERR(rq)) { err = PTR_ERR(rq); goto out_ce; } pr_debug("%s: Cancelling active non-preemptable request\n", engine->name); i915_request_get(rq); i915_request_add(rq); if (!igt_wait_for_spinner(&spin, rq)) { struct drm_printer p = drm_info_printer(engine->i915->drm.dev); pr_err("Failed to start spinner on %s\n", engine->name); intel_engine_dump(engine, &p, "%s\n", engine->name); err = -ETIME; goto out_rq; } nop = intel_context_create_request(ce); if (IS_ERR(nop)) goto out_rq; i915_request_get(nop); i915_request_add(nop); i915_request_cancel(rq, -EINTR); if (i915_request_wait(rq, 0, HZ) < 0) { struct drm_printer p = drm_info_printer(engine->i915->drm.dev); pr_err("%s: Failed to cancel hung request\n", engine->name); intel_engine_dump(engine, &p, "%s\n", engine->name); err = -ETIME; goto out_nop; } if (rq->fence.error != -EINTR) { pr_err("%s: fence not cancelled (%u)\n", engine->name, rq->fence.error); err = -EINVAL; goto out_nop; } if (i915_request_wait(nop, 0, HZ) < 0) { struct drm_printer p = drm_info_printer(engine->i915->drm.dev); pr_err("%s: Failed to complete nop request\n", engine->name); intel_engine_dump(engine, &p, "%s\n", engine->name); err = -ETIME; goto out_nop; } if (nop->fence.error != 0) { pr_err("%s: Nop request errored (%u)\n", engine->name, nop->fence.error); err = -EINVAL; } out_nop: i915_request_put(nop); out_rq: i915_request_put(rq); out_ce: intel_context_put(ce); out_spin: igt_spinner_fini(&spin); out_restore: engine->props.preempt_timeout_ms = preempt_timeout_ms; if (err) pr_err("%s: %s error %d\n", __func__, engine->name, err); return err; } static int live_cancel_request(void *arg) { struct drm_i915_private *i915 = arg; struct intel_engine_cs *engine; /* * Check cancellation of requests. We expect to be able to immediately * cancel active requests, even if they are currently on the GPU. */ for_each_uabi_engine(engine, i915) { struct igt_live_test t; int err, err2; if (!intel_engine_has_preemption(engine)) continue; err = igt_live_test_begin(&t, i915, __func__, engine->name); if (err) return err; err = __cancel_inactive(engine); if (err == 0) err = __cancel_active(engine); if (err == 0) err = __cancel_completed(engine); err2 = igt_live_test_end(&t); if (err) return err; if (err2) return err2; /* Expects reset so call outside of igt_live_test_* */ err = __cancel_reset(i915, engine); if (err) return err; if (igt_flush_test(i915)) return -EIO; } return 0; } static struct i915_vma *empty_batch(struct intel_gt *gt) { struct drm_i915_gem_object *obj; struct i915_vma *vma; u32 *cmd; int err; obj = i915_gem_object_create_internal(gt->i915, PAGE_SIZE); if (IS_ERR(obj)) return ERR_CAST(obj); cmd = i915_gem_object_pin_map_unlocked(obj, I915_MAP_WC); if (IS_ERR(cmd)) { err = PTR_ERR(cmd); goto err; } *cmd = MI_BATCH_BUFFER_END; __i915_gem_object_flush_map(obj, 0, 64); i915_gem_object_unpin_map(obj); intel_gt_chipset_flush(gt); vma = i915_vma_instance(obj, gt->vm, NULL); if (IS_ERR(vma)) { err = PTR_ERR(vma); goto err; } err = i915_vma_pin(vma, 0, 0, PIN_USER); if (err) goto err; /* Force the wait now to avoid including it in the benchmark */ err = i915_vma_sync(vma); if (err) goto err_pin; return vma; err_pin: i915_vma_unpin(vma); err: i915_gem_object_put(obj); return ERR_PTR(err); } static int emit_bb_start(struct i915_request *rq, struct i915_vma *batch) { return rq->engine->emit_bb_start(rq, i915_vma_offset(batch), i915_vma_size(batch), 0); } static struct i915_request * empty_request(struct intel_engine_cs *engine, struct i915_vma *batch) { struct i915_request *request; int err; request = i915_request_create(engine->kernel_context); if (IS_ERR(request)) return request; err = emit_bb_start(request, batch); if (err) goto out_request; i915_request_get(request); out_request: i915_request_add(request); return err ? ERR_PTR(err) : request; } static int live_empty_request(void *arg) { struct drm_i915_private *i915 = arg; struct intel_engine_cs *engine; struct igt_live_test t; int err; /* * Submit various sized batches of empty requests, to each engine * (individually), and wait for the batch to complete. We can check * the overhead of submitting requests to the hardware. */ for_each_uabi_engine(engine, i915) { IGT_TIMEOUT(end_time); struct i915_request *request; struct i915_vma *batch; unsigned long n, prime; ktime_t times[2] = {}; batch = empty_batch(engine->gt); if (IS_ERR(batch)) return PTR_ERR(batch); err = igt_live_test_begin(&t, i915, __func__, engine->name); if (err) goto out_batch; intel_engine_pm_get(engine); /* Warmup / preload */ request = empty_request(engine, batch); if (IS_ERR(request)) { err = PTR_ERR(request); intel_engine_pm_put(engine); goto out_batch; } i915_request_wait(request, 0, MAX_SCHEDULE_TIMEOUT); for_each_prime_number_from(prime, 1, 8192) { times[1] = ktime_get_raw(); for (n = 0; n < prime; n++) { i915_request_put(request); request = empty_request(engine, batch); if (IS_ERR(request)) { err = PTR_ERR(request); intel_engine_pm_put(engine); goto out_batch; } } i915_request_wait(request, 0, MAX_SCHEDULE_TIMEOUT); times[1] = ktime_sub(ktime_get_raw(), times[1]); if (prime == 1) times[0] = times[1]; if (__igt_timeout(end_time, NULL)) break; } i915_request_put(request); intel_engine_pm_put(engine); err = igt_live_test_end(&t); if (err) goto out_batch; pr_info("Batch latencies on %s: 1 = %lluns, %lu = %lluns\n", engine->name, ktime_to_ns(times[0]), prime, div64_u64(ktime_to_ns(times[1]), prime)); out_batch: i915_vma_unpin(batch); i915_vma_put(batch); if (err) break; } return err; } static struct i915_vma *recursive_batch(struct intel_gt *gt) { struct drm_i915_gem_object *obj; const int ver = GRAPHICS_VER(gt->i915); struct i915_vma *vma; u32 *cmd; int err; obj = i915_gem_object_create_internal(gt->i915, PAGE_SIZE); if (IS_ERR(obj)) return ERR_CAST(obj); vma = i915_vma_instance(obj, gt->vm, NULL); if (IS_ERR(vma)) { err = PTR_ERR(vma); goto err; } err = i915_vma_pin(vma, 0, 0, PIN_USER); if (err) goto err; cmd = i915_gem_object_pin_map_unlocked(obj, I915_MAP_WC); if (IS_ERR(cmd)) { err = PTR_ERR(cmd); goto err; } if (ver >= 8) { *cmd++ = MI_BATCH_BUFFER_START | 1 << 8 | 1; *cmd++ = lower_32_bits(i915_vma_offset(vma)); *cmd++ = upper_32_bits(i915_vma_offset(vma)); } else if (ver >= 6) { *cmd++ = MI_BATCH_BUFFER_START | 1 << 8; *cmd++ = lower_32_bits(i915_vma_offset(vma)); } else { *cmd++ = MI_BATCH_BUFFER_START | MI_BATCH_GTT; *cmd++ = lower_32_bits(i915_vma_offset(vma)); } *cmd++ = MI_BATCH_BUFFER_END; /* terminate early in case of error */ __i915_gem_object_flush_map(obj, 0, 64); i915_gem_object_unpin_map(obj); intel_gt_chipset_flush(gt); return vma; err: i915_gem_object_put(obj); return ERR_PTR(err); } static int recursive_batch_resolve(struct i915_vma *batch) { u32 *cmd; cmd = i915_gem_object_pin_map_unlocked(batch->obj, I915_MAP_WC); if (IS_ERR(cmd)) return PTR_ERR(cmd); *cmd = MI_BATCH_BUFFER_END; __i915_gem_object_flush_map(batch->obj, 0, sizeof(*cmd)); i915_gem_object_unpin_map(batch->obj); intel_gt_chipset_flush(batch->vm->gt); return 0; } static int live_all_engines(void *arg) { struct drm_i915_private *i915 = arg; const unsigned int nengines = num_uabi_engines(i915); struct intel_engine_cs *engine; struct i915_request **request; struct igt_live_test t; unsigned int idx; int err; /* * Check we can submit requests to all engines simultaneously. We * send a recursive batch to each engine - checking that we don't * block doing so, and that they don't complete too soon. */ request = kcalloc(nengines, sizeof(*request), GFP_KERNEL); if (!request) return -ENOMEM; err = igt_live_test_begin(&t, i915, __func__, ""); if (err) goto out_free; idx = 0; for_each_uabi_engine(engine, i915) { struct i915_vma *batch; batch = recursive_batch(engine->gt); if (IS_ERR(batch)) { err = PTR_ERR(batch); pr_err("%s: Unable to create batch, err=%d\n", __func__, err); goto out_free; } i915_vma_lock(batch); request[idx] = intel_engine_create_kernel_request(engine); if (IS_ERR(request[idx])) { err = PTR_ERR(request[idx]); pr_err("%s: Request allocation failed with err=%d\n", __func__, err); goto out_unlock; } GEM_BUG_ON(request[idx]->context->vm != batch->vm); err = i915_vma_move_to_active(batch, request[idx], 0); GEM_BUG_ON(err); err = emit_bb_start(request[idx], batch); GEM_BUG_ON(err); request[idx]->batch = batch; i915_request_get(request[idx]); i915_request_add(request[idx]); idx++; out_unlock: i915_vma_unlock(batch); if (err) goto out_request; } idx = 0; for_each_uabi_engine(engine, i915) { if (i915_request_completed(request[idx])) { pr_err("%s(%s): request completed too early!\n", __func__, engine->name); err = -EINVAL; goto out_request; } idx++; } idx = 0; for_each_uabi_engine(engine, i915) { err = recursive_batch_resolve(request[idx]->batch); if (err) { pr_err("%s: failed to resolve batch, err=%d\n", __func__, err); goto out_request; } idx++; } idx = 0; for_each_uabi_engine(engine, i915) { struct i915_request *rq = request[idx]; long timeout; timeout = i915_request_wait(rq, 0, MAX_SCHEDULE_TIMEOUT); if (timeout < 0) { err = timeout; pr_err("%s: error waiting for request on %s, err=%d\n", __func__, engine->name, err); goto out_request; } GEM_BUG_ON(!i915_request_completed(rq)); i915_vma_unpin(rq->batch); i915_vma_put(rq->batch); i915_request_put(rq); request[idx] = NULL; idx++; } err = igt_live_test_end(&t); out_request: idx = 0; for_each_uabi_engine(engine, i915) { struct i915_request *rq = request[idx]; if (!rq) continue; if (rq->batch) { i915_vma_unpin(rq->batch); i915_vma_put(rq->batch); } i915_request_put(rq); idx++; } out_free: kfree(request); return err; } static int live_sequential_engines(void *arg) { struct drm_i915_private *i915 = arg; const unsigned int nengines = num_uabi_engines(i915); struct i915_request **request; struct i915_request *prev = NULL; struct intel_engine_cs *engine; struct igt_live_test t; unsigned int idx; int err; /* * Check we can submit requests to all engines sequentially, such * that each successive request waits for the earlier ones. This * tests that we don't execute requests out of order, even though * they are running on independent engines. */ request = kcalloc(nengines, sizeof(*request), GFP_KERNEL); if (!request) return -ENOMEM; err = igt_live_test_begin(&t, i915, __func__, ""); if (err) goto out_free; idx = 0; for_each_uabi_engine(engine, i915) { struct i915_vma *batch; batch = recursive_batch(engine->gt); if (IS_ERR(batch)) { err = PTR_ERR(batch); pr_err("%s: Unable to create batch for %s, err=%d\n", __func__, engine->name, err); goto out_free; } i915_vma_lock(batch); request[idx] = intel_engine_create_kernel_request(engine); if (IS_ERR(request[idx])) { err = PTR_ERR(request[idx]); pr_err("%s: Request allocation failed for %s with err=%d\n", __func__, engine->name, err); goto out_unlock; } GEM_BUG_ON(request[idx]->context->vm != batch->vm); if (prev) { err = i915_request_await_dma_fence(request[idx], &prev->fence); if (err) { i915_request_add(request[idx]); pr_err("%s: Request await failed for %s with err=%d\n", __func__, engine->name, err); goto out_unlock; } } err = i915_vma_move_to_active(batch, request[idx], 0); GEM_BUG_ON(err); err = emit_bb_start(request[idx], batch); GEM_BUG_ON(err); request[idx]->batch = batch; i915_request_get(request[idx]); i915_request_add(request[idx]); prev = request[idx]; idx++; out_unlock: i915_vma_unlock(batch); if (err) goto out_request; } idx = 0; for_each_uabi_engine(engine, i915) { long timeout; if (i915_request_completed(request[idx])) { pr_err("%s(%s): request completed too early!\n", __func__, engine->name); err = -EINVAL; goto out_request; } err = recursive_batch_resolve(request[idx]->batch); if (err) { pr_err("%s: failed to resolve batch, err=%d\n", __func__, err); goto out_request; } timeout = i915_request_wait(request[idx], 0, MAX_SCHEDULE_TIMEOUT); if (timeout < 0) { err = timeout; pr_err("%s: error waiting for request on %s, err=%d\n", __func__, engine->name, err); goto out_request; } GEM_BUG_ON(!i915_request_completed(request[idx])); idx++; } err = igt_live_test_end(&t); out_request: idx = 0; for_each_uabi_engine(engine, i915) { u32 *cmd; if (!request[idx]) break; cmd = i915_gem_object_pin_map_unlocked(request[idx]->batch->obj, I915_MAP_WC); if (!IS_ERR(cmd)) { *cmd = MI_BATCH_BUFFER_END; __i915_gem_object_flush_map(request[idx]->batch->obj, 0, sizeof(*cmd)); i915_gem_object_unpin_map(request[idx]->batch->obj); intel_gt_chipset_flush(engine->gt); } i915_vma_put(request[idx]->batch); i915_request_put(request[idx]); idx++; } out_free: kfree(request); return err; } struct parallel_thread { struct kthread_worker *worker; struct kthread_work work; struct intel_engine_cs *engine; int result; }; static void __live_parallel_engine1(struct kthread_work *work) { struct parallel_thread *thread = container_of(work, typeof(*thread), work); struct intel_engine_cs *engine = thread->engine; IGT_TIMEOUT(end_time); unsigned long count; int err = 0; count = 0; intel_engine_pm_get(engine); do { struct i915_request *rq; rq = i915_request_create(engine->kernel_context); if (IS_ERR(rq)) { err = PTR_ERR(rq); break; } i915_request_get(rq); i915_request_add(rq); err = 0; if (i915_request_wait(rq, 0, HZ) < 0) err = -ETIME; i915_request_put(rq); if (err) break; count++; } while (!__igt_timeout(end_time, NULL)); intel_engine_pm_put(engine); pr_info("%s: %lu request + sync\n", engine->name, count); thread->result = err; } static void __live_parallel_engineN(struct kthread_work *work) { struct parallel_thread *thread = container_of(work, typeof(*thread), work); struct intel_engine_cs *engine = thread->engine; IGT_TIMEOUT(end_time); unsigned long count; int err = 0; count = 0; intel_engine_pm_get(engine); do { struct i915_request *rq; rq = i915_request_create(engine->kernel_context); if (IS_ERR(rq)) { err = PTR_ERR(rq); break; } i915_request_add(rq); count++; } while (!__igt_timeout(end_time, NULL)); intel_engine_pm_put(engine); pr_info("%s: %lu requests\n", engine->name, count); thread->result = err; } static bool wake_all(struct drm_i915_private *i915) { if (atomic_dec_and_test(&i915->selftest.counter)) { wake_up_var(&i915->selftest.counter); return true; } return false; } static int wait_for_all(struct drm_i915_private *i915) { if (wake_all(i915)) return 0; if (wait_var_event_timeout(&i915->selftest.counter, !atomic_read(&i915->selftest.counter), i915_selftest.timeout_jiffies)) return 0; return -ETIME; } static void __live_parallel_spin(struct kthread_work *work) { struct parallel_thread *thread = container_of(work, typeof(*thread), work); struct intel_engine_cs *engine = thread->engine; struct igt_spinner spin; struct i915_request *rq; int err = 0; /* * Create a spinner running for eternity on each engine. If a second * spinner is incorrectly placed on the same engine, it will not be * able to start in time. */ if (igt_spinner_init(&spin, engine->gt)) { wake_all(engine->i915); thread->result = -ENOMEM; return; } intel_engine_pm_get(engine); rq = igt_spinner_create_request(&spin, engine->kernel_context, MI_NOOP); /* no preemption */ intel_engine_pm_put(engine); if (IS_ERR(rq)) { err = PTR_ERR(rq); if (err == -ENODEV) err = 0; wake_all(engine->i915); goto out_spin; } i915_request_get(rq); i915_request_add(rq); if (igt_wait_for_spinner(&spin, rq)) { /* Occupy this engine for the whole test */ err = wait_for_all(engine->i915); } else { pr_err("Failed to start spinner on %s\n", engine->name); err = -EINVAL; } igt_spinner_end(&spin); if (err == 0 && i915_request_wait(rq, 0, HZ) < 0) err = -EIO; i915_request_put(rq); out_spin: igt_spinner_fini(&spin); thread->result = err; } static int live_parallel_engines(void *arg) { struct drm_i915_private *i915 = arg; static void (* const func[])(struct kthread_work *) = { __live_parallel_engine1, __live_parallel_engineN, __live_parallel_spin, NULL, }; const unsigned int nengines = num_uabi_engines(i915); struct parallel_thread *threads; struct intel_engine_cs *engine; void (* const *fn)(struct kthread_work *); int err = 0; /* * Check we can submit requests to all engines concurrently. This * tests that we load up the system maximally. */ threads = kcalloc(nengines, sizeof(*threads), GFP_KERNEL); if (!threads) return -ENOMEM; for (fn = func; !err && *fn; fn++) { char name[KSYM_NAME_LEN]; struct igt_live_test t; unsigned int idx; snprintf(name, sizeof(name), "%ps", *fn); err = igt_live_test_begin(&t, i915, __func__, name); if (err) break; atomic_set(&i915->selftest.counter, nengines); idx = 0; for_each_uabi_engine(engine, i915) { struct kthread_worker *worker; worker = kthread_create_worker(0, "igt/parallel:%s", engine->name); if (IS_ERR(worker)) { err = PTR_ERR(worker); break; } threads[idx].worker = worker; threads[idx].result = 0; threads[idx].engine = engine; kthread_init_work(&threads[idx].work, *fn); kthread_queue_work(worker, &threads[idx].work); idx++; } idx = 0; for_each_uabi_engine(engine, i915) { int status; if (!threads[idx].worker) break; kthread_flush_work(&threads[idx].work); status = READ_ONCE(threads[idx].result); if (status && !err) err = status; kthread_destroy_worker(threads[idx++].worker); } if (igt_live_test_end(&t)) err = -EIO; } kfree(threads); return err; } static int max_batches(struct i915_gem_context *ctx, struct intel_engine_cs *engine) { struct i915_request *rq; int ret; /* * Before execlists, all contexts share the same ringbuffer. With * execlists, each context/engine has a separate ringbuffer and * for the purposes of this test, inexhaustible. * * For the global ringbuffer though, we have to be very careful * that we do not wrap while preventing the execution of requests * with a unsignaled fence. */ if (HAS_EXECLISTS(ctx->i915)) return INT_MAX; rq = igt_request_alloc(ctx, engine); if (IS_ERR(rq)) { ret = PTR_ERR(rq); } else { int sz; ret = rq->ring->size - rq->reserved_space; i915_request_add(rq); sz = rq->ring->emit - rq->head; if (sz < 0) sz += rq->ring->size; ret /= sz; ret /= 2; /* leave half spare, in case of emergency! */ } return ret; } static int live_breadcrumbs_smoketest(void *arg) { struct drm_i915_private *i915 = arg; const unsigned int nengines = num_uabi_engines(i915); const unsigned int ncpus = /* saturate with nengines * ncpus */ max_t(int, 2, DIV_ROUND_UP(num_online_cpus(), nengines)); unsigned long num_waits, num_fences; struct intel_engine_cs *engine; struct smoke_thread *threads; struct igt_live_test live; intel_wakeref_t wakeref; struct smoketest *smoke; unsigned int n, idx; struct file *file; int ret = 0; /* * Smoketest our breadcrumb/signal handling for requests across multiple * threads. A very simple test to only catch the most egregious of bugs. * See __igt_breadcrumbs_smoketest(); * * On real hardware this time. */ wakeref = intel_runtime_pm_get(&i915->runtime_pm); file = mock_file(i915); if (IS_ERR(file)) { ret = PTR_ERR(file); goto out_rpm; } smoke = kcalloc(nengines, sizeof(*smoke), GFP_KERNEL); if (!smoke) { ret = -ENOMEM; goto out_file; } threads = kcalloc(ncpus * nengines, sizeof(*threads), GFP_KERNEL); if (!threads) { ret = -ENOMEM; goto out_smoke; } smoke[0].request_alloc = __live_request_alloc; smoke[0].ncontexts = 64; smoke[0].contexts = kcalloc(smoke[0].ncontexts, sizeof(*smoke[0].contexts), GFP_KERNEL); if (!smoke[0].contexts) { ret = -ENOMEM; goto out_threads; } for (n = 0; n < smoke[0].ncontexts; n++) { smoke[0].contexts[n] = live_context(i915, file); if (IS_ERR(smoke[0].contexts[n])) { ret = PTR_ERR(smoke[0].contexts[n]); goto out_contexts; } } ret = igt_live_test_begin(&live, i915, __func__, ""); if (ret) goto out_contexts; idx = 0; for_each_uabi_engine(engine, i915) { smoke[idx] = smoke[0]; smoke[idx].engine = engine; smoke[idx].max_batch = max_batches(smoke[0].contexts[0], engine); if (smoke[idx].max_batch < 0) { ret = smoke[idx].max_batch; goto out_flush; } /* One ring interleaved between requests from all cpus */ smoke[idx].max_batch /= ncpus + 1; pr_debug("Limiting batches to %d requests on %s\n", smoke[idx].max_batch, engine->name); for (n = 0; n < ncpus; n++) { unsigned int i = idx * ncpus + n; struct kthread_worker *worker; worker = kthread_create_worker(0, "igt/%d.%d", idx, n); if (IS_ERR(worker)) { ret = PTR_ERR(worker); goto out_flush; } threads[i].worker = worker; threads[i].t = &smoke[idx]; kthread_init_work(&threads[i].work, __igt_breadcrumbs_smoketest); kthread_queue_work(worker, &threads[i].work); } idx++; } msleep(jiffies_to_msecs(i915_selftest.timeout_jiffies)); out_flush: idx = 0; num_waits = 0; num_fences = 0; for_each_uabi_engine(engine, i915) { for (n = 0; n < ncpus; n++) { unsigned int i = idx * ncpus + n; int err; if (!threads[i].worker) continue; WRITE_ONCE(threads[i].stop, true); kthread_flush_work(&threads[i].work); err = READ_ONCE(threads[i].result); if (err < 0 && !ret) ret = err; kthread_destroy_worker(threads[i].worker); } num_waits += atomic_long_read(&smoke[idx].num_waits); num_fences += atomic_long_read(&smoke[idx].num_fences); idx++; } pr_info("Completed %lu waits for %lu fences across %d engines and %d cpus\n", num_waits, num_fences, idx, ncpus); ret = igt_live_test_end(&live) ?: ret; out_contexts: kfree(smoke[0].contexts); out_threads: kfree(threads); out_smoke: kfree(smoke); out_file: fput(file); out_rpm: intel_runtime_pm_put(&i915->runtime_pm, wakeref); return ret; } int i915_request_live_selftests(struct drm_i915_private *i915) { static const struct i915_subtest tests[] = { SUBTEST(live_nop_request), SUBTEST(live_all_engines), SUBTEST(live_sequential_engines), SUBTEST(live_parallel_engines), SUBTEST(live_empty_request), SUBTEST(live_cancel_request), SUBTEST(live_breadcrumbs_smoketest), }; if (intel_gt_is_wedged(to_gt(i915))) return 0; return i915_live_subtests(tests, i915); } static int switch_to_kernel_sync(struct intel_context *ce, int err) { struct i915_request *rq; struct dma_fence *fence; rq = intel_engine_create_kernel_request(ce->engine); if (IS_ERR(rq)) return PTR_ERR(rq); fence = i915_active_fence_get(&ce->timeline->last_request); if (fence) { i915_request_await_dma_fence(rq, fence); dma_fence_put(fence); } rq = i915_request_get(rq); i915_request_add(rq); if (i915_request_wait(rq, 0, HZ / 2) < 0 && !err) err = -ETIME; i915_request_put(rq); while (!err && !intel_engine_is_idle(ce->engine)) intel_engine_flush_submission(ce->engine); return err; } struct perf_stats { struct intel_engine_cs *engine; unsigned long count; ktime_t time; ktime_t busy; u64 runtime; }; struct perf_series { struct drm_i915_private *i915; unsigned int nengines; struct intel_context *ce[] __counted_by(nengines); }; static int cmp_u32(const void *A, const void *B) { const u32 *a = A, *b = B; return *a - *b; } static u32 trifilter(u32 *a) { u64 sum; #define TF_COUNT 5 sort(a, TF_COUNT, sizeof(*a), cmp_u32, NULL); sum = mul_u32_u32(a[2], 2); sum += a[1]; sum += a[3]; GEM_BUG_ON(sum > U32_MAX); return sum; #define TF_BIAS 2 } static u64 cycles_to_ns(struct intel_engine_cs *engine, u32 cycles) { u64 ns = intel_gt_clock_interval_to_ns(engine->gt, cycles); return DIV_ROUND_CLOSEST(ns, 1 << TF_BIAS); } static u32 *emit_timestamp_store(u32 *cs, struct intel_context *ce, u32 offset) { *cs++ = MI_STORE_REGISTER_MEM_GEN8 | MI_USE_GGTT; *cs++ = i915_mmio_reg_offset(RING_TIMESTAMP((ce->engine->mmio_base))); *cs++ = offset; *cs++ = 0; return cs; } static u32 *emit_store_dw(u32 *cs, u32 offset, u32 value) { *cs++ = MI_STORE_DWORD_IMM_GEN4 | MI_USE_GGTT; *cs++ = offset; *cs++ = 0; *cs++ = value; return cs; } static u32 *emit_semaphore_poll(u32 *cs, u32 mode, u32 value, u32 offset) { *cs++ = MI_SEMAPHORE_WAIT | MI_SEMAPHORE_GLOBAL_GTT | MI_SEMAPHORE_POLL | mode; *cs++ = value; *cs++ = offset; *cs++ = 0; return cs; } static u32 *emit_semaphore_poll_until(u32 *cs, u32 offset, u32 value) { return emit_semaphore_poll(cs, MI_SEMAPHORE_SAD_EQ_SDD, value, offset); } static void semaphore_set(u32 *sema, u32 value) { WRITE_ONCE(*sema, value); wmb(); /* flush the update to the cache, and beyond */ } static u32 *hwsp_scratch(const struct intel_context *ce) { return memset32(ce->engine->status_page.addr + 1000, 0, 21); } static u32 hwsp_offset(const struct intel_context *ce, u32 *dw) { return (i915_ggtt_offset(ce->engine->status_page.vma) + offset_in_page(dw)); } static int measure_semaphore_response(struct intel_context *ce) { u32 *sema = hwsp_scratch(ce); const u32 offset = hwsp_offset(ce, sema); u32 elapsed[TF_COUNT], cycles; struct i915_request *rq; u32 *cs; int err; int i; /* * Measure how many cycles it takes for the HW to detect the change * in a semaphore value. * * A: read CS_TIMESTAMP from CPU * poke semaphore * B: read CS_TIMESTAMP on GPU * * Semaphore latency: B - A */ semaphore_set(sema, -1); rq = i915_request_create(ce); if (IS_ERR(rq)) return PTR_ERR(rq); cs = intel_ring_begin(rq, 4 + 12 * ARRAY_SIZE(elapsed)); if (IS_ERR(cs)) { i915_request_add(rq); err = PTR_ERR(cs); goto err; } cs = emit_store_dw(cs, offset, 0); for (i = 1; i <= ARRAY_SIZE(elapsed); i++) { cs = emit_semaphore_poll_until(cs, offset, i); cs = emit_timestamp_store(cs, ce, offset + i * sizeof(u32)); cs = emit_store_dw(cs, offset, 0); } intel_ring_advance(rq, cs); i915_request_add(rq); if (wait_for(READ_ONCE(*sema) == 0, 50)) { err = -EIO; goto err; } for (i = 1; i <= ARRAY_SIZE(elapsed); i++) { preempt_disable(); cycles = ENGINE_READ_FW(ce->engine, RING_TIMESTAMP); semaphore_set(sema, i); preempt_enable(); if (wait_for(READ_ONCE(*sema) == 0, 50)) { err = -EIO; goto err; } elapsed[i - 1] = sema[i] - cycles; } cycles = trifilter(elapsed); pr_info("%s: semaphore response %d cycles, %lluns\n", ce->engine->name, cycles >> TF_BIAS, cycles_to_ns(ce->engine, cycles)); return intel_gt_wait_for_idle(ce->engine->gt, HZ); err: intel_gt_set_wedged(ce->engine->gt); return err; } static int measure_idle_dispatch(struct intel_context *ce) { u32 *sema = hwsp_scratch(ce); const u32 offset = hwsp_offset(ce, sema); u32 elapsed[TF_COUNT], cycles; u32 *cs; int err; int i; /* * Measure how long it takes for us to submit a request while the * engine is idle, but is resting in our context. * * A: read CS_TIMESTAMP from CPU * submit request * B: read CS_TIMESTAMP on GPU * * Submission latency: B - A */ for (i = 0; i < ARRAY_SIZE(elapsed); i++) { struct i915_request *rq; err = intel_gt_wait_for_idle(ce->engine->gt, HZ / 2); if (err) return err; rq = i915_request_create(ce); if (IS_ERR(rq)) { err = PTR_ERR(rq); goto err; } cs = intel_ring_begin(rq, 4); if (IS_ERR(cs)) { i915_request_add(rq); err = PTR_ERR(cs); goto err; } cs = emit_timestamp_store(cs, ce, offset + i * sizeof(u32)); intel_ring_advance(rq, cs); preempt_disable(); local_bh_disable(); elapsed[i] = ENGINE_READ_FW(ce->engine, RING_TIMESTAMP); i915_request_add(rq); local_bh_enable(); preempt_enable(); } err = intel_gt_wait_for_idle(ce->engine->gt, HZ / 2); if (err) goto err; for (i = 0; i < ARRAY_SIZE(elapsed); i++) elapsed[i] = sema[i] - elapsed[i]; cycles = trifilter(elapsed); pr_info("%s: idle dispatch latency %d cycles, %lluns\n", ce->engine->name, cycles >> TF_BIAS, cycles_to_ns(ce->engine, cycles)); return intel_gt_wait_for_idle(ce->engine->gt, HZ); err: intel_gt_set_wedged(ce->engine->gt); return err; } static int measure_busy_dispatch(struct intel_context *ce) { u32 *sema = hwsp_scratch(ce); const u32 offset = hwsp_offset(ce, sema); u32 elapsed[TF_COUNT + 1], cycles; u32 *cs; int err; int i; /* * Measure how long it takes for us to submit a request while the * engine is busy, polling on a semaphore in our context. With * direct submission, this will include the cost of a lite restore. * * A: read CS_TIMESTAMP from CPU * submit request * B: read CS_TIMESTAMP on GPU * * Submission latency: B - A */ for (i = 1; i <= ARRAY_SIZE(elapsed); i++) { struct i915_request *rq; rq = i915_request_create(ce); if (IS_ERR(rq)) { err = PTR_ERR(rq); goto err; } cs = intel_ring_begin(rq, 12); if (IS_ERR(cs)) { i915_request_add(rq); err = PTR_ERR(cs); goto err; } cs = emit_store_dw(cs, offset + i * sizeof(u32), -1); cs = emit_semaphore_poll_until(cs, offset, i); cs = emit_timestamp_store(cs, ce, offset + i * sizeof(u32)); intel_ring_advance(rq, cs); if (i > 1 && wait_for(READ_ONCE(sema[i - 1]), 500)) { err = -EIO; goto err; } preempt_disable(); local_bh_disable(); elapsed[i - 1] = ENGINE_READ_FW(ce->engine, RING_TIMESTAMP); i915_request_add(rq); local_bh_enable(); semaphore_set(sema, i - 1); preempt_enable(); } wait_for(READ_ONCE(sema[i - 1]), 500); semaphore_set(sema, i - 1); for (i = 1; i <= TF_COUNT; i++) { GEM_BUG_ON(sema[i] == -1); elapsed[i - 1] = sema[i] - elapsed[i]; } cycles = trifilter(elapsed); pr_info("%s: busy dispatch latency %d cycles, %lluns\n", ce->engine->name, cycles >> TF_BIAS, cycles_to_ns(ce->engine, cycles)); return intel_gt_wait_for_idle(ce->engine->gt, HZ); err: intel_gt_set_wedged(ce->engine->gt); return err; } static int plug(struct intel_engine_cs *engine, u32 *sema, u32 mode, int value) { const u32 offset = i915_ggtt_offset(engine->status_page.vma) + offset_in_page(sema); struct i915_request *rq; u32 *cs; rq = i915_request_create(engine->kernel_context); if (IS_ERR(rq)) return PTR_ERR(rq); cs = intel_ring_begin(rq, 4); if (IS_ERR(cs)) { i915_request_add(rq); return PTR_ERR(cs); } cs = emit_semaphore_poll(cs, mode, value, offset); intel_ring_advance(rq, cs); i915_request_add(rq); return 0; } static int measure_inter_request(struct intel_context *ce) { u32 *sema = hwsp_scratch(ce); const u32 offset = hwsp_offset(ce, sema); u32 elapsed[TF_COUNT + 1], cycles; struct i915_sw_fence *submit; int i, err; /* * Measure how long it takes to advance from one request into the * next. Between each request we flush the GPU caches to memory, * update the breadcrumbs, and then invalidate those caches. * We queue up all the requests to be submitted in one batch so * it should be one set of contiguous measurements. * * A: read CS_TIMESTAMP on GPU * advance request * B: read CS_TIMESTAMP on GPU * * Request latency: B - A */ err = plug(ce->engine, sema, MI_SEMAPHORE_SAD_NEQ_SDD, 0); if (err) return err; submit = heap_fence_create(GFP_KERNEL); if (!submit) { semaphore_set(sema, 1); return -ENOMEM; } intel_engine_flush_submission(ce->engine); for (i = 1; i <= ARRAY_SIZE(elapsed); i++) { struct i915_request *rq; u32 *cs; rq = i915_request_create(ce); if (IS_ERR(rq)) { err = PTR_ERR(rq); goto err_submit; } err = i915_sw_fence_await_sw_fence_gfp(&rq->submit, submit, GFP_KERNEL); if (err < 0) { i915_request_add(rq); goto err_submit; } cs = intel_ring_begin(rq, 4); if (IS_ERR(cs)) { i915_request_add(rq); err = PTR_ERR(cs); goto err_submit; } cs = emit_timestamp_store(cs, ce, offset + i * sizeof(u32)); intel_ring_advance(rq, cs); i915_request_add(rq); } i915_sw_fence_commit(submit); intel_engine_flush_submission(ce->engine); heap_fence_put(submit); semaphore_set(sema, 1); err = intel_gt_wait_for_idle(ce->engine->gt, HZ / 2); if (err) goto err; for (i = 1; i <= TF_COUNT; i++) elapsed[i - 1] = sema[i + 1] - sema[i]; cycles = trifilter(elapsed); pr_info("%s: inter-request latency %d cycles, %lluns\n", ce->engine->name, cycles >> TF_BIAS, cycles_to_ns(ce->engine, cycles)); return intel_gt_wait_for_idle(ce->engine->gt, HZ); err_submit: i915_sw_fence_commit(submit); heap_fence_put(submit); semaphore_set(sema, 1); err: intel_gt_set_wedged(ce->engine->gt); return err; } static int measure_context_switch(struct intel_context *ce) { u32 *sema = hwsp_scratch(ce); const u32 offset = hwsp_offset(ce, sema); struct i915_request *fence = NULL; u32 elapsed[TF_COUNT + 1], cycles; int i, j, err; u32 *cs; /* * Measure how long it takes to advance from one request in one * context to a request in another context. This allows us to * measure how long the context save/restore take, along with all * the inter-context setup we require. * * A: read CS_TIMESTAMP on GPU * switch context * B: read CS_TIMESTAMP on GPU * * Context switch latency: B - A */ err = plug(ce->engine, sema, MI_SEMAPHORE_SAD_NEQ_SDD, 0); if (err) return err; for (i = 1; i <= ARRAY_SIZE(elapsed); i++) { struct intel_context *arr[] = { ce, ce->engine->kernel_context }; u32 addr = offset + ARRAY_SIZE(arr) * i * sizeof(u32); for (j = 0; j < ARRAY_SIZE(arr); j++) { struct i915_request *rq; rq = i915_request_create(arr[j]); if (IS_ERR(rq)) { err = PTR_ERR(rq); goto err_fence; } if (fence) { err = i915_request_await_dma_fence(rq, &fence->fence); if (err) { i915_request_add(rq); goto err_fence; } } cs = intel_ring_begin(rq, 4); if (IS_ERR(cs)) { i915_request_add(rq); err = PTR_ERR(cs); goto err_fence; } cs = emit_timestamp_store(cs, ce, addr); addr += sizeof(u32); intel_ring_advance(rq, cs); i915_request_put(fence); fence = i915_request_get(rq); i915_request_add(rq); } } i915_request_put(fence); intel_engine_flush_submission(ce->engine); semaphore_set(sema, 1); err = intel_gt_wait_for_idle(ce->engine->gt, HZ / 2); if (err) goto err; for (i = 1; i <= TF_COUNT; i++) elapsed[i - 1] = sema[2 * i + 2] - sema[2 * i + 1]; cycles = trifilter(elapsed); pr_info("%s: context switch latency %d cycles, %lluns\n", ce->engine->name, cycles >> TF_BIAS, cycles_to_ns(ce->engine, cycles)); return intel_gt_wait_for_idle(ce->engine->gt, HZ); err_fence: i915_request_put(fence); semaphore_set(sema, 1); err: intel_gt_set_wedged(ce->engine->gt); return err; } static int measure_preemption(struct intel_context *ce) { u32 *sema = hwsp_scratch(ce); const u32 offset = hwsp_offset(ce, sema); u32 elapsed[TF_COUNT], cycles; u32 *cs; int err; int i; /* * We measure two latencies while triggering preemption. The first * latency is how long it takes for us to submit a preempting request. * The second latency is how it takes for us to return from the * preemption back to the original context. * * A: read CS_TIMESTAMP from CPU * submit preemption * B: read CS_TIMESTAMP on GPU (in preempting context) * context switch * C: read CS_TIMESTAMP on GPU (in original context) * * Preemption dispatch latency: B - A * Preemption switch latency: C - B */ if (!intel_engine_has_preemption(ce->engine)) return 0; for (i = 1; i <= ARRAY_SIZE(elapsed); i++) { u32 addr = offset + 2 * i * sizeof(u32); struct i915_request *rq; rq = i915_request_create(ce); if (IS_ERR(rq)) { err = PTR_ERR(rq); goto err; } cs = intel_ring_begin(rq, 12); if (IS_ERR(cs)) { i915_request_add(rq); err = PTR_ERR(cs); goto err; } cs = emit_store_dw(cs, addr, -1); cs = emit_semaphore_poll_until(cs, offset, i); cs = emit_timestamp_store(cs, ce, addr + sizeof(u32)); intel_ring_advance(rq, cs); i915_request_add(rq); if (wait_for(READ_ONCE(sema[2 * i]) == -1, 500)) { err = -EIO; goto err; } rq = i915_request_create(ce->engine->kernel_context); if (IS_ERR(rq)) { err = PTR_ERR(rq); goto err; } cs = intel_ring_begin(rq, 8); if (IS_ERR(cs)) { i915_request_add(rq); err = PTR_ERR(cs); goto err; } cs = emit_timestamp_store(cs, ce, addr); cs = emit_store_dw(cs, offset, i); intel_ring_advance(rq, cs); rq->sched.attr.priority = I915_PRIORITY_BARRIER; elapsed[i - 1] = ENGINE_READ_FW(ce->engine, RING_TIMESTAMP); i915_request_add(rq); } if (wait_for(READ_ONCE(sema[2 * i - 2]) != -1, 500)) { err = -EIO; goto err; } for (i = 1; i <= TF_COUNT; i++) elapsed[i - 1] = sema[2 * i + 0] - elapsed[i - 1]; cycles = trifilter(elapsed); pr_info("%s: preemption dispatch latency %d cycles, %lluns\n", ce->engine->name, cycles >> TF_BIAS, cycles_to_ns(ce->engine, cycles)); for (i = 1; i <= TF_COUNT; i++) elapsed[i - 1] = sema[2 * i + 1] - sema[2 * i + 0]; cycles = trifilter(elapsed); pr_info("%s: preemption switch latency %d cycles, %lluns\n", ce->engine->name, cycles >> TF_BIAS, cycles_to_ns(ce->engine, cycles)); return intel_gt_wait_for_idle(ce->engine->gt, HZ); err: intel_gt_set_wedged(ce->engine->gt); return err; } struct signal_cb { struct dma_fence_cb base; bool seen; }; static void signal_cb(struct dma_fence *fence, struct dma_fence_cb *cb) { struct signal_cb *s = container_of(cb, typeof(*s), base); smp_store_mb(s->seen, true); /* be safe, be strong */ } static int measure_completion(struct intel_context *ce) { u32 *sema = hwsp_scratch(ce); const u32 offset = hwsp_offset(ce, sema); u32 elapsed[TF_COUNT], cycles; u32 *cs; int err; int i; /* * Measure how long it takes for the signal (interrupt) to be * sent from the GPU to be processed by the CPU. * * A: read CS_TIMESTAMP on GPU * signal * B: read CS_TIMESTAMP from CPU * * Completion latency: B - A */ for (i = 1; i <= ARRAY_SIZE(elapsed); i++) { struct signal_cb cb = { .seen = false }; struct i915_request *rq; rq = i915_request_create(ce); if (IS_ERR(rq)) { err = PTR_ERR(rq); goto err; } cs = intel_ring_begin(rq, 12); if (IS_ERR(cs)) { i915_request_add(rq); err = PTR_ERR(cs); goto err; } cs = emit_store_dw(cs, offset + i * sizeof(u32), -1); cs = emit_semaphore_poll_until(cs, offset, i); cs = emit_timestamp_store(cs, ce, offset + i * sizeof(u32)); intel_ring_advance(rq, cs); dma_fence_add_callback(&rq->fence, &cb.base, signal_cb); i915_request_add(rq); intel_engine_flush_submission(ce->engine); if (wait_for(READ_ONCE(sema[i]) == -1, 50)) { err = -EIO; goto err; } preempt_disable(); semaphore_set(sema, i); while (!READ_ONCE(cb.seen)) cpu_relax(); elapsed[i - 1] = ENGINE_READ_FW(ce->engine, RING_TIMESTAMP); preempt_enable(); } err = intel_gt_wait_for_idle(ce->engine->gt, HZ / 2); if (err) goto err; for (i = 0; i < ARRAY_SIZE(elapsed); i++) { GEM_BUG_ON(sema[i + 1] == -1); elapsed[i] = elapsed[i] - sema[i + 1]; } cycles = trifilter(elapsed); pr_info("%s: completion latency %d cycles, %lluns\n", ce->engine->name, cycles >> TF_BIAS, cycles_to_ns(ce->engine, cycles)); return intel_gt_wait_for_idle(ce->engine->gt, HZ); err: intel_gt_set_wedged(ce->engine->gt); return err; } static void rps_pin(struct intel_gt *gt) { /* Pin the frequency to max */ atomic_inc(>->rps.num_waiters); intel_uncore_forcewake_get(gt->uncore, FORCEWAKE_ALL); mutex_lock(>->rps.lock); intel_rps_set(>->rps, gt->rps.max_freq); mutex_unlock(>->rps.lock); } static void rps_unpin(struct intel_gt *gt) { intel_uncore_forcewake_put(gt->uncore, FORCEWAKE_ALL); atomic_dec(>->rps.num_waiters); } static int perf_request_latency(void *arg) { struct drm_i915_private *i915 = arg; struct intel_engine_cs *engine; struct pm_qos_request qos; int err = 0; if (GRAPHICS_VER(i915) < 8) /* per-engine CS timestamp, semaphores */ return 0; cpu_latency_qos_add_request(&qos, 0); /* disable cstates */ for_each_uabi_engine(engine, i915) { struct intel_context *ce; ce = intel_context_create(engine); if (IS_ERR(ce)) { err = PTR_ERR(ce); goto out; } err = intel_context_pin(ce); if (err) { intel_context_put(ce); goto out; } st_engine_heartbeat_disable(engine); rps_pin(engine->gt); if (err == 0) err = measure_semaphore_response(ce); if (err == 0) err = measure_idle_dispatch(ce); if (err == 0) err = measure_busy_dispatch(ce); if (err == 0) err = measure_inter_request(ce); if (err == 0) err = measure_context_switch(ce); if (err == 0) err = measure_preemption(ce); if (err == 0) err = measure_completion(ce); rps_unpin(engine->gt); st_engine_heartbeat_enable(engine); intel_context_unpin(ce); intel_context_put(ce); if (err) goto out; } out: if (igt_flush_test(i915)) err = -EIO; cpu_latency_qos_remove_request(&qos); return err; } static int s_sync0(void *arg) { struct perf_series *ps = arg; IGT_TIMEOUT(end_time); unsigned int idx = 0; int err = 0; GEM_BUG_ON(!ps->nengines); do { struct i915_request *rq; rq = i915_request_create(ps->ce[idx]); if (IS_ERR(rq)) { err = PTR_ERR(rq); break; } i915_request_get(rq); i915_request_add(rq); if (i915_request_wait(rq, 0, HZ / 5) < 0) err = -ETIME; i915_request_put(rq); if (err) break; if (++idx == ps->nengines) idx = 0; } while (!__igt_timeout(end_time, NULL)); return err; } static int s_sync1(void *arg) { struct perf_series *ps = arg; struct i915_request *prev = NULL; IGT_TIMEOUT(end_time); unsigned int idx = 0; int err = 0; GEM_BUG_ON(!ps->nengines); do { struct i915_request *rq; rq = i915_request_create(ps->ce[idx]); if (IS_ERR(rq)) { err = PTR_ERR(rq); break; } i915_request_get(rq); i915_request_add(rq); if (prev && i915_request_wait(prev, 0, HZ / 5) < 0) err = -ETIME; i915_request_put(prev); prev = rq; if (err) break; if (++idx == ps->nengines) idx = 0; } while (!__igt_timeout(end_time, NULL)); i915_request_put(prev); return err; } static int s_many(void *arg) { struct perf_series *ps = arg; IGT_TIMEOUT(end_time); unsigned int idx = 0; GEM_BUG_ON(!ps->nengines); do { struct i915_request *rq; rq = i915_request_create(ps->ce[idx]); if (IS_ERR(rq)) return PTR_ERR(rq); i915_request_add(rq); if (++idx == ps->nengines) idx = 0; } while (!__igt_timeout(end_time, NULL)); return 0; } static int perf_series_engines(void *arg) { struct drm_i915_private *i915 = arg; static int (* const func[])(void *arg) = { s_sync0, s_sync1, s_many, NULL, }; const unsigned int nengines = num_uabi_engines(i915); struct intel_engine_cs *engine; int (* const *fn)(void *arg); struct pm_qos_request qos; struct perf_stats *stats; struct perf_series *ps; unsigned int idx; int err = 0; stats = kcalloc(nengines, sizeof(*stats), GFP_KERNEL); if (!stats) return -ENOMEM; ps = kzalloc(struct_size(ps, ce, nengines), GFP_KERNEL); if (!ps) { kfree(stats); return -ENOMEM; } cpu_latency_qos_add_request(&qos, 0); /* disable cstates */ ps->i915 = i915; ps->nengines = nengines; idx = 0; for_each_uabi_engine(engine, i915) { struct intel_context *ce; ce = intel_context_create(engine); if (IS_ERR(ce)) { err = PTR_ERR(ce); goto out; } err = intel_context_pin(ce); if (err) { intel_context_put(ce); goto out; } ps->ce[idx++] = ce; } GEM_BUG_ON(idx != ps->nengines); for (fn = func; *fn && !err; fn++) { char name[KSYM_NAME_LEN]; struct igt_live_test t; snprintf(name, sizeof(name), "%ps", *fn); err = igt_live_test_begin(&t, i915, __func__, name); if (err) break; for (idx = 0; idx < nengines; idx++) { struct perf_stats *p = memset(&stats[idx], 0, sizeof(stats[idx])); struct intel_context *ce = ps->ce[idx]; p->engine = ps->ce[idx]->engine; intel_engine_pm_get(p->engine); if (intel_engine_supports_stats(p->engine)) p->busy = intel_engine_get_busy_time(p->engine, &p->time) + 1; else p->time = ktime_get(); p->runtime = -intel_context_get_total_runtime_ns(ce); } err = (*fn)(ps); if (igt_live_test_end(&t)) err = -EIO; for (idx = 0; idx < nengines; idx++) { struct perf_stats *p = &stats[idx]; struct intel_context *ce = ps->ce[idx]; int integer, decimal; u64 busy, dt, now; if (p->busy) p->busy = ktime_sub(intel_engine_get_busy_time(p->engine, &now), p->busy - 1); else now = ktime_get(); p->time = ktime_sub(now, p->time); err = switch_to_kernel_sync(ce, err); p->runtime += intel_context_get_total_runtime_ns(ce); intel_engine_pm_put(p->engine); busy = 100 * ktime_to_ns(p->busy); dt = ktime_to_ns(p->time); if (dt) { integer = div64_u64(busy, dt); busy -= integer * dt; decimal = div64_u64(100 * busy, dt); } else { integer = 0; decimal = 0; } pr_info("%s %5s: { seqno:%d, busy:%d.%02d%%, runtime:%lldms, walltime:%lldms }\n", name, p->engine->name, ce->timeline->seqno, integer, decimal, div_u64(p->runtime, 1000 * 1000), div_u64(ktime_to_ns(p->time), 1000 * 1000)); } } out: for (idx = 0; idx < nengines; idx++) { if (IS_ERR_OR_NULL(ps->ce[idx])) break; intel_context_unpin(ps->ce[idx]); intel_context_put(ps->ce[idx]); } kfree(ps); cpu_latency_qos_remove_request(&qos); kfree(stats); return err; } struct p_thread { struct perf_stats p; struct kthread_worker *worker; struct kthread_work work; struct intel_engine_cs *engine; int result; }; static void p_sync0(struct kthread_work *work) { struct p_thread *thread = container_of(work, typeof(*thread), work); struct perf_stats *p = &thread->p; struct intel_engine_cs *engine = p->engine; struct intel_context *ce; IGT_TIMEOUT(end_time); unsigned long count; bool busy; int err = 0; ce = intel_context_create(engine); if (IS_ERR(ce)) { thread->result = PTR_ERR(ce); return; } err = intel_context_pin(ce); if (err) { intel_context_put(ce); thread->result = err; return; } if (intel_engine_supports_stats(engine)) { p->busy = intel_engine_get_busy_time(engine, &p->time); busy = true; } else { p->time = ktime_get(); busy = false; } count = 0; do { struct i915_request *rq; rq = i915_request_create(ce); if (IS_ERR(rq)) { err = PTR_ERR(rq); break; } i915_request_get(rq); i915_request_add(rq); err = 0; if (i915_request_wait(rq, 0, HZ) < 0) err = -ETIME; i915_request_put(rq); if (err) break; count++; } while (!__igt_timeout(end_time, NULL)); if (busy) { ktime_t now; p->busy = ktime_sub(intel_engine_get_busy_time(engine, &now), p->busy); p->time = ktime_sub(now, p->time); } else { p->time = ktime_sub(ktime_get(), p->time); } err = switch_to_kernel_sync(ce, err); p->runtime = intel_context_get_total_runtime_ns(ce); p->count = count; intel_context_unpin(ce); intel_context_put(ce); thread->result = err; } static void p_sync1(struct kthread_work *work) { struct p_thread *thread = container_of(work, typeof(*thread), work); struct perf_stats *p = &thread->p; struct intel_engine_cs *engine = p->engine; struct i915_request *prev = NULL; struct intel_context *ce; IGT_TIMEOUT(end_time); unsigned long count; bool busy; int err = 0; ce = intel_context_create(engine); if (IS_ERR(ce)) { thread->result = PTR_ERR(ce); return; } err = intel_context_pin(ce); if (err) { intel_context_put(ce); thread->result = err; return; } if (intel_engine_supports_stats(engine)) { p->busy = intel_engine_get_busy_time(engine, &p->time); busy = true; } else { p->time = ktime_get(); busy = false; } count = 0; do { struct i915_request *rq; rq = i915_request_create(ce); if (IS_ERR(rq)) { err = PTR_ERR(rq); break; } i915_request_get(rq); i915_request_add(rq); err = 0; if (prev && i915_request_wait(prev, 0, HZ) < 0) err = -ETIME; i915_request_put(prev); prev = rq; if (err) break; count++; } while (!__igt_timeout(end_time, NULL)); i915_request_put(prev); if (busy) { ktime_t now; p->busy = ktime_sub(intel_engine_get_busy_time(engine, &now), p->busy); p->time = ktime_sub(now, p->time); } else { p->time = ktime_sub(ktime_get(), p->time); } err = switch_to_kernel_sync(ce, err); p->runtime = intel_context_get_total_runtime_ns(ce); p->count = count; intel_context_unpin(ce); intel_context_put(ce); thread->result = err; } static void p_many(struct kthread_work *work) { struct p_thread *thread = container_of(work, typeof(*thread), work); struct perf_stats *p = &thread->p; struct intel_engine_cs *engine = p->engine; struct intel_context *ce; IGT_TIMEOUT(end_time); unsigned long count; int err = 0; bool busy; ce = intel_context_create(engine); if (IS_ERR(ce)) { thread->result = PTR_ERR(ce); return; } err = intel_context_pin(ce); if (err) { intel_context_put(ce); thread->result = err; return; } if (intel_engine_supports_stats(engine)) { p->busy = intel_engine_get_busy_time(engine, &p->time); busy = true; } else { p->time = ktime_get(); busy = false; } count = 0; do { struct i915_request *rq; rq = i915_request_create(ce); if (IS_ERR(rq)) { err = PTR_ERR(rq); break; } i915_request_add(rq); count++; } while (!__igt_timeout(end_time, NULL)); if (busy) { ktime_t now; p->busy = ktime_sub(intel_engine_get_busy_time(engine, &now), p->busy); p->time = ktime_sub(now, p->time); } else { p->time = ktime_sub(ktime_get(), p->time); } err = switch_to_kernel_sync(ce, err); p->runtime = intel_context_get_total_runtime_ns(ce); p->count = count; intel_context_unpin(ce); intel_context_put(ce); thread->result = err; } static int perf_parallel_engines(void *arg) { struct drm_i915_private *i915 = arg; static void (* const func[])(struct kthread_work *) = { p_sync0, p_sync1, p_many, NULL, }; const unsigned int nengines = num_uabi_engines(i915); void (* const *fn)(struct kthread_work *); struct intel_engine_cs *engine; struct pm_qos_request qos; struct p_thread *engines; int err = 0; engines = kcalloc(nengines, sizeof(*engines), GFP_KERNEL); if (!engines) return -ENOMEM; cpu_latency_qos_add_request(&qos, 0); for (fn = func; *fn; fn++) { char name[KSYM_NAME_LEN]; struct igt_live_test t; unsigned int idx; snprintf(name, sizeof(name), "%ps", *fn); err = igt_live_test_begin(&t, i915, __func__, name); if (err) break; atomic_set(&i915->selftest.counter, nengines); idx = 0; for_each_uabi_engine(engine, i915) { struct kthread_worker *worker; intel_engine_pm_get(engine); memset(&engines[idx].p, 0, sizeof(engines[idx].p)); worker = kthread_create_worker(0, "igt:%s", engine->name); if (IS_ERR(worker)) { err = PTR_ERR(worker); intel_engine_pm_put(engine); break; } engines[idx].worker = worker; engines[idx].result = 0; engines[idx].p.engine = engine; engines[idx].engine = engine; kthread_init_work(&engines[idx].work, *fn); kthread_queue_work(worker, &engines[idx].work); idx++; } idx = 0; for_each_uabi_engine(engine, i915) { int status; if (!engines[idx].worker) break; kthread_flush_work(&engines[idx].work); status = READ_ONCE(engines[idx].result); if (status && !err) err = status; intel_engine_pm_put(engine); kthread_destroy_worker(engines[idx].worker); idx++; } if (igt_live_test_end(&t)) err = -EIO; if (err) break; idx = 0; for_each_uabi_engine(engine, i915) { struct perf_stats *p = &engines[idx].p; u64 busy = 100 * ktime_to_ns(p->busy); u64 dt = ktime_to_ns(p->time); int integer, decimal; if (dt) { integer = div64_u64(busy, dt); busy -= integer * dt; decimal = div64_u64(100 * busy, dt); } else { integer = 0; decimal = 0; } GEM_BUG_ON(engine != p->engine); pr_info("%s %5s: { count:%lu, busy:%d.%02d%%, runtime:%lldms, walltime:%lldms }\n", name, engine->name, p->count, integer, decimal, div_u64(p->runtime, 1000 * 1000), div_u64(ktime_to_ns(p->time), 1000 * 1000)); idx++; } } cpu_latency_qos_remove_request(&qos); kfree(engines); return err; } int i915_request_perf_selftests(struct drm_i915_private *i915) { static const struct i915_subtest tests[] = { SUBTEST(perf_request_latency), SUBTEST(perf_series_engines), SUBTEST(perf_parallel_engines), }; if (intel_gt_is_wedged(to_gt(i915))) return 0; return i915_subtests(tests, i915); }