/* * Copyright © 2016 Collabora, Ltd. * * 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. * * Authors: * Robert Foss */ #include #include #include #include #include #include #include "igt.h" #include "igt_aux.h" #include "igt_primes.h" #include "sw_sync.h" IGT_TEST_DESCRIPTION("Test SW Sync Framework"); typedef struct { int timeline; uint32_t thread_id; uint32_t *counter; sem_t *sem; } data_t; static void test_alloc_timeline(void) { int timeline; timeline = sw_sync_timeline_create(); close(timeline); } static void test_alloc_fence(void) { int in_fence; int timeline; timeline = sw_sync_timeline_create(); in_fence = sw_sync_timeline_create_fence(timeline, 0); close(in_fence); close(timeline); } static void test_alloc_fence_invalid_timeline(void) { igt_assert_f(__sw_sync_timeline_create_fence(-1, 0) < 0, "Did not fail to create fence on invalid timeline\n"); } static void test_timeline_closed(void) { int fence; int timeline; timeline = sw_sync_timeline_create(); fence = sw_sync_timeline_create_fence(timeline, 1); close(timeline); igt_assert_f(sync_fence_wait(fence, 0) == 0, "Failure waiting on unsignaled fence on closed timeline\n"); igt_assert_f(sync_fence_status(fence) == -ENOENT, "Failure in marking up an unsignaled fence on closed timeline\n"); } static void test_timeline_closed_signaled(void) { int fence; int timeline; timeline = sw_sync_timeline_create(); fence = sw_sync_timeline_create_fence(timeline, 1); sw_sync_timeline_inc(timeline, 1); close(timeline); igt_assert_f(sync_fence_wait(fence, 0) == 0, "Failure waiting on signaled fence for closed timeline\n"); } static void test_alloc_merge_fence(void) { int in_fence[2]; int fence_merge; int timeline[2]; timeline[0] = sw_sync_timeline_create(); timeline[1] = sw_sync_timeline_create(); in_fence[0] = sw_sync_timeline_create_fence(timeline[0], 1); in_fence[1] = sw_sync_timeline_create_fence(timeline[1], 1); fence_merge = sync_fence_merge(in_fence[1], in_fence[0]); close(in_fence[0]); close(in_fence[1]); close(fence_merge); close(timeline[0]); close(timeline[1]); } static void test_sync_busy(void) { int fence; int timeline; int seqno; timeline = sw_sync_timeline_create(); fence = sw_sync_timeline_create_fence(timeline, 5); /* Make sure that fence has not been signaled yet */ igt_assert_f(sync_fence_wait(fence, 0) == -ETIME, "Fence signaled early (timeline value 0, fence seqno 5)\n"); /* Advance timeline from 0 -> 1 */ sw_sync_timeline_inc(timeline, 1); /* Make sure that fence has not been signaled yet */ igt_assert_f(sync_fence_wait(fence, 0) == -ETIME, "Fence signaled early (timeline value 1, fence seqno 5)\n"); /* Advance timeline from 1 -> 5: signaling the fence (seqno 5)*/ sw_sync_timeline_inc(timeline, 4); igt_assert_f(sync_fence_wait(fence, 0) == 0, "Fence not signaled (timeline value 5, fence seqno 5)\n"); /* Go even further, and confirm wait still succeeds */ sw_sync_timeline_inc(timeline, 5); igt_assert_f(sync_fence_wait(fence, 0) == 0, "Fence not signaled (timeline value 10, fence seqno 5)\n"); seqno = 10; for_each_prime_number(prime, 100) { int fence_prime; seqno += prime; fence_prime = sw_sync_timeline_create_fence(timeline, seqno); sw_sync_timeline_inc(timeline, prime); igt_assert_f(sync_fence_wait(fence_prime, 0) == 0, "Fence not signaled during test of prime timeline increments\n"); close(fence_prime); } close(fence); close(timeline); } static void test_sync_busy_fork_unixsocket(void) { int fence; int timeline; int sv[2]; igt_require(socketpair(AF_UNIX, SOCK_DGRAM, 0, sv) == 0); timeline = sw_sync_timeline_create(); fence = sw_sync_timeline_create_fence(timeline, 1); igt_fork(child, 1) { /* Child process */ int socket = sv[1]; int socket_timeline; struct msghdr msg = {0}; struct cmsghdr *cmsg; unsigned char *data; char m_buffer[256]; char c_buffer[256]; struct iovec io = { .iov_base = m_buffer, .iov_len = sizeof(m_buffer) }; close(sv[0]); msg.msg_iov = &io; msg.msg_iovlen = 1; msg.msg_control = c_buffer; msg.msg_controllen = sizeof(c_buffer); igt_assert(recvmsg(socket, &msg, 0) > 0); cmsg = CMSG_FIRSTHDR(&msg); data = CMSG_DATA(cmsg); socket_timeline = *((int *) data); /* Advance timeline from 0 -> 1 */ sw_sync_timeline_inc(socket_timeline, 1); } { /* Parent process */ int socket = sv[0]; struct cmsghdr *cmsg; struct iovec io = { .iov_base = (char *)"ABC", .iov_len = 3 }; struct msghdr msg = { 0 }; char buf[CMSG_SPACE(sizeof(timeline))]; memset(buf, '\0', sizeof(buf)); close(sv[1]); msg.msg_iov = &io; msg.msg_iovlen = 1; msg.msg_control = buf; msg.msg_controllen = sizeof(buf); cmsg = CMSG_FIRSTHDR(&msg); cmsg->cmsg_level = SOL_SOCKET; cmsg->cmsg_type = SCM_RIGHTS; cmsg->cmsg_len = CMSG_LEN(sizeof(timeline)); *((int *) CMSG_DATA(cmsg)) = timeline; msg.msg_controllen = cmsg->cmsg_len; igt_assert_f(sync_fence_wait(fence, 0) == -ETIME, "Fence signaled (it should not have been signalled yet)\n"); igt_assert(sendmsg(socket, &msg, 0) > 0); igt_assert_f(sync_fence_wait(fence, 2*1000) == 0, "Fence not signaled (timeline value 1 fence seqno 1)\n"); } igt_waitchildren(); close(fence); close(timeline); } static void test_sync_busy_fork(void) { int timeline = sw_sync_timeline_create(); int fence = sw_sync_timeline_create_fence(timeline, 1); igt_assert_f(sync_fence_wait(fence, 0) == -ETIME, "Fence signaled (it should not have been signalled yet)\n"); igt_fork(child, 1) { usleep(1*1000*1000); /* Advance timeline from 0 -> 1 */ sw_sync_timeline_inc(timeline, 1); } igt_assert_f(sync_fence_wait(fence, 2*1000) == 0, "Fence not signaled (timeline value 1 fence seqno 1)\n"); igt_waitchildren(); close(fence); close(timeline); } static void test_sync_merge_invalid(void) { int in_fence; int fence_invalid; int fence_merge; int timeline; char tmppath[] = "/tmp/igt-XXXXXX"; int skip = 0; timeline = sw_sync_timeline_create(); in_fence = sw_sync_timeline_create_fence(timeline, 1); fence_invalid = -1; fence_merge = sync_fence_merge(in_fence, fence_invalid); igt_assert_f(fence_merge < 0, "Verify invalid fd (-1) handling"); fence_invalid = drm_open_driver(DRIVER_ANY); fence_merge = sync_fence_merge(in_fence, fence_invalid); igt_assert_f(fence_merge < 0, "Verify invalid fd (device fd) handling"); fence_invalid = mkstemp(tmppath); if (fence_invalid == -1) { skip = 1; goto out; } unlink(tmppath); fence_invalid = drm_open_driver(DRIVER_ANY); fence_merge = sync_fence_merge(in_fence, fence_invalid); close(fence_invalid); igt_assert_f(fence_merge < 0, "Verify invalid fd (file fd) handling"); out: close(in_fence); close(fence_merge); close(timeline); igt_require(skip == 0); } static void test_sync_merge(void) { int in_fence[3]; int fence_merge; int timeline; int active, signaled; timeline = sw_sync_timeline_create(); in_fence[0] = sw_sync_timeline_create_fence(timeline, 1); in_fence[1] = sw_sync_timeline_create_fence(timeline, 2); in_fence[2] = sw_sync_timeline_create_fence(timeline, 3); fence_merge = sync_fence_merge(in_fence[0], in_fence[1]); fence_merge = sync_fence_merge(in_fence[2], fence_merge); /* confirm all fences have one active point (even d) */ active = sync_fence_count_status(in_fence[0], SW_SYNC_FENCE_STATUS_ACTIVE); igt_assert_f(active == 1, "in_fence[0] has too many active fences\n"); active = sync_fence_count_status(in_fence[1], SW_SYNC_FENCE_STATUS_ACTIVE); igt_assert_f(active == 1, "in_fence[1] has too many active fences\n"); active = sync_fence_count_status(in_fence[2], SW_SYNC_FENCE_STATUS_ACTIVE); igt_assert_f(active == 1, "in_fence[2] has too many active fences\n"); active = sync_fence_count_status(fence_merge, SW_SYNC_FENCE_STATUS_ACTIVE); igt_assert_f(active == 1, "fence_merge has too many active fences\n"); /* confirm that fence_merge is not signaled until the max of fence 0,1,2 */ sw_sync_timeline_inc(timeline, 1); signaled = sync_fence_count_status(in_fence[0], SW_SYNC_FENCE_STATUS_SIGNALED); active = sync_fence_count_status(fence_merge, SW_SYNC_FENCE_STATUS_ACTIVE); igt_assert_f(signaled == 1, "in_fence[0] did not signal\n"); igt_assert_f(active == 1, "fence_merge signaled too early\n"); sw_sync_timeline_inc(timeline, 1); signaled = sync_fence_count_status(in_fence[1], SW_SYNC_FENCE_STATUS_SIGNALED); active = sync_fence_count_status(fence_merge, SW_SYNC_FENCE_STATUS_ACTIVE); igt_assert_f(signaled == 1, "in_fence[1] did not signal\n"); igt_assert_f(active == 1, "fence_merge signaled too early\n"); sw_sync_timeline_inc(timeline, 1); signaled = sync_fence_count_status(in_fence[2], SW_SYNC_FENCE_STATUS_SIGNALED); igt_assert_f(signaled == 1, "in_fence[2] did not signal\n"); signaled = sync_fence_count_status(fence_merge, SW_SYNC_FENCE_STATUS_SIGNALED); active = sync_fence_count_status(fence_merge, SW_SYNC_FENCE_STATUS_ACTIVE); igt_assert_f(active == 0 && signaled == 1, "fence_merge did not signal\n"); close(in_fence[0]); close(in_fence[1]); close(in_fence[2]); close(fence_merge); close(timeline); } static void test_sync_merge_same(void) { int in_fence[2]; int timeline; int signaled; timeline = sw_sync_timeline_create(); in_fence[0] = sw_sync_timeline_create_fence(timeline, 1); in_fence[1] = sync_fence_merge(in_fence[0], in_fence[0]); signaled = sync_fence_count_status(in_fence[0], SW_SYNC_FENCE_STATUS_SIGNALED); igt_assert_f(signaled == 0, "Fence signaled too early\n"); sw_sync_timeline_inc(timeline, 1); signaled = sync_fence_count_status(in_fence[0], SW_SYNC_FENCE_STATUS_SIGNALED); igt_assert_f(signaled == 1, "Fence did not signal\n"); close(in_fence[0]); close(in_fence[1]); close(timeline); } static void test_sync_multi_timeline_wait(void) { int timeline[3]; int in_fence[3]; int fence_merge; int active, signaled; timeline[0] = sw_sync_timeline_create(); timeline[1] = sw_sync_timeline_create(); timeline[2] = sw_sync_timeline_create(); in_fence[0] = sw_sync_timeline_create_fence(timeline[0], 5); in_fence[1] = sw_sync_timeline_create_fence(timeline[1], 5); in_fence[2] = sw_sync_timeline_create_fence(timeline[2], 5); fence_merge = sync_fence_merge(in_fence[0], in_fence[1]); fence_merge = sync_fence_merge(in_fence[2], fence_merge); /* Confirm fence isn't signaled */ active = sync_fence_count_status(fence_merge, SW_SYNC_FENCE_STATUS_ACTIVE); igt_assert_f(active == 3, "Fence signaled too early\n"); igt_assert_f(sync_fence_wait(fence_merge, 0) == -ETIME, "Failure waiting on fence until timeout\n"); sw_sync_timeline_inc(timeline[0], 5); active = sync_fence_count_status(fence_merge, SW_SYNC_FENCE_STATUS_ACTIVE); signaled = sync_fence_count_status(fence_merge, SW_SYNC_FENCE_STATUS_SIGNALED); igt_assert_f(active == 2 && signaled == 1, "Fence did not signal properly\n"); sw_sync_timeline_inc(timeline[1], 5); active = sync_fence_count_status(fence_merge, SW_SYNC_FENCE_STATUS_ACTIVE); signaled = sync_fence_count_status(fence_merge, SW_SYNC_FENCE_STATUS_SIGNALED); igt_assert_f(active == 1 && signaled == 2, "Fence did not signal properly\n"); sw_sync_timeline_inc(timeline[2], 5); active = sync_fence_count_status(fence_merge, SW_SYNC_FENCE_STATUS_ACTIVE); signaled = sync_fence_count_status(fence_merge, SW_SYNC_FENCE_STATUS_SIGNALED); igt_assert_f(active == 0 && signaled == 3, "Fence did not signal properly\n"); /* confirm you can successfully wait */ igt_assert_f(sync_fence_wait(fence_merge, 100) == 0, "Failure waiting on signaled fence\n"); close(in_fence[0]); close(in_fence[1]); close(in_fence[2]); close(fence_merge); close(timeline[0]); close(timeline[1]); close(timeline[2]); } #define MULTI_CONSUMER_THREADS 8 #define MULTI_CONSUMER_ITERATIONS (1 << 14) static void * test_sync_multi_consumer_thread(void *arg) { data_t *data = arg; int thread_id = data->thread_id; int timeline = data->timeline; int i; for (i = 0; i < MULTI_CONSUMER_ITERATIONS; i++) { int next_point = i * MULTI_CONSUMER_THREADS + thread_id; int fence = sw_sync_timeline_create_fence(timeline, next_point); if (sync_fence_wait(fence, 1000) < 0) return (void *) 1; if (READ_ONCE(*data->counter) != next_point) return (void *) 1; sem_post(data->sem); close(fence); } return NULL; } static void test_sync_multi_consumer(void) { data_t data_arr[MULTI_CONSUMER_THREADS]; pthread_t thread_arr[MULTI_CONSUMER_THREADS]; sem_t sem; int timeline; uint32_t counter = 0; uintptr_t thread_ret = 0; data_t data; int i, ret; sem_init(&sem, 0, 0); timeline = sw_sync_timeline_create(); data.counter = &counter; data.timeline = timeline; data.sem = &sem; /* Start sync threads. */ for (i = 0; i < MULTI_CONSUMER_THREADS; i++) { data_arr[i] = data; data_arr[i].thread_id = i; ret = pthread_create(&thread_arr[i], NULL, test_sync_multi_consumer_thread, (void *) &(data_arr[i])); igt_assert_eq(ret, 0); } /* Produce 'content'. */ for (i = 0; i < MULTI_CONSUMER_THREADS * MULTI_CONSUMER_ITERATIONS; i++) { sem_wait(&sem); __sync_fetch_and_add(&counter, 1); sw_sync_timeline_inc(timeline, 1); } /* Wait for threads to complete. */ for (i = 0; i < MULTI_CONSUMER_THREADS; i++) { uintptr_t local_thread_ret; pthread_join(thread_arr[i], (void **)&local_thread_ret); thread_ret |= local_thread_ret; } close(timeline); sem_destroy(&sem); igt_assert_eq(counter, MULTI_CONSUMER_THREADS * MULTI_CONSUMER_ITERATIONS); igt_assert_f(thread_ret == 0, "A sync thread reported failure.\n"); } #define MULTI_CONSUMER_PRODUCER_THREADS 8 #define MULTI_CONSUMER_PRODUCER_ITERATIONS (1 << 14) static void * test_sync_multi_consumer_producer_thread(void *arg) { data_t *data = arg; int thread_id = data->thread_id; int timeline = data->timeline; int i; for (i = 0; i < MULTI_CONSUMER_PRODUCER_ITERATIONS; i++) { int next_point = i * MULTI_CONSUMER_PRODUCER_THREADS + thread_id; int fence = sw_sync_timeline_create_fence(timeline, next_point); if (sync_fence_wait(fence, 1000) < 0) return (void *) 1; if (__sync_fetch_and_add(data->counter, 1) != next_point) return (void *) 1; /* Kick off the next thread. */ sw_sync_timeline_inc(timeline, 1); close(fence); } return NULL; } static void test_sync_multi_consumer_producer(void) { data_t data_arr[MULTI_CONSUMER_PRODUCER_THREADS]; pthread_t thread_arr[MULTI_CONSUMER_PRODUCER_THREADS]; int timeline; uint32_t counter = 0; uintptr_t thread_ret = 0; data_t data; int i, ret; timeline = sw_sync_timeline_create(); data.counter = &counter; data.timeline = timeline; /* Start consumer threads. */ for (i = 0; i < MULTI_CONSUMER_PRODUCER_THREADS; i++) { data_arr[i] = data; data_arr[i].thread_id = i; ret = pthread_create(&thread_arr[i], NULL, test_sync_multi_consumer_producer_thread, (void *) &(data_arr[i])); igt_assert_eq(ret, 0); } /* Wait for threads to complete. */ for (i = 0; i < MULTI_CONSUMER_PRODUCER_THREADS; i++) { uintptr_t local_thread_ret; pthread_join(thread_arr[i], (void **)&local_thread_ret); thread_ret |= local_thread_ret; } close(timeline); igt_assert_eq(counter, MULTI_CONSUMER_PRODUCER_THREADS * MULTI_CONSUMER_PRODUCER_ITERATIONS); igt_assert_f(thread_ret == 0, "A sync thread reported failure.\n"); } static int test_mspc_wait_on_fence(int fence) { int error, active; do { error = sync_fence_count_status(fence, SW_SYNC_FENCE_STATUS_ERROR); igt_assert_f(error == 0, "Error occurred on fence\n"); active = sync_fence_count_status(fence, SW_SYNC_FENCE_STATUS_ACTIVE); } while (active); return 0; } static struct { int iterations; int threads; int counter; int cons_timeline; int *prod_timeline; pthread_mutex_t lock; } test_mpsc_data; static void *mpsc_producer_thread(void *d) { int id = (long)d; int fence, i; int *prod_timeline = test_mpsc_data.prod_timeline; int cons_timeline = test_mpsc_data.cons_timeline; int iterations = test_mpsc_data.iterations; for (i = 0; i < iterations; i++) { fence = sw_sync_timeline_create_fence(cons_timeline, i); /* Wait for the consumer to finish. Use alternate * means of waiting on the fence */ if ((iterations + id) % 8 != 0) { igt_assert_f(sync_fence_wait(fence, -1) == 0, "Failure waiting on fence\n"); } else { igt_assert_f(test_mspc_wait_on_fence(fence) == 0, "Failure waiting on fence\n"); } /* Every producer increments the counter, the consumer * checks and erases it */ pthread_mutex_lock(&test_mpsc_data.lock); test_mpsc_data.counter++; pthread_mutex_unlock(&test_mpsc_data.lock); sw_sync_timeline_inc(prod_timeline[id], 1); close(fence); } return NULL; } static int mpsc_consumer_thread(void) { int fence, merged, tmp, it, i; int *prod_timeline = test_mpsc_data.prod_timeline; int cons_timeline = test_mpsc_data.cons_timeline; int iterations = test_mpsc_data.iterations; int n = test_mpsc_data.threads; for (it = 1; it <= iterations; it++) { fence = sw_sync_timeline_create_fence(prod_timeline[0], it); for (i = 1; i < n; i++) { tmp = sw_sync_timeline_create_fence(prod_timeline[i], it); merged = sync_fence_merge(tmp, fence); close(tmp); close(fence); fence = merged; } /* Make sure we see an increment from every producer thread. * Vary the means by which we wait. */ if (iterations % 8 != 0) { igt_assert_f(sync_fence_wait(fence, -1) == 0, "Producers did not increment as expected\n"); } else { igt_assert_f(test_mspc_wait_on_fence(fence) == 0, "Failure waiting on fence\n"); } igt_assert_f(test_mpsc_data.counter == n * it, "Counter value mismatch\n"); /* Release the producer threads */ sw_sync_timeline_inc(cons_timeline, 1); close(fence); } return 0; } /* IMPORTANT NOTE: if you see this test failing on your system, it may be * due to a shortage of file descriptors. Please ensure your system has * a sensible limit for this test to finish correctly. */ static void test_sync_multi_producer_single_consumer(void) { int iterations = 1 << 12; int n = 5; int prod_timeline[n]; int cons_timeline; pthread_t threads[n]; long i; cons_timeline = sw_sync_timeline_create(); for (i = 0; i < n; i++) prod_timeline[i] = sw_sync_timeline_create(); test_mpsc_data.prod_timeline = prod_timeline; test_mpsc_data.cons_timeline = cons_timeline; test_mpsc_data.iterations = iterations; test_mpsc_data.threads = n; test_mpsc_data.counter = 0; pthread_mutex_init(&test_mpsc_data.lock, NULL); for (i = 0; i < n; i++) { pthread_create(&threads[i], NULL, (void * (*)(void *)) mpsc_producer_thread, (void *)i); } mpsc_consumer_thread(); for (i = 0; i < n; i++) pthread_join(threads[i], NULL); } static void test_sync_expired_merge(void) { int iterations = 1 << 20; int timeline; int i; int fence_expired, fence_merged; timeline = sw_sync_timeline_create(); sw_sync_timeline_inc(timeline, 100); fence_expired = sw_sync_timeline_create_fence(timeline, 1); igt_assert_f(sync_fence_wait(fence_expired, 0) == 0, "Failure waiting for expired fence\n"); fence_merged = sync_fence_merge(fence_expired, fence_expired); close(fence_merged); for (i = 0; i < iterations; i++) { int fence = sync_fence_merge(fence_expired, fence_expired); igt_assert_f(sync_fence_wait(fence, -1) == 0, "Failure waiting on fence\n"); close(fence); } close(fence_expired); } static void test_sync_random_merge(void) { int i, size; const int nbr_timeline = 32; const int nbr_merge = 1024; int fence_map[nbr_timeline]; int timeline_arr[nbr_timeline]; int fence, tmpfence, merged; int timeline, timeline_offset, sync_pt; srand(time(NULL)); for (i = 0; i < nbr_timeline; i++) { timeline_arr[i] = sw_sync_timeline_create(); fence_map[i] = -1; } sync_pt = rand(); fence = sw_sync_timeline_create_fence(timeline_arr[0], sync_pt); fence_map[0] = sync_pt; /* Randomly create syncpoints out of a fixed set of timelines, * and merge them together. */ for (i = 0; i < nbr_merge; i++) { /* Generate syncpoint. */ timeline_offset = rand() % nbr_timeline; timeline = timeline_arr[timeline_offset]; sync_pt = rand(); /* Keep track of the latest sync_pt in each timeline. */ if (fence_map[timeline_offset] == -1) fence_map[timeline_offset] = sync_pt; else if (fence_map[timeline_offset] < sync_pt) fence_map[timeline_offset] = sync_pt; /* Merge. */ tmpfence = sw_sync_timeline_create_fence(timeline, sync_pt); merged = sync_fence_merge(tmpfence, fence); close(tmpfence); close(fence); fence = merged; } size = 0; for (i = 0; i < nbr_timeline; i++) if (fence_map[i] != -1) size++; /* Trigger the merged fence. */ for (i = 0; i < nbr_timeline; i++) { if (fence_map[i] != -1) { igt_assert_f(sync_fence_wait(fence, 0) == -ETIME, "Failure waiting on fence until timeout\n"); /* Increment the timeline to the last sync_pt */ sw_sync_timeline_inc(timeline_arr[i], fence_map[i]); } } /* Check that the fence is triggered. */ igt_assert_f(sync_fence_wait(fence, 1) == 0, "Failure triggering fence\n"); close(fence); for (i = 0; i < nbr_timeline; i++) close(timeline_arr[i]); } igt_main { igt_fixture igt_require_sw_sync(); igt_subtest("alloc_timeline") test_alloc_timeline(); igt_subtest("alloc_fence") test_alloc_fence(); igt_subtest("alloc_fence_invalid_timeline") test_alloc_fence_invalid_timeline(); igt_subtest("timeline_closed") test_timeline_closed(); igt_subtest("timeline_closed_signaled") test_timeline_closed_signaled(); igt_subtest("alloc_merge_fence") test_alloc_merge_fence(); igt_subtest("sync_busy") test_sync_busy(); igt_subtest("sync_busy_fork") test_sync_busy_fork(); igt_subtest("sync_busy_fork_unixsocket") test_sync_busy_fork_unixsocket(); igt_subtest("sync_merge_invalid") test_sync_merge_invalid(); igt_subtest("sync_merge") test_sync_merge(); igt_subtest("sync_merge_same") test_sync_merge_same(); igt_subtest("sync_multi_timeline_wait") test_sync_multi_timeline_wait(); igt_subtest("sync_multi_consumer") test_sync_multi_consumer(); igt_subtest("sync_multi_consumer_producer") test_sync_multi_consumer_producer(); igt_subtest("sync_multi_producer_single_consumer") test_sync_multi_producer_single_consumer(); igt_subtest("sync_expired_merge") test_sync_expired_merge(); igt_subtest("sync_random_merge") test_sync_random_merge(); }