/* * Copyright (C) 2014-2018 Advanced Micro Devices, Inc. All Rights Reserved. * * 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 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 "KFDEventTest.hpp" #include "PM4Queue.hpp" #include "PM4Packet.hpp" void KFDEventTest::SetUp() { ROUTINE_START KFDBaseComponentTest::SetUp(); m_pHsaEvent = NULL; ROUTINE_END } void KFDEventTest::TearDown() { ROUTINE_START // Not all tests create an event, destroy only if there is one if (m_pHsaEvent != NULL) { // hsaKmtDestroyEvent moved to TearDown to make sure it is being called EXPECT_SUCCESS(hsaKmtDestroyEvent(m_pHsaEvent)); } KFDBaseComponentTest::TearDown(); ROUTINE_END } TEST_F(KFDEventTest, CreateDestroyEvent) { TEST_START(TESTPROFILE_RUNALL); ASSERT_SUCCESS(CreateQueueTypeEvent(false, false, m_NodeInfo.HsaDefaultGPUNode(), &m_pHsaEvent)); EXPECT_NE(0, m_pHsaEvent->EventData.HWData2); // Destroy event is being called in test TearDown TEST_END; } TEST_F(KFDEventTest, CreateMaxEvents) { TEST_START(TESTPROFILE_RUNALL); static const unsigned int MAX_EVENT_NUMBER = 256; HsaEvent* pHsaEvent[MAX_EVENT_NUMBER]; unsigned int i = 0; for (i = 0; i < MAX_EVENT_NUMBER; i++) { pHsaEvent[i] = NULL; ASSERT_SUCCESS(CreateQueueTypeEvent(false, false, m_NodeInfo.HsaDefaultGPUNode(), &pHsaEvent[i])); } for (i = 0; i < MAX_EVENT_NUMBER; i++) { EXPECT_SUCCESS(hsaKmtDestroyEvent(pHsaEvent[i])); } TEST_END; } TEST_F(KFDEventTest, SignalEvent) { TEST_START(TESTPROFILE_RUNALL); PM4Queue queue; HsaEvent *tmp_event; int defaultGPUNode = m_NodeInfo.HsaDefaultGPUNode(); ASSERT_GE(defaultGPUNode, 0) << "failed to get default GPU Node"; ASSERT_SUCCESS(CreateQueueTypeEvent(false, false, defaultGPUNode, &tmp_event)); /* Intentionally let event id for m_pHsaEvent be non zero */ ASSERT_SUCCESS(CreateQueueTypeEvent(false, false, defaultGPUNode, &m_pHsaEvent)); ASSERT_NE(0, m_pHsaEvent->EventData.HWData2); ASSERT_SUCCESS(queue.Create(defaultGPUNode)); /* From gfx9 onward, m_pHsaEvent->EventId will also be passed to int_ctxid in * the Release Mem packet, which is used as context id in ISR. */ queue.PlaceAndSubmitPacket(PM4ReleaseMemoryPacket(false, m_pHsaEvent->EventData.HWData2, m_pHsaEvent->EventId)); queue.Wait4PacketConsumption(); EXPECT_SUCCESS(hsaKmtWaitOnEvent(m_pHsaEvent, g_TestTimeOut)); EXPECT_SUCCESS(hsaKmtDestroyEvent(tmp_event)); EXPECT_SUCCESS(queue.Destroy()); TEST_END; } static uint64_t gettime() { struct timespec ts; clock_gettime(CLOCK_MONOTONIC, &ts); return ((int64_t)ts.tv_sec) * 1000 * 1000 * 1000 + ts.tv_nsec; } static inline double pow2_round_up(int num) { return pow(2, ceil(log(num)/log(2))); } class QueueAndSignalBenchmark { private: static const int HISTORY_SIZE = 100; int mNumEvents; int mHistorySlot; uint64_t mTimeHistory[HISTORY_SIZE]; uint64_t mLatHistory[HISTORY_SIZE]; public: QueueAndSignalBenchmark(int events) : mNumEvents(events), mHistorySlot(0) { memset(mTimeHistory, 0, sizeof(mTimeHistory)); memset(mLatHistory, 0, sizeof(mLatHistory)); } int queueAndSignalEvents(int node, int eventCount, uint64_t &time, uint64_t &latency) { int r; uint64_t startTime; PM4Queue queue; HsaEvent** pHsaEvent = reinterpret_cast(calloc(eventCount, sizeof(HsaEvent*))); size_t packetSize = PM4ReleaseMemoryPacket(false, 0, 0).SizeInBytes(); int qSize = fmax(PAGE_SIZE, pow2_round_up(packetSize*eventCount + 1)); time = 0; r = queue.Create(node, qSize); if (r != HSAKMT_STATUS_SUCCESS) goto exit; for (int i = 0; i < eventCount; i++) { r = CreateQueueTypeEvent(false, false, node, &pHsaEvent[i]); if (r != HSAKMT_STATUS_SUCCESS) goto exit; queue.PlacePacket(PM4ReleaseMemoryPacket(false, pHsaEvent[i]->EventData.HWData2, pHsaEvent[i]->EventId)); } startTime = gettime(); queue.SubmitPacket(); for (int i = 0; i < eventCount; i++) { r = hsaKmtWaitOnEvent(pHsaEvent[i], g_TestTimeOut); if (r != HSAKMT_STATUS_SUCCESS) goto exit; if (i == 0) latency = gettime() - startTime; } time = gettime() - startTime; exit: for (int i = 0; i < eventCount; i++) { if (pHsaEvent[i]) hsaKmtDestroyEvent(pHsaEvent[i]); } queue.Destroy(); return r; } void run(int node) { int r = 0; uint64_t time = 0, latency = 0; uint64_t avgLat = 0, avgTime = 0; uint64_t minTime = ULONG_MAX, maxTime = 0; uint64_t minLat = ULONG_MAX, maxLat = 0; ASSERT_EQ(queueAndSignalEvents(node, mNumEvents, time, latency), HSAKMT_STATUS_SUCCESS); mTimeHistory[mHistorySlot%HISTORY_SIZE] = time; mLatHistory[mHistorySlot%HISTORY_SIZE] = latency; for (int i = 0; i < HISTORY_SIZE; i++) { minTime = mTimeHistory[i] < minTime ? mTimeHistory[i] : minTime; maxTime = mTimeHistory[i] > maxTime ? mTimeHistory[i] : maxTime; avgTime += mTimeHistory[i]; minLat = mLatHistory[i] < minLat ? mLatHistory[i] : minLat; maxLat = mLatHistory[i] > maxLat ? mLatHistory[i] : maxLat; avgLat += mLatHistory[i]; } avgTime /= HISTORY_SIZE; avgLat /= HISTORY_SIZE; mHistorySlot++; printf("\033[KEvents: %d History: %d/%d\n", mNumEvents, mHistorySlot, HISTORY_SIZE); printf("\033[KMin Latency: %f ms\n", (float)minLat/1000000); printf("\033[KMax Latency: %f ms\n", (float)maxLat/1000000); printf("\033[KAvg Latency: %f ms\n", (float)avgLat/1000000); printf("\033[K Min Rate: %f IH/ms\n", ((float)mNumEvents)/maxTime*1000000); printf("\033[K Max Rate: %f IH/ms\n", ((float)mNumEvents)/minTime*1000000); printf("\033[K Avg Rate: %f IH/ms\n", ((float)mNumEvents)/avgTime*1000000); } }; TEST_F(KFDEventTest, MeasureInterruptConsumption) { TEST_START(TESTPROFILE_RUNALL); QueueAndSignalBenchmark latencyBench(128); QueueAndSignalBenchmark sustainedBench(4096); printf("\033[2J"); while (true) { printf("\033[H"); printf("--------------------------\n"); latencyBench.run(m_NodeInfo.HsaDefaultGPUNode()); printf("--------------------------\n"); sustainedBench.run(m_NodeInfo.HsaDefaultGPUNode()); printf("--------------------------\n"); } TEST_END; } TEST_F(KFDEventTest, SignalMaxEvents) { TEST_START(TESTPROFILE_RUNALL); static const unsigned int MAX_EVENT_NUMBER = 4096; uint64_t time, latency; QueueAndSignalBenchmark maxEventTest(MAX_EVENT_NUMBER); maxEventTest.queueAndSignalEvents(m_NodeInfo.HsaDefaultGPUNode(), MAX_EVENT_NUMBER, time, latency); TEST_END; } TEST_F(KFDEventTest, SignalMultipleEventsWaitForAll) { TEST_START(TESTPROFILE_RUNALL); static const unsigned int EVENT_NUMBER = 64; // 64 is the maximum for hsaKmtWaitOnMultipleEvents static const unsigned int WAIT_BETWEEN_SUBMISSIONS_MS = 50; HsaEvent* pHsaEvent[EVENT_NUMBER]; unsigned int i = 0; int defaultGPUNode = m_NodeInfo.HsaDefaultGPUNode(); ASSERT_GE(defaultGPUNode, 0) << "failed to get default GPU Node"; for (i = 0; i < EVENT_NUMBER; i++) { pHsaEvent[i] = NULL; ASSERT_SUCCESS(CreateQueueTypeEvent(false, false, defaultGPUNode, &pHsaEvent[i])); } PM4Queue queue; ASSERT_SUCCESS(queue.Create(defaultGPUNode)); unsigned int pktSizeDwords = 0; for (i = 0; i < EVENT_NUMBER; i++) { queue.PlaceAndSubmitPacket(PM4ReleaseMemoryPacket(false, pHsaEvent[i]->EventData.HWData2, pHsaEvent[i]->EventId)); queue.Wait4PacketConsumption(); Delay(WAIT_BETWEEN_SUBMISSIONS_MS); } EXPECT_SUCCESS(hsaKmtWaitOnMultipleEvents(pHsaEvent, EVENT_NUMBER, true, g_TestTimeOut)); EXPECT_SUCCESS(queue.Destroy()); for (i = 0; i < EVENT_NUMBER; i++) EXPECT_SUCCESS(hsaKmtDestroyEvent(pHsaEvent[i])); TEST_END; }