/* * Copyright (C) 2018 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ // Unit tests for Isochronous Clock Model #include #include #include #include #include #include using namespace aaudio; // We can use arbitrary values here because we are not opening a real audio stream. #define SAMPLE_RATE 48000 #define HW_FRAMES_PER_BURST 48 #define NANOS_PER_BURST (NANOS_PER_SECOND * HW_FRAMES_PER_BURST / SAMPLE_RATE) class ClockModelTestFixture: public ::testing::Test { public: ClockModelTestFixture() { } void SetUp() { model.setSampleRate(SAMPLE_RATE); model.setFramesPerBurst(HW_FRAMES_PER_BURST); } void TearDown() { } ~ClockModelTestFixture() { // cleanup any pending stuff, but no exceptions allowed } // Test processing of timestamps when the hardware may be slightly off from // the expected sample rate. void checkDriftingClock(double hardwareFramesPerSecond, int numLoops) { const int64_t startTimeNanos = 500000000; // arbitrary model.start(startTimeNanos); const int64_t startPositionFrames = HW_FRAMES_PER_BURST; // hardware // arbitrary time for first burst const int64_t markerTime = startTimeNanos + NANOS_PER_MILLISECOND + (200 * NANOS_PER_MICROSECOND); // Should set initial marker. model.processTimestamp(startPositionFrames, markerTime); ASSERT_EQ(startPositionFrames, model.convertTimeToPosition(markerTime)); double elapsedTimeSeconds = startTimeNanos / (double) NANOS_PER_SECOND; for (int i = 0; i < numLoops; i++) { // Calculate random delay over several bursts. const double timeDelaySeconds = 10.0 * drand48() * NANOS_PER_BURST / NANOS_PER_SECOND; elapsedTimeSeconds += timeDelaySeconds; const int64_t elapsedTimeNanos = (int64_t)(elapsedTimeSeconds * NANOS_PER_SECOND); const int64_t currentTimeNanos = startTimeNanos + elapsedTimeNanos; // Simulate DSP running at the specified rate. const int64_t currentTimeFrames = startPositionFrames + (int64_t)(hardwareFramesPerSecond * elapsedTimeSeconds); const int64_t numBursts = currentTimeFrames / HW_FRAMES_PER_BURST; const int64_t alignedPosition = startPositionFrames + (numBursts * HW_FRAMES_PER_BURST); // Apply drifting timestamp. model.processTimestamp(alignedPosition, currentTimeNanos); ASSERT_EQ(alignedPosition, model.convertTimeToPosition(currentTimeNanos)); } } IsochronousClockModel model; }; // Check default setup. TEST_F(ClockModelTestFixture, clock_setup) { ASSERT_EQ(SAMPLE_RATE, model.getSampleRate()); ASSERT_EQ(HW_FRAMES_PER_BURST, model.getFramesPerBurst()); } // Test delta calculations. TEST_F(ClockModelTestFixture, clock_deltas) { int64_t position = model.convertDeltaTimeToPosition(NANOS_PER_SECOND); ASSERT_EQ(SAMPLE_RATE, position); // Deltas are not quantized. // Compare time to the equivalent position in frames. constexpr int64_t kNanosPerBurst = HW_FRAMES_PER_BURST * NANOS_PER_SECOND / SAMPLE_RATE; position = model.convertDeltaTimeToPosition(NANOS_PER_SECOND + (kNanosPerBurst / 2)); ASSERT_EQ(SAMPLE_RATE + (HW_FRAMES_PER_BURST / 2), position); int64_t time = model.convertDeltaPositionToTime(SAMPLE_RATE); ASSERT_EQ(NANOS_PER_SECOND, time); // Compare position in frames to the equivalent time. time = model.convertDeltaPositionToTime(SAMPLE_RATE + (HW_FRAMES_PER_BURST / 2)); ASSERT_EQ(NANOS_PER_SECOND + (kNanosPerBurst / 2), time); } // start() should force the internal markers TEST_F(ClockModelTestFixture, clock_start) { const int64_t startTime = 100000; model.start(startTime); int64_t position = model.convertTimeToPosition(startTime); EXPECT_EQ(0, position); int64_t time = model.convertPositionToTime(position); EXPECT_EQ(startTime, time); time = startTime + (500 * NANOS_PER_MICROSECOND); position = model.convertTimeToPosition(time); EXPECT_EQ(0, position); } // timestamps moves the window if outside the bounds TEST_F(ClockModelTestFixture, clock_timestamp) { const int64_t startTime = 100000000; model.start(startTime); const int64_t position = HW_FRAMES_PER_BURST; // hardware int64_t markerTime = startTime + NANOS_PER_MILLISECOND + (200 * NANOS_PER_MICROSECOND); // Should set marker. model.processTimestamp(position, markerTime); EXPECT_EQ(position, model.convertTimeToPosition(markerTime)); // convertTimeToPosition rounds down EXPECT_EQ(position, model.convertTimeToPosition(markerTime + (73 * NANOS_PER_MICROSECOND))); // convertPositionToTime rounds up EXPECT_EQ(markerTime + NANOS_PER_BURST, model.convertPositionToTime(position + 17)); } #define NUM_LOOPS_DRIFT 10000 // test nudging the window by using a drifting HW clock TEST_F(ClockModelTestFixture, clock_no_drift) { checkDriftingClock(SAMPLE_RATE, NUM_LOOPS_DRIFT); } // These slow drift rates caused errors when I disabled the code that handles // drifting in the clock model. So I think the test is valid. // It is unlikely that real hardware would be off by more than this amount. TEST_F(ClockModelTestFixture, clock_slow_drift) { checkDriftingClock(0.998 * SAMPLE_RATE, NUM_LOOPS_DRIFT); } TEST_F(ClockModelTestFixture, clock_fast_drift) { checkDriftingClock(1.002 * SAMPLE_RATE, NUM_LOOPS_DRIFT); }