/* * Copyright 2004 The WebRTC Project Authors. All rights reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #include "rtc_base/time_utils.h" #include #include "api/units/time_delta.h" #include "rtc_base/event.h" #include "rtc_base/fake_clock.h" #include "rtc_base/helpers.h" #include "rtc_base/location.h" #include "rtc_base/message_handler.h" #include "rtc_base/thread.h" #include "test/gtest.h" namespace rtc { using ::webrtc::TimeDelta; TEST(TimeTest, TimeInMs) { int64_t ts_earlier = TimeMillis(); Thread::SleepMs(100); int64_t ts_now = TimeMillis(); // Allow for the thread to wakeup ~20ms early. EXPECT_GE(ts_now, ts_earlier + 80); // Make sure the Time is not returning in smaller unit like microseconds. EXPECT_LT(ts_now, ts_earlier + 1000); } TEST(TimeTest, Intervals) { int64_t ts_earlier = TimeMillis(); int64_t ts_later = TimeAfter(500); // We can't depend on ts_later and ts_earlier to be exactly 500 apart // since time elapses between the calls to TimeMillis() and TimeAfter(500) EXPECT_LE(500, TimeDiff(ts_later, ts_earlier)); EXPECT_GE(-500, TimeDiff(ts_earlier, ts_later)); // Time has elapsed since ts_earlier EXPECT_GE(TimeSince(ts_earlier), 0); // ts_earlier is earlier than now, so TimeUntil ts_earlier is -ve EXPECT_LE(TimeUntil(ts_earlier), 0); // ts_later likely hasn't happened yet, so TimeSince could be -ve // but within 500 EXPECT_GE(TimeSince(ts_later), -500); // TimeUntil ts_later is at most 500 EXPECT_LE(TimeUntil(ts_later), 500); } TEST(TimeTest, TestTimeDiff64) { int64_t ts_diff = 100; int64_t ts_earlier = rtc::TimeMillis(); int64_t ts_later = ts_earlier + ts_diff; EXPECT_EQ(ts_diff, rtc::TimeDiff(ts_later, ts_earlier)); EXPECT_EQ(-ts_diff, rtc::TimeDiff(ts_earlier, ts_later)); } class TimestampWrapAroundHandlerTest : public ::testing::Test { public: TimestampWrapAroundHandlerTest() {} protected: TimestampWrapAroundHandler wraparound_handler_; }; TEST_F(TimestampWrapAroundHandlerTest, Unwrap) { // Start value. int64_t ts = 2; EXPECT_EQ(ts, wraparound_handler_.Unwrap(static_cast(ts & 0xffffffff))); // Wrap backwards. ts = -2; EXPECT_EQ(ts, wraparound_handler_.Unwrap(static_cast(ts & 0xffffffff))); // Forward to 2 again. ts = 2; EXPECT_EQ(ts, wraparound_handler_.Unwrap(static_cast(ts & 0xffffffff))); // Max positive skip ahead, until max value (0xffffffff). for (uint32_t i = 0; i <= 0xf; ++i) { ts = (i << 28) + 0x0fffffff; EXPECT_EQ( ts, wraparound_handler_.Unwrap(static_cast(ts & 0xffffffff))); } // Wrap around. ts += 2; EXPECT_EQ(ts, wraparound_handler_.Unwrap(static_cast(ts & 0xffffffff))); // Max wrap backward... ts -= 0x0fffffff; EXPECT_EQ(ts, wraparound_handler_.Unwrap(static_cast(ts & 0xffffffff))); // ...and back again. ts += 0x0fffffff; EXPECT_EQ(ts, wraparound_handler_.Unwrap(static_cast(ts & 0xffffffff))); } TEST_F(TimestampWrapAroundHandlerTest, NoNegativeStart) { int64_t ts = 0xfffffff0; EXPECT_EQ(ts, wraparound_handler_.Unwrap(static_cast(ts & 0xffffffff))); } class TmToSeconds : public ::testing::Test { public: TmToSeconds() { // Set use of the test RNG to get deterministic expiration timestamp. rtc::SetRandomTestMode(true); } ~TmToSeconds() override { // Put it back for the next test. rtc::SetRandomTestMode(false); } void TestTmToSeconds(int times) { static char mdays[12] = {31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31}; for (int i = 0; i < times; i++) { // First generate something correct and check that TmToSeconds is happy. int year = rtc::CreateRandomId() % 400 + 1970; bool leap_year = false; if (year % 4 == 0) leap_year = true; if (year % 100 == 0) leap_year = false; if (year % 400 == 0) leap_year = true; std::tm tm; tm.tm_year = year - 1900; // std::tm is year 1900 based. tm.tm_mon = rtc::CreateRandomId() % 12; tm.tm_mday = rtc::CreateRandomId() % mdays[tm.tm_mon] + 1; tm.tm_hour = rtc::CreateRandomId() % 24; tm.tm_min = rtc::CreateRandomId() % 60; tm.tm_sec = rtc::CreateRandomId() % 60; int64_t t = rtc::TmToSeconds(tm); EXPECT_TRUE(t >= 0); // Now damage a random field and check that TmToSeconds is unhappy. switch (rtc::CreateRandomId() % 11) { case 0: tm.tm_year = 1969 - 1900; break; case 1: tm.tm_mon = -1; break; case 2: tm.tm_mon = 12; break; case 3: tm.tm_mday = 0; break; case 4: tm.tm_mday = mdays[tm.tm_mon] + (leap_year && tm.tm_mon == 1) + 1; break; case 5: tm.tm_hour = -1; break; case 6: tm.tm_hour = 24; break; case 7: tm.tm_min = -1; break; case 8: tm.tm_min = 60; break; case 9: tm.tm_sec = -1; break; case 10: tm.tm_sec = 60; break; } EXPECT_EQ(rtc::TmToSeconds(tm), -1); } // Check consistency with the system gmtime_r. With time_t, we can only // portably test dates until 2038, which is achieved by the % 0x80000000. for (int i = 0; i < times; i++) { time_t t = rtc::CreateRandomId() % 0x80000000; #if defined(WEBRTC_WIN) std::tm* tm = std::gmtime(&t); EXPECT_TRUE(tm); EXPECT_TRUE(rtc::TmToSeconds(*tm) == t); #else std::tm tm; EXPECT_TRUE(gmtime_r(&t, &tm)); EXPECT_TRUE(rtc::TmToSeconds(tm) == t); #endif } } }; TEST_F(TmToSeconds, TestTmToSeconds) { TestTmToSeconds(100000); } // Test that all the time functions exposed by TimeUtils get time from the // fake clock when it's set. TEST(FakeClock, TimeFunctionsUseFakeClock) { FakeClock clock; SetClockForTesting(&clock); clock.SetTime(webrtc::Timestamp::Micros(987654)); EXPECT_EQ(987u, Time32()); EXPECT_EQ(987, TimeMillis()); EXPECT_EQ(987654, TimeMicros()); EXPECT_EQ(987654000, TimeNanos()); EXPECT_EQ(1000u, TimeAfter(13)); SetClockForTesting(nullptr); // After it's unset, we should get a normal time. EXPECT_NE(987, TimeMillis()); } TEST(FakeClock, InitialTime) { FakeClock clock; EXPECT_EQ(0, clock.TimeNanos()); } TEST(FakeClock, SetTime) { FakeClock clock; clock.SetTime(webrtc::Timestamp::Micros(123)); EXPECT_EQ(123000, clock.TimeNanos()); clock.SetTime(webrtc::Timestamp::Micros(456)); EXPECT_EQ(456000, clock.TimeNanos()); } TEST(FakeClock, AdvanceTime) { FakeClock clock; clock.AdvanceTime(webrtc::TimeDelta::Micros(1u)); EXPECT_EQ(1000, clock.TimeNanos()); clock.AdvanceTime(webrtc::TimeDelta::Micros(2222u)); EXPECT_EQ(2223000, clock.TimeNanos()); clock.AdvanceTime(webrtc::TimeDelta::Millis(3333u)); EXPECT_EQ(3335223000, clock.TimeNanos()); clock.AdvanceTime(webrtc::TimeDelta::Seconds(4444u)); EXPECT_EQ(4447335223000, clock.TimeNanos()); } // When the clock is advanced, threads that are waiting in a socket select // should wake up and look at the new time. This allows tests using the // fake clock to run much faster, if the test is bound by time constraints // (such as a test for a STUN ping timeout). TEST(FakeClock, SettingTimeWakesThreads) { int64_t real_start_time_ms = TimeMillis(); ThreadProcessingFakeClock clock; SetClockForTesting(&clock); std::unique_ptr worker(Thread::CreateWithSocketServer()); worker->Start(); // Post an event that won't be executed for 10 seconds. Event message_handler_dispatched; worker->PostDelayedTask( [&message_handler_dispatched] { message_handler_dispatched.Set(); }, TimeDelta::Seconds(60)); // Wait for a bit for the worker thread to be started and enter its socket // select(). Otherwise this test would be trivial since the worker thread // would process the event as soon as it was started. Thread::Current()->SleepMs(1000); // Advance the fake clock, expecting the worker thread to wake up // and dispatch the message instantly. clock.AdvanceTime(webrtc::TimeDelta::Seconds(60u)); EXPECT_TRUE(message_handler_dispatched.Wait(0)); worker->Stop(); SetClockForTesting(nullptr); // The message should have been dispatched long before the 60 seconds fully // elapsed (just a sanity check). int64_t real_end_time_ms = TimeMillis(); EXPECT_LT(real_end_time_ms - real_start_time_ms, 10000); } } // namespace rtc