// This file Copyright (C) 2022 Mnemosyne LLC. // It may be used under GPLv2 (SPDX: GPL-2.0-only), GPLv3 (SPDX: GPL-3.0-only), // or any future license endorsed by Mnemosyne LLC. // License text can be found in the licenses/ folder. #include "transmission.h" #include "timer-ev.h" #include "utils-ev.h" #include "test-fixtures.h" using namespace std::literals; namespace libtransmission::test { class TimerTest : public ::testing::Test { protected: // setup + teardown to manage an event_base void SetUp() override { ::testing::Test::SetUp(); evbase_.reset(event_base_new()); } void TearDown() override { evbase_.reset(); ::testing::Test::TearDown(); } static auto constexpr AsMSec = [](auto val) { return std::chrono::duration_cast(val); }; void sleepMsec(std::chrono::milliseconds msec) { EXPECT_FALSE(waitFor( evbase_.get(), []() { return false; }, msec)); } static void expectTime( std::chrono::milliseconds expected, std::chrono::milliseconds actual, std::chrono::milliseconds allowed_deviation) { auto const lower_bound = expected - allowed_deviation; EXPECT_LT(lower_bound, actual) << "lower_bound:" << lower_bound.count() << " actual:" << actual.count(); auto const upper_bound = expected + allowed_deviation; EXPECT_LT(actual, upper_bound) << "actual:" << actual.count() << " upper_bound:" << upper_bound.count(); } // This checks that `actual` is in the bounds of [expected/2 ... expected*1.5] // to confirm that the timer didn't kick too close to the previous or next interval. static void expectInterval(std::chrono::milliseconds expected, std::chrono::milliseconds actual) { expectTime(expected, actual, expected / 2); } [[nodiscard]] static auto currentTime() { return std::chrono::steady_clock::now(); } evhelpers::evbase_unique_ptr evbase_; }; TEST_F(TimerTest, canInstantiate) { auto timer_maker = EvTimerMaker{ evbase_.get() }; auto timer = timer_maker.create(); EXPECT_TRUE(timer); } TEST_F(TimerTest, singleShotCallsCallback) { auto timer_maker = EvTimerMaker{ evbase_.get() }; auto timer = timer_maker.create(); EXPECT_TRUE(timer); auto called = false; auto callback = [&called]() { called = true; }; timer->setCallback(callback); static auto constexpr Interval = 100ms; timer->startSingleShot(Interval); waitFor(evbase_.get(), [&called] { return called; }); EXPECT_TRUE(called); } TEST_F(TimerTest, repeatingCallsCallback) { auto timer_maker = EvTimerMaker{ evbase_.get() }; auto timer = timer_maker.create(); EXPECT_TRUE(timer); auto called = false; auto callback = [&called]() { called = true; }; timer->setCallback(callback); static auto constexpr Interval = 100ms; timer->startRepeating(Interval); waitFor(evbase_.get(), [&called] { return called; }); EXPECT_TRUE(called); } TEST_F(TimerTest, singleShotHonorsInterval) { auto timer_maker = EvTimerMaker{ evbase_.get() }; auto timer = timer_maker.create(); EXPECT_TRUE(timer); auto called = false; auto callback = [&called]() { called = true; }; timer->setCallback(callback); // run a single-shot timer auto const begin_time = currentTime(); static auto constexpr Interval = 100ms; timer->startSingleShot(Interval); EXPECT_FALSE(timer->isRepeating()); EXPECT_EQ(Interval, timer->interval()); waitFor(evbase_.get(), [&called] { return called; }); auto const end_time = currentTime(); // confirm that it kicked at the right interval EXPECT_TRUE(called); expectInterval(Interval, AsMSec(end_time - begin_time)); } TEST_F(TimerTest, repeatingHonorsInterval) { auto timer_maker = EvTimerMaker{ evbase_.get() }; auto timer = timer_maker.create(); EXPECT_TRUE(timer); auto n_calls = size_t{ 0U }; auto callback = [&n_calls]() { ++n_calls; }; timer->setCallback(callback); // start a repeating timer auto const begin_time = currentTime(); static auto constexpr Interval = 100ms; static auto constexpr DesiredLoops = 3; timer->startRepeating(Interval); EXPECT_TRUE(timer->isRepeating()); EXPECT_EQ(Interval, timer->interval()); waitFor(evbase_.get(), [&n_calls] { return n_calls >= DesiredLoops; }); auto const end_time = currentTime(); // confirm that it kicked the right number of times expectInterval(Interval * DesiredLoops, AsMSec(end_time - begin_time)); EXPECT_EQ(DesiredLoops, n_calls); } TEST_F(TimerTest, restartWithDifferentInterval) { auto timer_maker = EvTimerMaker{ evbase_.get() }; auto timer = timer_maker.create(); EXPECT_TRUE(timer); auto n_calls = size_t{ 0U }; auto callback = [&n_calls]() { ++n_calls; }; timer->setCallback(callback); auto const test = [this, &n_calls, &timer](auto interval) { auto const next = n_calls + 1; auto const begin_time = currentTime(); timer->startSingleShot(interval); waitFor(evbase_.get(), [&n_calls, next]() { return n_calls >= next; }); auto const end_time = currentTime(); expectInterval(interval, AsMSec(end_time - begin_time)); }; test(100ms); test(200ms); test(100ms); } TEST_F(TimerTest, restartWithSameInterval) { auto timer_maker = EvTimerMaker{ evbase_.get() }; auto timer = timer_maker.create(); EXPECT_TRUE(timer); auto n_calls = size_t{ 0U }; auto callback = [&n_calls]() { ++n_calls; }; timer->setCallback(callback); auto const test = [this, &n_calls, &timer](auto interval) { auto const next = n_calls + 1; auto const begin_time = currentTime(); timer->startSingleShot(interval); waitFor(evbase_.get(), [&n_calls, next]() { return n_calls >= next; }); auto const end_time = currentTime(); expectInterval(interval, AsMSec(end_time - begin_time)); }; test(timer->interval()); test(timer->interval()); test(timer->interval()); } TEST_F(TimerTest, repeatingThenSingleShot) { auto timer_maker = EvTimerMaker{ evbase_.get() }; auto timer = timer_maker.create(); EXPECT_TRUE(timer); auto n_calls = size_t{ 0U }; auto callback = [&n_calls]() { ++n_calls; }; timer->setCallback(callback); // start a repeating timer and confirm that it's running auto begin_time = currentTime(); static auto constexpr RepeatingInterval = 100ms; static auto constexpr DesiredLoops = 2; timer->startRepeating(RepeatingInterval); EXPECT_EQ(RepeatingInterval, timer->interval()); EXPECT_TRUE(timer->isRepeating()); waitFor(evbase_.get(), [&n_calls]() { return n_calls >= DesiredLoops; }); auto end_time = currentTime(); expectTime(RepeatingInterval * DesiredLoops, AsMSec(end_time - begin_time), RepeatingInterval / 2); // now restart it as a single shot auto const baseline = n_calls; begin_time = currentTime(); static auto constexpr SingleShotInterval = 80ms; timer->startSingleShot(SingleShotInterval); EXPECT_EQ(SingleShotInterval, timer->interval()); EXPECT_FALSE(timer->isRepeating()); waitFor(evbase_.get(), [&n_calls]() { return n_calls >= DesiredLoops + 1; }); end_time = currentTime(); // confirm that the single shot interval was honored expectInterval(SingleShotInterval, AsMSec(end_time - begin_time)); // confirm that the timer only kicks once, since it was converted into single-shot sleepMsec(SingleShotInterval * 3); EXPECT_EQ(baseline + 1, n_calls); } TEST_F(TimerTest, singleShotStop) { auto timer_maker = EvTimerMaker{ evbase_.get() }; auto timer = timer_maker.create(); EXPECT_TRUE(timer); auto n_calls = size_t{ 0U }; auto callback = [&n_calls]() { ++n_calls; }; timer->setCallback(callback); // start a single-shot timer static auto constexpr Interval = 200ms; timer->startSingleShot(Interval); EXPECT_EQ(Interval, timer->interval()); EXPECT_FALSE(timer->isRepeating()); // wait half the interval, then stop the timer sleepMsec(Interval / 2); EXPECT_EQ(0U, n_calls); timer->stop(); // wait until the timer has gone past. // since we stopped it, callback should not have been called. sleepMsec(Interval); EXPECT_EQ(0U, n_calls); } TEST_F(TimerTest, repeatingStop) { auto timer_maker = EvTimerMaker{ evbase_.get() }; auto timer = timer_maker.create(); EXPECT_TRUE(timer); auto n_calls = size_t{ 0U }; auto callback = [&n_calls]() { ++n_calls; }; timer->setCallback(callback); // start a repeating timer static auto constexpr Interval = 200ms; timer->startRepeating(Interval); EXPECT_EQ(Interval, timer->interval()); EXPECT_TRUE(timer->isRepeating()); // wait half the interval, then stop the timer sleepMsec(Interval / 2); EXPECT_EQ(0U, n_calls); timer->stop(); // wait until the timer has gone past. // since we stopped it, callback should not have been called. sleepMsec(Interval); EXPECT_EQ(0U, n_calls); } TEST_F(TimerTest, destroyedTimersStop) { auto timer_maker = EvTimerMaker{ evbase_.get() }; auto timer = timer_maker.create(); EXPECT_TRUE(timer); auto n_calls = size_t{ 0U }; auto callback = [&n_calls]() { ++n_calls; }; timer->setCallback(callback); // start a repeating timer static auto constexpr Interval = 200ms; timer->startRepeating(Interval); EXPECT_EQ(Interval, timer->interval()); EXPECT_TRUE(timer->isRepeating()); // wait half the interval, then destroy the timer sleepMsec(Interval / 2); EXPECT_EQ(0U, n_calls); timer.reset(); // wait until the timer has gone past. // since we destroyed it, callback should not have been called. sleepMsec(Interval); EXPECT_EQ(0U, n_calls); } } // namespace libtransmission::test