//------------------------------------------------------------------------------ /* This file is part of clio: https://github.com/XRPLF/clio Copyright (c) 2024, the clio developers. Permission to use, copy, modify, and distribute this software for any purpose with or without fee is hereby granted, provided that the above copyright notice and this permission notice appear in all copies. THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ //============================================================================== #include "util/Profiler.hpp" #include "util/async/Operation.hpp" #include "util/async/context/BasicExecutionContext.hpp" #include "util/async/context/SyncExecutionContext.hpp" #include #include #include #include #include #include #include #include #include using namespace util::async; using ::testing::Types; template struct ExecutionContextTests : public ::testing::Test { using ExecutionContextType = T; ExecutionContextType ctx{2}; ~ExecutionContextTests() override { ctx.stop(); ctx.join(); } }; // Suite for tests to be ran against all context types but SyncExecutionContext template using AsyncExecutionContextTests = ExecutionContextTests; using ExecutionContextTypes = Types; using AsyncExecutionContextTypes = Types; TYPED_TEST_CASE(ExecutionContextTests, ExecutionContextTypes); TYPED_TEST_CASE(AsyncExecutionContextTests, AsyncExecutionContextTypes); TYPED_TEST(ExecutionContextTests, move) { auto mineNow = std::move(this->ctx); EXPECT_TRUE(mineNow.execute([] { return true; }).get().value()); } TYPED_TEST(ExecutionContextTests, execute) { auto res = this->ctx.execute([]() { return 42; }); EXPECT_EQ(res.get().value(), 42); } TYPED_TEST(ExecutionContextTests, executeVoid) { auto value = 0; auto res = this->ctx.execute([&value]() { value = 42; }); res.wait(); ASSERT_EQ(value, 42); } TYPED_TEST(ExecutionContextTests, executeStdException) { auto res = this->ctx.execute([]() { throw std::runtime_error("test"); }); auto const err = res.get().error(); EXPECT_TRUE(err.message.ends_with("test")); EXPECT_TRUE(std::string{err}.ends_with("test")); } TYPED_TEST(ExecutionContextTests, executeUnknownException) { auto res = this->ctx.execute([]() { throw 0; }); auto const err = res.get().error(); EXPECT_TRUE(err.message.ends_with("unknown")); EXPECT_TRUE(std::string{err}.ends_with("unknown")); } // note: this fails on pool context with 1 thread TYPED_TEST(ExecutionContextTests, executeWithTimeout) { auto res = this->ctx.execute( [](auto stopRequested) { while (not stopRequested) ; return 42; }, std::chrono::milliseconds{1} ); EXPECT_EQ(res.get().value(), 42); } TYPED_TEST(ExecutionContextTests, timer) { auto res = this->ctx.scheduleAfter(std::chrono::milliseconds(1), []([[maybe_unused]] auto stopRequested, auto cancelled) { if (not cancelled) return 42; return 0; }); EXPECT_EQ(res.get().value(), 42); } TYPED_TEST(ExecutionContextTests, timerWithStopToken) { auto res = this->ctx.scheduleAfter(std::chrono::milliseconds(1), [](auto stopRequested) { while (not stopRequested) ; return 42; }); res.requestStop(); EXPECT_EQ(res.get().value(), 42); } TYPED_TEST(ExecutionContextTests, timerCancel) { auto value = 0; std::binary_semaphore sem{0}; auto res = this->ctx.scheduleAfter( std::chrono::milliseconds(10), [&value, &sem]([[maybe_unused]] auto stopRequested, auto cancelled) { if (cancelled) value = 42; sem.release(); } ); res.cancel(); sem.acquire(); EXPECT_EQ(value, 42); } TYPED_TEST(ExecutionContextTests, timerAutoCancels) { auto value = 0; std::binary_semaphore sem{0}; { auto res = this->ctx.scheduleAfter( std::chrono::milliseconds(1), [&value, &sem]([[maybe_unused]] auto stopRequested, auto cancelled) { if (cancelled) value = 42; sem.release(); } ); } // res goes out of scope and cancels the timer sem.acquire(); EXPECT_EQ(value, 42); } TYPED_TEST(ExecutionContextTests, timerStdException) { auto res = this->ctx.scheduleAfter(std::chrono::milliseconds(1), []([[maybe_unused]] auto stopRequested, auto cancelled) { if (not cancelled) throw std::runtime_error("test"); return 0; }); auto const err = res.get().error(); EXPECT_TRUE(err.message.ends_with("test")); EXPECT_TRUE(std::string{err}.ends_with("test")); } TYPED_TEST(ExecutionContextTests, timerUnknownException) { auto res = this->ctx.scheduleAfter(std::chrono::milliseconds(1), []([[maybe_unused]] auto stopRequested, auto cancelled) { if (not cancelled) throw 0; return 0; }); auto const err = res.get().error(); EXPECT_TRUE(err.message.ends_with("unknown")); EXPECT_TRUE(std::string{err}.ends_with("unknown")); } TYPED_TEST(ExecutionContextTests, repeatingOperation) { auto const repeatDelay = std::chrono::milliseconds{1}; auto const timeout = std::chrono::milliseconds{15}; auto callCount = 0uz; auto res = this->ctx.executeRepeatedly(repeatDelay, [&] { ++callCount; }); auto timeSpent = util::timed([timeout] { std::this_thread::sleep_for(timeout); }); // calculate actual time spent res.abort(); // outside of the above stopwatch because it blocks and can take arbitrary time auto const expectedPureCalls = timeout.count() / repeatDelay.count(); auto const expectedActualCount = timeSpent / repeatDelay.count(); EXPECT_GE(callCount, expectedPureCalls / 2u); // expect at least half of the scheduled calls EXPECT_LE(callCount, expectedActualCount); // never should be called more times than possible before timeout } TYPED_TEST(ExecutionContextTests, repeatingOperationForceInvoke) { std::atomic_size_t callCount = 64uz; std::binary_semaphore unblock(0); auto res = this->ctx.executeRepeatedly(std::chrono::seconds{10}, [&] { if (--callCount == 0uz) unblock.release(); }); for ([[maybe_unused]] auto unused : std::views::iota(0uz, callCount.load())) res.invoke(); unblock.acquire(); res.abort(); EXPECT_EQ(callCount, 0uz); } TYPED_TEST(ExecutionContextTests, strandMove) { auto strand = this->ctx.makeStrand(); auto yoink = std::move(strand); auto res = yoink.execute([] { return 42; }); EXPECT_EQ(res.get().value(), 42); } TYPED_TEST(ExecutionContextTests, strand) { auto strand = this->ctx.makeStrand(); auto res = strand.execute([] { return 42; }); EXPECT_EQ(res.get().value(), 42); } TYPED_TEST(ExecutionContextTests, strandStdException) { auto strand = this->ctx.makeStrand(); auto res = strand.execute([]() { throw std::runtime_error("test"); }); auto const err = res.get().error(); EXPECT_TRUE(err.message.ends_with("test")); EXPECT_TRUE(std::string{err}.ends_with("test")); } TYPED_TEST(ExecutionContextTests, strandUnknownException) { auto strand = this->ctx.makeStrand(); auto res = strand.execute([]() { throw 0; }); auto const err = res.get().error(); EXPECT_TRUE(err.message.ends_with("unknown")); EXPECT_TRUE(std::string{err}.ends_with("unknown")); } // note: this fails on pool context with 1 thread TYPED_TEST(ExecutionContextTests, strandWithTimeout) { auto strand = this->ctx.makeStrand(); auto res = strand.execute( [](auto stopRequested) { while (not stopRequested) ; return 42; }, std::chrono::milliseconds{1} ); EXPECT_EQ(res.get().value(), 42); } TYPED_TEST(ExecutionContextTests, strandedRepeatingOperation) { auto strand = this->ctx.makeStrand(); auto const repeatDelay = std::chrono::milliseconds{1}; auto const timeout = std::chrono::milliseconds{15}; auto callCount = 0uz; auto res = strand.executeRepeatedly(repeatDelay, [&] { ++callCount; }); auto timeSpent = util::timed([timeout] { std::this_thread::sleep_for(timeout); }); // calculate actual time spent res.abort(); // outside of the above stopwatch because it blocks and can take arbitrary time auto const expectedPureCalls = timeout.count() / repeatDelay.count(); auto const expectedActualCount = timeSpent / repeatDelay.count(); EXPECT_GE(callCount, expectedPureCalls / 2u); // expect at least half of the scheduled calls EXPECT_LE(callCount, expectedActualCount); // never should be called more times than possible before timeout } TYPED_TEST(ExecutionContextTests, strandedRepeatingOperationForceInvoke) { auto strand = this->ctx.makeStrand(); auto callCount = 64uz; // does not need to be atomic since we are on a strand std::binary_semaphore unblock(0); auto res = strand.executeRepeatedly(std::chrono::seconds{10}, [&] { if (--callCount == 0uz) unblock.release(); }); for ([[maybe_unused]] auto unused : std::views::iota(0uz, callCount)) res.invoke(); unblock.acquire(); res.abort(); EXPECT_EQ(callCount, 0uz); } TYPED_TEST(AsyncExecutionContextTests, executeAutoAborts) { auto value = 0; std::binary_semaphore sem{0}; { auto res = this->ctx.execute([&](auto stopRequested) { while (not stopRequested) ; value = 42; sem.release(); }); } // res goes out of scope and aborts operation sem.acquire(); EXPECT_EQ(value, 42); } TYPED_TEST(AsyncExecutionContextTests, repeatingOperationAutoAborts) { auto const repeatDelay = std::chrono::milliseconds{1}; auto const timeout = std::chrono::milliseconds{15}; auto callCount = 0uz; auto timeSpentMs = 0u; { auto res = this->ctx.executeRepeatedly(repeatDelay, [&] { ++callCount; }); timeSpentMs = util::timed([timeout] { std::this_thread::sleep_for(timeout); }); // calculate actual time spent } // res goes out of scope and automatically aborts the repeating operation // double the delay so that if abort did not happen we will fail below expectations std::this_thread::sleep_for(timeout); auto const expectedPureCalls = timeout.count() / repeatDelay.count(); auto const expectedActualCount = timeSpentMs / repeatDelay.count(); EXPECT_GE(callCount, expectedPureCalls / 2u); // expect at least half of the scheduled calls EXPECT_LE(callCount, expectedActualCount); // never should be called more times than possible before timeout } using NoErrorHandlerSyncExecutionContext = BasicExecutionContext< impl::SameThreadContext, impl::BasicStopSource, impl::SyncDispatchStrategy, impl::SelfContextProvider, impl::NoErrorHandler>; TEST(NoErrorHandlerSyncExecutionContextTests, executeStdException) { auto ctx = NoErrorHandlerSyncExecutionContext{}; EXPECT_THROW(ctx.execute([] { throw std::runtime_error("test"); }).wait(), std::runtime_error); } TEST(NoErrorHandlerSyncExecutionContextTests, executeUnknownException) { auto ctx = NoErrorHandlerSyncExecutionContext{}; EXPECT_ANY_THROW(ctx.execute([] { throw 0; }).wait()); } TEST(NoErrorHandlerSyncExecutionContextTests, executeStdExceptionInStrand) { auto ctx = NoErrorHandlerSyncExecutionContext{}; auto strand = ctx.makeStrand(); EXPECT_THROW(strand.execute([] { throw std::runtime_error("test"); }).wait(), std::runtime_error); } TEST(NoErrorHandlerSyncExecutionContextTests, executeUnknownExceptionInStrand) { auto ctx = NoErrorHandlerSyncExecutionContext{}; auto strand = ctx.makeStrand(); EXPECT_ANY_THROW(strand.execute([] { throw 0; }).wait()); }