#undef NDEBUG #include "benchmark/benchmark.h" #include "output_test.h" // ========================================================================= // // ---------------------- Testing Prologue Output -------------------------- // // ========================================================================= // // clang-format off ADD_CASES(TC_ConsoleOut, {{"^[-]+$", MR_Next}, {"^Benchmark %s Time %s CPU %s Iterations UserCounters...$", MR_Next}, {"^[-]+$", MR_Next}}); ADD_CASES(TC_CSVOut, {{"%csv_header,\"bar\",\"foo\""}}); // clang-format on // ========================================================================= // // ------------------------- Simple Counters Output ------------------------ // // ========================================================================= // void BM_Counters_Simple(benchmark::State& state) { for (auto _ : state) { } state.counters["foo"] = 1; state.counters["bar"] = 2 * static_cast(state.iterations()); } BENCHMARK(BM_Counters_Simple); ADD_CASES(TC_ConsoleOut, {{"^BM_Counters_Simple %console_report bar=%hrfloat foo=%hrfloat$"}}); ADD_CASES(TC_JSONOut, {{"\"name\": \"BM_Counters_Simple\",$"}, {"\"family_index\": 0,$", MR_Next}, {"\"per_family_instance_index\": 0,$", MR_Next}, {"\"run_name\": \"BM_Counters_Simple\",$", MR_Next}, {"\"run_type\": \"iteration\",$", MR_Next}, {"\"repetitions\": 1,$", MR_Next}, {"\"repetition_index\": 0,$", MR_Next}, {"\"threads\": 1,$", MR_Next}, {"\"iterations\": %int,$", MR_Next}, {"\"real_time\": %float,$", MR_Next}, {"\"cpu_time\": %float,$", MR_Next}, {"\"time_unit\": \"ns\",$", MR_Next}, {"\"bar\": %float,$", MR_Next}, {"\"foo\": %float$", MR_Next}, {"}", MR_Next}}); ADD_CASES(TC_CSVOut, {{"^\"BM_Counters_Simple\",%csv_report,%float,%float$"}}); // VS2013 does not allow this function to be passed as a lambda argument // to CHECK_BENCHMARK_RESULTS() void CheckSimple(Results const& e) { double its = e.NumIterations(); CHECK_COUNTER_VALUE(e, int, "foo", EQ, 1); // check that the value of bar is within 0.1% of the expected value CHECK_FLOAT_COUNTER_VALUE(e, "bar", EQ, 2. * its, 0.001); } CHECK_BENCHMARK_RESULTS("BM_Counters_Simple", &CheckSimple); // ========================================================================= // // --------------------- Counters+Items+Bytes/s Output --------------------- // // ========================================================================= // namespace { int num_calls1 = 0; } void BM_Counters_WithBytesAndItemsPSec(benchmark::State& state) { for (auto _ : state) { // This test requires a non-zero CPU time to avoid divide-by-zero auto iterations = state.iterations(); benchmark::DoNotOptimize(iterations); } state.counters["foo"] = 1; state.counters["bar"] = ++num_calls1; state.SetBytesProcessed(364); state.SetItemsProcessed(150); } BENCHMARK(BM_Counters_WithBytesAndItemsPSec); ADD_CASES(TC_ConsoleOut, {{"^BM_Counters_WithBytesAndItemsPSec %console_report " "bar=%hrfloat bytes_per_second=%hrfloat/s " "foo=%hrfloat items_per_second=%hrfloat/s$"}}); ADD_CASES(TC_JSONOut, {{"\"name\": \"BM_Counters_WithBytesAndItemsPSec\",$"}, {"\"family_index\": 1,$", MR_Next}, {"\"per_family_instance_index\": 0,$", MR_Next}, {"\"run_name\": \"BM_Counters_WithBytesAndItemsPSec\",$", MR_Next}, {"\"run_type\": \"iteration\",$", MR_Next}, {"\"repetitions\": 1,$", MR_Next}, {"\"repetition_index\": 0,$", MR_Next}, {"\"threads\": 1,$", MR_Next}, {"\"iterations\": %int,$", MR_Next}, {"\"real_time\": %float,$", MR_Next}, {"\"cpu_time\": %float,$", MR_Next}, {"\"time_unit\": \"ns\",$", MR_Next}, {"\"bar\": %float,$", MR_Next}, {"\"bytes_per_second\": %float,$", MR_Next}, {"\"foo\": %float,$", MR_Next}, {"\"items_per_second\": %float$", MR_Next}, {"}", MR_Next}}); ADD_CASES(TC_CSVOut, {{"^\"BM_Counters_WithBytesAndItemsPSec\"," "%csv_bytes_items_report,%float,%float$"}}); // VS2013 does not allow this function to be passed as a lambda argument // to CHECK_BENCHMARK_RESULTS() void CheckBytesAndItemsPSec(Results const& e) { double t = e.DurationCPUTime(); // this (and not real time) is the time used CHECK_COUNTER_VALUE(e, int, "foo", EQ, 1); CHECK_COUNTER_VALUE(e, int, "bar", EQ, num_calls1); // check that the values are within 0.1% of the expected values CHECK_FLOAT_RESULT_VALUE(e, "bytes_per_second", EQ, 364. / t, 0.001); CHECK_FLOAT_RESULT_VALUE(e, "items_per_second", EQ, 150. / t, 0.001); } CHECK_BENCHMARK_RESULTS("BM_Counters_WithBytesAndItemsPSec", &CheckBytesAndItemsPSec); // ========================================================================= // // ------------------------- Rate Counters Output -------------------------- // // ========================================================================= // void BM_Counters_Rate(benchmark::State& state) { for (auto _ : state) { // This test requires a non-zero CPU time to avoid divide-by-zero auto iterations = state.iterations(); benchmark::DoNotOptimize(iterations); } namespace bm = benchmark; state.counters["foo"] = bm::Counter{1, bm::Counter::kIsRate}; state.counters["bar"] = bm::Counter{2, bm::Counter::kIsRate}; } BENCHMARK(BM_Counters_Rate); ADD_CASES( TC_ConsoleOut, {{"^BM_Counters_Rate %console_report bar=%hrfloat/s foo=%hrfloat/s$"}}); ADD_CASES(TC_JSONOut, {{"\"name\": \"BM_Counters_Rate\",$"}, {"\"family_index\": 2,$", MR_Next}, {"\"per_family_instance_index\": 0,$", MR_Next}, {"\"run_name\": \"BM_Counters_Rate\",$", MR_Next}, {"\"run_type\": \"iteration\",$", MR_Next}, {"\"repetitions\": 1,$", MR_Next}, {"\"repetition_index\": 0,$", MR_Next}, {"\"threads\": 1,$", MR_Next}, {"\"iterations\": %int,$", MR_Next}, {"\"real_time\": %float,$", MR_Next}, {"\"cpu_time\": %float,$", MR_Next}, {"\"time_unit\": \"ns\",$", MR_Next}, {"\"bar\": %float,$", MR_Next}, {"\"foo\": %float$", MR_Next}, {"}", MR_Next}}); ADD_CASES(TC_CSVOut, {{"^\"BM_Counters_Rate\",%csv_report,%float,%float$"}}); // VS2013 does not allow this function to be passed as a lambda argument // to CHECK_BENCHMARK_RESULTS() void CheckRate(Results const& e) { double t = e.DurationCPUTime(); // this (and not real time) is the time used // check that the values are within 0.1% of the expected values CHECK_FLOAT_COUNTER_VALUE(e, "foo", EQ, 1. / t, 0.001); CHECK_FLOAT_COUNTER_VALUE(e, "bar", EQ, 2. / t, 0.001); } CHECK_BENCHMARK_RESULTS("BM_Counters_Rate", &CheckRate); // ========================================================================= // // ----------------------- Inverted Counters Output ------------------------ // // ========================================================================= // void BM_Invert(benchmark::State& state) { for (auto _ : state) { // This test requires a non-zero CPU time to avoid divide-by-zero auto iterations = state.iterations(); benchmark::DoNotOptimize(iterations); } namespace bm = benchmark; state.counters["foo"] = bm::Counter{0.0001, bm::Counter::kInvert}; state.counters["bar"] = bm::Counter{10000, bm::Counter::kInvert}; } BENCHMARK(BM_Invert); ADD_CASES(TC_ConsoleOut, {{"^BM_Invert %console_report bar=%hrfloatu foo=%hrfloatk$"}}); ADD_CASES(TC_JSONOut, {{"\"name\": \"BM_Invert\",$"}, {"\"family_index\": 3,$", MR_Next}, {"\"per_family_instance_index\": 0,$", MR_Next}, {"\"run_name\": \"BM_Invert\",$", MR_Next}, {"\"run_type\": \"iteration\",$", MR_Next}, {"\"repetitions\": 1,$", MR_Next}, {"\"repetition_index\": 0,$", MR_Next}, {"\"threads\": 1,$", MR_Next}, {"\"iterations\": %int,$", MR_Next}, {"\"real_time\": %float,$", MR_Next}, {"\"cpu_time\": %float,$", MR_Next}, {"\"time_unit\": \"ns\",$", MR_Next}, {"\"bar\": %float,$", MR_Next}, {"\"foo\": %float$", MR_Next}, {"}", MR_Next}}); ADD_CASES(TC_CSVOut, {{"^\"BM_Invert\",%csv_report,%float,%float$"}}); // VS2013 does not allow this function to be passed as a lambda argument // to CHECK_BENCHMARK_RESULTS() void CheckInvert(Results const& e) { CHECK_FLOAT_COUNTER_VALUE(e, "foo", EQ, 10000, 0.0001); CHECK_FLOAT_COUNTER_VALUE(e, "bar", EQ, 0.0001, 0.0001); } CHECK_BENCHMARK_RESULTS("BM_Invert", &CheckInvert); // ========================================================================= // // --------------------- InvertedRate Counters Output ---------------------- // // ========================================================================= // void BM_Counters_InvertedRate(benchmark::State& state) { for (auto _ : state) { // This test requires a non-zero CPU time to avoid divide-by-zero auto iterations = state.iterations(); benchmark::DoNotOptimize(iterations); } namespace bm = benchmark; state.counters["foo"] = bm::Counter{1, bm::Counter::kIsRate | bm::Counter::kInvert}; state.counters["bar"] = bm::Counter{8192, bm::Counter::kIsRate | bm::Counter::kInvert}; } BENCHMARK(BM_Counters_InvertedRate); ADD_CASES(TC_ConsoleOut, {{"^BM_Counters_InvertedRate %console_report " "bar=%hrfloats foo=%hrfloats$"}}); ADD_CASES(TC_JSONOut, {{"\"name\": \"BM_Counters_InvertedRate\",$"}, {"\"family_index\": 4,$", MR_Next}, {"\"per_family_instance_index\": 0,$", MR_Next}, {"\"run_name\": \"BM_Counters_InvertedRate\",$", MR_Next}, {"\"run_type\": \"iteration\",$", MR_Next}, {"\"repetitions\": 1,$", MR_Next}, {"\"repetition_index\": 0,$", MR_Next}, {"\"threads\": 1,$", MR_Next}, {"\"iterations\": %int,$", MR_Next}, {"\"real_time\": %float,$", MR_Next}, {"\"cpu_time\": %float,$", MR_Next}, {"\"time_unit\": \"ns\",$", MR_Next}, {"\"bar\": %float,$", MR_Next}, {"\"foo\": %float$", MR_Next}, {"}", MR_Next}}); ADD_CASES(TC_CSVOut, {{"^\"BM_Counters_InvertedRate\",%csv_report,%float,%float$"}}); // VS2013 does not allow this function to be passed as a lambda argument // to CHECK_BENCHMARK_RESULTS() void CheckInvertedRate(Results const& e) { double t = e.DurationCPUTime(); // this (and not real time) is the time used // check that the values are within 0.1% of the expected values CHECK_FLOAT_COUNTER_VALUE(e, "foo", EQ, t, 0.001); CHECK_FLOAT_COUNTER_VALUE(e, "bar", EQ, t / 8192.0, 0.001); } CHECK_BENCHMARK_RESULTS("BM_Counters_InvertedRate", &CheckInvertedRate); // ========================================================================= // // ------------------------- Thread Counters Output ------------------------ // // ========================================================================= // void BM_Counters_Threads(benchmark::State& state) { for (auto _ : state) { } state.counters["foo"] = 1; state.counters["bar"] = 2; } BENCHMARK(BM_Counters_Threads)->ThreadRange(1, 8); ADD_CASES(TC_ConsoleOut, {{"^BM_Counters_Threads/threads:%int %console_report " "bar=%hrfloat foo=%hrfloat$"}}); ADD_CASES(TC_JSONOut, {{"\"name\": \"BM_Counters_Threads/threads:%int\",$"}, {"\"family_index\": 5,$", MR_Next}, {"\"per_family_instance_index\": 0,$", MR_Next}, {"\"run_name\": \"BM_Counters_Threads/threads:%int\",$", MR_Next}, {"\"run_type\": \"iteration\",$", MR_Next}, {"\"repetitions\": 1,$", MR_Next}, {"\"repetition_index\": 0,$", MR_Next}, {"\"threads\": 1,$", MR_Next}, {"\"iterations\": %int,$", MR_Next}, {"\"real_time\": %float,$", MR_Next}, {"\"cpu_time\": %float,$", MR_Next}, {"\"time_unit\": \"ns\",$", MR_Next}, {"\"bar\": %float,$", MR_Next}, {"\"foo\": %float$", MR_Next}, {"}", MR_Next}}); ADD_CASES( TC_CSVOut, {{"^\"BM_Counters_Threads/threads:%int\",%csv_report,%float,%float$"}}); // VS2013 does not allow this function to be passed as a lambda argument // to CHECK_BENCHMARK_RESULTS() void CheckThreads(Results const& e) { CHECK_COUNTER_VALUE(e, int, "foo", EQ, e.NumThreads()); CHECK_COUNTER_VALUE(e, int, "bar", EQ, 2 * e.NumThreads()); } CHECK_BENCHMARK_RESULTS("BM_Counters_Threads/threads:%int", &CheckThreads); // ========================================================================= // // ---------------------- ThreadAvg Counters Output ------------------------ // // ========================================================================= // void BM_Counters_AvgThreads(benchmark::State& state) { for (auto _ : state) { } namespace bm = benchmark; state.counters["foo"] = bm::Counter{1, bm::Counter::kAvgThreads}; state.counters["bar"] = bm::Counter{2, bm::Counter::kAvgThreads}; } BENCHMARK(BM_Counters_AvgThreads)->ThreadRange(1, 8); ADD_CASES(TC_ConsoleOut, {{"^BM_Counters_AvgThreads/threads:%int " "%console_report bar=%hrfloat foo=%hrfloat$"}}); ADD_CASES(TC_JSONOut, {{"\"name\": \"BM_Counters_AvgThreads/threads:%int\",$"}, {"\"family_index\": 6,$", MR_Next}, {"\"per_family_instance_index\": 0,$", MR_Next}, {"\"run_name\": \"BM_Counters_AvgThreads/threads:%int\",$", MR_Next}, {"\"run_type\": \"iteration\",$", MR_Next}, {"\"repetitions\": 1,$", MR_Next}, {"\"repetition_index\": 0,$", MR_Next}, {"\"threads\": 1,$", MR_Next}, {"\"iterations\": %int,$", MR_Next}, {"\"real_time\": %float,$", MR_Next}, {"\"cpu_time\": %float,$", MR_Next}, {"\"time_unit\": \"ns\",$", MR_Next}, {"\"bar\": %float,$", MR_Next}, {"\"foo\": %float$", MR_Next}, {"}", MR_Next}}); ADD_CASES( TC_CSVOut, {{"^\"BM_Counters_AvgThreads/threads:%int\",%csv_report,%float,%float$"}}); // VS2013 does not allow this function to be passed as a lambda argument // to CHECK_BENCHMARK_RESULTS() void CheckAvgThreads(Results const& e) { CHECK_COUNTER_VALUE(e, int, "foo", EQ, 1); CHECK_COUNTER_VALUE(e, int, "bar", EQ, 2); } CHECK_BENCHMARK_RESULTS("BM_Counters_AvgThreads/threads:%int", &CheckAvgThreads); // ========================================================================= // // ---------------------- ThreadAvg Counters Output ------------------------ // // ========================================================================= // void BM_Counters_AvgThreadsRate(benchmark::State& state) { for (auto _ : state) { // This test requires a non-zero CPU time to avoid divide-by-zero auto iterations = state.iterations(); benchmark::DoNotOptimize(iterations); } namespace bm = benchmark; state.counters["foo"] = bm::Counter{1, bm::Counter::kAvgThreadsRate}; state.counters["bar"] = bm::Counter{2, bm::Counter::kAvgThreadsRate}; } BENCHMARK(BM_Counters_AvgThreadsRate)->ThreadRange(1, 8); ADD_CASES(TC_ConsoleOut, {{"^BM_Counters_AvgThreadsRate/threads:%int " "%console_report bar=%hrfloat/s foo=%hrfloat/s$"}}); ADD_CASES(TC_JSONOut, {{"\"name\": \"BM_Counters_AvgThreadsRate/threads:%int\",$"}, {"\"family_index\": 7,$", MR_Next}, {"\"per_family_instance_index\": 0,$", MR_Next}, {"\"run_name\": \"BM_Counters_AvgThreadsRate/threads:%int\",$", MR_Next}, {"\"run_type\": \"iteration\",$", MR_Next}, {"\"repetitions\": 1,$", MR_Next}, {"\"repetition_index\": 0,$", MR_Next}, {"\"threads\": 1,$", MR_Next}, {"\"iterations\": %int,$", MR_Next}, {"\"real_time\": %float,$", MR_Next}, {"\"cpu_time\": %float,$", MR_Next}, {"\"time_unit\": \"ns\",$", MR_Next}, {"\"bar\": %float,$", MR_Next}, {"\"foo\": %float$", MR_Next}, {"}", MR_Next}}); ADD_CASES(TC_CSVOut, {{"^\"BM_Counters_AvgThreadsRate/" "threads:%int\",%csv_report,%float,%float$"}}); // VS2013 does not allow this function to be passed as a lambda argument // to CHECK_BENCHMARK_RESULTS() void CheckAvgThreadsRate(Results const& e) { CHECK_FLOAT_COUNTER_VALUE(e, "foo", EQ, 1. / e.DurationCPUTime(), 0.001); CHECK_FLOAT_COUNTER_VALUE(e, "bar", EQ, 2. / e.DurationCPUTime(), 0.001); } CHECK_BENCHMARK_RESULTS("BM_Counters_AvgThreadsRate/threads:%int", &CheckAvgThreadsRate); // ========================================================================= // // ------------------- IterationInvariant Counters Output ------------------ // // ========================================================================= // void BM_Counters_IterationInvariant(benchmark::State& state) { for (auto _ : state) { } namespace bm = benchmark; state.counters["foo"] = bm::Counter{1, bm::Counter::kIsIterationInvariant}; state.counters["bar"] = bm::Counter{2, bm::Counter::kIsIterationInvariant}; } BENCHMARK(BM_Counters_IterationInvariant); ADD_CASES(TC_ConsoleOut, {{"^BM_Counters_IterationInvariant %console_report " "bar=%hrfloat foo=%hrfloat$"}}); ADD_CASES(TC_JSONOut, {{"\"name\": \"BM_Counters_IterationInvariant\",$"}, {"\"family_index\": 8,$", MR_Next}, {"\"per_family_instance_index\": 0,$", MR_Next}, {"\"run_name\": \"BM_Counters_IterationInvariant\",$", MR_Next}, {"\"run_type\": \"iteration\",$", MR_Next}, {"\"repetitions\": 1,$", MR_Next}, {"\"repetition_index\": 0,$", MR_Next}, {"\"threads\": 1,$", MR_Next}, {"\"iterations\": %int,$", MR_Next}, {"\"real_time\": %float,$", MR_Next}, {"\"cpu_time\": %float,$", MR_Next}, {"\"time_unit\": \"ns\",$", MR_Next}, {"\"bar\": %float,$", MR_Next}, {"\"foo\": %float$", MR_Next}, {"}", MR_Next}}); ADD_CASES(TC_CSVOut, {{"^\"BM_Counters_IterationInvariant\",%csv_report,%float,%float$"}}); // VS2013 does not allow this function to be passed as a lambda argument // to CHECK_BENCHMARK_RESULTS() void CheckIterationInvariant(Results const& e) { double its = e.NumIterations(); // check that the values are within 0.1% of the expected value CHECK_FLOAT_COUNTER_VALUE(e, "foo", EQ, its, 0.001); CHECK_FLOAT_COUNTER_VALUE(e, "bar", EQ, 2. * its, 0.001); } CHECK_BENCHMARK_RESULTS("BM_Counters_IterationInvariant", &CheckIterationInvariant); // ========================================================================= // // ----------------- IterationInvariantRate Counters Output ---------------- // // ========================================================================= // void BM_Counters_kIsIterationInvariantRate(benchmark::State& state) { for (auto _ : state) { // This test requires a non-zero CPU time to avoid divide-by-zero auto iterations = state.iterations(); benchmark::DoNotOptimize(iterations); } namespace bm = benchmark; state.counters["foo"] = bm::Counter{1, bm::Counter::kIsIterationInvariantRate}; state.counters["bar"] = bm::Counter{2, bm::Counter::kIsRate | bm::Counter::kIsIterationInvariant}; } BENCHMARK(BM_Counters_kIsIterationInvariantRate); ADD_CASES(TC_ConsoleOut, {{"^BM_Counters_kIsIterationInvariantRate " "%console_report bar=%hrfloat/s foo=%hrfloat/s$"}}); ADD_CASES(TC_JSONOut, {{"\"name\": \"BM_Counters_kIsIterationInvariantRate\",$"}, {"\"family_index\": 9,$", MR_Next}, {"\"per_family_instance_index\": 0,$", MR_Next}, {"\"run_name\": \"BM_Counters_kIsIterationInvariantRate\",$", MR_Next}, {"\"run_type\": \"iteration\",$", MR_Next}, {"\"repetitions\": 1,$", MR_Next}, {"\"repetition_index\": 0,$", MR_Next}, {"\"threads\": 1,$", MR_Next}, {"\"iterations\": %int,$", MR_Next}, {"\"real_time\": %float,$", MR_Next}, {"\"cpu_time\": %float,$", MR_Next}, {"\"time_unit\": \"ns\",$", MR_Next}, {"\"bar\": %float,$", MR_Next}, {"\"foo\": %float$", MR_Next}, {"}", MR_Next}}); ADD_CASES(TC_CSVOut, {{"^\"BM_Counters_kIsIterationInvariantRate\",%csv_report," "%float,%float$"}}); // VS2013 does not allow this function to be passed as a lambda argument // to CHECK_BENCHMARK_RESULTS() void CheckIsIterationInvariantRate(Results const& e) { double its = e.NumIterations(); double t = e.DurationCPUTime(); // this (and not real time) is the time used // check that the values are within 0.1% of the expected values CHECK_FLOAT_COUNTER_VALUE(e, "foo", EQ, its * 1. / t, 0.001); CHECK_FLOAT_COUNTER_VALUE(e, "bar", EQ, its * 2. / t, 0.001); } CHECK_BENCHMARK_RESULTS("BM_Counters_kIsIterationInvariantRate", &CheckIsIterationInvariantRate); // ========================================================================= // // --------------------- AvgIterations Counters Output --------------------- // // ========================================================================= // void BM_Counters_AvgIterations(benchmark::State& state) { for (auto _ : state) { } namespace bm = benchmark; state.counters["foo"] = bm::Counter{1, bm::Counter::kAvgIterations}; state.counters["bar"] = bm::Counter{2, bm::Counter::kAvgIterations}; } BENCHMARK(BM_Counters_AvgIterations); ADD_CASES(TC_ConsoleOut, {{"^BM_Counters_AvgIterations %console_report " "bar=%hrfloat foo=%hrfloat$"}}); ADD_CASES(TC_JSONOut, {{"\"name\": \"BM_Counters_AvgIterations\",$"}, {"\"family_index\": 10,$", MR_Next}, {"\"per_family_instance_index\": 0,$", MR_Next}, {"\"run_name\": \"BM_Counters_AvgIterations\",$", MR_Next}, {"\"run_type\": \"iteration\",$", MR_Next}, {"\"repetitions\": 1,$", MR_Next}, {"\"repetition_index\": 0,$", MR_Next}, {"\"threads\": 1,$", MR_Next}, {"\"iterations\": %int,$", MR_Next}, {"\"real_time\": %float,$", MR_Next}, {"\"cpu_time\": %float,$", MR_Next}, {"\"time_unit\": \"ns\",$", MR_Next}, {"\"bar\": %float,$", MR_Next}, {"\"foo\": %float$", MR_Next}, {"}", MR_Next}}); ADD_CASES(TC_CSVOut, {{"^\"BM_Counters_AvgIterations\",%csv_report,%float,%float$"}}); // VS2013 does not allow this function to be passed as a lambda argument // to CHECK_BENCHMARK_RESULTS() void CheckAvgIterations(Results const& e) { double its = e.NumIterations(); // check that the values are within 0.1% of the expected value CHECK_FLOAT_COUNTER_VALUE(e, "foo", EQ, 1. / its, 0.001); CHECK_FLOAT_COUNTER_VALUE(e, "bar", EQ, 2. / its, 0.001); } CHECK_BENCHMARK_RESULTS("BM_Counters_AvgIterations", &CheckAvgIterations); // ========================================================================= // // ------------------- AvgIterationsRate Counters Output ------------------- // // ========================================================================= // void BM_Counters_kAvgIterationsRate(benchmark::State& state) { for (auto _ : state) { // This test requires a non-zero CPU time to avoid divide-by-zero auto iterations = state.iterations(); benchmark::DoNotOptimize(iterations); } namespace bm = benchmark; state.counters["foo"] = bm::Counter{1, bm::Counter::kAvgIterationsRate}; state.counters["bar"] = bm::Counter{2, bm::Counter::kIsRate | bm::Counter::kAvgIterations}; } BENCHMARK(BM_Counters_kAvgIterationsRate); ADD_CASES(TC_ConsoleOut, {{"^BM_Counters_kAvgIterationsRate " "%console_report bar=%hrfloat/s foo=%hrfloat/s$"}}); ADD_CASES(TC_JSONOut, {{"\"name\": \"BM_Counters_kAvgIterationsRate\",$"}, {"\"family_index\": 11,$", MR_Next}, {"\"per_family_instance_index\": 0,$", MR_Next}, {"\"run_name\": \"BM_Counters_kAvgIterationsRate\",$", MR_Next}, {"\"run_type\": \"iteration\",$", MR_Next}, {"\"repetitions\": 1,$", MR_Next}, {"\"repetition_index\": 0,$", MR_Next}, {"\"threads\": 1,$", MR_Next}, {"\"iterations\": %int,$", MR_Next}, {"\"real_time\": %float,$", MR_Next}, {"\"cpu_time\": %float,$", MR_Next}, {"\"time_unit\": \"ns\",$", MR_Next}, {"\"bar\": %float,$", MR_Next}, {"\"foo\": %float$", MR_Next}, {"}", MR_Next}}); ADD_CASES(TC_CSVOut, {{"^\"BM_Counters_kAvgIterationsRate\",%csv_report," "%float,%float$"}}); // VS2013 does not allow this function to be passed as a lambda argument // to CHECK_BENCHMARK_RESULTS() void CheckAvgIterationsRate(Results const& e) { double its = e.NumIterations(); double t = e.DurationCPUTime(); // this (and not real time) is the time used // check that the values are within 0.1% of the expected values CHECK_FLOAT_COUNTER_VALUE(e, "foo", EQ, 1. / its / t, 0.001); CHECK_FLOAT_COUNTER_VALUE(e, "bar", EQ, 2. / its / t, 0.001); } CHECK_BENCHMARK_RESULTS("BM_Counters_kAvgIterationsRate", &CheckAvgIterationsRate); // ========================================================================= // // --------------------------- TEST CASES END ------------------------------ // // ========================================================================= // int main(int argc, char* argv[]) { RunOutputTests(argc, argv); }