/* * Copyright (C) 2013 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. */ #include #include #include #include "util.h" static const double values[] = { 1234.0, nan(""), HUGE_VAL, 0.0 }; static const char* names[] = { "1234.0", "nan", "HUGE_VAL", "0.0" }; static void SetLabel(benchmark::State& state) { state.SetLabel(names[state.range(0)]); } // Avoid optimization. volatile double d; volatile double v; volatile float f; static float zero = 0.0f; static double zerod = 0.0f; static void BM_math_sqrt(benchmark::State& state) { d = 0.0; v = 2.0; while (state.KeepRunning()) { d += sqrt(v); } } BIONIC_BENCHMARK(BM_math_sqrt); static void BM_math_log10(benchmark::State& state) { d = 0.0; v = 1234.0; while (state.KeepRunning()) { d += log10(v); } } BIONIC_BENCHMARK(BM_math_log10); static void BM_math_logb(benchmark::State& state) { d = 0.0; v = 1234.0; while (state.KeepRunning()) { d += logb(v); } } BIONIC_BENCHMARK(BM_math_logb); static void BM_math_isfinite_macro(benchmark::State& state) { d = 0.0; v = values[state.range(0)]; while (state.KeepRunning()) { d += isfinite(v); } SetLabel(state); } BIONIC_BENCHMARK_WITH_ARG(BM_math_isfinite_macro, "MATH_COMMON"); static void BM_math_isfinite(benchmark::State& state) { d = 0.0; v = values[state.range(0)]; while (state.KeepRunning()) { d += isfinite(v); } SetLabel(state); } BIONIC_BENCHMARK_WITH_ARG(BM_math_isfinite, "MATH_COMMON"); static void BM_math_isinf_macro(benchmark::State& state) { d = 0.0; v = values[state.range(0)]; while (state.KeepRunning()) { d += isinf(v); } SetLabel(state); } BIONIC_BENCHMARK_WITH_ARG(BM_math_isinf_macro, "MATH_COMMON"); static void BM_math_isinf(benchmark::State& state) { d = 0.0; v = values[state.range(0)]; while (state.KeepRunning()) { d += (isinf)(v); } SetLabel(state); } BIONIC_BENCHMARK_WITH_ARG(BM_math_isinf, "MATH_COMMON"); static void BM_math_isnan_macro(benchmark::State& state) { d = 0.0; v = values[state.range(0)]; while (state.KeepRunning()) { d += isnan(v); } SetLabel(state); } BIONIC_BENCHMARK_WITH_ARG(BM_math_isnan_macro, "MATH_COMMON"); static void BM_math_isnan(benchmark::State& state) { d = 0.0; v = values[state.range(0)]; while (state.KeepRunning()) { d += (isnan)(v); } SetLabel(state); } BIONIC_BENCHMARK_WITH_ARG(BM_math_isnan, "MATH_COMMON"); static void BM_math_isnormal_macro(benchmark::State& state) { d = 0.0; v = values[state.range(0)]; while (state.KeepRunning()) { d += isnormal(v); } SetLabel(state); } BIONIC_BENCHMARK_WITH_ARG(BM_math_isnormal_macro, "MATH_COMMON"); static void BM_math_isnormal(benchmark::State& state) { d = 0.0; v = values[state.range(0)]; while (state.KeepRunning()) { d += isnormal(v); } SetLabel(state); } BIONIC_BENCHMARK_WITH_ARG(BM_math_isnormal, "MATH_COMMON"); static void BM_math_sin_fast(benchmark::State& state) { d = 1.0; while (state.KeepRunning()) { d += sin(d); } } BIONIC_BENCHMARK(BM_math_sin_fast); static void BM_math_sin_feupdateenv(benchmark::State& state) { d = 1.0; while (state.KeepRunning()) { fenv_t __libc_save_rm; feholdexcept(&__libc_save_rm); fesetround(FE_TONEAREST); d += sin(d); feupdateenv(&__libc_save_rm); } } BIONIC_BENCHMARK(BM_math_sin_feupdateenv); static void BM_math_sin_fesetenv(benchmark::State& state) { d = 1.0; while (state.KeepRunning()) { fenv_t __libc_save_rm; feholdexcept(&__libc_save_rm); fesetround(FE_TONEAREST); d += sin(d); fesetenv(&__libc_save_rm); } } BIONIC_BENCHMARK(BM_math_sin_fesetenv); static void BM_math_fpclassify(benchmark::State& state) { d = 0.0; v = values[state.range(0)]; while (state.KeepRunning()) { d += fpclassify(v); } SetLabel(state); } BIONIC_BENCHMARK_WITH_ARG(BM_math_fpclassify, "MATH_COMMON"); static void BM_math_signbit_macro(benchmark::State& state) { d = 0.0; v = values[state.range(0)]; while (state.KeepRunning()) { d += signbit(v); } SetLabel(state); } BIONIC_BENCHMARK_WITH_ARG(BM_math_signbit_macro, "MATH_COMMON"); static void BM_math_signbit(benchmark::State& state) { d = 0.0; v = values[state.range(0)]; while (state.KeepRunning()) { d += signbit(v); } SetLabel(state); } BIONIC_BENCHMARK_WITH_ARG(BM_math_signbit, "MATH_COMMON"); static void BM_math_fabs_macro(benchmark::State& state) { d = 0.0; v = values[state.range(0)]; while (state.KeepRunning()) { d += fabs(v); } SetLabel(state); } BIONIC_BENCHMARK_WITH_ARG(BM_math_fabs_macro, "MATH_COMMON"); static void BM_math_fabs(benchmark::State& state) { d = 0.0; v = values[state.range(0)]; while (state.KeepRunning()) { d += (fabs)(v); } SetLabel(state); } BIONIC_BENCHMARK_WITH_ARG(BM_math_fabs, "MATH_COMMON"); static void BM_math_sincos(benchmark::State& state) { d = 1.0; while (state.KeepRunning()) { double s, c; sincos(d, &s, &c); d += s + c; } } BIONIC_BENCHMARK(BM_math_sincos); #include "expf_input.cpp" static void BM_math_expf_speccpu2017(benchmark::State& state) { f = 0.0; auto cin = expf_input.cbegin(); for (auto _ : state) { f = expf(*cin); if (++cin == expf_input.cend()) cin = expf_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_expf_speccpu2017); static void BM_math_expf_speccpu2017_latency(benchmark::State& state) { f = 0.0; auto cin = expf_input.cbegin(); for (auto _ : state) { f = expf(f * zero + *cin); if (++cin == expf_input.cend()) cin = expf_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_expf_speccpu2017_latency); // Create a double version of expf_input to avoid overhead of float to // double conversion. static const std::vector exp_input (expf_input.begin(), expf_input.end()); static void BM_math_exp_speccpu2017(benchmark::State& state) { d = 0.0; auto cin = exp_input.cbegin(); for (auto _ : state) { d = exp(*cin); if (++cin == exp_input.cend()) cin = exp_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_exp_speccpu2017); static void BM_math_exp_speccpu2017_latency(benchmark::State& state) { d = 0.0; auto cin = exp_input.cbegin(); for (auto _ : state) { d = exp(d * zerod + *cin); if (++cin == exp_input.cend()) cin = exp_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_exp_speccpu2017_latency); static void BM_math_exp2f_speccpu2017(benchmark::State& state) { f = 0.0; auto cin = expf_input.cbegin(); for (auto _ : state) { f = exp2f(*cin); if (++cin == expf_input.cend()) cin = expf_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_exp2f_speccpu2017); static void BM_math_exp2f_speccpu2017_latency(benchmark::State& state) { f = 0.0; auto cin = expf_input.cbegin(); for (auto _ : state) { f = exp2f(f * zero + *cin); if (++cin == expf_input.cend()) cin = expf_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_exp2f_speccpu2017_latency); static void BM_math_exp2_speccpu2017(benchmark::State& state) { d = 0.0; auto cin = exp_input.cbegin(); for (auto _ : state) { f = exp2(*cin); if (++cin == exp_input.cend()) cin = exp_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_exp2_speccpu2017); static void BM_math_exp2_speccpu2017_latency(benchmark::State& state) { d = 0.0; auto cin = exp_input.cbegin(); for (auto _ : state) { f = exp2(d * zero + *cin); if (++cin == exp_input.cend()) cin = exp_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_exp2_speccpu2017_latency); #include "powf_input.cpp" static const std::vector> pow_input (powf_input.begin(), powf_input.end()); static void BM_math_powf_speccpu2006(benchmark::State& state) { f = 0.0; auto cin = powf_input.cbegin(); for (auto _ : state) { f = powf(cin->first, cin->second); if (++cin == powf_input.cend()) cin = powf_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_powf_speccpu2006); static void BM_math_powf_speccpu2017_latency(benchmark::State& state) { f = 0.0; auto cin = powf_input.cbegin(); for (auto _ : state) { f = powf(f * zero + cin->first, cin->second); if (++cin == powf_input.cend()) cin = powf_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_powf_speccpu2017_latency); static void BM_math_pow_speccpu2006(benchmark::State& state) { d = 0.0; auto cin = pow_input.cbegin(); for (auto _ : state) { f = pow(cin->first, cin->second); if (++cin == pow_input.cend()) cin = pow_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_pow_speccpu2006); static void BM_math_pow_speccpu2017_latency(benchmark::State& state) { d = 0.0; auto cin = pow_input.cbegin(); for (auto _ : state) { d = powf(d * zero + cin->first, cin->second); if (++cin == pow_input.cend()) cin = pow_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_pow_speccpu2017_latency); #include "logf_input.cpp" static const std::vector log_input (logf_input.begin(), logf_input.end()); static void BM_math_logf_speccpu2017(benchmark::State& state) { f = 0.0; auto cin = logf_input.cbegin(); for (auto _ : state) { f = logf(*cin); if (++cin == logf_input.cend()) cin = logf_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_logf_speccpu2017); static void BM_math_logf_speccpu2017_latency(benchmark::State& state) { f = 0.0; auto cin = logf_input.cbegin(); for (auto _ : state) { f = logf(f * zero + *cin); if (++cin == logf_input.cend()) cin = logf_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_logf_speccpu2017_latency); static void BM_math_log_speccpu2017(benchmark::State& state) { d = 0.0; auto cin = log_input.cbegin(); for (auto _ : state) { d = log(*cin); if (++cin == log_input.cend()) cin = log_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_log_speccpu2017); static void BM_math_log_speccpu2017_latency(benchmark::State& state) { d = 0.0; auto cin = log_input.cbegin(); for (auto _ : state) { d = log(d * zerod + *cin); if (++cin == log_input.cend()) cin = log_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_log_speccpu2017_latency); static void BM_math_log2f_speccpu2017(benchmark::State& state) { f = 0.0; auto cin = logf_input.cbegin(); for (auto _ : state) { f = log2f(*cin); if (++cin == logf_input.cend()) cin = logf_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_log2f_speccpu2017); static void BM_math_log2_speccpu2017_latency(benchmark::State& state) { d = 0.0; auto cin = log_input.cbegin(); for (auto _ : state) { d = log2(d * zerod + *cin); if (++cin == log_input.cend()) cin = log_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_log2_speccpu2017_latency); static void BM_math_log2_speccpu2017(benchmark::State& state) { d = 0.0; auto cin = log_input.cbegin(); for (auto _ : state) { d = log2(*cin); if (++cin == log_input.cend()) cin = log_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_log2_speccpu2017); static void BM_math_log2f_speccpu2017_latency(benchmark::State& state) { f = 0.0; auto cin = logf_input.cbegin(); for (auto _ : state) { f = log2f(f * zero + *cin); if (++cin == logf_input.cend()) cin = logf_input.cbegin(); } } BIONIC_BENCHMARK(BM_math_log2f_speccpu2017_latency); // Four ranges of values are checked: // * 0.0 <= x < 0.1 // * 0.1 <= x < 0.7 // * 0.7 <= x < 3.1 // * -3.1 <= x < 3.1 // * 3.3 <= x < 33.3 // * 100.0 <= x < 1000.0 // * 1e6 <= x < 1e32 // * 1e32 < x < FLT_MAX #include "sincosf_input.cpp" static void BM_math_sinf(benchmark::State& state) { auto range = sincosf_input[state.range(0)]; auto cin = range.values.cbegin(); f = 0.0; for (auto _ : state) { f = sinf(*cin); if (++cin == range.values.cend()) cin = range.values.cbegin(); } state.SetLabel(range.label); } BIONIC_BENCHMARK_WITH_ARG(BM_math_sinf, "MATH_SINCOS_COMMON"); static void BM_math_sinf_latency(benchmark::State& state) { auto range = sincosf_input[state.range(0)]; auto cin = range.values.cbegin(); f = 0.0; for (auto _ : state) { f = sinf(f * zero + *cin); if (++cin == range.values.cend()) cin = range.values.cbegin(); } state.SetLabel(range.label); } BIONIC_BENCHMARK_WITH_ARG(BM_math_sinf_latency, "MATH_SINCOS_COMMON"); static void BM_math_cosf(benchmark::State& state) { auto range = sincosf_input[state.range(0)]; auto cin = range.values.cbegin(); f = 0.0; for (auto _ : state) { f = cosf(*cin); if (++cin == range.values.cend()) cin = range.values.cbegin(); } state.SetLabel(range.label); } BIONIC_BENCHMARK_WITH_ARG(BM_math_cosf, "MATH_SINCOS_COMMON"); static void BM_math_cosf_latency(benchmark::State& state) { auto range = sincosf_input[state.range(0)]; auto cin = range.values.cbegin(); f = 0.0; for (auto _ : state) { f = cosf(f * zero + *cin); if (++cin == range.values.cend()) cin = range.values.cbegin(); } state.SetLabel(range.label); } BIONIC_BENCHMARK_WITH_ARG(BM_math_cosf_latency, "MATH_SINCOS_COMMON"); static void BM_math_sincosf(benchmark::State& state) { auto range = sincosf_input[state.range(0)]; auto cin = range.values.cbegin(); f = 0.0; for (auto _ : state) { float s, c; sincosf(*cin, &s, &c); f += s; if (++cin == range.values.cend()) cin = range.values.cbegin(); } state.SetLabel(range.label); } BIONIC_BENCHMARK_WITH_ARG(BM_math_sincosf, "MATH_SINCOS_COMMON"); static void BM_math_sincosf_latency(benchmark::State& state) { auto range = sincosf_input[state.range(0)]; auto cin = range.values.cbegin(); f = 0.0; for (auto _ : state) { float s, c; sincosf(f * zero + *cin, &s, &c); f += s; if (++cin == range.values.cend()) cin = range.values.cbegin(); } state.SetLabel(range.label); } BIONIC_BENCHMARK_WITH_ARG(BM_math_sincosf_latency, "MATH_SINCOS_COMMON");