tests/PipelineBenchmarks/PipelineBenchmarks.cpp - SwiftShader - Git at Google

 // Copyright 2022 The SwiftShader Authors. All Rights Reserved.
 //
 // 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 "ShaderCore.hpp"
 #include "Reactor/Reactor.hpp"

 #include "benchmark/benchmark.h"

 #include <vector>

 BENCHMARK_MAIN();

 // Macro that creates a lambda wrapper around the input overloaded function,
 // creating a non-overload based on the args. This is useful for passing
 // overloaded functions as template arguments.
 // See https://stackoverflow.com/questions/25871381/c-overloaded-function-as-template-argument
 #define LIFT(fname)                                          \
 	[](auto &&...args) -> decltype(auto) {                   \
 		return fname(std::forward<decltype(args)>(args)...); \
 	}

 namespace sw {

 template<typename Func, class... Args>
 static void Transcendental1(benchmark::State &state, Func func, Args &&...args)
 {
 	const int REPS = state.range(0);

 	FunctionT<void(float *, float *)> function;
 	{
 		Pointer<SIMD::Float> r = Pointer<Float>(function.Arg<0>());
 		Pointer<SIMD::Float> a = Pointer<Float>(function.Arg<1>());

 		for(int i = 0; i < REPS; i++)
 		{
 			r[i] = func(a[i], args...);
 		}
 	}

 	auto routine = function("one");

 	std::vector<float> r(REPS * SIMD::Width);
 	std::vector<float> a(REPS * SIMD::Width, 1.0f);

 	for(auto _ : state)
 	{
 		routine(r.data(), a.data());
 	}
 }

 template<typename Func, class... Args>
 static void Transcendental2(benchmark::State &state, Func func, Args &&...args)
 {
 	const int REPS = state.range(0);

 	FunctionT<void(float *, float *, float *)> function;
 	{
 		Pointer<SIMD::Float> r = Pointer<Float>(function.Arg<0>());
 		Pointer<SIMD::Float> a = Pointer<Float>(function.Arg<1>());
 		Pointer<SIMD::Float> b = Pointer<Float>(function.Arg<2>());

 		for(int i = 0; i < REPS; i++)
 		{
 			r[i] = func(a[i], b[i], args...);
 		}
 	}

 	auto routine = function("two");

 	std::vector<float> r(REPS * SIMD::Width);
 	std::vector<float> a(REPS * SIMD::Width, 0.456f);
 	std::vector<float> b(REPS * SIMD::Width, 0.789f);

 	for(auto _ : state)
 	{
 		routine(r.data(), a.data(), b.data());
 	}
 }

 // No operation; just copy the input to the output, for use as a baseline.
 static SIMD::Float Nop(RValue<SIMD::Float> x)
 {
 	return x;
 }

 static const int REPS = 10;

 BENCHMARK_CAPTURE(Transcendental1, Nop, Nop)->Arg(REPS);

 BENCHMARK_CAPTURE(Transcendental1, rr_Sin, LIFT(rr::Sin))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Sin_highp, LIFT(sw::Sin), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Sin_mediump, LIFT(sw::Sin), true /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, rr_Cos, LIFT(rr::Cos))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Cos_highp, LIFT(sw::Cos), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Cos_mediump, LIFT(sw::Cos), true /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, rr_Tan, LIFT(rr::Tan))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Tan_highp, LIFT(sw::Tan), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Tan_mediump, LIFT(sw::Tan), true /* relaxedPrecision */)->Arg(REPS);

 BENCHMARK_CAPTURE(Transcendental1, rr_Asin, LIFT(rr::Asin))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Asin_highp, LIFT(sw::Asin), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Asin_mediump, LIFT(sw::Asin), true /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, rr_Acos, LIFT(rr::Acos))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Acos_highp, LIFT(sw::Acos), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Acos_mediump, LIFT(sw::Acos), true /* relaxedPrecision */)->Arg(REPS);

 BENCHMARK_CAPTURE(Transcendental1, rr_Atan, LIFT(rr::Atan))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Atan_highp, LIFT(sw::Atan), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Atan_mediump, LIFT(sw::Atan), true /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, rr_Sinh, LIFT(rr::Sinh))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Sinh_highp, LIFT(sw::Sinh), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Sinh_mediump, LIFT(sw::Sinh), true /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, rr_Cosh, LIFT(rr::Cosh))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Cosh_highp, LIFT(sw::Cosh), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Cosh_mediump, LIFT(sw::Cosh), true /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, rr_Tanh, LIFT(rr::Tanh))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Tanh_highp, LIFT(sw::Tanh), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Tanh_mediump, LIFT(sw::Tanh), true /* relaxedPrecision */)->Arg(REPS);

 BENCHMARK_CAPTURE(Transcendental1, rr_Asinh, LIFT(rr::Asinh))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Asinh_highp, LIFT(sw::Asinh), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Asinh_mediump, LIFT(sw::Asinh), true /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, rr_Acosh, LIFT(rr::Acosh))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Acosh_highp, LIFT(sw::Acosh), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Acosh_mediump, LIFT(sw::Acosh), true /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, rr_Atanh, LIFT(rr::Atanh))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Atanh_highp, LIFT(sw::Atanh), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Atanh_mediump, LIFT(sw::Atanh), true /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental2, rr_Atan2, LIFT(rr::Atan2))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental2, sw_Atan2_highp, LIFT(sw::Atan2), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental2, sw_Atan2_mediump, LIFT(sw::Atan2), true /* relaxedPrecision */)->Arg(REPS);

 BENCHMARK_CAPTURE(Transcendental2, rr_Pow, LIFT(rr::Pow))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental2, sw_Pow_highp, LIFT(sw::Pow<sw::Highp>))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental2, sw_Pow_mediump, LIFT(sw::Pow<sw::Mediump>))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, rr_Exp, LIFT(rr::Exp))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Exp_highp, LIFT(sw::Exp), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Exp_mediump, LIFT(sw::Exp), true /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, rr_Log, LIFT(rr::Log))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Log_highp, LIFT(sw::Log), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Log_mediump, LIFT(sw::Log), true /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, rr_Exp2, LIFT(rr::Exp2))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Exp2_highp, LIFT(sw::Exp2), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Exp2_mediump, LIFT(sw::Exp2), true /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, rr_Log2, LIFT(rr::Log2))->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Log2_highp, LIFT(sw::Log2), false /* relaxedPrecision */)->Arg(REPS);
 BENCHMARK_CAPTURE(Transcendental1, sw_Log2_mediump, LIFT(sw::Log2), true /* relaxedPrecision */)->Arg(REPS);

 }  // namespace sw
	// Copyright 2022 The SwiftShader Authors. All Rights Reserved.
	//
	// 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 "ShaderCore.hpp"
	#include "Reactor/Reactor.hpp"

	#include "benchmark/benchmark.h"

	#include <vector>

	BENCHMARK_MAIN();

	// Macro that creates a lambda wrapper around the input overloaded function,
	// creating a non-overload based on the args. This is useful for passing
	// overloaded functions as template arguments.
	// See https://stackoverflow.com/questions/25871381/c-overloaded-function-as-template-argument
	#define LIFT(fname) \
	[](auto &&...args) -> decltype(auto) { \
	return fname(std::forward<decltype(args)>(args)...); \
	}

	namespace sw {

	template<typename Func, class... Args>
	static void Transcendental1(benchmark::State &state, Func func, Args &&...args)
	{
	const int REPS = state.range(0);

	FunctionT<void(float , float )> function;
	{
	Pointer<SIMD::Float> r = Pointer<Float>(function.Arg<0>());
	Pointer<SIMD::Float> a = Pointer<Float>(function.Arg<1>());

	for(int i = 0; i < REPS; i++)
	{
	r[i] = func(a[i], args...);
	}
	}

	auto routine = function("one");

	std::vector<float> r(REPS * SIMD::Width);
	std::vector<float> a(REPS * SIMD::Width, 1.0f);

	for(auto _ : state)
	{
	routine(r.data(), a.data());
	}
	}

	template<typename Func, class... Args>
	static void Transcendental2(benchmark::State &state, Func func, Args &&...args)
	{
	const int REPS = state.range(0);

	FunctionT<void(float , float , float *)> function;
	{
	Pointer<SIMD::Float> r = Pointer<Float>(function.Arg<0>());
	Pointer<SIMD::Float> a = Pointer<Float>(function.Arg<1>());
	Pointer<SIMD::Float> b = Pointer<Float>(function.Arg<2>());

	for(int i = 0; i < REPS; i++)
	{
	r[i] = func(a[i], b[i], args...);
	}
	}

	auto routine = function("two");

	std::vector<float> r(REPS * SIMD::Width);
	std::vector<float> a(REPS * SIMD::Width, 0.456f);
	std::vector<float> b(REPS * SIMD::Width, 0.789f);

	for(auto _ : state)
	{
	routine(r.data(), a.data(), b.data());
	}
	}

	// No operation; just copy the input to the output, for use as a baseline.
	static SIMD::Float Nop(RValue<SIMD::Float> x)
	{
	return x;
	}

	static const int REPS = 10;

	BENCHMARK_CAPTURE(Transcendental1, Nop, Nop)->Arg(REPS);

	BENCHMARK_CAPTURE(Transcendental1, rr_Sin, LIFT(rr::Sin))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Sin_highp, LIFT(sw::Sin), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Sin_mediump, LIFT(sw::Sin), true /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, rr_Cos, LIFT(rr::Cos))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Cos_highp, LIFT(sw::Cos), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Cos_mediump, LIFT(sw::Cos), true /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, rr_Tan, LIFT(rr::Tan))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Tan_highp, LIFT(sw::Tan), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Tan_mediump, LIFT(sw::Tan), true /* relaxedPrecision */)->Arg(REPS);

	BENCHMARK_CAPTURE(Transcendental1, rr_Asin, LIFT(rr::Asin))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Asin_highp, LIFT(sw::Asin), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Asin_mediump, LIFT(sw::Asin), true /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, rr_Acos, LIFT(rr::Acos))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Acos_highp, LIFT(sw::Acos), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Acos_mediump, LIFT(sw::Acos), true /* relaxedPrecision */)->Arg(REPS);

	BENCHMARK_CAPTURE(Transcendental1, rr_Atan, LIFT(rr::Atan))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Atan_highp, LIFT(sw::Atan), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Atan_mediump, LIFT(sw::Atan), true /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, rr_Sinh, LIFT(rr::Sinh))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Sinh_highp, LIFT(sw::Sinh), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Sinh_mediump, LIFT(sw::Sinh), true /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, rr_Cosh, LIFT(rr::Cosh))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Cosh_highp, LIFT(sw::Cosh), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Cosh_mediump, LIFT(sw::Cosh), true /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, rr_Tanh, LIFT(rr::Tanh))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Tanh_highp, LIFT(sw::Tanh), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Tanh_mediump, LIFT(sw::Tanh), true /* relaxedPrecision */)->Arg(REPS);

	BENCHMARK_CAPTURE(Transcendental1, rr_Asinh, LIFT(rr::Asinh))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Asinh_highp, LIFT(sw::Asinh), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Asinh_mediump, LIFT(sw::Asinh), true /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, rr_Acosh, LIFT(rr::Acosh))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Acosh_highp, LIFT(sw::Acosh), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Acosh_mediump, LIFT(sw::Acosh), true /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, rr_Atanh, LIFT(rr::Atanh))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Atanh_highp, LIFT(sw::Atanh), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Atanh_mediump, LIFT(sw::Atanh), true /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental2, rr_Atan2, LIFT(rr::Atan2))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental2, sw_Atan2_highp, LIFT(sw::Atan2), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental2, sw_Atan2_mediump, LIFT(sw::Atan2), true /* relaxedPrecision */)->Arg(REPS);

	BENCHMARK_CAPTURE(Transcendental2, rr_Pow, LIFT(rr::Pow))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental2, sw_Pow_highp, LIFT(sw::Pow<sw::Highp>))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental2, sw_Pow_mediump, LIFT(sw::Pow<sw::Mediump>))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, rr_Exp, LIFT(rr::Exp))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Exp_highp, LIFT(sw::Exp), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Exp_mediump, LIFT(sw::Exp), true /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, rr_Log, LIFT(rr::Log))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Log_highp, LIFT(sw::Log), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Log_mediump, LIFT(sw::Log), true /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, rr_Exp2, LIFT(rr::Exp2))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Exp2_highp, LIFT(sw::Exp2), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Exp2_mediump, LIFT(sw::Exp2), true /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, rr_Log2, LIFT(rr::Log2))->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Log2_highp, LIFT(sw::Log2), false /* relaxedPrecision */)->Arg(REPS);
	BENCHMARK_CAPTURE(Transcendental1, sw_Log2_mediump, LIFT(sw::Log2), true /* relaxedPrecision */)->Arg(REPS);

	} // namespace sw