media/base/vector_math_perftest.cc - chromium/src - Git at Google

 // Copyright 2013 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include <memory>

 #include "base/macros.h"
 #include "base/memory/aligned_memory.h"
 #include "base/time/time.h"
 #include "build/build_config.h"
 #include "media/base/vector_math.h"
 #include "media/base/vector_math_testing.h"
 #include "testing/gtest/include/gtest/gtest.h"
 #include "testing/perf/perf_test.h"

 using base::TimeTicks;
 using std::fill;

 namespace media {

 static const int kBenchmarkIterations = 200000;
 static const int kEWMABenchmarkIterations = 50000;
 static const float kScale = 0.5;
 static const int kVectorSize = 8192;

 class VectorMathPerfTest : public testing::Test {
  public:
   VectorMathPerfTest() {
     // Initialize input and output vectors.
     input_vector_.reset(static_cast<float*>(base::AlignedAlloc(
         sizeof(float) * kVectorSize, vector_math::kRequiredAlignment)));
     output_vector_.reset(static_cast<float*>(base::AlignedAlloc(
         sizeof(float) * kVectorSize, vector_math::kRequiredAlignment)));
     fill(input_vector_.get(), input_vector_.get() + kVectorSize, 1.0f);
     fill(output_vector_.get(), output_vector_.get() + kVectorSize, 0.0f);
   }

   void RunBenchmark(void (*fn)(const float[], float, int, float[]),
                     bool aligned,
                     const std::string& test_name,
                     const std::string& trace_name) {
     TimeTicks start = TimeTicks::Now();
     for (int i = 0; i < kBenchmarkIterations; ++i) {
       fn(input_vector_.get(),
          kScale,
          kVectorSize - (aligned ? 0 : 1),
          output_vector_.get());
     }
     double total_time_milliseconds =
         (TimeTicks::Now() - start).InMillisecondsF();
     perf_test::PrintResult(test_name,
                            "",
                            trace_name,
                            kBenchmarkIterations / total_time_milliseconds,
                            "runs/ms",
                            true);
   }

   void RunBenchmark(
       std::pair<float, float> (*fn)(float, const float[], int, float),
       int len,
       const std::string& test_name,
       const std::string& trace_name) {
     TimeTicks start = TimeTicks::Now();
     for (int i = 0; i < kEWMABenchmarkIterations; ++i) {
       fn(0.5f, input_vector_.get(), len, 0.1f);
     }
     double total_time_milliseconds =
         (TimeTicks::Now() - start).InMillisecondsF();
     perf_test::PrintResult(test_name,
                            "",
                            trace_name,
                            kEWMABenchmarkIterations / total_time_milliseconds,
                            "runs/ms",
                            true);
   }

  protected:
   std::unique_ptr<float, base::AlignedFreeDeleter> input_vector_;
   std::unique_ptr<float, base::AlignedFreeDeleter> output_vector_;

   DISALLOW_COPY_AND_ASSIGN(VectorMathPerfTest);
 };

 // Define platform dependent function names for SIMD optimized methods.
 #if defined(ARCH_CPU_X86_FAMILY)
 #define FMAC_FUNC FMAC_SSE
 #define FMUL_FUNC FMUL_SSE
 #define EWMAAndMaxPower_FUNC EWMAAndMaxPower_SSE
 #elif defined(ARCH_CPU_ARM_FAMILY) && defined(USE_NEON)
 #define FMAC_FUNC FMAC_NEON
 #define FMUL_FUNC FMUL_NEON
 #define EWMAAndMaxPower_FUNC EWMAAndMaxPower_NEON
 #endif

 // Benchmarks for each optimized vector_math::FMAC() method.
 // Benchmark FMAC_C().
 TEST_F(VectorMathPerfTest, FMAC_unoptimized) {
   RunBenchmark(
       vector_math::FMAC_C, true, "vector_math_fmac", "unoptimized");
 }

 #if defined(FMAC_FUNC)
 // Benchmark FMAC_FUNC() with unaligned size.
 TEST_F(VectorMathPerfTest, FMAC_optimized_unaligned) {
   ASSERT_NE((kVectorSize - 1) % (vector_math::kRequiredAlignment /
                                  sizeof(float)), 0U);
   RunBenchmark(
       vector_math::FMAC_FUNC, false, "vector_math_fmac", "optimized_unaligned");
 }

 // Benchmark FMAC_FUNC() with aligned size.
 TEST_F(VectorMathPerfTest, FMAC_optimized_aligned) {
   ASSERT_EQ(kVectorSize % (vector_math::kRequiredAlignment / sizeof(float)),
             0U);
   RunBenchmark(
       vector_math::FMAC_FUNC, true, "vector_math_fmac", "optimized_aligned");
 }
 #endif

 // Benchmarks for each optimized vector_math::FMUL() method.
 // Benchmark FMUL_C().
 TEST_F(VectorMathPerfTest, FMUL_unoptimized) {
   RunBenchmark(
       vector_math::FMUL_C, true, "vector_math_fmul", "unoptimized");
 }

 #if defined(FMUL_FUNC)
 // Benchmark FMUL_FUNC() with unaligned size.
 TEST_F(VectorMathPerfTest, FMUL_optimized_unaligned) {
   ASSERT_NE((kVectorSize - 1) % (vector_math::kRequiredAlignment /
                                  sizeof(float)), 0U);
   RunBenchmark(
       vector_math::FMUL_FUNC, false, "vector_math_fmul", "optimized_unaligned");
 }

 // Benchmark FMUL_FUNC() with aligned size.
 TEST_F(VectorMathPerfTest, FMUL_optimized_aligned) {
   ASSERT_EQ(kVectorSize % (vector_math::kRequiredAlignment / sizeof(float)),
             0U);
   RunBenchmark(
       vector_math::FMUL_FUNC, true, "vector_math_fmul", "optimized_aligned");
 }
 #endif

 // Benchmarks for each optimized vector_math::EWMAAndMaxPower() method.
 // Benchmark EWMAAndMaxPower_C().
 TEST_F(VectorMathPerfTest, EWMAAndMaxPower_unoptimized) {
   RunBenchmark(vector_math::EWMAAndMaxPower_C,
                kVectorSize,
                "vector_math_ewma_and_max_power",
                "unoptimized");
 }

 #if defined(EWMAAndMaxPower_FUNC)
 // Benchmark EWMAAndMaxPower_FUNC() with unaligned size.
 TEST_F(VectorMathPerfTest, EWMAAndMaxPower_optimized_unaligned) {
   ASSERT_NE((kVectorSize - 1) % (vector_math::kRequiredAlignment /
                                  sizeof(float)), 0U);
   RunBenchmark(vector_math::EWMAAndMaxPower_FUNC,
                kVectorSize - 1,
                "vector_math_ewma_and_max_power",
                "optimized_unaligned");
 }

 // Benchmark EWMAAndMaxPower_FUNC() with aligned size.
 TEST_F(VectorMathPerfTest, EWMAAndMaxPower_optimized_aligned) {
   ASSERT_EQ(kVectorSize % (vector_math::kRequiredAlignment / sizeof(float)),
             0U);
   RunBenchmark(vector_math::EWMAAndMaxPower_FUNC,
                kVectorSize,
                "vector_math_ewma_and_max_power",
                "optimized_aligned");
 }
 #endif

 } // namespace media
	// Copyright 2013 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include <memory>

	#include "base/macros.h"
	#include "base/memory/aligned_memory.h"
	#include "base/time/time.h"
	#include "build/build_config.h"
	#include "media/base/vector_math.h"
	#include "media/base/vector_math_testing.h"
	#include "testing/gtest/include/gtest/gtest.h"
	#include "testing/perf/perf_test.h"

	using base::TimeTicks;
	using std::fill;

	namespace media {

	static const int kBenchmarkIterations = 200000;
	static const int kEWMABenchmarkIterations = 50000;
	static const float kScale = 0.5;
	static const int kVectorSize = 8192;

	class VectorMathPerfTest : public testing::Test {
	public:
	VectorMathPerfTest() {
	// Initialize input and output vectors.
	input_vector_.reset(static_cast<float*>(base::AlignedAlloc(
	sizeof(float) * kVectorSize, vector_math::kRequiredAlignment)));
	output_vector_.reset(static_cast<float*>(base::AlignedAlloc(
	sizeof(float) * kVectorSize, vector_math::kRequiredAlignment)));
	fill(input_vector_.get(), input_vector_.get() + kVectorSize, 1.0f);
	fill(output_vector_.get(), output_vector_.get() + kVectorSize, 0.0f);
	}

	void RunBenchmark(void (*fn)(const float[], float, int, float[]),
	bool aligned,
	const std::string& test_name,
	const std::string& trace_name) {
	TimeTicks start = TimeTicks::Now();
	for (int i = 0; i < kBenchmarkIterations; ++i) {
	fn(input_vector_.get(),
	kScale,
	kVectorSize - (aligned ? 0 : 1),
	output_vector_.get());
	}
	double total_time_milliseconds =
	(TimeTicks::Now() - start).InMillisecondsF();
	perf_test::PrintResult(test_name,
	"",
	trace_name,
	kBenchmarkIterations / total_time_milliseconds,
	"runs/ms",
	true);
	}

	void RunBenchmark(
	std::pair<float, float> (*fn)(float, const float[], int, float),
	int len,
	const std::string& test_name,
	const std::string& trace_name) {
	TimeTicks start = TimeTicks::Now();
	for (int i = 0; i < kEWMABenchmarkIterations; ++i) {
	fn(0.5f, input_vector_.get(), len, 0.1f);
	}
	double total_time_milliseconds =
	(TimeTicks::Now() - start).InMillisecondsF();
	perf_test::PrintResult(test_name,
	"",
	trace_name,
	kEWMABenchmarkIterations / total_time_milliseconds,
	"runs/ms",
	true);
	}

	protected:
	std::unique_ptr<float, base::AlignedFreeDeleter> input_vector_;
	std::unique_ptr<float, base::AlignedFreeDeleter> output_vector_;

	DISALLOW_COPY_AND_ASSIGN(VectorMathPerfTest);
	};

	// Define platform dependent function names for SIMD optimized methods.
	#if defined(ARCH_CPU_X86_FAMILY)
	#define FMAC_FUNC FMAC_SSE
	#define FMUL_FUNC FMUL_SSE
	#define EWMAAndMaxPower_FUNC EWMAAndMaxPower_SSE
	#elif defined(ARCH_CPU_ARM_FAMILY) && defined(USE_NEON)
	#define FMAC_FUNC FMAC_NEON
	#define FMUL_FUNC FMUL_NEON
	#define EWMAAndMaxPower_FUNC EWMAAndMaxPower_NEON
	#endif

	// Benchmarks for each optimized vector_math::FMAC() method.
	// Benchmark FMAC_C().
	TEST_F(VectorMathPerfTest, FMAC_unoptimized) {
	RunBenchmark(
	vector_math::FMAC_C, true, "vector_math_fmac", "unoptimized");
	}

	#if defined(FMAC_FUNC)
	// Benchmark FMAC_FUNC() with unaligned size.
	TEST_F(VectorMathPerfTest, FMAC_optimized_unaligned) {
	ASSERT_NE((kVectorSize - 1) % (vector_math::kRequiredAlignment /
	sizeof(float)), 0U);
	RunBenchmark(
	vector_math::FMAC_FUNC, false, "vector_math_fmac", "optimized_unaligned");
	}

	// Benchmark FMAC_FUNC() with aligned size.
	TEST_F(VectorMathPerfTest, FMAC_optimized_aligned) {
	ASSERT_EQ(kVectorSize % (vector_math::kRequiredAlignment / sizeof(float)),
	0U);
	RunBenchmark(
	vector_math::FMAC_FUNC, true, "vector_math_fmac", "optimized_aligned");
	}
	#endif

	// Benchmarks for each optimized vector_math::FMUL() method.
	// Benchmark FMUL_C().
	TEST_F(VectorMathPerfTest, FMUL_unoptimized) {
	RunBenchmark(
	vector_math::FMUL_C, true, "vector_math_fmul", "unoptimized");
	}

	#if defined(FMUL_FUNC)
	// Benchmark FMUL_FUNC() with unaligned size.
	TEST_F(VectorMathPerfTest, FMUL_optimized_unaligned) {
	ASSERT_NE((kVectorSize - 1) % (vector_math::kRequiredAlignment /
	sizeof(float)), 0U);
	RunBenchmark(
	vector_math::FMUL_FUNC, false, "vector_math_fmul", "optimized_unaligned");
	}

	// Benchmark FMUL_FUNC() with aligned size.
	TEST_F(VectorMathPerfTest, FMUL_optimized_aligned) {
	ASSERT_EQ(kVectorSize % (vector_math::kRequiredAlignment / sizeof(float)),
	0U);
	RunBenchmark(
	vector_math::FMUL_FUNC, true, "vector_math_fmul", "optimized_aligned");
	}
	#endif

	// Benchmarks for each optimized vector_math::EWMAAndMaxPower() method.
	// Benchmark EWMAAndMaxPower_C().
	TEST_F(VectorMathPerfTest, EWMAAndMaxPower_unoptimized) {
	RunBenchmark(vector_math::EWMAAndMaxPower_C,
	kVectorSize,
	"vector_math_ewma_and_max_power",
	"unoptimized");
	}

	#if defined(EWMAAndMaxPower_FUNC)
	// Benchmark EWMAAndMaxPower_FUNC() with unaligned size.
	TEST_F(VectorMathPerfTest, EWMAAndMaxPower_optimized_unaligned) {
	ASSERT_NE((kVectorSize - 1) % (vector_math::kRequiredAlignment /
	sizeof(float)), 0U);
	RunBenchmark(vector_math::EWMAAndMaxPower_FUNC,
	kVectorSize - 1,
	"vector_math_ewma_and_max_power",
	"optimized_unaligned");
	}

	// Benchmark EWMAAndMaxPower_FUNC() with aligned size.
	TEST_F(VectorMathPerfTest, EWMAAndMaxPower_optimized_aligned) {
	ASSERT_EQ(kVectorSize % (vector_math::kRequiredAlignment / sizeof(float)),
	0U);
	RunBenchmark(vector_math::EWMAAndMaxPower_FUNC,
	kVectorSize,
	"vector_math_ewma_and_max_power",
	"optimized_aligned");
	}
	#endif

	} // namespace media