libc/benchmarks/automemcpy/unittests/ResultAnalyzerTest.cpp - llvm-project - Git at Google

 //===--  Automemcpy Json Results Analyzer Test ----------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "automemcpy/ResultAnalyzer.h"
 #include "gmock/gmock.h"
 #include "gtest/gtest.h"

 using testing::ElementsAre;
 using testing::Pair;
 using testing::SizeIs;

 namespace llvm {
 namespace automemcpy {
 namespace {

 TEST(AutomemcpyJsonResultsAnalyzer, getThroughputsOneSample) {
   static constexpr FunctionId Foo1 = {"memcpy1", FunctionType::MEMCPY};
   static constexpr DistributionId DistA = {{"A"}};
   static constexpr SampleId Id = {Foo1, DistA};
   static constexpr Sample kSamples[] = {
       Sample{Id, 4},
   };

   const std::vector<FunctionData> Data = getThroughputs(kSamples);
   EXPECT_THAT(Data, SizeIs(1));
   EXPECT_THAT(Data[0].Id, Foo1);
   EXPECT_THAT(Data[0].PerDistributionData, SizeIs(1));
   // A single value is provided.
   EXPECT_THAT(
       Data[0].PerDistributionData.lookup(DistA.Name).MedianBytesPerSecond, 4);
 }

 TEST(AutomemcpyJsonResultsAnalyzer, getThroughputsManySamplesSameBucket) {
   static constexpr FunctionId Foo1 = {"memcpy1", FunctionType::MEMCPY};
   static constexpr DistributionId DistA = {{"A"}};
   static constexpr SampleId Id = {Foo1, DistA};
   static constexpr Sample kSamples[] = {Sample{Id, 4}, Sample{Id, 5},
                                         Sample{Id, 5}};

   const std::vector<FunctionData> Data = getThroughputs(kSamples);
   EXPECT_THAT(Data, SizeIs(1));
   EXPECT_THAT(Data[0].Id, Foo1);
   EXPECT_THAT(Data[0].PerDistributionData, SizeIs(1));
   // When multiple values are provided we pick the median one (here median of 4,
   // 5, 5).
   EXPECT_THAT(
       Data[0].PerDistributionData.lookup(DistA.Name).MedianBytesPerSecond, 5);
 }

 TEST(AutomemcpyJsonResultsAnalyzer, getThroughputsServeralFunctionAndDist) {
   static constexpr FunctionId Foo1 = {"memcpy1", FunctionType::MEMCPY};
   static constexpr DistributionId DistA = {{"A"}};
   static constexpr FunctionId Foo2 = {"memcpy2", FunctionType::MEMCPY};
   static constexpr DistributionId DistB = {{"B"}};
   static constexpr Sample kSamples[] = {
       Sample{{Foo1, DistA}, 1}, Sample{{Foo1, DistB}, 2},
       Sample{{Foo2, DistA}, 3}, Sample{{Foo2, DistB}, 4}};
   // Data is aggregated per function.
   const std::vector<FunctionData> Data = getThroughputs(kSamples);
   EXPECT_THAT(Data, SizeIs(2)); // 2 functions Foo1 and Foo2.
   // Each function has data for both distributions DistA and DistB.
   EXPECT_THAT(Data[0].PerDistributionData, SizeIs(2));
   EXPECT_THAT(Data[1].PerDistributionData, SizeIs(2));
 }

 TEST(AutomemcpyJsonResultsAnalyzer, getScore) {
   static constexpr FunctionId Foo1 = {"memcpy1", FunctionType::MEMCPY};
   static constexpr FunctionId Foo2 = {"memcpy2", FunctionType::MEMCPY};
   static constexpr FunctionId Foo3 = {"memcpy3", FunctionType::MEMCPY};
   static constexpr DistributionId Dist = {{"A"}};
   static constexpr Sample kSamples[] = {Sample{{Foo1, Dist}, 1},
                                         Sample{{Foo2, Dist}, 2},
                                         Sample{{Foo3, Dist}, 3}};

   // Data is aggregated per function.
   std::vector<FunctionData> Data = getThroughputs(kSamples);

   // Sort Data by function name so we can test them.
   std::sort(
       Data.begin(), Data.end(),
       [](const FunctionData &A, const FunctionData &B) { return A.Id < B.Id; });

   EXPECT_THAT(Data[0].Id, Foo1);
   EXPECT_THAT(Data[0].PerDistributionData.lookup("A").MedianBytesPerSecond, 1);
   EXPECT_THAT(Data[1].Id, Foo2);
   EXPECT_THAT(Data[1].PerDistributionData.lookup("A").MedianBytesPerSecond, 2);
   EXPECT_THAT(Data[2].Id, Foo3);
   EXPECT_THAT(Data[2].PerDistributionData.lookup("A").MedianBytesPerSecond, 3);

   // Normalizes throughput per distribution.
   fillScores(Data);
   EXPECT_THAT(Data[0].PerDistributionData.lookup("A").Score, 0);
   EXPECT_THAT(Data[1].PerDistributionData.lookup("A").Score, 0.5);
   EXPECT_THAT(Data[2].PerDistributionData.lookup("A").Score, 1);
 }

 TEST(AutomemcpyJsonResultsAnalyzer, castVotes) {
   static constexpr double kAbsErr = 0.01;

   static constexpr FunctionId Foo1 = {"memcpy1", FunctionType::MEMCPY};
   static constexpr FunctionId Foo2 = {"memcpy2", FunctionType::MEMCPY};
   static constexpr FunctionId Foo3 = {"memcpy3", FunctionType::MEMCPY};
   static constexpr DistributionId DistA = {{"A"}};
   static constexpr DistributionId DistB = {{"B"}};
   static constexpr Sample kSamples[] = {
       Sample{{Foo1, DistA}, 0}, Sample{{Foo1, DistB}, 30},
       Sample{{Foo2, DistA}, 1}, Sample{{Foo2, DistB}, 100},
       Sample{{Foo3, DistA}, 7}, Sample{{Foo3, DistB}, 100},
   };

   // DistA Thoughput ranges from 0 to 7.
   // DistB Thoughput ranges from 30 to 100.

   // Data is aggregated per function.
   std::vector<FunctionData> Data = getThroughputs(kSamples);

   // Sort Data by function name so we can test them.
   std::sort(
       Data.begin(), Data.end(),
       [](const FunctionData &A, const FunctionData &B) { return A.Id < B.Id; });

   // Normalizes throughput per distribution.
   fillScores(Data);

   // Cast votes
   castVotes(Data);

   EXPECT_THAT(Data[0].Id, Foo1);
   EXPECT_THAT(Data[1].Id, Foo2);
   EXPECT_THAT(Data[2].Id, Foo3);

   // Distribution A
   // Throughput is 0, 1 and 7, so normalized scores are 0, 1/7 and 1.
   EXPECT_NEAR(Data[0].PerDistributionData.lookup("A").Score, 0, kAbsErr);
   EXPECT_NEAR(Data[1].PerDistributionData.lookup("A").Score, 1. / 7, kAbsErr);
   EXPECT_NEAR(Data[2].PerDistributionData.lookup("A").Score, 1, kAbsErr);
   // which are turned into grades BAD,  MEDIOCRE and EXCELLENT.
   EXPECT_THAT(Data[0].PerDistributionData.lookup("A").Grade, Grade::BAD);
   EXPECT_THAT(Data[1].PerDistributionData.lookup("A").Grade, Grade::MEDIOCRE);
   EXPECT_THAT(Data[2].PerDistributionData.lookup("A").Grade, Grade::EXCELLENT);

   // Distribution B
   // Throughput is 30, 100 and 100, so normalized scores are 0, 1 and 1.
   EXPECT_NEAR(Data[0].PerDistributionData.lookup("B").Score, 0, kAbsErr);
   EXPECT_NEAR(Data[1].PerDistributionData.lookup("B").Score, 1, kAbsErr);
   EXPECT_NEAR(Data[2].PerDistributionData.lookup("B").Score, 1, kAbsErr);
   // which are turned into grades BAD, EXCELLENT and EXCELLENT.
   EXPECT_THAT(Data[0].PerDistributionData.lookup("B").Grade, Grade::BAD);
   EXPECT_THAT(Data[1].PerDistributionData.lookup("B").Grade, Grade::EXCELLENT);
   EXPECT_THAT(Data[2].PerDistributionData.lookup("B").Grade, Grade::EXCELLENT);

   // Now looking from the functions point of view.
   // Note the array is indexed by GradeEnum values (EXCELLENT=0 / BAD = 6)
   EXPECT_THAT(Data[0].GradeHisto, ElementsAre(0, 0, 0, 0, 0, 0, 2));
   EXPECT_THAT(Data[1].GradeHisto, ElementsAre(1, 0, 0, 0, 0, 1, 0));
   EXPECT_THAT(Data[2].GradeHisto, ElementsAre(2, 0, 0, 0, 0, 0, 0));

   EXPECT_THAT(Data[0].FinalGrade, Grade::BAD);
   EXPECT_THAT(Data[1].FinalGrade, Grade::MEDIOCRE);
   EXPECT_THAT(Data[2].FinalGrade, Grade::EXCELLENT);
 }

 } // namespace
 } // namespace automemcpy
 } // namespace llvm
	//===-- Automemcpy Json Results Analyzer Test ----------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "automemcpy/ResultAnalyzer.h"
	#include "gmock/gmock.h"
	#include "gtest/gtest.h"

	using testing::ElementsAre;
	using testing::Pair;
	using testing::SizeIs;

	namespace llvm {
	namespace automemcpy {
	namespace {

	TEST(AutomemcpyJsonResultsAnalyzer, getThroughputsOneSample) {
	static constexpr FunctionId Foo1 = {"memcpy1", FunctionType::MEMCPY};
	static constexpr DistributionId DistA = {{"A"}};
	static constexpr SampleId Id = {Foo1, DistA};
	static constexpr Sample kSamples[] = {
	Sample{Id, 4},
	};

	const std::vector<FunctionData> Data = getThroughputs(kSamples);
	EXPECT_THAT(Data, SizeIs(1));
	EXPECT_THAT(Data[0].Id, Foo1);
	EXPECT_THAT(Data[0].PerDistributionData, SizeIs(1));
	// A single value is provided.
	EXPECT_THAT(
	Data[0].PerDistributionData.lookup(DistA.Name).MedianBytesPerSecond, 4);
	}

	TEST(AutomemcpyJsonResultsAnalyzer, getThroughputsManySamplesSameBucket) {
	static constexpr FunctionId Foo1 = {"memcpy1", FunctionType::MEMCPY};
	static constexpr DistributionId DistA = {{"A"}};
	static constexpr SampleId Id = {Foo1, DistA};
	static constexpr Sample kSamples[] = {Sample{Id, 4}, Sample{Id, 5},
	Sample{Id, 5}};

	const std::vector<FunctionData> Data = getThroughputs(kSamples);
	EXPECT_THAT(Data, SizeIs(1));
	EXPECT_THAT(Data[0].Id, Foo1);
	EXPECT_THAT(Data[0].PerDistributionData, SizeIs(1));
	// When multiple values are provided we pick the median one (here median of 4,
	// 5, 5).
	EXPECT_THAT(
	Data[0].PerDistributionData.lookup(DistA.Name).MedianBytesPerSecond, 5);
	}

	TEST(AutomemcpyJsonResultsAnalyzer, getThroughputsServeralFunctionAndDist) {
	static constexpr FunctionId Foo1 = {"memcpy1", FunctionType::MEMCPY};
	static constexpr DistributionId DistA = {{"A"}};
	static constexpr FunctionId Foo2 = {"memcpy2", FunctionType::MEMCPY};
	static constexpr DistributionId DistB = {{"B"}};
	static constexpr Sample kSamples[] = {
	Sample{{Foo1, DistA}, 1}, Sample{{Foo1, DistB}, 2},
	Sample{{Foo2, DistA}, 3}, Sample{{Foo2, DistB}, 4}};
	// Data is aggregated per function.
	const std::vector<FunctionData> Data = getThroughputs(kSamples);
	EXPECT_THAT(Data, SizeIs(2)); // 2 functions Foo1 and Foo2.
	// Each function has data for both distributions DistA and DistB.
	EXPECT_THAT(Data[0].PerDistributionData, SizeIs(2));
	EXPECT_THAT(Data[1].PerDistributionData, SizeIs(2));
	}

	TEST(AutomemcpyJsonResultsAnalyzer, getScore) {
	static constexpr FunctionId Foo1 = {"memcpy1", FunctionType::MEMCPY};
	static constexpr FunctionId Foo2 = {"memcpy2", FunctionType::MEMCPY};
	static constexpr FunctionId Foo3 = {"memcpy3", FunctionType::MEMCPY};
	static constexpr DistributionId Dist = {{"A"}};
	static constexpr Sample kSamples[] = {Sample{{Foo1, Dist}, 1},
	Sample{{Foo2, Dist}, 2},
	Sample{{Foo3, Dist}, 3}};

	// Data is aggregated per function.
	std::vector<FunctionData> Data = getThroughputs(kSamples);

	// Sort Data by function name so we can test them.
	std::sort(
	Data.begin(), Data.end(),
	[](const FunctionData &A, const FunctionData &B) { return A.Id < B.Id; });

	EXPECT_THAT(Data[0].Id, Foo1);
	EXPECT_THAT(Data[0].PerDistributionData.lookup("A").MedianBytesPerSecond, 1);
	EXPECT_THAT(Data[1].Id, Foo2);
	EXPECT_THAT(Data[1].PerDistributionData.lookup("A").MedianBytesPerSecond, 2);
	EXPECT_THAT(Data[2].Id, Foo3);
	EXPECT_THAT(Data[2].PerDistributionData.lookup("A").MedianBytesPerSecond, 3);

	// Normalizes throughput per distribution.
	fillScores(Data);
	EXPECT_THAT(Data[0].PerDistributionData.lookup("A").Score, 0);
	EXPECT_THAT(Data[1].PerDistributionData.lookup("A").Score, 0.5);
	EXPECT_THAT(Data[2].PerDistributionData.lookup("A").Score, 1);
	}

	TEST(AutomemcpyJsonResultsAnalyzer, castVotes) {
	static constexpr double kAbsErr = 0.01;

	static constexpr FunctionId Foo1 = {"memcpy1", FunctionType::MEMCPY};
	static constexpr FunctionId Foo2 = {"memcpy2", FunctionType::MEMCPY};
	static constexpr FunctionId Foo3 = {"memcpy3", FunctionType::MEMCPY};
	static constexpr DistributionId DistA = {{"A"}};
	static constexpr DistributionId DistB = {{"B"}};
	static constexpr Sample kSamples[] = {
	Sample{{Foo1, DistA}, 0}, Sample{{Foo1, DistB}, 30},
	Sample{{Foo2, DistA}, 1}, Sample{{Foo2, DistB}, 100},
	Sample{{Foo3, DistA}, 7}, Sample{{Foo3, DistB}, 100},
	};

	// DistA Thoughput ranges from 0 to 7.
	// DistB Thoughput ranges from 30 to 100.

	// Data is aggregated per function.
	std::vector<FunctionData> Data = getThroughputs(kSamples);

	// Sort Data by function name so we can test them.
	std::sort(
	Data.begin(), Data.end(),
	[](const FunctionData &A, const FunctionData &B) { return A.Id < B.Id; });

	// Normalizes throughput per distribution.
	fillScores(Data);

	// Cast votes
	castVotes(Data);

	EXPECT_THAT(Data[0].Id, Foo1);
	EXPECT_THAT(Data[1].Id, Foo2);
	EXPECT_THAT(Data[2].Id, Foo3);

	// Distribution A
	// Throughput is 0, 1 and 7, so normalized scores are 0, 1/7 and 1.
	EXPECT_NEAR(Data[0].PerDistributionData.lookup("A").Score, 0, kAbsErr);
	EXPECT_NEAR(Data[1].PerDistributionData.lookup("A").Score, 1. / 7, kAbsErr);
	EXPECT_NEAR(Data[2].PerDistributionData.lookup("A").Score, 1, kAbsErr);
	// which are turned into grades BAD, MEDIOCRE and EXCELLENT.
	EXPECT_THAT(Data[0].PerDistributionData.lookup("A").Grade, Grade::BAD);
	EXPECT_THAT(Data[1].PerDistributionData.lookup("A").Grade, Grade::MEDIOCRE);
	EXPECT_THAT(Data[2].PerDistributionData.lookup("A").Grade, Grade::EXCELLENT);

	// Distribution B
	// Throughput is 30, 100 and 100, so normalized scores are 0, 1 and 1.
	EXPECT_NEAR(Data[0].PerDistributionData.lookup("B").Score, 0, kAbsErr);
	EXPECT_NEAR(Data[1].PerDistributionData.lookup("B").Score, 1, kAbsErr);
	EXPECT_NEAR(Data[2].PerDistributionData.lookup("B").Score, 1, kAbsErr);
	// which are turned into grades BAD, EXCELLENT and EXCELLENT.
	EXPECT_THAT(Data[0].PerDistributionData.lookup("B").Grade, Grade::BAD);
	EXPECT_THAT(Data[1].PerDistributionData.lookup("B").Grade, Grade::EXCELLENT);
	EXPECT_THAT(Data[2].PerDistributionData.lookup("B").Grade, Grade::EXCELLENT);

	// Now looking from the functions point of view.
	// Note the array is indexed by GradeEnum values (EXCELLENT=0 / BAD = 6)
	EXPECT_THAT(Data[0].GradeHisto, ElementsAre(0, 0, 0, 0, 0, 0, 2));
	EXPECT_THAT(Data[1].GradeHisto, ElementsAre(1, 0, 0, 0, 0, 1, 0));
	EXPECT_THAT(Data[2].GradeHisto, ElementsAre(2, 0, 0, 0, 0, 0, 0));

	EXPECT_THAT(Data[0].FinalGrade, Grade::BAD);
	EXPECT_THAT(Data[1].FinalGrade, Grade::MEDIOCRE);
	EXPECT_THAT(Data[2].FinalGrade, Grade::EXCELLENT);
	}

	} // namespace
	} // namespace automemcpy
	} // namespace llvm