libc/benchmarks/LibcMemoryGoogleBenchmarkMain.cpp - llvm-project - Git at Google

 #include "LibcBenchmark.h"
 #include "LibcMemoryBenchmark.h"
 #include "MemorySizeDistributions.h"
 #include "benchmark/benchmark.h"
 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/Twine.h"
 #include <chrono>
 #include <cstdint>
 #include <random>
 #include <vector>

 using llvm::Align;
 using llvm::ArrayRef;
 using llvm::Twine;
 using llvm::libc_benchmarks::BzeroConfiguration;
 using llvm::libc_benchmarks::ComparisonSetup;
 using llvm::libc_benchmarks::CopySetup;
 using llvm::libc_benchmarks::MemcmpOrBcmpConfiguration;
 using llvm::libc_benchmarks::MemcpyConfiguration;
 using llvm::libc_benchmarks::MemmoveConfiguration;
 using llvm::libc_benchmarks::MemorySizeDistribution;
 using llvm::libc_benchmarks::MemsetConfiguration;
 using llvm::libc_benchmarks::MoveSetup;
 using llvm::libc_benchmarks::OffsetDistribution;
 using llvm::libc_benchmarks::SetSetup;

 // Alignment to use for when accessing the buffers.
 static constexpr Align kBenchmarkAlignment = Align::Constant<1>();

 static std::mt19937_64 &getGenerator() {
   static std::mt19937_64 Generator(
       std::chrono::system_clock::now().time_since_epoch().count());
   return Generator;
 }

 template <typename SetupType, typename ConfigurationType> struct Runner {
   Runner(benchmark::State &S, llvm::ArrayRef<ConfigurationType> Configurations)
       : State(S), Distribution(SetupType::getDistributions()[State.range(0)]),
         Probabilities(Distribution.Probabilities),
         SizeSampler(Probabilities.begin(), Probabilities.end()),
         OffsetSampler(Setup.BufferSize, Probabilities.size() - 1,
                       kBenchmarkAlignment),
         Configuration(Configurations[State.range(1)]) {
     for (auto &P : Setup.Parameters) {
       P.OffsetBytes = OffsetSampler(getGenerator());
       P.SizeBytes = SizeSampler(getGenerator());
       Setup.checkValid(P);
     }
   }

   ~Runner() {
     const size_t AvgBytesPerIteration = Setup.getBatchBytes() / Setup.BatchSize;
     const size_t TotalBytes = State.iterations() * AvgBytesPerIteration;
     State.SetBytesProcessed(TotalBytes);
     State.SetItemsProcessed(State.iterations());
     State.SetLabel((Twine(Configuration.Name) + "," + Distribution.Name).str());
     State.counters["bytes_per_cycle"] = benchmark::Counter(
         TotalBytes / benchmark::CPUInfo::Get().cycles_per_second,
         benchmark::Counter::kIsRate);
   }

   inline void runBatch() {
     for (const auto &P : Setup.Parameters)
       benchmark::DoNotOptimize(Setup.Call(P, Configuration.Function));
   }

   size_t getBatchSize() const { return Setup.BatchSize; }

 private:
   SetupType Setup;
   benchmark::State &State;
   MemorySizeDistribution Distribution;
   ArrayRef<double> Probabilities;
   std::discrete_distribution<unsigned> SizeSampler;
   OffsetDistribution OffsetSampler;
   ConfigurationType Configuration;
 };

 #define BENCHMARK_MEMORY_FUNCTION(BM_NAME, SETUP, CONFIGURATION_TYPE,          \
                                   CONFIGURATION_ARRAY_REF)                     \
   void BM_NAME(benchmark::State &State) {                                      \
     Runner<SETUP, CONFIGURATION_TYPE> Setup(State, CONFIGURATION_ARRAY_REF);   \
     const size_t BatchSize = Setup.getBatchSize();                             \
     while (State.KeepRunningBatch(BatchSize))                                  \
       Setup.runBatch();                                                        \
   }                                                                            \
   BENCHMARK(BM_NAME)->Apply([](benchmark::internal::Benchmark *benchmark) {    \
     const int64_t DistributionSize = SETUP::getDistributions().size();         \
     const int64_t ConfigurationSize = CONFIGURATION_ARRAY_REF.size();          \
     for (int64_t DistIndex = 0; DistIndex < DistributionSize; ++DistIndex)     \
       for (int64_t ConfIndex = 0; ConfIndex < ConfigurationSize; ++ConfIndex)  \
         benchmark->Args({DistIndex, ConfIndex});                               \
   })

 extern llvm::ArrayRef<MemcpyConfiguration> getMemcpyConfigurations();
 BENCHMARK_MEMORY_FUNCTION(BM_Memcpy, CopySetup, MemcpyConfiguration,
                           getMemcpyConfigurations());

 extern llvm::ArrayRef<MemmoveConfiguration> getMemmoveConfigurations();
 BENCHMARK_MEMORY_FUNCTION(BM_Memmove, MoveSetup, MemmoveConfiguration,
                           getMemmoveConfigurations());

 extern llvm::ArrayRef<MemcmpOrBcmpConfiguration> getMemcmpConfigurations();
 BENCHMARK_MEMORY_FUNCTION(BM_Memcmp, ComparisonSetup, MemcmpOrBcmpConfiguration,
                           getMemcmpConfigurations());

 extern llvm::ArrayRef<MemcmpOrBcmpConfiguration> getBcmpConfigurations();
 BENCHMARK_MEMORY_FUNCTION(BM_Bcmp, ComparisonSetup, MemcmpOrBcmpConfiguration,
                           getBcmpConfigurations());

 extern llvm::ArrayRef<MemsetConfiguration> getMemsetConfigurations();
 BENCHMARK_MEMORY_FUNCTION(BM_Memset, SetSetup, MemsetConfiguration,
                           getMemsetConfigurations());

 extern llvm::ArrayRef<BzeroConfiguration> getBzeroConfigurations();
 BENCHMARK_MEMORY_FUNCTION(BM_Bzero, SetSetup, BzeroConfiguration,
                           getBzeroConfigurations());
	#include "LibcBenchmark.h"
	#include "LibcMemoryBenchmark.h"
	#include "MemorySizeDistributions.h"
	#include "benchmark/benchmark.h"
	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/Twine.h"
	#include <chrono>
	#include <cstdint>
	#include <random>
	#include <vector>

	using llvm::Align;
	using llvm::ArrayRef;
	using llvm::Twine;
	using llvm::libc_benchmarks::BzeroConfiguration;
	using llvm::libc_benchmarks::ComparisonSetup;
	using llvm::libc_benchmarks::CopySetup;
	using llvm::libc_benchmarks::MemcmpOrBcmpConfiguration;
	using llvm::libc_benchmarks::MemcpyConfiguration;
	using llvm::libc_benchmarks::MemmoveConfiguration;
	using llvm::libc_benchmarks::MemorySizeDistribution;
	using llvm::libc_benchmarks::MemsetConfiguration;
	using llvm::libc_benchmarks::MoveSetup;
	using llvm::libc_benchmarks::OffsetDistribution;
	using llvm::libc_benchmarks::SetSetup;

	// Alignment to use for when accessing the buffers.
	static constexpr Align kBenchmarkAlignment = Align::Constant<1>();

	static std::mt19937_64 &getGenerator() {
	static std::mt19937_64 Generator(
	std::chrono::system_clock::now().time_since_epoch().count());
	return Generator;
	}

	template <typename SetupType, typename ConfigurationType> struct Runner {
	Runner(benchmark::State &S, llvm::ArrayRef<ConfigurationType> Configurations)
	: State(S), Distribution(SetupType::getDistributions()[State.range(0)]),
	Probabilities(Distribution.Probabilities),
	SizeSampler(Probabilities.begin(), Probabilities.end()),
	OffsetSampler(Setup.BufferSize, Probabilities.size() - 1,
	kBenchmarkAlignment),
	Configuration(Configurations[State.range(1)]) {
	for (auto &P : Setup.Parameters) {
	P.OffsetBytes = OffsetSampler(getGenerator());
	P.SizeBytes = SizeSampler(getGenerator());
	Setup.checkValid(P);
	}
	}

	~Runner() {
	const size_t AvgBytesPerIteration = Setup.getBatchBytes() / Setup.BatchSize;
	const size_t TotalBytes = State.iterations() * AvgBytesPerIteration;
	State.SetBytesProcessed(TotalBytes);
	State.SetItemsProcessed(State.iterations());
	State.SetLabel((Twine(Configuration.Name) + "," + Distribution.Name).str());
	State.counters["bytes_per_cycle"] = benchmark::Counter(
	TotalBytes / benchmark::CPUInfo::Get().cycles_per_second,
	benchmark::Counter::kIsRate);
	}

	inline void runBatch() {
	for (const auto &P : Setup.Parameters)
	benchmark::DoNotOptimize(Setup.Call(P, Configuration.Function));
	}

	size_t getBatchSize() const { return Setup.BatchSize; }

	private:
	SetupType Setup;
	benchmark::State &State;
	MemorySizeDistribution Distribution;
	ArrayRef<double> Probabilities;
	std::discrete_distribution<unsigned> SizeSampler;
	OffsetDistribution OffsetSampler;
	ConfigurationType Configuration;
	};

	#define BENCHMARK_MEMORY_FUNCTION(BM_NAME, SETUP, CONFIGURATION_TYPE, \
	CONFIGURATION_ARRAY_REF) \
	void BM_NAME(benchmark::State &State) { \
	Runner<SETUP, CONFIGURATION_TYPE> Setup(State, CONFIGURATION_ARRAY_REF); \
	const size_t BatchSize = Setup.getBatchSize(); \
	while (State.KeepRunningBatch(BatchSize)) \
	Setup.runBatch(); \
	} \
	BENCHMARK(BM_NAME)->Apply([](benchmark::internal::Benchmark *benchmark) { \
	const int64_t DistributionSize = SETUP::getDistributions().size(); \
	const int64_t ConfigurationSize = CONFIGURATION_ARRAY_REF.size(); \
	for (int64_t DistIndex = 0; DistIndex < DistributionSize; ++DistIndex) \
	for (int64_t ConfIndex = 0; ConfIndex < ConfigurationSize; ++ConfIndex) \
	benchmark->Args({DistIndex, ConfIndex}); \
	})

	extern llvm::ArrayRef<MemcpyConfiguration> getMemcpyConfigurations();
	BENCHMARK_MEMORY_FUNCTION(BM_Memcpy, CopySetup, MemcpyConfiguration,
	getMemcpyConfigurations());

	extern llvm::ArrayRef<MemmoveConfiguration> getMemmoveConfigurations();
	BENCHMARK_MEMORY_FUNCTION(BM_Memmove, MoveSetup, MemmoveConfiguration,
	getMemmoveConfigurations());

	extern llvm::ArrayRef<MemcmpOrBcmpConfiguration> getMemcmpConfigurations();
	BENCHMARK_MEMORY_FUNCTION(BM_Memcmp, ComparisonSetup, MemcmpOrBcmpConfiguration,
	getMemcmpConfigurations());

	extern llvm::ArrayRef<MemcmpOrBcmpConfiguration> getBcmpConfigurations();
	BENCHMARK_MEMORY_FUNCTION(BM_Bcmp, ComparisonSetup, MemcmpOrBcmpConfiguration,
	getBcmpConfigurations());

	extern llvm::ArrayRef<MemsetConfiguration> getMemsetConfigurations();
	BENCHMARK_MEMORY_FUNCTION(BM_Memset, SetSetup, MemsetConfiguration,
	getMemsetConfigurations());

	extern llvm::ArrayRef<BzeroConfiguration> getBzeroConfigurations();
	BENCHMARK_MEMORY_FUNCTION(BM_Bzero, SetSetup, BzeroConfiguration,
	getBzeroConfigurations());