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

 //===-- Benchmark memory specific tools -----------------------------------===//
 //
 // 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 "LibcMemoryBenchmark.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/ADT/Twine.h"
 #include "llvm/Support/ErrorHandling.h"
 #include "llvm/Support/MathExtras.h"
 #include <algorithm>

 namespace llvm {
 namespace libc_benchmarks {

 // Returns a distribution that samples the buffer to satisfy the required
 // alignment.
 // When alignment is set, the distribution is scaled down by `Factor` and scaled
 // up again by the same amount during sampling.
 static std::uniform_int_distribution<uint32_t>
 getOffsetDistribution(size_t BufferSize, size_t MaxSizeValue,
                       MaybeAlign AccessAlignment) {
   if (AccessAlignment && *AccessAlignment > AlignedBuffer::Alignment)
     report_fatal_error(
         "AccessAlignment must be less or equal to AlignedBuffer::Alignment");
   if (!AccessAlignment)
     return std::uniform_int_distribution<uint32_t>(0, 0); // Always 0.
   // If we test up to Size bytes, the returned offset must stay under
   // BuffersSize - Size.
   int64_t MaxOffset = BufferSize;
   MaxOffset -= MaxSizeValue;
   MaxOffset -= 1;
   if (MaxOffset < 0)
     report_fatal_error(
         "BufferSize too small to exercise specified Size configuration");
   MaxOffset /= AccessAlignment->value();
   return std::uniform_int_distribution<uint32_t>(0, MaxOffset);
 }

 OffsetDistribution::OffsetDistribution(size_t BufferSize, size_t MaxSizeValue,
                                        MaybeAlign AccessAlignment)
     : Distribution(
           getOffsetDistribution(BufferSize, MaxSizeValue, AccessAlignment)),
       Factor(AccessAlignment.valueOrOne().value()) {}

 // Precomputes offset where to insert mismatches between the two buffers.
 MismatchOffsetDistribution::MismatchOffsetDistribution(size_t BufferSize,
                                                        size_t MaxSizeValue,
                                                        size_t MismatchAt)
     : MismatchAt(MismatchAt) {
   if (MismatchAt <= 1)
     return;
   for (size_t I = MaxSizeValue + 1; I < BufferSize; I += MaxSizeValue)
     MismatchIndices.push_back(I);
   if (MismatchIndices.empty())
     report_fatal_error("Unable to generate mismatch");
   MismatchIndexSelector =
       std::uniform_int_distribution<size_t>(0, MismatchIndices.size() - 1);
 }

 static size_t getL1DataCacheSize() {
   const std::vector<CacheInfo> &CacheInfos = HostState::get().Caches;
   const auto IsL1DataCache = [](const CacheInfo &CI) {
     return CI.Type == "Data" && CI.Level == 1;
   };
   const auto CacheIt = find_if(CacheInfos, IsL1DataCache);
   if (CacheIt != CacheInfos.end())
     return CacheIt->Size;
   report_fatal_error("Unable to read L1 Cache Data Size");
 }

 static size_t getAvailableBufferSize() {
   static constexpr int64_t KiB = 1024;
   static constexpr int64_t ParameterStorageBytes = 4 * KiB;
   static constexpr int64_t L1LeftAsideBytes = 1 * KiB;
   return getL1DataCacheSize() - L1LeftAsideBytes - ParameterStorageBytes;
 }

 ParameterBatch::ParameterBatch(size_t BufferCount)
     : BufferSize(getAvailableBufferSize() / BufferCount),
       BatchSize(BufferSize / sizeof(ParameterType)), Parameters(BatchSize) {
   if (BufferSize <= 0 || BatchSize < 100)
     report_fatal_error("Not enough L1 cache");
 }

 size_t ParameterBatch::getBatchBytes() const {
   size_t BatchBytes = 0;
   for (auto &P : Parameters)
     BatchBytes += P.SizeBytes;
   return BatchBytes;
 }

 void ParameterBatch::checkValid(const ParameterType &P) const {
   if (P.OffsetBytes + P.SizeBytes >= BufferSize)
     report_fatal_error(
         llvm::Twine("Call would result in buffer overflow: Offset=")
             .concat(llvm::Twine(P.OffsetBytes))
             .concat(", Size=")
             .concat(llvm::Twine(P.SizeBytes))
             .concat(", BufferSize=")
             .concat(llvm::Twine(BufferSize)));
 }

 CopySetup::CopySetup()
     : ParameterBatch(2), SrcBuffer(ParameterBatch::BufferSize),
       DstBuffer(ParameterBatch::BufferSize) {}

 MoveSetup::MoveSetup()
     : ParameterBatch(3), Buffer(ParameterBatch::BufferSize * 3) {}

 ComparisonSetup::ComparisonSetup()
     : ParameterBatch(2), LhsBuffer(ParameterBatch::BufferSize),
       RhsBuffer(ParameterBatch::BufferSize) {
   // The memcmp buffers always compare equal.
   memset(LhsBuffer.begin(), 0xF, BufferSize);
   memset(RhsBuffer.begin(), 0xF, BufferSize);
 }

 SetSetup::SetSetup()
     : ParameterBatch(1), DstBuffer(ParameterBatch::BufferSize) {}

 } // namespace libc_benchmarks
 } // namespace llvm
	//===-- Benchmark memory specific tools -----------------------------------===//
	//
	// 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 "LibcMemoryBenchmark.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/ADT/Twine.h"
	#include "llvm/Support/ErrorHandling.h"
	#include "llvm/Support/MathExtras.h"
	#include <algorithm>

	namespace llvm {
	namespace libc_benchmarks {

	// Returns a distribution that samples the buffer to satisfy the required
	// alignment.
	// When alignment is set, the distribution is scaled down by `Factor` and scaled
	// up again by the same amount during sampling.
	static std::uniform_int_distribution<uint32_t>
	getOffsetDistribution(size_t BufferSize, size_t MaxSizeValue,
	MaybeAlign AccessAlignment) {
	if (AccessAlignment && *AccessAlignment > AlignedBuffer::Alignment)
	report_fatal_error(
	"AccessAlignment must be less or equal to AlignedBuffer::Alignment");
	if (!AccessAlignment)
	return std::uniform_int_distribution<uint32_t>(0, 0); // Always 0.
	// If we test up to Size bytes, the returned offset must stay under
	// BuffersSize - Size.
	int64_t MaxOffset = BufferSize;
	MaxOffset -= MaxSizeValue;
	MaxOffset -= 1;
	if (MaxOffset < 0)
	report_fatal_error(
	"BufferSize too small to exercise specified Size configuration");
	MaxOffset /= AccessAlignment->value();
	return std::uniform_int_distribution<uint32_t>(0, MaxOffset);
	}

	OffsetDistribution::OffsetDistribution(size_t BufferSize, size_t MaxSizeValue,
	MaybeAlign AccessAlignment)
	: Distribution(
	getOffsetDistribution(BufferSize, MaxSizeValue, AccessAlignment)),
	Factor(AccessAlignment.valueOrOne().value()) {}

	// Precomputes offset where to insert mismatches between the two buffers.
	MismatchOffsetDistribution::MismatchOffsetDistribution(size_t BufferSize,
	size_t MaxSizeValue,
	size_t MismatchAt)
	: MismatchAt(MismatchAt) {
	if (MismatchAt <= 1)
	return;
	for (size_t I = MaxSizeValue + 1; I < BufferSize; I += MaxSizeValue)
	MismatchIndices.push_back(I);
	if (MismatchIndices.empty())
	report_fatal_error("Unable to generate mismatch");
	MismatchIndexSelector =
	std::uniform_int_distribution<size_t>(0, MismatchIndices.size() - 1);
	}

	static size_t getL1DataCacheSize() {
	const std::vector<CacheInfo> &CacheInfos = HostState::get().Caches;
	const auto IsL1DataCache = [](const CacheInfo &CI) {
	return CI.Type == "Data" && CI.Level == 1;
	};
	const auto CacheIt = find_if(CacheInfos, IsL1DataCache);
	if (CacheIt != CacheInfos.end())
	return CacheIt->Size;
	report_fatal_error("Unable to read L1 Cache Data Size");
	}

	static size_t getAvailableBufferSize() {
	static constexpr int64_t KiB = 1024;
	static constexpr int64_t ParameterStorageBytes = 4 * KiB;
	static constexpr int64_t L1LeftAsideBytes = 1 * KiB;
	return getL1DataCacheSize() - L1LeftAsideBytes - ParameterStorageBytes;
	}

	ParameterBatch::ParameterBatch(size_t BufferCount)
	: BufferSize(getAvailableBufferSize() / BufferCount),
	BatchSize(BufferSize / sizeof(ParameterType)), Parameters(BatchSize) {
	if (BufferSize <= 0 \|\| BatchSize < 100)
	report_fatal_error("Not enough L1 cache");
	}

	size_t ParameterBatch::getBatchBytes() const {
	size_t BatchBytes = 0;
	for (auto &P : Parameters)
	BatchBytes += P.SizeBytes;
	return BatchBytes;
	}

	void ParameterBatch::checkValid(const ParameterType &P) const {
	if (P.OffsetBytes + P.SizeBytes >= BufferSize)
	report_fatal_error(
	llvm::Twine("Call would result in buffer overflow: Offset=")
	.concat(llvm::Twine(P.OffsetBytes))
	.concat(", Size=")
	.concat(llvm::Twine(P.SizeBytes))
	.concat(", BufferSize=")
	.concat(llvm::Twine(BufferSize)));
	}

	CopySetup::CopySetup()
	: ParameterBatch(2), SrcBuffer(ParameterBatch::BufferSize),
	DstBuffer(ParameterBatch::BufferSize) {}

	MoveSetup::MoveSetup()
	: ParameterBatch(3), Buffer(ParameterBatch::BufferSize * 3) {}

	ComparisonSetup::ComparisonSetup()
	: ParameterBatch(2), LhsBuffer(ParameterBatch::BufferSize),
	RhsBuffer(ParameterBatch::BufferSize) {
	// The memcmp buffers always compare equal.
	memset(LhsBuffer.begin(), 0xF, BufferSize);
	memset(RhsBuffer.begin(), 0xF, BufferSize);
	}

	SetSetup::SetSetup()
	: ParameterBatch(1), DstBuffer(ParameterBatch::BufferSize) {}

	} // namespace libc_benchmarks
	} // namespace llvm