llvm/lib/XRay/FDRTraceWriter.cpp - llvm-project - Git at Google

 //===- FDRTraceWriter.cpp - XRay FDR Trace Writer ---------------*- C++ -*-===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 //
 // Test a utility that can write out XRay FDR Mode formatted trace files.
 //
 //===----------------------------------------------------------------------===//
 #include "llvm/XRay/FDRTraceWriter.h"
 #include <tuple>

 namespace llvm {
 namespace xray {

 namespace {

 template <size_t Index> struct IndexedWriter {
   template <
       class Tuple,
       std::enable_if_t<(Index <
                         std::tuple_size<std::remove_reference_t<Tuple>>::value),
                        int> = 0>
   static size_t write(support::endian::Writer &OS, Tuple &&T) {
     OS.write(std::get<Index>(T));
     return sizeof(std::get<Index>(T)) + IndexedWriter<Index + 1>::write(OS, T);
   }

   template <
       class Tuple,
       std::enable_if_t<(Index >=
                         std::tuple_size<std::remove_reference_t<Tuple>>::value),
                        int> = 0>
   static size_t write(support::endian::Writer &OS, Tuple &&) {
     return 0;
   }
 };

 template <uint8_t Kind, class... Values>
 Error writeMetadata(support::endian::Writer &OS, Values &&... Ds) {
   // The first bit in the first byte of metadata records is always set to 1, so
   // we ensure this is the case when we write out the first byte of the record.
   uint8_t FirstByte = (static_cast<uint8_t>(Kind) << 1) | uint8_t{0x01u};
   auto T = std::make_tuple(std::forward<Values>(std::move(Ds))...);
   // Write in field order.
   OS.write(FirstByte);
   auto Bytes = IndexedWriter<0>::write(OS, T);
   assert(Bytes <= 15 && "Must only ever write at most 16 byte metadata!");
   // Pad out with appropriate numbers of zero's.
   for (; Bytes < 15; ++Bytes)
     OS.write('\0');
   return Error::success();
 }

 } // namespace

 FDRTraceWriter::FDRTraceWriter(raw_ostream &O, const XRayFileHeader &H)
     : OS(O, support::endianness::native) {
   // We need to re-construct a header, by writing the fields we care about for
   // traces, in the format that the runtime would have written.
   uint32_t BitField =
       (H.ConstantTSC ? 0x01 : 0x0) | (H.NonstopTSC ? 0x02 : 0x0);

   // For endian-correctness, we need to write these fields in the order they
   // appear and that we expect, instead of blasting bytes of the struct through.
   OS.write(H.Version);
   OS.write(H.Type);
   OS.write(BitField);
   OS.write(H.CycleFrequency);
   ArrayRef<char> FreeFormBytes(H.FreeFormData,
                                sizeof(XRayFileHeader::FreeFormData));
   OS.write(FreeFormBytes);
 }

 FDRTraceWriter::~FDRTraceWriter() {}

 Error FDRTraceWriter::visit(BufferExtents &R) {
   return writeMetadata<7u>(OS, R.size());
 }

 Error FDRTraceWriter::visit(WallclockRecord &R) {
   return writeMetadata<4u>(OS, R.seconds(), R.nanos());
 }

 Error FDRTraceWriter::visit(NewCPUIDRecord &R) {
   return writeMetadata<2u>(OS, R.cpuid(), R.tsc());
 }

 Error FDRTraceWriter::visit(TSCWrapRecord &R) {
   return writeMetadata<3u>(OS, R.tsc());
 }

 Error FDRTraceWriter::visit(CustomEventRecord &R) {
   if (auto E = writeMetadata<5u>(OS, R.size(), R.tsc(), R.cpu()))
     return E;
   auto D = R.data();
   ArrayRef<char> Bytes(D.data(), D.size());
   OS.write(Bytes);
   return Error::success();
 }

 Error FDRTraceWriter::visit(CustomEventRecordV5 &R) {
   if (auto E = writeMetadata<5u>(OS, R.size(), R.delta()))
     return E;
   auto D = R.data();
   ArrayRef<char> Bytes(D.data(), D.size());
   OS.write(Bytes);
   return Error::success();
 }

 Error FDRTraceWriter::visit(TypedEventRecord &R) {
   if (auto E = writeMetadata<8u>(OS, R.size(), R.delta(), R.eventType()))
     return E;
   auto D = R.data();
   ArrayRef<char> Bytes(D.data(), D.size());
   OS.write(Bytes);
   return Error::success();
 }

 Error FDRTraceWriter::visit(CallArgRecord &R) {
   return writeMetadata<6u>(OS, R.arg());
 }

 Error FDRTraceWriter::visit(PIDRecord &R) {
   return writeMetadata<9u>(OS, R.pid());
 }

 Error FDRTraceWriter::visit(NewBufferRecord &R) {
   return writeMetadata<0u>(OS, R.tid());
 }

 Error FDRTraceWriter::visit(EndBufferRecord &R) {
   return writeMetadata<1u>(OS, 0);
 }

 Error FDRTraceWriter::visit(FunctionRecord &R) {
   // Write out the data in "field" order, to be endian-aware.
   uint32_t TypeRecordFuncId = uint32_t{R.functionId() & ~uint32_t{0x0Fu << 28}};
   TypeRecordFuncId <<= 3;
   TypeRecordFuncId |= static_cast<uint32_t>(R.recordType());
   TypeRecordFuncId <<= 1;
   TypeRecordFuncId &= ~uint32_t{0x01};
   OS.write(TypeRecordFuncId);
   OS.write(R.delta());
   return Error::success();
 }

 } // namespace xray
 } // namespace llvm
	//===- FDRTraceWriter.cpp - XRay FDR Trace Writer ---------------- C++ --===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	//
	// Test a utility that can write out XRay FDR Mode formatted trace files.
	//
	//===----------------------------------------------------------------------===//
	#include "llvm/XRay/FDRTraceWriter.h"
	#include <tuple>

	namespace llvm {
	namespace xray {

	namespace {

	template <size_t Index> struct IndexedWriter {
	template <
	class Tuple,
	std::enable_if_t<(Index <
	std::tuple_size<std::remove_reference_t<Tuple>>::value),
	int> = 0>
	static size_t write(support::endian::Writer &OS, Tuple &&T) {
	OS.write(std::get<Index>(T));
	return sizeof(std::get<Index>(T)) + IndexedWriter<Index + 1>::write(OS, T);
	}

	template <
	class Tuple,
	std::enable_if_t<(Index >=
	std::tuple_size<std::remove_reference_t<Tuple>>::value),
	int> = 0>
	static size_t write(support::endian::Writer &OS, Tuple &&) {
	return 0;
	}
	};

	template <uint8_t Kind, class... Values>
	Error writeMetadata(support::endian::Writer &OS, Values &&... Ds) {
	// The first bit in the first byte of metadata records is always set to 1, so
	// we ensure this is the case when we write out the first byte of the record.
	uint8_t FirstByte = (static_cast<uint8_t>(Kind) << 1) \| uint8_t{0x01u};
	auto T = std::make_tuple(std::forward<Values>(std::move(Ds))...);
	// Write in field order.
	OS.write(FirstByte);
	auto Bytes = IndexedWriter<0>::write(OS, T);
	assert(Bytes <= 15 && "Must only ever write at most 16 byte metadata!");
	// Pad out with appropriate numbers of zero's.
	for (; Bytes < 15; ++Bytes)
	OS.write('\0');
	return Error::success();
	}

	} // namespace

	FDRTraceWriter::FDRTraceWriter(raw_ostream &O, const XRayFileHeader &H)
	: OS(O, support::endianness::native) {
	// We need to re-construct a header, by writing the fields we care about for
	// traces, in the format that the runtime would have written.
	uint32_t BitField =
	(H.ConstantTSC ? 0x01 : 0x0) \| (H.NonstopTSC ? 0x02 : 0x0);

	// For endian-correctness, we need to write these fields in the order they
	// appear and that we expect, instead of blasting bytes of the struct through.
	OS.write(H.Version);
	OS.write(H.Type);
	OS.write(BitField);
	OS.write(H.CycleFrequency);
	ArrayRef<char> FreeFormBytes(H.FreeFormData,
	sizeof(XRayFileHeader::FreeFormData));
	OS.write(FreeFormBytes);
	}

	FDRTraceWriter::~FDRTraceWriter() {}

	Error FDRTraceWriter::visit(BufferExtents &R) {
	return writeMetadata<7u>(OS, R.size());
	}

	Error FDRTraceWriter::visit(WallclockRecord &R) {
	return writeMetadata<4u>(OS, R.seconds(), R.nanos());
	}

	Error FDRTraceWriter::visit(NewCPUIDRecord &R) {
	return writeMetadata<2u>(OS, R.cpuid(), R.tsc());
	}

	Error FDRTraceWriter::visit(TSCWrapRecord &R) {
	return writeMetadata<3u>(OS, R.tsc());
	}

	Error FDRTraceWriter::visit(CustomEventRecord &R) {
	if (auto E = writeMetadata<5u>(OS, R.size(), R.tsc(), R.cpu()))
	return E;
	auto D = R.data();
	ArrayRef<char> Bytes(D.data(), D.size());
	OS.write(Bytes);
	return Error::success();
	}

	Error FDRTraceWriter::visit(CustomEventRecordV5 &R) {
	if (auto E = writeMetadata<5u>(OS, R.size(), R.delta()))
	return E;
	auto D = R.data();
	ArrayRef<char> Bytes(D.data(), D.size());
	OS.write(Bytes);
	return Error::success();
	}

	Error FDRTraceWriter::visit(TypedEventRecord &R) {
	if (auto E = writeMetadata<8u>(OS, R.size(), R.delta(), R.eventType()))
	return E;
	auto D = R.data();
	ArrayRef<char> Bytes(D.data(), D.size());
	OS.write(Bytes);
	return Error::success();
	}

	Error FDRTraceWriter::visit(CallArgRecord &R) {
	return writeMetadata<6u>(OS, R.arg());
	}

	Error FDRTraceWriter::visit(PIDRecord &R) {
	return writeMetadata<9u>(OS, R.pid());
	}

	Error FDRTraceWriter::visit(NewBufferRecord &R) {
	return writeMetadata<0u>(OS, R.tid());
	}

	Error FDRTraceWriter::visit(EndBufferRecord &R) {
	return writeMetadata<1u>(OS, 0);
	}

	Error FDRTraceWriter::visit(FunctionRecord &R) {
	// Write out the data in "field" order, to be endian-aware.
	uint32_t TypeRecordFuncId = uint32_t{R.functionId() & ~uint32_t{0x0Fu << 28}};
	TypeRecordFuncId <<= 3;
	TypeRecordFuncId \|= static_cast<uint32_t>(R.recordType());
	TypeRecordFuncId <<= 1;
	TypeRecordFuncId &= ~uint32_t{0x01};
	OS.write(TypeRecordFuncId);
	OS.write(R.delta());
	return Error::success();
	}

	} // namespace xray
	} // namespace llvm