compiler-rt/include/xray/xray_records.h - llvm-project - Git at Google

 //===-- xray_records.h ------------------------------------------*- 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
 //
 //===----------------------------------------------------------------------===//
 //
 // This file is a part of XRay, a dynamic runtime instrumentation system.
 //
 // This header exposes some record types useful for the XRay in-memory logging
 // implementation.
 //
 //===----------------------------------------------------------------------===//

 #ifndef XRAY_XRAY_RECORDS_H
 #define XRAY_XRAY_RECORDS_H

 #include <cstdint>

 namespace __xray {

 enum FileTypes {
   NAIVE_LOG = 0,
   FDR_LOG = 1,
 };

 // FDR mode use of the union field in the XRayFileHeader.
 struct alignas(16) FdrAdditionalHeaderData {
   uint64_t ThreadBufferSize;
 };

 static_assert(sizeof(FdrAdditionalHeaderData) == 16,
               "FdrAdditionalHeaderData != 16 bytes");

 // This data structure is used to describe the contents of the file. We use this
 // for versioning the supported XRay file formats.
 struct alignas(32) XRayFileHeader {
   uint16_t Version = 0;

   // The type of file we're writing out. See the FileTypes enum for more
   // information. This allows different implementations of the XRay logging to
   // have different files for different information being stored.
   uint16_t Type = 0;

   // What follows are a set of flags that indicate useful things for when
   // reading the data in the file.
   bool ConstantTSC : 1;
   bool NonstopTSC : 1;

   // The frequency by which TSC increases per-second.
   alignas(8) uint64_t CycleFrequency = 0;

   union {
     char FreeForm[16];
     // The current civiltime timestamp, as retrieved from 'clock_gettime'. This
     // allows readers of the file to determine when the file was created or
     // written down.
     struct timespec TS;

     struct FdrAdditionalHeaderData FdrData;
   };
 } __attribute__((packed));

 static_assert(sizeof(XRayFileHeader) == 32, "XRayFileHeader != 32 bytes");

 enum RecordTypes {
   NORMAL = 0,
   ARG_PAYLOAD = 1,
 };

 struct alignas(32) XRayRecord {
   // This is the type of the record being written. We use 16 bits to allow us to
   // treat this as a discriminant, and so that the first 4 bytes get packed
   // properly. See RecordTypes for more supported types.
   uint16_t RecordType = RecordTypes::NORMAL;

   // The CPU where the thread is running. We assume number of CPUs <= 256.
   uint8_t CPU = 0;

   // The type of the event. One of the following:
   //   ENTER = 0
   //   EXIT = 1
   //   TAIL_EXIT = 2
   //   ENTER_ARG = 3
   uint8_t Type = 0;

   // The function ID for the record.
   int32_t FuncId = 0;

   // Get the full 8 bytes of the TSC when we get the log record.
   uint64_t TSC = 0;

   // The thread ID for the currently running thread.
   uint32_t TId = 0;

   // The ID of process that is currently running
   uint32_t PId = 0;

   // Use some bytes in the end of the record for buffers.
   char Buffer[8] = {};
 } __attribute__((packed));

 static_assert(sizeof(XRayRecord) == 32, "XRayRecord != 32 bytes");

 struct alignas(32) XRayArgPayload {
   // We use the same 16 bits as a discriminant for the records in the log here
   // too, and so that the first 4 bytes are packed properly.
   uint16_t RecordType = RecordTypes::ARG_PAYLOAD;

   // Add a few bytes to pad.
   uint8_t Padding[2] = {};

   // The function ID for the record.
   int32_t FuncId = 0;

   // The thread ID for the currently running thread.
   uint32_t TId = 0;

   // The ID of process that is currently running
   uint32_t PId = 0;

   // The argument payload.
   uint64_t Arg = 0;

   // The rest of this record ought to be left as padding.
   uint8_t TailPadding[8] = {};
 } __attribute__((packed));

 static_assert(sizeof(XRayArgPayload) == 32, "XRayArgPayload != 32 bytes");

 } // namespace __xray

 #endif // XRAY_XRAY_RECORDS_H
	//===-- xray_records.h ------------------------------------------- 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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file is a part of XRay, a dynamic runtime instrumentation system.
	//
	// This header exposes some record types useful for the XRay in-memory logging
	// implementation.
	//
	//===----------------------------------------------------------------------===//

	#ifndef XRAY_XRAY_RECORDS_H
	#define XRAY_XRAY_RECORDS_H

	#include <cstdint>

	namespace __xray {

	enum FileTypes {
	NAIVE_LOG = 0,
	FDR_LOG = 1,
	};

	// FDR mode use of the union field in the XRayFileHeader.
	struct alignas(16) FdrAdditionalHeaderData {
	uint64_t ThreadBufferSize;
	};

	static_assert(sizeof(FdrAdditionalHeaderData) == 16,
	"FdrAdditionalHeaderData != 16 bytes");

	// This data structure is used to describe the contents of the file. We use this
	// for versioning the supported XRay file formats.
	struct alignas(32) XRayFileHeader {
	uint16_t Version = 0;

	// The type of file we're writing out. See the FileTypes enum for more
	// information. This allows different implementations of the XRay logging to
	// have different files for different information being stored.
	uint16_t Type = 0;

	// What follows are a set of flags that indicate useful things for when
	// reading the data in the file.
	bool ConstantTSC : 1;
	bool NonstopTSC : 1;

	// The frequency by which TSC increases per-second.
	alignas(8) uint64_t CycleFrequency = 0;

	union {
	char FreeForm[16];
	// The current civiltime timestamp, as retrieved from 'clock_gettime'. This
	// allows readers of the file to determine when the file was created or
	// written down.
	struct timespec TS;

	struct FdrAdditionalHeaderData FdrData;
	};
	} __attribute__((packed));

	static_assert(sizeof(XRayFileHeader) == 32, "XRayFileHeader != 32 bytes");

	enum RecordTypes {
	NORMAL = 0,
	ARG_PAYLOAD = 1,
	};

	struct alignas(32) XRayRecord {
	// This is the type of the record being written. We use 16 bits to allow us to
	// treat this as a discriminant, and so that the first 4 bytes get packed
	// properly. See RecordTypes for more supported types.
	uint16_t RecordType = RecordTypes::NORMAL;

	// The CPU where the thread is running. We assume number of CPUs <= 256.
	uint8_t CPU = 0;

	// The type of the event. One of the following:
	// ENTER = 0
	// EXIT = 1
	// TAIL_EXIT = 2
	// ENTER_ARG = 3
	uint8_t Type = 0;

	// The function ID for the record.
	int32_t FuncId = 0;

	// Get the full 8 bytes of the TSC when we get the log record.
	uint64_t TSC = 0;

	// The thread ID for the currently running thread.
	uint32_t TId = 0;

	// The ID of process that is currently running
	uint32_t PId = 0;

	// Use some bytes in the end of the record for buffers.
	char Buffer[8] = {};
	} __attribute__((packed));

	static_assert(sizeof(XRayRecord) == 32, "XRayRecord != 32 bytes");

	struct alignas(32) XRayArgPayload {
	// We use the same 16 bits as a discriminant for the records in the log here
	// too, and so that the first 4 bytes are packed properly.
	uint16_t RecordType = RecordTypes::ARG_PAYLOAD;

	// Add a few bytes to pad.
	uint8_t Padding[2] = {};

	// The function ID for the record.
	int32_t FuncId = 0;

	// The thread ID for the currently running thread.
	uint32_t TId = 0;

	// The ID of process that is currently running
	uint32_t PId = 0;

	// The argument payload.
	uint64_t Arg = 0;

	// The rest of this record ought to be left as padding.
	uint8_t TailPadding[8] = {};
	} __attribute__((packed));

	static_assert(sizeof(XRayArgPayload) == 32, "XRayArgPayload != 32 bytes");

	} // namespace __xray

	#endif // XRAY_XRAY_RECORDS_H