perfprofd/quipper/perf_reader.h - nest-cam/4320010/perfprofd - Git at Google

 // Copyright (c) 2012 The Chromium OS Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef CHROMIUMOS_WIDE_PROFILING_PERF_READER_H_
 #define CHROMIUMOS_WIDE_PROFILING_PERF_READER_H_

 #include <stdint.h>

 #include <map>
 #include <set>
 #include <string>
 #include <type_traits>
 #include <vector>

 #include "base/macros.h"

 #include "perf_internals.h"
 #include "quipper_string.h"
 #include "perf_utils.h"

 namespace quipper {

 struct PerfFileAttr {
   struct perf_event_attr attr;
   std::vector<u64> ids;
 };

 // Based on code in tools/perf/util/header.c, the metadata are of the following
 // formats:

 // Based on kernel/perf_internals.h
 const size_t kBuildIDArraySize = 20;
 const size_t kBuildIDStringLength = kBuildIDArraySize * 2;

 struct CStringWithLength {
   u32 len;
   string str;
 };

 struct PerfStringMetadata {
   u32 type;
   std::vector<CStringWithLength> data;
 };

 struct PerfUint32Metadata {
   u32 type;
   std::vector<uint32_t> data;
 };

 struct PerfUint64Metadata {
   u32 type;
   std::vector<uint64_t> data;
 };

 typedef u32 num_siblings_type;

 struct PerfCPUTopologyMetadata {
   std::vector<CStringWithLength> core_siblings;
   std::vector<CStringWithLength> thread_siblings;
 };

 struct PerfNodeTopologyMetadata {
   u32 id;
   u64 total_memory;
   u64 free_memory;
   CStringWithLength cpu_list;
 };

 struct BufferWithSize;
 struct ConstBufferWithSize;

 class PerfReader {
  public:
   PerfReader() : sample_type_(0),
                  read_format_(0),
                  is_cross_endian_(0) {}
   ~PerfReader();

   // Makes |build_id| fit the perf format, by either truncating it or adding
   // zeros to the end so that it has length kBuildIDStringLength.
   static void PerfizeBuildIDString(string* build_id);

   // Changes |build_id| to the best guess of what the build id was before going
   // through perf.  Specifically, it keeps removing trailing sequences of four
   // zero bytes (or eight '0' characters) until there are no more such
   // sequences, or the build id would be empty if the process were repeated.
   static void UnperfizeBuildIDString(string* build_id);

   bool ReadFile(const string& filename);
   bool ReadFromVector(const std::vector<char>& data);
   bool ReadFromString(const string& str);
   bool ReadFromPointer(const char* perf_data, size_t size);

   // TODO(rohinmshah): GetSize should not use RegenerateHeader (so that it can
   // be const).  Ideally, RegenerateHeader would be deleted and instead of
   // having out_header_ as an instance variable, it would be computed
   // dynamically whenever needed.

   // Returns the size in bytes that would be written by any of the methods that
   // write the entire perf data file (WriteFile, WriteToPointer, etc).
   size_t GetSize();

   bool WriteFile(const string& filename);
   bool WriteToVector(std::vector<char>* data);
   bool WriteToString(string* str);
   bool WriteToPointer(char* buffer, size_t size);

   bool RegenerateHeader();

   // Stores the mapping from filenames to build ids in build_id_events_.
   // Returns true on success.
   // Note: If |filenames_to_build_ids| contains a mapping for a filename for
   // which there is already a build_id_event in build_id_events_, a duplicate
   // build_id_event will be created, and the old build_id_event will NOT be
   // deleted.
   bool InjectBuildIDs(const std::map<string, string>& filenames_to_build_ids);

   // Replaces existing filenames with filenames from |build_ids_to_filenames|
   // by joining on build ids.  If a build id in |build_ids_to_filenames| is not
   // present in this parser, it is ignored.
   bool Localize(const std::map<string, string>& build_ids_to_filenames);

   // Same as Localize, but joins on filenames instead of build ids.
   bool LocalizeUsingFilenames(const std::map<string, string>& filename_map);

   // Stores a list of unique filenames found in MMAP/MMAP2 events into
   // |filenames|.  Any existing data in |filenames| will be lost.
   void GetFilenames(std::vector<string>* filenames) const;
   void GetFilenamesAsSet(std::set<string>* filenames) const;

   // Uses build id events to populate |filenames_to_build_ids|.
   // Any existing data in |filenames_to_build_ids| will be lost.
   // Note:  A filename returned by GetFilenames need not be present in this map,
   // since there may be no build id event corresponding to the MMAP/MMAP2.
   void GetFilenamesToBuildIDs(
       std::map<string, string>* filenames_to_build_ids) const;

   static bool IsSupportedEventType(uint32_t type);

   // If a program using PerfReader calls events(), it could work with the
   // resulting events by importing kernel/perf_internals.h.  This would also
   // apply to other forms of data (attributes, event types, build ids, etc.)
   // However, there is no easy way to work with the sample info within events.
   // The following two methods have been added for this purpose.

   // Extracts from a perf event |event| info about the perf sample that
   // contains the event.  Stores info in |sample|.
   bool ReadPerfSampleInfo(const event_t& event,
                           struct perf_sample* sample) const;
   // Writes |sample| info back to a perf event |event|.
   bool WritePerfSampleInfo(const perf_sample& sample,
                            event_t* event) const;

   // Accessor funcs.
   const std::vector<PerfFileAttr>& attrs() const {
     return attrs_;
   }

   const std::vector<malloced_unique_ptr<event_t>>& events() const {
     return events_;
   }

   const std::vector<perf_trace_event_type>& event_types() const {
     return event_types_;
   }

   const std::vector<build_id_event*>& build_id_events() const {
     return build_id_events_;
   }

   const std::vector<char>& tracing_data() const {
     return tracing_data_;
   }

  protected:
   bool ReadHeader(const ConstBufferWithSize& data);

   bool ReadAttrs(const ConstBufferWithSize& data);
   bool ReadAttr(const ConstBufferWithSize& data, size_t* offset);
   bool ReadEventAttr(const ConstBufferWithSize& data, size_t* offset,
                      perf_event_attr* attr);
   bool ReadUniqueIDs(const ConstBufferWithSize& data, size_t num_ids,
                      size_t* offset, std::vector<u64>* ids);

   bool ReadEventTypes(const ConstBufferWithSize& data);
   bool ReadEventType(const ConstBufferWithSize& data, size_t* offset);

   bool ReadData(const ConstBufferWithSize& data);

   // Reads metadata in normal mode.
   bool ReadMetadata(const ConstBufferWithSize& data);
   bool ReadTracingMetadata(const ConstBufferWithSize& data,
                            size_t offset, size_t size);
   bool ReadBuildIDMetadata(const ConstBufferWithSize& data, u32 type,
                            size_t offset, size_t size);
   bool ReadStringMetadata(const ConstBufferWithSize& data, u32 type,
                           size_t offset, size_t size);
   bool ReadUint32Metadata(const ConstBufferWithSize& data, u32 type,
                           size_t offset, size_t size);
   bool ReadUint64Metadata(const ConstBufferWithSize& data, u32 type,
                           size_t offset, size_t size);
   bool ReadCPUTopologyMetadata(const ConstBufferWithSize& data, u32 type,
                                size_t offset, size_t size);
   bool ReadNUMATopologyMetadata(const ConstBufferWithSize& data, u32 type,
                                 size_t offset, size_t size);

   // Read perf data from piped perf output data.
   bool ReadPipedData(const ConstBufferWithSize& data);
   bool ReadTracingMetadataEvent(const ConstBufferWithSize& data, size_t offset);

   // Like WriteToPointer, but does not check if the buffer is large enough.
   bool WriteToPointerWithoutCheckingSize(char* buffer, size_t size);

   bool WriteHeader(const BufferWithSize& data) const;
   bool WriteAttrs(const BufferWithSize& data) const;
   bool WriteEventTypes(const BufferWithSize& data) const;
   bool WriteData(const BufferWithSize& data) const;
   bool WriteMetadata(const BufferWithSize& data) const;

   // For writing the various types of metadata.
   bool WriteBuildIDMetadata(u32 type, size_t* offset,
                             const BufferWithSize& data) const;
   bool WriteStringMetadata(u32 type, size_t* offset,
                            const BufferWithSize& data) const;
   bool WriteUint32Metadata(u32 type, size_t* offset,
                            const BufferWithSize& data) const;
   bool WriteUint64Metadata(u32 type, size_t* offset,
                            const BufferWithSize& data) const;
   bool WriteEventDescMetadata(u32 type, size_t* offset,
                               const BufferWithSize& data) const;
   bool WriteCPUTopologyMetadata(u32 type, size_t* offset,
                                 const BufferWithSize& data) const;
   bool WriteNUMATopologyMetadata(u32 type, size_t* offset,
                                  const BufferWithSize& data) const;

   // For reading event blocks within piped perf data.
   bool ReadAttrEventBlock(const ConstBufferWithSize& data, size_t offset,
                           size_t size);
   bool ReadPerfEventBlock(const event_t& event);

   // Returns the number of types of metadata stored.
   size_t GetNumMetadata() const;

   // For computing the sizes of the various types of metadata.
   size_t GetBuildIDMetadataSize() const;
   size_t GetStringMetadataSize() const;
   size_t GetUint32MetadataSize() const;
   size_t GetUint64MetadataSize() const;
   size_t GetEventDescMetadataSize() const;
   size_t GetCPUTopologyMetadataSize() const;
   size_t GetNUMATopologyMetadataSize() const;

   // Returns true if we should write the number of strings for the string
   // metadata of type |type|.
   bool NeedsNumberOfStringData(u32 type) const;

   // Replaces existing filenames in MMAP/MMAP2 events based on |filename_map|.
   // This method does not change |build_id_events_|.
   bool LocalizeMMapFilenames(const std::map<string, string>& filename_map);

   std::vector<PerfFileAttr> attrs_;
   std::vector<perf_trace_event_type> event_types_;
   std::vector<malloced_unique_ptr<event_t>> events_;
   std::vector<build_id_event*> build_id_events_;
   std::vector<PerfStringMetadata> string_metadata_;
   std::vector<PerfUint32Metadata> uint32_metadata_;
   std::vector<PerfUint64Metadata> uint64_metadata_;
   PerfCPUTopologyMetadata cpu_topology_;
   std::vector<PerfNodeTopologyMetadata> numa_topology_;
   std::vector<char> tracing_data_;
   uint64_t sample_type_;
   uint64_t read_format_;
   uint64_t metadata_mask_;

   // Indicates that the perf data being read is from machine with a different
   // endianness than the current machine.
   bool is_cross_endian_;

  private:
   u32 ReadPerfEventAttrSize(const ConstBufferWithSize& data,
                             size_t attr_offset);

   // The file header is either a normal header or a piped header.
   union {
     struct perf_file_header header_;
     struct perf_pipe_file_header piped_header_;
   };
   struct perf_file_header out_header_;

   DISALLOW_COPY_AND_ASSIGN(PerfReader);
 };

 }  // namespace quipper

 #endif  // CHROMIUMOS_WIDE_PROFILING_PERF_READER_H_
	// Copyright (c) 2012 The Chromium OS Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef CHROMIUMOS_WIDE_PROFILING_PERF_READER_H_
	#define CHROMIUMOS_WIDE_PROFILING_PERF_READER_H_

	#include <stdint.h>

	#include <map>
	#include <set>
	#include <string>
	#include <type_traits>
	#include <vector>

	#include "base/macros.h"

	#include "perf_internals.h"
	#include "quipper_string.h"
	#include "perf_utils.h"

	namespace quipper {

	struct PerfFileAttr {
	struct perf_event_attr attr;
	std::vector<u64> ids;
	};

	// Based on code in tools/perf/util/header.c, the metadata are of the following
	// formats:

	// Based on kernel/perf_internals.h
	const size_t kBuildIDArraySize = 20;
	const size_t kBuildIDStringLength = kBuildIDArraySize * 2;

	struct CStringWithLength {
	u32 len;
	string str;
	};

	struct PerfStringMetadata {
	u32 type;
	std::vector<CStringWithLength> data;
	};

	struct PerfUint32Metadata {
	u32 type;
	std::vector<uint32_t> data;
	};

	struct PerfUint64Metadata {
	u32 type;
	std::vector<uint64_t> data;
	};

	typedef u32 num_siblings_type;

	struct PerfCPUTopologyMetadata {
	std::vector<CStringWithLength> core_siblings;
	std::vector<CStringWithLength> thread_siblings;
	};

	struct PerfNodeTopologyMetadata {
	u32 id;
	u64 total_memory;
	u64 free_memory;
	CStringWithLength cpu_list;
	};

	struct BufferWithSize;
	struct ConstBufferWithSize;

	class PerfReader {
	public:
	PerfReader() : sample_type_(0),
	read_format_(0),
	is_cross_endian_(0) {}
	~PerfReader();

	// Makes \|build_id\| fit the perf format, by either truncating it or adding
	// zeros to the end so that it has length kBuildIDStringLength.
	static void PerfizeBuildIDString(string* build_id);

	// Changes \|build_id\| to the best guess of what the build id was before going
	// through perf. Specifically, it keeps removing trailing sequences of four
	// zero bytes (or eight '0' characters) until there are no more such
	// sequences, or the build id would be empty if the process were repeated.
	static void UnperfizeBuildIDString(string* build_id);

	bool ReadFile(const string& filename);
	bool ReadFromVector(const std::vector<char>& data);
	bool ReadFromString(const string& str);
	bool ReadFromPointer(const char* perf_data, size_t size);

	// TODO(rohinmshah): GetSize should not use RegenerateHeader (so that it can
	// be const). Ideally, RegenerateHeader would be deleted and instead of
	// having out_header_ as an instance variable, it would be computed
	// dynamically whenever needed.

	// Returns the size in bytes that would be written by any of the methods that
	// write the entire perf data file (WriteFile, WriteToPointer, etc).
	size_t GetSize();

	bool WriteFile(const string& filename);
	bool WriteToVector(std::vector<char>* data);
	bool WriteToString(string* str);
	bool WriteToPointer(char* buffer, size_t size);

	bool RegenerateHeader();

	// Stores the mapping from filenames to build ids in build_id_events_.
	// Returns true on success.
	// Note: If \|filenames_to_build_ids\| contains a mapping for a filename for
	// which there is already a build_id_event in build_id_events_, a duplicate
	// build_id_event will be created, and the old build_id_event will NOT be
	// deleted.
	bool InjectBuildIDs(const std::map<string, string>& filenames_to_build_ids);

	// Replaces existing filenames with filenames from \|build_ids_to_filenames\|
	// by joining on build ids. If a build id in \|build_ids_to_filenames\| is not
	// present in this parser, it is ignored.
	bool Localize(const std::map<string, string>& build_ids_to_filenames);

	// Same as Localize, but joins on filenames instead of build ids.
	bool LocalizeUsingFilenames(const std::map<string, string>& filename_map);

	// Stores a list of unique filenames found in MMAP/MMAP2 events into
	// \|filenames\|. Any existing data in \|filenames\| will be lost.
	void GetFilenames(std::vector<string>* filenames) const;
	void GetFilenamesAsSet(std::set<string>* filenames) const;

	// Uses build id events to populate \|filenames_to_build_ids\|.
	// Any existing data in \|filenames_to_build_ids\| will be lost.
	// Note: A filename returned by GetFilenames need not be present in this map,
	// since there may be no build id event corresponding to the MMAP/MMAP2.
	void GetFilenamesToBuildIDs(
	std::map<string, string>* filenames_to_build_ids) const;

	static bool IsSupportedEventType(uint32_t type);

	// If a program using PerfReader calls events(), it could work with the
	// resulting events by importing kernel/perf_internals.h. This would also
	// apply to other forms of data (attributes, event types, build ids, etc.)
	// However, there is no easy way to work with the sample info within events.
	// The following two methods have been added for this purpose.

	// Extracts from a perf event \|event\| info about the perf sample that
	// contains the event. Stores info in \|sample\|.
	bool ReadPerfSampleInfo(const event_t& event,
	struct perf_sample* sample) const;
	// Writes \|sample\| info back to a perf event \|event\|.
	bool WritePerfSampleInfo(const perf_sample& sample,
	event_t* event) const;

	// Accessor funcs.
	const std::vector<PerfFileAttr>& attrs() const {
	return attrs_;
	}

	const std::vector<malloced_unique_ptr<event_t>>& events() const {
	return events_;
	}

	const std::vector<perf_trace_event_type>& event_types() const {
	return event_types_;
	}

	const std::vector<build_id_event*>& build_id_events() const {
	return build_id_events_;
	}

	const std::vector<char>& tracing_data() const {
	return tracing_data_;
	}

	protected:
	bool ReadHeader(const ConstBufferWithSize& data);

	bool ReadAttrs(const ConstBufferWithSize& data);
	bool ReadAttr(const ConstBufferWithSize& data, size_t* offset);
	bool ReadEventAttr(const ConstBufferWithSize& data, size_t* offset,
	perf_event_attr* attr);
	bool ReadUniqueIDs(const ConstBufferWithSize& data, size_t num_ids,
	size_t* offset, std::vector<u64>* ids);

	bool ReadEventTypes(const ConstBufferWithSize& data);
	bool ReadEventType(const ConstBufferWithSize& data, size_t* offset);

	bool ReadData(const ConstBufferWithSize& data);

	// Reads metadata in normal mode.
	bool ReadMetadata(const ConstBufferWithSize& data);
	bool ReadTracingMetadata(const ConstBufferWithSize& data,
	size_t offset, size_t size);
	bool ReadBuildIDMetadata(const ConstBufferWithSize& data, u32 type,
	size_t offset, size_t size);
	bool ReadStringMetadata(const ConstBufferWithSize& data, u32 type,
	size_t offset, size_t size);
	bool ReadUint32Metadata(const ConstBufferWithSize& data, u32 type,
	size_t offset, size_t size);
	bool ReadUint64Metadata(const ConstBufferWithSize& data, u32 type,
	size_t offset, size_t size);
	bool ReadCPUTopologyMetadata(const ConstBufferWithSize& data, u32 type,
	size_t offset, size_t size);
	bool ReadNUMATopologyMetadata(const ConstBufferWithSize& data, u32 type,
	size_t offset, size_t size);

	// Read perf data from piped perf output data.
	bool ReadPipedData(const ConstBufferWithSize& data);
	bool ReadTracingMetadataEvent(const ConstBufferWithSize& data, size_t offset);

	// Like WriteToPointer, but does not check if the buffer is large enough.
	bool WriteToPointerWithoutCheckingSize(char* buffer, size_t size);

	bool WriteHeader(const BufferWithSize& data) const;
	bool WriteAttrs(const BufferWithSize& data) const;
	bool WriteEventTypes(const BufferWithSize& data) const;
	bool WriteData(const BufferWithSize& data) const;
	bool WriteMetadata(const BufferWithSize& data) const;

	// For writing the various types of metadata.
	bool WriteBuildIDMetadata(u32 type, size_t* offset,
	const BufferWithSize& data) const;
	bool WriteStringMetadata(u32 type, size_t* offset,
	const BufferWithSize& data) const;
	bool WriteUint32Metadata(u32 type, size_t* offset,
	const BufferWithSize& data) const;
	bool WriteUint64Metadata(u32 type, size_t* offset,
	const BufferWithSize& data) const;
	bool WriteEventDescMetadata(u32 type, size_t* offset,
	const BufferWithSize& data) const;
	bool WriteCPUTopologyMetadata(u32 type, size_t* offset,
	const BufferWithSize& data) const;
	bool WriteNUMATopologyMetadata(u32 type, size_t* offset,
	const BufferWithSize& data) const;

	// For reading event blocks within piped perf data.
	bool ReadAttrEventBlock(const ConstBufferWithSize& data, size_t offset,
	size_t size);
	bool ReadPerfEventBlock(const event_t& event);

	// Returns the number of types of metadata stored.
	size_t GetNumMetadata() const;

	// For computing the sizes of the various types of metadata.
	size_t GetBuildIDMetadataSize() const;
	size_t GetStringMetadataSize() const;
	size_t GetUint32MetadataSize() const;
	size_t GetUint64MetadataSize() const;
	size_t GetEventDescMetadataSize() const;
	size_t GetCPUTopologyMetadataSize() const;
	size_t GetNUMATopologyMetadataSize() const;

	// Returns true if we should write the number of strings for the string
	// metadata of type \|type\|.
	bool NeedsNumberOfStringData(u32 type) const;

	// Replaces existing filenames in MMAP/MMAP2 events based on \|filename_map\|.
	// This method does not change \|build_id_events_\|.
	bool LocalizeMMapFilenames(const std::map<string, string>& filename_map);

	std::vector<PerfFileAttr> attrs_;
	std::vector<perf_trace_event_type> event_types_;
	std::vector<malloced_unique_ptr<event_t>> events_;
	std::vector<build_id_event*> build_id_events_;
	std::vector<PerfStringMetadata> string_metadata_;
	std::vector<PerfUint32Metadata> uint32_metadata_;
	std::vector<PerfUint64Metadata> uint64_metadata_;
	PerfCPUTopologyMetadata cpu_topology_;
	std::vector<PerfNodeTopologyMetadata> numa_topology_;
	std::vector<char> tracing_data_;
	uint64_t sample_type_;
	uint64_t read_format_;
	uint64_t metadata_mask_;

	// Indicates that the perf data being read is from machine with a different
	// endianness than the current machine.
	bool is_cross_endian_;

	private:
	u32 ReadPerfEventAttrSize(const ConstBufferWithSize& data,
	size_t attr_offset);

	// The file header is either a normal header or a piped header.
	union {
	struct perf_file_header header_;
	struct perf_pipe_file_header piped_header_;
	};
	struct perf_file_header out_header_;

	DISALLOW_COPY_AND_ASSIGN(PerfReader);
	};

	} // namespace quipper

	#endif // CHROMIUMOS_WIDE_PROFILING_PERF_READER_H_