third_party/perfetto/src/trace_processor/util/profile_builder.h - cobalt - Git at Google

 /*
  * Copyright (C) 2022 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #ifndef SRC_TRACE_PROCESSOR_UTIL_PROFILE_BUILDER_H_
 #define SRC_TRACE_PROCESSOR_UTIL_PROFILE_BUILDER_H_

 #include <optional>

 #include "perfetto/ext/base/string_view.h"
 #include "perfetto/protozero/packed_repeated_fields.h"
 #include "perfetto/protozero/scattered_heap_buffer.h"
 #include "protos/perfetto/trace_processor/stack.pbzero.h"
 #include "protos/third_party/pprof/profile.pbzero.h"
 #include "src/trace_processor/containers/string_pool.h"
 #include "src/trace_processor/storage/trace_storage.h"
 #include "src/trace_processor/tables/profiler_tables_py.h"
 #include "src/trace_processor/util/annotated_callsites.h"

 #include <algorithm>
 #include <cstdint>
 #include <functional>
 #include <unordered_map>
 #include <vector>

 namespace perfetto {
 namespace trace_processor {

 class TraceProcessorContext;

 // Builds a |perftools.profiles.Profile| proto.
 class GProfileBuilder {
  public:
   struct ValueType {
     std::string type;
     std::string unit;
   };

   // |sample_types| A description of the values stored with each sample.
   // |annotated| Whether to annotate callstack frames.
   //
   // Important: Annotations might interfere with certain aggregations, as we
   // will could have a frame that is annotated with different annotations. That
   // will lead to multiple functions being generated (sane name, line etc, but
   // different annotation). Since there is no field in a Profile proto to track
   // these annotations we extend the function name (my_func [annotation]), so
   // from pprof perspective we now have different functions. So in flame graphs
   // for example you will have one separate slice for each of these same
   // functions with different annotations.
   GProfileBuilder(const TraceProcessorContext* context,
                   const std::vector<ValueType>& sample_types);
   ~GProfileBuilder();

   // Returns false if the operation fails (e.g callsite_id was not found)
   bool AddSample(const protos::pbzero::Stack_Decoder& stack,
                  const protozero::PackedVarInt& values);

   // Finalizes the profile and returns the serialized proto. Can be called
   // multiple times but after the first invocation `AddSample` calls will have
   // no effect.
   std::string Build();

  private:
   static constexpr int64_t kEmptyStringIndex = 0;
   static constexpr uint64_t kNullFunctionId = 0;

   // Strings are stored in the `Profile` in a table and referenced by their
   // index. This helper class takes care of all the book keeping.
   // `TraceProcessor` uses its own `StringPool` for strings. This helper
   // provides convenient ways of dealing with `StringPool::Id` values instead of
   // actual string. This class ensures that two equal strings will have the same
   // index, so you can compare them instead of the actual strings.
   class StringTable {
    public:
     // |result| This is the `Profile` proto we are building. Strings will be
     // added to it as necessary. |string_pool| `StringPool` to quey for strings
     // passed as `StringPool:Id`
     StringTable(protozero::HeapBuffered<
                     third_party::perftools::profiles::pbzero::Profile>* result,
                 const StringPool* string_pool);

     // Adds the given string to the table, if not currently present, and returns
     // the index to it. Might write data to the infligt `Profile` so it should
     // not be called while in the middle of writing a message to the proto.
     int64_t InternString(base::StringView str);
     // Adds a string stored in the `TraceProcessor` `StringPool` to the table,
     // if not currently present, and returns the index to it. Might write data
     // to the inflight `Profile` so it should not be called while in the middle
     // of writing a message to the proto.
     int64_t InternString(StringPool::Id id);

     int64_t GetAnnotatedString(StringPool::Id str,
                                CallsiteAnnotation annotation);
     int64_t GetAnnotatedString(base::StringView str,
                                CallsiteAnnotation annotation);

    private:
     // Unconditionally writes the given string to the table and returns its
     // index.
     int64_t WriteString(base::StringView str);

     const StringPool& string_pool_;
     protozero::HeapBuffered<third_party::perftools::profiles::pbzero::Profile>&
         result_;

     std::unordered_map<StringPool::Id, int64_t> seen_string_pool_ids_;
     // Maps strings (hashes thereof) to indexes in the table.
     std::unordered_map<uint64_t, int64_t> seen_strings_;
     // Index where the next string will be written to
     int64_t next_index_{0};
   };

   struct AnnotatedFrameId {
     struct Hash {
       size_t operator()(const AnnotatedFrameId& id) const {
         return static_cast<size_t>(perfetto::base::Hasher::Combine(
             id.frame_id.value, static_cast<int>(id.annotation)));
       }
     };

     FrameId frame_id;
     CallsiteAnnotation annotation;

     bool operator==(const AnnotatedFrameId& other) const {
       return frame_id == other.frame_id && annotation == other.annotation;
     }
   };

   struct Line {
     uint64_t function_id;
     int64_t line;
     bool operator==(const Line& other) const {
       return function_id == other.function_id && line == other.line;
     }
   };

   // Location, MappingKey, Mapping, Function, and Line are helper structs to
   // deduplicate entities. We do not write these directly to the proto Profile
   // but instead stage them and write them out during `Finalize`. Samples on the
   // other hand are directly written to the proto.

   struct Location {
     struct Hash {
       size_t operator()(const Location& loc) const {
         perfetto::base::Hasher hasher;
         hasher.UpdateAll(loc.mapping_id, loc.rel_pc, loc.lines.size());
         for (const auto& line : loc.lines) {
           hasher.UpdateAll(line.function_id, line.line);
         }
         return static_cast<size_t>(hasher.digest());
       }
     };

     uint64_t mapping_id;
     uint64_t rel_pc;
     std::vector<Line> lines;

     bool operator==(const Location& other) const {
       return mapping_id == other.mapping_id && rel_pc == other.rel_pc &&
              lines == other.lines;
     }
   };

   // Mappings are tricky. We could have samples for different processes and
   // given address space layout randomization the same mapping could be located
   // at different addresses. MappingKey has the set of properties that uniquely
   // identify mapping in order to deduplicate rows in the stack_profile_mapping
   // table.
   struct MappingKey {
     struct Hash {
       size_t operator()(const MappingKey& mapping) const {
         perfetto::base::Hasher hasher;
         hasher.UpdateAll(mapping.size, mapping.file_offset,
                          mapping.build_id_or_filename);
         return static_cast<size_t>(hasher.digest());
       }
     };

     explicit MappingKey(
         const tables::StackProfileMappingTable::ConstRowReference& mapping,
         StringTable& string_table);

     bool operator==(const MappingKey& other) const {
       return size == other.size && file_offset == other.file_offset &&
              build_id_or_filename == other.build_id_or_filename;
     }

     uint64_t size;
     uint64_t file_offset;
     int64_t build_id_or_filename;
   };

   // Keeps track of what debug information is available for a mapping.
   // TODO(carlscab): We could be a bit more "clever" here. Currently if there is
   // debug info for at least one frame we flag the mapping as having debug info.
   // We could use some heuristic instead, e.g. if x% for frames have the info
   // etc.
   struct DebugInfo {
     bool has_functions{false};
     bool has_filenames{false};
     bool has_line_numbers{false};
     bool has_inline_frames{false};
   };

   struct Mapping {
     explicit Mapping(
         const tables::StackProfileMappingTable::ConstRowReference& mapping,
         const StringPool& string_pool,
         StringTable& string_table);

     // Heuristic to determine if this maps to the main binary. Bigger scores
     // mean higher likelihood.
     int64_t ComputeMainBinaryScore() const;

     const uint64_t memory_start;
     const uint64_t memory_limit;
     const uint64_t file_offset;
     const int64_t filename;
     const int64_t build_id;

     const std::string filename_str;

     DebugInfo debug_info;
   };

   struct Function {
     struct Hash {
       size_t operator()(const Function& func) const {
         return static_cast<size_t>(perfetto::base::Hasher::Combine(
             func.name, func.system_name, func.filename));
       }
     };

     int64_t name;
     int64_t system_name;
     int64_t filename;

     bool operator==(const Function& other) const {
       return name == other.name && system_name == other.system_name &&
              filename == other.filename;
     }
   };

   const protozero::PackedVarInt& GetLocationIdsForCallsite(
       const CallsiteId& callsite_id,
       bool annotated);

   std::vector<Line> GetLinesForSymbolSetId(
       std::optional<uint32_t> symbol_set_id,
       CallsiteAnnotation annotation,
       uint64_t mapping_id);

   std::vector<Line> GetLines(
       const tables::StackProfileFrameTable::ConstRowReference& frame,
       CallsiteAnnotation annotation,
       uint64_t mapping_id);

   int64_t GetNameForFrame(
       const tables::StackProfileFrameTable::ConstRowReference& frame,
       CallsiteAnnotation annotation);

   int64_t GetSystemNameForFrame(
       const tables::StackProfileFrameTable::ConstRowReference& frame);

   uint64_t WriteLocationIfNeeded(FrameId frame_id,
                                  CallsiteAnnotation annotation);
   uint64_t WriteFakeLocationIfNeeded(const std::string& name);

   uint64_t WriteFunctionIfNeeded(
       const tables::SymbolTable::ConstRowReference& symbol,
       CallsiteAnnotation annotation,
       uint64_t mapping_id);

   uint64_t WriteFunctionIfNeeded(
       const tables::StackProfileFrameTable::ConstRowReference& frame,
       CallsiteAnnotation annotation,
       uint64_t mapping_id);

   uint64_t WriteFakeFunctionIfNeeded(int64_t name_id);

   uint64_t WriteMappingIfNeeded(
       const tables::StackProfileMappingTable::ConstRowReference& mapping);
   void WriteMappings();
   void WriteMapping(uint64_t mapping_id);
   void WriteFunctions();
   void WriteLocations();

   void WriteSampleTypes(const std::vector<ValueType>& sample_types);

   void Finalize();

   Mapping& GetMapping(uint64_t mapping_id) {
     return mappings_[static_cast<size_t>(mapping_id - 1)];
   }

   // Goes over the list of staged mappings and tries to determine which is the
   // most likely main binary.
   std::optional<uint64_t> GuessMainBinary() const;

   bool AddSample(const protozero::PackedVarInt& location_ids,
                  const protozero::PackedVarInt& values);

   // Profile proto being serialized.
   protozero::HeapBuffered<third_party::perftools::profiles::pbzero::Profile>
       result_;

   const TraceProcessorContext& context_;
   StringTable string_table_;

   bool finalized_{false};
   AnnotatedCallsites annotations_;

   // Caches a (possibly annotated) CallsiteId (callstack) to the list of
   // locations emitted to the profile.
   struct MaybeAnnotatedCallsiteId {
     struct Hash {
       size_t operator()(const MaybeAnnotatedCallsiteId& id) const {
         return static_cast<size_t>(
             perfetto::base::Hasher::Combine(id.callsite_id.value, id.annotate));
       }
     };

     CallsiteId callsite_id;
     bool annotate;

     bool operator==(const MaybeAnnotatedCallsiteId& other) const {
       return callsite_id == other.callsite_id && annotate == other.annotate;
     }
   };
   std::unordered_map<MaybeAnnotatedCallsiteId,
                      protozero::PackedVarInt,
                      MaybeAnnotatedCallsiteId::Hash>
       cached_location_ids_;

   // Helpers to map TraceProcessor rows to already written Profile entities
   // (their ids).
   std::unordered_map<AnnotatedFrameId, uint64_t, AnnotatedFrameId::Hash>
       seen_locations_;
   std::unordered_map<AnnotatedFrameId, uint64_t, AnnotatedFrameId::Hash>
       seen_functions_;
   std::unordered_map<MappingId, uint64_t> seen_mappings_;
   std::unordered_map<int64_t, uint64_t> seen_fake_locations_;

   // Helpers to deduplicate entries. Map entity to its id. These also serve as a
   // staging area until written out to the profile proto during `Finalize`. Ids
   // are consecutive integers starting at 1. (Ids with value 0 are not allowed).
   // Ids are not unique across entities (i.e. there can be a mapping_id = 1 and
   // a function_id = 1)
   std::unordered_map<Location, uint64_t, Location::Hash> locations_;
   std::unordered_map<MappingKey, uint64_t, MappingKey::Hash> mapping_keys_;
   std::unordered_map<Function, uint64_t, Function::Hash> functions_;
   // Staging area for Mappings. mapping_id - 1 = index in the vector.
   std::vector<Mapping> mappings_;
 };

 }  // namespace trace_processor
 }  // namespace perfetto

 #endif  // SRC_TRACE_PROCESSOR_UTIL_PROFILE_BUILDER_H_
	/*
	* Copyright (C) 2022 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#ifndef SRC_TRACE_PROCESSOR_UTIL_PROFILE_BUILDER_H_
	#define SRC_TRACE_PROCESSOR_UTIL_PROFILE_BUILDER_H_

	#include <optional>

	#include "perfetto/ext/base/string_view.h"
	#include "perfetto/protozero/packed_repeated_fields.h"
	#include "perfetto/protozero/scattered_heap_buffer.h"
	#include "protos/perfetto/trace_processor/stack.pbzero.h"
	#include "protos/third_party/pprof/profile.pbzero.h"
	#include "src/trace_processor/containers/string_pool.h"
	#include "src/trace_processor/storage/trace_storage.h"
	#include "src/trace_processor/tables/profiler_tables_py.h"
	#include "src/trace_processor/util/annotated_callsites.h"

	#include <algorithm>
	#include <cstdint>
	#include <functional>
	#include <unordered_map>
	#include <vector>

	namespace perfetto {
	namespace trace_processor {

	class TraceProcessorContext;

	// Builds a \|perftools.profiles.Profile\| proto.
	class GProfileBuilder {
	public:
	struct ValueType {
	std::string type;
	std::string unit;
	};

	// \|sample_types\| A description of the values stored with each sample.
	// \|annotated\| Whether to annotate callstack frames.
	//
	// Important: Annotations might interfere with certain aggregations, as we
	// will could have a frame that is annotated with different annotations. That
	// will lead to multiple functions being generated (sane name, line etc, but
	// different annotation). Since there is no field in a Profile proto to track
	// these annotations we extend the function name (my_func [annotation]), so
	// from pprof perspective we now have different functions. So in flame graphs
	// for example you will have one separate slice for each of these same
	// functions with different annotations.
	GProfileBuilder(const TraceProcessorContext* context,
	const std::vector<ValueType>& sample_types);
	~GProfileBuilder();

	// Returns false if the operation fails (e.g callsite_id was not found)
	bool AddSample(const protos::pbzero::Stack_Decoder& stack,
	const protozero::PackedVarInt& values);

	// Finalizes the profile and returns the serialized proto. Can be called
	// multiple times but after the first invocation `AddSample` calls will have
	// no effect.
	std::string Build();

	private:
	static constexpr int64_t kEmptyStringIndex = 0;
	static constexpr uint64_t kNullFunctionId = 0;

	// Strings are stored in the `Profile` in a table and referenced by their
	// index. This helper class takes care of all the book keeping.
	// `TraceProcessor` uses its own `StringPool` for strings. This helper
	// provides convenient ways of dealing with `StringPool::Id` values instead of
	// actual string. This class ensures that two equal strings will have the same
	// index, so you can compare them instead of the actual strings.
	class StringTable {
	public:
	// \|result\| This is the `Profile` proto we are building. Strings will be
	// added to it as necessary. \|string_pool\| `StringPool` to quey for strings
	// passed as `StringPool:Id`
	StringTable(protozero::HeapBuffered<
	third_party::perftools::profiles::pbzero::Profile>* result,
	const StringPool* string_pool);

	// Adds the given string to the table, if not currently present, and returns
	// the index to it. Might write data to the infligt `Profile` so it should
	// not be called while in the middle of writing a message to the proto.
	int64_t InternString(base::StringView str);
	// Adds a string stored in the `TraceProcessor` `StringPool` to the table,
	// if not currently present, and returns the index to it. Might write data
	// to the inflight `Profile` so it should not be called while in the middle
	// of writing a message to the proto.
	int64_t InternString(StringPool::Id id);

	int64_t GetAnnotatedString(StringPool::Id str,
	CallsiteAnnotation annotation);
	int64_t GetAnnotatedString(base::StringView str,
	CallsiteAnnotation annotation);

	private:
	// Unconditionally writes the given string to the table and returns its
	// index.
	int64_t WriteString(base::StringView str);

	const StringPool& string_pool_;
	protozero::HeapBuffered<third_party::perftools::profiles::pbzero::Profile>&
	result_;

	std::unordered_map<StringPool::Id, int64_t> seen_string_pool_ids_;
	// Maps strings (hashes thereof) to indexes in the table.
	std::unordered_map<uint64_t, int64_t> seen_strings_;
	// Index where the next string will be written to
	int64_t next_index_{0};
	};

	struct AnnotatedFrameId {
	struct Hash {
	size_t operator()(const AnnotatedFrameId& id) const {
	return static_cast<size_t>(perfetto::base::Hasher::Combine(
	id.frame_id.value, static_cast<int>(id.annotation)));
	}
	};

	FrameId frame_id;
	CallsiteAnnotation annotation;

	bool operator==(const AnnotatedFrameId& other) const {
	return frame_id == other.frame_id && annotation == other.annotation;
	}
	};

	struct Line {
	uint64_t function_id;
	int64_t line;
	bool operator==(const Line& other) const {
	return function_id == other.function_id && line == other.line;
	}
	};

	// Location, MappingKey, Mapping, Function, and Line are helper structs to
	// deduplicate entities. We do not write these directly to the proto Profile
	// but instead stage them and write them out during `Finalize`. Samples on the
	// other hand are directly written to the proto.

	struct Location {
	struct Hash {
	size_t operator()(const Location& loc) const {
	perfetto::base::Hasher hasher;
	hasher.UpdateAll(loc.mapping_id, loc.rel_pc, loc.lines.size());
	for (const auto& line : loc.lines) {
	hasher.UpdateAll(line.function_id, line.line);
	}
	return static_cast<size_t>(hasher.digest());
	}
	};

	uint64_t mapping_id;
	uint64_t rel_pc;
	std::vector<Line> lines;

	bool operator==(const Location& other) const {
	return mapping_id == other.mapping_id && rel_pc == other.rel_pc &&
	lines == other.lines;
	}
	};

	// Mappings are tricky. We could have samples for different processes and
	// given address space layout randomization the same mapping could be located
	// at different addresses. MappingKey has the set of properties that uniquely
	// identify mapping in order to deduplicate rows in the stack_profile_mapping
	// table.
	struct MappingKey {
	struct Hash {
	size_t operator()(const MappingKey& mapping) const {
	perfetto::base::Hasher hasher;
	hasher.UpdateAll(mapping.size, mapping.file_offset,
	mapping.build_id_or_filename);
	return static_cast<size_t>(hasher.digest());
	}
	};

	explicit MappingKey(
	const tables::StackProfileMappingTable::ConstRowReference& mapping,
	StringTable& string_table);

	bool operator==(const MappingKey& other) const {
	return size == other.size && file_offset == other.file_offset &&
	build_id_or_filename == other.build_id_or_filename;
	}

	uint64_t size;
	uint64_t file_offset;
	int64_t build_id_or_filename;
	};

	// Keeps track of what debug information is available for a mapping.
	// TODO(carlscab): We could be a bit more "clever" here. Currently if there is
	// debug info for at least one frame we flag the mapping as having debug info.
	// We could use some heuristic instead, e.g. if x% for frames have the info
	// etc.
	struct DebugInfo {
	bool has_functions{false};
	bool has_filenames{false};
	bool has_line_numbers{false};
	bool has_inline_frames{false};
	};

	struct Mapping {
	explicit Mapping(
	const tables::StackProfileMappingTable::ConstRowReference& mapping,
	const StringPool& string_pool,
	StringTable& string_table);

	// Heuristic to determine if this maps to the main binary. Bigger scores
	// mean higher likelihood.
	int64_t ComputeMainBinaryScore() const;

	const uint64_t memory_start;
	const uint64_t memory_limit;
	const uint64_t file_offset;
	const int64_t filename;
	const int64_t build_id;

	const std::string filename_str;

	DebugInfo debug_info;
	};

	struct Function {
	struct Hash {
	size_t operator()(const Function& func) const {
	return static_cast<size_t>(perfetto::base::Hasher::Combine(
	func.name, func.system_name, func.filename));
	}
	};

	int64_t name;
	int64_t system_name;
	int64_t filename;

	bool operator==(const Function& other) const {
	return name == other.name && system_name == other.system_name &&
	filename == other.filename;
	}
	};

	const protozero::PackedVarInt& GetLocationIdsForCallsite(
	const CallsiteId& callsite_id,
	bool annotated);

	std::vector<Line> GetLinesForSymbolSetId(
	std::optional<uint32_t> symbol_set_id,
	CallsiteAnnotation annotation,
	uint64_t mapping_id);

	std::vector<Line> GetLines(
	const tables::StackProfileFrameTable::ConstRowReference& frame,
	CallsiteAnnotation annotation,
	uint64_t mapping_id);

	int64_t GetNameForFrame(
	const tables::StackProfileFrameTable::ConstRowReference& frame,
	CallsiteAnnotation annotation);

	int64_t GetSystemNameForFrame(
	const tables::StackProfileFrameTable::ConstRowReference& frame);

	uint64_t WriteLocationIfNeeded(FrameId frame_id,
	CallsiteAnnotation annotation);
	uint64_t WriteFakeLocationIfNeeded(const std::string& name);

	uint64_t WriteFunctionIfNeeded(
	const tables::SymbolTable::ConstRowReference& symbol,
	CallsiteAnnotation annotation,
	uint64_t mapping_id);

	uint64_t WriteFunctionIfNeeded(
	const tables::StackProfileFrameTable::ConstRowReference& frame,
	CallsiteAnnotation annotation,
	uint64_t mapping_id);

	uint64_t WriteFakeFunctionIfNeeded(int64_t name_id);

	uint64_t WriteMappingIfNeeded(
	const tables::StackProfileMappingTable::ConstRowReference& mapping);
	void WriteMappings();
	void WriteMapping(uint64_t mapping_id);
	void WriteFunctions();
	void WriteLocations();

	void WriteSampleTypes(const std::vector<ValueType>& sample_types);

	void Finalize();

	Mapping& GetMapping(uint64_t mapping_id) {
	return mappings_[static_cast<size_t>(mapping_id - 1)];
	}

	// Goes over the list of staged mappings and tries to determine which is the
	// most likely main binary.
	std::optional<uint64_t> GuessMainBinary() const;

	bool AddSample(const protozero::PackedVarInt& location_ids,
	const protozero::PackedVarInt& values);

	// Profile proto being serialized.
	protozero::HeapBuffered<third_party::perftools::profiles::pbzero::Profile>
	result_;

	const TraceProcessorContext& context_;
	StringTable string_table_;

	bool finalized_{false};
	AnnotatedCallsites annotations_;

	// Caches a (possibly annotated) CallsiteId (callstack) to the list of
	// locations emitted to the profile.
	struct MaybeAnnotatedCallsiteId {
	struct Hash {
	size_t operator()(const MaybeAnnotatedCallsiteId& id) const {
	return static_cast<size_t>(
	perfetto::base::Hasher::Combine(id.callsite_id.value, id.annotate));
	}
	};

	CallsiteId callsite_id;
	bool annotate;

	bool operator==(const MaybeAnnotatedCallsiteId& other) const {
	return callsite_id == other.callsite_id && annotate == other.annotate;
	}
	};
	std::unordered_map<MaybeAnnotatedCallsiteId,
	protozero::PackedVarInt,
	MaybeAnnotatedCallsiteId::Hash>
	cached_location_ids_;

	// Helpers to map TraceProcessor rows to already written Profile entities
	// (their ids).
	std::unordered_map<AnnotatedFrameId, uint64_t, AnnotatedFrameId::Hash>
	seen_locations_;
	std::unordered_map<AnnotatedFrameId, uint64_t, AnnotatedFrameId::Hash>
	seen_functions_;
	std::unordered_map<MappingId, uint64_t> seen_mappings_;
	std::unordered_map<int64_t, uint64_t> seen_fake_locations_;

	// Helpers to deduplicate entries. Map entity to its id. These also serve as a
	// staging area until written out to the profile proto during `Finalize`. Ids
	// are consecutive integers starting at 1. (Ids with value 0 are not allowed).
	// Ids are not unique across entities (i.e. there can be a mapping_id = 1 and
	// a function_id = 1)
	std::unordered_map<Location, uint64_t, Location::Hash> locations_;
	std::unordered_map<MappingKey, uint64_t, MappingKey::Hash> mapping_keys_;
	std::unordered_map<Function, uint64_t, Function::Hash> functions_;
	// Staging area for Mappings. mapping_id - 1 = index in the vector.
	std::vector<Mapping> mappings_;
	};

	} // namespace trace_processor
	} // namespace perfetto

	#endif // SRC_TRACE_PROCESSOR_UTIL_PROFILE_BUILDER_H_