/* * Copyright (C) 2011 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 ART_RUNTIME_PROFILER_H_ #define ART_RUNTIME_PROFILER_H_ #include <memory> #include <ostream> #include <set> #include <string> #include <vector> #include "barrier.h" #include "base/macros.h" #include "base/mutex.h" #include "globals.h" #include "instrumentation.h" #include "profiler_options.h" #include "os.h" #include "safe_map.h" #include "method_reference.h" namespace art { namespace mirror { class Class; } // namespace mirror class ArtMethod; class Thread; typedef std::pair<ArtMethod*, uint32_t> InstructionLocation; // This class stores the sampled bounded stacks in a trie structure. A path of the trie represents // a particular context with the method on top of the stack being a leaf or an internal node of the // trie rather than the root. class StackTrieNode { public: StackTrieNode(MethodReference method, uint32_t dex_pc, uint32_t method_size, StackTrieNode* parent) : parent_(parent), method_(method), dex_pc_(dex_pc), count_(0), method_size_(method_size) { } StackTrieNode() : parent_(nullptr), method_(nullptr, 0), dex_pc_(0), count_(0), method_size_(0) { } StackTrieNode* GetParent() { return parent_; } MethodReference GetMethod() { return method_; } uint32_t GetCount() { return count_; } uint32_t GetDexPC() { return dex_pc_; } uint32_t GetMethodSize() { return method_size_; } void AppendChild(StackTrieNode* child) { children_.insert(child); } StackTrieNode* FindChild(MethodReference method, uint32_t dex_pc); void DeleteChildren(); void IncreaseCount() { ++count_; } private: // Comparator for stack trie node. struct StackTrieNodeComparator { bool operator()(StackTrieNode* node1, StackTrieNode* node2) const { MethodReference mr1 = node1->GetMethod(); MethodReference mr2 = node2->GetMethod(); if (mr1.dex_file == mr2.dex_file) { if (mr1.dex_method_index == mr2.dex_method_index) { return node1->GetDexPC() < node2->GetDexPC(); } else { return mr1.dex_method_index < mr2.dex_method_index; } } else { return mr1.dex_file < mr2.dex_file; } } }; std::set<StackTrieNode*, StackTrieNodeComparator> children_; StackTrieNode* parent_; MethodReference method_; uint32_t dex_pc_; uint32_t count_; uint32_t method_size_; }; // // This class holds all the results for all runs of the profiler. It also // counts the number of null methods (where we can't determine the method) and // the number of methods in the boot path (where we have already compiled the method). // // This object is an internal profiler object and uses the same locking as the profiler // itself. class ProfileSampleResults { public: explicit ProfileSampleResults(Mutex& lock); ~ProfileSampleResults(); void Put(ArtMethod* method); void PutStack(const std::vector<InstructionLocation>& stack_dump); uint32_t Write(std::ostream &os, ProfileDataType type); void ReadPrevious(int fd, ProfileDataType type); void Clear(); uint32_t GetNumSamples() { return num_samples_; } void NullMethod() { ++num_null_methods_; } void BootMethod() { ++num_boot_methods_; } private: uint32_t Hash(ArtMethod* method); static constexpr int kHashSize = 17; Mutex& lock_; // Reference to the main profiler lock - we don't need two of them. uint32_t num_samples_; // Total number of samples taken. uint32_t num_null_methods_; // Number of samples where can don't know the method. uint32_t num_boot_methods_; // Number of samples in the boot path. typedef std::map<ArtMethod*, uint32_t> Map; // Map of method vs its count. Map *table[kHashSize]; typedef std::set<StackTrieNode*> TrieNodeSet; // Map of method hit by profiler vs the set of stack trie nodes for this method. typedef std::map<MethodReference, TrieNodeSet*, MethodReferenceComparator> MethodContextMap; MethodContextMap *method_context_table; StackTrieNode* stack_trie_root_; // Root of the trie that stores sampled stack information. // Map from <pc, context> to counts. typedef std::map<std::pair<uint32_t, std::string>, uint32_t> PreviousContextMap; struct PreviousValue { PreviousValue() : count_(0), method_size_(0), context_map_(nullptr) {} PreviousValue(uint32_t count, uint32_t method_size, PreviousContextMap* context_map) : count_(count), method_size_(method_size), context_map_(context_map) {} uint32_t count_; uint32_t method_size_; PreviousContextMap* context_map_; }; typedef std::map<std::string, PreviousValue> PreviousProfile; PreviousProfile previous_; uint32_t previous_num_samples_; uint32_t previous_num_null_methods_; // Number of samples where can don't know the method. uint32_t previous_num_boot_methods_; // Number of samples in the boot path. }; // // The BackgroundMethodSamplingProfiler runs in a thread. Most of the time it is sleeping but // occasionally wakes up and counts the number of times a method is called. Each time // it ticks, it looks at the current method and records it in the ProfileSampleResults // table. // // The timing is controlled by a number of variables: // 1. Period: the time between sampling runs. // 2. Interval: the time between each sample in a run. // 3. Duration: the duration of a run. // // So the profiler thread is sleeping for the 'period' time. It wakes up and runs for the // 'duration'. The run consists of a series of samples, each of which is 'interval' microseconds // apart. At the end of a run, it writes the results table to a file and goes back to sleep. class BackgroundMethodSamplingProfiler { public: // Start a profile thread with the user-supplied arguments. // Returns true if the profile was started or if it was already running. Returns false otherwise. static bool Start(const std::string& output_filename, const ProfilerOptions& options) LOCKS_EXCLUDED(Locks::mutator_lock_, Locks::thread_list_lock_, Locks::thread_suspend_count_lock_, Locks::profiler_lock_); static void Stop() LOCKS_EXCLUDED(Locks::profiler_lock_, wait_lock_); static void Shutdown() LOCKS_EXCLUDED(Locks::profiler_lock_); void RecordMethod(ArtMethod *method) SHARED_LOCKS_REQUIRED(Locks::mutator_lock_); void RecordStack(const std::vector<InstructionLocation>& stack) SHARED_LOCKS_REQUIRED(Locks::mutator_lock_); bool ProcessMethod(ArtMethod* method) SHARED_LOCKS_REQUIRED(Locks::mutator_lock_); const ProfilerOptions& GetProfilerOptions() const { return options_; } Barrier& GetBarrier() { return *profiler_barrier_; } private: explicit BackgroundMethodSamplingProfiler( const std::string& output_filename, const ProfilerOptions& options); // The sampling interval in microseconds is passed as an argument. static void* RunProfilerThread(void* arg) LOCKS_EXCLUDED(Locks::profiler_lock_); uint32_t WriteProfile() SHARED_LOCKS_REQUIRED(Locks::mutator_lock_); void CleanProfile(); uint32_t DumpProfile(std::ostream& os) SHARED_LOCKS_REQUIRED(Locks::mutator_lock_); static bool ShuttingDown(Thread* self) LOCKS_EXCLUDED(Locks::profiler_lock_); static BackgroundMethodSamplingProfiler* profiler_ GUARDED_BY(Locks::profiler_lock_); // We need to shut the sample thread down at exit. Setting this to true will do that. static volatile bool shutting_down_ GUARDED_BY(Locks::profiler_lock_); // Sampling thread, non-zero when sampling. static pthread_t profiler_pthread_; // Some measure of the number of samples that are significant. static constexpr uint32_t kSignificantSamples = 10; // The name of the file where profile data will be written. std::string output_filename_; // The options used to start the profiler. const ProfilerOptions& options_; // Profile condition support. Mutex wait_lock_ DEFAULT_MUTEX_ACQUIRED_AFTER; ConditionVariable period_condition_ GUARDED_BY(wait_lock_); ProfileSampleResults profile_table_; std::unique_ptr<Barrier> profiler_barrier_; // Set of methods to be filtered out. This will probably be rare because // most of the methods we want to be filtered reside in the boot path and // are automatically filtered. typedef std::set<std::string> FilteredMethods; FilteredMethods filtered_methods_; DISALLOW_COPY_AND_ASSIGN(BackgroundMethodSamplingProfiler); }; // // Contains profile data generated from previous runs of the program and stored // in a file. It is used to determine whether to compile a particular method or not. class ProfileFile { public: class ProfileData { public: ProfileData() : count_(0), method_size_(0), used_percent_(0) {} ProfileData(const std::string& method_name, uint32_t count, uint32_t method_size, double used_percent, double top_k_used_percentage) : method_name_(method_name), count_(count), method_size_(method_size), used_percent_(used_percent), top_k_used_percentage_(top_k_used_percentage) { // TODO: currently method_size_ is unused UNUSED(method_size_); } double GetUsedPercent() const { return used_percent_; } uint32_t GetCount() const { return count_; } double GetTopKUsedPercentage() const { return top_k_used_percentage_; } private: std::string method_name_; // Method name. uint32_t count_; // Number of times it has been called. uint32_t method_size_; // Size of the method on dex instructions. double used_percent_; // Percentage of how many times this method was called. double top_k_used_percentage_; // The percentage of the group that comprise K% of the total // used methods this methods belongs to. }; public: // Loads profile data from the given file. The new data are merged with any existing data. // Returns true if the file was loaded successfully and false otherwise. bool LoadFile(const std::string& filename); // Computes the group that comprise top_k_percentage of the total used methods. bool GetTopKSamples(std::set<std::string>& top_k_methods, double top_k_percentage); // If the given method has an entry in the profile table it updates the data // and returns true. Otherwise returns false and leaves the data unchanged. bool GetProfileData(ProfileData* data, const std::string& method_name); private: // Profile data is stored in a map, indexed by the full method name. typedef std::map<std::string, ProfileData> ProfileMap; ProfileMap profile_map_; }; } // namespace art #endif // ART_RUNTIME_PROFILER_H_