/* * 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. */ #include "profiler.h" #include <sys/file.h> #include <sys/stat.h> #include <sys/uio.h> #include <fstream> #include "art_method-inl.h" #include "base/stl_util.h" #include "base/time_utils.h" #include "base/unix_file/fd_file.h" #include "class_linker.h" #include "common_throws.h" #include "debugger.h" #include "dex_file-inl.h" #include "instrumentation.h" #include "mirror/class-inl.h" #include "mirror/dex_cache.h" #include "mirror/object_array-inl.h" #include "mirror/object-inl.h" #include "os.h" #include "scoped_thread_state_change.h" #include "ScopedLocalRef.h" #include "thread.h" #include "thread_list.h" #include "utils.h" #include "entrypoints/quick/quick_entrypoints.h" namespace art { BackgroundMethodSamplingProfiler* BackgroundMethodSamplingProfiler::profiler_ = nullptr; pthread_t BackgroundMethodSamplingProfiler::profiler_pthread_ = 0U; volatile bool BackgroundMethodSamplingProfiler::shutting_down_ = false; // TODO: this profiler runs regardless of the state of the machine. Maybe we should use the // wakelock or something to modify the run characteristics. This can be done when we // have some performance data after it's been used for a while. // Walk through the method within depth of max_depth_ on the Java stack class BoundedStackVisitor : public StackVisitor { public: BoundedStackVisitor(std::vector<std::pair<ArtMethod*, uint32_t>>* stack, Thread* thread, uint32_t max_depth) SHARED_LOCKS_REQUIRED(Locks::mutator_lock_) : StackVisitor(thread, nullptr, StackVisitor::StackWalkKind::kIncludeInlinedFrames), stack_(stack), max_depth_(max_depth), depth_(0) {} bool VisitFrame() SHARED_LOCKS_REQUIRED(Locks::mutator_lock_) { ArtMethod* m = GetMethod(); if (m->IsRuntimeMethod()) { return true; } uint32_t dex_pc_ = GetDexPc(); stack_->push_back(std::make_pair(m, dex_pc_)); ++depth_; if (depth_ < max_depth_) { return true; } else { return false; } } private: std::vector<std::pair<ArtMethod*, uint32_t>>* stack_; const uint32_t max_depth_; uint32_t depth_; }; // This is called from either a thread list traversal or from a checkpoint. Regardless // of which caller, the mutator lock must be held. static void GetSample(Thread* thread, void* arg) SHARED_LOCKS_REQUIRED(Locks::mutator_lock_) { BackgroundMethodSamplingProfiler* profiler = reinterpret_cast<BackgroundMethodSamplingProfiler*>(arg); const ProfilerOptions profile_options = profiler->GetProfilerOptions(); switch (profile_options.GetProfileType()) { case kProfilerMethod: { ArtMethod* method = thread->GetCurrentMethod(nullptr); if ((false) && method == nullptr) { LOG(INFO) << "No current method available"; std::ostringstream os; thread->Dump(os); std::string data(os.str()); LOG(INFO) << data; } profiler->RecordMethod(method); break; } case kProfilerBoundedStack: { std::vector<InstructionLocation> stack; uint32_t max_depth = profile_options.GetMaxStackDepth(); BoundedStackVisitor bounded_stack_visitor(&stack, thread, max_depth); bounded_stack_visitor.WalkStack(); profiler->RecordStack(stack); break; } default: LOG(INFO) << "This profile type is not implemented."; } } // A closure that is called by the thread checkpoint code. class SampleCheckpoint FINAL : public Closure { public: explicit SampleCheckpoint(BackgroundMethodSamplingProfiler* const profiler) : profiler_(profiler) {} void Run(Thread* thread) OVERRIDE { Thread* self = Thread::Current(); if (thread == nullptr) { LOG(ERROR) << "Checkpoint with nullptr thread"; return; } // Grab the mutator lock (shared access). ScopedObjectAccess soa(self); // Grab a sample. GetSample(thread, this->profiler_); // And finally tell the barrier that we're done. this->profiler_->GetBarrier().Pass(self); } private: BackgroundMethodSamplingProfiler* const profiler_; }; bool BackgroundMethodSamplingProfiler::ShuttingDown(Thread* self) { MutexLock mu(self, *Locks::profiler_lock_); return shutting_down_; } void* BackgroundMethodSamplingProfiler::RunProfilerThread(void* arg) { Runtime* runtime = Runtime::Current(); BackgroundMethodSamplingProfiler* profiler = reinterpret_cast<BackgroundMethodSamplingProfiler*>(arg); // Add a random delay for the first time run so that we don't hammer the CPU // with all profiles running at the same time. const int kRandomDelayMaxSecs = 30; const double kMaxBackoffSecs = 24*60*60; // Max backoff time. srand(MicroTime() * getpid()); int startup_delay = rand() % kRandomDelayMaxSecs; // random delay for startup. CHECK(runtime->AttachCurrentThread("Profiler", true, runtime->GetSystemThreadGroup(), !runtime->IsAotCompiler())); Thread* self = Thread::Current(); double backoff = 1.0; while (true) { if (ShuttingDown(self)) { break; } { // wait until we need to run another profile uint64_t delay_secs = profiler->options_.GetPeriodS() * backoff; // Add a startup delay to prevent all the profiles running at once. delay_secs += startup_delay; // Immediate startup for benchmarking? if (profiler->options_.GetStartImmediately() && startup_delay > 0) { delay_secs = 0; } startup_delay = 0; VLOG(profiler) << "Delaying profile start for " << delay_secs << " secs"; MutexLock mu(self, profiler->wait_lock_); profiler->period_condition_.TimedWait(self, delay_secs * 1000, 0); // We were either signaled by Stop or timedout, in either case ignore the timed out result. // Expand the backoff by its coefficient, but don't go beyond the max. backoff = std::min(backoff * profiler->options_.GetBackoffCoefficient(), kMaxBackoffSecs); } if (ShuttingDown(self)) { break; } uint64_t start_us = MicroTime(); uint64_t end_us = start_us + profiler->options_.GetDurationS() * UINT64_C(1000000); uint64_t now_us = start_us; VLOG(profiler) << "Starting profiling run now for " << PrettyDuration((end_us - start_us) * 1000); SampleCheckpoint check_point(profiler); size_t valid_samples = 0; while (now_us < end_us) { if (ShuttingDown(self)) { break; } usleep(profiler->options_.GetIntervalUs()); // Non-interruptible sleep. ThreadList* thread_list = runtime->GetThreadList(); profiler->profiler_barrier_->Init(self, 0); size_t barrier_count = thread_list->RunCheckpointOnRunnableThreads(&check_point); // All threads are suspended, nothing to do. if (barrier_count == 0) { now_us = MicroTime(); continue; } valid_samples += barrier_count; ScopedThreadStateChange tsc(self, kWaitingForCheckPointsToRun); // Wait for the barrier to be crossed by all runnable threads. This wait // is done with a timeout so that we can detect problems with the checkpoint // running code. We should never see this. const uint32_t kWaitTimeoutMs = 10000; // Wait for all threads to pass the barrier. bool timed_out = profiler->profiler_barrier_->Increment(self, barrier_count, kWaitTimeoutMs); // We should never get a timeout. If we do, it suggests a problem with the checkpoint // code. Crash the process in this case. CHECK(!timed_out); // Update the current time. now_us = MicroTime(); } if (valid_samples > 0) { // After the profile has been taken, write it out. ScopedObjectAccess soa(self); // Acquire the mutator lock. uint32_t size = profiler->WriteProfile(); VLOG(profiler) << "Profile size: " << size; } } LOG(INFO) << "Profiler shutdown"; runtime->DetachCurrentThread(); return nullptr; } // Write out the profile file if we are generating a profile. uint32_t BackgroundMethodSamplingProfiler::WriteProfile() { std::string full_name = output_filename_; VLOG(profiler) << "Saving profile to " << full_name; int fd = open(full_name.c_str(), O_RDWR); if (fd < 0) { // Open failed. LOG(ERROR) << "Failed to open profile file " << full_name; return 0; } // Lock the file for exclusive access. This will block if another process is using // the file. int err = flock(fd, LOCK_EX); if (err < 0) { LOG(ERROR) << "Failed to lock profile file " << full_name; return 0; } // Read the previous profile. profile_table_.ReadPrevious(fd, options_.GetProfileType()); // Move back to the start of the file. lseek(fd, 0, SEEK_SET); // Format the profile output and write to the file. std::ostringstream os; uint32_t num_methods = DumpProfile(os); std::string data(os.str()); const char *p = data.c_str(); size_t length = data.length(); size_t full_length = length; do { int n = ::write(fd, p, length); p += n; length -= n; } while (length > 0); // Truncate the file to the new length. ftruncate(fd, full_length); // Now unlock the file, allowing another process in. err = flock(fd, LOCK_UN); if (err < 0) { LOG(ERROR) << "Failed to unlock profile file " << full_name; } // Done, close the file. ::close(fd); // Clean the profile for the next time. CleanProfile(); return num_methods; } bool BackgroundMethodSamplingProfiler::Start( const std::string& output_filename, const ProfilerOptions& options) { if (!options.IsEnabled()) { return false; } CHECK(!output_filename.empty()); Thread* self = Thread::Current(); { MutexLock mu(self, *Locks::profiler_lock_); // Don't start two profiler threads. if (profiler_ != nullptr) { return true; } } LOG(INFO) << "Starting profiler using output file: " << output_filename << " and options: " << options; { MutexLock mu(self, *Locks::profiler_lock_); profiler_ = new BackgroundMethodSamplingProfiler(output_filename, options); CHECK_PTHREAD_CALL(pthread_create, (&profiler_pthread_, nullptr, &RunProfilerThread, reinterpret_cast<void*>(profiler_)), "Profiler thread"); } return true; } void BackgroundMethodSamplingProfiler::Stop() { BackgroundMethodSamplingProfiler* profiler = nullptr; pthread_t profiler_pthread = 0U; { MutexLock trace_mu(Thread::Current(), *Locks::profiler_lock_); CHECK(!shutting_down_); profiler = profiler_; shutting_down_ = true; profiler_pthread = profiler_pthread_; } // Now wake up the sampler thread if it sleeping. { MutexLock profile_mu(Thread::Current(), profiler->wait_lock_); profiler->period_condition_.Signal(Thread::Current()); } // Wait for the sample thread to stop. CHECK_PTHREAD_CALL(pthread_join, (profiler_pthread, nullptr), "profiler thread shutdown"); { MutexLock mu(Thread::Current(), *Locks::profiler_lock_); profiler_ = nullptr; } delete profiler; } void BackgroundMethodSamplingProfiler::Shutdown() { Stop(); } BackgroundMethodSamplingProfiler::BackgroundMethodSamplingProfiler( const std::string& output_filename, const ProfilerOptions& options) : output_filename_(output_filename), options_(options), wait_lock_("Profile wait lock"), period_condition_("Profile condition", wait_lock_), profile_table_(wait_lock_), profiler_barrier_(new Barrier(0)) { // Populate the filtered_methods set. // This is empty right now, but to add a method, do this: // // filtered_methods_.insert("void java.lang.Object.wait(long, int)"); } // Filter out methods the profiler doesn't want to record. // We require mutator lock since some statistics will be updated here. bool BackgroundMethodSamplingProfiler::ProcessMethod(ArtMethod* method) { if (method == nullptr) { profile_table_.NullMethod(); // Don't record a null method. return false; } mirror::Class* cls = method->GetDeclaringClass(); if (cls != nullptr) { if (cls->GetClassLoader() == nullptr) { // Don't include things in the boot profile_table_.BootMethod(); return false; } } bool is_filtered = false; if (strcmp(method->GetName(), "<clinit>") == 0) { // always filter out class init is_filtered = true; } // Filter out methods by name if there are any. if (!is_filtered && filtered_methods_.size() > 0) { std::string method_full_name = PrettyMethod(method); // Don't include specific filtered methods. is_filtered = filtered_methods_.count(method_full_name) != 0; } return !is_filtered; } // A method has been hit, record its invocation in the method map. // The mutator_lock must be held (shared) when this is called. void BackgroundMethodSamplingProfiler::RecordMethod(ArtMethod* method) { // Add to the profile table unless it is filtered out. if (ProcessMethod(method)) { profile_table_.Put(method); } } // Record the current bounded stack into sampling results. void BackgroundMethodSamplingProfiler::RecordStack(const std::vector<InstructionLocation>& stack) { if (stack.size() == 0) { return; } // Get the method on top of the stack. We use this method to perform filtering. ArtMethod* method = stack.front().first; if (ProcessMethod(method)) { profile_table_.PutStack(stack); } } // Clean out any recordings for the method traces. void BackgroundMethodSamplingProfiler::CleanProfile() { profile_table_.Clear(); } uint32_t BackgroundMethodSamplingProfiler::DumpProfile(std::ostream& os) { return profile_table_.Write(os, options_.GetProfileType()); } // Profile Table. // This holds a mapping of ArtMethod* to a count of how many times a sample // hit it at the top of the stack. ProfileSampleResults::ProfileSampleResults(Mutex& lock) : lock_(lock), num_samples_(0), num_null_methods_(0), num_boot_methods_(0) { for (int i = 0; i < kHashSize; i++) { table[i] = nullptr; } method_context_table = nullptr; stack_trie_root_ = nullptr; } ProfileSampleResults::~ProfileSampleResults() { Clear(); } // Add a method to the profile table. If it's the first time the method // has been seen, add it with count=1, otherwise increment the count. void ProfileSampleResults::Put(ArtMethod* method) { MutexLock mu(Thread::Current(), lock_); uint32_t index = Hash(method); if (table[index] == nullptr) { table[index] = new Map(); } Map::iterator i = table[index]->find(method); if (i == table[index]->end()) { (*table[index])[method] = 1; } else { i->second++; } num_samples_++; } // Add a bounded stack to the profile table. Only the count of the method on // top of the frame will be increased. void ProfileSampleResults::PutStack(const std::vector<InstructionLocation>& stack) { MutexLock mu(Thread::Current(), lock_); ScopedObjectAccess soa(Thread::Current()); if (stack_trie_root_ == nullptr) { // The root of the stack trie is a dummy node so that we don't have to maintain // a collection of tries. stack_trie_root_ = new StackTrieNode(); } StackTrieNode* current = stack_trie_root_; if (stack.size() == 0) { current->IncreaseCount(); return; } for (std::vector<InstructionLocation>::const_reverse_iterator iter = stack.rbegin(); iter != stack.rend(); ++iter) { InstructionLocation inst_loc = *iter; ArtMethod* method = inst_loc.first; if (method == nullptr) { // skip null method continue; } uint32_t dex_pc = inst_loc.second; uint32_t method_idx = method->GetDexMethodIndex(); const DexFile* dex_file = method->GetDeclaringClass()->GetDexCache()->GetDexFile(); MethodReference method_ref(dex_file, method_idx); StackTrieNode* child = current->FindChild(method_ref, dex_pc); if (child != nullptr) { current = child; } else { uint32_t method_size = 0; const DexFile::CodeItem* codeitem = method->GetCodeItem(); if (codeitem != nullptr) { method_size = codeitem->insns_size_in_code_units_; } StackTrieNode* new_node = new StackTrieNode(method_ref, dex_pc, method_size, current); current->AppendChild(new_node); current = new_node; } } if (current != stack_trie_root_ && current->GetCount() == 0) { // Insert into method_context table; if (method_context_table == nullptr) { method_context_table = new MethodContextMap(); } MethodReference method = current->GetMethod(); MethodContextMap::iterator i = method_context_table->find(method); if (i == method_context_table->end()) { TrieNodeSet* node_set = new TrieNodeSet(); node_set->insert(current); (*method_context_table)[method] = node_set; } else { TrieNodeSet* node_set = i->second; node_set->insert(current); } } current->IncreaseCount(); num_samples_++; } // Write the profile table to the output stream. Also merge with the previous profile. uint32_t ProfileSampleResults::Write(std::ostream& os, ProfileDataType type) { ScopedObjectAccess soa(Thread::Current()); num_samples_ += previous_num_samples_; num_null_methods_ += previous_num_null_methods_; num_boot_methods_ += previous_num_boot_methods_; VLOG(profiler) << "Profile: " << num_samples_ << "/" << num_null_methods_ << "/" << num_boot_methods_; os << num_samples_ << "/" << num_null_methods_ << "/" << num_boot_methods_ << "\n"; uint32_t num_methods = 0; if (type == kProfilerMethod) { for (int i = 0 ; i < kHashSize; i++) { Map *map = table[i]; if (map != nullptr) { for (const auto &meth_iter : *map) { ArtMethod *method = meth_iter.first; std::string method_name = PrettyMethod(method); const DexFile::CodeItem* codeitem = method->GetCodeItem(); uint32_t method_size = 0; if (codeitem != nullptr) { method_size = codeitem->insns_size_in_code_units_; } uint32_t count = meth_iter.second; // Merge this profile entry with one from a previous run (if present). Also // remove the previous entry. PreviousProfile::iterator pi = previous_.find(method_name); if (pi != previous_.end()) { count += pi->second.count_; previous_.erase(pi); } os << StringPrintf("%s/%u/%u\n", method_name.c_str(), count, method_size); ++num_methods; } } } } else if (type == kProfilerBoundedStack) { if (method_context_table != nullptr) { for (const auto &method_iter : *method_context_table) { MethodReference method = method_iter.first; TrieNodeSet* node_set = method_iter.second; std::string method_name = PrettyMethod(method.dex_method_index, *(method.dex_file)); uint32_t method_size = 0; uint32_t total_count = 0; PreviousContextMap new_context_map; for (const auto &trie_node_i : *node_set) { StackTrieNode* node = trie_node_i; method_size = node->GetMethodSize(); uint32_t count = node->GetCount(); uint32_t dexpc = node->GetDexPC(); total_count += count; StackTrieNode* current = node->GetParent(); // We go backward on the trie to retrieve context and dex_pc until the dummy root. // The format of the context is "method_1@pc_1@method_2@pc_2@..." std::vector<std::string> context_vector; while (current != nullptr && current->GetParent() != nullptr) { context_vector.push_back(StringPrintf("%s@%u", PrettyMethod(current->GetMethod().dex_method_index, *(current->GetMethod().dex_file)).c_str(), current->GetDexPC())); current = current->GetParent(); } std::string context_sig = Join(context_vector, '@'); new_context_map[std::make_pair(dexpc, context_sig)] = count; } PreviousProfile::iterator pi = previous_.find(method_name); if (pi != previous_.end()) { total_count += pi->second.count_; PreviousContextMap* previous_context_map = pi->second.context_map_; if (previous_context_map != nullptr) { for (const auto &context_i : *previous_context_map) { uint32_t count = context_i.second; PreviousContextMap::iterator ci = new_context_map.find(context_i.first); if (ci == new_context_map.end()) { new_context_map[context_i.first] = count; } else { ci->second += count; } } } delete previous_context_map; previous_.erase(pi); } // We write out profile data with dex pc and context information in the following format: // "method/total_count/size/[pc_1:count_1:context_1#pc_2:count_2:context_2#...]". std::vector<std::string> context_count_vector; for (const auto &context_i : new_context_map) { context_count_vector.push_back(StringPrintf("%u:%u:%s", context_i.first.first, context_i.second, context_i.first.second.c_str())); } os << StringPrintf("%s/%u/%u/[%s]\n", method_name.c_str(), total_count, method_size, Join(context_count_vector, '#').c_str()); ++num_methods; } } } // Now we write out the remaining previous methods. for (const auto &pi : previous_) { if (type == kProfilerMethod) { os << StringPrintf("%s/%u/%u\n", pi.first.c_str(), pi.second.count_, pi.second.method_size_); } else if (type == kProfilerBoundedStack) { os << StringPrintf("%s/%u/%u/[", pi.first.c_str(), pi.second.count_, pi.second.method_size_); PreviousContextMap* previous_context_map = pi.second.context_map_; if (previous_context_map != nullptr) { std::vector<std::string> context_count_vector; for (const auto &context_i : *previous_context_map) { context_count_vector.push_back(StringPrintf("%u:%u:%s", context_i.first.first, context_i.second, context_i.first.second.c_str())); } os << Join(context_count_vector, '#'); } os << "]\n"; } ++num_methods; } return num_methods; } void ProfileSampleResults::Clear() { num_samples_ = 0; num_null_methods_ = 0; num_boot_methods_ = 0; for (int i = 0; i < kHashSize; i++) { delete table[i]; table[i] = nullptr; } if (stack_trie_root_ != nullptr) { stack_trie_root_->DeleteChildren(); delete stack_trie_root_; stack_trie_root_ = nullptr; if (method_context_table != nullptr) { delete method_context_table; method_context_table = nullptr; } } for (auto &pi : previous_) { if (pi.second.context_map_ != nullptr) { delete pi.second.context_map_; pi.second.context_map_ = nullptr; } } previous_.clear(); } uint32_t ProfileSampleResults::Hash(ArtMethod* method) { return (PointerToLowMemUInt32(method) >> 3) % kHashSize; } // Read a single line into the given string. Returns true if everything OK, false // on EOF or error. static bool ReadProfileLine(int fd, std::string& line) { char buf[4]; line.clear(); while (true) { int n = read(fd, buf, 1); // TODO: could speed this up but is it worth it? if (n != 1) { return false; } if (buf[0] == '\n') { break; } line += buf[0]; } return true; } void ProfileSampleResults::ReadPrevious(int fd, ProfileDataType type) { // Reset counters. previous_num_samples_ = previous_num_null_methods_ = previous_num_boot_methods_ = 0; std::string line; // The first line contains summary information. if (!ReadProfileLine(fd, line)) { return; } std::vector<std::string> summary_info; Split(line, '/', &summary_info); if (summary_info.size() != 3) { // Bad summary info. It should be count/nullcount/bootcount return; } previous_num_samples_ = strtoul(summary_info[0].c_str(), nullptr, 10); previous_num_null_methods_ = strtoul(summary_info[1].c_str(), nullptr, 10); previous_num_boot_methods_ = strtoul(summary_info[2].c_str(), nullptr, 10); // Now read each line until the end of file. Each line consists of 3 or 4 fields separated by / while (true) { if (!ReadProfileLine(fd, line)) { break; } std::vector<std::string> info; Split(line, '/', &info); if (info.size() != 3 && info.size() != 4) { // Malformed. break; } std::string methodname = info[0]; uint32_t total_count = strtoul(info[1].c_str(), nullptr, 10); uint32_t size = strtoul(info[2].c_str(), nullptr, 10); PreviousContextMap* context_map = nullptr; if (type == kProfilerBoundedStack && info.size() == 4) { context_map = new PreviousContextMap(); std::string context_counts_str = info[3].substr(1, info[3].size() - 2); std::vector<std::string> context_count_pairs; Split(context_counts_str, '#', &context_count_pairs); for (uint32_t i = 0; i < context_count_pairs.size(); ++i) { std::vector<std::string> context_count; Split(context_count_pairs[i], ':', &context_count); if (context_count.size() == 2) { // Handles the situtation when the profile file doesn't contain context information. uint32_t dexpc = strtoul(context_count[0].c_str(), nullptr, 10); uint32_t count = strtoul(context_count[1].c_str(), nullptr, 10); (*context_map)[std::make_pair(dexpc, "")] = count; } else { // Handles the situtation when the profile file contains context information. uint32_t dexpc = strtoul(context_count[0].c_str(), nullptr, 10); uint32_t count = strtoul(context_count[1].c_str(), nullptr, 10); std::string context = context_count[2]; (*context_map)[std::make_pair(dexpc, context)] = count; } } } previous_[methodname] = PreviousValue(total_count, size, context_map); } } bool ProfileFile::LoadFile(const std::string& fileName) { LOG(VERBOSE) << "reading profile file " << fileName; struct stat st; int err = stat(fileName.c_str(), &st); if (err == -1) { LOG(VERBOSE) << "not found"; return false; } if (st.st_size == 0) { return false; // Empty profiles are invalid. } std::ifstream in(fileName.c_str()); if (!in) { LOG(VERBOSE) << "profile file " << fileName << " exists but can't be opened"; LOG(VERBOSE) << "file owner: " << st.st_uid << ":" << st.st_gid; LOG(VERBOSE) << "me: " << getuid() << ":" << getgid(); LOG(VERBOSE) << "file permissions: " << std::oct << st.st_mode; LOG(VERBOSE) << "errno: " << errno; return false; } // The first line contains summary information. std::string line; std::getline(in, line); if (in.eof()) { return false; } std::vector<std::string> summary_info; Split(line, '/', &summary_info); if (summary_info.size() != 3) { // Bad summary info. It should be total/null/boot. return false; } // This is the number of hits in all profiled methods (without null or boot methods) uint32_t total_count = strtoul(summary_info[0].c_str(), nullptr, 10); // Now read each line until the end of file. Each line consists of 3 fields separated by '/'. // Store the info in descending order given by the most used methods. typedef std::set<std::pair<int, std::vector<std::string>>> ProfileSet; ProfileSet countSet; while (!in.eof()) { std::getline(in, line); if (in.eof()) { break; } std::vector<std::string> info; Split(line, '/', &info); if (info.size() != 3 && info.size() != 4) { // Malformed. return false; } int count = atoi(info[1].c_str()); countSet.insert(std::make_pair(-count, info)); } uint32_t curTotalCount = 0; ProfileSet::iterator end = countSet.end(); const ProfileData* prevData = nullptr; for (ProfileSet::iterator it = countSet.begin(); it != end ; it++) { const std::string& methodname = it->second[0]; uint32_t count = -it->first; uint32_t size = strtoul(it->second[2].c_str(), nullptr, 10); double usedPercent = (count * 100.0) / total_count; curTotalCount += count; // Methods with the same count should be part of the same top K percentage bucket. double topKPercentage = (prevData != nullptr) && (prevData->GetCount() == count) ? prevData->GetTopKUsedPercentage() : 100 * static_cast<double>(curTotalCount) / static_cast<double>(total_count); // Add it to the profile map. ProfileData curData = ProfileData(methodname, count, size, usedPercent, topKPercentage); profile_map_[methodname] = curData; prevData = &curData; } return true; } bool ProfileFile::GetProfileData(ProfileFile::ProfileData* data, const std::string& method_name) { ProfileMap::iterator i = profile_map_.find(method_name); if (i == profile_map_.end()) { return false; } *data = i->second; return true; } bool ProfileFile::GetTopKSamples(std::set<std::string>& topKSamples, double topKPercentage) { ProfileMap::iterator end = profile_map_.end(); for (ProfileMap::iterator it = profile_map_.begin(); it != end; it++) { if (it->second.GetTopKUsedPercentage() < topKPercentage) { topKSamples.insert(it->first); } } return true; } StackTrieNode* StackTrieNode::FindChild(MethodReference method, uint32_t dex_pc) { if (children_.size() == 0) { return nullptr; } // Create a dummy node for searching. StackTrieNode* node = new StackTrieNode(method, dex_pc, 0, nullptr); std::set<StackTrieNode*, StackTrieNodeComparator>::iterator i = children_.find(node); delete node; return (i == children_.end()) ? nullptr : *i; } void StackTrieNode::DeleteChildren() { for (auto &child : children_) { if (child != nullptr) { child->DeleteChildren(); delete child; } } } } // namespace art