/* * 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. */ #define ATRACE_TAG ATRACE_TAG_DALVIK #include #include #include "timing_logger.h" #include "base/logging.h" #include "thread.h" #include "base/stl_util.h" #include "base/histogram-inl.h" #include #include namespace art { CumulativeLogger::CumulativeLogger(const std::string& name) : name_(name), lock_name_("CumulativeLoggerLock" + name), lock_(lock_name_.c_str(), kDefaultMutexLevel, true) { Reset(); } CumulativeLogger::~CumulativeLogger() { STLDeleteValues(&histograms_); } void CumulativeLogger::SetName(const std::string& name) { name_.assign(name); } void CumulativeLogger::Start() { } void CumulativeLogger::End() { MutexLock mu(Thread::Current(), lock_); iterations_++; } void CumulativeLogger::Reset() { MutexLock mu(Thread::Current(), lock_); iterations_ = 0; STLDeleteValues(&histograms_); } uint64_t CumulativeLogger::GetTotalNs() const { return GetTotalTime() * kAdjust; } uint64_t CumulativeLogger::GetTotalTime() const { MutexLock mu(Thread::Current(), lock_); uint64_t total = 0; for (CumulativeLogger::HistogramsIterator it = histograms_.begin(), end = histograms_.end(); it != end; ++it) { total += it->second->Sum(); } return total; } void CumulativeLogger::AddLogger(const base::TimingLogger &logger) { MutexLock mu(Thread::Current(), lock_); const base::TimingLogger::SplitTimings& splits = logger.GetSplits(); for (base::TimingLogger::SplitTimingsIterator it = splits.begin(), end = splits.end(); it != end; ++it) { base::TimingLogger::SplitTiming split = *it; uint64_t split_time = split.first; const char* split_name = split.second; AddPair(split_name, split_time); } } void CumulativeLogger::Dump(std::ostream &os) { MutexLock mu(Thread::Current(), lock_); DumpHistogram(os); } void CumulativeLogger::AddPair(const std::string &label, uint64_t delta_time) { // Convert delta time to microseconds so that we don't overflow our counters. delta_time /= kAdjust; if (histograms_.find(label) == histograms_.end()) { // TODO: Shoud this be a defined constant so we we know out of which orifice 16 and 100 were picked? const size_t max_buckets = Runtime::Current()->GetHeap()->IsLowMemoryMode() ? 16 : 100; // TODO: Should this be a defined constant so we know 50 of WTF? histograms_[label] = new Histogram(label.c_str(), 50, max_buckets); } histograms_[label]->AddValue(delta_time); } void CumulativeLogger::DumpHistogram(std::ostream &os) { os << "Start Dumping histograms for " << iterations_ << " iterations" << " for " << name_ << "\n"; for (CumulativeLogger::HistogramsIterator it = histograms_.begin(), end = histograms_.end(); it != end; ++it) { Histogram::CumulativeData cumulative_data; it->second->CreateHistogram(cumulative_data); it->second->PrintConfidenceIntervals(os, 0.99, cumulative_data); // Reset cumulative values to save memory. We don't expect DumpHistogram to be called often, so // it is not performance critical. } os << "Done Dumping histograms \n"; } namespace base { TimingLogger::TimingLogger(const char* name, bool precise, bool verbose) : name_(name), precise_(precise), verbose_(verbose), current_split_(NULL) { } void TimingLogger::Reset() { current_split_ = NULL; splits_.clear(); } void TimingLogger::StartSplit(const char* new_split_label) { DCHECK(new_split_label != NULL) << "Starting split (" << new_split_label << ") with null label."; TimingLogger::ScopedSplit* explicit_scoped_split = new TimingLogger::ScopedSplit(new_split_label, this); explicit_scoped_split->explicit_ = true; } void TimingLogger::EndSplit() { CHECK(current_split_ != NULL) << "Ending a non-existent split."; DCHECK(current_split_->label_ != NULL); DCHECK(current_split_->explicit_ == true) << "Explicitly ending scoped split: " << current_split_->label_; delete current_split_; } // Ends the current split and starts the one given by the label. void TimingLogger::NewSplit(const char* new_split_label) { CHECK(current_split_ != NULL) << "Inserting a new split (" << new_split_label << ") into a non-existent split."; DCHECK(new_split_label != NULL) << "New split (" << new_split_label << ") with null label."; current_split_->TailInsertSplit(new_split_label); } uint64_t TimingLogger::GetTotalNs() const { uint64_t total_ns = 0; for (base::TimingLogger::SplitTimingsIterator it = splits_.begin(), end = splits_.end(); it != end; ++it) { base::TimingLogger::SplitTiming split = *it; total_ns += split.first; } return total_ns; } void TimingLogger::Dump(std::ostream &os) const { uint64_t longest_split = 0; uint64_t total_ns = 0; for (base::TimingLogger::SplitTimingsIterator it = splits_.begin(), end = splits_.end(); it != end; ++it) { base::TimingLogger::SplitTiming split = *it; uint64_t split_time = split.first; longest_split = std::max(longest_split, split_time); total_ns += split_time; } // Compute which type of unit we will use for printing the timings. TimeUnit tu = GetAppropriateTimeUnit(longest_split); uint64_t divisor = GetNsToTimeUnitDivisor(tu); // Print formatted splits. for (base::TimingLogger::SplitTimingsIterator it = splits_.begin(), end = splits_.end(); it != end; ++it) { base::TimingLogger::SplitTiming split = *it; uint64_t split_time = split.first; if (!precise_ && divisor >= 1000) { // Make the fractional part 0. split_time -= split_time % (divisor / 1000); } os << name_ << ": " << std::setw(8) << FormatDuration(split_time, tu) << " " << split.second << "\n"; } os << name_ << ": end, " << NsToMs(total_ns) << " ms\n"; } TimingLogger::ScopedSplit::ScopedSplit(const char* label, TimingLogger* timing_logger) { DCHECK(label != NULL) << "New scoped split (" << label << ") with null label."; CHECK(timing_logger != NULL) << "New scoped split (" << label << ") without TimingLogger."; timing_logger_ = timing_logger; label_ = label; running_ns_ = 0; explicit_ = false; // Stash away the current split and pause it. enclosing_split_ = timing_logger->current_split_; if (enclosing_split_ != NULL) { enclosing_split_->Pause(); } timing_logger_->current_split_ = this; ATRACE_BEGIN(label_); start_ns_ = NanoTime(); if (timing_logger_->verbose_) { LOG(INFO) << "Begin: " << label_; } } TimingLogger::ScopedSplit::~ScopedSplit() { uint64_t current_time = NanoTime(); uint64_t split_time = current_time - start_ns_; running_ns_ += split_time; ATRACE_END(); if (timing_logger_->verbose_) { LOG(INFO) << "End: " << label_ << " " << PrettyDuration(split_time); } // If one or more enclosed explcitly started splits are not terminated we can // either fail or "unwind" the stack of splits in the timing logger to 'this' // (by deleting the intervening scoped splits). This implements the latter. TimingLogger::ScopedSplit* current = timing_logger_->current_split_; while ((current != NULL) && (current != this)) { delete current; current = timing_logger_->current_split_; } CHECK(current != NULL) << "Missing scoped split (" << this->label_ << ") in timing logger (" << timing_logger_->name_ << ")."; CHECK(timing_logger_->current_split_ == this); timing_logger_->splits_.push_back(SplitTiming(running_ns_, label_)); timing_logger_->current_split_ = enclosing_split_; if (enclosing_split_ != NULL) { enclosing_split_->Resume(); } } void TimingLogger::ScopedSplit::TailInsertSplit(const char* label) { // Sleight of hand here: Rather than embedding a new scoped split, we're updating the current // scoped split in place. Basically, it's one way to make explicit and scoped splits compose // well while maintaining the current semantics of NewSplit. An alternative is to push a new split // since we unwind the stack of scoped splits in the scoped split destructor. However, this implies // that the current split is not ended by NewSplit (which calls TailInsertSplit), which would // be different from what we had before. uint64_t current_time = NanoTime(); uint64_t split_time = current_time - start_ns_; ATRACE_END(); timing_logger_->splits_.push_back(std::pair(split_time, label_)); if (timing_logger_->verbose_) { LOG(INFO) << "End: " << label_ << " " << PrettyDuration(split_time) << "\n" << "Begin: " << label; } label_ = label; start_ns_ = current_time; running_ns_ = 0; ATRACE_BEGIN(label); } void TimingLogger::ScopedSplit::Pause() { uint64_t current_time = NanoTime(); uint64_t split_time = current_time - start_ns_; running_ns_ += split_time; ATRACE_END(); } void TimingLogger::ScopedSplit::Resume() { uint64_t current_time = NanoTime(); start_ns_ = current_time; ATRACE_BEGIN(label_); } } // namespace base } // namespace art