// Copyright 2015 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "base/trace_event/trace_buffer.h" #include #include #include #include "base/macros.h" #include "base/trace_event/heap_profiler.h" #include "base/trace_event/trace_event_impl.h" namespace base { namespace trace_event { namespace { class TraceBufferRingBuffer : public TraceBuffer { public: TraceBufferRingBuffer(size_t max_chunks) : max_chunks_(max_chunks), recyclable_chunks_queue_(new size_t[queue_capacity()]), queue_head_(0), queue_tail_(max_chunks), current_iteration_index_(0), current_chunk_seq_(1) { chunks_.reserve(max_chunks); for (size_t i = 0; i < max_chunks; ++i) recyclable_chunks_queue_[i] = i; } std::unique_ptr GetChunk(size_t* index) override { HEAP_PROFILER_SCOPED_IGNORE; // Because the number of threads is much less than the number of chunks, // the queue should never be empty. DCHECK(!QueueIsEmpty()); *index = recyclable_chunks_queue_[queue_head_]; queue_head_ = NextQueueIndex(queue_head_); current_iteration_index_ = queue_head_; if (*index >= chunks_.size()) chunks_.resize(*index + 1); TraceBufferChunk* chunk = chunks_[*index].release(); chunks_[*index] = NULL; // Put NULL in the slot of a in-flight chunk. if (chunk) chunk->Reset(current_chunk_seq_++); else chunk = new TraceBufferChunk(current_chunk_seq_++); return std::unique_ptr(chunk); } void ReturnChunk(size_t index, std::unique_ptr chunk) override { // When this method is called, the queue should not be full because it // can contain all chunks including the one to be returned. DCHECK(!QueueIsFull()); DCHECK(chunk); DCHECK_LT(index, chunks_.size()); DCHECK(!chunks_[index]); chunks_[index] = std::move(chunk); recyclable_chunks_queue_[queue_tail_] = index; queue_tail_ = NextQueueIndex(queue_tail_); } bool IsFull() const override { return false; } size_t Size() const override { // This is approximate because not all of the chunks are full. return chunks_.size() * TraceBufferChunk::kTraceBufferChunkSize; } size_t Capacity() const override { return max_chunks_ * TraceBufferChunk::kTraceBufferChunkSize; } TraceEvent* GetEventByHandle(TraceEventHandle handle) override { if (handle.chunk_index >= chunks_.size()) return NULL; TraceBufferChunk* chunk = chunks_[handle.chunk_index].get(); if (!chunk || chunk->seq() != handle.chunk_seq) return NULL; return chunk->GetEventAt(handle.event_index); } const TraceBufferChunk* NextChunk() override { if (chunks_.empty()) return NULL; while (current_iteration_index_ != queue_tail_) { size_t chunk_index = recyclable_chunks_queue_[current_iteration_index_]; current_iteration_index_ = NextQueueIndex(current_iteration_index_); if (chunk_index >= chunks_.size()) // Skip uninitialized chunks. continue; DCHECK(chunks_[chunk_index]); return chunks_[chunk_index].get(); } return NULL; } void EstimateTraceMemoryOverhead( TraceEventMemoryOverhead* overhead) override { overhead->Add(TraceEventMemoryOverhead::kTraceBuffer, sizeof(*this)); for (size_t queue_index = queue_head_; queue_index != queue_tail_; queue_index = NextQueueIndex(queue_index)) { size_t chunk_index = recyclable_chunks_queue_[queue_index]; if (chunk_index >= chunks_.size()) // Skip uninitialized chunks. continue; chunks_[chunk_index]->EstimateTraceMemoryOverhead(overhead); } } private: bool QueueIsEmpty() const { return queue_head_ == queue_tail_; } size_t QueueSize() const { return queue_tail_ > queue_head_ ? queue_tail_ - queue_head_ : queue_tail_ + queue_capacity() - queue_head_; } bool QueueIsFull() const { return QueueSize() == queue_capacity() - 1; } size_t queue_capacity() const { // One extra space to help distinguish full state and empty state. return max_chunks_ + 1; } size_t NextQueueIndex(size_t index) const { index++; if (index >= queue_capacity()) index = 0; return index; } size_t max_chunks_; std::vector> chunks_; std::unique_ptr recyclable_chunks_queue_; size_t queue_head_; size_t queue_tail_; size_t current_iteration_index_; uint32_t current_chunk_seq_; DISALLOW_COPY_AND_ASSIGN(TraceBufferRingBuffer); }; class TraceBufferVector : public TraceBuffer { public: TraceBufferVector(size_t max_chunks) : in_flight_chunk_count_(0), current_iteration_index_(0), max_chunks_(max_chunks) { chunks_.reserve(max_chunks_); } std::unique_ptr GetChunk(size_t* index) override { HEAP_PROFILER_SCOPED_IGNORE; // This function may be called when adding normal events or indirectly from // AddMetadataEventsWhileLocked(). We can not DECHECK(!IsFull()) because we // have to add the metadata events and flush thread-local buffers even if // the buffer is full. *index = chunks_.size(); // Put nullptr in the slot of a in-flight chunk. chunks_.push_back(nullptr); ++in_flight_chunk_count_; // + 1 because zero chunk_seq is not allowed. return std::unique_ptr( new TraceBufferChunk(static_cast(*index) + 1)); } void ReturnChunk(size_t index, std::unique_ptr chunk) override { DCHECK_GT(in_flight_chunk_count_, 0u); DCHECK_LT(index, chunks_.size()); DCHECK(!chunks_[index]); --in_flight_chunk_count_; chunks_[index] = std::move(chunk); } bool IsFull() const override { return chunks_.size() >= max_chunks_; } size_t Size() const override { // This is approximate because not all of the chunks are full. return chunks_.size() * TraceBufferChunk::kTraceBufferChunkSize; } size_t Capacity() const override { return max_chunks_ * TraceBufferChunk::kTraceBufferChunkSize; } TraceEvent* GetEventByHandle(TraceEventHandle handle) override { if (handle.chunk_index >= chunks_.size()) return NULL; TraceBufferChunk* chunk = chunks_[handle.chunk_index].get(); if (!chunk || chunk->seq() != handle.chunk_seq) return NULL; return chunk->GetEventAt(handle.event_index); } const TraceBufferChunk* NextChunk() override { while (current_iteration_index_ < chunks_.size()) { // Skip in-flight chunks. const TraceBufferChunk* chunk = chunks_[current_iteration_index_++].get(); if (chunk) return chunk; } return NULL; } void EstimateTraceMemoryOverhead( TraceEventMemoryOverhead* overhead) override { const size_t chunks_ptr_vector_allocated_size = sizeof(*this) + max_chunks_ * sizeof(decltype(chunks_)::value_type); const size_t chunks_ptr_vector_resident_size = sizeof(*this) + chunks_.size() * sizeof(decltype(chunks_)::value_type); overhead->Add(TraceEventMemoryOverhead::kTraceBuffer, chunks_ptr_vector_allocated_size, chunks_ptr_vector_resident_size); for (size_t i = 0; i < chunks_.size(); ++i) { TraceBufferChunk* chunk = chunks_[i].get(); // Skip the in-flight (nullptr) chunks. They will be accounted by the // per-thread-local dumpers, see ThreadLocalEventBuffer::OnMemoryDump. if (chunk) chunk->EstimateTraceMemoryOverhead(overhead); } } private: size_t in_flight_chunk_count_; size_t current_iteration_index_; size_t max_chunks_; std::vector> chunks_; DISALLOW_COPY_AND_ASSIGN(TraceBufferVector); }; } // namespace TraceBufferChunk::TraceBufferChunk(uint32_t seq) : next_free_(0), seq_(seq) {} TraceBufferChunk::~TraceBufferChunk() {} void TraceBufferChunk::Reset(uint32_t new_seq) { for (size_t i = 0; i < next_free_; ++i) chunk_[i].Reset(); next_free_ = 0; seq_ = new_seq; cached_overhead_estimate_.reset(); } TraceEvent* TraceBufferChunk::AddTraceEvent(size_t* event_index) { DCHECK(!IsFull()); *event_index = next_free_++; return &chunk_[*event_index]; } void TraceBufferChunk::EstimateTraceMemoryOverhead( TraceEventMemoryOverhead* overhead) { if (!cached_overhead_estimate_) { cached_overhead_estimate_.reset(new TraceEventMemoryOverhead); // When estimating the size of TraceBufferChunk, exclude the array of trace // events, as they are computed individually below. cached_overhead_estimate_->Add(TraceEventMemoryOverhead::kTraceBufferChunk, sizeof(*this) - sizeof(chunk_)); } const size_t num_cached_estimated_events = cached_overhead_estimate_->GetCount( TraceEventMemoryOverhead::kTraceEvent); DCHECK_LE(num_cached_estimated_events, size()); if (IsFull() && num_cached_estimated_events == size()) { overhead->Update(*cached_overhead_estimate_); return; } for (size_t i = num_cached_estimated_events; i < size(); ++i) chunk_[i].EstimateTraceMemoryOverhead(cached_overhead_estimate_.get()); if (IsFull()) { cached_overhead_estimate_->AddSelf(); } else { // The unused TraceEvents in |chunks_| are not cached. They will keep // changing as new TraceEvents are added to this chunk, so they are // computed on the fly. const size_t num_unused_trace_events = capacity() - size(); overhead->Add(TraceEventMemoryOverhead::kUnusedTraceEvent, num_unused_trace_events * sizeof(TraceEvent)); } overhead->Update(*cached_overhead_estimate_); } TraceResultBuffer::OutputCallback TraceResultBuffer::SimpleOutput::GetCallback() { return Bind(&SimpleOutput::Append, Unretained(this)); } void TraceResultBuffer::SimpleOutput::Append( const std::string& json_trace_output) { json_output += json_trace_output; } TraceResultBuffer::TraceResultBuffer() : append_comma_(false) {} TraceResultBuffer::~TraceResultBuffer() {} void TraceResultBuffer::SetOutputCallback( const OutputCallback& json_chunk_callback) { output_callback_ = json_chunk_callback; } void TraceResultBuffer::Start() { append_comma_ = false; output_callback_.Run("["); } void TraceResultBuffer::AddFragment(const std::string& trace_fragment) { if (append_comma_) output_callback_.Run(","); append_comma_ = true; output_callback_.Run(trace_fragment); } void TraceResultBuffer::Finish() { output_callback_.Run("]"); } TraceBuffer* TraceBuffer::CreateTraceBufferRingBuffer(size_t max_chunks) { return new TraceBufferRingBuffer(max_chunks); } TraceBuffer* TraceBuffer::CreateTraceBufferVectorOfSize(size_t max_chunks) { return new TraceBufferVector(max_chunks); } } // namespace trace_event } // namespace base