src/base/trace_event/trace_buffer.cc - cobalt - Git at Google

 // 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 <memory>
 #include <utility>
 #include <vector>

 #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<TraceBufferChunk> 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] = nullptr;  // Put nullptr 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<TraceBufferChunk>(chunk);
   }

   void ReturnChunk(size_t index,
                    std::unique_ptr<TraceBufferChunk> 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 nullptr;
     TraceBufferChunk* chunk = chunks_[handle.chunk_index].get();
     if (!chunk || chunk->seq() != handle.chunk_seq)
       return nullptr;
     return chunk->GetEventAt(handle.event_index);
   }

   const TraceBufferChunk* NextChunk() override {
     if (chunks_.empty())
       return nullptr;

     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 nullptr;
   }

 #if !defined(STARBOARD)
   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);
     }
   }
 #endif

  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<std::unique_ptr<TraceBufferChunk>> chunks_;

   std::unique_ptr<size_t[]> 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<TraceBufferChunk> 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<TraceBufferChunk>(
         new TraceBufferChunk(static_cast<uint32_t>(*index) + 1));
   }

   void ReturnChunk(size_t index,
                    std::unique_ptr<TraceBufferChunk> 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 nullptr;
     TraceBufferChunk* chunk = chunks_[handle.chunk_index].get();
     if (!chunk || chunk->seq() != handle.chunk_seq)
       return nullptr;
     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 nullptr;
   }

 #if !defined(STARBOARD)
   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);
     }
   }
 #endif

  private:
   size_t in_flight_chunk_count_;
   size_t current_iteration_index_;
   size_t max_chunks_;
   std::vector<std::unique_ptr<TraceBufferChunk>> chunks_;

   DISALLOW_COPY_AND_ASSIGN(TraceBufferVector);
 };

 }  // namespace

 TraceBufferChunk::TraceBufferChunk(uint32_t seq) : next_free_(0), seq_(seq) {}

 TraceBufferChunk::~TraceBufferChunk() = default;

 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;
 #if !defined(STARBOARD)
   cached_overhead_estimate_.reset();
 #endif
 }

 TraceEvent* TraceBufferChunk::AddTraceEvent(size_t* event_index) {
   DCHECK(!IsFull());
   *event_index = next_free_++;
   return &chunk_[*event_index];
 }

 #if !defined(STARBOARD)
 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_);
 }
 #endif

 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() = default;

 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
	// 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 <memory>
	#include <utility>
	#include <vector>

	#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<TraceBufferChunk> 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] = nullptr; // Put nullptr 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<TraceBufferChunk>(chunk);
	}

	void ReturnChunk(size_t index,
	std::unique_ptr<TraceBufferChunk> 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 nullptr;
	TraceBufferChunk* chunk = chunks_[handle.chunk_index].get();
	if (!chunk \|\| chunk->seq() != handle.chunk_seq)
	return nullptr;
	return chunk->GetEventAt(handle.event_index);
	}

	const TraceBufferChunk* NextChunk() override {
	if (chunks_.empty())
	return nullptr;

	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 nullptr;
	}

	#if !defined(STARBOARD)
	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);
	}
	}
	#endif

	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<std::unique_ptr<TraceBufferChunk>> chunks_;

	std::unique_ptr<size_t[]> 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<TraceBufferChunk> 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<TraceBufferChunk>(
	new TraceBufferChunk(static_cast<uint32_t>(*index) + 1));
	}

	void ReturnChunk(size_t index,
	std::unique_ptr<TraceBufferChunk> 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 nullptr;
	TraceBufferChunk* chunk = chunks_[handle.chunk_index].get();
	if (!chunk \|\| chunk->seq() != handle.chunk_seq)
	return nullptr;
	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 nullptr;
	}

	#if !defined(STARBOARD)
	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);
	}
	}
	#endif

	private:
	size_t in_flight_chunk_count_;
	size_t current_iteration_index_;
	size_t max_chunks_;
	std::vector<std::unique_ptr<TraceBufferChunk>> chunks_;

	DISALLOW_COPY_AND_ASSIGN(TraceBufferVector);
	};

	} // namespace

	TraceBufferChunk::TraceBufferChunk(uint32_t seq) : next_free_(0), seq_(seq) {}

	TraceBufferChunk::~TraceBufferChunk() = default;

	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;
	#if !defined(STARBOARD)
	cached_overhead_estimate_.reset();
	#endif
	}

	TraceEvent* TraceBufferChunk::AddTraceEvent(size_t* event_index) {
	DCHECK(!IsFull());
	*event_index = next_free_++;
	return &chunk_[*event_index];
	}

	#if !defined(STARBOARD)
	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_);
	}
	#endif

	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() = default;

	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