// Copyright (c) 2012 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 "content/browser/byte_stream.h" #include <deque> #include <set> #include <utility> #include "base/bind.h" #include "base/location.h" #include "base/memory/ref_counted.h" #include "base/sequenced_task_runner.h" namespace content { namespace { typedef std::deque<std::pair<scoped_refptr<net::IOBuffer>, size_t> > ContentVector; class ByteStreamReaderImpl; // A poor man's weak pointer; a RefCountedThreadSafe boolean that can be // cleared in an object destructor and accessed to check for object // existence. We can't use weak pointers because they're tightly tied to // threads rather than task runners. // TODO(rdsmith): A better solution would be extending weak pointers // to support SequencedTaskRunners. struct LifetimeFlag : public base::RefCountedThreadSafe<LifetimeFlag> { public: LifetimeFlag() : is_alive(true) { } bool is_alive; protected: friend class base::RefCountedThreadSafe<LifetimeFlag>; virtual ~LifetimeFlag() { } private: DISALLOW_COPY_AND_ASSIGN(LifetimeFlag); }; // For both ByteStreamWriterImpl and ByteStreamReaderImpl, Construction and // SetPeer may happen anywhere; all other operations on each class must // happen in the context of their SequencedTaskRunner. class ByteStreamWriterImpl : public ByteStreamWriter { public: ByteStreamWriterImpl(scoped_refptr<base::SequencedTaskRunner> task_runner, scoped_refptr<LifetimeFlag> lifetime_flag, size_t buffer_size); virtual ~ByteStreamWriterImpl(); // Must be called before any operations are performed. void SetPeer(ByteStreamReaderImpl* peer, scoped_refptr<base::SequencedTaskRunner> peer_task_runner, scoped_refptr<LifetimeFlag> peer_lifetime_flag); // Overridden from ByteStreamWriter. virtual bool Write(scoped_refptr<net::IOBuffer> buffer, size_t byte_count) OVERRIDE; virtual void Flush() OVERRIDE; virtual void Close(int status) OVERRIDE; virtual void RegisterCallback(const base::Closure& source_callback) OVERRIDE; virtual size_t GetTotalBufferedBytes() const OVERRIDE; // PostTask target from |ByteStreamReaderImpl::MaybeUpdateInput|. static void UpdateWindow(scoped_refptr<LifetimeFlag> lifetime_flag, ByteStreamWriterImpl* target, size_t bytes_consumed); private: // Called from UpdateWindow when object existence has been validated. void UpdateWindowInternal(size_t bytes_consumed); void PostToPeer(bool complete, int status); const size_t total_buffer_size_; // All data objects in this class are only valid to access on // this task runner except as otherwise noted. scoped_refptr<base::SequencedTaskRunner> my_task_runner_; // True while this object is alive. scoped_refptr<LifetimeFlag> my_lifetime_flag_; base::Closure space_available_callback_; ContentVector input_contents_; size_t input_contents_size_; // ** Peer information. scoped_refptr<base::SequencedTaskRunner> peer_task_runner_; // How much we've sent to the output that for flow control purposes we // must assume hasn't been read yet. size_t output_size_used_; // Only valid to access on peer_task_runner_. scoped_refptr<LifetimeFlag> peer_lifetime_flag_; // Only valid to access on peer_task_runner_ if // |*peer_lifetime_flag_ == true| ByteStreamReaderImpl* peer_; }; class ByteStreamReaderImpl : public ByteStreamReader { public: ByteStreamReaderImpl(scoped_refptr<base::SequencedTaskRunner> task_runner, scoped_refptr<LifetimeFlag> lifetime_flag, size_t buffer_size); virtual ~ByteStreamReaderImpl(); // Must be called before any operations are performed. void SetPeer(ByteStreamWriterImpl* peer, scoped_refptr<base::SequencedTaskRunner> peer_task_runner, scoped_refptr<LifetimeFlag> peer_lifetime_flag); // Overridden from ByteStreamReader. virtual StreamState Read(scoped_refptr<net::IOBuffer>* data, size_t* length) OVERRIDE; virtual int GetStatus() const OVERRIDE; virtual void RegisterCallback(const base::Closure& sink_callback) OVERRIDE; // PostTask target from |ByteStreamWriterImpl::Write| and // |ByteStreamWriterImpl::Close|. // Receive data from our peer. // static because it may be called after the object it is targeting // has been destroyed. It may not access |*target| // if |*object_lifetime_flag| is false. static void TransferData( scoped_refptr<LifetimeFlag> object_lifetime_flag, ByteStreamReaderImpl* target, scoped_ptr<ContentVector> transfer_buffer, size_t transfer_buffer_bytes, bool source_complete, int status); private: // Called from TransferData once object existence has been validated. void TransferDataInternal( scoped_ptr<ContentVector> transfer_buffer, size_t transfer_buffer_bytes, bool source_complete, int status); void MaybeUpdateInput(); const size_t total_buffer_size_; scoped_refptr<base::SequencedTaskRunner> my_task_runner_; // True while this object is alive. scoped_refptr<LifetimeFlag> my_lifetime_flag_; ContentVector available_contents_; bool received_status_; int status_; base::Closure data_available_callback_; // Time of last point at which data in stream transitioned from full // to non-full. Nulled when a callback is sent. base::Time last_non_full_time_; // ** Peer information scoped_refptr<base::SequencedTaskRunner> peer_task_runner_; // How much has been removed from this class that we haven't told // the input about yet. size_t unreported_consumed_bytes_; // Only valid to access on peer_task_runner_. scoped_refptr<LifetimeFlag> peer_lifetime_flag_; // Only valid to access on peer_task_runner_ if // |*peer_lifetime_flag_ == true| ByteStreamWriterImpl* peer_; }; ByteStreamWriterImpl::ByteStreamWriterImpl( scoped_refptr<base::SequencedTaskRunner> task_runner, scoped_refptr<LifetimeFlag> lifetime_flag, size_t buffer_size) : total_buffer_size_(buffer_size), my_task_runner_(task_runner), my_lifetime_flag_(lifetime_flag), input_contents_size_(0), output_size_used_(0), peer_(NULL) { DCHECK(my_lifetime_flag_.get()); my_lifetime_flag_->is_alive = true; } ByteStreamWriterImpl::~ByteStreamWriterImpl() { my_lifetime_flag_->is_alive = false; } void ByteStreamWriterImpl::SetPeer( ByteStreamReaderImpl* peer, scoped_refptr<base::SequencedTaskRunner> peer_task_runner, scoped_refptr<LifetimeFlag> peer_lifetime_flag) { peer_ = peer; peer_task_runner_ = peer_task_runner; peer_lifetime_flag_ = peer_lifetime_flag; } bool ByteStreamWriterImpl::Write( scoped_refptr<net::IOBuffer> buffer, size_t byte_count) { DCHECK(my_task_runner_->RunsTasksOnCurrentThread()); // Check overflow. // // TODO(tyoshino): Discuss with content/browser/download developer and if // they're fine with, set smaller limit and make it configurable. size_t space_limit = std::numeric_limits<size_t>::max() - GetTotalBufferedBytes(); if (byte_count > space_limit) { // TODO(tyoshino): Tell the user that Write() failed. // Ignore input. return false; } input_contents_.push_back(std::make_pair(buffer, byte_count)); input_contents_size_ += byte_count; // Arbitrarily, we buffer to a third of the total size before sending. if (input_contents_size_ > total_buffer_size_ / kFractionBufferBeforeSending) PostToPeer(false, 0); return GetTotalBufferedBytes() <= total_buffer_size_; } void ByteStreamWriterImpl::Flush() { DCHECK(my_task_runner_->RunsTasksOnCurrentThread()); if (input_contents_size_ > 0) PostToPeer(false, 0); } void ByteStreamWriterImpl::Close(int status) { DCHECK(my_task_runner_->RunsTasksOnCurrentThread()); PostToPeer(true, status); } void ByteStreamWriterImpl::RegisterCallback( const base::Closure& source_callback) { DCHECK(my_task_runner_->RunsTasksOnCurrentThread()); space_available_callback_ = source_callback; } size_t ByteStreamWriterImpl::GetTotalBufferedBytes() const { DCHECK(my_task_runner_->RunsTasksOnCurrentThread()); // This sum doesn't overflow since Write() fails if this sum is going to // overflow. return input_contents_size_ + output_size_used_; } // static void ByteStreamWriterImpl::UpdateWindow( scoped_refptr<LifetimeFlag> lifetime_flag, ByteStreamWriterImpl* target, size_t bytes_consumed) { // If the target object isn't alive anymore, we do nothing. if (!lifetime_flag->is_alive) return; target->UpdateWindowInternal(bytes_consumed); } void ByteStreamWriterImpl::UpdateWindowInternal(size_t bytes_consumed) { DCHECK(my_task_runner_->RunsTasksOnCurrentThread()); bool was_above_limit = GetTotalBufferedBytes() > total_buffer_size_; DCHECK_GE(output_size_used_, bytes_consumed); output_size_used_ -= bytes_consumed; // Callback if we were above the limit and we're now <= to it. bool no_longer_above_limit = GetTotalBufferedBytes() <= total_buffer_size_; if (no_longer_above_limit && was_above_limit && !space_available_callback_.is_null()) space_available_callback_.Run(); } void ByteStreamWriterImpl::PostToPeer(bool complete, int status) { DCHECK(my_task_runner_->RunsTasksOnCurrentThread()); // Valid contexts in which to call. DCHECK(complete || 0 != input_contents_size_); scoped_ptr<ContentVector> transfer_buffer; size_t buffer_size = 0; if (0 != input_contents_size_) { transfer_buffer.reset(new ContentVector); transfer_buffer->swap(input_contents_); buffer_size = input_contents_size_; output_size_used_ += input_contents_size_; input_contents_size_ = 0; } peer_task_runner_->PostTask( FROM_HERE, base::Bind( &ByteStreamReaderImpl::TransferData, peer_lifetime_flag_, peer_, base::Passed(&transfer_buffer), buffer_size, complete, status)); } ByteStreamReaderImpl::ByteStreamReaderImpl( scoped_refptr<base::SequencedTaskRunner> task_runner, scoped_refptr<LifetimeFlag> lifetime_flag, size_t buffer_size) : total_buffer_size_(buffer_size), my_task_runner_(task_runner), my_lifetime_flag_(lifetime_flag), received_status_(false), status_(0), unreported_consumed_bytes_(0), peer_(NULL) { DCHECK(my_lifetime_flag_.get()); my_lifetime_flag_->is_alive = true; } ByteStreamReaderImpl::~ByteStreamReaderImpl() { my_lifetime_flag_->is_alive = false; } void ByteStreamReaderImpl::SetPeer( ByteStreamWriterImpl* peer, scoped_refptr<base::SequencedTaskRunner> peer_task_runner, scoped_refptr<LifetimeFlag> peer_lifetime_flag) { peer_ = peer; peer_task_runner_ = peer_task_runner; peer_lifetime_flag_ = peer_lifetime_flag; } ByteStreamReaderImpl::StreamState ByteStreamReaderImpl::Read(scoped_refptr<net::IOBuffer>* data, size_t* length) { DCHECK(my_task_runner_->RunsTasksOnCurrentThread()); if (available_contents_.size()) { *data = available_contents_.front().first; *length = available_contents_.front().second; available_contents_.pop_front(); unreported_consumed_bytes_ += *length; MaybeUpdateInput(); return STREAM_HAS_DATA; } if (received_status_) { return STREAM_COMPLETE; } return STREAM_EMPTY; } int ByteStreamReaderImpl::GetStatus() const { DCHECK(my_task_runner_->RunsTasksOnCurrentThread()); DCHECK(received_status_); return status_; } void ByteStreamReaderImpl::RegisterCallback( const base::Closure& sink_callback) { DCHECK(my_task_runner_->RunsTasksOnCurrentThread()); data_available_callback_ = sink_callback; } // static void ByteStreamReaderImpl::TransferData( scoped_refptr<LifetimeFlag> object_lifetime_flag, ByteStreamReaderImpl* target, scoped_ptr<ContentVector> transfer_buffer, size_t buffer_size, bool source_complete, int status) { // If our target is no longer alive, do nothing. if (!object_lifetime_flag->is_alive) return; target->TransferDataInternal( transfer_buffer.Pass(), buffer_size, source_complete, status); } void ByteStreamReaderImpl::TransferDataInternal( scoped_ptr<ContentVector> transfer_buffer, size_t buffer_size, bool source_complete, int status) { DCHECK(my_task_runner_->RunsTasksOnCurrentThread()); bool was_empty = available_contents_.empty(); if (transfer_buffer) { available_contents_.insert(available_contents_.end(), transfer_buffer->begin(), transfer_buffer->end()); } if (source_complete) { received_status_ = true; status_ = status; } // Callback on transition from empty to non-empty, or // source complete. if (((was_empty && !available_contents_.empty()) || source_complete) && !data_available_callback_.is_null()) data_available_callback_.Run(); } // Decide whether or not to send the input a window update. // Currently we do that whenever we've got unreported consumption // greater than 1/3 of total size. void ByteStreamReaderImpl::MaybeUpdateInput() { DCHECK(my_task_runner_->RunsTasksOnCurrentThread()); if (unreported_consumed_bytes_ <= total_buffer_size_ / kFractionReadBeforeWindowUpdate) return; peer_task_runner_->PostTask( FROM_HERE, base::Bind( &ByteStreamWriterImpl::UpdateWindow, peer_lifetime_flag_, peer_, unreported_consumed_bytes_)); unreported_consumed_bytes_ = 0; } } // namespace const int ByteStreamWriter::kFractionBufferBeforeSending = 3; const int ByteStreamReader::kFractionReadBeforeWindowUpdate = 3; ByteStreamReader::~ByteStreamReader() { } ByteStreamWriter::~ByteStreamWriter() { } void CreateByteStream( scoped_refptr<base::SequencedTaskRunner> input_task_runner, scoped_refptr<base::SequencedTaskRunner> output_task_runner, size_t buffer_size, scoped_ptr<ByteStreamWriter>* input, scoped_ptr<ByteStreamReader>* output) { scoped_refptr<LifetimeFlag> input_flag(new LifetimeFlag()); scoped_refptr<LifetimeFlag> output_flag(new LifetimeFlag()); ByteStreamWriterImpl* in = new ByteStreamWriterImpl( input_task_runner, input_flag, buffer_size); ByteStreamReaderImpl* out = new ByteStreamReaderImpl( output_task_runner, output_flag, buffer_size); in->SetPeer(out, output_task_runner, output_flag); out->SetPeer(in, input_task_runner, input_flag); input->reset(in); output->reset(out); } } // namespace content