// 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 "net/spdy/spdy_stream.h" #include #include #include #include "base/bind.h" #include "base/compiler_specific.h" #include "base/location.h" #include "base/logging.h" #include "base/metrics/histogram_functions.h" #include "base/metrics/histogram_macros.h" #include "base/single_thread_task_runner.h" #include "base/strings/string_number_conversions.h" #include "base/strings/stringprintf.h" #include "base/threading/thread_task_runner_handle.h" #include "base/trace_event/memory_usage_estimator.h" #include "base/values.h" #include "net/log/net_log.h" #include "net/log/net_log_capture_mode.h" #include "net/log/net_log_event_type.h" #include "net/spdy/spdy_buffer_producer.h" #include "net/spdy/spdy_http_utils.h" #include "net/spdy/spdy_session.h" namespace net { namespace { std::unique_ptr NetLogSpdyStreamErrorCallback( spdy::SpdyStreamId stream_id, int net_error, const std::string* description, NetLogCaptureMode /* capture_mode */) { auto dict = std::make_unique(); dict->SetInteger("stream_id", static_cast(stream_id)); dict->SetString("net_error", ErrorToShortString(net_error)); dict->SetString("description", *description); return std::move(dict); } std::unique_ptr NetLogSpdyStreamWindowUpdateCallback( spdy::SpdyStreamId stream_id, int32_t delta, int32_t window_size, NetLogCaptureMode /* capture_mode */) { auto dict = std::make_unique(); dict->SetInteger("stream_id", stream_id); dict->SetInteger("delta", delta); dict->SetInteger("window_size", window_size); return std::move(dict); } } // namespace // A wrapper around a stream that calls into ProduceHeadersFrame(). class SpdyStream::HeadersBufferProducer : public SpdyBufferProducer { public: explicit HeadersBufferProducer(const base::WeakPtr& stream) : stream_(stream) { DCHECK(stream_.get()); } ~HeadersBufferProducer() override = default; std::unique_ptr ProduceBuffer() override { if (!stream_.get()) { NOTREACHED(); return std::unique_ptr(); } DCHECK_GT(stream_->stream_id(), 0u); return std::make_unique(stream_->ProduceHeadersFrame()); } size_t EstimateMemoryUsage() const override { return 0; } private: const base::WeakPtr stream_; }; SpdyStream::SpdyStream(SpdyStreamType type, const base::WeakPtr& session, const GURL& url, RequestPriority priority, int32_t initial_send_window_size, int32_t max_recv_window_size, const NetLogWithSource& net_log, const NetworkTrafficAnnotationTag& traffic_annotation) : type_(type), stream_id_(0), url_(url), priority_(priority), send_stalled_by_flow_control_(false), send_window_size_(initial_send_window_size), max_recv_window_size_(max_recv_window_size), recv_window_size_(max_recv_window_size), unacked_recv_window_bytes_(0), session_(session), delegate_(NULL), request_headers_valid_(false), pending_send_status_(MORE_DATA_TO_SEND), request_time_(base::Time::Now()), response_state_(READY_FOR_HEADERS), io_state_(STATE_IDLE), response_status_(OK), net_log_(net_log), raw_received_bytes_(0), raw_sent_bytes_(0), send_bytes_(0), recv_bytes_(0), write_handler_guard_(false), traffic_annotation_(traffic_annotation), weak_ptr_factory_(this) { CHECK(type_ == SPDY_BIDIRECTIONAL_STREAM || type_ == SPDY_REQUEST_RESPONSE_STREAM || type_ == SPDY_PUSH_STREAM); CHECK_GE(priority_, MINIMUM_PRIORITY); CHECK_LE(priority_, MAXIMUM_PRIORITY); } SpdyStream::~SpdyStream() { CHECK(!write_handler_guard_); UpdateHistograms(); } void SpdyStream::SetDelegate(Delegate* delegate) { CHECK(!delegate_); CHECK(delegate); delegate_ = delegate; CHECK(io_state_ == STATE_IDLE || io_state_ == STATE_HALF_CLOSED_LOCAL_UNCLAIMED || io_state_ == STATE_RESERVED_REMOTE); if (io_state_ == STATE_HALF_CLOSED_LOCAL_UNCLAIMED) { DCHECK_EQ(type_, SPDY_PUSH_STREAM); base::ThreadTaskRunnerHandle::Get()->PostTask( FROM_HERE, base::Bind(&SpdyStream::PushedStreamReplay, GetWeakPtr())); } } void SpdyStream::PushedStreamReplay() { DCHECK_EQ(type_, SPDY_PUSH_STREAM); DCHECK_NE(stream_id_, 0u); CHECK_EQ(stream_id_ % 2, 0u); CHECK_EQ(io_state_, STATE_HALF_CLOSED_LOCAL_UNCLAIMED); io_state_ = STATE_HALF_CLOSED_LOCAL; // The delegate methods called below may delete |this|, so use // |weak_this| to detect that. base::WeakPtr weak_this = GetWeakPtr(); CHECK(delegate_); delegate_->OnHeadersReceived(response_headers_, &request_headers_); // OnHeadersReceived() may have closed |this|. if (!weak_this) return; while (!pending_recv_data_.empty()) { // Take ownership of the first element of |pending_recv_data_|. std::unique_ptr buffer = std::move(pending_recv_data_.at(0)); pending_recv_data_.erase(pending_recv_data_.begin()); bool eof = (buffer == NULL); CHECK(delegate_); delegate_->OnDataReceived(std::move(buffer)); // OnDataReceived() may have closed |this|. if (!weak_this) return; if (eof) { DCHECK(pending_recv_data_.empty()); session_->CloseActiveStream(stream_id_, OK); DCHECK(!weak_this); // |pending_recv_data_| is invalid at this point. break; } } } std::unique_ptr SpdyStream::ProduceHeadersFrame() { CHECK_EQ(io_state_, STATE_IDLE); CHECK(request_headers_valid_); CHECK_GT(stream_id_, 0u); spdy::SpdyControlFlags flags = (pending_send_status_ == NO_MORE_DATA_TO_SEND) ? spdy::CONTROL_FLAG_FIN : spdy::CONTROL_FLAG_NONE; std::unique_ptr frame(session_->CreateHeaders( stream_id_, priority_, flags, std::move(request_headers_), delegate_->source_dependency())); request_headers_valid_ = false; send_time_ = base::TimeTicks::Now(); return frame; } void SpdyStream::DetachDelegate() { DCHECK(!IsClosed()); delegate_ = NULL; Cancel(ERR_ABORTED); } void SpdyStream::SetPriority(RequestPriority priority) { if (priority_ == priority) { return; } session_->UpdateStreamPriority(this, /* old_priority = */ priority_, /* new_priority = */ priority); priority_ = priority; } bool SpdyStream::AdjustSendWindowSize(int32_t delta_window_size) { if (IsClosed()) return true; if (delta_window_size > 0) { if (send_window_size_ > std::numeric_limits::max() - delta_window_size) { return false; } } else { // Minimum allowed value for spdy::SETTINGS_INITIAL_WINDOW_SIZE is 0 and // maximum is 2^31-1. Data are not sent when |send_window_size_ < 0|, that // is, |send_window_size_ | can only decrease by a change in // spdy::SETTINGS_INITIAL_WINDOW_SIZE. Therefore |send_window_size_| should // never be able to become less than -(2^31-1). DCHECK_LE(std::numeric_limits::min() - delta_window_size, send_window_size_); } send_window_size_ += delta_window_size; net_log_.AddEvent( NetLogEventType::HTTP2_STREAM_UPDATE_SEND_WINDOW, base::Bind(&NetLogSpdyStreamWindowUpdateCallback, stream_id_, delta_window_size, send_window_size_)); PossiblyResumeIfSendStalled(); return true; } void SpdyStream::OnWriteBufferConsumed( size_t frame_payload_size, size_t consume_size, SpdyBuffer::ConsumeSource consume_source) { if (consume_source == SpdyBuffer::DISCARD) { // If we're discarding a frame or part of it, increase the send // window by the number of discarded bytes. (Although if we're // discarding part of a frame, it's probably because of a write // error and we'll be tearing down the stream soon.) size_t remaining_payload_bytes = std::min(consume_size, frame_payload_size); DCHECK_GT(remaining_payload_bytes, 0u); IncreaseSendWindowSize(static_cast(remaining_payload_bytes)); } // For consumed bytes, the send window is increased when we receive // a WINDOW_UPDATE frame. } void SpdyStream::IncreaseSendWindowSize(int32_t delta_window_size) { DCHECK_GE(delta_window_size, 1); if (!AdjustSendWindowSize(delta_window_size)) { std::string desc = base::StringPrintf( "Received WINDOW_UPDATE [delta: %d] for stream %d overflows " "send_window_size_ [current: %d]", delta_window_size, stream_id_, send_window_size_); session_->ResetStream(stream_id_, ERR_SPDY_FLOW_CONTROL_ERROR, desc); } } void SpdyStream::DecreaseSendWindowSize(int32_t delta_window_size) { if (IsClosed()) return; // We only call this method when sending a frame. Therefore, // |delta_window_size| should be within the valid frame size range. DCHECK_GE(delta_window_size, 1); DCHECK_LE(delta_window_size, kMaxSpdyFrameChunkSize); // |send_window_size_| should have been at least |delta_window_size| for // this call to happen. DCHECK_GE(send_window_size_, delta_window_size); send_window_size_ -= delta_window_size; net_log_.AddEvent( NetLogEventType::HTTP2_STREAM_UPDATE_SEND_WINDOW, base::Bind(&NetLogSpdyStreamWindowUpdateCallback, stream_id_, -delta_window_size, send_window_size_)); } void SpdyStream::OnReadBufferConsumed( size_t consume_size, SpdyBuffer::ConsumeSource consume_source) { DCHECK_GE(consume_size, 1u); DCHECK_LE(consume_size, static_cast(std::numeric_limits::max())); IncreaseRecvWindowSize(static_cast(consume_size)); } void SpdyStream::IncreaseRecvWindowSize(int32_t delta_window_size) { // By the time a read is processed by the delegate, this stream may // already be inactive. if (!session_->IsStreamActive(stream_id_)) return; DCHECK_GE(unacked_recv_window_bytes_, 0); DCHECK_GE(recv_window_size_, unacked_recv_window_bytes_); DCHECK_GE(delta_window_size, 1); // Check for overflow. DCHECK_LE(delta_window_size, std::numeric_limits::max() - recv_window_size_); recv_window_size_ += delta_window_size; net_log_.AddEvent( NetLogEventType::HTTP2_STREAM_UPDATE_RECV_WINDOW, base::Bind(&NetLogSpdyStreamWindowUpdateCallback, stream_id_, delta_window_size, recv_window_size_)); unacked_recv_window_bytes_ += delta_window_size; if (unacked_recv_window_bytes_ > max_recv_window_size_ / 2) { session_->SendStreamWindowUpdate( stream_id_, static_cast(unacked_recv_window_bytes_)); unacked_recv_window_bytes_ = 0; } } void SpdyStream::DecreaseRecvWindowSize(int32_t delta_window_size) { DCHECK(session_->IsStreamActive(stream_id_)); DCHECK_GE(delta_window_size, 1); // The receiving window size as the peer knows it is // |recv_window_size_ - unacked_recv_window_bytes_|, if more data are sent by // the peer, that means that the receive window is not being respected. if (delta_window_size > recv_window_size_ - unacked_recv_window_bytes_) { session_->ResetStream( stream_id_, ERR_SPDY_FLOW_CONTROL_ERROR, "delta_window_size is " + base::IntToString(delta_window_size) + " in DecreaseRecvWindowSize, which is larger than the receive " + "window size of " + base::IntToString(recv_window_size_)); return; } recv_window_size_ -= delta_window_size; net_log_.AddEvent( NetLogEventType::HTTP2_STREAM_UPDATE_RECV_WINDOW, base::Bind(&NetLogSpdyStreamWindowUpdateCallback, stream_id_, -delta_window_size, recv_window_size_)); } int SpdyStream::GetPeerAddress(IPEndPoint* address) const { return session_->GetPeerAddress(address); } int SpdyStream::GetLocalAddress(IPEndPoint* address) const { return session_->GetLocalAddress(address); } bool SpdyStream::WasEverUsed() const { return session_->WasEverUsed(); } base::Time SpdyStream::GetRequestTime() const { return request_time_; } void SpdyStream::SetRequestTime(base::Time t) { request_time_ = t; } void SpdyStream::OnHeadersReceived( const spdy::SpdyHeaderBlock& response_headers, base::Time response_time, base::TimeTicks recv_first_byte_time) { switch (response_state_) { case READY_FOR_HEADERS: // No header block has been received yet. DCHECK(response_headers_.empty()); { spdy::SpdyHeaderBlock::const_iterator it = response_headers.find(spdy::kHttp2StatusHeader); if (it == response_headers.end()) { const std::string error("Response headers do not include :status."); LogStreamError(ERR_SPDY_PROTOCOL_ERROR, error); session_->ResetStream(stream_id_, ERR_SPDY_PROTOCOL_ERROR, error); return; } int status; if (!StringToInt(it->second, &status)) { const std::string error("Cannot parse :status."); LogStreamError(ERR_SPDY_PROTOCOL_ERROR, error); session_->ResetStream(stream_id_, ERR_SPDY_PROTOCOL_ERROR, error); return; } base::UmaHistogramSparse("Net.SpdyResponseCode", status); // Ignore informational headers like 103 Early Hints. // TODO(bnc): Add support for 103 Early Hints, https://crbug.com/671310. // However, do not ignore 101 Switching Protocols, because broken // servers might send this as a response to a WebSocket request, // in which case it needs to pass through so that the WebSocket layer // can signal an error. if (status / 100 == 1 && status != 101) { return; } } response_state_ = READY_FOR_DATA_OR_TRAILERS; switch (type_) { case SPDY_BIDIRECTIONAL_STREAM: case SPDY_REQUEST_RESPONSE_STREAM: // A bidirectional stream or a request/response stream is ready for // the response headers only after request headers are sent. if (io_state_ == STATE_IDLE) { const std::string error("Response received before request sent."); LogStreamError(ERR_SPDY_PROTOCOL_ERROR, error); session_->ResetStream(stream_id_, ERR_SPDY_PROTOCOL_ERROR, error); return; } break; case SPDY_PUSH_STREAM: // Push streams transition to a locally half-closed state upon // headers. We must continue to buffer data while waiting for a call // to SetDelegate() (which may not ever happen). DCHECK_EQ(io_state_, STATE_RESERVED_REMOTE); if (!delegate_) { io_state_ = STATE_HALF_CLOSED_LOCAL_UNCLAIMED; } else { io_state_ = STATE_HALF_CLOSED_LOCAL; } break; } DCHECK_NE(io_state_, STATE_IDLE); response_time_ = response_time; recv_first_byte_time_ = recv_first_byte_time; SaveResponseHeaders(response_headers); break; case READY_FOR_DATA_OR_TRAILERS: // Second header block is trailers. if (type_ == SPDY_PUSH_STREAM) { const std::string error("Trailers not supported for push stream."); LogStreamError(ERR_SPDY_PROTOCOL_ERROR, error); session_->ResetStream(stream_id_, ERR_SPDY_PROTOCOL_ERROR, error); return; } response_state_ = TRAILERS_RECEIVED; delegate_->OnTrailers(response_headers); break; case TRAILERS_RECEIVED: // No further header blocks are allowed after trailers. const std::string error("Header block received after trailers."); LogStreamError(ERR_SPDY_PROTOCOL_ERROR, error); session_->ResetStream(stream_id_, ERR_SPDY_PROTOCOL_ERROR, error); break; } } bool SpdyStream::ShouldRetryRSTPushStream() const { // Retry if the stream is a pushed stream, has been claimed, but did not yet // receive response headers return (response_headers_.empty() && type_ == SPDY_PUSH_STREAM && delegate_); } void SpdyStream::OnPushPromiseHeadersReceived(spdy::SpdyHeaderBlock headers, GURL url) { CHECK(!request_headers_valid_); CHECK_EQ(io_state_, STATE_IDLE); CHECK_EQ(type_, SPDY_PUSH_STREAM); DCHECK(!delegate_); io_state_ = STATE_RESERVED_REMOTE; request_headers_ = std::move(headers); request_headers_valid_ = true; } void SpdyStream::OnDataReceived(std::unique_ptr buffer) { DCHECK(session_->IsStreamActive(stream_id_)); if (response_state_ == READY_FOR_HEADERS) { const std::string error("DATA received before headers."); LogStreamError(ERR_SPDY_PROTOCOL_ERROR, error); session_->ResetStream(stream_id_, ERR_SPDY_PROTOCOL_ERROR, error); return; } if (response_state_ == TRAILERS_RECEIVED && buffer) { const std::string error("DATA received after trailers."); LogStreamError(ERR_SPDY_PROTOCOL_ERROR, error); session_->ResetStream(stream_id_, ERR_SPDY_PROTOCOL_ERROR, error); return; } if (io_state_ == STATE_HALF_CLOSED_REMOTE) { const std::string error("DATA received on half-closed (remove) stream."); LogStreamError(ERR_SPDY_STREAM_CLOSED, error); session_->ResetStream(stream_id_, ERR_SPDY_STREAM_CLOSED, error); return; } // Track our bandwidth. recv_bytes_ += buffer ? buffer->GetRemainingSize() : 0; recv_last_byte_time_ = base::TimeTicks::Now(); // If we're still buffering data for a push stream, we will do the check for // data received with incomplete headers in PushedStreamReplay(). if (io_state_ == STATE_HALF_CLOSED_LOCAL_UNCLAIMED) { DCHECK_EQ(type_, SPDY_PUSH_STREAM); // It should be valid for this to happen in the server push case. // We'll return received data when delegate gets attached to the stream. if (buffer) { pending_recv_data_.push_back(std::move(buffer)); } else { pending_recv_data_.push_back(NULL); // Note: we leave the stream open in the session until the stream // is claimed. } return; } CHECK(!IsClosed()); if (!buffer) { if (io_state_ == STATE_OPEN) { io_state_ = STATE_HALF_CLOSED_REMOTE; delegate_->OnDataReceived(nullptr); } else if (io_state_ == STATE_HALF_CLOSED_LOCAL) { io_state_ = STATE_CLOSED; // Deletes |this|. session_->CloseActiveStream(stream_id_, OK); } else { NOTREACHED() << io_state_; } return; } size_t length = buffer->GetRemainingSize(); DCHECK_LE(length, spdy::kHttp2DefaultFramePayloadLimit); base::WeakPtr weak_this = GetWeakPtr(); // May close the stream. DecreaseRecvWindowSize(static_cast(length)); if (!weak_this) return; buffer->AddConsumeCallback( base::Bind(&SpdyStream::OnReadBufferConsumed, GetWeakPtr())); // May close |this|. delegate_->OnDataReceived(std::move(buffer)); } void SpdyStream::OnPaddingConsumed(size_t len) { // Decrease window size because padding bytes are received. // Increase window size because padding bytes are consumed (by discarding). // Net result: |unacked_recv_window_bytes_| increases by |len|, // |recv_window_size_| does not change. base::WeakPtr weak_this = GetWeakPtr(); // May close the stream. DecreaseRecvWindowSize(static_cast(len)); if (!weak_this) return; IncreaseRecvWindowSize(static_cast(len)); } void SpdyStream::OnFrameWriteComplete(spdy::SpdyFrameType frame_type, size_t frame_size) { // PRIORITY writes are allowed at any time and do not trigger a state update. if (frame_type == spdy::SpdyFrameType::PRIORITY) { return; } DCHECK_NE(type_, SPDY_PUSH_STREAM); CHECK(frame_type == spdy::SpdyFrameType::HEADERS || frame_type == spdy::SpdyFrameType::DATA) << frame_type; int result = (frame_type == spdy::SpdyFrameType::HEADERS) ? OnHeadersSent() : OnDataSent(frame_size); if (result == ERR_IO_PENDING) { // The write operation hasn't completed yet. return; } if (pending_send_status_ == NO_MORE_DATA_TO_SEND) { if (io_state_ == STATE_OPEN) { io_state_ = STATE_HALF_CLOSED_LOCAL; } else if (io_state_ == STATE_HALF_CLOSED_REMOTE) { io_state_ = STATE_CLOSED; } else { NOTREACHED() << io_state_; } } // Notify delegate of write completion. Must not destroy |this|. CHECK(delegate_); { base::WeakPtr weak_this = GetWeakPtr(); write_handler_guard_ = true; if (frame_type == spdy::SpdyFrameType::HEADERS) { delegate_->OnHeadersSent(); } else { delegate_->OnDataSent(); } CHECK(weak_this); write_handler_guard_ = false; } if (io_state_ == STATE_CLOSED) { // Deletes |this|. session_->CloseActiveStream(stream_id_, OK); } } int SpdyStream::OnHeadersSent() { CHECK_EQ(io_state_, STATE_IDLE); CHECK_NE(stream_id_, 0u); io_state_ = STATE_OPEN; return OK; } int SpdyStream::OnDataSent(size_t frame_size) { CHECK(io_state_ == STATE_OPEN || io_state_ == STATE_HALF_CLOSED_REMOTE) << io_state_; size_t frame_payload_size = frame_size - spdy::kDataFrameMinimumSize; CHECK_GE(frame_size, spdy::kDataFrameMinimumSize); CHECK_LE(frame_payload_size, spdy::kHttp2DefaultFramePayloadLimit); send_bytes_ += frame_payload_size; // If more data is available to send, dispatch it and // return that the write operation is still ongoing. pending_send_data_->DidConsume(frame_payload_size); if (pending_send_data_->BytesRemaining() > 0) { QueueNextDataFrame(); return ERR_IO_PENDING; } else { pending_send_data_ = NULL; return OK; } } void SpdyStream::LogStreamError(int error, const std::string& description) { net_log_.AddEvent(NetLogEventType::HTTP2_STREAM_ERROR, base::Bind(&NetLogSpdyStreamErrorCallback, stream_id_, error, &description)); } void SpdyStream::OnClose(int status) { // In most cases, the stream should already be CLOSED. The exception is when a // SpdySession is shutting down while the stream is in an intermediate state. io_state_ = STATE_CLOSED; if (status == ERR_SPDY_RST_STREAM_NO_ERROR_RECEIVED) { if (response_state_ == READY_FOR_HEADERS) { status = ERR_SPDY_PROTOCOL_ERROR; } else { status = OK; } } response_status_ = status; Delegate* delegate = delegate_; delegate_ = NULL; if (delegate) delegate->OnClose(status); // Unset |stream_id_| last so that the delegate can look it up. stream_id_ = 0; } void SpdyStream::Cancel(int error) { // We may be called again from a delegate's OnClose(). if (io_state_ == STATE_CLOSED) return; if (stream_id_ != 0) { session_->ResetStream(stream_id_, error, std::string()); } else { session_->CloseCreatedStream(GetWeakPtr(), error); } // |this| is invalid at this point. } void SpdyStream::Close() { // We may be called again from a delegate's OnClose(). if (io_state_ == STATE_CLOSED) return; if (stream_id_ != 0) { session_->CloseActiveStream(stream_id_, OK); } else { session_->CloseCreatedStream(GetWeakPtr(), OK); } // |this| is invalid at this point. } base::WeakPtr SpdyStream::GetWeakPtr() { return weak_ptr_factory_.GetWeakPtr(); } int SpdyStream::SendRequestHeaders(spdy::SpdyHeaderBlock request_headers, SpdySendStatus send_status) { CHECK_NE(type_, SPDY_PUSH_STREAM); CHECK_EQ(pending_send_status_, MORE_DATA_TO_SEND); CHECK(!request_headers_valid_); CHECK(!pending_send_data_.get()); CHECK_EQ(io_state_, STATE_IDLE); request_headers_ = std::move(request_headers); request_headers_valid_ = true; pending_send_status_ = send_status; session_->EnqueueStreamWrite( GetWeakPtr(), spdy::SpdyFrameType::HEADERS, std::make_unique(GetWeakPtr())); return ERR_IO_PENDING; } void SpdyStream::SendData(IOBuffer* data, int length, SpdySendStatus send_status) { CHECK_NE(type_, SPDY_PUSH_STREAM); CHECK_EQ(pending_send_status_, MORE_DATA_TO_SEND); CHECK(io_state_ == STATE_OPEN || io_state_ == STATE_HALF_CLOSED_REMOTE) << io_state_; CHECK(!pending_send_data_.get()); pending_send_data_ = new DrainableIOBuffer(data, length); pending_send_status_ = send_status; QueueNextDataFrame(); } bool SpdyStream::GetSSLInfo(SSLInfo* ssl_info) const { return session_->GetSSLInfo(ssl_info); } Error SpdyStream::GetTokenBindingSignature(crypto::ECPrivateKey* key, TokenBindingType tb_type, std::vector* out) const { return session_->GetTokenBindingSignature(key, tb_type, out); } bool SpdyStream::WasAlpnNegotiated() const { return session_->WasAlpnNegotiated(); } NextProto SpdyStream::GetNegotiatedProtocol() const { return session_->GetNegotiatedProtocol(); } SpdyStream::ShouldRequeueStream SpdyStream::PossiblyResumeIfSendStalled() { if (IsLocallyClosed() || !send_stalled_by_flow_control_) return DoNotRequeue; if (session_->IsSendStalled() || send_window_size_ <= 0) { return Requeue; } net_log_.AddEvent(NetLogEventType::HTTP2_STREAM_FLOW_CONTROL_UNSTALLED, NetLog::IntCallback("stream_id", stream_id_)); send_stalled_by_flow_control_ = false; QueueNextDataFrame(); return DoNotRequeue; } bool SpdyStream::IsClosed() const { return io_state_ == STATE_CLOSED; } bool SpdyStream::IsLocallyClosed() const { return io_state_ == STATE_HALF_CLOSED_LOCAL_UNCLAIMED || io_state_ == STATE_HALF_CLOSED_LOCAL || io_state_ == STATE_CLOSED; } bool SpdyStream::IsIdle() const { return io_state_ == STATE_IDLE; } bool SpdyStream::IsOpen() const { return io_state_ == STATE_OPEN; } bool SpdyStream::IsReservedRemote() const { return io_state_ == STATE_RESERVED_REMOTE; } void SpdyStream::AddRawReceivedBytes(size_t received_bytes) { raw_received_bytes_ += received_bytes; } void SpdyStream::AddRawSentBytes(size_t sent_bytes) { raw_sent_bytes_ += sent_bytes; } bool SpdyStream::GetLoadTimingInfo(LoadTimingInfo* load_timing_info) const { if (stream_id_ == 0) return false; bool result = session_->GetLoadTimingInfo(stream_id_, load_timing_info); if (type_ == SPDY_PUSH_STREAM) { load_timing_info->push_start = recv_first_byte_time_; bool done_receiving = IsClosed() || (!pending_recv_data_.empty() && !pending_recv_data_.back()); if (done_receiving) load_timing_info->push_end = recv_last_byte_time_; } return result; } size_t SpdyStream::EstimateMemoryUsage() const { // TODO(xunjieli): https://crbug.com/669108. Estimate |pending_send_data_| // once scoped_refptr support is in. return base::trace_event::EstimateMemoryUsage(url_) + base::trace_event::EstimateMemoryUsage(request_headers_) + base::trace_event::EstimateMemoryUsage(pending_recv_data_) + base::trace_event::EstimateMemoryUsage(response_headers_); } void SpdyStream::UpdateHistograms() { // We need at least the receive timers to be filled in, as otherwise // metrics can be bogus. if (recv_first_byte_time_.is_null() || recv_last_byte_time_.is_null()) return; base::TimeTicks effective_send_time; if (type_ == SPDY_PUSH_STREAM) { // Push streams shouldn't have |send_time_| filled in. DCHECK(send_time_.is_null()); effective_send_time = recv_first_byte_time_; } else { // For non-push streams, we also need |send_time_| to be filled // in. if (send_time_.is_null()) return; effective_send_time = send_time_; } UMA_HISTOGRAM_TIMES("Net.SpdyStreamTimeToFirstByte", recv_first_byte_time_ - effective_send_time); UMA_HISTOGRAM_TIMES("Net.SpdyStreamDownloadTime", recv_last_byte_time_ - recv_first_byte_time_); UMA_HISTOGRAM_TIMES("Net.SpdyStreamTime", recv_last_byte_time_ - effective_send_time); UMA_HISTOGRAM_COUNTS_1M("Net.SpdySendBytes", send_bytes_); UMA_HISTOGRAM_COUNTS_1M("Net.SpdyRecvBytes", recv_bytes_); } void SpdyStream::QueueNextDataFrame() { // Until the request has been completely sent, we cannot be sure // that our stream_id is correct. CHECK(io_state_ == STATE_OPEN || io_state_ == STATE_HALF_CLOSED_REMOTE) << io_state_; CHECK_GT(stream_id_, 0u); CHECK(pending_send_data_.get()); // Only the final fame may have a length of 0. if (pending_send_status_ == NO_MORE_DATA_TO_SEND) { CHECK_GE(pending_send_data_->BytesRemaining(), 0); } else { CHECK_GT(pending_send_data_->BytesRemaining(), 0); } spdy::SpdyDataFlags flags = (pending_send_status_ == NO_MORE_DATA_TO_SEND) ? spdy::DATA_FLAG_FIN : spdy::DATA_FLAG_NONE; std::unique_ptr data_buffer( session_->CreateDataBuffer(stream_id_, pending_send_data_.get(), pending_send_data_->BytesRemaining(), flags)); // We'll get called again by PossiblyResumeIfSendStalled(). if (!data_buffer) return; DCHECK_GE(data_buffer->GetRemainingSize(), spdy::kDataFrameMinimumSize); size_t payload_size = data_buffer->GetRemainingSize() - spdy::kDataFrameMinimumSize; DCHECK_LE(payload_size, spdy::kHttp2DefaultFramePayloadLimit); // Send window size is based on payload size, so nothing to do if this is // just a FIN with no payload. if (payload_size != 0) { DecreaseSendWindowSize(static_cast(payload_size)); // This currently isn't strictly needed, since write frames are // discarded only if the stream is about to be closed. But have it // here anyway just in case this changes. data_buffer->AddConsumeCallback(base::Bind( &SpdyStream::OnWriteBufferConsumed, GetWeakPtr(), payload_size)); } session_->EnqueueStreamWrite( GetWeakPtr(), spdy::SpdyFrameType::DATA, std::make_unique(std::move(data_buffer))); } void SpdyStream::SaveResponseHeaders( const spdy::SpdyHeaderBlock& response_headers) { DCHECK(response_headers_.empty()); if (response_headers.find("transfer-encoding") != response_headers.end()) { session_->ResetStream(stream_id_, ERR_SPDY_PROTOCOL_ERROR, "Received transfer-encoding header"); return; } for (spdy::SpdyHeaderBlock::const_iterator it = response_headers.begin(); it != response_headers.end(); ++it) { response_headers_.insert(*it); } // If delegate is not yet attached, OnHeadersReceived() will be called after // the delegate gets attached to the stream. if (!delegate_) return; if (type_ == SPDY_PUSH_STREAM) { // OnPushPromiseHeadersReceived() must have been called before // OnHeadersReceived(). DCHECK(request_headers_valid_); delegate_->OnHeadersReceived(response_headers_, &request_headers_); } else { delegate_->OnHeadersReceived(response_headers_, nullptr); } } #define STATE_CASE(s) \ case s: \ description = base::StringPrintf("%s (0x%08X)", #s, s); \ break std::string SpdyStream::DescribeState(State state) { std::string description; switch (state) { STATE_CASE(STATE_IDLE); STATE_CASE(STATE_OPEN); STATE_CASE(STATE_HALF_CLOSED_LOCAL_UNCLAIMED); STATE_CASE(STATE_HALF_CLOSED_LOCAL); STATE_CASE(STATE_CLOSED); default: description = base::StringPrintf("Unknown state 0x%08X (%u)", state, state); break; } return description; } #undef STATE_CASE } // namespace net