// 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_session.h" #include <algorithm> #include <map> #include "base/basictypes.h" #include "base/bind.h" #include "base/compiler_specific.h" #include "base/logging.h" #include "base/message_loop/message_loop.h" #include "base/metrics/field_trial.h" #include "base/metrics/histogram.h" #include "base/metrics/sparse_histogram.h" #include "base/metrics/stats_counters.h" #include "base/stl_util.h" #include "base/strings/string_number_conversions.h" #include "base/strings/string_util.h" #include "base/strings/stringprintf.h" #include "base/strings/utf_string_conversions.h" #include "base/time/time.h" #include "base/values.h" #include "crypto/ec_private_key.h" #include "crypto/ec_signature_creator.h" #include "net/base/connection_type_histograms.h" #include "net/base/net_log.h" #include "net/base/net_util.h" #include "net/cert/asn1_util.h" #include "net/http/http_log_util.h" #include "net/http/http_network_session.h" #include "net/http/http_server_properties.h" #include "net/http/http_util.h" #include "net/spdy/spdy_buffer_producer.h" #include "net/spdy/spdy_frame_builder.h" #include "net/spdy/spdy_http_utils.h" #include "net/spdy/spdy_protocol.h" #include "net/spdy/spdy_session_pool.h" #include "net/spdy/spdy_stream.h" #include "net/ssl/server_bound_cert_service.h" #include "net/ssl/ssl_cipher_suite_names.h" #include "net/ssl/ssl_connection_status_flags.h" namespace net { namespace { const int kReadBufferSize = 8 * 1024; const int kDefaultConnectionAtRiskOfLossSeconds = 10; const int kHungIntervalSeconds = 10; // Minimum seconds that unclaimed pushed streams will be kept in memory. const int kMinPushedStreamLifetimeSeconds = 300; scoped_ptr<base::ListValue> SpdyHeaderBlockToListValue( const SpdyHeaderBlock& headers, net::NetLog::LogLevel log_level) { scoped_ptr<base::ListValue> headers_list(new base::ListValue()); for (SpdyHeaderBlock::const_iterator it = headers.begin(); it != headers.end(); ++it) { headers_list->AppendString( it->first + ": " + ElideHeaderValueForNetLog(log_level, it->first, it->second)); } return headers_list.Pass(); } base::Value* NetLogSpdySynStreamSentCallback(const SpdyHeaderBlock* headers, bool fin, bool unidirectional, SpdyPriority spdy_priority, SpdyStreamId stream_id, NetLog::LogLevel log_level) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->Set("headers", SpdyHeaderBlockToListValue(*headers, log_level).release()); dict->SetBoolean("fin", fin); dict->SetBoolean("unidirectional", unidirectional); dict->SetInteger("spdy_priority", static_cast<int>(spdy_priority)); dict->SetInteger("stream_id", stream_id); return dict; } base::Value* NetLogSpdySynStreamReceivedCallback( const SpdyHeaderBlock* headers, bool fin, bool unidirectional, SpdyPriority spdy_priority, SpdyStreamId stream_id, SpdyStreamId associated_stream, NetLog::LogLevel log_level) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->Set("headers", SpdyHeaderBlockToListValue(*headers, log_level).release()); dict->SetBoolean("fin", fin); dict->SetBoolean("unidirectional", unidirectional); dict->SetInteger("spdy_priority", static_cast<int>(spdy_priority)); dict->SetInteger("stream_id", stream_id); dict->SetInteger("associated_stream", associated_stream); return dict; } base::Value* NetLogSpdySynReplyOrHeadersReceivedCallback( const SpdyHeaderBlock* headers, bool fin, SpdyStreamId stream_id, NetLog::LogLevel log_level) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->Set("headers", SpdyHeaderBlockToListValue(*headers, log_level).release()); dict->SetBoolean("fin", fin); dict->SetInteger("stream_id", stream_id); return dict; } base::Value* NetLogSpdySessionCloseCallback(int net_error, const std::string* description, NetLog::LogLevel /* log_level */) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->SetInteger("net_error", net_error); dict->SetString("description", *description); return dict; } base::Value* NetLogSpdySessionCallback(const HostPortProxyPair* host_pair, NetLog::LogLevel /* log_level */) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->SetString("host", host_pair->first.ToString()); dict->SetString("proxy", host_pair->second.ToPacString()); return dict; } base::Value* NetLogSpdySettingsCallback(const HostPortPair& host_port_pair, bool clear_persisted, NetLog::LogLevel /* log_level */) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->SetString("host", host_port_pair.ToString()); dict->SetBoolean("clear_persisted", clear_persisted); return dict; } base::Value* NetLogSpdySettingCallback(SpdySettingsIds id, SpdySettingsFlags flags, uint32 value, NetLog::LogLevel /* log_level */) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->SetInteger("id", id); dict->SetInteger("flags", flags); dict->SetInteger("value", value); return dict; } base::Value* NetLogSpdySendSettingsCallback(const SettingsMap* settings, NetLog::LogLevel /* log_level */) { base::DictionaryValue* dict = new base::DictionaryValue(); base::ListValue* settings_list = new base::ListValue(); for (SettingsMap::const_iterator it = settings->begin(); it != settings->end(); ++it) { const SpdySettingsIds id = it->first; const SpdySettingsFlags flags = it->second.first; const uint32 value = it->second.second; settings_list->Append(new base::StringValue( base::StringPrintf("[id:%u flags:%u value:%u]", id, flags, value))); } dict->Set("settings", settings_list); return dict; } base::Value* NetLogSpdyWindowUpdateFrameCallback( SpdyStreamId stream_id, uint32 delta, NetLog::LogLevel /* log_level */) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->SetInteger("stream_id", static_cast<int>(stream_id)); dict->SetInteger("delta", delta); return dict; } base::Value* NetLogSpdySessionWindowUpdateCallback( int32 delta, int32 window_size, NetLog::LogLevel /* log_level */) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->SetInteger("delta", delta); dict->SetInteger("window_size", window_size); return dict; } base::Value* NetLogSpdyDataCallback(SpdyStreamId stream_id, int size, bool fin, NetLog::LogLevel /* log_level */) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->SetInteger("stream_id", static_cast<int>(stream_id)); dict->SetInteger("size", size); dict->SetBoolean("fin", fin); return dict; } base::Value* NetLogSpdyRstCallback(SpdyStreamId stream_id, int status, const std::string* description, NetLog::LogLevel /* log_level */) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->SetInteger("stream_id", static_cast<int>(stream_id)); dict->SetInteger("status", status); dict->SetString("description", *description); return dict; } base::Value* NetLogSpdyPingCallback(SpdyPingId unique_id, bool is_ack, const char* type, NetLog::LogLevel /* log_level */) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->SetInteger("unique_id", unique_id); dict->SetString("type", type); dict->SetBoolean("is_ack", is_ack); return dict; } base::Value* NetLogSpdyGoAwayCallback(SpdyStreamId last_stream_id, int active_streams, int unclaimed_streams, SpdyGoAwayStatus status, NetLog::LogLevel /* log_level */) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->SetInteger("last_accepted_stream_id", static_cast<int>(last_stream_id)); dict->SetInteger("active_streams", active_streams); dict->SetInteger("unclaimed_streams", unclaimed_streams); dict->SetInteger("status", static_cast<int>(status)); return dict; } base::Value* NetLogSpdyPushPromiseReceivedCallback( const SpdyHeaderBlock* headers, SpdyStreamId stream_id, SpdyStreamId promised_stream_id, NetLog::LogLevel log_level) { base::DictionaryValue* dict = new base::DictionaryValue(); dict->Set("headers", SpdyHeaderBlockToListValue(*headers, log_level).release()); dict->SetInteger("id", stream_id); dict->SetInteger("promised_stream_id", promised_stream_id); return dict; } // Helper function to return the total size of an array of objects // with .size() member functions. template <typename T, size_t N> size_t GetTotalSize(const T (&arr)[N]) { size_t total_size = 0; for (size_t i = 0; i < N; ++i) { total_size += arr[i].size(); } return total_size; } // Helper class for std:find_if on STL container containing // SpdyStreamRequest weak pointers. class RequestEquals { public: RequestEquals(const base::WeakPtr<SpdyStreamRequest>& request) : request_(request) {} bool operator()(const base::WeakPtr<SpdyStreamRequest>& request) const { return request_.get() == request.get(); } private: const base::WeakPtr<SpdyStreamRequest> request_; }; // The maximum number of concurrent streams we will ever create. Even if // the server permits more, we will never exceed this limit. const size_t kMaxConcurrentStreamLimit = 256; } // namespace SpdyProtocolErrorDetails MapFramerErrorToProtocolError( SpdyFramer::SpdyError err) { switch(err) { case SpdyFramer::SPDY_NO_ERROR: return SPDY_ERROR_NO_ERROR; case SpdyFramer::SPDY_INVALID_CONTROL_FRAME: return SPDY_ERROR_INVALID_CONTROL_FRAME; case SpdyFramer::SPDY_CONTROL_PAYLOAD_TOO_LARGE: return SPDY_ERROR_CONTROL_PAYLOAD_TOO_LARGE; case SpdyFramer::SPDY_ZLIB_INIT_FAILURE: return SPDY_ERROR_ZLIB_INIT_FAILURE; case SpdyFramer::SPDY_UNSUPPORTED_VERSION: return SPDY_ERROR_UNSUPPORTED_VERSION; case SpdyFramer::SPDY_DECOMPRESS_FAILURE: return SPDY_ERROR_DECOMPRESS_FAILURE; case SpdyFramer::SPDY_COMPRESS_FAILURE: return SPDY_ERROR_COMPRESS_FAILURE; case SpdyFramer::SPDY_GOAWAY_FRAME_CORRUPT: return SPDY_ERROR_GOAWAY_FRAME_CORRUPT; case SpdyFramer::SPDY_RST_STREAM_FRAME_CORRUPT: return SPDY_ERROR_RST_STREAM_FRAME_CORRUPT; case SpdyFramer::SPDY_INVALID_DATA_FRAME_FLAGS: return SPDY_ERROR_INVALID_DATA_FRAME_FLAGS; case SpdyFramer::SPDY_INVALID_CONTROL_FRAME_FLAGS: return SPDY_ERROR_INVALID_CONTROL_FRAME_FLAGS; case SpdyFramer::SPDY_UNEXPECTED_FRAME: return SPDY_ERROR_UNEXPECTED_FRAME; default: NOTREACHED(); return static_cast<SpdyProtocolErrorDetails>(-1); } } Error MapFramerErrorToNetError(SpdyFramer::SpdyError err) { switch (err) { case SpdyFramer::SPDY_NO_ERROR: return OK; case SpdyFramer::SPDY_INVALID_CONTROL_FRAME: return ERR_SPDY_PROTOCOL_ERROR; case SpdyFramer::SPDY_CONTROL_PAYLOAD_TOO_LARGE: return ERR_SPDY_FRAME_SIZE_ERROR; case SpdyFramer::SPDY_ZLIB_INIT_FAILURE: return ERR_SPDY_COMPRESSION_ERROR; case SpdyFramer::SPDY_UNSUPPORTED_VERSION: return ERR_SPDY_PROTOCOL_ERROR; case SpdyFramer::SPDY_DECOMPRESS_FAILURE: return ERR_SPDY_COMPRESSION_ERROR; case SpdyFramer::SPDY_COMPRESS_FAILURE: return ERR_SPDY_COMPRESSION_ERROR; case SpdyFramer::SPDY_GOAWAY_FRAME_CORRUPT: return ERR_SPDY_PROTOCOL_ERROR; case SpdyFramer::SPDY_RST_STREAM_FRAME_CORRUPT: return ERR_SPDY_PROTOCOL_ERROR; case SpdyFramer::SPDY_INVALID_DATA_FRAME_FLAGS: return ERR_SPDY_PROTOCOL_ERROR; case SpdyFramer::SPDY_INVALID_CONTROL_FRAME_FLAGS: return ERR_SPDY_PROTOCOL_ERROR; case SpdyFramer::SPDY_UNEXPECTED_FRAME: return ERR_SPDY_PROTOCOL_ERROR; default: NOTREACHED(); return ERR_SPDY_PROTOCOL_ERROR; } } SpdyProtocolErrorDetails MapRstStreamStatusToProtocolError( SpdyRstStreamStatus status) { switch(status) { case RST_STREAM_PROTOCOL_ERROR: return STATUS_CODE_PROTOCOL_ERROR; case RST_STREAM_INVALID_STREAM: return STATUS_CODE_INVALID_STREAM; case RST_STREAM_REFUSED_STREAM: return STATUS_CODE_REFUSED_STREAM; case RST_STREAM_UNSUPPORTED_VERSION: return STATUS_CODE_UNSUPPORTED_VERSION; case RST_STREAM_CANCEL: return STATUS_CODE_CANCEL; case RST_STREAM_INTERNAL_ERROR: return STATUS_CODE_INTERNAL_ERROR; case RST_STREAM_FLOW_CONTROL_ERROR: return STATUS_CODE_FLOW_CONTROL_ERROR; case RST_STREAM_STREAM_IN_USE: return STATUS_CODE_STREAM_IN_USE; case RST_STREAM_STREAM_ALREADY_CLOSED: return STATUS_CODE_STREAM_ALREADY_CLOSED; case RST_STREAM_INVALID_CREDENTIALS: return STATUS_CODE_INVALID_CREDENTIALS; case RST_STREAM_FRAME_SIZE_ERROR: return STATUS_CODE_FRAME_SIZE_ERROR; case RST_STREAM_SETTINGS_TIMEOUT: return STATUS_CODE_SETTINGS_TIMEOUT; case RST_STREAM_CONNECT_ERROR: return STATUS_CODE_CONNECT_ERROR; case RST_STREAM_ENHANCE_YOUR_CALM: return STATUS_CODE_ENHANCE_YOUR_CALM; default: NOTREACHED(); return static_cast<SpdyProtocolErrorDetails>(-1); } } SpdyGoAwayStatus MapNetErrorToGoAwayStatus(Error err) { switch (err) { case OK: return GOAWAY_NO_ERROR; case ERR_SPDY_PROTOCOL_ERROR: return GOAWAY_PROTOCOL_ERROR; case ERR_SPDY_FLOW_CONTROL_ERROR: return GOAWAY_FLOW_CONTROL_ERROR; case ERR_SPDY_FRAME_SIZE_ERROR: return GOAWAY_FRAME_SIZE_ERROR; case ERR_SPDY_COMPRESSION_ERROR: return GOAWAY_COMPRESSION_ERROR; case ERR_SPDY_INADEQUATE_TRANSPORT_SECURITY: return GOAWAY_INADEQUATE_SECURITY; default: return GOAWAY_PROTOCOL_ERROR; } } void SplitPushedHeadersToRequestAndResponse(const SpdyHeaderBlock& headers, SpdyMajorVersion protocol_version, SpdyHeaderBlock* request_headers, SpdyHeaderBlock* response_headers) { DCHECK(response_headers); DCHECK(request_headers); for (SpdyHeaderBlock::const_iterator it = headers.begin(); it != headers.end(); ++it) { SpdyHeaderBlock* to_insert = response_headers; if (protocol_version == SPDY2) { if (it->first == "url") to_insert = request_headers; } else { const char* host = protocol_version >= SPDY4 ? ":authority" : ":host"; static const char* scheme = ":scheme"; static const char* path = ":path"; if (it->first == host || it->first == scheme || it->first == path) to_insert = request_headers; } to_insert->insert(*it); } } SpdyStreamRequest::SpdyStreamRequest() : weak_ptr_factory_(this) { Reset(); } SpdyStreamRequest::~SpdyStreamRequest() { CancelRequest(); } int SpdyStreamRequest::StartRequest( SpdyStreamType type, const base::WeakPtr<SpdySession>& session, const GURL& url, RequestPriority priority, const BoundNetLog& net_log, const CompletionCallback& callback) { DCHECK(session); DCHECK(!session_); DCHECK(!stream_); DCHECK(callback_.is_null()); type_ = type; session_ = session; url_ = url; priority_ = priority; net_log_ = net_log; callback_ = callback; base::WeakPtr<SpdyStream> stream; int rv = session->TryCreateStream(weak_ptr_factory_.GetWeakPtr(), &stream); if (rv == OK) { Reset(); stream_ = stream; } return rv; } void SpdyStreamRequest::CancelRequest() { if (session_) session_->CancelStreamRequest(weak_ptr_factory_.GetWeakPtr()); Reset(); // Do this to cancel any pending CompleteStreamRequest() tasks. weak_ptr_factory_.InvalidateWeakPtrs(); } base::WeakPtr<SpdyStream> SpdyStreamRequest::ReleaseStream() { DCHECK(!session_); base::WeakPtr<SpdyStream> stream = stream_; DCHECK(stream); Reset(); return stream; } void SpdyStreamRequest::OnRequestCompleteSuccess( const base::WeakPtr<SpdyStream>& stream) { DCHECK(session_); DCHECK(!stream_); DCHECK(!callback_.is_null()); CompletionCallback callback = callback_; Reset(); DCHECK(stream); stream_ = stream; callback.Run(OK); } void SpdyStreamRequest::OnRequestCompleteFailure(int rv) { DCHECK(session_); DCHECK(!stream_); DCHECK(!callback_.is_null()); CompletionCallback callback = callback_; Reset(); DCHECK_NE(rv, OK); callback.Run(rv); } void SpdyStreamRequest::Reset() { type_ = SPDY_BIDIRECTIONAL_STREAM; session_.reset(); stream_.reset(); url_ = GURL(); priority_ = MINIMUM_PRIORITY; net_log_ = BoundNetLog(); callback_.Reset(); } SpdySession::ActiveStreamInfo::ActiveStreamInfo() : stream(NULL), waiting_for_syn_reply(false) {} SpdySession::ActiveStreamInfo::ActiveStreamInfo(SpdyStream* stream) : stream(stream), waiting_for_syn_reply(stream->type() != SPDY_PUSH_STREAM) { } SpdySession::ActiveStreamInfo::~ActiveStreamInfo() {} SpdySession::PushedStreamInfo::PushedStreamInfo() : stream_id(0) {} SpdySession::PushedStreamInfo::PushedStreamInfo( SpdyStreamId stream_id, base::TimeTicks creation_time) : stream_id(stream_id), creation_time(creation_time) {} SpdySession::PushedStreamInfo::~PushedStreamInfo() {} SpdySession::SpdySession( const SpdySessionKey& spdy_session_key, const base::WeakPtr<HttpServerProperties>& http_server_properties, bool verify_domain_authentication, bool enable_sending_initial_data, bool enable_compression, bool enable_ping_based_connection_checking, NextProto default_protocol, size_t stream_initial_recv_window_size, size_t initial_max_concurrent_streams, size_t max_concurrent_streams_limit, TimeFunc time_func, const HostPortPair& trusted_spdy_proxy, NetLog* net_log) : in_io_loop_(false), spdy_session_key_(spdy_session_key), pool_(NULL), http_server_properties_(http_server_properties), read_buffer_(new IOBuffer(kReadBufferSize)), stream_hi_water_mark_(kFirstStreamId), in_flight_write_frame_type_(DATA), in_flight_write_frame_size_(0), is_secure_(false), certificate_error_code_(OK), availability_state_(STATE_AVAILABLE), read_state_(READ_STATE_DO_READ), write_state_(WRITE_STATE_IDLE), error_on_close_(OK), max_concurrent_streams_(initial_max_concurrent_streams == 0 ? kInitialMaxConcurrentStreams : initial_max_concurrent_streams), max_concurrent_streams_limit_(max_concurrent_streams_limit == 0 ? kMaxConcurrentStreamLimit : max_concurrent_streams_limit), streams_initiated_count_(0), streams_pushed_count_(0), streams_pushed_and_claimed_count_(0), streams_abandoned_count_(0), total_bytes_received_(0), sent_settings_(false), received_settings_(false), stalled_streams_(0), pings_in_flight_(0), next_ping_id_(1), last_activity_time_(time_func()), last_compressed_frame_len_(0), check_ping_status_pending_(false), send_connection_header_prefix_(false), flow_control_state_(FLOW_CONTROL_NONE), stream_initial_send_window_size_(kSpdyStreamInitialWindowSize), stream_initial_recv_window_size_(stream_initial_recv_window_size == 0 ? kDefaultInitialRecvWindowSize : stream_initial_recv_window_size), session_send_window_size_(0), session_recv_window_size_(0), session_unacked_recv_window_bytes_(0), net_log_(BoundNetLog::Make(net_log, NetLog::SOURCE_SPDY_SESSION)), verify_domain_authentication_(verify_domain_authentication), enable_sending_initial_data_(enable_sending_initial_data), enable_compression_(enable_compression), enable_ping_based_connection_checking_( enable_ping_based_connection_checking), protocol_(default_protocol), connection_at_risk_of_loss_time_( base::TimeDelta::FromSeconds(kDefaultConnectionAtRiskOfLossSeconds)), hung_interval_(base::TimeDelta::FromSeconds(kHungIntervalSeconds)), trusted_spdy_proxy_(trusted_spdy_proxy), time_func_(time_func), weak_factory_(this) { DCHECK_GE(protocol_, kProtoSPDYMinimumVersion); DCHECK_LE(protocol_, kProtoSPDYMaximumVersion); DCHECK(HttpStreamFactory::spdy_enabled()); net_log_.BeginEvent( NetLog::TYPE_SPDY_SESSION, base::Bind(&NetLogSpdySessionCallback, &host_port_proxy_pair())); next_unclaimed_push_stream_sweep_time_ = time_func_() + base::TimeDelta::FromSeconds(kMinPushedStreamLifetimeSeconds); // TODO(mbelshe): consider randomization of the stream_hi_water_mark. } SpdySession::~SpdySession() { CHECK(!in_io_loop_); DcheckDraining(); // TODO(akalin): Check connection->is_initialized() instead. This // requires re-working CreateFakeSpdySession(), though. DCHECK(connection_->socket()); // With SPDY we can't recycle sockets. connection_->socket()->Disconnect(); RecordHistograms(); net_log_.EndEvent(NetLog::TYPE_SPDY_SESSION); } void SpdySession::InitializeWithSocket( scoped_ptr<ClientSocketHandle> connection, SpdySessionPool* pool, bool is_secure, int certificate_error_code) { CHECK(!in_io_loop_); DCHECK_EQ(availability_state_, STATE_AVAILABLE); DCHECK_EQ(read_state_, READ_STATE_DO_READ); DCHECK_EQ(write_state_, WRITE_STATE_IDLE); DCHECK(!connection_); DCHECK(certificate_error_code == OK || certificate_error_code < ERR_IO_PENDING); // TODO(akalin): Check connection->is_initialized() instead. This // requires re-working CreateFakeSpdySession(), though. DCHECK(connection->socket()); base::StatsCounter spdy_sessions("spdy.sessions"); spdy_sessions.Increment(); connection_ = connection.Pass(); is_secure_ = is_secure; certificate_error_code_ = certificate_error_code; NextProto protocol_negotiated = connection_->socket()->GetNegotiatedProtocol(); if (protocol_negotiated != kProtoUnknown) { protocol_ = protocol_negotiated; } DCHECK_GE(protocol_, kProtoSPDYMinimumVersion); DCHECK_LE(protocol_, kProtoSPDYMaximumVersion); if (protocol_ == kProtoSPDY4) send_connection_header_prefix_ = true; if (protocol_ >= kProtoSPDY31) { flow_control_state_ = FLOW_CONTROL_STREAM_AND_SESSION; session_send_window_size_ = kSpdySessionInitialWindowSize; session_recv_window_size_ = kSpdySessionInitialWindowSize; } else if (protocol_ >= kProtoSPDY3) { flow_control_state_ = FLOW_CONTROL_STREAM; } else { flow_control_state_ = FLOW_CONTROL_NONE; } buffered_spdy_framer_.reset( new BufferedSpdyFramer(NextProtoToSpdyMajorVersion(protocol_), enable_compression_)); buffered_spdy_framer_->set_visitor(this); buffered_spdy_framer_->set_debug_visitor(this); UMA_HISTOGRAM_ENUMERATION("Net.SpdyVersion", protocol_, kProtoMaximumVersion); #if defined(SPDY_PROXY_AUTH_ORIGIN) UMA_HISTOGRAM_BOOLEAN("Net.SpdySessions_DataReductionProxy", host_port_pair().Equals(HostPortPair::FromURL( GURL(SPDY_PROXY_AUTH_ORIGIN)))); #endif net_log_.AddEvent( NetLog::TYPE_SPDY_SESSION_INITIALIZED, connection_->socket()->NetLog().source().ToEventParametersCallback()); DCHECK_EQ(availability_state_, STATE_AVAILABLE); connection_->AddHigherLayeredPool(this); if (enable_sending_initial_data_) SendInitialData(); pool_ = pool; // Bootstrap the read loop. base::MessageLoop::current()->PostTask( FROM_HERE, base::Bind(&SpdySession::PumpReadLoop, weak_factory_.GetWeakPtr(), READ_STATE_DO_READ, OK)); } bool SpdySession::VerifyDomainAuthentication(const std::string& domain) { if (!verify_domain_authentication_) return true; if (availability_state_ == STATE_DRAINING) return false; SSLInfo ssl_info; bool was_npn_negotiated; NextProto protocol_negotiated = kProtoUnknown; if (!GetSSLInfo(&ssl_info, &was_npn_negotiated, &protocol_negotiated)) return true; // This is not a secure session, so all domains are okay. // Disable pooling for secure sessions. // TODO(rch): re-enable this. return false; #if 0 bool unused = false; return !ssl_info.client_cert_sent && (!ssl_info.channel_id_sent || (ServerBoundCertService::GetDomainForHost(domain) == ServerBoundCertService::GetDomainForHost(host_port_pair().host()))) && ssl_info.cert->VerifyNameMatch(domain, &unused); #endif } int SpdySession::GetPushStream( const GURL& url, base::WeakPtr<SpdyStream>* stream, const BoundNetLog& stream_net_log) { CHECK(!in_io_loop_); stream->reset(); if (availability_state_ == STATE_DRAINING) return ERR_CONNECTION_CLOSED; Error err = TryAccessStream(url); if (err != OK) return err; *stream = GetActivePushStream(url); if (*stream) { DCHECK_LT(streams_pushed_and_claimed_count_, streams_pushed_count_); streams_pushed_and_claimed_count_++; } return OK; } // {,Try}CreateStream() and TryAccessStream() can be called with // |in_io_loop_| set if a stream is being created in response to // another being closed due to received data. Error SpdySession::TryAccessStream(const GURL& url) { if (is_secure_ && certificate_error_code_ != OK && (url.SchemeIs("https") || url.SchemeIs("wss"))) { RecordProtocolErrorHistogram( PROTOCOL_ERROR_REQUEST_FOR_SECURE_CONTENT_OVER_INSECURE_SESSION); DoDrainSession( static_cast<Error>(certificate_error_code_), "Tried to get SPDY stream for secure content over an unauthenticated " "session."); return ERR_SPDY_PROTOCOL_ERROR; } return OK; } int SpdySession::TryCreateStream( const base::WeakPtr<SpdyStreamRequest>& request, base::WeakPtr<SpdyStream>* stream) { DCHECK(request); if (availability_state_ == STATE_GOING_AWAY) return ERR_FAILED; if (availability_state_ == STATE_DRAINING) return ERR_CONNECTION_CLOSED; Error err = TryAccessStream(request->url()); if (err != OK) return err; if (!max_concurrent_streams_ || (active_streams_.size() + created_streams_.size() < max_concurrent_streams_)) { return CreateStream(*request, stream); } stalled_streams_++; net_log().AddEvent(NetLog::TYPE_SPDY_SESSION_STALLED_MAX_STREAMS); RequestPriority priority = request->priority(); CHECK_GE(priority, MINIMUM_PRIORITY); CHECK_LE(priority, MAXIMUM_PRIORITY); pending_create_stream_queues_[priority].push_back(request); return ERR_IO_PENDING; } int SpdySession::CreateStream(const SpdyStreamRequest& request, base::WeakPtr<SpdyStream>* stream) { DCHECK_GE(request.priority(), MINIMUM_PRIORITY); DCHECK_LE(request.priority(), MAXIMUM_PRIORITY); if (availability_state_ == STATE_GOING_AWAY) return ERR_FAILED; if (availability_state_ == STATE_DRAINING) return ERR_CONNECTION_CLOSED; Error err = TryAccessStream(request.url()); if (err != OK) { // This should have been caught in TryCreateStream(). NOTREACHED(); return err; } DCHECK(connection_->socket()); DCHECK(connection_->socket()->IsConnected()); if (connection_->socket()) { UMA_HISTOGRAM_BOOLEAN("Net.SpdySession.CreateStreamWithSocketConnected", connection_->socket()->IsConnected()); if (!connection_->socket()->IsConnected()) { DoDrainSession( ERR_CONNECTION_CLOSED, "Tried to create SPDY stream for a closed socket connection."); return ERR_CONNECTION_CLOSED; } } scoped_ptr<SpdyStream> new_stream( new SpdyStream(request.type(), GetWeakPtr(), request.url(), request.priority(), stream_initial_send_window_size_, stream_initial_recv_window_size_, request.net_log())); *stream = new_stream->GetWeakPtr(); InsertCreatedStream(new_stream.Pass()); UMA_HISTOGRAM_CUSTOM_COUNTS( "Net.SpdyPriorityCount", static_cast<int>(request.priority()), 0, 10, 11); return OK; } void SpdySession::CancelStreamRequest( const base::WeakPtr<SpdyStreamRequest>& request) { DCHECK(request); RequestPriority priority = request->priority(); CHECK_GE(priority, MINIMUM_PRIORITY); CHECK_LE(priority, MAXIMUM_PRIORITY); #if DCHECK_IS_ON // |request| should not be in a queue not matching its priority. for (int i = MINIMUM_PRIORITY; i <= MAXIMUM_PRIORITY; ++i) { if (priority == i) continue; PendingStreamRequestQueue* queue = &pending_create_stream_queues_[i]; DCHECK(std::find_if(queue->begin(), queue->end(), RequestEquals(request)) == queue->end()); } #endif PendingStreamRequestQueue* queue = &pending_create_stream_queues_[priority]; // Remove |request| from |queue| while preserving the order of the // other elements. PendingStreamRequestQueue::iterator it = std::find_if(queue->begin(), queue->end(), RequestEquals(request)); // The request may already be removed if there's a // CompleteStreamRequest() in flight. if (it != queue->end()) { it = queue->erase(it); // |request| should be in the queue at most once, and if it is // present, should not be pending completion. DCHECK(std::find_if(it, queue->end(), RequestEquals(request)) == queue->end()); } } base::WeakPtr<SpdyStreamRequest> SpdySession::GetNextPendingStreamRequest() { for (int j = MAXIMUM_PRIORITY; j >= MINIMUM_PRIORITY; --j) { if (pending_create_stream_queues_[j].empty()) continue; base::WeakPtr<SpdyStreamRequest> pending_request = pending_create_stream_queues_[j].front(); DCHECK(pending_request); pending_create_stream_queues_[j].pop_front(); return pending_request; } return base::WeakPtr<SpdyStreamRequest>(); } void SpdySession::ProcessPendingStreamRequests() { // Like |max_concurrent_streams_|, 0 means infinite for // |max_requests_to_process|. size_t max_requests_to_process = 0; if (max_concurrent_streams_ != 0) { max_requests_to_process = max_concurrent_streams_ - (active_streams_.size() + created_streams_.size()); } for (size_t i = 0; max_requests_to_process == 0 || i < max_requests_to_process; ++i) { base::WeakPtr<SpdyStreamRequest> pending_request = GetNextPendingStreamRequest(); if (!pending_request) break; // Note that this post can race with other stream creations, and it's // possible that the un-stalled stream will be stalled again if it loses. // TODO(jgraettinger): Provide stronger ordering guarantees. base::MessageLoop::current()->PostTask( FROM_HERE, base::Bind(&SpdySession::CompleteStreamRequest, weak_factory_.GetWeakPtr(), pending_request)); } } void SpdySession::AddPooledAlias(const SpdySessionKey& alias_key) { pooled_aliases_.insert(alias_key); } SpdyMajorVersion SpdySession::GetProtocolVersion() const { DCHECK(buffered_spdy_framer_.get()); return buffered_spdy_framer_->protocol_version(); } bool SpdySession::HasAcceptableTransportSecurity() const { // If we're not even using TLS, we have no standards to meet. if (!is_secure_) { return true; } // We don't enforce transport security standards for older SPDY versions. if (GetProtocolVersion() < SPDY4) { return true; } SSLInfo ssl_info; CHECK(connection_->socket()->GetSSLInfo(&ssl_info)); // HTTP/2 requires TLS 1.2+ if (SSLConnectionStatusToVersion(ssl_info.connection_status) < SSL_CONNECTION_VERSION_TLS1_2) { return false; } if (!IsSecureTLSCipherSuite( SSLConnectionStatusToCipherSuite(ssl_info.connection_status))) { return false; } return true; } base::WeakPtr<SpdySession> SpdySession::GetWeakPtr() { return weak_factory_.GetWeakPtr(); } bool SpdySession::CloseOneIdleConnection() { CHECK(!in_io_loop_); DCHECK(pool_); if (active_streams_.empty()) { DoDrainSession(ERR_CONNECTION_CLOSED, "Closing idle connection."); } // Return false as the socket wasn't immediately closed. return false; } void SpdySession::EnqueueStreamWrite( const base::WeakPtr<SpdyStream>& stream, SpdyFrameType frame_type, scoped_ptr<SpdyBufferProducer> producer) { DCHECK(frame_type == HEADERS || frame_type == DATA || frame_type == CREDENTIAL || frame_type == SYN_STREAM); EnqueueWrite(stream->priority(), frame_type, producer.Pass(), stream); } scoped_ptr<SpdyFrame> SpdySession::CreateSynStream( SpdyStreamId stream_id, RequestPriority priority, SpdyControlFlags flags, const SpdyHeaderBlock& headers) { ActiveStreamMap::const_iterator it = active_streams_.find(stream_id); CHECK(it != active_streams_.end()); CHECK_EQ(it->second.stream->stream_id(), stream_id); SendPrefacePingIfNoneInFlight(); DCHECK(buffered_spdy_framer_.get()); SpdyPriority spdy_priority = ConvertRequestPriorityToSpdyPriority(priority, GetProtocolVersion()); scoped_ptr<SpdyFrame> syn_frame( buffered_spdy_framer_->CreateSynStream(stream_id, 0, spdy_priority, flags, &headers)); base::StatsCounter spdy_requests("spdy.requests"); spdy_requests.Increment(); streams_initiated_count_++; if (net_log().IsLogging()) { net_log().AddEvent( NetLog::TYPE_SPDY_SESSION_SYN_STREAM, base::Bind(&NetLogSpdySynStreamSentCallback, &headers, (flags & CONTROL_FLAG_FIN) != 0, (flags & CONTROL_FLAG_UNIDIRECTIONAL) != 0, spdy_priority, stream_id)); } return syn_frame.Pass(); } scoped_ptr<SpdyBuffer> SpdySession::CreateDataBuffer(SpdyStreamId stream_id, IOBuffer* data, int len, SpdyDataFlags flags) { if (availability_state_ == STATE_DRAINING) { return scoped_ptr<SpdyBuffer>(); } ActiveStreamMap::const_iterator it = active_streams_.find(stream_id); CHECK(it != active_streams_.end()); SpdyStream* stream = it->second.stream; CHECK_EQ(stream->stream_id(), stream_id); if (len < 0) { NOTREACHED(); return scoped_ptr<SpdyBuffer>(); } int effective_len = std::min(len, kMaxSpdyFrameChunkSize); bool send_stalled_by_stream = (flow_control_state_ >= FLOW_CONTROL_STREAM) && (stream->send_window_size() <= 0); bool send_stalled_by_session = IsSendStalled(); // NOTE: There's an enum of the same name in histograms.xml. enum SpdyFrameFlowControlState { SEND_NOT_STALLED, SEND_STALLED_BY_STREAM, SEND_STALLED_BY_SESSION, SEND_STALLED_BY_STREAM_AND_SESSION, }; SpdyFrameFlowControlState frame_flow_control_state = SEND_NOT_STALLED; if (send_stalled_by_stream) { if (send_stalled_by_session) { frame_flow_control_state = SEND_STALLED_BY_STREAM_AND_SESSION; } else { frame_flow_control_state = SEND_STALLED_BY_STREAM; } } else if (send_stalled_by_session) { frame_flow_control_state = SEND_STALLED_BY_SESSION; } if (flow_control_state_ == FLOW_CONTROL_STREAM) { UMA_HISTOGRAM_ENUMERATION( "Net.SpdyFrameStreamFlowControlState", frame_flow_control_state, SEND_STALLED_BY_STREAM + 1); } else if (flow_control_state_ == FLOW_CONTROL_STREAM_AND_SESSION) { UMA_HISTOGRAM_ENUMERATION( "Net.SpdyFrameStreamAndSessionFlowControlState", frame_flow_control_state, SEND_STALLED_BY_STREAM_AND_SESSION + 1); } // Obey send window size of the stream if stream flow control is // enabled. if (flow_control_state_ >= FLOW_CONTROL_STREAM) { if (send_stalled_by_stream) { stream->set_send_stalled_by_flow_control(true); // Even though we're currently stalled only by the stream, we // might end up being stalled by the session also. QueueSendStalledStream(*stream); net_log().AddEvent( NetLog::TYPE_SPDY_SESSION_STREAM_STALLED_BY_STREAM_SEND_WINDOW, NetLog::IntegerCallback("stream_id", stream_id)); return scoped_ptr<SpdyBuffer>(); } effective_len = std::min(effective_len, stream->send_window_size()); } // Obey send window size of the session if session flow control is // enabled. if (flow_control_state_ == FLOW_CONTROL_STREAM_AND_SESSION) { if (send_stalled_by_session) { stream->set_send_stalled_by_flow_control(true); QueueSendStalledStream(*stream); net_log().AddEvent( NetLog::TYPE_SPDY_SESSION_STREAM_STALLED_BY_SESSION_SEND_WINDOW, NetLog::IntegerCallback("stream_id", stream_id)); return scoped_ptr<SpdyBuffer>(); } effective_len = std::min(effective_len, session_send_window_size_); } DCHECK_GE(effective_len, 0); // Clear FIN flag if only some of the data will be in the data // frame. if (effective_len < len) flags = static_cast<SpdyDataFlags>(flags & ~DATA_FLAG_FIN); if (net_log().IsLogging()) { net_log().AddEvent( NetLog::TYPE_SPDY_SESSION_SEND_DATA, base::Bind(&NetLogSpdyDataCallback, stream_id, effective_len, (flags & DATA_FLAG_FIN) != 0)); } // Send PrefacePing for DATA_FRAMEs with nonzero payload size. if (effective_len > 0) SendPrefacePingIfNoneInFlight(); // TODO(mbelshe): reduce memory copies here. DCHECK(buffered_spdy_framer_.get()); scoped_ptr<SpdyFrame> frame( buffered_spdy_framer_->CreateDataFrame( stream_id, data->data(), static_cast<uint32>(effective_len), flags)); scoped_ptr<SpdyBuffer> data_buffer(new SpdyBuffer(frame.Pass())); if (flow_control_state_ == FLOW_CONTROL_STREAM_AND_SESSION) { DecreaseSendWindowSize(static_cast<int32>(effective_len)); data_buffer->AddConsumeCallback( base::Bind(&SpdySession::OnWriteBufferConsumed, weak_factory_.GetWeakPtr(), static_cast<size_t>(effective_len))); } return data_buffer.Pass(); } void SpdySession::CloseActiveStream(SpdyStreamId stream_id, int status) { DCHECK_NE(stream_id, 0u); ActiveStreamMap::iterator it = active_streams_.find(stream_id); if (it == active_streams_.end()) { NOTREACHED(); return; } CloseActiveStreamIterator(it, status); } void SpdySession::CloseCreatedStream( const base::WeakPtr<SpdyStream>& stream, int status) { DCHECK_EQ(stream->stream_id(), 0u); CreatedStreamSet::iterator it = created_streams_.find(stream.get()); if (it == created_streams_.end()) { NOTREACHED(); return; } CloseCreatedStreamIterator(it, status); } void SpdySession::ResetStream(SpdyStreamId stream_id, SpdyRstStreamStatus status, const std::string& description) { DCHECK_NE(stream_id, 0u); ActiveStreamMap::iterator it = active_streams_.find(stream_id); if (it == active_streams_.end()) { NOTREACHED(); return; } ResetStreamIterator(it, status, description); } bool SpdySession::IsStreamActive(SpdyStreamId stream_id) const { return ContainsKey(active_streams_, stream_id); } LoadState SpdySession::GetLoadState() const { // Just report that we're idle since the session could be doing // many things concurrently. return LOAD_STATE_IDLE; } void SpdySession::CloseActiveStreamIterator(ActiveStreamMap::iterator it, int status) { // TODO(mbelshe): We should send a RST_STREAM control frame here // so that the server can cancel a large send. scoped_ptr<SpdyStream> owned_stream(it->second.stream); active_streams_.erase(it); // TODO(akalin): When SpdyStream was ref-counted (and // |unclaimed_pushed_streams_| held scoped_refptr<SpdyStream>), this // was only done when status was not OK. This meant that pushed // streams can still be claimed after they're closed. This is // probably something that we still want to support, although server // push is hardly used. Write tests for this and fix this. (See // http://crbug.com/261712 .) if (owned_stream->type() == SPDY_PUSH_STREAM) unclaimed_pushed_streams_.erase(owned_stream->url()); DeleteStream(owned_stream.Pass(), status); MaybeFinishGoingAway(); // If there are no active streams and the socket pool is stalled, close the // session to free up a socket slot. if (active_streams_.empty() && connection_->IsPoolStalled()) { DoDrainSession(ERR_CONNECTION_CLOSED, "Closing idle connection."); } } void SpdySession::CloseCreatedStreamIterator(CreatedStreamSet::iterator it, int status) { scoped_ptr<SpdyStream> owned_stream(*it); created_streams_.erase(it); DeleteStream(owned_stream.Pass(), status); } void SpdySession::ResetStreamIterator(ActiveStreamMap::iterator it, SpdyRstStreamStatus status, const std::string& description) { // Send the RST_STREAM frame first as CloseActiveStreamIterator() // may close us. SpdyStreamId stream_id = it->first; RequestPriority priority = it->second.stream->priority(); EnqueueResetStreamFrame(stream_id, priority, status, description); // Removes any pending writes for the stream except for possibly an // in-flight one. CloseActiveStreamIterator(it, ERR_SPDY_PROTOCOL_ERROR); } void SpdySession::EnqueueResetStreamFrame(SpdyStreamId stream_id, RequestPriority priority, SpdyRstStreamStatus status, const std::string& description) { DCHECK_NE(stream_id, 0u); net_log().AddEvent( NetLog::TYPE_SPDY_SESSION_SEND_RST_STREAM, base::Bind(&NetLogSpdyRstCallback, stream_id, status, &description)); DCHECK(buffered_spdy_framer_.get()); scoped_ptr<SpdyFrame> rst_frame( buffered_spdy_framer_->CreateRstStream(stream_id, status)); EnqueueSessionWrite(priority, RST_STREAM, rst_frame.Pass()); RecordProtocolErrorHistogram(MapRstStreamStatusToProtocolError(status)); } void SpdySession::PumpReadLoop(ReadState expected_read_state, int result) { CHECK(!in_io_loop_); if (availability_state_ == STATE_DRAINING) { return; } ignore_result(DoReadLoop(expected_read_state, result)); } int SpdySession::DoReadLoop(ReadState expected_read_state, int result) { CHECK(!in_io_loop_); CHECK_EQ(read_state_, expected_read_state); in_io_loop_ = true; int bytes_read_without_yielding = 0; // Loop until the session is draining, the read becomes blocked, or // the read limit is exceeded. while (true) { switch (read_state_) { case READ_STATE_DO_READ: CHECK_EQ(result, OK); result = DoRead(); break; case READ_STATE_DO_READ_COMPLETE: if (result > 0) bytes_read_without_yielding += result; result = DoReadComplete(result); break; default: NOTREACHED() << "read_state_: " << read_state_; break; } if (availability_state_ == STATE_DRAINING) break; if (result == ERR_IO_PENDING) break; if (bytes_read_without_yielding > kMaxReadBytesWithoutYielding) { read_state_ = READ_STATE_DO_READ; base::MessageLoop::current()->PostTask( FROM_HERE, base::Bind(&SpdySession::PumpReadLoop, weak_factory_.GetWeakPtr(), READ_STATE_DO_READ, OK)); result = ERR_IO_PENDING; break; } } CHECK(in_io_loop_); in_io_loop_ = false; return result; } int SpdySession::DoRead() { CHECK(in_io_loop_); CHECK(connection_); CHECK(connection_->socket()); read_state_ = READ_STATE_DO_READ_COMPLETE; return connection_->socket()->Read( read_buffer_.get(), kReadBufferSize, base::Bind(&SpdySession::PumpReadLoop, weak_factory_.GetWeakPtr(), READ_STATE_DO_READ_COMPLETE)); } int SpdySession::DoReadComplete(int result) { CHECK(in_io_loop_); // Parse a frame. For now this code requires that the frame fit into our // buffer (kReadBufferSize). // TODO(mbelshe): support arbitrarily large frames! if (result == 0) { UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdySession.BytesRead.EOF", total_bytes_received_, 1, 100000000, 50); DoDrainSession(ERR_CONNECTION_CLOSED, "Connection closed"); return ERR_CONNECTION_CLOSED; } if (result < 0) { DoDrainSession(static_cast<Error>(result), "result is < 0."); return result; } CHECK_LE(result, kReadBufferSize); total_bytes_received_ += result; last_activity_time_ = time_func_(); DCHECK(buffered_spdy_framer_.get()); char* data = read_buffer_->data(); while (result > 0) { uint32 bytes_processed = buffered_spdy_framer_->ProcessInput(data, result); result -= bytes_processed; data += bytes_processed; if (availability_state_ == STATE_DRAINING) { return ERR_CONNECTION_CLOSED; } DCHECK_EQ(buffered_spdy_framer_->error_code(), SpdyFramer::SPDY_NO_ERROR); } read_state_ = READ_STATE_DO_READ; return OK; } void SpdySession::PumpWriteLoop(WriteState expected_write_state, int result) { CHECK(!in_io_loop_); DCHECK_EQ(write_state_, expected_write_state); DoWriteLoop(expected_write_state, result); if (availability_state_ == STATE_DRAINING && !in_flight_write_ && write_queue_.IsEmpty()) { pool_->RemoveUnavailableSession(GetWeakPtr()); // Destroys |this|. return; } } int SpdySession::DoWriteLoop(WriteState expected_write_state, int result) { CHECK(!in_io_loop_); DCHECK_NE(write_state_, WRITE_STATE_IDLE); DCHECK_EQ(write_state_, expected_write_state); in_io_loop_ = true; // Loop until the session is closed or the write becomes blocked. while (true) { switch (write_state_) { case WRITE_STATE_DO_WRITE: DCHECK_EQ(result, OK); result = DoWrite(); break; case WRITE_STATE_DO_WRITE_COMPLETE: result = DoWriteComplete(result); break; case WRITE_STATE_IDLE: default: NOTREACHED() << "write_state_: " << write_state_; break; } if (write_state_ == WRITE_STATE_IDLE) { DCHECK_EQ(result, ERR_IO_PENDING); break; } if (result == ERR_IO_PENDING) break; } CHECK(in_io_loop_); in_io_loop_ = false; return result; } int SpdySession::DoWrite() { CHECK(in_io_loop_); DCHECK(buffered_spdy_framer_); if (in_flight_write_) { DCHECK_GT(in_flight_write_->GetRemainingSize(), 0u); } else { // Grab the next frame to send. SpdyFrameType frame_type = DATA; scoped_ptr<SpdyBufferProducer> producer; base::WeakPtr<SpdyStream> stream; if (!write_queue_.Dequeue(&frame_type, &producer, &stream)) { write_state_ = WRITE_STATE_IDLE; return ERR_IO_PENDING; } if (stream.get()) CHECK(!stream->IsClosed()); // Activate the stream only when sending the SYN_STREAM frame to // guarantee monotonically-increasing stream IDs. if (frame_type == SYN_STREAM) { CHECK(stream.get()); CHECK_EQ(stream->stream_id(), 0u); scoped_ptr<SpdyStream> owned_stream = ActivateCreatedStream(stream.get()); InsertActivatedStream(owned_stream.Pass()); if (stream_hi_water_mark_ > kLastStreamId) { CHECK_EQ(stream->stream_id(), kLastStreamId); // We've exhausted the stream ID space, and no new streams may be // created after this one. MakeUnavailable(); StartGoingAway(kLastStreamId, ERR_ABORTED); } } in_flight_write_ = producer->ProduceBuffer(); if (!in_flight_write_) { NOTREACHED(); return ERR_UNEXPECTED; } in_flight_write_frame_type_ = frame_type; in_flight_write_frame_size_ = in_flight_write_->GetRemainingSize(); DCHECK_GE(in_flight_write_frame_size_, buffered_spdy_framer_->GetFrameMinimumSize()); in_flight_write_stream_ = stream; } write_state_ = WRITE_STATE_DO_WRITE_COMPLETE; // Explicitly store in a scoped_refptr<IOBuffer> to avoid problems // with Socket implementations that don't store their IOBuffer // argument in a scoped_refptr<IOBuffer> (see crbug.com/232345). scoped_refptr<IOBuffer> write_io_buffer = in_flight_write_->GetIOBufferForRemainingData(); return connection_->socket()->Write( write_io_buffer.get(), in_flight_write_->GetRemainingSize(), base::Bind(&SpdySession::PumpWriteLoop, weak_factory_.GetWeakPtr(), WRITE_STATE_DO_WRITE_COMPLETE)); } int SpdySession::DoWriteComplete(int result) { CHECK(in_io_loop_); DCHECK_NE(result, ERR_IO_PENDING); DCHECK_GT(in_flight_write_->GetRemainingSize(), 0u); last_activity_time_ = time_func_(); if (result < 0) { DCHECK_NE(result, ERR_IO_PENDING); in_flight_write_.reset(); in_flight_write_frame_type_ = DATA; in_flight_write_frame_size_ = 0; in_flight_write_stream_.reset(); write_state_ = WRITE_STATE_DO_WRITE; DoDrainSession(static_cast<Error>(result), "Write error"); return OK; } // It should not be possible to have written more bytes than our // in_flight_write_. DCHECK_LE(static_cast<size_t>(result), in_flight_write_->GetRemainingSize()); if (result > 0) { in_flight_write_->Consume(static_cast<size_t>(result)); // We only notify the stream when we've fully written the pending frame. if (in_flight_write_->GetRemainingSize() == 0) { // It is possible that the stream was cancelled while we were // writing to the socket. if (in_flight_write_stream_.get()) { DCHECK_GT(in_flight_write_frame_size_, 0u); in_flight_write_stream_->OnFrameWriteComplete( in_flight_write_frame_type_, in_flight_write_frame_size_); } // Cleanup the write which just completed. in_flight_write_.reset(); in_flight_write_frame_type_ = DATA; in_flight_write_frame_size_ = 0; in_flight_write_stream_.reset(); } } write_state_ = WRITE_STATE_DO_WRITE; return OK; } void SpdySession::DcheckGoingAway() const { #if DCHECK_IS_ON DCHECK_GE(availability_state_, STATE_GOING_AWAY); for (int i = MINIMUM_PRIORITY; i <= MAXIMUM_PRIORITY; ++i) { DCHECK(pending_create_stream_queues_[i].empty()); } DCHECK(created_streams_.empty()); #endif } void SpdySession::DcheckDraining() const { DcheckGoingAway(); DCHECK_EQ(availability_state_, STATE_DRAINING); DCHECK(active_streams_.empty()); DCHECK(unclaimed_pushed_streams_.empty()); } void SpdySession::StartGoingAway(SpdyStreamId last_good_stream_id, Error status) { DCHECK_GE(availability_state_, STATE_GOING_AWAY); // The loops below are carefully written to avoid reentrancy problems. while (true) { size_t old_size = GetTotalSize(pending_create_stream_queues_); base::WeakPtr<SpdyStreamRequest> pending_request = GetNextPendingStreamRequest(); if (!pending_request) break; // No new stream requests should be added while the session is // going away. DCHECK_GT(old_size, GetTotalSize(pending_create_stream_queues_)); pending_request->OnRequestCompleteFailure(ERR_ABORTED); } while (true) { size_t old_size = active_streams_.size(); ActiveStreamMap::iterator it = active_streams_.lower_bound(last_good_stream_id + 1); if (it == active_streams_.end()) break; LogAbandonedActiveStream(it, status); CloseActiveStreamIterator(it, status); // No new streams should be activated while the session is going // away. DCHECK_GT(old_size, active_streams_.size()); } while (!created_streams_.empty()) { size_t old_size = created_streams_.size(); CreatedStreamSet::iterator it = created_streams_.begin(); LogAbandonedStream(*it, status); CloseCreatedStreamIterator(it, status); // No new streams should be created while the session is going // away. DCHECK_GT(old_size, created_streams_.size()); } write_queue_.RemovePendingWritesForStreamsAfter(last_good_stream_id); DcheckGoingAway(); } void SpdySession::MaybeFinishGoingAway() { if (active_streams_.empty() && availability_state_ == STATE_GOING_AWAY) { DoDrainSession(OK, "Finished going away"); } } void SpdySession::DoDrainSession(Error err, const std::string& description) { if (availability_state_ == STATE_DRAINING) { return; } MakeUnavailable(); // If |err| indicates an error occurred, inform the peer that we're closing // and why. Don't GOAWAY on a graceful or idle close, as that may // unnecessarily wake the radio. We could technically GOAWAY on network errors // (we'll probably fail to actually write it, but that's okay), however many // unit-tests would need to be updated. if (err != OK && err != ERR_ABORTED && // Used by SpdySessionPool to close idle sessions. err != ERR_NETWORK_CHANGED && // Used to deprecate sessions on IP change. err != ERR_SOCKET_NOT_CONNECTED && err != ERR_CONNECTION_CLOSED && err != ERR_CONNECTION_RESET) { // Enqueue a GOAWAY to inform the peer of why we're closing the connection. SpdyGoAwayIR goaway_ir(0, // Last accepted stream ID. MapNetErrorToGoAwayStatus(err), description); EnqueueSessionWrite(HIGHEST, GOAWAY, scoped_ptr<SpdyFrame>( buffered_spdy_framer_->SerializeFrame(goaway_ir))); } availability_state_ = STATE_DRAINING; error_on_close_ = err; net_log_.AddEvent( NetLog::TYPE_SPDY_SESSION_CLOSE, base::Bind(&NetLogSpdySessionCloseCallback, err, &description)); UMA_HISTOGRAM_SPARSE_SLOWLY("Net.SpdySession.ClosedOnError", -err); UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdySession.BytesRead.OtherErrors", total_bytes_received_, 1, 100000000, 50); if (err == OK) { // We ought to be going away already, as this is a graceful close. DcheckGoingAway(); } else { StartGoingAway(0, err); } DcheckDraining(); MaybePostWriteLoop(); } void SpdySession::LogAbandonedStream(SpdyStream* stream, Error status) { DCHECK(stream); std::string description = base::StringPrintf( "ABANDONED (stream_id=%d): ", stream->stream_id()) + stream->url().spec(); stream->LogStreamError(status, description); // We don't increment the streams abandoned counter here. If the // stream isn't active (i.e., it hasn't written anything to the wire // yet) then it's as if it never existed. If it is active, then // LogAbandonedActiveStream() will increment the counters. } void SpdySession::LogAbandonedActiveStream(ActiveStreamMap::const_iterator it, Error status) { DCHECK_GT(it->first, 0u); LogAbandonedStream(it->second.stream, status); ++streams_abandoned_count_; base::StatsCounter abandoned_streams("spdy.abandoned_streams"); abandoned_streams.Increment(); if (it->second.stream->type() == SPDY_PUSH_STREAM && unclaimed_pushed_streams_.find(it->second.stream->url()) != unclaimed_pushed_streams_.end()) { base::StatsCounter abandoned_push_streams("spdy.abandoned_push_streams"); abandoned_push_streams.Increment(); } } SpdyStreamId SpdySession::GetNewStreamId() { CHECK_LE(stream_hi_water_mark_, kLastStreamId); SpdyStreamId id = stream_hi_water_mark_; stream_hi_water_mark_ += 2; return id; } void SpdySession::CloseSessionOnError(Error err, const std::string& description) { DCHECK_LT(err, ERR_IO_PENDING); DoDrainSession(err, description); } void SpdySession::MakeUnavailable() { if (availability_state_ == STATE_AVAILABLE) { availability_state_ = STATE_GOING_AWAY; pool_->MakeSessionUnavailable(GetWeakPtr()); } } base::Value* SpdySession::GetInfoAsValue() const { base::DictionaryValue* dict = new base::DictionaryValue(); dict->SetInteger("source_id", net_log_.source().id); dict->SetString("host_port_pair", host_port_pair().ToString()); if (!pooled_aliases_.empty()) { base::ListValue* alias_list = new base::ListValue(); for (std::set<SpdySessionKey>::const_iterator it = pooled_aliases_.begin(); it != pooled_aliases_.end(); it++) { alias_list->Append(new base::StringValue( it->host_port_pair().ToString())); } dict->Set("aliases", alias_list); } dict->SetString("proxy", host_port_proxy_pair().second.ToURI()); dict->SetInteger("active_streams", active_streams_.size()); dict->SetInteger("unclaimed_pushed_streams", unclaimed_pushed_streams_.size()); dict->SetBoolean("is_secure", is_secure_); dict->SetString("protocol_negotiated", SSLClientSocket::NextProtoToString( connection_->socket()->GetNegotiatedProtocol())); dict->SetInteger("error", error_on_close_); dict->SetInteger("max_concurrent_streams", max_concurrent_streams_); dict->SetInteger("streams_initiated_count", streams_initiated_count_); dict->SetInteger("streams_pushed_count", streams_pushed_count_); dict->SetInteger("streams_pushed_and_claimed_count", streams_pushed_and_claimed_count_); dict->SetInteger("streams_abandoned_count", streams_abandoned_count_); DCHECK(buffered_spdy_framer_.get()); dict->SetInteger("frames_received", buffered_spdy_framer_->frames_received()); dict->SetBoolean("sent_settings", sent_settings_); dict->SetBoolean("received_settings", received_settings_); dict->SetInteger("send_window_size", session_send_window_size_); dict->SetInteger("recv_window_size", session_recv_window_size_); dict->SetInteger("unacked_recv_window_bytes", session_unacked_recv_window_bytes_); return dict; } bool SpdySession::IsReused() const { return buffered_spdy_framer_->frames_received() > 0 || connection_->reuse_type() == ClientSocketHandle::UNUSED_IDLE; } bool SpdySession::GetLoadTimingInfo(SpdyStreamId stream_id, LoadTimingInfo* load_timing_info) const { return connection_->GetLoadTimingInfo(stream_id != kFirstStreamId, load_timing_info); } int SpdySession::GetPeerAddress(IPEndPoint* address) const { int rv = ERR_SOCKET_NOT_CONNECTED; if (connection_->socket()) { rv = connection_->socket()->GetPeerAddress(address); } UMA_HISTOGRAM_BOOLEAN("Net.SpdySessionSocketNotConnectedGetPeerAddress", rv == ERR_SOCKET_NOT_CONNECTED); return rv; } int SpdySession::GetLocalAddress(IPEndPoint* address) const { int rv = ERR_SOCKET_NOT_CONNECTED; if (connection_->socket()) { rv = connection_->socket()->GetLocalAddress(address); } UMA_HISTOGRAM_BOOLEAN("Net.SpdySessionSocketNotConnectedGetLocalAddress", rv == ERR_SOCKET_NOT_CONNECTED); return rv; } void SpdySession::EnqueueSessionWrite(RequestPriority priority, SpdyFrameType frame_type, scoped_ptr<SpdyFrame> frame) { DCHECK(frame_type == RST_STREAM || frame_type == SETTINGS || frame_type == WINDOW_UPDATE || frame_type == PING || frame_type == GOAWAY); EnqueueWrite( priority, frame_type, scoped_ptr<SpdyBufferProducer>( new SimpleBufferProducer( scoped_ptr<SpdyBuffer>(new SpdyBuffer(frame.Pass())))), base::WeakPtr<SpdyStream>()); } void SpdySession::EnqueueWrite(RequestPriority priority, SpdyFrameType frame_type, scoped_ptr<SpdyBufferProducer> producer, const base::WeakPtr<SpdyStream>& stream) { if (availability_state_ == STATE_DRAINING) return; write_queue_.Enqueue(priority, frame_type, producer.Pass(), stream); MaybePostWriteLoop(); } void SpdySession::MaybePostWriteLoop() { if (write_state_ == WRITE_STATE_IDLE) { CHECK(!in_flight_write_); write_state_ = WRITE_STATE_DO_WRITE; base::MessageLoop::current()->PostTask( FROM_HERE, base::Bind(&SpdySession::PumpWriteLoop, weak_factory_.GetWeakPtr(), WRITE_STATE_DO_WRITE, OK)); } } void SpdySession::InsertCreatedStream(scoped_ptr<SpdyStream> stream) { CHECK_EQ(stream->stream_id(), 0u); CHECK(created_streams_.find(stream.get()) == created_streams_.end()); created_streams_.insert(stream.release()); } scoped_ptr<SpdyStream> SpdySession::ActivateCreatedStream(SpdyStream* stream) { CHECK_EQ(stream->stream_id(), 0u); CHECK(created_streams_.find(stream) != created_streams_.end()); stream->set_stream_id(GetNewStreamId()); scoped_ptr<SpdyStream> owned_stream(stream); created_streams_.erase(stream); return owned_stream.Pass(); } void SpdySession::InsertActivatedStream(scoped_ptr<SpdyStream> stream) { SpdyStreamId stream_id = stream->stream_id(); CHECK_NE(stream_id, 0u); std::pair<ActiveStreamMap::iterator, bool> result = active_streams_.insert( std::make_pair(stream_id, ActiveStreamInfo(stream.get()))); CHECK(result.second); ignore_result(stream.release()); } void SpdySession::DeleteStream(scoped_ptr<SpdyStream> stream, int status) { if (in_flight_write_stream_.get() == stream.get()) { // If we're deleting the stream for the in-flight write, we still // need to let the write complete, so we clear // |in_flight_write_stream_| and let the write finish on its own // without notifying |in_flight_write_stream_|. in_flight_write_stream_.reset(); } write_queue_.RemovePendingWritesForStream(stream->GetWeakPtr()); stream->OnClose(status); if (availability_state_ == STATE_AVAILABLE) { ProcessPendingStreamRequests(); } } base::WeakPtr<SpdyStream> SpdySession::GetActivePushStream(const GURL& url) { base::StatsCounter used_push_streams("spdy.claimed_push_streams"); PushedStreamMap::iterator unclaimed_it = unclaimed_pushed_streams_.find(url); if (unclaimed_it == unclaimed_pushed_streams_.end()) return base::WeakPtr<SpdyStream>(); SpdyStreamId stream_id = unclaimed_it->second.stream_id; unclaimed_pushed_streams_.erase(unclaimed_it); ActiveStreamMap::iterator active_it = active_streams_.find(stream_id); if (active_it == active_streams_.end()) { NOTREACHED(); return base::WeakPtr<SpdyStream>(); } net_log_.AddEvent(NetLog::TYPE_SPDY_STREAM_ADOPTED_PUSH_STREAM); used_push_streams.Increment(); return active_it->second.stream->GetWeakPtr(); } bool SpdySession::GetSSLInfo(SSLInfo* ssl_info, bool* was_npn_negotiated, NextProto* protocol_negotiated) { *was_npn_negotiated = connection_->socket()->WasNpnNegotiated(); *protocol_negotiated = connection_->socket()->GetNegotiatedProtocol(); return connection_->socket()->GetSSLInfo(ssl_info); } bool SpdySession::GetSSLCertRequestInfo( SSLCertRequestInfo* cert_request_info) { if (!is_secure_) return false; GetSSLClientSocket()->GetSSLCertRequestInfo(cert_request_info); return true; } void SpdySession::OnError(SpdyFramer::SpdyError error_code) { CHECK(in_io_loop_); RecordProtocolErrorHistogram(MapFramerErrorToProtocolError(error_code)); std::string description = base::StringPrintf("Framer error: %d (%s).", error_code, SpdyFramer::ErrorCodeToString(error_code)); DoDrainSession(MapFramerErrorToNetError(error_code), description); } void SpdySession::OnStreamError(SpdyStreamId stream_id, const std::string& description) { CHECK(in_io_loop_); ActiveStreamMap::iterator it = active_streams_.find(stream_id); if (it == active_streams_.end()) { // We still want to send a frame to reset the stream even if we // don't know anything about it. EnqueueResetStreamFrame( stream_id, IDLE, RST_STREAM_PROTOCOL_ERROR, description); return; } ResetStreamIterator(it, RST_STREAM_PROTOCOL_ERROR, description); } void SpdySession::OnDataFrameHeader(SpdyStreamId stream_id, size_t length, bool fin) { CHECK(in_io_loop_); ActiveStreamMap::iterator it = active_streams_.find(stream_id); // By the time data comes in, the stream may already be inactive. if (it == active_streams_.end()) return; SpdyStream* stream = it->second.stream; CHECK_EQ(stream->stream_id(), stream_id); DCHECK(buffered_spdy_framer_); size_t header_len = buffered_spdy_framer_->GetDataFrameMinimumSize(); stream->IncrementRawReceivedBytes(header_len); } void SpdySession::OnStreamFrameData(SpdyStreamId stream_id, const char* data, size_t len, bool fin) { CHECK(in_io_loop_); if (data == NULL && len != 0) { // This is notification of consumed data padding. // TODO(jgraettinger): Properly flow padding into WINDOW_UPDATE frames. // See crbug.com/353012. return; } DCHECK_LT(len, 1u << 24); if (net_log().IsLogging()) { net_log().AddEvent( NetLog::TYPE_SPDY_SESSION_RECV_DATA, base::Bind(&NetLogSpdyDataCallback, stream_id, len, fin)); } // Build the buffer as early as possible so that we go through the // session flow control checks and update // |unacked_recv_window_bytes_| properly even when the stream is // inactive (since the other side has still reduced its session send // window). scoped_ptr<SpdyBuffer> buffer; if (data) { DCHECK_GT(len, 0u); CHECK_LE(len, static_cast<size_t>(kReadBufferSize)); buffer.reset(new SpdyBuffer(data, len)); if (flow_control_state_ == FLOW_CONTROL_STREAM_AND_SESSION) { DecreaseRecvWindowSize(static_cast<int32>(len)); buffer->AddConsumeCallback( base::Bind(&SpdySession::OnReadBufferConsumed, weak_factory_.GetWeakPtr())); } } else { DCHECK_EQ(len, 0u); } ActiveStreamMap::iterator it = active_streams_.find(stream_id); // By the time data comes in, the stream may already be inactive. if (it == active_streams_.end()) return; SpdyStream* stream = it->second.stream; CHECK_EQ(stream->stream_id(), stream_id); stream->IncrementRawReceivedBytes(len); if (it->second.waiting_for_syn_reply) { const std::string& error = "Data received before SYN_REPLY."; stream->LogStreamError(ERR_SPDY_PROTOCOL_ERROR, error); ResetStreamIterator(it, RST_STREAM_PROTOCOL_ERROR, error); return; } stream->OnDataReceived(buffer.Pass()); } void SpdySession::OnSettings(bool clear_persisted) { CHECK(in_io_loop_); if (clear_persisted) http_server_properties_->ClearSpdySettings(host_port_pair()); if (net_log_.IsLogging()) { net_log_.AddEvent( NetLog::TYPE_SPDY_SESSION_RECV_SETTINGS, base::Bind(&NetLogSpdySettingsCallback, host_port_pair(), clear_persisted)); } if (GetProtocolVersion() >= SPDY4) { // Send an acknowledgment of the setting. SpdySettingsIR settings_ir; settings_ir.set_is_ack(true); EnqueueSessionWrite( HIGHEST, SETTINGS, scoped_ptr<SpdyFrame>( buffered_spdy_framer_->SerializeFrame(settings_ir))); } } void SpdySession::OnSetting(SpdySettingsIds id, uint8 flags, uint32 value) { CHECK(in_io_loop_); HandleSetting(id, value); http_server_properties_->SetSpdySetting( host_port_pair(), id, static_cast<SpdySettingsFlags>(flags), value); received_settings_ = true; // Log the setting. net_log_.AddEvent( NetLog::TYPE_SPDY_SESSION_RECV_SETTING, base::Bind(&NetLogSpdySettingCallback, id, static_cast<SpdySettingsFlags>(flags), value)); } void SpdySession::OnSendCompressedFrame( SpdyStreamId stream_id, SpdyFrameType type, size_t payload_len, size_t frame_len) { if (type != SYN_STREAM) return; DCHECK(buffered_spdy_framer_.get()); size_t compressed_len = frame_len - buffered_spdy_framer_->GetSynStreamMinimumSize(); if (payload_len) { // Make sure we avoid early decimal truncation. int compression_pct = 100 - (100 * compressed_len) / payload_len; UMA_HISTOGRAM_PERCENTAGE("Net.SpdySynStreamCompressionPercentage", compression_pct); } } void SpdySession::OnReceiveCompressedFrame( SpdyStreamId stream_id, SpdyFrameType type, size_t frame_len) { last_compressed_frame_len_ = frame_len; } int SpdySession::OnInitialResponseHeadersReceived( const SpdyHeaderBlock& response_headers, base::Time response_time, base::TimeTicks recv_first_byte_time, SpdyStream* stream) { CHECK(in_io_loop_); SpdyStreamId stream_id = stream->stream_id(); // May invalidate |stream|. int rv = stream->OnInitialResponseHeadersReceived( response_headers, response_time, recv_first_byte_time); if (rv < 0) { DCHECK_NE(rv, ERR_IO_PENDING); DCHECK(active_streams_.find(stream_id) == active_streams_.end()); } return rv; } void SpdySession::OnSynStream(SpdyStreamId stream_id, SpdyStreamId associated_stream_id, SpdyPriority priority, bool fin, bool unidirectional, const SpdyHeaderBlock& headers) { CHECK(in_io_loop_); if (GetProtocolVersion() >= SPDY4) { DCHECK_EQ(0u, associated_stream_id); OnHeaders(stream_id, fin, headers); return; } base::Time response_time = base::Time::Now(); base::TimeTicks recv_first_byte_time = time_func_(); if (net_log_.IsLogging()) { net_log_.AddEvent( NetLog::TYPE_SPDY_SESSION_PUSHED_SYN_STREAM, base::Bind(&NetLogSpdySynStreamReceivedCallback, &headers, fin, unidirectional, priority, stream_id, associated_stream_id)); } // Split headers to simulate push promise and response. SpdyHeaderBlock request_headers; SpdyHeaderBlock response_headers; SplitPushedHeadersToRequestAndResponse( headers, GetProtocolVersion(), &request_headers, &response_headers); if (!TryCreatePushStream( stream_id, associated_stream_id, priority, request_headers)) return; ActiveStreamMap::iterator active_it = active_streams_.find(stream_id); if (active_it == active_streams_.end()) { NOTREACHED(); return; } if (OnInitialResponseHeadersReceived(response_headers, response_time, recv_first_byte_time, active_it->second.stream) != OK) return; base::StatsCounter push_requests("spdy.pushed_streams"); push_requests.Increment(); } void SpdySession::DeleteExpiredPushedStreams() { if (unclaimed_pushed_streams_.empty()) return; // Check that adequate time has elapsed since the last sweep. if (time_func_() < next_unclaimed_push_stream_sweep_time_) return; // Gather old streams to delete. base::TimeTicks minimum_freshness = time_func_() - base::TimeDelta::FromSeconds(kMinPushedStreamLifetimeSeconds); std::vector<SpdyStreamId> streams_to_close; for (PushedStreamMap::iterator it = unclaimed_pushed_streams_.begin(); it != unclaimed_pushed_streams_.end(); ++it) { if (minimum_freshness > it->second.creation_time) streams_to_close.push_back(it->second.stream_id); } for (std::vector<SpdyStreamId>::const_iterator to_close_it = streams_to_close.begin(); to_close_it != streams_to_close.end(); ++to_close_it) { ActiveStreamMap::iterator active_it = active_streams_.find(*to_close_it); if (active_it == active_streams_.end()) continue; LogAbandonedActiveStream(active_it, ERR_INVALID_SPDY_STREAM); // CloseActiveStreamIterator() will remove the stream from // |unclaimed_pushed_streams_|. ResetStreamIterator( active_it, RST_STREAM_REFUSED_STREAM, "Stream not claimed."); } next_unclaimed_push_stream_sweep_time_ = time_func_() + base::TimeDelta::FromSeconds(kMinPushedStreamLifetimeSeconds); } void SpdySession::OnSynReply(SpdyStreamId stream_id, bool fin, const SpdyHeaderBlock& headers) { CHECK(in_io_loop_); base::Time response_time = base::Time::Now(); base::TimeTicks recv_first_byte_time = time_func_(); if (net_log().IsLogging()) { net_log().AddEvent( NetLog::TYPE_SPDY_SESSION_SYN_REPLY, base::Bind(&NetLogSpdySynReplyOrHeadersReceivedCallback, &headers, fin, stream_id)); } ActiveStreamMap::iterator it = active_streams_.find(stream_id); if (it == active_streams_.end()) { // NOTE: it may just be that the stream was cancelled. return; } SpdyStream* stream = it->second.stream; CHECK_EQ(stream->stream_id(), stream_id); stream->IncrementRawReceivedBytes(last_compressed_frame_len_); last_compressed_frame_len_ = 0; if (GetProtocolVersion() >= SPDY4) { const std::string& error = "SPDY4 wasn't expecting SYN_REPLY."; stream->LogStreamError(ERR_SPDY_PROTOCOL_ERROR, error); ResetStreamIterator(it, RST_STREAM_PROTOCOL_ERROR, error); return; } if (!it->second.waiting_for_syn_reply) { const std::string& error = "Received duplicate SYN_REPLY for stream."; stream->LogStreamError(ERR_SPDY_PROTOCOL_ERROR, error); ResetStreamIterator(it, RST_STREAM_PROTOCOL_ERROR, error); return; } it->second.waiting_for_syn_reply = false; ignore_result(OnInitialResponseHeadersReceived( headers, response_time, recv_first_byte_time, stream)); } void SpdySession::OnHeaders(SpdyStreamId stream_id, bool fin, const SpdyHeaderBlock& headers) { CHECK(in_io_loop_); if (net_log().IsLogging()) { net_log().AddEvent( NetLog::TYPE_SPDY_SESSION_RECV_HEADERS, base::Bind(&NetLogSpdySynReplyOrHeadersReceivedCallback, &headers, fin, stream_id)); } ActiveStreamMap::iterator it = active_streams_.find(stream_id); if (it == active_streams_.end()) { // NOTE: it may just be that the stream was cancelled. LOG(WARNING) << "Received HEADERS for invalid stream " << stream_id; return; } SpdyStream* stream = it->second.stream; CHECK_EQ(stream->stream_id(), stream_id); stream->IncrementRawReceivedBytes(last_compressed_frame_len_); last_compressed_frame_len_ = 0; base::Time response_time = base::Time::Now(); base::TimeTicks recv_first_byte_time = time_func_(); if (it->second.waiting_for_syn_reply) { if (GetProtocolVersion() < SPDY4) { const std::string& error = "Was expecting SYN_REPLY, not HEADERS."; stream->LogStreamError(ERR_SPDY_PROTOCOL_ERROR, error); ResetStreamIterator(it, RST_STREAM_PROTOCOL_ERROR, error); return; } it->second.waiting_for_syn_reply = false; ignore_result(OnInitialResponseHeadersReceived( headers, response_time, recv_first_byte_time, stream)); } else if (it->second.stream->IsReservedRemote()) { ignore_result(OnInitialResponseHeadersReceived( headers, response_time, recv_first_byte_time, stream)); } else { int rv = stream->OnAdditionalResponseHeadersReceived(headers); if (rv < 0) { DCHECK_NE(rv, ERR_IO_PENDING); DCHECK(active_streams_.find(stream_id) == active_streams_.end()); } } } void SpdySession::OnRstStream(SpdyStreamId stream_id, SpdyRstStreamStatus status) { CHECK(in_io_loop_); std::string description; net_log().AddEvent( NetLog::TYPE_SPDY_SESSION_RST_STREAM, base::Bind(&NetLogSpdyRstCallback, stream_id, status, &description)); ActiveStreamMap::iterator it = active_streams_.find(stream_id); if (it == active_streams_.end()) { // NOTE: it may just be that the stream was cancelled. LOG(WARNING) << "Received RST for invalid stream" << stream_id; return; } CHECK_EQ(it->second.stream->stream_id(), stream_id); if (status == 0) { it->second.stream->OnDataReceived(scoped_ptr<SpdyBuffer>()); } else if (status == RST_STREAM_REFUSED_STREAM) { CloseActiveStreamIterator(it, ERR_SPDY_SERVER_REFUSED_STREAM); } else { RecordProtocolErrorHistogram( PROTOCOL_ERROR_RST_STREAM_FOR_NON_ACTIVE_STREAM); it->second.stream->LogStreamError( ERR_SPDY_PROTOCOL_ERROR, base::StringPrintf("SPDY stream closed with status: %d", status)); // TODO(mbelshe): Map from Spdy-protocol errors to something sensical. // For now, it doesn't matter much - it is a protocol error. CloseActiveStreamIterator(it, ERR_SPDY_PROTOCOL_ERROR); } } void SpdySession::OnGoAway(SpdyStreamId last_accepted_stream_id, SpdyGoAwayStatus status) { CHECK(in_io_loop_); // TODO(jgraettinger): UMA histogram on |status|. net_log_.AddEvent(NetLog::TYPE_SPDY_SESSION_GOAWAY, base::Bind(&NetLogSpdyGoAwayCallback, last_accepted_stream_id, active_streams_.size(), unclaimed_pushed_streams_.size(), status)); MakeUnavailable(); StartGoingAway(last_accepted_stream_id, ERR_ABORTED); // This is to handle the case when we already don't have any active // streams (i.e., StartGoingAway() did nothing). Otherwise, we have // active streams and so the last one being closed will finish the // going away process (see DeleteStream()). MaybeFinishGoingAway(); } void SpdySession::OnPing(SpdyPingId unique_id, bool is_ack) { CHECK(in_io_loop_); net_log_.AddEvent( NetLog::TYPE_SPDY_SESSION_PING, base::Bind(&NetLogSpdyPingCallback, unique_id, is_ack, "received")); // Send response to a PING from server. if ((protocol_ >= kProtoSPDY4 && !is_ack) || (protocol_ < kProtoSPDY4 && unique_id % 2 == 0)) { WritePingFrame(unique_id, true); return; } --pings_in_flight_; if (pings_in_flight_ < 0) { RecordProtocolErrorHistogram(PROTOCOL_ERROR_UNEXPECTED_PING); DoDrainSession(ERR_SPDY_PROTOCOL_ERROR, "pings_in_flight_ is < 0."); pings_in_flight_ = 0; return; } if (pings_in_flight_ > 0) return; // We will record RTT in histogram when there are no more client sent // pings_in_flight_. RecordPingRTTHistogram(time_func_() - last_ping_sent_time_); } void SpdySession::OnWindowUpdate(SpdyStreamId stream_id, uint32 delta_window_size) { CHECK(in_io_loop_); DCHECK_LE(delta_window_size, static_cast<uint32>(kint32max)); net_log_.AddEvent( NetLog::TYPE_SPDY_SESSION_RECEIVED_WINDOW_UPDATE_FRAME, base::Bind(&NetLogSpdyWindowUpdateFrameCallback, stream_id, delta_window_size)); if (stream_id == kSessionFlowControlStreamId) { // WINDOW_UPDATE for the session. if (flow_control_state_ < FLOW_CONTROL_STREAM_AND_SESSION) { LOG(WARNING) << "Received WINDOW_UPDATE for session when " << "session flow control is not turned on"; // TODO(akalin): Record an error and close the session. return; } if (delta_window_size < 1u) { RecordProtocolErrorHistogram(PROTOCOL_ERROR_INVALID_WINDOW_UPDATE_SIZE); DoDrainSession( ERR_SPDY_PROTOCOL_ERROR, "Received WINDOW_UPDATE with an invalid delta_window_size " + base::UintToString(delta_window_size)); return; } IncreaseSendWindowSize(static_cast<int32>(delta_window_size)); } else { // WINDOW_UPDATE for a stream. if (flow_control_state_ < FLOW_CONTROL_STREAM) { // TODO(akalin): Record an error and close the session. LOG(WARNING) << "Received WINDOW_UPDATE for stream " << stream_id << " when flow control is not turned on"; return; } ActiveStreamMap::iterator it = active_streams_.find(stream_id); if (it == active_streams_.end()) { // NOTE: it may just be that the stream was cancelled. LOG(WARNING) << "Received WINDOW_UPDATE for invalid stream " << stream_id; return; } SpdyStream* stream = it->second.stream; CHECK_EQ(stream->stream_id(), stream_id); if (delta_window_size < 1u) { ResetStreamIterator(it, RST_STREAM_FLOW_CONTROL_ERROR, base::StringPrintf( "Received WINDOW_UPDATE with an invalid " "delta_window_size %ud", delta_window_size)); return; } CHECK_EQ(it->second.stream->stream_id(), stream_id); it->second.stream->IncreaseSendWindowSize( static_cast<int32>(delta_window_size)); } } bool SpdySession::TryCreatePushStream(SpdyStreamId stream_id, SpdyStreamId associated_stream_id, SpdyPriority priority, const SpdyHeaderBlock& headers) { // Server-initiated streams should have even sequence numbers. if ((stream_id & 0x1) != 0) { LOG(WARNING) << "Received invalid push stream id " << stream_id; return false; } if (IsStreamActive(stream_id)) { LOG(WARNING) << "Received push for active stream " << stream_id; return false; } RequestPriority request_priority = ConvertSpdyPriorityToRequestPriority(priority, GetProtocolVersion()); if (availability_state_ == STATE_GOING_AWAY) { // TODO(akalin): This behavior isn't in the SPDY spec, although it // probably should be. EnqueueResetStreamFrame(stream_id, request_priority, RST_STREAM_REFUSED_STREAM, "push stream request received when going away"); return false; } if (associated_stream_id == 0) { // In SPDY4 0 stream id in PUSH_PROMISE frame leads to framer error and // session going away. We should never get here. CHECK_GT(SPDY4, GetProtocolVersion()); std::string description = base::StringPrintf( "Received invalid associated stream id %d for pushed stream %d", associated_stream_id, stream_id); EnqueueResetStreamFrame( stream_id, request_priority, RST_STREAM_REFUSED_STREAM, description); return false; } streams_pushed_count_++; // TODO(mbelshe): DCHECK that this is a GET method? // Verify that the response had a URL for us. GURL gurl = GetUrlFromHeaderBlock(headers, GetProtocolVersion(), true); if (!gurl.is_valid()) { EnqueueResetStreamFrame(stream_id, request_priority, RST_STREAM_PROTOCOL_ERROR, "Pushed stream url was invalid: " + gurl.spec()); return false; } // Verify we have a valid stream association. ActiveStreamMap::iterator associated_it = active_streams_.find(associated_stream_id); if (associated_it == active_streams_.end()) { EnqueueResetStreamFrame( stream_id, request_priority, RST_STREAM_INVALID_STREAM, base::StringPrintf("Received push for inactive associated stream %d", associated_stream_id)); return false; } // Check that the pushed stream advertises the same origin as its associated // stream. Bypass this check if and only if this session is with a SPDY proxy // that is trusted explicitly via the --trusted-spdy-proxy switch. if (trusted_spdy_proxy_.Equals(host_port_pair())) { // Disallow pushing of HTTPS content. if (gurl.SchemeIs("https")) { EnqueueResetStreamFrame( stream_id, request_priority, RST_STREAM_REFUSED_STREAM, base::StringPrintf("Rejected push of Cross Origin HTTPS content %d", associated_stream_id)); } } else { GURL associated_url(associated_it->second.stream->GetUrlFromHeaders()); if (associated_url.GetOrigin() != gurl.GetOrigin()) { EnqueueResetStreamFrame( stream_id, request_priority, RST_STREAM_REFUSED_STREAM, base::StringPrintf("Rejected Cross Origin Push Stream %d", associated_stream_id)); return false; } } // There should not be an existing pushed stream with the same path. PushedStreamMap::iterator pushed_it = unclaimed_pushed_streams_.lower_bound(gurl); if (pushed_it != unclaimed_pushed_streams_.end() && pushed_it->first == gurl) { EnqueueResetStreamFrame( stream_id, request_priority, RST_STREAM_PROTOCOL_ERROR, "Received duplicate pushed stream with url: " + gurl.spec()); return false; } scoped_ptr<SpdyStream> stream(new SpdyStream(SPDY_PUSH_STREAM, GetWeakPtr(), gurl, request_priority, stream_initial_send_window_size_, stream_initial_recv_window_size_, net_log_)); stream->set_stream_id(stream_id); // In spdy4/http2 PUSH_PROMISE arrives on associated stream. if (associated_it != active_streams_.end() && GetProtocolVersion() >= SPDY4) { associated_it->second.stream->IncrementRawReceivedBytes( last_compressed_frame_len_); } else { stream->IncrementRawReceivedBytes(last_compressed_frame_len_); } last_compressed_frame_len_ = 0; DeleteExpiredPushedStreams(); PushedStreamMap::iterator inserted_pushed_it = unclaimed_pushed_streams_.insert( pushed_it, std::make_pair(gurl, PushedStreamInfo(stream_id, time_func_()))); DCHECK(inserted_pushed_it != pushed_it); InsertActivatedStream(stream.Pass()); ActiveStreamMap::iterator active_it = active_streams_.find(stream_id); if (active_it == active_streams_.end()) { NOTREACHED(); return false; } active_it->second.stream->OnPushPromiseHeadersReceived(headers); DCHECK(active_it->second.stream->IsReservedRemote()); return true; } void SpdySession::OnPushPromise(SpdyStreamId stream_id, SpdyStreamId promised_stream_id, const SpdyHeaderBlock& headers) { CHECK(in_io_loop_); if (net_log_.IsLogging()) { net_log_.AddEvent(NetLog::TYPE_SPDY_SESSION_RECV_PUSH_PROMISE, base::Bind(&NetLogSpdyPushPromiseReceivedCallback, &headers, stream_id, promised_stream_id)); } // Any priority will do. // TODO(baranovich): pass parent stream id priority? if (!TryCreatePushStream(promised_stream_id, stream_id, 0, headers)) return; base::StatsCounter push_requests("spdy.pushed_streams"); push_requests.Increment(); } void SpdySession::SendStreamWindowUpdate(SpdyStreamId stream_id, uint32 delta_window_size) { CHECK_GE(flow_control_state_, FLOW_CONTROL_STREAM); ActiveStreamMap::const_iterator it = active_streams_.find(stream_id); CHECK(it != active_streams_.end()); CHECK_EQ(it->second.stream->stream_id(), stream_id); SendWindowUpdateFrame( stream_id, delta_window_size, it->second.stream->priority()); } void SpdySession::SendInitialData() { DCHECK(enable_sending_initial_data_); if (send_connection_header_prefix_) { DCHECK_EQ(protocol_, kProtoSPDY4); scoped_ptr<SpdyFrame> connection_header_prefix_frame( new SpdyFrame(const_cast<char*>(kHttp2ConnectionHeaderPrefix), kHttp2ConnectionHeaderPrefixSize, false /* take_ownership */)); // Count the prefix as part of the subsequent SETTINGS frame. EnqueueSessionWrite(HIGHEST, SETTINGS, connection_header_prefix_frame.Pass()); } // First, notify the server about the settings they should use when // communicating with us. SettingsMap settings_map; // Create a new settings frame notifying the server of our // max concurrent streams and initial window size. settings_map[SETTINGS_MAX_CONCURRENT_STREAMS] = SettingsFlagsAndValue(SETTINGS_FLAG_NONE, kMaxConcurrentPushedStreams); if (flow_control_state_ >= FLOW_CONTROL_STREAM && stream_initial_recv_window_size_ != kSpdyStreamInitialWindowSize) { settings_map[SETTINGS_INITIAL_WINDOW_SIZE] = SettingsFlagsAndValue(SETTINGS_FLAG_NONE, stream_initial_recv_window_size_); } SendSettings(settings_map); // Next, notify the server about our initial recv window size. if (flow_control_state_ == FLOW_CONTROL_STREAM_AND_SESSION) { // Bump up the receive window size to the real initial value. This // has to go here since the WINDOW_UPDATE frame sent by // IncreaseRecvWindowSize() call uses |buffered_spdy_framer_|. DCHECK_GT(kDefaultInitialRecvWindowSize, session_recv_window_size_); // This condition implies that |kDefaultInitialRecvWindowSize| - // |session_recv_window_size_| doesn't overflow. DCHECK_GT(session_recv_window_size_, 0); IncreaseRecvWindowSize( kDefaultInitialRecvWindowSize - session_recv_window_size_); } // Finally, notify the server about the settings they have // previously told us to use when communicating with them (after // applying them). const SettingsMap& server_settings_map = http_server_properties_->GetSpdySettings(host_port_pair()); if (server_settings_map.empty()) return; SettingsMap::const_iterator it = server_settings_map.find(SETTINGS_CURRENT_CWND); uint32 cwnd = (it != server_settings_map.end()) ? it->second.second : 0; UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdySettingsCwndSent", cwnd, 1, 200, 100); for (SettingsMap::const_iterator it = server_settings_map.begin(); it != server_settings_map.end(); ++it) { const SpdySettingsIds new_id = it->first; const uint32 new_val = it->second.second; HandleSetting(new_id, new_val); } SendSettings(server_settings_map); } void SpdySession::SendSettings(const SettingsMap& settings) { net_log_.AddEvent( NetLog::TYPE_SPDY_SESSION_SEND_SETTINGS, base::Bind(&NetLogSpdySendSettingsCallback, &settings)); // Create the SETTINGS frame and send it. DCHECK(buffered_spdy_framer_.get()); scoped_ptr<SpdyFrame> settings_frame( buffered_spdy_framer_->CreateSettings(settings)); sent_settings_ = true; EnqueueSessionWrite(HIGHEST, SETTINGS, settings_frame.Pass()); } void SpdySession::HandleSetting(uint32 id, uint32 value) { switch (id) { case SETTINGS_MAX_CONCURRENT_STREAMS: max_concurrent_streams_ = std::min(static_cast<size_t>(value), kMaxConcurrentStreamLimit); ProcessPendingStreamRequests(); break; case SETTINGS_INITIAL_WINDOW_SIZE: { if (flow_control_state_ < FLOW_CONTROL_STREAM) { net_log().AddEvent( NetLog::TYPE_SPDY_SESSION_INITIAL_WINDOW_SIZE_NO_FLOW_CONTROL); return; } if (value > static_cast<uint32>(kint32max)) { net_log().AddEvent( NetLog::TYPE_SPDY_SESSION_INITIAL_WINDOW_SIZE_OUT_OF_RANGE, NetLog::IntegerCallback("initial_window_size", value)); return; } // SETTINGS_INITIAL_WINDOW_SIZE updates initial_send_window_size_ only. int32 delta_window_size = static_cast<int32>(value) - stream_initial_send_window_size_; stream_initial_send_window_size_ = static_cast<int32>(value); UpdateStreamsSendWindowSize(delta_window_size); net_log().AddEvent( NetLog::TYPE_SPDY_SESSION_UPDATE_STREAMS_SEND_WINDOW_SIZE, NetLog::IntegerCallback("delta_window_size", delta_window_size)); break; } } } void SpdySession::UpdateStreamsSendWindowSize(int32 delta_window_size) { DCHECK_GE(flow_control_state_, FLOW_CONTROL_STREAM); for (ActiveStreamMap::iterator it = active_streams_.begin(); it != active_streams_.end(); ++it) { it->second.stream->AdjustSendWindowSize(delta_window_size); } for (CreatedStreamSet::const_iterator it = created_streams_.begin(); it != created_streams_.end(); it++) { (*it)->AdjustSendWindowSize(delta_window_size); } } void SpdySession::SendPrefacePingIfNoneInFlight() { if (pings_in_flight_ || !enable_ping_based_connection_checking_) return; base::TimeTicks now = time_func_(); // If there is no activity in the session, then send a preface-PING. if ((now - last_activity_time_) > connection_at_risk_of_loss_time_) SendPrefacePing(); } void SpdySession::SendPrefacePing() { WritePingFrame(next_ping_id_, false); } void SpdySession::SendWindowUpdateFrame(SpdyStreamId stream_id, uint32 delta_window_size, RequestPriority priority) { CHECK_GE(flow_control_state_, FLOW_CONTROL_STREAM); ActiveStreamMap::const_iterator it = active_streams_.find(stream_id); if (it != active_streams_.end()) { CHECK_EQ(it->second.stream->stream_id(), stream_id); } else { CHECK_EQ(flow_control_state_, FLOW_CONTROL_STREAM_AND_SESSION); CHECK_EQ(stream_id, kSessionFlowControlStreamId); } net_log_.AddEvent( NetLog::TYPE_SPDY_SESSION_SENT_WINDOW_UPDATE_FRAME, base::Bind(&NetLogSpdyWindowUpdateFrameCallback, stream_id, delta_window_size)); DCHECK(buffered_spdy_framer_.get()); scoped_ptr<SpdyFrame> window_update_frame( buffered_spdy_framer_->CreateWindowUpdate(stream_id, delta_window_size)); EnqueueSessionWrite(priority, WINDOW_UPDATE, window_update_frame.Pass()); } void SpdySession::WritePingFrame(uint32 unique_id, bool is_ack) { DCHECK(buffered_spdy_framer_.get()); scoped_ptr<SpdyFrame> ping_frame( buffered_spdy_framer_->CreatePingFrame(unique_id, is_ack)); EnqueueSessionWrite(HIGHEST, PING, ping_frame.Pass()); if (net_log().IsLogging()) { net_log().AddEvent( NetLog::TYPE_SPDY_SESSION_PING, base::Bind(&NetLogSpdyPingCallback, unique_id, is_ack, "sent")); } if (!is_ack) { next_ping_id_ += 2; ++pings_in_flight_; PlanToCheckPingStatus(); last_ping_sent_time_ = time_func_(); } } void SpdySession::PlanToCheckPingStatus() { if (check_ping_status_pending_) return; check_ping_status_pending_ = true; base::MessageLoop::current()->PostDelayedTask( FROM_HERE, base::Bind(&SpdySession::CheckPingStatus, weak_factory_.GetWeakPtr(), time_func_()), hung_interval_); } void SpdySession::CheckPingStatus(base::TimeTicks last_check_time) { CHECK(!in_io_loop_); // Check if we got a response back for all PINGs we had sent. if (pings_in_flight_ == 0) { check_ping_status_pending_ = false; return; } DCHECK(check_ping_status_pending_); base::TimeTicks now = time_func_(); base::TimeDelta delay = hung_interval_ - (now - last_activity_time_); if (delay.InMilliseconds() < 0 || last_activity_time_ < last_check_time) { // Track all failed PING messages in a separate bucket. RecordPingRTTHistogram(base::TimeDelta::Max()); DoDrainSession(ERR_SPDY_PING_FAILED, "Failed ping."); return; } // Check the status of connection after a delay. base::MessageLoop::current()->PostDelayedTask( FROM_HERE, base::Bind(&SpdySession::CheckPingStatus, weak_factory_.GetWeakPtr(), now), delay); } void SpdySession::RecordPingRTTHistogram(base::TimeDelta duration) { UMA_HISTOGRAM_TIMES("Net.SpdyPing.RTT", duration); } void SpdySession::RecordProtocolErrorHistogram( SpdyProtocolErrorDetails details) { UMA_HISTOGRAM_ENUMERATION("Net.SpdySessionErrorDetails2", details, NUM_SPDY_PROTOCOL_ERROR_DETAILS); if (EndsWith(host_port_pair().host(), "google.com", false)) { UMA_HISTOGRAM_ENUMERATION("Net.SpdySessionErrorDetails_Google2", details, NUM_SPDY_PROTOCOL_ERROR_DETAILS); } } void SpdySession::RecordHistograms() { UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdyStreamsPerSession", streams_initiated_count_, 0, 300, 50); UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdyStreamsPushedPerSession", streams_pushed_count_, 0, 300, 50); UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdyStreamsPushedAndClaimedPerSession", streams_pushed_and_claimed_count_, 0, 300, 50); UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdyStreamsAbandonedPerSession", streams_abandoned_count_, 0, 300, 50); UMA_HISTOGRAM_ENUMERATION("Net.SpdySettingsSent", sent_settings_ ? 1 : 0, 2); UMA_HISTOGRAM_ENUMERATION("Net.SpdySettingsReceived", received_settings_ ? 1 : 0, 2); UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdyStreamStallsPerSession", stalled_streams_, 0, 300, 50); UMA_HISTOGRAM_ENUMERATION("Net.SpdySessionsWithStalls", stalled_streams_ > 0 ? 1 : 0, 2); if (received_settings_) { // Enumerate the saved settings, and set histograms for it. const SettingsMap& settings_map = http_server_properties_->GetSpdySettings(host_port_pair()); SettingsMap::const_iterator it; for (it = settings_map.begin(); it != settings_map.end(); ++it) { const SpdySettingsIds id = it->first; const uint32 val = it->second.second; switch (id) { case SETTINGS_CURRENT_CWND: // Record several different histograms to see if cwnd converges // for larger volumes of data being sent. UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdySettingsCwnd", val, 1, 200, 100); if (total_bytes_received_ > 10 * 1024) { UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdySettingsCwnd10K", val, 1, 200, 100); if (total_bytes_received_ > 25 * 1024) { UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdySettingsCwnd25K", val, 1, 200, 100); if (total_bytes_received_ > 50 * 1024) { UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdySettingsCwnd50K", val, 1, 200, 100); if (total_bytes_received_ > 100 * 1024) { UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdySettingsCwnd100K", val, 1, 200, 100); } } } } break; case SETTINGS_ROUND_TRIP_TIME: UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdySettingsRTT", val, 1, 1200, 100); break; case SETTINGS_DOWNLOAD_RETRANS_RATE: UMA_HISTOGRAM_CUSTOM_COUNTS("Net.SpdySettingsRetransRate", val, 1, 100, 50); break; default: break; } } } } void SpdySession::CompleteStreamRequest( const base::WeakPtr<SpdyStreamRequest>& pending_request) { // Abort if the request has already been cancelled. if (!pending_request) return; base::WeakPtr<SpdyStream> stream; int rv = TryCreateStream(pending_request, &stream); if (rv == OK) { DCHECK(stream); pending_request->OnRequestCompleteSuccess(stream); return; } DCHECK(!stream); if (rv != ERR_IO_PENDING) { pending_request->OnRequestCompleteFailure(rv); } } SSLClientSocket* SpdySession::GetSSLClientSocket() const { if (!is_secure_) return NULL; SSLClientSocket* ssl_socket = reinterpret_cast<SSLClientSocket*>(connection_->socket()); DCHECK(ssl_socket); return ssl_socket; } void SpdySession::OnWriteBufferConsumed( size_t frame_payload_size, size_t consume_size, SpdyBuffer::ConsumeSource consume_source) { // We can be called with |in_io_loop_| set if a write SpdyBuffer is // deleted (e.g., a stream is closed due to incoming data). DCHECK_EQ(flow_control_state_, FLOW_CONTROL_STREAM_AND_SESSION); 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 session soon.) size_t remaining_payload_bytes = std::min(consume_size, frame_payload_size); DCHECK_GT(remaining_payload_bytes, 0u); IncreaseSendWindowSize(static_cast<int32>(remaining_payload_bytes)); } // For consumed bytes, the send window is increased when we receive // a WINDOW_UPDATE frame. } void SpdySession::IncreaseSendWindowSize(int32 delta_window_size) { // We can be called with |in_io_loop_| set if a SpdyBuffer is // deleted (e.g., a stream is closed due to incoming data). DCHECK_EQ(flow_control_state_, FLOW_CONTROL_STREAM_AND_SESSION); DCHECK_GE(delta_window_size, 1); // Check for overflow. int32 max_delta_window_size = kint32max - session_send_window_size_; if (delta_window_size > max_delta_window_size) { RecordProtocolErrorHistogram(PROTOCOL_ERROR_INVALID_WINDOW_UPDATE_SIZE); DoDrainSession( ERR_SPDY_PROTOCOL_ERROR, "Received WINDOW_UPDATE [delta: " + base::IntToString(delta_window_size) + "] for session overflows session_send_window_size_ [current: " + base::IntToString(session_send_window_size_) + "]"); return; } session_send_window_size_ += delta_window_size; net_log_.AddEvent( NetLog::TYPE_SPDY_SESSION_UPDATE_SEND_WINDOW, base::Bind(&NetLogSpdySessionWindowUpdateCallback, delta_window_size, session_send_window_size_)); DCHECK(!IsSendStalled()); ResumeSendStalledStreams(); } void SpdySession::DecreaseSendWindowSize(int32 delta_window_size) { DCHECK_EQ(flow_control_state_, FLOW_CONTROL_STREAM_AND_SESSION); // 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(session_send_window_size_, delta_window_size); session_send_window_size_ -= delta_window_size; net_log_.AddEvent( NetLog::TYPE_SPDY_SESSION_UPDATE_SEND_WINDOW, base::Bind(&NetLogSpdySessionWindowUpdateCallback, -delta_window_size, session_send_window_size_)); } void SpdySession::OnReadBufferConsumed( size_t consume_size, SpdyBuffer::ConsumeSource consume_source) { // We can be called with |in_io_loop_| set if a read SpdyBuffer is // deleted (e.g., discarded by a SpdyReadQueue). DCHECK_EQ(flow_control_state_, FLOW_CONTROL_STREAM_AND_SESSION); DCHECK_GE(consume_size, 1u); DCHECK_LE(consume_size, static_cast<size_t>(kint32max)); IncreaseRecvWindowSize(static_cast<int32>(consume_size)); } void SpdySession::IncreaseRecvWindowSize(int32 delta_window_size) { DCHECK_EQ(flow_control_state_, FLOW_CONTROL_STREAM_AND_SESSION); DCHECK_GE(session_unacked_recv_window_bytes_, 0); DCHECK_GE(session_recv_window_size_, session_unacked_recv_window_bytes_); DCHECK_GE(delta_window_size, 1); // Check for overflow. DCHECK_LE(delta_window_size, kint32max - session_recv_window_size_); session_recv_window_size_ += delta_window_size; net_log_.AddEvent( NetLog::TYPE_SPDY_STREAM_UPDATE_RECV_WINDOW, base::Bind(&NetLogSpdySessionWindowUpdateCallback, delta_window_size, session_recv_window_size_)); session_unacked_recv_window_bytes_ += delta_window_size; if (session_unacked_recv_window_bytes_ > kSpdySessionInitialWindowSize / 2) { SendWindowUpdateFrame(kSessionFlowControlStreamId, session_unacked_recv_window_bytes_, HIGHEST); session_unacked_recv_window_bytes_ = 0; } } void SpdySession::DecreaseRecvWindowSize(int32 delta_window_size) { CHECK(in_io_loop_); DCHECK_EQ(flow_control_state_, FLOW_CONTROL_STREAM_AND_SESSION); DCHECK_GE(delta_window_size, 1); // Since we never decrease the initial receive window size, // |delta_window_size| should never cause |recv_window_size_| to go // negative. If we do, the receive window isn't being respected. if (delta_window_size > session_recv_window_size_) { RecordProtocolErrorHistogram(PROTOCOL_ERROR_RECEIVE_WINDOW_VIOLATION); DoDrainSession( 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(session_recv_window_size_)); return; } session_recv_window_size_ -= delta_window_size; net_log_.AddEvent( NetLog::TYPE_SPDY_SESSION_UPDATE_RECV_WINDOW, base::Bind(&NetLogSpdySessionWindowUpdateCallback, -delta_window_size, session_recv_window_size_)); } void SpdySession::QueueSendStalledStream(const SpdyStream& stream) { DCHECK(stream.send_stalled_by_flow_control()); RequestPriority priority = stream.priority(); CHECK_GE(priority, MINIMUM_PRIORITY); CHECK_LE(priority, MAXIMUM_PRIORITY); stream_send_unstall_queue_[priority].push_back(stream.stream_id()); } void SpdySession::ResumeSendStalledStreams() { DCHECK_EQ(flow_control_state_, FLOW_CONTROL_STREAM_AND_SESSION); // We don't have to worry about new streams being queued, since // doing so would cause IsSendStalled() to return true. But we do // have to worry about streams being closed, as well as ourselves // being closed. while (!IsSendStalled()) { size_t old_size = 0; #if DCHECK_IS_ON old_size = GetTotalSize(stream_send_unstall_queue_); #endif SpdyStreamId stream_id = PopStreamToPossiblyResume(); if (stream_id == 0) break; ActiveStreamMap::const_iterator it = active_streams_.find(stream_id); // The stream may actually still be send-stalled after this (due // to its own send window) but that's okay -- it'll then be // resumed once its send window increases. if (it != active_streams_.end()) it->second.stream->PossiblyResumeIfSendStalled(); // The size should decrease unless we got send-stalled again. if (!IsSendStalled()) DCHECK_LT(GetTotalSize(stream_send_unstall_queue_), old_size); } } SpdyStreamId SpdySession::PopStreamToPossiblyResume() { for (int i = MAXIMUM_PRIORITY; i >= MINIMUM_PRIORITY; --i) { std::deque<SpdyStreamId>* queue = &stream_send_unstall_queue_[i]; if (!queue->empty()) { SpdyStreamId stream_id = queue->front(); queue->pop_front(); return stream_id; } } return 0; } } // namespace net