/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set sw=2 ts=8 et tw=80 : */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ // HttpLog.h should generally be included first #include "HttpLog.h" // Log on level :5, instead of default :4. #undef LOG #define LOG(args) LOG5(args) #undef LOG_ENABLED #define LOG_ENABLED() LOG5_ENABLED() #include #include "Http2Push.h" #include "nsHttpChannel.h" #include "nsIHttpPushListener.h" #include "nsString.h" namespace mozilla { namespace net { class CallChannelOnPush final : public Runnable { public: CallChannelOnPush(nsIHttpChannelInternal *associatedChannel, const nsACString &pushedURI, Http2PushedStream *pushStream) : mAssociatedChannel(associatedChannel) , mPushedURI(pushedURI) , mPushedStream(pushStream) { } NS_IMETHOD Run() override { MOZ_ASSERT(NS_IsMainThread()); RefPtr channel; CallQueryInterface(mAssociatedChannel, channel.StartAssignment()); MOZ_ASSERT(channel); if (channel && NS_SUCCEEDED(channel->OnPush(mPushedURI, mPushedStream))) { return NS_OK; } LOG3(("Http2PushedStream Orphan %p failed OnPush\n", this)); mPushedStream->OnPushFailed(); return NS_OK; } private: nsCOMPtr mAssociatedChannel; const nsCString mPushedURI; Http2PushedStream *mPushedStream; }; ////////////////////////////////////////// // Http2PushedStream ////////////////////////////////////////// Http2PushedStream::Http2PushedStream(Http2PushTransactionBuffer *aTransaction, Http2Session *aSession, Http2Stream *aAssociatedStream, uint32_t aID) :Http2Stream(aTransaction, aSession, 0) , mConsumerStream(nullptr) , mAssociatedTransaction(aAssociatedStream->Transaction()) , mBufferedPush(aTransaction) , mStatus(NS_OK) , mPushCompleted(false) , mDeferCleanupOnSuccess(true) , mDeferCleanupOnPush(false) , mOnPushFailed(false) { LOG3(("Http2PushedStream ctor this=%p 0x%X\n", this, aID)); mStreamID = aID; MOZ_ASSERT(!(aID & 1)); // must be even to be a pushed stream mBufferedPush->SetPushStream(this); mRequestContext = aAssociatedStream->RequestContext(); mLastRead = TimeStamp::Now(); SetPriority(aAssociatedStream->Priority() + 1); } bool Http2PushedStream::GetPushComplete() { return mPushCompleted; } nsresult Http2PushedStream::WriteSegments(nsAHttpSegmentWriter *writer, uint32_t count, uint32_t *countWritten) { nsresult rv = Http2Stream::WriteSegments(writer, count, countWritten); if (NS_SUCCEEDED(rv) && *countWritten) { mLastRead = TimeStamp::Now(); } if (rv == NS_BASE_STREAM_CLOSED) { mPushCompleted = true; rv = NS_OK; // this is what a normal HTTP transaction would do } if (rv != NS_BASE_STREAM_WOULD_BLOCK && NS_FAILED(rv)) mStatus = rv; return rv; } bool Http2PushedStream::DeferCleanup(nsresult status) { LOG3(("Http2PushedStream::DeferCleanup Query %p %x\n", this, status)); if (NS_SUCCEEDED(status) && mDeferCleanupOnSuccess) { LOG3(("Http2PushedStream::DeferCleanup %p %x defer on success\n", this, status)); return true; } if (mDeferCleanupOnPush) { LOG3(("Http2PushedStream::DeferCleanup %p %x defer onPush ref\n", this, status)); return true; } if (mConsumerStream) { LOG3(("Http2PushedStream::DeferCleanup %p %x defer active consumer\n", this, status)); return true; } LOG3(("Http2PushedStream::DeferCleanup Query %p %x not deferred\n", this, status)); return false; } // return true if channel implements nsIHttpPushListener bool Http2PushedStream::TryOnPush() { nsHttpTransaction *trans = mAssociatedTransaction->QueryHttpTransaction(); if (!trans) { return false; } nsCOMPtr associatedChannel = do_QueryInterface(trans->HttpChannel()); if (!associatedChannel) { return false; } if (!(trans->Caps() & NS_HTTP_ONPUSH_LISTENER)) { return false; } mDeferCleanupOnPush = true; nsCString uri = Origin() + Path(); NS_DispatchToMainThread(new CallChannelOnPush(associatedChannel, uri, this)); return true; } // side effect free static method to determine if Http2Stream implements nsIHttpPushListener bool Http2PushedStream::TestOnPush(Http2Stream *stream) { if (!stream) { return false; } nsAHttpTransaction *abstractTransaction = stream->Transaction(); if (!abstractTransaction) { return false; } nsHttpTransaction *trans = abstractTransaction->QueryHttpTransaction(); if (!trans) { return false; } nsCOMPtr associatedChannel = do_QueryInterface(trans->HttpChannel()); if (!associatedChannel) { return false; } return (trans->Caps() & NS_HTTP_ONPUSH_LISTENER); } nsresult Http2PushedStream::ReadSegments(nsAHttpSegmentReader *reader, uint32_t, uint32_t *count) { nsresult rv = NS_OK; *count = 0; switch (mUpstreamState) { case GENERATING_HEADERS: // The request headers for this has been processed, so we need to verify // that :authority, :scheme, and :path MUST be present. :method MUST NOT be // present CreatePushHashKey(mHeaderScheme, mHeaderHost, mSession->Serial(), mHeaderPath, mOrigin, mHashKey); LOG3(("Http2PushStream 0x%X hash key %s\n", mStreamID, mHashKey.get())); // the write side of a pushed transaction just involves manipulating a little state SetSentFin(true); Http2Stream::mRequestHeadersDone = 1; Http2Stream::mOpenGenerated = 1; Http2Stream::ChangeState(UPSTREAM_COMPLETE); break; case UPSTREAM_COMPLETE: // Let's just clear the stream's transmit buffer by pushing it into // the session. This is probably a window adjustment. LOG3(("Http2Push::ReadSegments 0x%X \n", mStreamID)); mSegmentReader = reader; rv = TransmitFrame(nullptr, nullptr, true); mSegmentReader = nullptr; break; case GENERATING_BODY: case SENDING_BODY: case SENDING_FIN_STREAM: default: break; } return rv; } void Http2PushedStream::AdjustInitialWindow() { LOG3(("Http2PushStream %p 0x%X AdjustInitialWindow", this, mStreamID)); if (mConsumerStream) { LOG3(("Http2PushStream::AdjustInitialWindow %p 0x%X " "calling super consumer %p 0x%X\n", this, mStreamID, mConsumerStream, mConsumerStream->StreamID())); Http2Stream::AdjustInitialWindow(); // Http2PushedStream::ReadSegments is needed to call TransmitFrame() // and actually get this information into the session bytestream mSession->TransactionHasDataToWrite(this); } // Otherwise, when we get hooked up, the initial window will get bumped // anyway, so we're good to go. } void Http2PushedStream::SetConsumerStream(Http2Stream *consumer) { mConsumerStream = consumer; mDeferCleanupOnPush = false; } bool Http2PushedStream::GetHashKey(nsCString &key) { if (mHashKey.IsEmpty()) return false; key = mHashKey; return true; } void Http2PushedStream::ConnectPushedStream(Http2Stream *stream) { mSession->ConnectPushedStream(stream); } bool Http2PushedStream::IsOrphaned(TimeStamp now) { MOZ_ASSERT(!now.IsNull()); // if session is not transmitting, and is also not connected to a consumer // stream, and its been like that for too long then it is oprhaned if (mConsumerStream || mDeferCleanupOnPush) { return false; } if (mOnPushFailed) { return true; } bool rv = ((now - mLastRead).ToSeconds() > 30.0); if (rv) { LOG3(("Http2PushedStream:IsOrphaned 0x%X IsOrphaned %3.2f\n", mStreamID, (now - mLastRead).ToSeconds())); } return rv; } nsresult Http2PushedStream::GetBufferedData(char *buf, uint32_t count, uint32_t *countWritten) { if (NS_FAILED(mStatus)) return mStatus; nsresult rv = mBufferedPush->GetBufferedData(buf, count, countWritten); if (NS_FAILED(rv)) return rv; if (!*countWritten) rv = GetPushComplete() ? NS_BASE_STREAM_CLOSED : NS_BASE_STREAM_WOULD_BLOCK; return rv; } ////////////////////////////////////////// // Http2PushTransactionBuffer // This is the nsAHttpTransction owned by the stream when the pushed // stream has not yet been matched with a pull request ////////////////////////////////////////// NS_IMPL_ISUPPORTS0(Http2PushTransactionBuffer) Http2PushTransactionBuffer::Http2PushTransactionBuffer() : mStatus(NS_OK) , mRequestHead(nullptr) , mPushStream(nullptr) , mIsDone(false) , mBufferedHTTP1Size(kDefaultBufferSize) , mBufferedHTTP1Used(0) , mBufferedHTTP1Consumed(0) { mBufferedHTTP1 = MakeUnique(mBufferedHTTP1Size); } Http2PushTransactionBuffer::~Http2PushTransactionBuffer() { delete mRequestHead; } void Http2PushTransactionBuffer::SetConnection(nsAHttpConnection *conn) { } nsAHttpConnection * Http2PushTransactionBuffer::Connection() { return nullptr; } void Http2PushTransactionBuffer::GetSecurityCallbacks(nsIInterfaceRequestor **outCB) { *outCB = nullptr; } void Http2PushTransactionBuffer::OnTransportStatus(nsITransport* transport, nsresult status, int64_t progress) { } nsHttpConnectionInfo * Http2PushTransactionBuffer::ConnectionInfo() { if (!mPushStream) { return nullptr; } if (!mPushStream->Transaction()) { return nullptr; } MOZ_ASSERT(mPushStream->Transaction() != this); return mPushStream->Transaction()->ConnectionInfo(); } bool Http2PushTransactionBuffer::IsDone() { return mIsDone; } nsresult Http2PushTransactionBuffer::Status() { return mStatus; } uint32_t Http2PushTransactionBuffer::Caps() { return 0; } void Http2PushTransactionBuffer::SetDNSWasRefreshed() { } uint64_t Http2PushTransactionBuffer::Available() { return mBufferedHTTP1Used - mBufferedHTTP1Consumed; } nsresult Http2PushTransactionBuffer::ReadSegments(nsAHttpSegmentReader *reader, uint32_t count, uint32_t *countRead) { *countRead = 0; return NS_ERROR_NOT_IMPLEMENTED; } nsresult Http2PushTransactionBuffer::WriteSegments(nsAHttpSegmentWriter *writer, uint32_t count, uint32_t *countWritten) { if ((mBufferedHTTP1Size - mBufferedHTTP1Used) < 20480) { EnsureBuffer(mBufferedHTTP1,mBufferedHTTP1Size + kDefaultBufferSize, mBufferedHTTP1Used, mBufferedHTTP1Size); } count = std::min(count, mBufferedHTTP1Size - mBufferedHTTP1Used); nsresult rv = writer->OnWriteSegment(&mBufferedHTTP1[mBufferedHTTP1Used], count, countWritten); if (NS_SUCCEEDED(rv)) { mBufferedHTTP1Used += *countWritten; } else if (rv == NS_BASE_STREAM_CLOSED) { mIsDone = true; } if (Available() || mIsDone) { Http2Stream *consumer = mPushStream->GetConsumerStream(); if (consumer) { LOG3(("Http2PushTransactionBuffer::WriteSegments notifying connection " "consumer data available 0x%X [%u] done=%d\n", mPushStream->StreamID(), Available(), mIsDone)); mPushStream->ConnectPushedStream(consumer); } } return rv; } uint32_t Http2PushTransactionBuffer::Http1xTransactionCount() { return 0; } nsHttpRequestHead * Http2PushTransactionBuffer::RequestHead() { if (!mRequestHead) mRequestHead = new nsHttpRequestHead(); return mRequestHead; } nsresult Http2PushTransactionBuffer::TakeSubTransactions( nsTArray > &outTransactions) { return NS_ERROR_NOT_IMPLEMENTED; } void Http2PushTransactionBuffer::SetProxyConnectFailed() { } void Http2PushTransactionBuffer::Close(nsresult reason) { mStatus = reason; mIsDone = true; } nsresult Http2PushTransactionBuffer::AddTransaction(nsAHttpTransaction *trans) { return NS_ERROR_NOT_IMPLEMENTED; } uint32_t Http2PushTransactionBuffer::PipelineDepth() { return 0; } nsresult Http2PushTransactionBuffer::SetPipelinePosition(int32_t position) { return NS_OK; } int32_t Http2PushTransactionBuffer::PipelinePosition() { return 1; } nsresult Http2PushTransactionBuffer::GetBufferedData(char *buf, uint32_t count, uint32_t *countWritten) { *countWritten = std::min(count, static_cast(Available())); if (*countWritten) { memcpy(buf, &mBufferedHTTP1[mBufferedHTTP1Consumed], *countWritten); mBufferedHTTP1Consumed += *countWritten; } // If all the data has been consumed then reset the buffer if (mBufferedHTTP1Consumed == mBufferedHTTP1Used) { mBufferedHTTP1Consumed = 0; mBufferedHTTP1Used = 0; } return NS_OK; } } // namespace net } // namespace mozilla