/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* 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/. */ #ifndef nsHttpTransaction_h__ #define nsHttpTransaction_h__ #include "nsHttp.h" #include "nsHttpHeaderArray.h" #include "nsAHttpTransaction.h" #include "nsAHttpConnection.h" #include "EventTokenBucket.h" #include "nsCOMPtr.h" #include "nsIPipe.h" #include "nsIInputStream.h" #include "nsILoadGroup.h" #include "nsIOutputStream.h" #include "nsIInterfaceRequestor.h" #include "nsISocketTransportService.h" #include "nsITransport.h" #include "nsIEventTarget.h" #include "TimingStruct.h" //----------------------------------------------------------------------------- class nsHttpRequestHead; class nsHttpResponseHead; class nsHttpChunkedDecoder; class nsIHttpActivityObserver; class UpdateSecurityCallbacks; //----------------------------------------------------------------------------- // nsHttpTransaction represents a single HTTP transaction. It is thread-safe, // intended to run on the socket thread. //----------------------------------------------------------------------------- class nsHttpTransaction : public nsAHttpTransaction , public mozilla::net::ATokenBucketEvent , public nsIInputStreamCallback , public nsIOutputStreamCallback { public: NS_DECL_ISUPPORTS NS_DECL_NSAHTTPTRANSACTION NS_DECL_NSIINPUTSTREAMCALLBACK NS_DECL_NSIOUTPUTSTREAMCALLBACK nsHttpTransaction(); virtual ~nsHttpTransaction(); // // called to initialize the transaction // // @param caps // the transaction capabilities (see nsHttp.h) // @param connInfo // the connection type for this transaction. // @param reqHeaders // the request header struct // @param reqBody // the request body (POST or PUT data stream) // @param reqBodyIncludesHeaders // fun stuff to support NPAPI plugins. // @param target // the dispatch target were notifications should be sent. // @param callbacks // the notification callbacks to be given to PSM. // @param responseBody // the input stream that will contain the response data. async // wait on this input stream for data. on first notification, // headers should be available (check transaction status). // nsresult Init(uint32_t caps, nsHttpConnectionInfo *connInfo, nsHttpRequestHead *reqHeaders, nsIInputStream *reqBody, bool reqBodyIncludesHeaders, nsIEventTarget *consumerTarget, nsIInterfaceRequestor *callbacks, nsITransportEventSink *eventsink, nsIAsyncInputStream **responseBody); // attributes nsHttpConnectionInfo *ConnectionInfo() { return mConnInfo; } nsHttpResponseHead *ResponseHead() { return mHaveAllHeaders ? mResponseHead : nullptr; } nsISupports *SecurityInfo() { return mSecurityInfo; } nsIEventTarget *ConsumerTarget() { return mConsumerTarget; } void SetSecurityCallbacks(nsIInterfaceRequestor* aCallbacks); // Called to take ownership of the response headers; the transaction // will drop any reference to the response headers after this call. nsHttpResponseHead *TakeResponseHead(); // Called to find out if the transaction generated a complete response. bool ResponseIsComplete() { return mResponseIsComplete; } bool ProxyConnectFailed() { return mProxyConnectFailed; } // SetPriority() may only be used by the connection manager. void SetPriority(int32_t priority) { mPriority = priority; } int32_t Priority() { return mPriority; } const TimingStruct& Timings() const { return mTimings; } enum Classifier Classification() { return mClassification; } void PrintDiagnostics(nsCString &log); // Sets mPendingTime to the current time stamp or to a null time stamp (if now is false) void SetPendingTime(bool now = true) { mPendingTime = now ? mozilla::TimeStamp::Now() : mozilla::TimeStamp(); } const mozilla::TimeStamp GetPendingTime() { return mPendingTime; } bool UsesPipelining() const { return mCaps & NS_HTTP_ALLOW_PIPELINING; } // overload of nsAHttpTransaction::LoadGroupConnectionInfo() nsILoadGroupConnectionInfo *LoadGroupConnectionInfo() { return mLoadGroupCI.get(); } void SetLoadGroupConnectionInfo(nsILoadGroupConnectionInfo *aLoadGroupCI) { mLoadGroupCI = aLoadGroupCI; } void DispatchedAsBlocking(); void RemoveDispatchedAsBlocking(); private: nsresult Restart(); nsresult RestartInProgress(); char *LocateHttpStart(char *buf, uint32_t len, bool aAllowPartialMatch); nsresult ParseLine(char *line); nsresult ParseLineSegment(char *seg, uint32_t len); nsresult ParseHead(char *, uint32_t count, uint32_t *countRead); nsresult HandleContentStart(); nsresult HandleContent(char *, uint32_t count, uint32_t *contentRead, uint32_t *contentRemaining); nsresult ProcessData(char *, uint32_t, uint32_t *); void DeleteSelfOnConsumerThread(); void ReleaseBlockingTransaction(); Classifier Classify(); void CancelPipeline(uint32_t reason); static NS_METHOD ReadRequestSegment(nsIInputStream *, void *, const char *, uint32_t, uint32_t, uint32_t *); static NS_METHOD WritePipeSegment(nsIOutputStream *, void *, char *, uint32_t, uint32_t, uint32_t *); bool TimingEnabled() const { return mCaps & NS_HTTP_TIMING_ENABLED; } private: class UpdateSecurityCallbacks : public nsRunnable { public: UpdateSecurityCallbacks(nsHttpTransaction* aTrans, nsIInterfaceRequestor* aCallbacks) : mTrans(aTrans), mCallbacks(aCallbacks) {} NS_IMETHOD Run() { if (mTrans->mConnection) mTrans->mConnection->SetSecurityCallbacks(mCallbacks); return NS_OK; } private: nsRefPtr mTrans; nsCOMPtr mCallbacks; }; mozilla::Mutex mCallbacksLock; nsCOMPtr mCallbacks; nsCOMPtr mTransportSink; nsCOMPtr mConsumerTarget; nsCOMPtr mSecurityInfo; nsCOMPtr mPipeIn; nsCOMPtr mPipeOut; nsCOMPtr mLoadGroupCI; nsCOMPtr mChannel; nsCOMPtr mActivityDistributor; nsCString mReqHeaderBuf; // flattened request headers nsCOMPtr mRequestStream; uint64_t mRequestSize; nsAHttpConnection *mConnection; // hard ref nsHttpConnectionInfo *mConnInfo; // hard ref nsHttpRequestHead *mRequestHead; // weak ref nsHttpResponseHead *mResponseHead; // hard ref nsAHttpSegmentReader *mReader; nsAHttpSegmentWriter *mWriter; nsCString mLineBuf; // may contain a partial line int64_t mContentLength; // equals -1 if unknown int64_t mContentRead; // count of consumed content bytes // After a 304/204 or other "no-content" style response we will skip over // up to MAX_INVALID_RESPONSE_BODY_SZ bytes when looking for the next // response header to deal with servers that actually sent a response // body where they should not have. This member tracks how many bytes have // so far been skipped. uint32_t mInvalidResponseBytesRead; nsHttpChunkedDecoder *mChunkedDecoder; TimingStruct mTimings; nsresult mStatus; int16_t mPriority; uint16_t mRestartCount; // the number of times this transaction has been restarted uint32_t mCaps; enum Classifier mClassification; int32_t mPipelinePosition; int64_t mMaxPipelineObjectSize; nsHttpVersion mHttpVersion; // state flags, all logically boolean, but not packed together into a // bitfield so as to avoid bitfield-induced races. See bug 560579. bool mClosed; bool mConnected; bool mHaveStatusLine; bool mHaveAllHeaders; bool mTransactionDone; bool mResponseIsComplete; bool mDidContentStart; bool mNoContent; // expecting an empty entity body bool mSentData; bool mReceivedData; bool mStatusEventPending; bool mHasRequestBody; bool mProxyConnectFailed; bool mHttpResponseMatched; bool mPreserveStream; bool mDispatchedAsBlocking; // mClosed := transaction has been explicitly closed // mTransactionDone := transaction ran to completion or was interrupted // mResponseComplete := transaction ran to completion // For Restart-In-Progress Functionality bool mReportedStart; bool mReportedResponseHeader; // protected by nsHttp::GetLock() nsHttpResponseHead *mForTakeResponseHead; bool mResponseHeadTaken; // The time when the transaction was submitted to the Connection Manager mozilla::TimeStamp mPendingTime; class RestartVerifier { // When a idemptotent transaction has received part of its response body // and incurs an error it can be restarted. To do this we mark the place // where we stopped feeding the body to the consumer and start the // network call over again. If everything we track (headers, length, etc..) // matches up to the place where we left off then the consumer starts being // fed data again with the new information. This can be done N times up // to the normal restart (i.e. with no response info) limit. public: RestartVerifier() : mContentLength(-1) , mAlreadyProcessed(0) , mToReadBeforeRestart(0) , mSetup(false) {} ~RestartVerifier() {} void Set(int64_t contentLength, nsHttpResponseHead *head); bool Verify(int64_t contentLength, nsHttpResponseHead *head); bool IsDiscardingContent() { return mToReadBeforeRestart != 0; } bool IsSetup() { return mSetup; } int64_t AlreadyProcessed() { return mAlreadyProcessed; } void SetAlreadyProcessed(int64_t val) { mAlreadyProcessed = val; mToReadBeforeRestart = val; } int64_t ToReadBeforeRestart() { return mToReadBeforeRestart; } void HaveReadBeforeRestart(uint32_t amt) { MOZ_ASSERT(amt <= mToReadBeforeRestart, "too large of a HaveReadBeforeRestart deduction"); mToReadBeforeRestart -= amt; } private: // This is the data from the first complete response header // used to make sure that all subsequent response headers match int64_t mContentLength; nsCString mETag; nsCString mLastModified; nsCString mContentRange; nsCString mContentEncoding; nsCString mTransferEncoding; // This is the amount of data that has been passed to the channel // from previous iterations of the transaction and must therefore // be skipped in the new one. int64_t mAlreadyProcessed; // The amount of data that must be discarded in the current iteration // (where iteration > 0) to reach the mAlreadyProcessed high water // mark. int64_t mToReadBeforeRestart; // true when ::Set has been called with a response header bool mSetup; } mRestartInProgressVerifier; // For Rate Pacing via an EventTokenBucket public: // called by the connection manager to run this transaction through the // token bucket. If the token bucket admits the transaction immediately it // returns true. The function is called repeatedly until it returns true. bool TryToRunPacedRequest(); // ATokenBucketEvent pure virtual implementation. Called by the token bucket // when the transaction is ready to run. If this happens asynchrounously to // token bucket submission the transaction just posts an event that causes // the pending transaction queue to be rerun (and TryToRunPacedRequest() to // be run again. void OnTokenBucketAdmitted(); // ATokenBucketEvent // CancelPacing() can be used to tell the token bucket to remove this // transaction from the list of pending transactions. This is used when a // transaction is believed to be HTTP/1 (and thus subject to rate pacing) // but later can be dispatched via spdy (not subject to rate pacing). void CancelPacing(nsresult reason); private: bool mSubmittedRatePacing; bool mPassedRatePacing; bool mSynchronousRatePaceRequest; nsCOMPtr mTokenBucketCancel; }; #endif // nsHttpTransaction_h__