/* -*- 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/. */ #ifndef mozilla_net_InterceptedHttpChannel_h #define mozilla_net_InterceptedHttpChannel_h #include "HttpBaseChannel.h" #include "nsIAsyncVerifyRedirectCallback.h" #include "nsINetworkInterceptController.h" #include "nsIInputStream.h" #include "nsICacheInfoChannel.h" #include "nsIThreadRetargetableRequest.h" #include "nsIThreadRetargetableStreamListener.h" namespace mozilla::net { // This class represents an http channel that is being intercepted by a // ServiceWorker. This means that when the channel is opened a FetchEvent // will be fired on the ServiceWorker thread. The channel will complete // depending on what the worker does. The options are: // // 1. If the ServiceWorker does not handle the FetchEvent or does not call // FetchEvent.respondWith(), then the channel needs to fall back to a // normal request. When this happens ResetInterception() is called and // the channel will perform an internal redirect back to an nsHttpChannel. // // 2. If the ServiceWorker provides a Response to FetchEvent.respondWith() // then the status, headers, and body must be synthesized. When // FinishSynthesizedResponse() is called the synthesized data must be // reported back to the channel listener. This is handled in a few // different ways: // a. If a redirect was synthesized, then we perform the redirect to // a new nsHttpChannel. This new channel might trigger yet another // interception. // b. If a same-origin or CORS Response was synthesized, then we simply // crate an nsInputStreamPump to process it and call back to the // listener. // c. If an opaque Response was synthesized, then we perform an internal // redirect to a new InterceptedHttpChannel using the cross-origin URL. // When this new channel is opened, it then creates a pump as in case // (b). The extra redirect here is to make sure the various listeners // treat the result as unsafe cross-origin data. // // 3. If an error occurs, such as the ServiceWorker passing garbage to // FetchEvent.respondWith(), then CancelInterception() is called. This is // handled the same as a normal nsIChannel::Cancel() call. We abort the // channel and end up calling OnStopRequest() with an error code. class InterceptedHttpChannel final : public HttpBaseChannel, public HttpAsyncAborter, public nsIInterceptedChannel, public nsICacheInfoChannel, public nsIAsyncVerifyRedirectCallback, public nsIThreadRetargetableRequest, public nsIThreadRetargetableStreamListener { NS_DECL_ISUPPORTS_INHERITED NS_DECL_NSIINTERCEPTEDCHANNEL NS_DECL_NSICACHEINFOCHANNEL NS_DECL_NSIASYNCVERIFYREDIRECTCALLBACK NS_DECL_NSIREQUESTOBSERVER NS_DECL_NSISTREAMLISTENER NS_DECL_NSITHREADRETARGETABLEREQUEST NS_DECL_NSITHREADRETARGETABLESTREAMLISTENER private: friend class HttpAsyncAborter; UniquePtr mSynthesizedResponseHead; nsCOMPtr mRedirectChannel; nsCOMPtr mBodyReader; nsCOMPtr mReleaseHandle; nsCOMPtr mProgressSink; nsCOMPtr mBodyCallback; nsCOMPtr mSynthesizedCacheInfo; RefPtr mPump; TimeStamp mInterceptedChannelCreationTimestamp; // For the profiler markers TimeStamp mLastStatusReported; Atomic mProgress; int64_t mProgressReported; int64_t mSynthesizedStreamLength; uint64_t mResumeStartPos; nsCString mResumeEntityId; nsString mStatusHost; Atomic mCallingStatusAndProgress; bool mInterceptionReset{false}; /** * InterceptionTimeStamps is used to record the time stamps of the * interception. * The general usage: * Step 1. Initialize the InterceptionTimeStamps; * InterceptionTimeStamps::Init(channel); * Step 2. Record time for each stage * InterceptionTimeStamps::RecordTime(); or * InterceptionTimeStamps::RecordTime(timeStamp); * Step 3. Record time for the last stage with the final status * InterceptionTimeStamps::RecordTime(InterceptionTimeStamps::Synthesized); */ class InterceptionTimeStamps final { public: // The possible status of the interception. enum Status { Created, Initialized, Synthesized, Reset, Redirected, Canceled, CanceledAfterSynthesized, CanceledAfterReset, CanceledAfterRedirected }; InterceptionTimeStamps(); ~InterceptionTimeStamps() = default; /** * Initialize with the given channel. * This method should be called before any RecordTime(). */ void Init(nsIChannel* aChannel); /** * Record the given time stamp for current stage. If there is no given time * stamp, TimeStamp::Now() will be recorded. * The current stage is auto moved to the next one. */ void RecordTime(TimeStamp&& aTimeStamp = TimeStamp::Now()); /** * Record the given time stamp for the last stage(InterceptionFinish) and * set the final status to the given status. * If these is no given time stamp, TimeStamp::Now() will be recorded. * Notice that this method is for the last stage, it calls SaveTimeStamps() * to write data into telemetries. */ void RecordTime(Status&& aStatus, TimeStamp&& aTimeStamp = TimeStamp::Now()); // The time stamp which the intercepted channel is created and async opend. TimeStamp mInterceptionStart; // The time stamp which the interception finishes. TimeStamp mInterceptionFinish; // The time stamp which the fetch event starts to be handled by fetch event // handler. TimeStamp mFetchHandlerStart; // The time stamp which the fetch event handling finishes. It would the time // which remote worker sends result back. TimeStamp mFetchHandlerFinish; private: // The stage of interception. enum Stage { InterceptionStart, FetchHandlerStart, FetchHandlerFinish, InterceptionFinish } mStage; // The final status of the interception. Status mStatus; bool mIsNonSubresourceRequest; // The keys used for telemetries. nsCString mKey; nsCString mSubresourceKey; void RecordTimeInternal(TimeStamp&& aTimeStamp); // Generate the record keys with final status. void GenKeysWithStatus(nsCString& aKey, nsCString& aSubresourceKey); // Save the time stamps into telemetries. void SaveTimeStamps(); }; InterceptionTimeStamps mTimeStamps; InterceptedHttpChannel(PRTime aCreationTime, const TimeStamp& aCreationTimestamp, const TimeStamp& aAsyncOpenTimestamp); ~InterceptedHttpChannel() = default; virtual void ReleaseListeners() override; [[nodiscard]] virtual nsresult SetupReplacementChannel( nsIURI* aURI, nsIChannel* aChannel, bool aPreserveMethod, uint32_t aRedirectFlags) override; void AsyncOpenInternal(); bool ShouldRedirect() const; nsresult FollowSyntheticRedirect(); // If the response's URL is different from the request's then do a service // worker redirect. If Response.redirected is false we do an internal // redirect. Otherwise, if Response.redirect is true do a non-internal // redirect so end consumers detect the redirected state. nsresult RedirectForResponseURL(nsIURI* aResponseURI, bool aResponseRedirected); nsresult StartPump(); nsresult OpenRedirectChannel(); void MaybeCallStatusAndProgress(); void MaybeCallBodyCallback(); TimeStamp mServiceWorkerLaunchStart; TimeStamp mServiceWorkerLaunchEnd; public: static already_AddRefed CreateForInterception( PRTime aCreationTime, const TimeStamp& aCreationTimestamp, const TimeStamp& aAsyncOpenTimestamp); static already_AddRefed CreateForSynthesis( const nsHttpResponseHead* aHead, nsIInputStream* aBody, nsIInterceptedBodyCallback* aBodyCallback, PRTime aCreationTime, const TimeStamp& aCreationTimestamp, const TimeStamp& aAsyncOpenTimestamp); NS_IMETHOD SetCanceledReason(const nsACString& aReason) override; NS_IMETHOD GetCanceledReason(nsACString& aReason) override; NS_IMETHOD CancelWithReason(nsresult status, const nsACString& reason) override; NS_IMETHOD Cancel(nsresult aStatus) override; NS_IMETHOD Suspend(void) override; NS_IMETHOD Resume(void) override; NS_IMETHOD GetSecurityInfo(nsITransportSecurityInfo** aSecurityInfo) override; NS_IMETHOD AsyncOpen(nsIStreamListener* aListener) override; NS_IMETHOD LogBlockedCORSRequest(const nsAString& aMessage, const nsACString& aCategory, bool aIsWarning) override; NS_IMETHOD LogMimeTypeMismatch(const nsACString& aMessageName, bool aWarning, const nsAString& aURL, const nsAString& aContentType) override; NS_IMETHOD GetIsAuthChannel(bool* aIsAuthChannel) override; NS_IMETHOD SetPriority(int32_t aPriority) override; NS_IMETHOD SetClassFlags(uint32_t aClassFlags) override; NS_IMETHOD ClearClassFlags(uint32_t flags) override; NS_IMETHOD AddClassFlags(uint32_t flags) override; NS_IMETHOD SetClassOfService(ClassOfService cos) override; NS_IMETHOD SetIncremental(bool incremental) override; NS_IMETHOD ResumeAt(uint64_t startPos, const nsACString& entityID) override; NS_IMETHOD SetEarlyHintObserver(nsIEarlyHintObserver* aObserver) override { return NS_OK; } NS_IMETHOD SetWebTransportSessionEventListener( WebTransportSessionEventListener* aListener) override { return NS_OK; } NS_IMETHOD SetLaunchServiceWorkerStart(TimeStamp aTimeStamp) override; NS_IMETHOD GetLaunchServiceWorkerStart(TimeStamp* aRetVal) override; NS_IMETHOD SetLaunchServiceWorkerEnd(TimeStamp aTimeStamp) override; NS_IMETHOD GetLaunchServiceWorkerEnd(TimeStamp* aRetVal) override; NS_IMETHOD GetDispatchFetchEventStart(TimeStamp* aRetVal) override; NS_IMETHOD GetDispatchFetchEventEnd(TimeStamp* aRetVal) override; NS_IMETHOD GetHandleFetchEventStart(TimeStamp* aRetVal) override; NS_IMETHOD GetHandleFetchEventEnd(TimeStamp* aRetVal) override; void DoNotifyListenerCleanup() override; void DoAsyncAbort(nsresult aStatus) override; }; } // namespace mozilla::net #endif // mozilla_net_InterceptedHttpChannel_h