/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set sw=2 sts=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/. */ #include "nsBaseChannel.h" #include "nsContentUtils.h" #include "nsURLHelper.h" #include "nsNetCID.h" #include "nsMimeTypes.h" #include "nsUnknownDecoder.h" #include "nsIScriptSecurityManager.h" #include "nsMimeTypes.h" #include "nsIChannelEventSink.h" #include "nsIStreamConverterService.h" #include "nsChannelClassifier.h" #include "nsAsyncRedirectVerifyHelper.h" #include "nsProxyRelease.h" #include "nsXULAppAPI.h" #include "nsContentSecurityManager.h" #include "LoadInfo.h" #include "nsServiceManagerUtils.h" #include "nsRedirectHistoryEntry.h" #include "mozilla/BasePrincipal.h" using namespace mozilla; // This class is used to suspend a request across a function scope. class ScopedRequestSuspender { public: explicit ScopedRequestSuspender(nsIRequest* request) : mRequest(request) { if (mRequest && NS_FAILED(mRequest->Suspend())) { NS_WARNING("Couldn't suspend pump"); mRequest = nullptr; } } ~ScopedRequestSuspender() { if (mRequest) mRequest->Resume(); } private: nsIRequest* mRequest; }; // Used to suspend data events from mRequest within a function scope. This is // usually needed when a function makes callbacks that could process events. #define SUSPEND_PUMP_FOR_SCOPE() \ ScopedRequestSuspender pump_suspender__(mRequest) //----------------------------------------------------------------------------- // nsBaseChannel nsBaseChannel::nsBaseChannel() : NeckoTargetHolder(nullptr), mPumpingData(false), mLoadFlags(LOAD_NORMAL), mQueriedProgressSink(true), mSynthProgressEvents(false), mAllowThreadRetargeting(true), mWaitingOnAsyncRedirect(false), mOpenRedirectChannel(false), mRedirectFlags{0}, mStatus(NS_OK), mContentDispositionHint(UINT32_MAX), mContentLength(-1), mWasOpened(false), mCanceled(false) { mContentType.AssignLiteral(UNKNOWN_CONTENT_TYPE); } nsBaseChannel::~nsBaseChannel() { NS_ReleaseOnMainThread("nsBaseChannel::mLoadInfo", mLoadInfo.forget()); } nsresult nsBaseChannel::Redirect(nsIChannel* newChannel, uint32_t redirectFlags, bool openNewChannel) { SUSPEND_PUMP_FOR_SCOPE(); // Transfer properties newChannel->SetLoadGroup(mLoadGroup); newChannel->SetNotificationCallbacks(mCallbacks); newChannel->SetLoadFlags(mLoadFlags | LOAD_REPLACE); // make a copy of the loadinfo, append to the redirectchain // and set it on the new channel nsSecurityFlags secFlags = mLoadInfo->GetSecurityFlags() & ~nsILoadInfo::SEC_FORCE_INHERIT_PRINCIPAL; nsCOMPtr newLoadInfo = static_cast(mLoadInfo.get()) ->CloneWithNewSecFlags(secFlags); nsCOMPtr uriPrincipal; nsIScriptSecurityManager* sm = nsContentUtils::GetSecurityManager(); sm->GetChannelURIPrincipal(this, getter_AddRefs(uriPrincipal)); bool isInternalRedirect = (redirectFlags & (nsIChannelEventSink::REDIRECT_INTERNAL | nsIChannelEventSink::REDIRECT_STS_UPGRADE)); // nsBaseChannel hst no thing to do with HttpBaseChannel, we would not care // about referrer and remote address in this case nsCOMPtr entry = new net::nsRedirectHistoryEntry(uriPrincipal, nullptr, EmptyCString()); newLoadInfo->AppendRedirectHistoryEntry(entry, isInternalRedirect); // Ensure the channel's loadInfo's result principal URI so that it's // either non-null or updated to the redirect target URI. // We must do this because in case the loadInfo's result principal URI // is null, it would be taken from OriginalURI of the channel. But we // overwrite it with the whole redirect chain first URI before opening // the target channel, hence the information would be lost. // If the protocol handler that created the channel wants to use // the originalURI of the channel as the principal URI, it has left // the result principal URI on the load info null. nsCOMPtr resultPrincipalURI; nsCOMPtr existingLoadInfo = newChannel->LoadInfo(); if (existingLoadInfo) { existingLoadInfo->GetResultPrincipalURI(getter_AddRefs(resultPrincipalURI)); } if (!resultPrincipalURI) { newChannel->GetOriginalURI(getter_AddRefs(resultPrincipalURI)); } newLoadInfo->SetResultPrincipalURI(resultPrincipalURI); newChannel->SetLoadInfo(newLoadInfo); // Preserve the privacy bit if it has been overridden if (mPrivateBrowsingOverriden) { nsCOMPtr newPBChannel = do_QueryInterface(newChannel); if (newPBChannel) { newPBChannel->SetPrivate(mPrivateBrowsing); } } if (nsCOMPtr bag = ::do_QueryInterface(newChannel)) { nsHashPropertyBag::CopyFrom(bag, static_cast(this)); } // Notify consumer, giving chance to cancel redirect. auto redirectCallbackHelper = MakeRefPtr(); bool checkRedirectSynchronously = !openNewChannel; nsCOMPtr target = GetNeckoTarget(); mRedirectChannel = newChannel; mRedirectFlags = redirectFlags; mOpenRedirectChannel = openNewChannel; nsresult rv = redirectCallbackHelper->Init( this, newChannel, redirectFlags, target, checkRedirectSynchronously); if (NS_FAILED(rv)) return rv; if (checkRedirectSynchronously && NS_FAILED(mStatus)) return mStatus; return NS_OK; } nsresult nsBaseChannel::ContinueRedirect() { // Make sure to do this _after_ making all the OnChannelRedirect calls mRedirectChannel->SetOriginalURI(OriginalURI()); // If we fail to open the new channel, then we want to leave this channel // unaffected, so we defer tearing down our channel until we have succeeded // with the redirect. if (mOpenRedirectChannel) { nsresult rv = NS_OK; rv = mRedirectChannel->AsyncOpen(mListener); NS_ENSURE_SUCCESS(rv, rv); } mRedirectChannel = nullptr; // close down this channel Cancel(NS_BINDING_REDIRECTED); ChannelDone(); return NS_OK; } bool nsBaseChannel::HasContentTypeHint() const { NS_ASSERTION(!Pending(), "HasContentTypeHint called too late"); return !mContentType.EqualsLiteral(UNKNOWN_CONTENT_TYPE); } nsresult nsBaseChannel::PushStreamConverter(const char* fromType, const char* toType, bool invalidatesContentLength, nsIStreamListener** result) { NS_ASSERTION(mListener, "no listener"); nsresult rv; nsCOMPtr scs = do_GetService(NS_STREAMCONVERTERSERVICE_CONTRACTID, &rv); if (NS_FAILED(rv)) return rv; nsCOMPtr converter; rv = scs->AsyncConvertData(fromType, toType, mListener, nullptr, getter_AddRefs(converter)); if (NS_SUCCEEDED(rv)) { mListener = converter; if (invalidatesContentLength) mContentLength = -1; if (result) { *result = nullptr; converter.swap(*result); } } return rv; } nsresult nsBaseChannel::BeginPumpingData() { nsresult rv; rv = BeginAsyncRead(this, getter_AddRefs(mRequest)); if (NS_SUCCEEDED(rv)) { mPumpingData = true; return NS_OK; } if (rv != NS_ERROR_NOT_IMPLEMENTED) { return rv; } nsCOMPtr stream; nsCOMPtr channel; rv = OpenContentStream(true, getter_AddRefs(stream), getter_AddRefs(channel)); if (NS_FAILED(rv)) return rv; NS_ASSERTION(!stream || !channel, "Got both a channel and a stream?"); if (channel) { nsCOMPtr runnable = new RedirectRunnable(this, channel); rv = Dispatch(runnable.forget()); if (NS_SUCCEEDED(rv)) mWaitingOnAsyncRedirect = true; return rv; } // By assigning mPump, we flag this channel as pending (see Pending). It's // important that the pending flag is set when we call into the stream (the // call to AsyncRead results in the stream's AsyncWait method being called) // and especially when we call into the loadgroup. Our caller takes care to // release mPump if we return an error. nsCOMPtr target = GetNeckoTarget(); rv = nsInputStreamPump::Create(getter_AddRefs(mPump), stream, 0, 0, true, target); if (NS_FAILED(rv)) { return rv; } mPumpingData = true; mRequest = mPump; rv = mPump->AsyncRead(this, nullptr); if (NS_FAILED(rv)) { return rv; } RefPtr promise; rv = ListenerBlockingPromise(getter_AddRefs(promise)); if (NS_FAILED(rv)) { return rv; } if (promise) { mPump->Suspend(); RefPtr self(this); nsCOMPtr serialTarget(do_QueryInterface(target)); MOZ_ASSERT(serialTarget); promise->Then( serialTarget, __func__, [self, this](nsresult rv) { MOZ_ASSERT(mPump); MOZ_ASSERT(NS_SUCCEEDED(rv)); mPump->Resume(); }, [self, this](nsresult rv) { MOZ_ASSERT(mPump); MOZ_ASSERT(NS_FAILED(rv)); Cancel(rv); mPump->Resume(); }); } return NS_OK; } void nsBaseChannel::HandleAsyncRedirect(nsIChannel* newChannel) { NS_ASSERTION(!mPumpingData, "Shouldn't have gotten here"); nsresult rv = mStatus; if (NS_SUCCEEDED(mStatus)) { rv = Redirect(newChannel, nsIChannelEventSink::REDIRECT_TEMPORARY, true); if (NS_SUCCEEDED(rv)) { // OnRedirectVerifyCallback will be called asynchronously return; } } ContinueHandleAsyncRedirect(rv); } void nsBaseChannel::ContinueHandleAsyncRedirect(nsresult result) { mWaitingOnAsyncRedirect = false; if (NS_FAILED(result)) Cancel(result); if (NS_FAILED(result) && mListener) { // Notify our consumer ourselves mListener->OnStartRequest(this); mListener->OnStopRequest(this, mStatus); ChannelDone(); } if (mLoadGroup) mLoadGroup->RemoveRequest(this, nullptr, mStatus); // Drop notification callbacks to prevent cycles. mCallbacks = nullptr; CallbacksChanged(); } void nsBaseChannel::ClassifyURI() { // For channels created in the child process, delegate to the parent to // classify URIs. if (!XRE_IsParentProcess()) { return; } if (NS_ShouldClassifyChannel(this)) { auto classifier = MakeRefPtr(this); if (classifier) { classifier->Start(); } else { Cancel(NS_ERROR_OUT_OF_MEMORY); } } } //----------------------------------------------------------------------------- // nsBaseChannel::nsISupports NS_IMPL_ADDREF(nsBaseChannel) NS_IMPL_RELEASE(nsBaseChannel) NS_INTERFACE_MAP_BEGIN(nsBaseChannel) NS_INTERFACE_MAP_ENTRY(nsIRequest) NS_INTERFACE_MAP_ENTRY(nsIChannel) NS_INTERFACE_MAP_ENTRY(nsIThreadRetargetableRequest) NS_INTERFACE_MAP_ENTRY(nsIInterfaceRequestor) NS_INTERFACE_MAP_ENTRY(nsITransportEventSink) NS_INTERFACE_MAP_ENTRY(nsIRequestObserver) NS_INTERFACE_MAP_ENTRY(nsIStreamListener) NS_INTERFACE_MAP_ENTRY(nsIThreadRetargetableStreamListener) NS_INTERFACE_MAP_ENTRY(nsIAsyncVerifyRedirectCallback) NS_INTERFACE_MAP_ENTRY(nsIPrivateBrowsingChannel) NS_INTERFACE_MAP_END_INHERITING(nsHashPropertyBag) //----------------------------------------------------------------------------- // nsBaseChannel::nsIRequest NS_IMETHODIMP nsBaseChannel::GetName(nsACString& result) { if (!mURI) { result.Truncate(); return NS_OK; } return mURI->GetSpec(result); } NS_IMETHODIMP nsBaseChannel::IsPending(bool* result) { *result = Pending(); return NS_OK; } NS_IMETHODIMP nsBaseChannel::GetStatus(nsresult* status) { if (mRequest && NS_SUCCEEDED(mStatus)) { mRequest->GetStatus(status); } else { *status = mStatus; } return NS_OK; } NS_IMETHODIMP nsBaseChannel::Cancel(nsresult status) { // Ignore redundant cancelation if (mCanceled) { return NS_OK; } mCanceled = true; mStatus = status; if (mRequest) { mRequest->Cancel(status); } return NS_OK; } NS_IMETHODIMP nsBaseChannel::Suspend() { NS_ENSURE_TRUE(mPumpingData, NS_ERROR_NOT_INITIALIZED); NS_ENSURE_TRUE(mRequest, NS_ERROR_NOT_IMPLEMENTED); return mRequest->Suspend(); } NS_IMETHODIMP nsBaseChannel::Resume() { NS_ENSURE_TRUE(mPumpingData, NS_ERROR_NOT_INITIALIZED); NS_ENSURE_TRUE(mRequest, NS_ERROR_NOT_IMPLEMENTED); return mRequest->Resume(); } NS_IMETHODIMP nsBaseChannel::GetLoadFlags(nsLoadFlags* aLoadFlags) { *aLoadFlags = mLoadFlags; return NS_OK; } NS_IMETHODIMP nsBaseChannel::SetLoadFlags(nsLoadFlags aLoadFlags) { mLoadFlags = aLoadFlags; return NS_OK; } NS_IMETHODIMP nsBaseChannel::GetTRRMode(nsIRequest::TRRMode* aTRRMode) { return GetTRRModeImpl(aTRRMode); } NS_IMETHODIMP nsBaseChannel::SetTRRMode(nsIRequest::TRRMode aTRRMode) { return SetTRRModeImpl(aTRRMode); } NS_IMETHODIMP nsBaseChannel::GetLoadGroup(nsILoadGroup** aLoadGroup) { nsCOMPtr loadGroup(mLoadGroup); loadGroup.forget(aLoadGroup); return NS_OK; } NS_IMETHODIMP nsBaseChannel::SetLoadGroup(nsILoadGroup* aLoadGroup) { if (!CanSetLoadGroup(aLoadGroup)) { return NS_ERROR_FAILURE; } mLoadGroup = aLoadGroup; CallbacksChanged(); UpdatePrivateBrowsing(); return NS_OK; } //----------------------------------------------------------------------------- // nsBaseChannel::nsIChannel NS_IMETHODIMP nsBaseChannel::GetOriginalURI(nsIURI** aURI) { RefPtr uri = OriginalURI(); uri.forget(aURI); return NS_OK; } NS_IMETHODIMP nsBaseChannel::SetOriginalURI(nsIURI* aURI) { NS_ENSURE_ARG_POINTER(aURI); mOriginalURI = aURI; return NS_OK; } NS_IMETHODIMP nsBaseChannel::GetURI(nsIURI** aURI) { nsCOMPtr uri(mURI); uri.forget(aURI); return NS_OK; } NS_IMETHODIMP nsBaseChannel::GetOwner(nsISupports** aOwner) { nsCOMPtr owner(mOwner); owner.forget(aOwner); return NS_OK; } NS_IMETHODIMP nsBaseChannel::SetOwner(nsISupports* aOwner) { mOwner = aOwner; return NS_OK; } NS_IMETHODIMP nsBaseChannel::SetLoadInfo(nsILoadInfo* aLoadInfo) { MOZ_RELEASE_ASSERT(aLoadInfo, "loadinfo can't be null"); mLoadInfo = aLoadInfo; // Need to update |mNeckoTarget| when load info has changed. SetupNeckoTarget(); return NS_OK; } NS_IMETHODIMP nsBaseChannel::GetLoadInfo(nsILoadInfo** aLoadInfo) { nsCOMPtr loadInfo(mLoadInfo); loadInfo.forget(aLoadInfo); return NS_OK; } NS_IMETHODIMP nsBaseChannel::GetIsDocument(bool* aIsDocument) { return NS_GetIsDocumentChannel(this, aIsDocument); } NS_IMETHODIMP nsBaseChannel::GetNotificationCallbacks(nsIInterfaceRequestor** aCallbacks) { nsCOMPtr callbacks(mCallbacks); callbacks.forget(aCallbacks); return NS_OK; } NS_IMETHODIMP nsBaseChannel::SetNotificationCallbacks(nsIInterfaceRequestor* aCallbacks) { if (!CanSetCallbacks(aCallbacks)) { return NS_ERROR_FAILURE; } mCallbacks = aCallbacks; CallbacksChanged(); UpdatePrivateBrowsing(); return NS_OK; } NS_IMETHODIMP nsBaseChannel::GetSecurityInfo(nsISupports** aSecurityInfo) { nsCOMPtr securityInfo(mSecurityInfo); securityInfo.forget(aSecurityInfo); return NS_OK; } NS_IMETHODIMP nsBaseChannel::GetContentType(nsACString& aContentType) { aContentType = mContentType; return NS_OK; } NS_IMETHODIMP nsBaseChannel::SetContentType(const nsACString& aContentType) { // mContentCharset is unchanged if not parsed bool dummy; net_ParseContentType(aContentType, mContentType, mContentCharset, &dummy); return NS_OK; } NS_IMETHODIMP nsBaseChannel::GetContentCharset(nsACString& aContentCharset) { aContentCharset = mContentCharset; return NS_OK; } NS_IMETHODIMP nsBaseChannel::SetContentCharset(const nsACString& aContentCharset) { mContentCharset = aContentCharset; return NS_OK; } NS_IMETHODIMP nsBaseChannel::GetContentDisposition(uint32_t* aContentDisposition) { // preserve old behavior, fail unless explicitly set. if (mContentDispositionHint == UINT32_MAX) { return NS_ERROR_NOT_AVAILABLE; } *aContentDisposition = mContentDispositionHint; return NS_OK; } NS_IMETHODIMP nsBaseChannel::SetContentDisposition(uint32_t aContentDisposition) { mContentDispositionHint = aContentDisposition; return NS_OK; } NS_IMETHODIMP nsBaseChannel::GetContentDispositionFilename( nsAString& aContentDispositionFilename) { if (!mContentDispositionFilename) { return NS_ERROR_NOT_AVAILABLE; } aContentDispositionFilename = *mContentDispositionFilename; return NS_OK; } NS_IMETHODIMP nsBaseChannel::SetContentDispositionFilename( const nsAString& aContentDispositionFilename) { mContentDispositionFilename = MakeUnique(aContentDispositionFilename); return NS_OK; } NS_IMETHODIMP nsBaseChannel::GetContentDispositionHeader( nsACString& aContentDispositionHeader) { return NS_ERROR_NOT_AVAILABLE; } NS_IMETHODIMP nsBaseChannel::GetContentLength(int64_t* aContentLength) { *aContentLength = mContentLength; return NS_OK; } NS_IMETHODIMP nsBaseChannel::SetContentLength(int64_t aContentLength) { mContentLength = aContentLength; return NS_OK; } NS_IMETHODIMP nsBaseChannel::Open(nsIInputStream** aStream) { nsCOMPtr listener; nsresult rv = nsContentSecurityManager::doContentSecurityCheck(this, listener); NS_ENSURE_SUCCESS(rv, rv); NS_ENSURE_TRUE(mURI, NS_ERROR_NOT_INITIALIZED); NS_ENSURE_TRUE(!mPumpingData, NS_ERROR_IN_PROGRESS); NS_ENSURE_TRUE(!mWasOpened, NS_ERROR_IN_PROGRESS); nsCOMPtr chan; rv = OpenContentStream(false, aStream, getter_AddRefs(chan)); NS_ASSERTION(!chan || !*aStream, "Got both a channel and a stream?"); if (NS_SUCCEEDED(rv) && chan) { rv = Redirect(chan, nsIChannelEventSink::REDIRECT_INTERNAL, false); if (NS_FAILED(rv)) return rv; rv = chan->Open(aStream); } else if (rv == NS_ERROR_NOT_IMPLEMENTED) return NS_ImplementChannelOpen(this, aStream); if (NS_SUCCEEDED(rv)) { mWasOpened = true; ClassifyURI(); } return rv; } NS_IMETHODIMP nsBaseChannel::AsyncOpen(nsIStreamListener* aListener) { nsCOMPtr listener = aListener; nsresult rv = nsContentSecurityManager::doContentSecurityCheck(this, listener); if (NS_FAILED(rv)) { mCallbacks = nullptr; return rv; } MOZ_ASSERT( mLoadInfo->GetSecurityMode() == 0 || mLoadInfo->GetInitialSecurityCheckDone() || (mLoadInfo->GetSecurityMode() == nsILoadInfo::SEC_ALLOW_CROSS_ORIGIN_DATA_IS_NULL && mLoadInfo->GetLoadingPrincipal() && mLoadInfo->GetLoadingPrincipal()->IsSystemPrincipal()), "security flags in loadInfo but doContentSecurityCheck() not called"); NS_ENSURE_TRUE(mURI, NS_ERROR_NOT_INITIALIZED); NS_ENSURE_TRUE(!mPumpingData, NS_ERROR_IN_PROGRESS); NS_ENSURE_TRUE(!mWasOpened, NS_ERROR_ALREADY_OPENED); NS_ENSURE_ARG(listener); SetupNeckoTarget(); // Skip checking for chrome:// sub-resources. nsAutoCString scheme; mURI->GetScheme(scheme); if (!scheme.EqualsLiteral("file")) { NS_CompareLoadInfoAndLoadContext(this); } // Ensure that this is an allowed port before proceeding. rv = NS_CheckPortSafety(mURI); if (NS_FAILED(rv)) { mCallbacks = nullptr; return rv; } // Store the listener and context early so that OpenContentStream and the // stream's AsyncWait method (called by AsyncRead) can have access to them // via PushStreamConverter and the StreamListener methods. However, since // this typically introduces a reference cycle between this and the listener, // we need to be sure to break the reference if this method does not succeed. mListener = listener; // This method assigns mPump as a side-effect. We need to clear mPump if // this method fails. rv = BeginPumpingData(); if (NS_FAILED(rv)) { mPump = nullptr; mRequest = nullptr; mPumpingData = false; ChannelDone(); mCallbacks = nullptr; return rv; } // At this point, we are going to return success no matter what. mWasOpened = true; SUSPEND_PUMP_FOR_SCOPE(); if (mLoadGroup) mLoadGroup->AddRequest(this, nullptr); ClassifyURI(); return NS_OK; } //----------------------------------------------------------------------------- // nsBaseChannel::nsITransportEventSink NS_IMETHODIMP nsBaseChannel::OnTransportStatus(nsITransport* transport, nsresult status, int64_t progress, int64_t progressMax) { // In some cases, we may wish to suppress transport-layer status events. if (!mPumpingData || NS_FAILED(mStatus)) { return NS_OK; } SUSPEND_PUMP_FOR_SCOPE(); // Lazily fetch mProgressSink if (!mProgressSink) { if (mQueriedProgressSink) { return NS_OK; } GetCallback(mProgressSink); mQueriedProgressSink = true; if (!mProgressSink) { return NS_OK; } } if (!HasLoadFlag(LOAD_BACKGROUND)) { nsAutoString statusArg; if (GetStatusArg(status, statusArg)) { mProgressSink->OnStatus(this, status, statusArg.get()); } } if (progress) { mProgressSink->OnProgress(this, progress, progressMax); } return NS_OK; } //----------------------------------------------------------------------------- // nsBaseChannel::nsIInterfaceRequestor NS_IMETHODIMP nsBaseChannel::GetInterface(const nsIID& iid, void** result) { NS_QueryNotificationCallbacks(mCallbacks, mLoadGroup, iid, result); return *result ? NS_OK : NS_ERROR_NO_INTERFACE; } //----------------------------------------------------------------------------- // nsBaseChannel::nsIRequestObserver static void CallTypeSniffers(void* aClosure, const uint8_t* aData, uint32_t aCount) { nsIChannel* chan = static_cast(aClosure); nsAutoCString newType; NS_SniffContent(NS_CONTENT_SNIFFER_CATEGORY, chan, aData, aCount, newType); if (!newType.IsEmpty()) { chan->SetContentType(newType); } } static void CallUnknownTypeSniffer(void* aClosure, const uint8_t* aData, uint32_t aCount) { nsIChannel* chan = static_cast(aClosure); RefPtr sniffer = new nsUnknownDecoder(); nsAutoCString detected; nsresult rv = sniffer->GetMIMETypeFromContent(chan, aData, aCount, detected); if (NS_SUCCEEDED(rv)) chan->SetContentType(detected); } NS_IMETHODIMP nsBaseChannel::OnStartRequest(nsIRequest* request) { MOZ_ASSERT_IF(mRequest, request == mRequest); nsAutoCString scheme; mURI->GetScheme(scheme); if (mPump && !scheme.EqualsLiteral("ftp")) { // If our content type is unknown, use the content type // sniffer. If the sniffer is not available for some reason, then we just // keep going as-is. if (NS_SUCCEEDED(mStatus) && mContentType.EqualsLiteral(UNKNOWN_CONTENT_TYPE)) { mPump->PeekStream(CallUnknownTypeSniffer, static_cast(this)); } // Now, the general type sniffers. Skip this if we have none. if (mLoadFlags & LOAD_CALL_CONTENT_SNIFFERS) mPump->PeekStream(CallTypeSniffers, static_cast(this)); } SUSPEND_PUMP_FOR_SCOPE(); if (mListener) // null in case of redirect return mListener->OnStartRequest(this); return NS_OK; } NS_IMETHODIMP nsBaseChannel::OnStopRequest(nsIRequest* request, nsresult status) { // If both mStatus and status are failure codes, we keep mStatus as-is since // that is consistent with our GetStatus and Cancel methods. if (NS_SUCCEEDED(mStatus)) mStatus = status; // Cause Pending to return false. mPump = nullptr; mRequest = nullptr; mPumpingData = false; if (mListener) // null in case of redirect mListener->OnStopRequest(this, mStatus); ChannelDone(); // No need to suspend pump in this scope since we will not be receiving // any more events from it. if (mLoadGroup) mLoadGroup->RemoveRequest(this, nullptr, mStatus); // Drop notification callbacks to prevent cycles. mCallbacks = nullptr; CallbacksChanged(); return NS_OK; } //----------------------------------------------------------------------------- // nsBaseChannel::nsIStreamListener NS_IMETHODIMP nsBaseChannel::OnDataAvailable(nsIRequest* request, nsIInputStream* stream, uint64_t offset, uint32_t count) { SUSPEND_PUMP_FOR_SCOPE(); nsresult rv = mListener->OnDataAvailable(this, stream, offset, count); if (mSynthProgressEvents && NS_SUCCEEDED(rv)) { int64_t prog = offset + count; if (NS_IsMainThread()) { OnTransportStatus(nullptr, NS_NET_STATUS_READING, prog, mContentLength); } else { class OnTransportStatusAsyncEvent : public Runnable { RefPtr mChannel; int64_t mProgress; int64_t mContentLength; public: OnTransportStatusAsyncEvent(nsBaseChannel* aChannel, int64_t aProgress, int64_t aContentLength) : Runnable("OnTransportStatusAsyncEvent"), mChannel(aChannel), mProgress(aProgress), mContentLength(aContentLength) {} NS_IMETHOD Run() override { return mChannel->OnTransportStatus(nullptr, NS_NET_STATUS_READING, mProgress, mContentLength); } }; nsCOMPtr runnable = new OnTransportStatusAsyncEvent(this, prog, mContentLength); Dispatch(runnable.forget()); } } return rv; } NS_IMETHODIMP nsBaseChannel::OnRedirectVerifyCallback(nsresult result) { if (NS_SUCCEEDED(result)) result = ContinueRedirect(); if (NS_FAILED(result) && !mWaitingOnAsyncRedirect) { if (NS_SUCCEEDED(mStatus)) mStatus = result; return NS_OK; } if (mWaitingOnAsyncRedirect) ContinueHandleAsyncRedirect(result); return NS_OK; } NS_IMETHODIMP nsBaseChannel::RetargetDeliveryTo(nsIEventTarget* aEventTarget) { MOZ_ASSERT(NS_IsMainThread()); NS_ENSURE_TRUE(mRequest, NS_ERROR_NOT_INITIALIZED); nsCOMPtr req; if (mAllowThreadRetargeting) { req = do_QueryInterface(mRequest); } NS_ENSURE_TRUE(req, NS_ERROR_NOT_IMPLEMENTED); return req->RetargetDeliveryTo(aEventTarget); } NS_IMETHODIMP nsBaseChannel::GetDeliveryTarget(nsIEventTarget** aEventTarget) { MOZ_ASSERT(NS_IsMainThread()); NS_ENSURE_TRUE(mRequest, NS_ERROR_NOT_INITIALIZED); nsCOMPtr req; req = do_QueryInterface(mRequest); NS_ENSURE_TRUE(req, NS_ERROR_NOT_IMPLEMENTED); return req->GetDeliveryTarget(aEventTarget); } NS_IMETHODIMP nsBaseChannel::CheckListenerChain() { MOZ_ASSERT(NS_IsMainThread()); if (!mAllowThreadRetargeting) { return NS_ERROR_NOT_IMPLEMENTED; } nsCOMPtr listener = do_QueryInterface(mListener); if (!listener) { return NS_ERROR_NO_INTERFACE; } return listener->CheckListenerChain(); } NS_IMETHODIMP nsBaseChannel::GetCanceled(bool* aCanceled) { *aCanceled = mCanceled; return NS_OK; } void nsBaseChannel::SetupNeckoTarget() { mNeckoTarget = nsContentUtils::GetEventTargetByLoadInfo(mLoadInfo, TaskCategory::Other); }