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|
/* -*- 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"
#include "nsError.h"
#include "nsHttp.h"
#include "nsICacheEntry.h"
#include "mozilla/BasePrincipal.h"
#include "mozilla/PerfStats.h"
#include "mozilla/Unused.h"
#include "mozilla/dom/ContentChild.h"
#include "mozilla/dom/DocGroup.h"
#include "mozilla/dom/ServiceWorkerUtils.h"
#include "mozilla/dom/BrowserChild.h"
#include "mozilla/dom/LinkStyle.h"
#include "mozilla/extensions/StreamFilterParent.h"
#include "mozilla/ipc/IPCStreamUtils.h"
#include "mozilla/net/NeckoChild.h"
#include "mozilla/net/HttpChannelChild.h"
#include "mozilla/net/PBackgroundDataBridge.h"
#include "mozilla/net/UrlClassifierCommon.h"
#include "mozilla/net/UrlClassifierFeatureFactory.h"
#include "AltDataOutputStreamChild.h"
#include "CookieServiceChild.h"
#include "HttpBackgroundChannelChild.h"
#include "NetworkMarker.h"
#include "nsCOMPtr.h"
#include "nsContentPolicyUtils.h"
#include "nsDOMNavigationTiming.h"
#include "nsIThreadRetargetableStreamListener.h"
#include "nsIStreamTransportService.h"
#include "nsStringStream.h"
#include "nsHttpChannel.h"
#include "nsHttpHandler.h"
#include "nsQueryObject.h"
#include "nsNetUtil.h"
#include "nsSerializationHelper.h"
#include "mozilla/Attributes.h"
#include "mozilla/Telemetry.h"
#include "mozilla/dom/PerformanceStorage.h"
#include "mozilla/ipc/InputStreamUtils.h"
#include "mozilla/ipc/URIUtils.h"
#include "mozilla/ipc/BackgroundUtils.h"
#include "mozilla/net/DNS.h"
#include "mozilla/net/SocketProcessBridgeChild.h"
#include "mozilla/ScopeExit.h"
#include "mozilla/StaticPrefs_network.h"
#include "mozilla/StoragePrincipalHelper.h"
#include "SerializedLoadContext.h"
#include "nsInputStreamPump.h"
#include "nsContentSecurityManager.h"
#include "nsICompressConvStats.h"
#include "mozilla/dom/Document.h"
#include "nsIScriptError.h"
#include "nsISerialEventTarget.h"
#include "nsRedirectHistoryEntry.h"
#include "nsSocketTransportService2.h"
#include "nsStreamUtils.h"
#include "nsThreadUtils.h"
#include "nsCORSListenerProxy.h"
#include "nsIOService.h"
#include <functional>
using namespace mozilla::dom;
using namespace mozilla::ipc;
namespace mozilla::net {
//-----------------------------------------------------------------------------
// HttpChannelChild
//-----------------------------------------------------------------------------
HttpChannelChild::HttpChannelChild()
: HttpAsyncAborter<HttpChannelChild>(this),
NeckoTargetHolder(nullptr),
mCacheEntryAvailable(false),
mAltDataCacheEntryAvailable(false),
mSendResumeAt(false),
mKeptAlive(false),
mIPCActorDeleted(false),
mSuspendSent(false),
mIsFirstPartOfMultiPart(false),
mIsLastPartOfMultiPart(false),
mSuspendForWaitCompleteRedirectSetup(false),
mRecvOnStartRequestSentCalled(false),
mSuspendedByWaitingForPermissionCookie(false),
mAlreadyReleased(false) {
LOG(("Creating HttpChannelChild @%p\n", this));
mChannelCreationTime = PR_Now();
mChannelCreationTimestamp = TimeStamp::Now();
mLastStatusReported =
mChannelCreationTimestamp; // in case we enable the profiler after Init()
mAsyncOpenTime = TimeStamp::Now();
mEventQ = new ChannelEventQueue(static_cast<nsIHttpChannel*>(this));
// Ensure that the cookie service is initialized before the first
// IPC HTTP channel is created.
// We require that the parent cookie service actor exists while
// processing HTTP responses.
RefPtr<CookieServiceChild> cookieService = CookieServiceChild::GetSingleton();
}
HttpChannelChild::~HttpChannelChild() {
LOG(("Destroying HttpChannelChild @%p\n", this));
// See HttpChannelChild::Release, HttpChannelChild should be always destroyed
// on the main thread.
MOZ_RELEASE_ASSERT(NS_IsMainThread());
#ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED
if (mDoDiagnosticAssertWhenOnStopNotCalledOnDestroy && mAsyncOpenSucceeded &&
!mSuccesfullyRedirected && !LoadOnStopRequestCalled()) {
bool emptyBgChildQueue, nullBgChild;
{
MutexAutoLock lock(mBgChildMutex);
nullBgChild = !mBgChild;
emptyBgChildQueue = !nullBgChild && mBgChild->IsQueueEmpty();
}
uint32_t flags =
(mRedirectChannelChild ? 1 << 0 : 0) |
(mEventQ->IsEmpty() ? 1 << 1 : 0) | (nullBgChild ? 1 << 2 : 0) |
(emptyBgChildQueue ? 1 << 3 : 0) |
(LoadOnStartRequestCalled() ? 1 << 4 : 0) |
(mBackgroundChildQueueFinalState == BCKCHILD_EMPTY ? 1 << 5 : 0) |
(mBackgroundChildQueueFinalState == BCKCHILD_NON_EMPTY ? 1 << 6 : 0) |
(mRemoteChannelExistedAtCancel ? 1 << 7 : 0) |
(mEverHadBgChildAtAsyncOpen ? 1 << 8 : 0) |
(mEverHadBgChildAtConnectParent ? 1 << 9 : 0) |
(mCreateBackgroundChannelFailed ? 1 << 10 : 0) |
(mBgInitFailCallbackTriggered ? 1 << 11 : 0) |
(mCanSendAtCancel ? 1 << 12 : 0) | (!!mSuspendCount ? 1 << 13 : 0) |
(!!mCallOnResume ? 1 << 14 : 0);
MOZ_CRASH_UNSAFE_PRINTF(
"~HttpChannelChild, LoadOnStopRequestCalled()=false, mStatus=0x%08x, "
"mActorDestroyReason=%d, 20200717 flags=%u",
static_cast<uint32_t>(nsresult(mStatus)),
static_cast<int32_t>(mActorDestroyReason ? *mActorDestroyReason : -1),
flags);
}
#endif
mEventQ->NotifyReleasingOwner();
ReleaseMainThreadOnlyReferences();
}
void HttpChannelChild::ReleaseMainThreadOnlyReferences() {
if (NS_IsMainThread()) {
// Already on main thread, let dtor to
// take care of releasing references
return;
}
NS_ReleaseOnMainThread("HttpChannelChild::mRedirectChannelChild",
mRedirectChannelChild.forget());
}
//-----------------------------------------------------------------------------
// HttpChannelChild::nsISupports
//-----------------------------------------------------------------------------
NS_IMPL_ADDREF(HttpChannelChild)
NS_IMETHODIMP_(MozExternalRefCountType) HttpChannelChild::Release() {
if (!NS_IsMainThread()) {
nsrefcnt count = mRefCnt;
nsresult rv = NS_DispatchToMainThread(NewNonOwningRunnableMethod(
"HttpChannelChild::Release", this, &HttpChannelChild::Release));
// Continue Release procedure if failed to dispatch to main thread.
if (!NS_WARN_IF(NS_FAILED(rv))) {
return count - 1;
}
}
nsrefcnt count = --mRefCnt;
MOZ_ASSERT(int32_t(count) >= 0, "dup release");
// Normally we Send_delete in OnStopRequest, but when we need to retain the
// remote channel for security info IPDL itself holds 1 reference, so we
// Send_delete when refCnt==1. But if !CanSend(), then there's nobody to send
// to, so we fall through.
if (mKeptAlive && count == 1 && CanSend()) {
NS_LOG_RELEASE(this, 1, "HttpChannelChild");
mKeptAlive = false;
// We send a message to the parent, which calls SendDelete, and then the
// child calling Send__delete__() to finally drop the refcount to 0.
TrySendDeletingChannel();
return 1;
}
if (count == 0) {
mRefCnt = 1; /* stabilize */
// We don't have a listener when AsyncOpen has failed or when this channel
// has been sucessfully redirected.
if (MOZ_LIKELY(LoadOnStartRequestCalled() && LoadOnStopRequestCalled()) ||
!mListener || mAlreadyReleased) {
NS_LOG_RELEASE(this, 0, "HttpChannelChild");
delete this;
return 0;
}
// This ensures that when the refcount goes to 0 again, we don't dispatch
// yet another runnable and get in a loop.
mAlreadyReleased = true;
// This makes sure we fulfill the stream listener contract all the time.
if (NS_SUCCEEDED(mStatus)) {
mStatus = NS_ERROR_ABORT;
}
// Turn the stabilization refcount into a regular strong reference.
// 1) We tell refcount logging about the "stabilization" AddRef, which
// will become the reference for |channel|. We do this first so that we
// don't tell refcount logging that the refcount has dropped to zero, which
// it will interpret as destroying the object.
NS_LOG_ADDREF(this, 2, "HttpChannelChild", sizeof(*this));
// 2) We tell refcount logging about the original call to Release().
NS_LOG_RELEASE(this, 1, "HttpChannelChild");
// 3) Finally, we turn the reference into a regular smart pointer.
RefPtr<HttpChannelChild> channel = dont_AddRef(this);
NS_DispatchToMainThread(NS_NewRunnableFunction(
"~HttpChannelChild>DoNotifyListener",
[chan = std::move(channel)] { chan->DoNotifyListener(false); }));
// If NS_DispatchToMainThread failed then we're going to leak the runnable,
// and thus the channel, so there's no need to do anything else.
return mRefCnt;
}
NS_LOG_RELEASE(this, count, "HttpChannelChild");
return count;
}
NS_INTERFACE_MAP_BEGIN(HttpChannelChild)
NS_INTERFACE_MAP_ENTRY(nsIRequest)
NS_INTERFACE_MAP_ENTRY(nsIChannel)
NS_INTERFACE_MAP_ENTRY(nsIHttpChannel)
NS_INTERFACE_MAP_ENTRY(nsIHttpChannelInternal)
NS_INTERFACE_MAP_ENTRY_CONDITIONAL(nsICacheInfoChannel,
!mMultiPartID.isSome())
NS_INTERFACE_MAP_ENTRY(nsIResumableChannel)
NS_INTERFACE_MAP_ENTRY(nsISupportsPriority)
NS_INTERFACE_MAP_ENTRY(nsIClassOfService)
NS_INTERFACE_MAP_ENTRY(nsIProxiedChannel)
NS_INTERFACE_MAP_ENTRY(nsITraceableChannel)
NS_INTERFACE_MAP_ENTRY(nsIAsyncVerifyRedirectCallback)
NS_INTERFACE_MAP_ENTRY(nsIChildChannel)
NS_INTERFACE_MAP_ENTRY(nsIHttpChannelChild)
NS_INTERFACE_MAP_ENTRY_CONDITIONAL(nsIMultiPartChannel, mMultiPartID.isSome())
NS_INTERFACE_MAP_ENTRY_CONDITIONAL(nsIThreadRetargetableRequest,
!mMultiPartID.isSome())
NS_INTERFACE_MAP_ENTRY_CONCRETE(HttpChannelChild)
NS_INTERFACE_MAP_END_INHERITING(HttpBaseChannel)
//-----------------------------------------------------------------------------
// HttpChannelChild::PHttpChannelChild
//-----------------------------------------------------------------------------
void HttpChannelChild::OnBackgroundChildReady(
HttpBackgroundChannelChild* aBgChild) {
LOG(("HttpChannelChild::OnBackgroundChildReady [this=%p, bgChild=%p]\n", this,
aBgChild));
MOZ_ASSERT(OnSocketThread());
{
MutexAutoLock lock(mBgChildMutex);
// mBgChild might be removed or replaced while the original background
// channel is inited on STS thread.
if (mBgChild != aBgChild) {
return;
}
MOZ_ASSERT(mBgInitFailCallback);
mBgInitFailCallback = nullptr;
}
}
void HttpChannelChild::OnBackgroundChildDestroyed(
HttpBackgroundChannelChild* aBgChild) {
LOG(("HttpChannelChild::OnBackgroundChildDestroyed [this=%p]\n", this));
// This function might be called during shutdown phase, so OnSocketThread()
// might return false even on STS thread. Use IsOnCurrentThreadInfallible()
// to get correct information.
MOZ_ASSERT(gSocketTransportService);
MOZ_ASSERT(gSocketTransportService->IsOnCurrentThreadInfallible());
nsCOMPtr<nsIRunnable> callback;
{
MutexAutoLock lock(mBgChildMutex);
// mBgChild might be removed or replaced while the original background
// channel is destroyed on STS thread.
if (aBgChild != mBgChild) {
return;
}
mBgChild = nullptr;
callback = std::move(mBgInitFailCallback);
}
if (callback) {
#ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED
mBgInitFailCallbackTriggered = true;
#endif
nsCOMPtr<nsISerialEventTarget> neckoTarget = GetNeckoTarget();
neckoTarget->Dispatch(callback, NS_DISPATCH_NORMAL);
}
}
mozilla::ipc::IPCResult HttpChannelChild::RecvOnStartRequestSent() {
LOG(("HttpChannelChild::RecvOnStartRequestSent [this=%p]\n", this));
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(!mRecvOnStartRequestSentCalled);
mRecvOnStartRequestSentCalled = true;
if (mSuspendedByWaitingForPermissionCookie) {
mSuspendedByWaitingForPermissionCookie = false;
mEventQ->Resume();
}
return IPC_OK();
}
void HttpChannelChild::ProcessOnStartRequest(
const nsHttpResponseHead& aResponseHead, const bool& aUseResponseHead,
const nsHttpHeaderArray& aRequestHeaders,
const HttpChannelOnStartRequestArgs& aArgs,
const HttpChannelAltDataStream& aAltData,
const TimeStamp& aOnStartRequestStartTime) {
LOG(("HttpChannelChild::ProcessOnStartRequest [this=%p]\n", this));
MOZ_ASSERT(OnSocketThread());
TimeStamp start = TimeStamp::Now();
mAltDataInputStream = DeserializeIPCStream(aAltData.altDataInputStream());
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this, [self = UnsafePtr<HttpChannelChild>(this), aResponseHead,
aUseResponseHead, aRequestHeaders, aArgs, start]() {
TimeDuration delay = TimeStamp::Now() - start;
glean::networking::http_content_onstart_delay.AccumulateRawDuration(
delay);
self->OnStartRequest(aResponseHead, aUseResponseHead, aRequestHeaders,
aArgs);
}));
}
static void ResourceTimingStructArgsToTimingsStruct(
const ResourceTimingStructArgs& aArgs, TimingStruct& aTimings) {
aTimings.domainLookupStart = aArgs.domainLookupStart();
aTimings.domainLookupEnd = aArgs.domainLookupEnd();
aTimings.connectStart = aArgs.connectStart();
aTimings.tcpConnectEnd = aArgs.tcpConnectEnd();
aTimings.secureConnectionStart = aArgs.secureConnectionStart();
aTimings.connectEnd = aArgs.connectEnd();
aTimings.requestStart = aArgs.requestStart();
aTimings.responseStart = aArgs.responseStart();
aTimings.responseEnd = aArgs.responseEnd();
aTimings.transactionPending = aArgs.transactionPending();
}
void HttpChannelChild::OnStartRequest(
const nsHttpResponseHead& aResponseHead, const bool& aUseResponseHead,
const nsHttpHeaderArray& aRequestHeaders,
const HttpChannelOnStartRequestArgs& aArgs) {
LOG(("HttpChannelChild::OnStartRequest [this=%p]\n", this));
// If this channel was aborted by ActorDestroy, then there may be other
// OnStartRequest/OnStopRequest/OnDataAvailable IPC messages that need to
// be handled. In that case we just ignore them to avoid calling the listener
// twice.
if (LoadOnStartRequestCalled() && mIPCActorDeleted) {
return;
}
// Copy arguments only. It's possible to handle other IPC between
// OnStartRequest and DoOnStartRequest.
mComputedCrossOriginOpenerPolicy = aArgs.openerPolicy();
if (!mCanceled && NS_SUCCEEDED(mStatus)) {
mStatus = aArgs.channelStatus();
}
// Cookies headers should not be visible to the child process
MOZ_ASSERT(!aRequestHeaders.HasHeader(nsHttp::Cookie));
MOZ_ASSERT(!nsHttpResponseHead(aResponseHead).HasHeader(nsHttp::Set_Cookie));
if (aUseResponseHead && !mCanceled) {
mResponseHead = MakeUnique<nsHttpResponseHead>(aResponseHead);
}
mSecurityInfo = aArgs.securityInfo();
ipc::MergeParentLoadInfoForwarder(aArgs.loadInfoForwarder(), mLoadInfo);
mIsFromCache = aArgs.isFromCache();
mIsRacing = aArgs.isRacing();
mCacheEntryAvailable = aArgs.cacheEntryAvailable();
mCacheEntryId = aArgs.cacheEntryId();
mCacheFetchCount = aArgs.cacheFetchCount();
mProtocolVersion = aArgs.protocolVersion();
mCacheExpirationTime = aArgs.cacheExpirationTime();
mSelfAddr = aArgs.selfAddr();
mPeerAddr = aArgs.peerAddr();
mRedirectCount = aArgs.redirectCount();
mAvailableCachedAltDataType = aArgs.altDataType();
StoreDeliveringAltData(aArgs.deliveringAltData());
mAltDataLength = aArgs.altDataLength();
StoreResolvedByTRR(aArgs.isResolvedByTRR());
mEffectiveTRRMode = aArgs.effectiveTRRMode();
mTRRSkipReason = aArgs.trrSkipReason();
SetApplyConversion(aArgs.applyConversion());
StoreAfterOnStartRequestBegun(true);
StoreHasHTTPSRR(aArgs.hasHTTPSRR());
AutoEventEnqueuer ensureSerialDispatch(mEventQ);
mCacheKey = aArgs.cacheKey();
StoreIsProxyUsed(aArgs.isProxyUsed());
// replace our request headers with what actually got sent in the parent
mRequestHead.SetHeaders(aRequestHeaders);
// Note: this is where we would notify "http-on-examine-response" observers.
// We have deliberately disabled this for child processes (see bug 806753)
//
// gHttpHandler->OnExamineResponse(this);
ResourceTimingStructArgsToTimingsStruct(aArgs.timing(), mTransactionTimings);
nsAutoCString cosString;
ClassOfService::ToString(mClassOfService, cosString);
if (!mAsyncOpenTime.IsNull() &&
!aArgs.timing().transactionPending().IsNull()) {
Telemetry::AccumulateTimeDelta(
Telemetry::NETWORK_ASYNC_OPEN_CHILD_TO_TRANSACTION_PENDING_EXP_MS,
cosString, mAsyncOpenTime, aArgs.timing().transactionPending());
PerfStats::RecordMeasurement(
PerfStats::Metric::HttpChannelAsyncOpenToTransactionPending,
aArgs.timing().transactionPending() - mAsyncOpenTime);
}
const TimeStamp now = TimeStamp::Now();
if (!aArgs.timing().responseStart().IsNull()) {
Telemetry::AccumulateTimeDelta(
Telemetry::NETWORK_RESPONSE_START_PARENT_TO_CONTENT_EXP_MS, cosString,
aArgs.timing().responseStart(), now);
PerfStats::RecordMeasurement(
PerfStats::Metric::HttpChannelResponseStartParentToContent,
now - aArgs.timing().responseStart());
}
if (!mOnStartRequestStartTime.IsNull()) {
PerfStats::RecordMeasurement(PerfStats::Metric::OnStartRequestToContent,
now - mOnStartRequestStartTime);
}
StoreAllRedirectsSameOrigin(aArgs.allRedirectsSameOrigin());
mMultiPartID = aArgs.multiPartID();
mIsFirstPartOfMultiPart = aArgs.isFirstPartOfMultiPart();
mIsLastPartOfMultiPart = aArgs.isLastPartOfMultiPart();
if (aArgs.overrideReferrerInfo()) {
// The arguments passed to SetReferrerInfoInternal here should mirror the
// arguments passed in
// nsHttpChannel::ReEvaluateReferrerAfterTrackingStatusIsKnown(), except for
// aRespectBeforeConnect which we pass false here since we're intentionally
// overriding the referrer after BeginConnect().
Unused << SetReferrerInfoInternal(aArgs.overrideReferrerInfo(), false, true,
false);
}
if (!aArgs.cookie().IsEmpty()) {
SetCookie(aArgs.cookie());
}
if (aArgs.shouldWaitForOnStartRequestSent() &&
!mRecvOnStartRequestSentCalled) {
LOG((" > pending DoOnStartRequest until RecvOnStartRequestSent\n"));
MOZ_ASSERT(NS_IsMainThread());
mEventQ->Suspend();
mSuspendedByWaitingForPermissionCookie = true;
mEventQ->PrependEvent(MakeUnique<NeckoTargetChannelFunctionEvent>(
this, [self = UnsafePtr<HttpChannelChild>(this)]() {
self->DoOnStartRequest(self);
}));
return;
}
// Remember whether HTTP3 is supported
if (mResponseHead) {
mSupportsHTTP3 =
nsHttpHandler::IsHttp3SupportedByServer(mResponseHead.get());
}
DoOnStartRequest(this);
}
void HttpChannelChild::ProcessOnAfterLastPart(const nsresult& aStatus) {
LOG(("HttpChannelChild::ProcessOnAfterLastPart [this=%p]\n", this));
MOZ_ASSERT(OnSocketThread());
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this, [self = UnsafePtr<HttpChannelChild>(this), aStatus]() {
self->OnAfterLastPart(aStatus);
}));
}
void HttpChannelChild::OnAfterLastPart(const nsresult& aStatus) {
if (LoadOnStopRequestCalled()) {
return;
}
StoreOnStopRequestCalled(true);
// notify "http-on-stop-connect" observers
gHttpHandler->OnStopRequest(this);
ReleaseListeners();
// If a preferred alt-data type was set, the parent would hold a reference to
// the cache entry in case the child calls openAlternativeOutputStream().
// (see nsHttpChannel::OnStopRequest)
if (!mPreferredCachedAltDataTypes.IsEmpty()) {
mAltDataCacheEntryAvailable = mCacheEntryAvailable;
}
mCacheEntryAvailable = false;
if (mLoadGroup) mLoadGroup->RemoveRequest(this, nullptr, mStatus);
CleanupBackgroundChannel();
if (mLoadFlags & LOAD_DOCUMENT_URI) {
// Keep IPDL channel open, but only for updating security info.
// If IPDL is already closed, then do nothing.
if (CanSend()) {
mKeptAlive = true;
SendDocumentChannelCleanup(true);
}
} else {
// The parent process will respond by sending a DeleteSelf message and
// making sure not to send any more messages after that.
TrySendDeletingChannel();
}
}
void HttpChannelChild::DoOnStartRequest(nsIRequest* aRequest) {
nsresult rv;
LOG(("HttpChannelChild::DoOnStartRequest [this=%p]\n", this));
// We handle all the listener chaining before OnStartRequest at this moment.
// Prevent additional listeners being added to the chain after the request
// as started.
StoreTracingEnabled(false);
// mListener could be null if the redirect setup is not completed.
MOZ_ASSERT(mListener || LoadOnStartRequestCalled());
if (!mListener) {
Cancel(NS_ERROR_FAILURE);
return;
}
if (mListener) {
nsCOMPtr<nsIStreamListener> listener(mListener);
StoreOnStartRequestCalled(true);
rv = listener->OnStartRequest(aRequest);
} else {
rv = NS_ERROR_UNEXPECTED;
}
StoreOnStartRequestCalled(true);
if (NS_FAILED(rv)) {
CancelWithReason(rv, "HttpChannelChild listener->OnStartRequest failed"_ns);
return;
}
nsCOMPtr<nsIStreamListener> listener;
rv = DoApplyContentConversions(mListener, getter_AddRefs(listener), nullptr);
if (NS_FAILED(rv)) {
CancelWithReason(rv,
"HttpChannelChild DoApplyContentConversions failed"_ns);
} else if (listener) {
mListener = listener;
mCompressListener = listener;
// We call MaybeRetarget here to allow the stream converter
// the option to request data on another thread, even if the
// final listener might not support it
if (nsCOMPtr<nsIStreamConverter> conv =
do_QueryInterface((mCompressListener))) {
rv = conv->MaybeRetarget(this);
if (NS_SUCCEEDED(rv)) {
mOMTResult = LABELS_HTTP_CHILD_OMT_STATS_2::successOnlyDecomp;
}
}
}
}
void HttpChannelChild::ProcessOnTransportAndData(
const nsresult& aChannelStatus, const nsresult& aTransportStatus,
const uint64_t& aOffset, const uint32_t& aCount, const nsACString& aData,
const TimeStamp& aOnDataAvailableStartTime) {
LOG(("HttpChannelChild::ProcessOnTransportAndData [this=%p]\n", this));
MOZ_ASSERT(OnSocketThread());
mEventQ->RunOrEnqueue(new ChannelFunctionEvent(
[self = UnsafePtr<HttpChannelChild>(this)]() {
return self->GetODATarget();
},
[self = UnsafePtr<HttpChannelChild>(this), aChannelStatus,
aTransportStatus, aOffset, aCount, aData = nsCString(aData),
aOnDataAvailableStartTime]() {
self->mOnDataAvailableStartTime = aOnDataAvailableStartTime;
self->OnTransportAndData(aChannelStatus, aTransportStatus, aOffset,
aCount, aData);
}));
}
void HttpChannelChild::OnTransportAndData(const nsresult& aChannelStatus,
const nsresult& aTransportStatus,
const uint64_t& aOffset,
const uint32_t& aCount,
const nsACString& aData) {
LOG(("HttpChannelChild::OnTransportAndData [this=%p]\n", this));
if (!mCanceled && NS_SUCCEEDED(mStatus)) {
mStatus = aChannelStatus;
}
if (mCanceled || NS_FAILED(mStatus)) {
return;
}
if (!mOnDataAvailableStartTime.IsNull()) {
PerfStats::RecordMeasurement(PerfStats::Metric::OnDataAvailableToContent,
TimeStamp::Now() - mOnDataAvailableStartTime);
}
// Hold queue lock throughout all three calls, else we might process a later
// necko msg in between them.
AutoEventEnqueuer ensureSerialDispatch(mEventQ);
int64_t progressMax;
if (NS_FAILED(GetContentLength(&progressMax))) {
progressMax = -1;
}
const int64_t progress = aOffset + aCount;
// OnTransportAndData will be run on retargeted thread if applicable, however
// OnStatus/OnProgress event can only be fired on main thread. We need to
// dispatch the status/progress event handling back to main thread with the
// appropriate event target for networking.
if (NS_IsMainThread()) {
DoOnStatus(this, aTransportStatus);
DoOnProgress(this, progress, progressMax);
} else {
RefPtr<HttpChannelChild> self = this;
nsCOMPtr<nsISerialEventTarget> neckoTarget = GetNeckoTarget();
MOZ_ASSERT(neckoTarget);
DebugOnly<nsresult> rv = neckoTarget->Dispatch(
NS_NewRunnableFunction(
"net::HttpChannelChild::OnTransportAndData",
[self, aTransportStatus, progress, progressMax]() {
self->DoOnStatus(self, aTransportStatus);
self->DoOnProgress(self, progress, progressMax);
}),
NS_DISPATCH_NORMAL);
MOZ_ASSERT(NS_SUCCEEDED(rv));
}
// OnDataAvailable
//
// NOTE: the OnDataAvailable contract requires the client to read all the data
// in the inputstream. This code relies on that ('data' will go away after
// this function). Apparently the previous, non-e10s behavior was to actually
// support only reading part of the data, allowing later calls to read the
// rest.
nsCOMPtr<nsIInputStream> stringStream;
nsresult rv =
NS_NewByteInputStream(getter_AddRefs(stringStream),
Span(aData).To(aCount), NS_ASSIGNMENT_DEPEND);
if (NS_FAILED(rv)) {
CancelWithReason(rv, "HttpChannelChild NS_NewByteInputStream failed"_ns);
return;
}
DoOnDataAvailable(this, stringStream, aOffset, aCount);
stringStream->Close();
// TODO: Bug 1523916 backpressure needs to take into account if the data is
// coming from the main process or from the socket process via PBackground.
if (NeedToReportBytesRead()) {
mUnreportBytesRead += aCount;
if (mUnreportBytesRead >= gHttpHandler->SendWindowSize() >> 2) {
if (NS_IsMainThread()) {
Unused << SendBytesRead(mUnreportBytesRead);
} else {
// PHttpChannel connects to the main thread
RefPtr<HttpChannelChild> self = this;
int32_t bytesRead = mUnreportBytesRead;
nsCOMPtr<nsISerialEventTarget> neckoTarget = GetNeckoTarget();
MOZ_ASSERT(neckoTarget);
DebugOnly<nsresult> rv = neckoTarget->Dispatch(
NS_NewRunnableFunction("net::HttpChannelChild::SendBytesRead",
[self, bytesRead]() {
Unused << self->SendBytesRead(bytesRead);
}),
NS_DISPATCH_NORMAL);
MOZ_ASSERT(NS_SUCCEEDED(rv));
}
mUnreportBytesRead = 0;
}
}
}
bool HttpChannelChild::NeedToReportBytesRead() {
if (mCacheNeedToReportBytesReadInitialized) {
return mNeedToReportBytesRead;
}
// Might notify parent for partial cache, and the IPC message is ignored by
// parent.
int64_t contentLength = -1;
if (gHttpHandler->SendWindowSize() == 0 || mIsFromCache ||
NS_FAILED(GetContentLength(&contentLength)) ||
contentLength < gHttpHandler->SendWindowSize()) {
mNeedToReportBytesRead = false;
}
mCacheNeedToReportBytesReadInitialized = true;
return mNeedToReportBytesRead;
}
void HttpChannelChild::DoOnStatus(nsIRequest* aRequest, nsresult status) {
LOG(("HttpChannelChild::DoOnStatus [this=%p]\n", this));
MOZ_ASSERT(NS_IsMainThread());
if (mCanceled) return;
// cache the progress sink so we don't have to query for it each time.
if (!mProgressSink) GetCallback(mProgressSink);
// block status/progress after Cancel or OnStopRequest has been called,
// or if channel has LOAD_BACKGROUND set.
if (mProgressSink && NS_SUCCEEDED(mStatus) && LoadIsPending() &&
!(mLoadFlags & LOAD_BACKGROUND)) {
nsAutoCString host;
mURI->GetHost(host);
mProgressSink->OnStatus(aRequest, status,
NS_ConvertUTF8toUTF16(host).get());
}
}
void HttpChannelChild::DoOnProgress(nsIRequest* aRequest, int64_t progress,
int64_t progressMax) {
LOG(("HttpChannelChild::DoOnProgress [this=%p]\n", this));
MOZ_ASSERT(NS_IsMainThread());
if (mCanceled) return;
// cache the progress sink so we don't have to query for it each time.
if (!mProgressSink) GetCallback(mProgressSink);
// block status/progress after Cancel or OnStopRequest has been called,
// or if channel has LOAD_BACKGROUND set.
if (mProgressSink && NS_SUCCEEDED(mStatus) && LoadIsPending()) {
// OnProgress
//
if (progress > 0) {
mProgressSink->OnProgress(aRequest, progress, progressMax);
}
}
// mOnProgressEventSent indicates we have flushed all the
// progress events on the main thread. It is needed if
// we do not want to dispatch OnDataFinished before sending
// all of the progress updates.
if (progress == progressMax) {
mOnProgressEventSent = true;
}
}
void HttpChannelChild::DoOnDataAvailable(nsIRequest* aRequest,
nsIInputStream* aStream,
uint64_t aOffset, uint32_t aCount) {
AUTO_PROFILER_LABEL("HttpChannelChild::DoOnDataAvailable", NETWORK);
LOG(("HttpChannelChild::DoOnDataAvailable [this=%p]\n", this));
if (mCanceled) return;
if (mListener) {
nsCOMPtr<nsIStreamListener> listener(mListener);
nsresult rv = listener->OnDataAvailable(aRequest, aStream, aOffset, aCount);
if (NS_FAILED(rv)) {
CancelOnMainThread(rv, "HttpChannelChild OnDataAvailable failed"_ns);
}
}
}
void HttpChannelChild::SendOnDataFinished(const nsresult& aChannelStatus) {
LOG(("HttpChannelChild::SendOnDataFinished [this=%p]\n", this));
if (mCanceled) return;
// we need to ensure we OnDataFinished only after all the progress
// updates are dispatched on the main thread
if (StaticPrefs::network_send_OnDataFinished_after_progress_updates() &&
!mOnProgressEventSent) {
return;
}
if (mListener) {
nsCOMPtr<nsIThreadRetargetableStreamListener> omtEventListener =
do_QueryInterface(mListener);
if (omtEventListener) {
LOG(
("HttpChannelChild::SendOnDataFinished sending data end "
"notification[this=%p]\n",
this));
// We want to calculate the delta time between this call and
// ProcessOnStopRequest. Complicating things is that OnStopRequest
// could come first, and that it will run on a different thread, so
// we need to synchronize and lock data.
omtEventListener->OnDataFinished(aChannelStatus);
} else {
LOG(
("HttpChannelChild::SendOnDataFinished missing "
"nsIThreadRetargetableStreamListener "
"implementation [this=%p]\n",
this));
}
}
}
class RecordStopRequestDelta final {
public:
NS_INLINE_DECL_THREADSAFE_REFCOUNTING(RecordStopRequestDelta);
TimeStamp mOnStopRequestTime;
TimeStamp mOnDataFinishedTime;
private:
~RecordStopRequestDelta() {
if (mOnDataFinishedTime.IsNull() || mOnStopRequestTime.IsNull()) {
return;
}
TimeDuration delta = (mOnStopRequestTime - mOnDataFinishedTime);
MOZ_ASSERT((delta.ToMilliseconds() >= 0),
"OnDataFinished after OnStopRequest");
glean::networking::http_content_ondatafinished_to_onstop_delay
.AccumulateRawDuration(delta);
}
};
void HttpChannelChild::ProcessOnStopRequest(
const nsresult& aChannelStatus, const ResourceTimingStructArgs& aTiming,
const nsHttpHeaderArray& aResponseTrailers,
nsTArray<ConsoleReportCollected>&& aConsoleReports, bool aFromSocketProcess,
const TimeStamp& aOnStopRequestStartTime) {
LOG(
("HttpChannelChild::ProcessOnStopRequest [this=%p, "
"aFromSocketProcess=%d]\n",
this, aFromSocketProcess));
MOZ_ASSERT(OnSocketThread());
{ // assign some of the members that would be accessed by the listeners
// upon getting OnDataFinished notications
MutexAutoLock lock(mOnDataFinishedMutex);
mTransferSize = aTiming.transferSize();
mEncodedBodySize = aTiming.encodedBodySize();
}
RefPtr<RecordStopRequestDelta> timing;
TimeStamp start = TimeStamp::Now();
if (StaticPrefs::network_send_OnDataFinished()) {
timing = new RecordStopRequestDelta;
mEventQ->RunOrEnqueue(new ChannelFunctionEvent(
[self = UnsafePtr<HttpChannelChild>(this)]() {
return self->GetODATarget();
},
[self = UnsafePtr<HttpChannelChild>(this), status = aChannelStatus,
start, timing]() {
TimeStamp now = TimeStamp::Now();
TimeDuration delay = now - start;
glean::networking::http_content_ondatafinished_delay
.AccumulateRawDuration(delay);
timing->mOnDataFinishedTime = now;
self->SendOnDataFinished(status);
}));
}
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this, [self = UnsafePtr<HttpChannelChild>(this), aChannelStatus, aTiming,
aResponseTrailers,
consoleReports = CopyableTArray{aConsoleReports.Clone()},
aFromSocketProcess, start, timing]() mutable {
TimeStamp now = TimeStamp::Now();
TimeDuration delay = now - start;
glean::networking::http_content_onstop_delay.AccumulateRawDuration(
delay);
if (timing) {
timing->mOnStopRequestTime = now;
}
self->OnStopRequest(aChannelStatus, aTiming, aResponseTrailers);
if (!aFromSocketProcess) {
self->DoOnConsoleReport(std::move(consoleReports));
self->ContinueOnStopRequest();
}
}));
}
void HttpChannelChild::ProcessOnConsoleReport(
nsTArray<ConsoleReportCollected>&& aConsoleReports) {
LOG(("HttpChannelChild::ProcessOnConsoleReport [this=%p]\n", this));
MOZ_ASSERT(OnSocketThread());
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this,
[self = UnsafePtr<HttpChannelChild>(this),
consoleReports = CopyableTArray{aConsoleReports.Clone()}]() mutable {
self->DoOnConsoleReport(std::move(consoleReports));
self->ContinueOnStopRequest();
}));
}
void HttpChannelChild::DoOnConsoleReport(
nsTArray<ConsoleReportCollected>&& aConsoleReports) {
if (aConsoleReports.IsEmpty()) {
return;
}
for (ConsoleReportCollected& report : aConsoleReports) {
if (report.propertiesFile() <
nsContentUtils::PropertiesFile::PropertiesFile_COUNT) {
AddConsoleReport(report.errorFlags(), report.category(),
nsContentUtils::PropertiesFile(report.propertiesFile()),
report.sourceFileURI(), report.lineNumber(),
report.columnNumber(), report.messageName(),
report.stringParams());
}
}
MaybeFlushConsoleReports();
}
void HttpChannelChild::RecordChannelCompletionDurationForEarlyHint() {
if (!mLoadGroup) {
return;
}
uint32_t earlyHintType = 0;
nsCOMPtr<nsIRequest> req;
Unused << mLoadGroup->GetDefaultLoadRequest(getter_AddRefs(req));
if (nsCOMPtr<nsIHttpChannelInternal> httpChannel = do_QueryInterface(req)) {
Unused << httpChannel->GetEarlyHintLinkType(&earlyHintType);
}
if (!earlyHintType) {
return;
}
nsAutoCString earlyHintKey;
if (mIsFromCache) {
earlyHintKey.Append("cache_"_ns);
} else {
earlyHintKey.Append("net_"_ns);
}
if (earlyHintType & LinkStyle::ePRECONNECT) {
earlyHintKey.Append("preconnect_"_ns);
}
if (earlyHintType & LinkStyle::ePRELOAD) {
earlyHintKey.Append("preload_"_ns);
earlyHintKey.Append(mEarlyHintPreloaderId ? "1"_ns : "0"_ns);
}
Telemetry::AccumulateTimeDelta(Telemetry::EH_PERF_CHANNEL_COMPLETION_TIME,
earlyHintKey, mAsyncOpenTime,
TimeStamp::Now());
}
void HttpChannelChild::OnStopRequest(
const nsresult& aChannelStatus, const ResourceTimingStructArgs& aTiming,
const nsHttpHeaderArray& aResponseTrailers) {
LOG(("HttpChannelChild::OnStopRequest [this=%p status=%" PRIx32 "]\n", this,
static_cast<uint32_t>(aChannelStatus)));
MOZ_ASSERT(NS_IsMainThread());
// If this channel was aborted by ActorDestroy, then there may be other
// OnStartRequest/OnStopRequest/OnDataAvailable IPC messages that need to
// be handled. In that case we just ignore them to avoid calling the listener
// twice.
if (LoadOnStopRequestCalled() && mIPCActorDeleted) {
return;
}
nsCOMPtr<nsICompressConvStats> conv = do_QueryInterface(mCompressListener);
if (conv) {
conv->GetDecodedDataLength(&mDecodedBodySize);
}
ResourceTimingStructArgsToTimingsStruct(aTiming, mTransactionTimings);
// Do not overwrite or adjust the original mAsyncOpenTime by timing.fetchStart
// We must use the original child process time in order to account for child
// side work and IPC transit overhead.
// XXX: This depends on TimeStamp being equivalent across processes.
// This is true for modern hardware but for older platforms it is not always
// true.
mRedirectStartTimeStamp = aTiming.redirectStart();
mRedirectEndTimeStamp = aTiming.redirectEnd();
// mTransferSize and mEncodedBodySize are set in ProcessOnStopRequest
// TODO: check if we need to move assignments of other members to
// ProcessOnStopRequest
mCacheReadStart = aTiming.cacheReadStart();
mCacheReadEnd = aTiming.cacheReadEnd();
const TimeStamp now = TimeStamp::Now();
if (profiler_thread_is_being_profiled_for_markers()) {
nsAutoCString requestMethod;
GetRequestMethod(requestMethod);
nsAutoCString contentType;
if (mResponseHead) {
mResponseHead->ContentType(contentType);
}
int32_t priority = PRIORITY_NORMAL;
GetPriority(&priority);
profiler_add_network_marker(
mURI, requestMethod, priority, mChannelId, NetworkLoadType::LOAD_STOP,
mLastStatusReported, now, mTransferSize, kCacheUnknown,
mLoadInfo->GetInnerWindowID(),
mLoadInfo->GetOriginAttributes().mPrivateBrowsingId > 0,
&mTransactionTimings, std::move(mSource),
Some(nsDependentCString(contentType.get())));
}
RecordChannelCompletionDurationForEarlyHint();
TimeDuration channelCompletionDuration = now - mAsyncOpenTime;
if (mIsFromCache) {
PerfStats::RecordMeasurement(PerfStats::Metric::HttpChannelCompletion_Cache,
channelCompletionDuration);
} else {
PerfStats::RecordMeasurement(
PerfStats::Metric::HttpChannelCompletion_Network,
channelCompletionDuration);
}
PerfStats::RecordMeasurement(PerfStats::Metric::HttpChannelCompletion,
channelCompletionDuration);
if (!aTiming.responseEnd().IsNull()) {
nsAutoCString cosString;
ClassOfService::ToString(mClassOfService, cosString);
Telemetry::AccumulateTimeDelta(
Telemetry::NETWORK_RESPONSE_END_PARENT_TO_CONTENT_MS, cosString,
aTiming.responseEnd(), now);
PerfStats::RecordMeasurement(
PerfStats::Metric::HttpChannelResponseEndParentToContent,
now - aTiming.responseEnd());
}
if (!mOnStopRequestStartTime.IsNull()) {
PerfStats::RecordMeasurement(PerfStats::Metric::OnStopRequestToContent,
now - mOnStopRequestStartTime);
}
mResponseTrailers = MakeUnique<nsHttpHeaderArray>(aResponseTrailers);
DoPreOnStopRequest(aChannelStatus);
{ // We must flush the queue before we Send__delete__
// (although we really shouldn't receive any msgs after OnStop),
// so make sure this goes out of scope before then.
AutoEventEnqueuer ensureSerialDispatch(mEventQ);
DoOnStopRequest(this, aChannelStatus);
// DoOnStopRequest() calls ReleaseListeners()
}
}
void HttpChannelChild::ContinueOnStopRequest() {
// If we're a multi-part stream, then don't cleanup yet, and we'll do so
// in OnAfterLastPart.
if (mMultiPartID) {
LOG(
("HttpChannelChild::OnStopRequest - Expecting future parts on a "
"multipart channel postpone cleaning up."));
return;
}
CollectMixedContentTelemetry();
CleanupBackgroundChannel();
// If there is a possibility we might want to write alt data to the cache
// entry, we keep the channel alive. We still send the DocumentChannelCleanup
// message but request the cache entry to be kept by the parent.
// If the channel has failed, the cache entry is in a non-writtable state and
// we want to release it to not block following consumers.
if (NS_SUCCEEDED(mStatus) && !mPreferredCachedAltDataTypes.IsEmpty()) {
mKeptAlive = true;
SendDocumentChannelCleanup(false); // don't clear cache entry
return;
}
if (mLoadFlags & LOAD_DOCUMENT_URI) {
// Keep IPDL channel open, but only for updating security info.
// If IPDL is already closed, then do nothing.
if (CanSend()) {
mKeptAlive = true;
SendDocumentChannelCleanup(true);
}
} else {
// The parent process will respond by sending a DeleteSelf message and
// making sure not to send any more messages after that.
TrySendDeletingChannel();
}
}
void HttpChannelChild::DoPreOnStopRequest(nsresult aStatus) {
AUTO_PROFILER_LABEL("HttpChannelChild::DoPreOnStopRequest", NETWORK);
LOG(("HttpChannelChild::DoPreOnStopRequest [this=%p status=%" PRIx32 "]\n",
this, static_cast<uint32_t>(aStatus)));
StoreIsPending(false);
MaybeReportTimingData();
if (!mCanceled && NS_SUCCEEDED(mStatus)) {
mStatus = aStatus;
}
CollectOMTTelemetry();
}
void HttpChannelChild::CollectOMTTelemetry() {
MOZ_ASSERT(NS_IsMainThread());
// Only collect telemetry for HTTP channel that is loaded successfully and
// completely.
if (mCanceled || NS_FAILED(mStatus)) {
return;
}
// Use content policy type to accumulate data by usage.
nsAutoCString key(
NS_CP_ContentTypeName(mLoadInfo->InternalContentPolicyType()));
Telemetry::AccumulateCategoricalKeyed(
key, static_cast<LABELS_HTTP_CHILD_OMT_STATS_2>(mOMTResult));
}
// We want to inspect all upgradable mixed content loads
// (i.e., loads point to HTTP from an HTTPS page), for
// resources that stem from audio, video and img elements.
// Of those, we want to measure which succceed and which fail.
// Some double negatives, but we check the following:exempt loads that
// 1) Request was upgraded as mixed passive content
// 2) Request _could_ have been upgraded as mixed passive content if the pref
// had been set and Request wasn't upgraded by any other means (URL isn't https)
void HttpChannelChild::CollectMixedContentTelemetry() {
MOZ_ASSERT(NS_IsMainThread());
bool wasUpgraded = mLoadInfo->GetBrowserDidUpgradeInsecureRequests();
if (!wasUpgraded) {
// If this wasn't upgraded, let's check if it _could_ have been upgraded as
// passive mixed content and that it wasn't upgraded with any other method
if (!mURI->SchemeIs("https") &&
!mLoadInfo->GetBrowserWouldUpgradeInsecureRequests()) {
return;
}
}
// UseCounters require a document.
RefPtr<Document> doc;
mLoadInfo->GetLoadingDocument(getter_AddRefs(doc));
if (!doc) {
return;
}
nsContentPolicyType internalLoadType;
mLoadInfo->GetInternalContentPolicyType(&internalLoadType);
bool statusIsSuccess = NS_SUCCEEDED(mStatus);
if (internalLoadType == nsIContentPolicy::TYPE_INTERNAL_IMAGE) {
if (wasUpgraded) {
doc->SetUseCounter(
statusIsSuccess
? eUseCounter_custom_MixedContentUpgradedImageSuccess
: eUseCounter_custom_MixedContentUpgradedImageFailure);
} else {
doc->SetUseCounter(
statusIsSuccess
? eUseCounter_custom_MixedContentNotUpgradedImageSuccess
: eUseCounter_custom_MixedContentNotUpgradedImageFailure);
}
return;
}
if (internalLoadType == nsIContentPolicy::TYPE_INTERNAL_VIDEO) {
if (wasUpgraded) {
doc->SetUseCounter(
statusIsSuccess
? eUseCounter_custom_MixedContentUpgradedVideoSuccess
: eUseCounter_custom_MixedContentUpgradedVideoFailure);
} else {
doc->SetUseCounter(
statusIsSuccess
? eUseCounter_custom_MixedContentNotUpgradedVideoSuccess
: eUseCounter_custom_MixedContentNotUpgradedVideoFailure);
}
return;
}
if (internalLoadType == nsIContentPolicy::TYPE_INTERNAL_AUDIO) {
if (wasUpgraded) {
doc->SetUseCounter(
statusIsSuccess
? eUseCounter_custom_MixedContentUpgradedAudioSuccess
: eUseCounter_custom_MixedContentUpgradedAudioFailure);
} else {
doc->SetUseCounter(
statusIsSuccess
? eUseCounter_custom_MixedContentNotUpgradedAudioSuccess
: eUseCounter_custom_MixedContentNotUpgradedAudioFailure);
}
}
}
void HttpChannelChild::DoOnStopRequest(nsIRequest* aRequest,
nsresult aChannelStatus) {
AUTO_PROFILER_LABEL("HttpChannelChild::DoOnStopRequest", NETWORK);
LOG(("HttpChannelChild::DoOnStopRequest [this=%p]\n", this));
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(!LoadIsPending());
auto checkForBlockedContent = [&]() {
// NB: We use aChannelStatus here instead of mStatus because if there was an
// nsCORSListenerProxy on this request, it will override the tracking
// protection's return value.
if (UrlClassifierFeatureFactory::IsClassifierBlockingErrorCode(
aChannelStatus) ||
aChannelStatus == NS_ERROR_MALWARE_URI ||
aChannelStatus == NS_ERROR_UNWANTED_URI ||
aChannelStatus == NS_ERROR_BLOCKED_URI ||
aChannelStatus == NS_ERROR_HARMFUL_URI ||
aChannelStatus == NS_ERROR_PHISHING_URI) {
nsCString list, provider, fullhash;
nsresult rv = GetMatchedList(list);
NS_ENSURE_SUCCESS_VOID(rv);
rv = GetMatchedProvider(provider);
NS_ENSURE_SUCCESS_VOID(rv);
rv = GetMatchedFullHash(fullhash);
NS_ENSURE_SUCCESS_VOID(rv);
UrlClassifierCommon::SetBlockedContent(this, aChannelStatus, list,
provider, fullhash);
}
};
checkForBlockedContent();
MaybeLogCOEPError(aChannelStatus);
// See bug 1587686. If the redirect setup is not completed, the post-redirect
// channel will be not opened and mListener will be null.
MOZ_ASSERT(mListener || !LoadWasOpened());
if (!mListener) {
return;
}
MOZ_ASSERT(!LoadOnStopRequestCalled(),
"We should not call OnStopRequest twice");
// notify "http-on-before-stop-request" observers
gHttpHandler->OnBeforeStopRequest(this);
if (mListener) {
nsCOMPtr<nsIStreamListener> listener(mListener);
StoreOnStopRequestCalled(true);
listener->OnStopRequest(aRequest, mStatus);
}
StoreOnStopRequestCalled(true);
// If we're a multi-part stream, then don't cleanup yet, and we'll do so
// in OnAfterLastPart.
if (mMultiPartID) {
LOG(
("HttpChannelChild::DoOnStopRequest - Expecting future parts on a "
"multipart channel not releasing listeners."));
StoreOnStopRequestCalled(false);
StoreOnStartRequestCalled(false);
return;
}
// notify "http-on-stop-request" observers
gHttpHandler->OnStopRequest(this);
ReleaseListeners();
// If a preferred alt-data type was set, the parent would hold a reference to
// the cache entry in case the child calls openAlternativeOutputStream().
// (see nsHttpChannel::OnStopRequest)
if (!mPreferredCachedAltDataTypes.IsEmpty()) {
mAltDataCacheEntryAvailable = mCacheEntryAvailable;
}
mCacheEntryAvailable = false;
if (mLoadGroup) mLoadGroup->RemoveRequest(this, nullptr, mStatus);
}
void HttpChannelChild::ProcessOnProgress(const int64_t& aProgress,
const int64_t& aProgressMax) {
MOZ_ASSERT(OnSocketThread());
LOG(("HttpChannelChild::ProcessOnProgress [this=%p]\n", this));
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this,
[self = UnsafePtr<HttpChannelChild>(this), aProgress, aProgressMax]() {
AutoEventEnqueuer ensureSerialDispatch(self->mEventQ);
self->DoOnProgress(self, aProgress, aProgressMax);
}));
}
void HttpChannelChild::ProcessOnStatus(const nsresult& aStatus) {
MOZ_ASSERT(OnSocketThread());
LOG(("HttpChannelChild::ProcessOnStatus [this=%p]\n", this));
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this, [self = UnsafePtr<HttpChannelChild>(this), aStatus]() {
AutoEventEnqueuer ensureSerialDispatch(self->mEventQ);
self->DoOnStatus(self, aStatus);
}));
}
mozilla::ipc::IPCResult HttpChannelChild::RecvFailedAsyncOpen(
const nsresult& aStatus) {
LOG(("HttpChannelChild::RecvFailedAsyncOpen [this=%p]\n", this));
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this, [self = UnsafePtr<HttpChannelChild>(this), aStatus]() {
self->FailedAsyncOpen(aStatus);
}));
return IPC_OK();
}
// We need to have an implementation of this function just so that we can keep
// all references to mCallOnResume of type HttpChannelChild: it's not OK in C++
// to set a member function ptr to a base class function.
void HttpChannelChild::HandleAsyncAbort() {
HttpAsyncAborter<HttpChannelChild>::HandleAsyncAbort();
// Ignore all the messages from background channel after channel aborted.
CleanupBackgroundChannel();
}
void HttpChannelChild::FailedAsyncOpen(const nsresult& status) {
LOG(("HttpChannelChild::FailedAsyncOpen [this=%p status=%" PRIx32 "]\n", this,
static_cast<uint32_t>(status)));
MOZ_ASSERT(NS_IsMainThread());
// Might be called twice in race condition in theory.
// (one by RecvFailedAsyncOpen, another by
// HttpBackgroundChannelChild::ActorFailed)
if (LoadOnStartRequestCalled()) {
return;
}
if (NS_SUCCEEDED(mStatus)) {
mStatus = status;
}
// We're already being called from IPDL, therefore already "async"
HandleAsyncAbort();
if (CanSend()) {
TrySendDeletingChannel();
}
}
void HttpChannelChild::CleanupBackgroundChannel() {
MutexAutoLock lock(mBgChildMutex);
AUTO_PROFILER_LABEL("HttpChannelChild::CleanupBackgroundChannel", NETWORK);
LOG(("HttpChannelChild::CleanupBackgroundChannel [this=%p bgChild=%p]\n",
this, mBgChild.get()));
mBgInitFailCallback = nullptr;
if (!mBgChild) {
return;
}
RefPtr<HttpBackgroundChannelChild> bgChild = std::move(mBgChild);
MOZ_RELEASE_ASSERT(gSocketTransportService);
if (!OnSocketThread()) {
gSocketTransportService->Dispatch(
NewRunnableMethod("HttpBackgroundChannelChild::OnChannelClosed",
bgChild,
&HttpBackgroundChannelChild::OnChannelClosed),
NS_DISPATCH_NORMAL);
} else {
bgChild->OnChannelClosed();
}
}
void HttpChannelChild::DoNotifyListenerCleanup() {
LOG(("HttpChannelChild::DoNotifyListenerCleanup [this=%p]\n", this));
}
void HttpChannelChild::DoAsyncAbort(nsresult aStatus) {
Unused << AsyncAbort(aStatus);
}
mozilla::ipc::IPCResult HttpChannelChild::RecvDeleteSelf() {
LOG(("HttpChannelChild::RecvDeleteSelf [this=%p]\n", this));
MOZ_ASSERT(NS_IsMainThread());
// The redirection is vetoed. No need to suspend the event queue.
if (mSuspendForWaitCompleteRedirectSetup) {
mSuspendForWaitCompleteRedirectSetup = false;
mEventQ->Resume();
}
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this,
[self = UnsafePtr<HttpChannelChild>(this)]() { self->DeleteSelf(); }));
return IPC_OK();
}
void HttpChannelChild::DeleteSelf() { Send__delete__(this); }
void HttpChannelChild::NotifyOrReleaseListeners(nsresult rv) {
MOZ_ASSERT(NS_IsMainThread());
if (NS_SUCCEEDED(rv) ||
(LoadOnStartRequestCalled() && LoadOnStopRequestCalled())) {
ReleaseListeners();
return;
}
if (NS_SUCCEEDED(mStatus)) {
mStatus = rv;
}
// This is enough what we need. Undelivered notifications will be pushed.
// DoNotifyListener ensures the call to ReleaseListeners when done.
DoNotifyListener();
}
void HttpChannelChild::DoNotifyListener(bool aUseEventQueue) {
LOG(("HttpChannelChild::DoNotifyListener this=%p", this));
MOZ_ASSERT(NS_IsMainThread());
// In case nsHttpChannel::OnStartRequest wasn't called (e.g. due to flag
// LOAD_ONLY_IF_MODIFIED) we want to set LoadAfterOnStartRequestBegun() to
// true before notifying listener.
if (!LoadAfterOnStartRequestBegun()) {
StoreAfterOnStartRequestBegun(true);
}
if (mListener && !LoadOnStartRequestCalled()) {
nsCOMPtr<nsIStreamListener> listener = mListener;
// avoid reentrancy bugs by setting this now
StoreOnStartRequestCalled(true);
listener->OnStartRequest(this);
}
StoreOnStartRequestCalled(true);
if (aUseEventQueue) {
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this, [self = UnsafePtr<HttpChannelChild>(this)] {
self->ContinueDoNotifyListener();
}));
} else {
ContinueDoNotifyListener();
}
}
void HttpChannelChild::ContinueDoNotifyListener() {
LOG(("HttpChannelChild::ContinueDoNotifyListener this=%p", this));
MOZ_ASSERT(NS_IsMainThread());
// Make sure IsPending is set to false. At this moment we are done from
// the point of view of our consumer and we have to report our self
// as not-pending.
StoreIsPending(false);
// notify "http-on-before-stop-request" observers
gHttpHandler->OnBeforeStopRequest(this);
if (mListener && !LoadOnStopRequestCalled()) {
nsCOMPtr<nsIStreamListener> listener = mListener;
StoreOnStopRequestCalled(true);
listener->OnStopRequest(this, mStatus);
}
StoreOnStopRequestCalled(true);
// notify "http-on-stop-request" observers
gHttpHandler->OnStopRequest(this);
// This channel has finished its job, potentially release any tail-blocked
// requests with this.
RemoveAsNonTailRequest();
// We have to make sure to drop the references to listeners and callbacks
// no longer needed.
ReleaseListeners();
DoNotifyListenerCleanup();
// If this is a navigation, then we must let the docshell flush the reports
// to the console later. The LoadDocument() is pointing at the detached
// document that started the navigation. We want to show the reports on the
// new document. Otherwise the console is wiped and the user never sees
// the information.
if (!IsNavigation()) {
if (mLoadGroup) {
FlushConsoleReports(mLoadGroup);
} else {
RefPtr<dom::Document> doc;
mLoadInfo->GetLoadingDocument(getter_AddRefs(doc));
FlushConsoleReports(doc);
}
}
}
mozilla::ipc::IPCResult HttpChannelChild::RecvReportSecurityMessage(
const nsAString& messageTag, const nsAString& messageCategory) {
DebugOnly<nsresult> rv = AddSecurityMessage(messageTag, messageCategory);
MOZ_ASSERT(NS_SUCCEEDED(rv));
return IPC_OK();
}
mozilla::ipc::IPCResult HttpChannelChild::RecvRedirect1Begin(
const uint32_t& aRegistrarId, nsIURI* aNewUri,
const uint32_t& aNewLoadFlags, const uint32_t& aRedirectFlags,
const ParentLoadInfoForwarderArgs& aLoadInfoForwarder,
const nsHttpResponseHead& aResponseHead,
nsITransportSecurityInfo* aSecurityInfo, const uint64_t& aChannelId,
const NetAddr& aOldPeerAddr, const ResourceTimingStructArgs& aTiming) {
// TODO: handle security info
LOG(("HttpChannelChild::RecvRedirect1Begin [this=%p]\n", this));
// We set peer address of child to the old peer,
// Then it will be updated to new peer in OnStartRequest
mPeerAddr = aOldPeerAddr;
// Cookies headers should not be visible to the child process
MOZ_ASSERT(!nsHttpResponseHead(aResponseHead).HasHeader(nsHttp::Set_Cookie));
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this, [self = UnsafePtr<HttpChannelChild>(this), aRegistrarId,
newUri = RefPtr{aNewUri}, aNewLoadFlags, aRedirectFlags,
aLoadInfoForwarder, aResponseHead,
aSecurityInfo = nsCOMPtr{aSecurityInfo}, aChannelId, aTiming]() {
self->Redirect1Begin(aRegistrarId, newUri, aNewLoadFlags,
aRedirectFlags, aLoadInfoForwarder, aResponseHead,
aSecurityInfo, aChannelId, aTiming);
}));
return IPC_OK();
}
nsresult HttpChannelChild::SetupRedirect(nsIURI* uri,
const nsHttpResponseHead* responseHead,
const uint32_t& redirectFlags,
nsIChannel** outChannel) {
LOG(("HttpChannelChild::SetupRedirect [this=%p]\n", this));
if (mCanceled) {
return NS_ERROR_ABORT;
}
nsresult rv;
nsCOMPtr<nsIIOService> ioService;
rv = gHttpHandler->GetIOService(getter_AddRefs(ioService));
NS_ENSURE_SUCCESS(rv, rv);
nsCOMPtr<nsIChannel> newChannel;
nsCOMPtr<nsILoadInfo> redirectLoadInfo =
CloneLoadInfoForRedirect(uri, redirectFlags);
rv = NS_NewChannelInternal(getter_AddRefs(newChannel), uri, redirectLoadInfo,
nullptr, // PerformanceStorage
nullptr, // aLoadGroup
nullptr, // aCallbacks
nsIRequest::LOAD_NORMAL, ioService);
NS_ENSURE_SUCCESS(rv, rv);
// We won't get OnStartRequest, set cookies here.
mResponseHead = MakeUnique<nsHttpResponseHead>(*responseHead);
bool rewriteToGET = HttpBaseChannel::ShouldRewriteRedirectToGET(
mResponseHead->Status(), mRequestHead.ParsedMethod());
rv = SetupReplacementChannel(uri, newChannel, !rewriteToGET, redirectFlags);
NS_ENSURE_SUCCESS(rv, rv);
mRedirectChannelChild = do_QueryInterface(newChannel);
newChannel.forget(outChannel);
return NS_OK;
}
void HttpChannelChild::Redirect1Begin(
const uint32_t& registrarId, nsIURI* newOriginalURI,
const uint32_t& newLoadFlags, const uint32_t& redirectFlags,
const ParentLoadInfoForwarderArgs& loadInfoForwarder,
const nsHttpResponseHead& responseHead,
nsITransportSecurityInfo* securityInfo, const uint64_t& channelId,
const ResourceTimingStructArgs& timing) {
nsresult rv;
LOG(("HttpChannelChild::Redirect1Begin [this=%p]\n", this));
MOZ_ASSERT(newOriginalURI, "newOriginalURI should not be null");
ipc::MergeParentLoadInfoForwarder(loadInfoForwarder, mLoadInfo);
ResourceTimingStructArgsToTimingsStruct(timing, mTransactionTimings);
if (profiler_thread_is_being_profiled_for_markers()) {
nsAutoCString requestMethod;
GetRequestMethod(requestMethod);
nsAutoCString contentType;
responseHead.ContentType(contentType);
profiler_add_network_marker(
mURI, requestMethod, mPriority, mChannelId,
NetworkLoadType::LOAD_REDIRECT, mLastStatusReported, TimeStamp::Now(),
0, kCacheUnknown, mLoadInfo->GetInnerWindowID(),
mLoadInfo->GetOriginAttributes().mPrivateBrowsingId > 0,
&mTransactionTimings, std::move(mSource),
Some(nsDependentCString(contentType.get())), newOriginalURI,
redirectFlags, channelId);
}
mSecurityInfo = securityInfo;
nsCOMPtr<nsIChannel> newChannel;
rv = SetupRedirect(newOriginalURI, &responseHead, redirectFlags,
getter_AddRefs(newChannel));
if (NS_SUCCEEDED(rv)) {
MOZ_ALWAYS_SUCCEEDS(newChannel->SetLoadFlags(newLoadFlags));
if (mRedirectChannelChild) {
// Set the channelId allocated in parent to the child instance
nsCOMPtr<nsIHttpChannel> httpChannel =
do_QueryInterface(mRedirectChannelChild);
if (httpChannel) {
rv = httpChannel->SetChannelId(channelId);
MOZ_ASSERT(NS_SUCCEEDED(rv));
}
mRedirectChannelChild->ConnectParent(registrarId);
}
nsCOMPtr<nsISerialEventTarget> target = GetNeckoTarget();
MOZ_ASSERT(target);
rv = gHttpHandler->AsyncOnChannelRedirect(this, newChannel, redirectFlags,
target);
}
if (NS_FAILED(rv)) OnRedirectVerifyCallback(rv);
}
mozilla::ipc::IPCResult HttpChannelChild::RecvRedirect3Complete() {
LOG(("HttpChannelChild::RecvRedirect3Complete [this=%p]\n", this));
nsCOMPtr<nsIChannel> redirectChannel =
do_QueryInterface(mRedirectChannelChild);
MOZ_ASSERT(redirectChannel);
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this, [self = UnsafePtr<HttpChannelChild>(this), redirectChannel]() {
nsresult rv = NS_OK;
Unused << self->GetStatus(&rv);
if (NS_FAILED(rv)) {
// Pre-redirect channel was canceled. Call |HandleAsyncAbort|, so
// mListener's OnStart/StopRequest can be called. Nothing else will
// trigger these notification after this point.
// We do this before |CompleteRedirectSetup|, so post-redirect channel
// stays unopened and we also make sure that OnStart/StopRequest won't
// be called twice.
self->HandleAsyncAbort();
nsCOMPtr<nsIHttpChannelChild> chan =
do_QueryInterface(redirectChannel);
RefPtr<HttpChannelChild> httpChannelChild =
static_cast<HttpChannelChild*>(chan.get());
if (httpChannelChild) {
// For sending an IPC message to parent channel so that the loading
// can be cancelled.
Unused << httpChannelChild->CancelWithReason(
rv, "HttpChannelChild Redirect3 failed"_ns);
// The post-redirect channel could still get OnStart/StopRequest IPC
// messages from parent, but the mListener is still null. So, we
// call |DoNotifyListener| to pretend that OnStart/StopRequest are
// already called.
httpChannelChild->DoNotifyListener();
}
return;
}
self->Redirect3Complete();
}));
return IPC_OK();
}
mozilla::ipc::IPCResult HttpChannelChild::RecvRedirectFailed(
const nsresult& status) {
LOG(("HttpChannelChild::RecvRedirectFailed this=%p status=%X\n", this,
static_cast<uint32_t>(status)));
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this, [self = UnsafePtr<HttpChannelChild>(this), status]() {
nsCOMPtr<nsIRedirectResultListener> vetoHook;
self->GetCallback(vetoHook);
if (vetoHook) {
vetoHook->OnRedirectResult(status);
}
if (RefPtr<HttpChannelChild> httpChannelChild =
do_QueryObject(self->mRedirectChannelChild)) {
// For sending an IPC message to parent channel so that the loading
// can be cancelled.
Unused << httpChannelChild->CancelWithReason(
status, "HttpChannelChild RecvRedirectFailed"_ns);
// The post-redirect channel could still get OnStart/StopRequest IPC
// messages from parent, but the mListener is still null. So, we
// call |DoNotifyListener| to pretend that OnStart/StopRequest are
// already called.
httpChannelChild->DoNotifyListener();
}
}));
return IPC_OK();
}
void HttpChannelChild::ProcessNotifyClassificationFlags(
uint32_t aClassificationFlags, bool aIsThirdParty) {
LOG(
("HttpChannelChild::ProcessNotifyClassificationFlags thirdparty=%d "
"flags=%" PRIu32 " [this=%p]\n",
static_cast<int>(aIsThirdParty), aClassificationFlags, this));
MOZ_ASSERT(OnSocketThread());
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this, [self = UnsafePtr<HttpChannelChild>(this), aClassificationFlags,
aIsThirdParty]() {
self->AddClassificationFlags(aClassificationFlags, aIsThirdParty);
}));
}
void HttpChannelChild::ProcessSetClassifierMatchedInfo(
const nsACString& aList, const nsACString& aProvider,
const nsACString& aFullHash) {
LOG(("HttpChannelChild::ProcessSetClassifierMatchedInfo [this=%p]\n", this));
MOZ_ASSERT(OnSocketThread());
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this,
[self = UnsafePtr<HttpChannelChild>(this), aList = nsCString(aList),
aProvider = nsCString(aProvider), aFullHash = nsCString(aFullHash)]() {
self->SetMatchedInfo(aList, aProvider, aFullHash);
}));
}
void HttpChannelChild::ProcessSetClassifierMatchedTrackingInfo(
const nsACString& aLists, const nsACString& aFullHashes) {
LOG(("HttpChannelChild::ProcessSetClassifierMatchedTrackingInfo [this=%p]\n",
this));
MOZ_ASSERT(OnSocketThread());
nsTArray<nsCString> lists, fullhashes;
for (const nsACString& token : aLists.Split(',')) {
lists.AppendElement(token);
}
for (const nsACString& token : aFullHashes.Split(',')) {
fullhashes.AppendElement(token);
}
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this, [self = UnsafePtr<HttpChannelChild>(this),
lists = CopyableTArray{std::move(lists)},
fullhashes = CopyableTArray{std::move(fullhashes)}]() {
self->SetMatchedTrackingInfo(lists, fullhashes);
}));
}
// Completes the redirect and cleans up the old channel.
void HttpChannelChild::Redirect3Complete() {
LOG(("HttpChannelChild::Redirect3Complete [this=%p]\n", this));
MOZ_ASSERT(NS_IsMainThread());
// Using an error as the default so that when we fail to forward this redirect
// to the target channel, we make sure to notify the current listener from
// CleanupRedirectingChannel.
nsresult rv = NS_BINDING_ABORTED;
nsCOMPtr<nsIRedirectResultListener> vetoHook;
GetCallback(vetoHook);
if (vetoHook) {
vetoHook->OnRedirectResult(NS_OK);
}
// Chrome channel has been AsyncOpen'd. Reflect this in child.
if (mRedirectChannelChild) {
rv = mRedirectChannelChild->CompleteRedirectSetup(mListener);
#ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED
mSuccesfullyRedirected = NS_SUCCEEDED(rv);
#endif
}
CleanupRedirectingChannel(rv);
}
void HttpChannelChild::CleanupRedirectingChannel(nsresult rv) {
// Redirecting to new channel: shut this down and init new channel
if (mLoadGroup) mLoadGroup->RemoveRequest(this, nullptr, NS_BINDING_ABORTED);
if (NS_SUCCEEDED(rv)) {
mLoadInfo->AppendRedirectHistoryEntry(this, false);
} else {
NS_WARNING("CompleteRedirectSetup failed, HttpChannelChild already open?");
}
// Release ref to new channel.
mRedirectChannelChild = nullptr;
NotifyOrReleaseListeners(rv);
CleanupBackgroundChannel();
}
//-----------------------------------------------------------------------------
// HttpChannelChild::nsIChildChannel
//-----------------------------------------------------------------------------
NS_IMETHODIMP
HttpChannelChild::ConnectParent(uint32_t registrarId) {
LOG(("HttpChannelChild::ConnectParent [this=%p, id=%" PRIu32 "]\n", this,
registrarId));
MOZ_ASSERT(NS_IsMainThread());
mozilla::dom::BrowserChild* browserChild = nullptr;
nsCOMPtr<nsIBrowserChild> iBrowserChild;
GetCallback(iBrowserChild);
if (iBrowserChild) {
browserChild =
static_cast<mozilla::dom::BrowserChild*>(iBrowserChild.get());
}
if (browserChild && !browserChild->IPCOpen()) {
return NS_ERROR_FAILURE;
}
ContentChild* cc = static_cast<ContentChild*>(gNeckoChild->Manager());
if (cc->IsShuttingDown()) {
return NS_ERROR_FAILURE;
}
HttpBaseChannel::SetDocshellUserAgentOverride();
// This must happen before the constructor message is sent. Otherwise messages
// from the parent could arrive quickly and be delivered to the wrong event
// target.
SetEventTarget();
if (browserChild) {
MOZ_ASSERT(browserChild->WebNavigation());
if (BrowsingContext* bc = browserChild->GetBrowsingContext()) {
mBrowserId = bc->BrowserId();
}
}
HttpChannelConnectArgs connectArgs(registrarId);
if (!gNeckoChild->SendPHttpChannelConstructor(
this, browserChild, IPC::SerializedLoadContext(this), connectArgs)) {
return NS_ERROR_FAILURE;
}
{
MutexAutoLock lock(mBgChildMutex);
MOZ_ASSERT(!mBgChild);
MOZ_ASSERT(!mBgInitFailCallback);
mBgInitFailCallback = NewRunnableMethod<nsresult>(
"HttpChannelChild::OnRedirectVerifyCallback", this,
&HttpChannelChild::OnRedirectVerifyCallback, NS_ERROR_FAILURE);
RefPtr<HttpBackgroundChannelChild> bgChild =
new HttpBackgroundChannelChild();
MOZ_RELEASE_ASSERT(gSocketTransportService);
RefPtr<HttpChannelChild> self = this;
nsresult rv = gSocketTransportService->Dispatch(
NewRunnableMethod<RefPtr<HttpChannelChild>>(
"HttpBackgroundChannelChild::Init", bgChild,
&HttpBackgroundChannelChild::Init, std::move(self)),
NS_DISPATCH_NORMAL);
if (NS_WARN_IF(NS_FAILED(rv))) {
return rv;
}
mBgChild = std::move(bgChild);
#ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED
mEverHadBgChildAtConnectParent = true;
#endif
}
// Should wait for CompleteRedirectSetup to set the listener.
mEventQ->Suspend();
MOZ_ASSERT(!mSuspendForWaitCompleteRedirectSetup);
mSuspendForWaitCompleteRedirectSetup = true;
// Connect to socket process after mEventQ is suspended.
MaybeConnectToSocketProcess();
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::CompleteRedirectSetup(nsIStreamListener* aListener) {
LOG(("HttpChannelChild::CompleteRedirectSetup [this=%p]\n", this));
MOZ_ASSERT(NS_IsMainThread());
NS_ENSURE_TRUE(!LoadIsPending(), NS_ERROR_IN_PROGRESS);
NS_ENSURE_TRUE(!LoadWasOpened(), NS_ERROR_ALREADY_OPENED);
// Resume the suspension in ConnectParent.
auto eventQueueResumeGuard = MakeScopeExit([&] {
MOZ_ASSERT(mSuspendForWaitCompleteRedirectSetup);
mEventQ->Resume();
mSuspendForWaitCompleteRedirectSetup = false;
});
/*
* No need to check for cancel: we don't get here if nsHttpChannel canceled
* before AsyncOpen(); if it's canceled after that, OnStart/Stop will just
* get called with error code as usual. So just setup mListener and make the
* channel reflect AsyncOpen'ed state.
*/
mLastStatusReported = TimeStamp::Now();
if (profiler_thread_is_being_profiled_for_markers()) {
nsAutoCString requestMethod;
GetRequestMethod(requestMethod);
profiler_add_network_marker(
mURI, requestMethod, mPriority, mChannelId, NetworkLoadType::LOAD_START,
mChannelCreationTimestamp, mLastStatusReported, 0, kCacheUnknown,
mLoadInfo->GetInnerWindowID(),
mLoadInfo->GetOriginAttributes().mPrivateBrowsingId > 0);
}
StoreIsPending(true);
StoreWasOpened(true);
mListener = aListener;
// add ourselves to the load group.
if (mLoadGroup) mLoadGroup->AddRequest(this, nullptr);
// We already have an open IPDL connection to the parent. If on-modify-request
// listeners or load group observers canceled us, let the parent handle it
// and send it back to us naturally.
return NS_OK;
}
//-----------------------------------------------------------------------------
// HttpChannelChild::nsIAsyncVerifyRedirectCallback
//-----------------------------------------------------------------------------
NS_IMETHODIMP
HttpChannelChild::OnRedirectVerifyCallback(nsresult aResult) {
LOG(("HttpChannelChild::OnRedirectVerifyCallback [this=%p]\n", this));
MOZ_ASSERT(NS_IsMainThread());
nsCOMPtr<nsIURI> redirectURI;
DebugOnly<nsresult> rv = NS_OK;
nsCOMPtr<nsIHttpChannel> newHttpChannel =
do_QueryInterface(mRedirectChannelChild);
if (NS_SUCCEEDED(aResult) && !mRedirectChannelChild) {
// mRedirectChannelChild doesn't exist means we're redirecting to a protocol
// that doesn't implement nsIChildChannel. The redirect result should be set
// as failed by veto listeners and shouldn't enter this condition. As the
// last resort, we synthesize the error result as NS_ERROR_DOM_BAD_URI here
// to let nsHttpChannel::ContinueProcessResponse2 know it's redirecting to
// another protocol and throw an error.
LOG((" redirecting to a protocol that doesn't implement nsIChildChannel"));
aResult = NS_ERROR_DOM_BAD_URI;
}
nsCOMPtr<nsIReferrerInfo> referrerInfo;
if (newHttpChannel) {
// Must not be called until after redirect observers called.
newHttpChannel->SetOriginalURI(mOriginalURI);
referrerInfo = newHttpChannel->GetReferrerInfo();
}
RequestHeaderTuples emptyHeaders;
RequestHeaderTuples* headerTuples = &emptyHeaders;
nsLoadFlags loadFlags = 0;
Maybe<CorsPreflightArgs> corsPreflightArgs;
nsCOMPtr<nsIHttpChannelChild> newHttpChannelChild =
do_QueryInterface(mRedirectChannelChild);
if (newHttpChannelChild && NS_SUCCEEDED(aResult)) {
rv = newHttpChannelChild->AddCookiesToRequest();
MOZ_ASSERT(NS_SUCCEEDED(rv));
rv = newHttpChannelChild->GetClientSetRequestHeaders(&headerTuples);
MOZ_ASSERT(NS_SUCCEEDED(rv));
newHttpChannelChild->GetClientSetCorsPreflightParameters(corsPreflightArgs);
}
if (NS_SUCCEEDED(aResult)) {
// Note: this is where we would notify "http-on-modify-response" observers.
// We have deliberately disabled this for child processes (see bug 806753)
//
// After we verify redirect, nsHttpChannel may hit the network: must give
// "http-on-modify-request" observers the chance to cancel before that.
// base->CallOnModifyRequestObservers();
nsCOMPtr<nsIHttpChannelInternal> newHttpChannelInternal =
do_QueryInterface(mRedirectChannelChild);
if (newHttpChannelInternal) {
Unused << newHttpChannelInternal->GetApiRedirectToURI(
getter_AddRefs(redirectURI));
}
nsCOMPtr<nsIRequest> request = do_QueryInterface(mRedirectChannelChild);
if (request) {
request->GetLoadFlags(&loadFlags);
}
}
uint32_t sourceRequestBlockingReason = 0;
mLoadInfo->GetRequestBlockingReason(&sourceRequestBlockingReason);
Maybe<ChildLoadInfoForwarderArgs> targetLoadInfoForwarder;
nsCOMPtr<nsIChannel> newChannel = do_QueryInterface(mRedirectChannelChild);
if (newChannel) {
ChildLoadInfoForwarderArgs args;
nsCOMPtr<nsILoadInfo> loadInfo = newChannel->LoadInfo();
LoadInfoToChildLoadInfoForwarder(loadInfo, &args);
targetLoadInfoForwarder.emplace(args);
}
if (CanSend()) {
SendRedirect2Verify(aResult, *headerTuples, sourceRequestBlockingReason,
targetLoadInfoForwarder, loadFlags, referrerInfo,
redirectURI, corsPreflightArgs);
}
return NS_OK;
}
//-----------------------------------------------------------------------------
// HttpChannelChild::nsIRequest
//-----------------------------------------------------------------------------
NS_IMETHODIMP HttpChannelChild::SetCanceledReason(const nsACString& aReason) {
return SetCanceledReasonImpl(aReason);
}
NS_IMETHODIMP HttpChannelChild::GetCanceledReason(nsACString& aReason) {
return GetCanceledReasonImpl(aReason);
}
NS_IMETHODIMP
HttpChannelChild::CancelWithReason(nsresult aStatus,
const nsACString& aReason) {
return CancelWithReasonImpl(aStatus, aReason);
}
NS_IMETHODIMP
HttpChannelChild::Cancel(nsresult aStatus) {
LOG(("HttpChannelChild::Cancel [this=%p, status=%" PRIx32 "]\n", this,
static_cast<uint32_t>(aStatus)));
// only logging on parent is necessary
Maybe<nsCString> logStack = CallingScriptLocationString();
Maybe<nsCString> logOnParent;
if (logStack.isSome()) {
logOnParent = Some(""_ns);
logOnParent->AppendPrintf(
"[this=%p] cancelled call in child process from script: %s", this,
logStack->get());
}
MOZ_ASSERT(NS_IsMainThread());
if (!mCanceled) {
// If this cancel occurs before nsHttpChannel has been set up, AsyncOpen
// is responsible for cleaning up.
mCanceled = true;
mStatus = aStatus;
bool remoteChannelExists = RemoteChannelExists();
#ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED
mCanSendAtCancel = CanSend();
mRemoteChannelExistedAtCancel = remoteChannelExists;
#endif
if (remoteChannelExists) {
SendCancel(aStatus, mLoadInfo->GetRequestBlockingReason(),
mCanceledReason, logOnParent);
} else if (MOZ_UNLIKELY(!LoadOnStartRequestCalled() ||
!LoadOnStopRequestCalled())) {
Unused << AsyncAbort(mStatus);
}
}
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::Suspend() {
LOG(("HttpChannelChild::Suspend [this=%p, mSuspendCount=%" PRIu32 "\n", this,
mSuspendCount + 1));
MOZ_ASSERT(NS_IsMainThread());
LogCallingScriptLocation(this);
// SendSuspend only once, when suspend goes from 0 to 1.
// Don't SendSuspend at all if we're diverting callbacks to the parent;
// suspend will be called at the correct time in the parent itself.
if (!mSuspendCount++) {
if (RemoteChannelExists()) {
SendSuspend();
mSuspendSent = true;
}
}
mEventQ->Suspend();
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::Resume() {
LOG(("HttpChannelChild::Resume [this=%p, mSuspendCount=%" PRIu32 "\n", this,
mSuspendCount - 1));
MOZ_ASSERT(NS_IsMainThread());
NS_ENSURE_TRUE(mSuspendCount > 0, NS_ERROR_UNEXPECTED);
LogCallingScriptLocation(this);
nsresult rv = NS_OK;
// SendResume only once, when suspend count drops to 0.
// Don't SendResume at all if we're diverting callbacks to the parent (unless
// suspend was sent earlier); otherwise, resume will be called at the correct
// time in the parent itself.
if (!--mSuspendCount) {
if (RemoteChannelExists() && mSuspendSent) {
SendResume();
}
if (mCallOnResume) {
nsCOMPtr<nsISerialEventTarget> neckoTarget = GetNeckoTarget();
MOZ_ASSERT(neckoTarget);
RefPtr<HttpChannelChild> self = this;
std::function<nsresult(HttpChannelChild*)> callOnResume = nullptr;
std::swap(callOnResume, mCallOnResume);
rv = neckoTarget->Dispatch(
NS_NewRunnableFunction(
"net::HttpChannelChild::mCallOnResume",
[callOnResume, self{std::move(self)}]() { callOnResume(self); }),
NS_DISPATCH_NORMAL);
}
}
mEventQ->Resume();
return rv;
}
//-----------------------------------------------------------------------------
// HttpChannelChild::nsIChannel
//-----------------------------------------------------------------------------
NS_IMETHODIMP
HttpChannelChild::GetSecurityInfo(nsITransportSecurityInfo** aSecurityInfo) {
NS_ENSURE_ARG_POINTER(aSecurityInfo);
*aSecurityInfo = do_AddRef(mSecurityInfo).take();
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::AsyncOpen(nsIStreamListener* aListener) {
LOG(("HttpChannelChild::AsyncOpen [this=%p uri=%s]\n", this, mSpec.get()));
nsresult rv = AsyncOpenInternal(aListener);
if (NS_FAILED(rv)) {
uint32_t blockingReason = 0;
mLoadInfo->GetRequestBlockingReason(&blockingReason);
LOG(
("HttpChannelChild::AsyncOpen failed [this=%p rv=0x%08x "
"blocking-reason=%u]\n",
this, static_cast<uint32_t>(rv), blockingReason));
gHttpHandler->OnFailedOpeningRequest(this);
}
#ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED
mAsyncOpenSucceeded = NS_SUCCEEDED(rv);
#endif
return rv;
}
nsresult HttpChannelChild::AsyncOpenInternal(nsIStreamListener* aListener) {
nsresult rv;
nsCOMPtr<nsIStreamListener> listener = aListener;
rv = nsContentSecurityManager::doContentSecurityCheck(this, listener);
if (NS_WARN_IF(NS_FAILED(rv))) {
ReleaseListeners();
return rv;
}
MOZ_ASSERT(
mLoadInfo->GetSecurityMode() == 0 ||
mLoadInfo->GetInitialSecurityCheckDone() ||
(mLoadInfo->GetSecurityMode() ==
nsILoadInfo::SEC_ALLOW_CROSS_ORIGIN_SEC_CONTEXT_IS_NULL &&
mLoadInfo->GetLoadingPrincipal() &&
mLoadInfo->GetLoadingPrincipal()->IsSystemPrincipal()),
"security flags in loadInfo but doContentSecurityCheck() not called");
LogCallingScriptLocation(this);
if (!mLoadGroup && !mCallbacks) {
// If no one called SetLoadGroup or SetNotificationCallbacks, the private
// state has not been updated on PrivateBrowsingChannel (which we derive
// from) Hence, we have to call UpdatePrivateBrowsing() here
UpdatePrivateBrowsing();
}
#ifdef DEBUG
AssertPrivateBrowsingId();
#endif
if (mCanceled) {
ReleaseListeners();
return mStatus;
}
NS_ENSURE_TRUE(gNeckoChild != nullptr, NS_ERROR_FAILURE);
NS_ENSURE_ARG_POINTER(listener);
NS_ENSURE_TRUE(!LoadIsPending(), NS_ERROR_IN_PROGRESS);
NS_ENSURE_TRUE(!LoadWasOpened(), NS_ERROR_ALREADY_OPENED);
if (MaybeWaitForUploadStreamNormalization(listener, nullptr)) {
return NS_OK;
}
if (!LoadAsyncOpenTimeOverriden()) {
mAsyncOpenTime = TimeStamp::Now();
}
// Port checked in parent, but duplicate here so we can return with error
// immediately
rv = NS_CheckPortSafety(mURI);
if (NS_FAILED(rv)) {
ReleaseListeners();
return rv;
}
nsAutoCString cookie;
if (NS_SUCCEEDED(mRequestHead.GetHeader(nsHttp::Cookie, cookie))) {
mUserSetCookieHeader = cookie;
}
DebugOnly<nsresult> check = AddCookiesToRequest();
MOZ_ASSERT(NS_SUCCEEDED(check));
//
// NOTE: From now on we must return NS_OK; all errors must be handled via
// OnStart/OnStopRequest
//
// We notify "http-on-opening-request" observers in the child
// process so that devtools can capture a stack trace at the
// appropriate spot. See bug 806753 for some information about why
// other http-* notifications are disabled in child processes.
gHttpHandler->OnOpeningRequest(this);
mLastStatusReported = TimeStamp::Now();
if (profiler_thread_is_being_profiled_for_markers()) {
nsAutoCString requestMethod;
GetRequestMethod(requestMethod);
profiler_add_network_marker(
mURI, requestMethod, mPriority, mChannelId, NetworkLoadType::LOAD_START,
mChannelCreationTimestamp, mLastStatusReported, 0, kCacheUnknown,
mLoadInfo->GetInnerWindowID(),
mLoadInfo->GetOriginAttributes().mPrivateBrowsingId > 0);
}
StoreIsPending(true);
StoreWasOpened(true);
mListener = listener;
if (mCanceled) {
// We may have been canceled already, either by on-modify-request
// listeners or by load group observers; in that case, don't create IPDL
// connection. See nsHttpChannel::AsyncOpen().
ReleaseListeners();
return mStatus;
}
// Set user agent override from docshell
HttpBaseChannel::SetDocshellUserAgentOverride();
rv = ContinueAsyncOpen();
if (NS_FAILED(rv)) {
ReleaseListeners();
}
return rv;
}
// Assigns an nsISerialEventTarget to our IPDL actor so that IPC messages are
// sent to the correct DocGroup/TabGroup.
void HttpChannelChild::SetEventTarget() {
MutexAutoLock lock(mEventTargetMutex);
mNeckoTarget = GetMainThreadSerialEventTarget();
}
already_AddRefed<nsISerialEventTarget> HttpChannelChild::GetNeckoTarget() {
nsCOMPtr<nsISerialEventTarget> target;
{
MutexAutoLock lock(mEventTargetMutex);
target = mNeckoTarget;
}
if (!target) {
target = GetMainThreadSerialEventTarget();
}
return target.forget();
}
already_AddRefed<nsIEventTarget> HttpChannelChild::GetODATarget() {
nsCOMPtr<nsIEventTarget> target;
{
MutexAutoLock lock(mEventTargetMutex);
if (mODATarget) {
target = mODATarget;
} else {
target = mNeckoTarget;
}
}
if (!target) {
target = GetMainThreadSerialEventTarget();
}
return target.forget();
}
nsresult HttpChannelChild::ContinueAsyncOpen() {
nsresult rv;
//
// Send request to the chrome process...
//
mozilla::dom::BrowserChild* browserChild = nullptr;
nsCOMPtr<nsIBrowserChild> iBrowserChild;
GetCallback(iBrowserChild);
if (iBrowserChild) {
browserChild =
static_cast<mozilla::dom::BrowserChild*>(iBrowserChild.get());
}
// This id identifies the inner window's top-level document,
// which changes on every new load or navigation.
uint64_t contentWindowId = 0;
TimeStamp navigationStartTimeStamp;
if (browserChild) {
MOZ_ASSERT(browserChild->WebNavigation());
if (RefPtr<Document> document = browserChild->GetTopLevelDocument()) {
contentWindowId = document->InnerWindowID();
nsDOMNavigationTiming* navigationTiming = document->GetNavigationTiming();
if (navigationTiming) {
navigationStartTimeStamp =
navigationTiming->GetNavigationStartTimeStamp();
}
}
if (BrowsingContext* bc = browserChild->GetBrowsingContext()) {
mBrowserId = bc->BrowserId();
}
}
SetTopLevelContentWindowId(contentWindowId);
if (browserChild && !browserChild->IPCOpen()) {
return NS_ERROR_FAILURE;
}
ContentChild* cc = static_cast<ContentChild*>(gNeckoChild->Manager());
if (cc->IsShuttingDown()) {
return NS_ERROR_FAILURE;
}
// add ourselves to the load group.
if (mLoadGroup) {
mLoadGroup->AddRequest(this, nullptr);
}
HttpChannelOpenArgs openArgs;
// No access to HttpChannelOpenArgs members, but they each have a
// function with the struct name that returns a ref.
openArgs.uri() = mURI;
openArgs.original() = mOriginalURI;
openArgs.doc() = mDocumentURI;
openArgs.apiRedirectTo() = mAPIRedirectToURI;
openArgs.loadFlags() = mLoadFlags;
openArgs.requestHeaders() = mClientSetRequestHeaders;
mRequestHead.Method(openArgs.requestMethod());
openArgs.preferredAlternativeTypes() = mPreferredCachedAltDataTypes.Clone();
openArgs.referrerInfo() = mReferrerInfo;
if (mUploadStream) {
MOZ_ALWAYS_TRUE(SerializeIPCStream(do_AddRef(mUploadStream),
openArgs.uploadStream(),
/* aAllowLazy */ false));
}
Maybe<CorsPreflightArgs> optionalCorsPreflightArgs;
GetClientSetCorsPreflightParameters(optionalCorsPreflightArgs);
// NB: This call forces us to cache mTopWindowURI if we haven't already.
nsCOMPtr<nsIURI> uri;
GetTopWindowURI(mURI, getter_AddRefs(uri));
openArgs.topWindowURI() = mTopWindowURI;
openArgs.preflightArgs() = optionalCorsPreflightArgs;
openArgs.uploadStreamHasHeaders() = LoadUploadStreamHasHeaders();
openArgs.priority() = mPriority;
openArgs.classOfService() = mClassOfService;
openArgs.redirectionLimit() = mRedirectionLimit;
openArgs.allowSTS() = LoadAllowSTS();
openArgs.thirdPartyFlags() = LoadThirdPartyFlags();
openArgs.resumeAt() = mSendResumeAt;
openArgs.startPos() = mStartPos;
openArgs.entityID() = mEntityID;
openArgs.allowSpdy() = LoadAllowSpdy();
openArgs.allowHttp3() = LoadAllowHttp3();
openArgs.allowAltSvc() = LoadAllowAltSvc();
openArgs.beConservative() = LoadBeConservative();
openArgs.bypassProxy() = BypassProxy();
openArgs.tlsFlags() = mTlsFlags;
openArgs.initialRwin() = mInitialRwin;
openArgs.cacheKey() = mCacheKey;
openArgs.blockAuthPrompt() = LoadBlockAuthPrompt();
openArgs.allowStaleCacheContent() = LoadAllowStaleCacheContent();
openArgs.preferCacheLoadOverBypass() = LoadPreferCacheLoadOverBypass();
openArgs.contentTypeHint() = mContentTypeHint;
rv = mozilla::ipc::LoadInfoToLoadInfoArgs(mLoadInfo, &openArgs.loadInfo());
NS_ENSURE_SUCCESS(rv, rv);
EnsureRequestContextID();
openArgs.requestContextID() = mRequestContextID;
openArgs.requestMode() = mRequestMode;
openArgs.redirectMode() = mRedirectMode;
openArgs.channelId() = mChannelId;
openArgs.integrityMetadata() = mIntegrityMetadata;
openArgs.contentWindowId() = contentWindowId;
openArgs.browserId() = mBrowserId;
LOG(("HttpChannelChild::ContinueAsyncOpen this=%p gid=%" PRIu64
" browser id=%" PRIx64,
this, mChannelId, mBrowserId));
openArgs.launchServiceWorkerStart() = mLaunchServiceWorkerStart;
openArgs.launchServiceWorkerEnd() = mLaunchServiceWorkerEnd;
openArgs.dispatchFetchEventStart() = mDispatchFetchEventStart;
openArgs.dispatchFetchEventEnd() = mDispatchFetchEventEnd;
openArgs.handleFetchEventStart() = mHandleFetchEventStart;
openArgs.handleFetchEventEnd() = mHandleFetchEventEnd;
openArgs.forceMainDocumentChannel() = LoadForceMainDocumentChannel();
openArgs.navigationStartTimeStamp() = navigationStartTimeStamp;
openArgs.earlyHintPreloaderId() = mEarlyHintPreloaderId;
openArgs.classicScriptHintCharset() = mClassicScriptHintCharset;
openArgs.isUserAgentHeaderModified() = LoadIsUserAgentHeaderModified();
RefPtr<Document> doc;
mLoadInfo->GetLoadingDocument(getter_AddRefs(doc));
if (doc) {
nsAutoString documentCharacterSet;
doc->GetCharacterSet(documentCharacterSet);
openArgs.documentCharacterSet() = documentCharacterSet;
}
// This must happen before the constructor message is sent. Otherwise messages
// from the parent could arrive quickly and be delivered to the wrong event
// target.
SetEventTarget();
if (!gNeckoChild->SendPHttpChannelConstructor(
this, browserChild, IPC::SerializedLoadContext(this), openArgs)) {
return NS_ERROR_FAILURE;
}
{
MutexAutoLock lock(mBgChildMutex);
MOZ_RELEASE_ASSERT(gSocketTransportService);
// Service worker might use the same HttpChannelChild to do async open
// twice. Need to disconnect with previous background channel before
// creating the new one, to prevent receiving further notification
// from it.
if (mBgChild) {
RefPtr<HttpBackgroundChannelChild> prevBgChild = std::move(mBgChild);
gSocketTransportService->Dispatch(
NewRunnableMethod("HttpBackgroundChannelChild::OnChannelClosed",
prevBgChild,
&HttpBackgroundChannelChild::OnChannelClosed),
NS_DISPATCH_NORMAL);
}
MOZ_ASSERT(!mBgInitFailCallback);
mBgInitFailCallback = NewRunnableMethod<nsresult>(
"HttpChannelChild::FailedAsyncOpen", this,
&HttpChannelChild::FailedAsyncOpen, NS_ERROR_FAILURE);
RefPtr<HttpBackgroundChannelChild> bgChild =
new HttpBackgroundChannelChild();
RefPtr<HttpChannelChild> self = this;
nsresult rv = gSocketTransportService->Dispatch(
NewRunnableMethod<RefPtr<HttpChannelChild>>(
"HttpBackgroundChannelChild::Init", bgChild,
&HttpBackgroundChannelChild::Init, self),
NS_DISPATCH_NORMAL);
if (NS_WARN_IF(NS_FAILED(rv))) {
return rv;
}
mBgChild = std::move(bgChild);
#ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED
mEverHadBgChildAtAsyncOpen = true;
#endif
}
MaybeConnectToSocketProcess();
return NS_OK;
}
//-----------------------------------------------------------------------------
// HttpChannelChild::nsIHttpChannel
//-----------------------------------------------------------------------------
NS_IMETHODIMP
HttpChannelChild::SetRequestHeader(const nsACString& aHeader,
const nsACString& aValue, bool aMerge) {
LOG(("HttpChannelChild::SetRequestHeader [this=%p]\n", this));
nsresult rv = HttpBaseChannel::SetRequestHeader(aHeader, aValue, aMerge);
if (NS_FAILED(rv)) return rv;
RequestHeaderTuple* tuple = mClientSetRequestHeaders.AppendElement();
if (!tuple) return NS_ERROR_OUT_OF_MEMORY;
// Mark that the User-Agent header has been modified.
if (nsHttp::ResolveAtom(aHeader) == nsHttp::User_Agent) {
StoreIsUserAgentHeaderModified(true);
}
tuple->mHeader = aHeader;
tuple->mValue = aValue;
tuple->mMerge = aMerge;
tuple->mEmpty = false;
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::SetEmptyRequestHeader(const nsACString& aHeader) {
LOG(("HttpChannelChild::SetEmptyRequestHeader [this=%p]\n", this));
nsresult rv = HttpBaseChannel::SetEmptyRequestHeader(aHeader);
if (NS_FAILED(rv)) return rv;
RequestHeaderTuple* tuple = mClientSetRequestHeaders.AppendElement();
if (!tuple) return NS_ERROR_OUT_OF_MEMORY;
// Mark that the User-Agent header has been modified.
if (nsHttp::ResolveAtom(aHeader) == nsHttp::User_Agent) {
StoreIsUserAgentHeaderModified(true);
}
tuple->mHeader = aHeader;
tuple->mMerge = false;
tuple->mEmpty = true;
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::RedirectTo(nsIURI* newURI) {
// disabled until/unless addons run in child or something else needs this
return NS_ERROR_NOT_IMPLEMENTED;
}
NS_IMETHODIMP
HttpChannelChild::UpgradeToSecure() {
// disabled until/unless addons run in child or something else needs this
return NS_ERROR_NOT_IMPLEMENTED;
}
NS_IMETHODIMP
HttpChannelChild::GetProtocolVersion(nsACString& aProtocolVersion) {
aProtocolVersion = mProtocolVersion;
return NS_OK;
}
//-----------------------------------------------------------------------------
// HttpChannelChild::nsIHttpChannelInternal
//-----------------------------------------------------------------------------
NS_IMETHODIMP
HttpChannelChild::GetIsAuthChannel(bool* aIsAuthChannel) { DROP_DEAD(); }
//-----------------------------------------------------------------------------
// HttpChannelChild::nsICacheInfoChannel
//-----------------------------------------------------------------------------
NS_IMETHODIMP
HttpChannelChild::GetCacheTokenFetchCount(uint32_t* _retval) {
NS_ENSURE_ARG_POINTER(_retval);
MOZ_ASSERT(NS_IsMainThread());
if (!mCacheEntryAvailable && !mAltDataCacheEntryAvailable) {
return NS_ERROR_NOT_AVAILABLE;
}
*_retval = mCacheFetchCount;
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::GetCacheTokenExpirationTime(uint32_t* _retval) {
NS_ENSURE_ARG_POINTER(_retval);
MOZ_ASSERT(NS_IsMainThread());
if (!mCacheEntryAvailable) return NS_ERROR_NOT_AVAILABLE;
*_retval = mCacheExpirationTime;
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::IsFromCache(bool* value) {
if (!LoadIsPending()) return NS_ERROR_NOT_AVAILABLE;
*value = mIsFromCache;
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::GetCacheEntryId(uint64_t* aCacheEntryId) {
bool fromCache = false;
if (NS_FAILED(IsFromCache(&fromCache)) || !fromCache ||
!mCacheEntryAvailable) {
return NS_ERROR_NOT_AVAILABLE;
}
*aCacheEntryId = mCacheEntryId;
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::IsRacing(bool* aIsRacing) {
if (!LoadAfterOnStartRequestBegun()) {
return NS_ERROR_NOT_AVAILABLE;
}
*aIsRacing = mIsRacing;
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::GetCacheKey(uint32_t* cacheKey) {
MOZ_ASSERT(NS_IsMainThread());
*cacheKey = mCacheKey;
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::SetCacheKey(uint32_t cacheKey) {
ENSURE_CALLED_BEFORE_ASYNC_OPEN();
mCacheKey = cacheKey;
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::SetAllowStaleCacheContent(bool aAllowStaleCacheContent) {
StoreAllowStaleCacheContent(aAllowStaleCacheContent);
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::GetAllowStaleCacheContent(bool* aAllowStaleCacheContent) {
NS_ENSURE_ARG(aAllowStaleCacheContent);
*aAllowStaleCacheContent = LoadAllowStaleCacheContent();
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::SetForceValidateCacheContent(
bool aForceValidateCacheContent) {
StoreForceValidateCacheContent(aForceValidateCacheContent);
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::GetForceValidateCacheContent(
bool* aForceValidateCacheContent) {
NS_ENSURE_ARG(aForceValidateCacheContent);
*aForceValidateCacheContent = LoadForceValidateCacheContent();
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::SetPreferCacheLoadOverBypass(
bool aPreferCacheLoadOverBypass) {
StorePreferCacheLoadOverBypass(aPreferCacheLoadOverBypass);
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::GetPreferCacheLoadOverBypass(
bool* aPreferCacheLoadOverBypass) {
NS_ENSURE_ARG(aPreferCacheLoadOverBypass);
*aPreferCacheLoadOverBypass = LoadPreferCacheLoadOverBypass();
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::PreferAlternativeDataType(
const nsACString& aType, const nsACString& aContentType,
PreferredAlternativeDataDeliveryType aDeliverAltData) {
ENSURE_CALLED_BEFORE_ASYNC_OPEN();
mPreferredCachedAltDataTypes.AppendElement(PreferredAlternativeDataTypeParams(
nsCString(aType), nsCString(aContentType), aDeliverAltData));
return NS_OK;
}
const nsTArray<PreferredAlternativeDataTypeParams>&
HttpChannelChild::PreferredAlternativeDataTypes() {
return mPreferredCachedAltDataTypes;
}
NS_IMETHODIMP
HttpChannelChild::GetAlternativeDataType(nsACString& aType) {
// Must be called during or after OnStartRequest
if (!LoadAfterOnStartRequestBegun()) {
return NS_ERROR_NOT_AVAILABLE;
}
aType = mAvailableCachedAltDataType;
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::OpenAlternativeOutputStream(const nsACString& aType,
int64_t aPredictedSize,
nsIAsyncOutputStream** _retval) {
MOZ_ASSERT(NS_IsMainThread(), "Main thread only");
if (!CanSend()) {
return NS_ERROR_NOT_AVAILABLE;
}
if (static_cast<ContentChild*>(gNeckoChild->Manager())->IsShuttingDown()) {
return NS_ERROR_NOT_AVAILABLE;
}
nsCOMPtr<nsISerialEventTarget> neckoTarget = GetNeckoTarget();
MOZ_ASSERT(neckoTarget);
RefPtr<AltDataOutputStreamChild> stream = new AltDataOutputStreamChild();
stream->AddIPDLReference();
if (!gNeckoChild->SendPAltDataOutputStreamConstructor(
stream, nsCString(aType), aPredictedSize, WrapNotNull(this))) {
return NS_ERROR_FAILURE;
}
stream.forget(_retval);
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::GetOriginalInputStream(nsIInputStreamReceiver* aReceiver) {
if (aReceiver == nullptr) {
return NS_ERROR_INVALID_ARG;
}
if (!CanSend()) {
return NS_ERROR_NOT_AVAILABLE;
}
mOriginalInputStreamReceiver = aReceiver;
Unused << SendOpenOriginalCacheInputStream();
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::GetAlternativeDataInputStream(nsIInputStream** aInputStream) {
NS_ENSURE_ARG_POINTER(aInputStream);
nsCOMPtr<nsIInputStream> is = mAltDataInputStream;
is.forget(aInputStream);
return NS_OK;
}
mozilla::ipc::IPCResult HttpChannelChild::RecvOriginalCacheInputStreamAvailable(
const Maybe<IPCStream>& aStream) {
nsCOMPtr<nsIInputStream> stream = DeserializeIPCStream(aStream);
nsCOMPtr<nsIInputStreamReceiver> receiver;
receiver.swap(mOriginalInputStreamReceiver);
if (receiver) {
receiver->OnInputStreamReady(stream);
}
return IPC_OK();
}
//-----------------------------------------------------------------------------
// HttpChannelChild::nsIResumableChannel
//-----------------------------------------------------------------------------
NS_IMETHODIMP
HttpChannelChild::ResumeAt(uint64_t startPos, const nsACString& entityID) {
LOG(("HttpChannelChild::ResumeAt [this=%p]\n", this));
ENSURE_CALLED_BEFORE_CONNECT();
mStartPos = startPos;
mEntityID = entityID;
mSendResumeAt = true;
return NS_OK;
}
// GetEntityID is shared in HttpBaseChannel
//-----------------------------------------------------------------------------
// HttpChannelChild::nsISupportsPriority
//-----------------------------------------------------------------------------
NS_IMETHODIMP
HttpChannelChild::SetPriority(int32_t aPriority) {
LOG(("HttpChannelChild::SetPriority %p p=%d", this, aPriority));
int16_t newValue = clamped<int32_t>(aPriority, INT16_MIN, INT16_MAX);
if (mPriority == newValue) return NS_OK;
mPriority = newValue;
if (RemoteChannelExists()) SendSetPriority(mPriority);
return NS_OK;
}
//-----------------------------------------------------------------------------
// HttpChannelChild::nsIClassOfService
//-----------------------------------------------------------------------------
NS_IMETHODIMP
HttpChannelChild::SetClassFlags(uint32_t inFlags) {
if (mClassOfService.Flags() == inFlags) {
return NS_OK;
}
mClassOfService.SetFlags(inFlags);
LOG(("HttpChannelChild %p ClassOfService flags=%lu inc=%d", this,
mClassOfService.Flags(), mClassOfService.Incremental()));
if (RemoteChannelExists()) {
SendSetClassOfService(mClassOfService);
}
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::AddClassFlags(uint32_t inFlags) {
mClassOfService.SetFlags(inFlags | mClassOfService.Flags());
LOG(("HttpChannelChild %p ClassOfService flags=%lu inc=%d", this,
mClassOfService.Flags(), mClassOfService.Incremental()));
if (RemoteChannelExists()) {
SendSetClassOfService(mClassOfService);
}
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::ClearClassFlags(uint32_t inFlags) {
mClassOfService.SetFlags(~inFlags & mClassOfService.Flags());
LOG(("HttpChannelChild %p ClassOfService=%lu", this,
mClassOfService.Flags()));
if (RemoteChannelExists()) {
SendSetClassOfService(mClassOfService);
}
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::SetClassOfService(ClassOfService inCos) {
mClassOfService = inCos;
LOG(("HttpChannelChild %p ClassOfService flags=%lu inc=%d", this,
mClassOfService.Flags(), mClassOfService.Incremental()));
if (RemoteChannelExists()) {
SendSetClassOfService(mClassOfService);
}
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::SetIncremental(bool inIncremental) {
mClassOfService.SetIncremental(inIncremental);
LOG(("HttpChannelChild %p ClassOfService flags=%lu inc=%d", this,
mClassOfService.Flags(), mClassOfService.Incremental()));
if (RemoteChannelExists()) {
SendSetClassOfService(mClassOfService);
}
return NS_OK;
}
//-----------------------------------------------------------------------------
// HttpChannelChild::nsIProxiedChannel
//-----------------------------------------------------------------------------
NS_IMETHODIMP
HttpChannelChild::GetProxyInfo(nsIProxyInfo** aProxyInfo) { DROP_DEAD(); }
NS_IMETHODIMP HttpChannelChild::GetHttpProxyConnectResponseCode(
int32_t* aResponseCode) {
DROP_DEAD();
}
//-----------------------------------------------------------------------------
// HttpChannelChild::nsIHttpChannelChild
//-----------------------------------------------------------------------------
NS_IMETHODIMP HttpChannelChild::AddCookiesToRequest() {
HttpBaseChannel::AddCookiesToRequest();
return NS_OK;
}
NS_IMETHODIMP HttpChannelChild::GetClientSetRequestHeaders(
RequestHeaderTuples** aRequestHeaders) {
*aRequestHeaders = &mClientSetRequestHeaders;
return NS_OK;
}
void HttpChannelChild::GetClientSetCorsPreflightParameters(
Maybe<CorsPreflightArgs>& aArgs) {
if (LoadRequireCORSPreflight()) {
CorsPreflightArgs args;
args.unsafeHeaders() = mUnsafeHeaders.Clone();
aArgs.emplace(args);
} else {
aArgs = Nothing();
}
}
NS_IMETHODIMP
HttpChannelChild::RemoveCorsPreflightCacheEntry(
nsIURI* aURI, nsIPrincipal* aPrincipal,
const OriginAttributes& aOriginAttributes) {
PrincipalInfo principalInfo;
MOZ_ASSERT(aURI, "aURI should not be null");
nsresult rv = PrincipalToPrincipalInfo(aPrincipal, &principalInfo);
if (NS_WARN_IF(NS_FAILED(rv))) {
return rv;
}
bool result = false;
// Be careful to not attempt to send a message to the parent after the
// actor has been destroyed.
if (CanSend()) {
result = SendRemoveCorsPreflightCacheEntry(aURI, principalInfo,
aOriginAttributes);
}
return result ? NS_OK : NS_ERROR_FAILURE;
}
//-----------------------------------------------------------------------------
// HttpChannelChild::nsIMuliPartChannel
//-----------------------------------------------------------------------------
NS_IMETHODIMP
HttpChannelChild::GetBaseChannel(nsIChannel** aBaseChannel) {
if (!mMultiPartID) {
MOZ_ASSERT(false, "Not a multipart channel");
return NS_ERROR_NOT_AVAILABLE;
}
nsCOMPtr<nsIChannel> channel = this;
channel.forget(aBaseChannel);
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::GetPartID(uint32_t* aPartID) {
if (!mMultiPartID) {
MOZ_ASSERT(false, "Not a multipart channel");
return NS_ERROR_NOT_AVAILABLE;
}
*aPartID = *mMultiPartID;
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::GetIsFirstPart(bool* aIsFirstPart) {
if (!mMultiPartID) {
return NS_ERROR_NOT_AVAILABLE;
}
*aIsFirstPart = mIsFirstPartOfMultiPart;
return NS_OK;
}
NS_IMETHODIMP
HttpChannelChild::GetIsLastPart(bool* aIsLastPart) {
if (!mMultiPartID) {
return NS_ERROR_NOT_AVAILABLE;
}
*aIsLastPart = mIsLastPartOfMultiPart;
return NS_OK;
}
//-----------------------------------------------------------------------------
// HttpChannelChild::nsIThreadRetargetableRequest
//-----------------------------------------------------------------------------
NS_IMETHODIMP
HttpChannelChild::RetargetDeliveryTo(nsISerialEventTarget* aNewTarget) {
LOG(("HttpChannelChild::RetargetDeliveryTo [this=%p, aNewTarget=%p]", this,
aNewTarget));
MOZ_ASSERT(NS_IsMainThread(), "Should be called on main thread only");
MOZ_ASSERT(aNewTarget);
NS_ENSURE_ARG(aNewTarget);
if (aNewTarget->IsOnCurrentThread()) {
NS_WARNING("Retargeting delivery to same thread");
mOMTResult = LABELS_HTTP_CHILD_OMT_STATS_2::successMainThread;
return NS_OK;
}
if (mMultiPartID) {
// TODO: Maybe add a new label for this? Maybe it doesn't
// matter though, since we also blocked QI, so we shouldn't
// ever get here.
mOMTResult = LABELS_HTTP_CHILD_OMT_STATS_2::failListener;
return NS_ERROR_NO_INTERFACE;
}
// Ensure that |mListener| and any subsequent listeners can be retargeted
// to another thread.
nsresult rv = NS_OK;
nsCOMPtr<nsIThreadRetargetableStreamListener> retargetableListener =
do_QueryInterface(mListener, &rv);
if (!retargetableListener || NS_FAILED(rv)) {
NS_WARNING("Listener is not retargetable");
mOMTResult = LABELS_HTTP_CHILD_OMT_STATS_2::failListener;
return NS_ERROR_NO_INTERFACE;
}
rv = retargetableListener->CheckListenerChain();
if (NS_FAILED(rv)) {
NS_WARNING("Subsequent listeners are not retargetable");
mOMTResult = LABELS_HTTP_CHILD_OMT_STATS_2::failListenerChain;
return rv;
}
{
MutexAutoLock lock(mEventTargetMutex);
MOZ_ASSERT(!mODATarget);
RetargetDeliveryToImpl(aNewTarget, lock);
}
mOMTResult = LABELS_HTTP_CHILD_OMT_STATS_2::success;
return NS_OK;
}
void HttpChannelChild::RetargetDeliveryToImpl(nsISerialEventTarget* aNewTarget,
MutexAutoLock& aLockRef) {
aLockRef.AssertOwns(mEventTargetMutex);
mODATarget = aNewTarget;
}
NS_IMETHODIMP
HttpChannelChild::GetDeliveryTarget(nsISerialEventTarget** aEventTarget) {
MutexAutoLock lock(mEventTargetMutex);
nsCOMPtr<nsISerialEventTarget> target = mODATarget;
if (!mODATarget) {
target = GetCurrentSerialEventTarget();
}
target.forget(aEventTarget);
return NS_OK;
}
void HttpChannelChild::TrySendDeletingChannel() {
AUTO_PROFILER_LABEL("HttpChannelChild::TrySendDeletingChannel", NETWORK);
MOZ_ASSERT(NS_IsMainThread());
if (!mDeletingChannelSent.compareExchange(false, true)) {
// SendDeletingChannel is already sent.
return;
}
if (NS_WARN_IF(!CanSend())) {
// IPC actor is destroyed already, do not send more messages.
return;
}
Unused << PHttpChannelChild::SendDeletingChannel();
}
nsresult HttpChannelChild::AsyncCallImpl(
void (HttpChannelChild::*funcPtr)(),
nsRunnableMethod<HttpChannelChild>** retval) {
nsresult rv;
RefPtr<nsRunnableMethod<HttpChannelChild>> event =
NewRunnableMethod("net::HttpChannelChild::AsyncCall", this, funcPtr);
nsCOMPtr<nsISerialEventTarget> neckoTarget = GetNeckoTarget();
MOZ_ASSERT(neckoTarget);
rv = neckoTarget->Dispatch(event, NS_DISPATCH_NORMAL);
if (NS_SUCCEEDED(rv) && retval) {
*retval = event;
}
return rv;
}
nsresult HttpChannelChild::SetReferrerHeader(const nsACString& aReferrer,
bool aRespectBeforeConnect) {
// Normally this would be ENSURE_CALLED_BEFORE_CONNECT, but since the
// "connect" is done in the main process, and LoadRequestObserversCalled() is
// never set in the ChannelChild, before connect basically means before
// asyncOpen.
if (aRespectBeforeConnect) {
ENSURE_CALLED_BEFORE_ASYNC_OPEN();
}
// remove old referrer if any
mClientSetRequestHeaders.RemoveElementsBy(
[](const auto& header) { return "Referer"_ns.Equals(header.mHeader); });
return HttpBaseChannel::SetReferrerHeader(aReferrer, aRespectBeforeConnect);
}
void HttpChannelChild::CancelOnMainThread(nsresult aRv,
const nsACString& aReason) {
LOG(("HttpChannelChild::CancelOnMainThread [this=%p]", this));
if (NS_IsMainThread()) {
CancelWithReason(aRv, aReason);
return;
}
mEventQ->Suspend();
// Cancel is expected to preempt any other channel events, thus we put this
// event in the front of mEventQ to make sure nsIStreamListener not receiving
// any ODA/OnStopRequest callbacks.
nsCString reason(aReason);
mEventQ->PrependEvent(MakeUnique<NeckoTargetChannelFunctionEvent>(
this, [self = UnsafePtr<HttpChannelChild>(this), aRv, reason]() {
self->CancelWithReason(aRv, reason);
}));
mEventQ->Resume();
}
mozilla::ipc::IPCResult HttpChannelChild::RecvSetPriority(
const int16_t& aPriority) {
mPriority = aPriority;
return IPC_OK();
}
// We don't have a copyable Endpoint and NeckoTargetChannelFunctionEvent takes
// std::function<void()>. It's not possible to avoid the copy from the type of
// lambda to std::function, so does the capture list. Hence, we're forced to
// use the old-fashioned channel event inheritance.
class AttachStreamFilterEvent : public ChannelEvent {
public:
AttachStreamFilterEvent(HttpChannelChild* aChild,
already_AddRefed<nsIEventTarget> aTarget,
Endpoint<extensions::PStreamFilterParent>&& aEndpoint)
: mChild(aChild), mTarget(aTarget), mEndpoint(std::move(aEndpoint)) {}
already_AddRefed<nsIEventTarget> GetEventTarget() override {
nsCOMPtr<nsIEventTarget> target = mTarget;
return target.forget();
}
void Run() override {
extensions::StreamFilterParent::Attach(mChild, std::move(mEndpoint));
}
private:
HttpChannelChild* mChild;
nsCOMPtr<nsIEventTarget> mTarget;
Endpoint<extensions::PStreamFilterParent> mEndpoint;
};
void HttpChannelChild::RegisterStreamFilter(
RefPtr<extensions::StreamFilterParent>& aStreamFilter) {
MOZ_ASSERT(NS_IsMainThread());
mStreamFilters.AppendElement(aStreamFilter);
}
void HttpChannelChild::ProcessAttachStreamFilter(
Endpoint<extensions::PStreamFilterParent>&& aEndpoint) {
LOG(("HttpChannelChild::ProcessAttachStreamFilter [this=%p]\n", this));
MOZ_ASSERT(OnSocketThread());
mEventQ->RunOrEnqueue(new AttachStreamFilterEvent(this, GetNeckoTarget(),
std::move(aEndpoint)));
}
void HttpChannelChild::OnDetachStreamFilters() {
LOG(("HttpChannelChild::OnDetachStreamFilters [this=%p]\n", this));
MOZ_ASSERT(NS_IsMainThread());
for (auto& StreamFilter : mStreamFilters) {
StreamFilter->Disconnect("ServiceWorker fallback redirection"_ns);
}
mStreamFilters.Clear();
}
void HttpChannelChild::ProcessDetachStreamFilters() {
LOG(("HttpChannelChild::ProcessDetachStreamFilter [this=%p]\n", this));
MOZ_ASSERT(OnSocketThread());
mEventQ->RunOrEnqueue(new NeckoTargetChannelFunctionEvent(
this, [self = UnsafePtr<HttpChannelChild>(this)]() {
self->OnDetachStreamFilters();
}));
}
void HttpChannelChild::ActorDestroy(ActorDestroyReason aWhy) {
MOZ_ASSERT(NS_IsMainThread());
#ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED
mActorDestroyReason.emplace(aWhy);
#endif
// OnStartRequest might be dropped if IPDL is destroyed abnormally
// and BackgroundChild might have pending IPC messages.
// Clean up BackgroundChild at this time to prevent memleak.
if (aWhy != Deletion) {
// Make sure all the messages are processed.
AutoEventEnqueuer ensureSerialDispatch(mEventQ);
mStatus = NS_ERROR_DOCSHELL_DYING;
HandleAsyncAbort();
// Cleanup the background channel before we resume the eventQ so we don't
// get any other events.
CleanupBackgroundChannel();
mIPCActorDeleted = true;
mCanceled = true;
}
}
mozilla::ipc::IPCResult HttpChannelChild::RecvLogBlockedCORSRequest(
const nsAString& aMessage, const nsACString& aCategory,
const bool& aIsWarning) {
Unused << LogBlockedCORSRequest(aMessage, aCategory, aIsWarning);
return IPC_OK();
}
NS_IMETHODIMP
HttpChannelChild::LogBlockedCORSRequest(const nsAString& aMessage,
const nsACString& aCategory,
bool aIsWarning) {
uint64_t innerWindowID = mLoadInfo->GetInnerWindowID();
bool privateBrowsing = !!mLoadInfo->GetOriginAttributes().mPrivateBrowsingId;
bool fromChromeContext =
mLoadInfo->TriggeringPrincipal()->IsSystemPrincipal();
nsCORSListenerProxy::LogBlockedCORSRequest(innerWindowID, privateBrowsing,
fromChromeContext, aMessage,
aCategory, aIsWarning);
return NS_OK;
}
mozilla::ipc::IPCResult HttpChannelChild::RecvLogMimeTypeMismatch(
const nsACString& aMessageName, const bool& aWarning, const nsAString& aURL,
const nsAString& aContentType) {
Unused << LogMimeTypeMismatch(aMessageName, aWarning, aURL, aContentType);
return IPC_OK();
}
NS_IMETHODIMP
HttpChannelChild::LogMimeTypeMismatch(const nsACString& aMessageName,
bool aWarning, const nsAString& aURL,
const nsAString& aContentType) {
RefPtr<Document> doc;
mLoadInfo->GetLoadingDocument(getter_AddRefs(doc));
AutoTArray<nsString, 2> params;
params.AppendElement(aURL);
params.AppendElement(aContentType);
nsContentUtils::ReportToConsole(
aWarning ? nsIScriptError::warningFlag : nsIScriptError::errorFlag,
"MIMEMISMATCH"_ns, doc, nsContentUtils::eSECURITY_PROPERTIES,
nsCString(aMessageName).get(), params);
return NS_OK;
}
nsresult HttpChannelChild::MaybeLogCOEPError(nsresult aStatus) {
if (aStatus == NS_ERROR_DOM_CORP_FAILED) {
RefPtr<Document> doc;
mLoadInfo->GetLoadingDocument(getter_AddRefs(doc));
nsAutoCString url;
mURI->GetSpec(url);
AutoTArray<nsString, 2> params;
params.AppendElement(NS_ConvertUTF8toUTF16(url));
// The MDN URL intentionally ends with a # so the webconsole linkification
// doesn't ignore the final ) of the URL
params.AppendElement(
u"https://developer.mozilla.org/docs/Web/HTTP/Cross-Origin_Resource_Policy_(CORP)#"_ns);
nsContentUtils::ReportToConsole(nsIScriptError::errorFlag, "COEP"_ns, doc,
nsContentUtils::eNECKO_PROPERTIES,
"CORPBlocked", params);
}
return NS_OK;
}
nsresult HttpChannelChild::CrossProcessRedirectFinished(nsresult aStatus) {
if (!CanSend()) {
return NS_BINDING_FAILED;
}
if (!mCanceled && NS_SUCCEEDED(mStatus)) {
mStatus = aStatus;
}
return mStatus;
}
void HttpChannelChild::DoDiagnosticAssertWhenOnStopNotCalledOnDestroy() {
#ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED
mDoDiagnosticAssertWhenOnStopNotCalledOnDestroy = true;
#endif
}
void HttpChannelChild::MaybeConnectToSocketProcess() {
if (!nsIOService::UseSocketProcess()) {
return;
}
if (!StaticPrefs::network_send_ODA_to_content_directly()) {
return;
}
RefPtr<HttpBackgroundChannelChild> bgChild;
{
MutexAutoLock lock(mBgChildMutex);
bgChild = mBgChild;
}
SocketProcessBridgeChild::GetSocketProcessBridge()->Then(
GetCurrentSerialEventTarget(), __func__,
[bgChild, channelId = ChannelId()](
const RefPtr<SocketProcessBridgeChild>& aBridge) {
Endpoint<PBackgroundDataBridgeParent> parentEndpoint;
Endpoint<PBackgroundDataBridgeChild> childEndpoint;
PBackgroundDataBridge::CreateEndpoints(&parentEndpoint, &childEndpoint);
aBridge->SendInitBackgroundDataBridge(std::move(parentEndpoint),
channelId);
gSocketTransportService->Dispatch(
NS_NewRunnableFunction(
"HttpBackgroundChannelChild::CreateDataBridge",
[bgChild, endpoint = std::move(childEndpoint)]() mutable {
bgChild->CreateDataBridge(std::move(endpoint));
}),
NS_DISPATCH_NORMAL);
},
[]() { NS_WARNING("Failed to create SocketProcessBridgeChild"); });
}
NS_IMETHODIMP
HttpChannelChild::SetEarlyHintObserver(nsIEarlyHintObserver* aObserver) {
return NS_OK;
}
NS_IMETHODIMP HttpChannelChild::SetWebTransportSessionEventListener(
WebTransportSessionEventListener* aListener) {
return NS_OK;
}
void HttpChannelChild::ExplicitSetUploadStreamLength(
uint64_t aContentLength, bool aSetContentLengthHeader) {
// SetRequestHeader propagates headers to chrome if HttpChannelChild
MOZ_ASSERT(!LoadWasOpened());
HttpBaseChannel::ExplicitSetUploadStreamLength(aContentLength,
aSetContentLengthHeader);
}
} // namespace mozilla::net
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