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/* vim:set ts=4 sw=2 sts=2 et cin: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
// HttpLog.h should generally be included first
#include "HttpLog.h"
// Log on level :5, instead of default :4.
#undef LOG
#define LOG(args) LOG5(args)
#undef LOG_ENABLED
#define LOG_ENABLED() LOG5_ENABLED()
#include <algorithm>
#include <utility>
#include "ConnectionHandle.h"
#include "HttpConnectionUDP.h"
#include "NullHttpTransaction.h"
#include "SpeculativeTransaction.h"
#include "mozilla/Components.h"
#include "mozilla/PerfStats.h"
#include "mozilla/ProfilerMarkers.h"
#include "mozilla/SpinEventLoopUntil.h"
#include "mozilla/StaticPrefs_network.h"
#include "mozilla/Telemetry.h"
#include "mozilla/Unused.h"
#include "mozilla/glean/GleanMetrics.h"
#include "mozilla/net/DNS.h"
#include "mozilla/net/DashboardTypes.h"
#include "nsCOMPtr.h"
#include "nsHttpConnectionMgr.h"
#include "nsHttpHandler.h"
#include "nsIClassOfService.h"
#include "nsIDNSByTypeRecord.h"
#include "nsIDNSListener.h"
#include "nsIDNSRecord.h"
#include "nsIDNSService.h"
#include "nsIHttpChannelInternal.h"
#include "nsIPipe.h"
#include "nsIRequestContext.h"
#include "nsISocketTransport.h"
#include "nsISocketTransportService.h"
#include "nsITransport.h"
#include "nsIXPConnect.h"
#include "nsInterfaceRequestorAgg.h"
#include "nsNetCID.h"
#include "nsNetSegmentUtils.h"
#include "nsNetUtil.h"
#include "nsQueryObject.h"
#include "nsSocketTransportService2.h"
#include "nsStreamUtils.h"
using namespace mozilla;
namespace geckoprofiler::markers {
struct UrlMarker {
static constexpr Span<const char> MarkerTypeName() {
return MakeStringSpan("Url");
}
static void StreamJSONMarkerData(
mozilla::baseprofiler::SpliceableJSONWriter& aWriter,
const mozilla::ProfilerString8View& aURL, const TimeDuration& aDuration,
uint64_t aChannelId) {
if (aURL.Length() != 0) {
aWriter.StringProperty("url", aURL);
}
if (!aDuration.IsZero()) {
aWriter.DoubleProperty("duration", aDuration.ToMilliseconds());
}
aWriter.IntProperty("channelId", static_cast<int64_t>(aChannelId));
}
static MarkerSchema MarkerTypeDisplay() {
using MS = MarkerSchema;
MS schema(MS::Location::MarkerChart, MS::Location::MarkerTable);
schema.SetTableLabel("{marker.name} - {marker.data.url}");
schema.AddKeyFormatSearchable("url", MS::Format::Url,
MS::Searchable::Searchable);
schema.AddKeyLabelFormat("duration", "Duration", MS::Format::Duration);
return schema;
}
};
} // namespace geckoprofiler::markers
namespace mozilla::net {
//-----------------------------------------------------------------------------
NS_IMPL_ISUPPORTS(nsHttpConnectionMgr, nsIObserver, nsINamed)
//-----------------------------------------------------------------------------
nsHttpConnectionMgr::nsHttpConnectionMgr() {
LOG(("Creating nsHttpConnectionMgr @%p\n", this));
}
nsHttpConnectionMgr::~nsHttpConnectionMgr() {
LOG(("Destroying nsHttpConnectionMgr @%p\n", this));
MOZ_ASSERT(mCoalescingHash.Count() == 0);
if (mTimeoutTick) mTimeoutTick->Cancel();
}
nsresult nsHttpConnectionMgr::EnsureSocketThreadTarget() {
nsCOMPtr<nsIEventTarget> sts;
nsCOMPtr<nsIIOService> ioService = components::IO::Service();
if (ioService) {
nsCOMPtr<nsISocketTransportService> realSTS =
components::SocketTransport::Service();
sts = do_QueryInterface(realSTS);
}
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
// do nothing if already initialized or if we've shut down
if (mSocketThreadTarget || mIsShuttingDown) return NS_OK;
mSocketThreadTarget = sts;
return sts ? NS_OK : NS_ERROR_NOT_AVAILABLE;
}
nsresult nsHttpConnectionMgr::Init(
uint16_t maxUrgentExcessiveConns, uint16_t maxConns,
uint16_t maxPersistConnsPerHost, uint16_t maxPersistConnsPerProxy,
uint16_t maxRequestDelay, bool throttleEnabled, uint32_t throttleVersion,
uint32_t throttleSuspendFor, uint32_t throttleResumeFor,
uint32_t throttleReadLimit, uint32_t throttleReadInterval,
uint32_t throttleHoldTime, uint32_t throttleMaxTime,
bool beConservativeForProxy) {
LOG(("nsHttpConnectionMgr::Init\n"));
{
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
mMaxUrgentExcessiveConns = maxUrgentExcessiveConns;
mMaxConns = maxConns;
mMaxPersistConnsPerHost = maxPersistConnsPerHost;
mMaxPersistConnsPerProxy = maxPersistConnsPerProxy;
mMaxRequestDelay = maxRequestDelay;
mThrottleEnabled = throttleEnabled;
mThrottleVersion = throttleVersion;
mThrottleSuspendFor = throttleSuspendFor;
mThrottleResumeFor = throttleResumeFor;
mThrottleReadLimit = throttleReadLimit;
mThrottleReadInterval = throttleReadInterval;
mThrottleHoldTime = throttleHoldTime;
mThrottleMaxTime = TimeDuration::FromMilliseconds(throttleMaxTime);
mBeConservativeForProxy = beConservativeForProxy;
mIsShuttingDown = false;
}
return EnsureSocketThreadTarget();
}
class BoolWrapper : public ARefBase {
public:
BoolWrapper() = default;
NS_INLINE_DECL_THREADSAFE_REFCOUNTING(BoolWrapper, override)
public: // intentional!
bool mBool{false};
private:
virtual ~BoolWrapper() = default;
};
nsresult nsHttpConnectionMgr::Shutdown() {
LOG(("nsHttpConnectionMgr::Shutdown\n"));
RefPtr<BoolWrapper> shutdownWrapper = new BoolWrapper();
{
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
// do nothing if already shutdown
if (!mSocketThreadTarget) return NS_OK;
nsresult rv =
PostEvent(&nsHttpConnectionMgr::OnMsgShutdown, 0, shutdownWrapper);
// release our reference to the STS to prevent further events
// from being posted. this is how we indicate that we are
// shutting down.
mIsShuttingDown = true;
mSocketThreadTarget = nullptr;
if (NS_FAILED(rv)) {
NS_WARNING("unable to post SHUTDOWN message");
return rv;
}
}
// wait for shutdown event to complete
SpinEventLoopUntil("nsHttpConnectionMgr::Shutdown"_ns,
[&, shutdownWrapper]() { return shutdownWrapper->mBool; });
return NS_OK;
}
class ConnEvent : public Runnable {
public:
ConnEvent(nsHttpConnectionMgr* mgr, nsConnEventHandler handler,
int32_t iparam, ARefBase* vparam)
: Runnable("net::ConnEvent"),
mMgr(mgr),
mHandler(handler),
mIParam(iparam),
mVParam(vparam) {}
NS_IMETHOD Run() override {
(mMgr->*mHandler)(mIParam, mVParam);
return NS_OK;
}
private:
virtual ~ConnEvent() = default;
RefPtr<nsHttpConnectionMgr> mMgr;
nsConnEventHandler mHandler;
int32_t mIParam;
RefPtr<ARefBase> mVParam;
};
nsresult nsHttpConnectionMgr::PostEvent(nsConnEventHandler handler,
int32_t iparam, ARefBase* vparam) {
Unused << EnsureSocketThreadTarget();
nsCOMPtr<nsIEventTarget> target;
{
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
target = mSocketThreadTarget;
}
if (!target) {
NS_WARNING("cannot post event if not initialized");
return NS_ERROR_NOT_INITIALIZED;
}
nsCOMPtr<nsIRunnable> event = new ConnEvent(this, handler, iparam, vparam);
return target->Dispatch(event, NS_DISPATCH_NORMAL);
}
void nsHttpConnectionMgr::PruneDeadConnectionsAfter(uint32_t timeInSeconds) {
LOG(("nsHttpConnectionMgr::PruneDeadConnectionsAfter\n"));
if (!mTimer) mTimer = NS_NewTimer();
// failure to create a timer is not a fatal error, but idle connections
// will not be cleaned up until we try to use them.
if (mTimer) {
mTimeOfNextWakeUp = timeInSeconds + NowInSeconds();
mTimer->Init(this, timeInSeconds * 1000, nsITimer::TYPE_ONE_SHOT);
} else {
NS_WARNING("failed to create: timer for pruning the dead connections!");
}
}
void nsHttpConnectionMgr::ConditionallyStopPruneDeadConnectionsTimer() {
// Leave the timer in place if there are connections that potentially
// need management
if (mNumIdleConns ||
(mNumActiveConns && StaticPrefs::network_http_http2_enabled())) {
return;
}
LOG(("nsHttpConnectionMgr::StopPruneDeadConnectionsTimer\n"));
// Reset mTimeOfNextWakeUp so that we can find a new shortest value.
mTimeOfNextWakeUp = UINT64_MAX;
if (mTimer) {
mTimer->Cancel();
mTimer = nullptr;
}
}
void nsHttpConnectionMgr::ConditionallyStopTimeoutTick() {
LOG(
("nsHttpConnectionMgr::ConditionallyStopTimeoutTick "
"armed=%d active=%d\n",
mTimeoutTickArmed, mNumActiveConns));
if (!mTimeoutTickArmed) return;
if (mNumActiveConns) return;
LOG(("nsHttpConnectionMgr::ConditionallyStopTimeoutTick stop==true\n"));
mTimeoutTick->Cancel();
mTimeoutTickArmed = false;
}
//-----------------------------------------------------------------------------
// nsHttpConnectionMgr::nsINamed
//-----------------------------------------------------------------------------
NS_IMETHODIMP
nsHttpConnectionMgr::GetName(nsACString& aName) {
aName.AssignLiteral("nsHttpConnectionMgr");
return NS_OK;
}
//-----------------------------------------------------------------------------
// nsHttpConnectionMgr::nsIObserver
//-----------------------------------------------------------------------------
NS_IMETHODIMP
nsHttpConnectionMgr::Observe(nsISupports* subject, const char* topic,
const char16_t* data) {
LOG(("nsHttpConnectionMgr::Observe [topic=\"%s\"]\n", topic));
if (0 == strcmp(topic, NS_TIMER_CALLBACK_TOPIC)) {
nsCOMPtr<nsITimer> timer = do_QueryInterface(subject);
if (timer == mTimer) {
Unused << PruneDeadConnections();
} else if (timer == mTimeoutTick) {
TimeoutTick();
} else if (timer == mTrafficTimer) {
Unused << PruneNoTraffic();
} else if (timer == mThrottleTicker) {
ThrottlerTick();
} else if (timer == mDelayedResumeReadTimer) {
ResumeBackgroundThrottledTransactions();
} else {
MOZ_ASSERT(false, "unexpected timer-callback");
LOG(("Unexpected timer object\n"));
return NS_ERROR_UNEXPECTED;
}
}
return NS_OK;
}
//-----------------------------------------------------------------------------
nsresult nsHttpConnectionMgr::AddTransaction(HttpTransactionShell* trans,
int32_t priority) {
LOG(("nsHttpConnectionMgr::AddTransaction [trans=%p %d]\n", trans, priority));
// Make sure a transaction is not in a pending queue.
CheckTransInPendingQueue(trans->AsHttpTransaction());
return PostEvent(&nsHttpConnectionMgr::OnMsgNewTransaction, priority,
trans->AsHttpTransaction());
}
class NewTransactionData : public ARefBase {
public:
NewTransactionData(nsHttpTransaction* trans, int32_t priority,
nsHttpTransaction* transWithStickyConn)
: mTrans(trans),
mPriority(priority),
mTransWithStickyConn(transWithStickyConn) {}
NS_INLINE_DECL_THREADSAFE_REFCOUNTING(NewTransactionData, override)
RefPtr<nsHttpTransaction> mTrans;
int32_t mPriority;
RefPtr<nsHttpTransaction> mTransWithStickyConn;
private:
virtual ~NewTransactionData() = default;
};
nsresult nsHttpConnectionMgr::AddTransactionWithStickyConn(
HttpTransactionShell* trans, int32_t priority,
HttpTransactionShell* transWithStickyConn) {
LOG(
("nsHttpConnectionMgr::AddTransactionWithStickyConn "
"[trans=%p %d transWithStickyConn=%p]\n",
trans, priority, transWithStickyConn));
// Make sure a transaction is not in a pending queue.
CheckTransInPendingQueue(trans->AsHttpTransaction());
RefPtr<NewTransactionData> data =
new NewTransactionData(trans->AsHttpTransaction(), priority,
transWithStickyConn->AsHttpTransaction());
return PostEvent(&nsHttpConnectionMgr::OnMsgNewTransactionWithStickyConn, 0,
data);
}
nsresult nsHttpConnectionMgr::RescheduleTransaction(HttpTransactionShell* trans,
int32_t priority) {
LOG(("nsHttpConnectionMgr::RescheduleTransaction [trans=%p %d]\n", trans,
priority));
return PostEvent(&nsHttpConnectionMgr::OnMsgReschedTransaction, priority,
trans->AsHttpTransaction());
}
void nsHttpConnectionMgr::UpdateClassOfServiceOnTransaction(
HttpTransactionShell* trans, const ClassOfService& classOfService) {
LOG(
("nsHttpConnectionMgr::UpdateClassOfServiceOnTransaction [trans=%p "
"classOfService flags=%" PRIu32 " inc=%d]\n",
trans, static_cast<uint32_t>(classOfService.Flags()),
classOfService.Incremental()));
Unused << EnsureSocketThreadTarget();
nsCOMPtr<nsIEventTarget> target;
{
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
target = mSocketThreadTarget;
}
if (!target) {
NS_WARNING("cannot post event if not initialized");
return;
}
RefPtr<nsHttpConnectionMgr> self(this);
Unused << target->Dispatch(NS_NewRunnableFunction(
"nsHttpConnectionMgr::CallUpdateClassOfServiceOnTransaction",
[cos{classOfService}, self{std::move(self)}, trans = RefPtr{trans}]() {
self->OnMsgUpdateClassOfServiceOnTransaction(
cos, trans->AsHttpTransaction());
}));
}
nsresult nsHttpConnectionMgr::CancelTransaction(HttpTransactionShell* trans,
nsresult reason) {
LOG(("nsHttpConnectionMgr::CancelTransaction [trans=%p reason=%" PRIx32 "]\n",
trans, static_cast<uint32_t>(reason)));
return PostEvent(&nsHttpConnectionMgr::OnMsgCancelTransaction,
static_cast<int32_t>(reason), trans->AsHttpTransaction());
}
nsresult nsHttpConnectionMgr::PruneDeadConnections() {
return PostEvent(&nsHttpConnectionMgr::OnMsgPruneDeadConnections);
}
//
// Called after a timeout. Check for active connections that have had no
// traffic since they were "marked" and nuke them.
nsresult nsHttpConnectionMgr::PruneNoTraffic() {
LOG(("nsHttpConnectionMgr::PruneNoTraffic\n"));
mPruningNoTraffic = true;
return PostEvent(&nsHttpConnectionMgr::OnMsgPruneNoTraffic);
}
nsresult nsHttpConnectionMgr::VerifyTraffic() {
LOG(("nsHttpConnectionMgr::VerifyTraffic\n"));
return PostEvent(&nsHttpConnectionMgr::OnMsgVerifyTraffic);
}
nsresult nsHttpConnectionMgr::DoShiftReloadConnectionCleanup() {
return PostEvent(&nsHttpConnectionMgr::OnMsgDoShiftReloadConnectionCleanup, 0,
nullptr);
}
nsresult nsHttpConnectionMgr::DoShiftReloadConnectionCleanupWithConnInfo(
nsHttpConnectionInfo* aCI) {
if (!aCI) {
return NS_ERROR_INVALID_ARG;
}
RefPtr<nsHttpConnectionInfo> ci = aCI->Clone();
return PostEvent(&nsHttpConnectionMgr::OnMsgDoShiftReloadConnectionCleanup, 0,
ci);
}
nsresult nsHttpConnectionMgr::DoSingleConnectionCleanup(
nsHttpConnectionInfo* aCI) {
if (!aCI) {
return NS_ERROR_INVALID_ARG;
}
RefPtr<nsHttpConnectionInfo> ci = aCI->Clone();
return PostEvent(&nsHttpConnectionMgr::OnMsgDoSingleConnectionCleanup, 0, ci);
}
class SpeculativeConnectArgs : public ARefBase {
public:
SpeculativeConnectArgs() = default;
NS_INLINE_DECL_THREADSAFE_REFCOUNTING(SpeculativeConnectArgs, override)
public: // intentional!
RefPtr<SpeculativeTransaction> mTrans;
bool mFetchHTTPSRR{false};
private:
virtual ~SpeculativeConnectArgs() = default;
NS_DECL_OWNINGTHREAD
};
nsresult nsHttpConnectionMgr::SpeculativeConnect(
nsHttpConnectionInfo* ci, nsIInterfaceRequestor* callbacks, uint32_t caps,
SpeculativeTransaction* aTransaction, bool aFetchHTTPSRR) {
if (!IsNeckoChild() && NS_IsMainThread()) {
// HACK: make sure PSM gets initialized on the main thread.
net_EnsurePSMInit();
}
LOG(("nsHttpConnectionMgr::SpeculativeConnect [ci=%s]\n",
ci->HashKey().get()));
nsCOMPtr<nsISpeculativeConnectionOverrider> overrider =
do_GetInterface(callbacks);
bool allow1918 = overrider ? overrider->GetAllow1918() : false;
// Hosts that are Local IP Literals should not be speculatively
// connected - Bug 853423.
if ((!allow1918) && ci && ci->HostIsLocalIPLiteral()) {
LOG(
("nsHttpConnectionMgr::SpeculativeConnect skipping RFC1918 "
"address [%s]",
ci->Origin()));
return NS_OK;
}
nsAutoCString url(ci->EndToEndSSL() ? "https://"_ns : "http://"_ns);
url += ci->GetOrigin();
PROFILER_MARKER("SpeculativeConnect", NETWORK, {}, UrlMarker, url,
TimeDuration::Zero(), 0);
RefPtr<SpeculativeConnectArgs> args = new SpeculativeConnectArgs();
// Wrap up the callbacks and the target to ensure they're released on the
// target thread properly.
nsCOMPtr<nsIInterfaceRequestor> wrappedCallbacks;
NS_NewInterfaceRequestorAggregation(callbacks, nullptr,
getter_AddRefs(wrappedCallbacks));
caps |= ci->GetAnonymous() ? NS_HTTP_LOAD_ANONYMOUS : 0;
caps |= NS_HTTP_ERROR_SOFTLY;
args->mTrans = aTransaction
? aTransaction
: new SpeculativeTransaction(ci, wrappedCallbacks, caps);
args->mFetchHTTPSRR = aFetchHTTPSRR;
if (overrider) {
args->mTrans->SetParallelSpeculativeConnectLimit(
overrider->GetParallelSpeculativeConnectLimit());
args->mTrans->SetIgnoreIdle(overrider->GetIgnoreIdle());
args->mTrans->SetIsFromPredictor(overrider->GetIsFromPredictor());
args->mTrans->SetAllow1918(overrider->GetAllow1918());
}
return PostEvent(&nsHttpConnectionMgr::OnMsgSpeculativeConnect, 0, args);
}
nsresult nsHttpConnectionMgr::GetSocketThreadTarget(nsIEventTarget** target) {
Unused << EnsureSocketThreadTarget();
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
nsCOMPtr<nsIEventTarget> temp(mSocketThreadTarget);
temp.forget(target);
return NS_OK;
}
nsresult nsHttpConnectionMgr::ReclaimConnection(HttpConnectionBase* conn) {
LOG(("nsHttpConnectionMgr::ReclaimConnection [conn=%p]\n", conn));
Unused << EnsureSocketThreadTarget();
nsCOMPtr<nsIEventTarget> target;
{
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
target = mSocketThreadTarget;
}
if (!target) {
NS_WARNING("cannot post event if not initialized");
return NS_ERROR_NOT_INITIALIZED;
}
RefPtr<HttpConnectionBase> connRef(conn);
RefPtr<nsHttpConnectionMgr> self(this);
return target->Dispatch(NS_NewRunnableFunction(
"nsHttpConnectionMgr::CallReclaimConnection",
[conn{std::move(connRef)}, self{std::move(self)}]() {
self->OnMsgReclaimConnection(conn);
}));
}
// A structure used to marshall 6 pointers across the various necessary
// threads to complete an HTTP upgrade.
class nsCompleteUpgradeData : public ARefBase {
public:
nsCompleteUpgradeData(nsHttpTransaction* aTrans,
nsIHttpUpgradeListener* aListener, bool aJsWrapped)
: mTrans(aTrans), mUpgradeListener(aListener), mJsWrapped(aJsWrapped) {}
NS_INLINE_DECL_THREADSAFE_REFCOUNTING(nsCompleteUpgradeData, override)
RefPtr<nsHttpTransaction> mTrans;
nsCOMPtr<nsIHttpUpgradeListener> mUpgradeListener;
nsCOMPtr<nsISocketTransport> mSocketTransport;
nsCOMPtr<nsIAsyncInputStream> mSocketIn;
nsCOMPtr<nsIAsyncOutputStream> mSocketOut;
bool mJsWrapped;
private:
virtual ~nsCompleteUpgradeData() {
NS_ReleaseOnMainThread("nsCompleteUpgradeData.mUpgradeListener",
mUpgradeListener.forget());
}
};
nsresult nsHttpConnectionMgr::CompleteUpgrade(
HttpTransactionShell* aTrans, nsIHttpUpgradeListener* aUpgradeListener) {
// test if aUpgradeListener is a wrapped JsObject
nsCOMPtr<nsIXPConnectWrappedJS> wrapper = do_QueryInterface(aUpgradeListener);
bool wrapped = !!wrapper;
RefPtr<nsCompleteUpgradeData> data = new nsCompleteUpgradeData(
aTrans->AsHttpTransaction(), aUpgradeListener, wrapped);
return PostEvent(&nsHttpConnectionMgr::OnMsgCompleteUpgrade, 0, data);
}
nsresult nsHttpConnectionMgr::UpdateParam(nsParamName name, uint16_t value) {
uint32_t param = (uint32_t(name) << 16) | uint32_t(value);
return PostEvent(&nsHttpConnectionMgr::OnMsgUpdateParam,
static_cast<int32_t>(param), nullptr);
}
nsresult nsHttpConnectionMgr::ProcessPendingQ(nsHttpConnectionInfo* aCI) {
LOG(("nsHttpConnectionMgr::ProcessPendingQ [ci=%s]\n", aCI->HashKey().get()));
RefPtr<nsHttpConnectionInfo> ci;
if (aCI) {
ci = aCI->Clone();
}
return PostEvent(&nsHttpConnectionMgr::OnMsgProcessPendingQ, 0, ci);
}
nsresult nsHttpConnectionMgr::ProcessPendingQ() {
LOG(("nsHttpConnectionMgr::ProcessPendingQ [All CI]\n"));
return PostEvent(&nsHttpConnectionMgr::OnMsgProcessPendingQ, 0, nullptr);
}
void nsHttpConnectionMgr::OnMsgUpdateRequestTokenBucket(int32_t,
ARefBase* param) {
EventTokenBucket* tokenBucket = static_cast<EventTokenBucket*>(param);
gHttpHandler->SetRequestTokenBucket(tokenBucket);
}
nsresult nsHttpConnectionMgr::UpdateRequestTokenBucket(
EventTokenBucket* aBucket) {
// Call From main thread when a new EventTokenBucket has been made in order
// to post the new value to the socket thread.
return PostEvent(&nsHttpConnectionMgr::OnMsgUpdateRequestTokenBucket, 0,
aBucket);
}
nsresult nsHttpConnectionMgr::ClearConnectionHistory() {
return PostEvent(&nsHttpConnectionMgr::OnMsgClearConnectionHistory, 0,
nullptr);
}
void nsHttpConnectionMgr::OnMsgClearConnectionHistory(int32_t,
ARefBase* param) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::OnMsgClearConnectionHistory"));
for (auto iter = mCT.Iter(); !iter.Done(); iter.Next()) {
RefPtr<ConnectionEntry> ent = iter.Data();
if (ent->IdleConnectionsLength() == 0 && ent->ActiveConnsLength() == 0 &&
ent->DnsAndConnectSocketsLength() == 0 &&
ent->UrgentStartQueueLength() == 0 && ent->PendingQueueLength() == 0 &&
!ent->mDoNotDestroy) {
iter.Remove();
}
}
}
nsresult nsHttpConnectionMgr::CloseIdleConnection(nsHttpConnection* conn) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::CloseIdleConnection %p conn=%p", this, conn));
if (!conn->ConnectionInfo()) {
return NS_ERROR_UNEXPECTED;
}
ConnectionEntry* ent = mCT.GetWeak(conn->ConnectionInfo()->HashKey());
if (!ent || NS_FAILED(ent->CloseIdleConnection(conn))) {
return NS_ERROR_UNEXPECTED;
}
return NS_OK;
}
nsresult nsHttpConnectionMgr::RemoveIdleConnection(nsHttpConnection* conn) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::RemoveIdleConnection %p conn=%p", this, conn));
if (!conn->ConnectionInfo()) {
return NS_ERROR_UNEXPECTED;
}
ConnectionEntry* ent = mCT.GetWeak(conn->ConnectionInfo()->HashKey());
if (!ent || NS_FAILED(ent->RemoveIdleConnection(conn))) {
return NS_ERROR_UNEXPECTED;
}
return NS_OK;
}
HttpConnectionBase* nsHttpConnectionMgr::FindCoalescableConnectionByHashKey(
ConnectionEntry* ent, const nsCString& key, bool justKidding, bool aNoHttp2,
bool aNoHttp3) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
MOZ_ASSERT(!aNoHttp2 || !aNoHttp3);
MOZ_ASSERT(ent->mConnInfo);
nsHttpConnectionInfo* ci = ent->mConnInfo;
nsTArray<nsWeakPtr>* listOfWeakConns = mCoalescingHash.Get(key);
if (!listOfWeakConns) {
return nullptr;
}
uint32_t listLen = listOfWeakConns->Length();
for (uint32_t j = 0; j < listLen;) {
RefPtr<HttpConnectionBase> potentialMatch =
do_QueryReferent(listOfWeakConns->ElementAt(j));
if (!potentialMatch) {
// This is a connection that needs to be removed from the list
LOG(
("FindCoalescableConnectionByHashKey() found old conn %p that has "
"null weak ptr - removing\n",
listOfWeakConns->ElementAt(j).get()));
if (j != listLen - 1) {
listOfWeakConns->Elements()[j] =
listOfWeakConns->Elements()[listLen - 1];
}
listOfWeakConns->RemoveLastElement();
MOZ_ASSERT(listOfWeakConns->Length() == listLen - 1);
listLen--;
continue; // without adjusting iterator
}
if (aNoHttp3 && potentialMatch->UsingHttp3()) {
j++;
continue;
}
if (aNoHttp2 && potentialMatch->UsingSpdy()) {
j++;
continue;
}
bool couldJoin;
if (justKidding) {
couldJoin =
potentialMatch->TestJoinConnection(ci->GetOrigin(), ci->OriginPort());
} else {
couldJoin =
potentialMatch->JoinConnection(ci->GetOrigin(), ci->OriginPort());
}
if (couldJoin) {
LOG(
("FindCoalescableConnectionByHashKey() found match conn=%p key=%s "
"newCI=%s matchedCI=%s join ok\n",
potentialMatch.get(), key.get(), ci->HashKey().get(),
potentialMatch->ConnectionInfo()->HashKey().get()));
return potentialMatch.get();
}
LOG(
("FindCoalescableConnectionByHashKey() found match conn=%p key=%s "
"newCI=%s matchedCI=%s join failed\n",
potentialMatch.get(), key.get(), ci->HashKey().get(),
potentialMatch->ConnectionInfo()->HashKey().get()));
++j; // bypassed by continue when weakptr fails
}
if (!listLen) { // shrunk to 0 while iterating
LOG(("FindCoalescableConnectionByHashKey() removing empty list element\n"));
mCoalescingHash.Remove(key);
}
return nullptr;
}
static void BuildOriginFrameHashKey(nsACString& newKey,
nsHttpConnectionInfo* ci,
const nsACString& host, int32_t port) {
newKey.Assign(host);
if (ci->GetAnonymous()) {
newKey.AppendLiteral("~A:");
} else {
newKey.AppendLiteral("~.:");
}
if (ci->GetFallbackConnection()) {
newKey.AppendLiteral("~F:");
} else {
newKey.AppendLiteral("~.:");
}
newKey.AppendInt(port);
newKey.AppendLiteral("/[");
nsAutoCString suffix;
ci->GetOriginAttributes().CreateSuffix(suffix);
newKey.Append(suffix);
newKey.AppendLiteral("]viaORIGIN.FRAME");
}
HttpConnectionBase* nsHttpConnectionMgr::FindCoalescableConnection(
ConnectionEntry* ent, bool justKidding, bool aNoHttp2, bool aNoHttp3) {
MOZ_ASSERT(!aNoHttp2 || !aNoHttp3);
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
MOZ_ASSERT(ent->mConnInfo);
nsHttpConnectionInfo* ci = ent->mConnInfo;
LOG(("FindCoalescableConnection %s\n", ci->HashKey().get()));
if (ci->GetWebTransport()) {
LOG(("Don't coalesce a WebTransport conn "));
return nullptr;
}
// First try and look it up by origin frame
nsCString newKey;
BuildOriginFrameHashKey(newKey, ci, ci->GetOrigin(), ci->OriginPort());
HttpConnectionBase* conn = FindCoalescableConnectionByHashKey(
ent, newKey, justKidding, aNoHttp2, aNoHttp3);
if (conn) {
LOG(("FindCoalescableConnection(%s) match conn %p on frame key %s\n",
ci->HashKey().get(), conn, newKey.get()));
return conn;
}
// now check for DNS based keys
// deleted conns (null weak pointers) are removed from list
uint32_t keyLen = ent->mCoalescingKeys.Length();
for (uint32_t i = 0; i < keyLen; ++i) {
conn = FindCoalescableConnectionByHashKey(ent, ent->mCoalescingKeys[i],
justKidding, aNoHttp2, aNoHttp3);
auto usableEntry = [&](HttpConnectionBase* conn) {
// This is allowed by the spec, but other browsers don't coalesce
// so agressively, which surprises developers. See bug 1420777.
if (StaticPrefs::network_http_http2_aggressive_coalescing()) {
return true;
}
// Make sure that the connection's IP address is one that is in
// the set of IP addresses in the entry's DNS response.
NetAddr addr;
nsresult rv = conn->GetPeerAddr(&addr);
if (NS_FAILED(rv)) {
// Err on the side of not coalescing
return false;
}
// We don't care about remote port when matching entries.
addr.inet.port = 0;
return ent->mAddresses.Contains(addr);
};
if (conn) {
LOG(("Found connection with matching hash"));
if (usableEntry(conn)) {
LOG(("> coalescing"));
return conn;
} else {
LOG(("> not coalescing as remote address not present in DNS records"));
}
}
}
LOG(("FindCoalescableConnection(%s) no matching conn\n",
ci->HashKey().get()));
return nullptr;
}
void nsHttpConnectionMgr::UpdateCoalescingForNewConn(
HttpConnectionBase* newConn, ConnectionEntry* ent, bool aNoHttp3) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
MOZ_ASSERT(newConn);
MOZ_ASSERT(newConn->ConnectionInfo());
MOZ_ASSERT(ent);
MOZ_ASSERT(mCT.GetWeak(newConn->ConnectionInfo()->HashKey()) == ent);
LOG(("UpdateCoalescingForNewConn newConn=%p aNoHttp3=%d", newConn, aNoHttp3));
if (newConn->ConnectionInfo()->GetWebTransport()) {
LOG(("Don't coalesce a WebTransport conn %p", newConn));
// TODO: implement this properly in bug 1815735.
return;
}
HttpConnectionBase* existingConn =
FindCoalescableConnection(ent, true, false, false);
if (existingConn) {
// Prefer http3 connection, but allow an HTTP/2 connection if it is used for
// WebSocket.
if (newConn->UsingHttp3() && existingConn->UsingSpdy()) {
RefPtr<nsHttpConnection> connTCP = do_QueryObject(existingConn);
if (connTCP && !connTCP->IsForWebSocket()) {
LOG(
("UpdateCoalescingForNewConn() found existing active H2 conn that "
"could have served newConn, but new connection is H3, therefore "
"close the H2 conncetion"));
existingConn->SetCloseReason(
ConnectionCloseReason::CLOSE_EXISTING_CONN_FOR_COALESCING);
existingConn->DontReuse();
}
} else if (existingConn->UsingHttp3() && newConn->UsingSpdy()) {
RefPtr<nsHttpConnection> connTCP = do_QueryObject(newConn);
if (connTCP && !connTCP->IsForWebSocket() && !aNoHttp3) {
LOG(
("UpdateCoalescingForNewConn() found existing active H3 conn that "
"could have served H2 newConn graceful close of newConn=%p to "
"migrate to existingConn %p\n",
newConn, existingConn));
newConn->SetCloseReason(
ConnectionCloseReason::CLOSE_NEW_CONN_FOR_COALESCING);
newConn->DontReuse();
return;
}
} else {
LOG(
("UpdateCoalescingForNewConn() found existing active conn that could "
"have served newConn "
"graceful close of newConn=%p to migrate to existingConn %p\n",
newConn, existingConn));
newConn->SetCloseReason(
ConnectionCloseReason::CLOSE_NEW_CONN_FOR_COALESCING);
newConn->DontReuse();
return;
}
}
// This connection might go into the mCoalescingHash for new transactions to
// be coalesced onto if it can accept new transactions
if (!newConn->CanDirectlyActivate()) {
return;
}
uint32_t keyLen = ent->mCoalescingKeys.Length();
for (uint32_t i = 0; i < keyLen; ++i) {
LOG((
"UpdateCoalescingForNewConn() registering newConn %p %s under key %s\n",
newConn, newConn->ConnectionInfo()->HashKey().get(),
ent->mCoalescingKeys[i].get()));
mCoalescingHash
.LookupOrInsertWith(
ent->mCoalescingKeys[i],
[] {
LOG(("UpdateCoalescingForNewConn() need new list element\n"));
return MakeUnique<nsTArray<nsWeakPtr>>(1);
})
->AppendElement(do_GetWeakReference(
static_cast<nsISupportsWeakReference*>(newConn)));
}
// this is a new connection that can be coalesced onto. hooray!
// if there are other connection to this entry (e.g.
// some could still be handshaking, shutting down, etc..) then close
// them down after any transactions that are on them are complete.
// This probably happened due to the parallel connection algorithm
// that is used only before the host is known to speak h2.
ent->MakeAllDontReuseExcept(newConn);
}
// This function lets a connection, after completing the NPN phase,
// report whether or not it is using spdy through the usingSpdy
// argument. It would not be necessary if NPN were driven out of
// the connection manager. The connection entry associated with the
// connection is then updated to indicate whether or not we want to use
// spdy with that host and update the coalescing hash
// entries used for de-sharding hostsnames.
void nsHttpConnectionMgr::ReportSpdyConnection(nsHttpConnection* conn,
bool usingSpdy,
bool disallowHttp3) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
if (!conn->ConnectionInfo()) {
return;
}
ConnectionEntry* ent = mCT.GetWeak(conn->ConnectionInfo()->HashKey());
if (!ent || !usingSpdy) {
return;
}
ent->mUsingSpdy = true;
mNumSpdyHttp3ActiveConns++;
// adjust timeout timer
uint32_t ttl = conn->TimeToLive();
uint64_t timeOfExpire = NowInSeconds() + ttl;
if (!mTimer || timeOfExpire < mTimeOfNextWakeUp) {
PruneDeadConnectionsAfter(ttl);
}
UpdateCoalescingForNewConn(conn, ent, disallowHttp3);
nsresult rv = ProcessPendingQ(ent->mConnInfo);
if (NS_FAILED(rv)) {
LOG(
("ReportSpdyConnection conn=%p ent=%p "
"failed to process pending queue (%08x)\n",
conn, ent, static_cast<uint32_t>(rv)));
}
rv = PostEvent(&nsHttpConnectionMgr::OnMsgProcessAllSpdyPendingQ);
if (NS_FAILED(rv)) {
LOG(
("ReportSpdyConnection conn=%p ent=%p "
"failed to post event (%08x)\n",
conn, ent, static_cast<uint32_t>(rv)));
}
}
void nsHttpConnectionMgr::ReportHttp3Connection(HttpConnectionBase* conn) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
if (!conn->ConnectionInfo()) {
return;
}
ConnectionEntry* ent = mCT.GetWeak(conn->ConnectionInfo()->HashKey());
if (!ent) {
return;
}
mNumSpdyHttp3ActiveConns++;
UpdateCoalescingForNewConn(conn, ent, false);
nsresult rv = ProcessPendingQ(ent->mConnInfo);
if (NS_FAILED(rv)) {
LOG(
("ReportHttp3Connection conn=%p ent=%p "
"failed to process pending queue (%08x)\n",
conn, ent, static_cast<uint32_t>(rv)));
}
rv = PostEvent(&nsHttpConnectionMgr::OnMsgProcessAllSpdyPendingQ);
if (NS_FAILED(rv)) {
LOG(
("ReportHttp3Connection conn=%p ent=%p "
"failed to post event (%08x)\n",
conn, ent, static_cast<uint32_t>(rv)));
}
}
//-----------------------------------------------------------------------------
bool nsHttpConnectionMgr::DispatchPendingQ(
nsTArray<RefPtr<PendingTransactionInfo>>& pendingQ, ConnectionEntry* ent,
bool considerAll) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
PendingTransactionInfo* pendingTransInfo = nullptr;
nsresult rv;
bool dispatchedSuccessfully = false;
// if !considerAll iterate the pending list until one is dispatched
// successfully. Keep iterating afterwards only until a transaction fails to
// dispatch. if considerAll == true then try and dispatch all items.
for (uint32_t i = 0; i < pendingQ.Length();) {
pendingTransInfo = pendingQ[i];
bool alreadyDnsAndConnectSocketOrWaitingForTLS =
pendingTransInfo->IsAlreadyClaimedInitializingConn();
rv = TryDispatchTransaction(ent, alreadyDnsAndConnectSocketOrWaitingForTLS,
pendingTransInfo);
if (NS_SUCCEEDED(rv) || (rv != NS_ERROR_NOT_AVAILABLE)) {
if (NS_SUCCEEDED(rv)) {
LOG((" dispatching pending transaction...\n"));
} else {
LOG(
(" removing pending transaction based on "
"TryDispatchTransaction returning hard error %" PRIx32 "\n",
static_cast<uint32_t>(rv)));
}
if (pendingQ.RemoveElement(pendingTransInfo)) {
// pendingTransInfo is now potentially destroyed
dispatchedSuccessfully = true;
continue; // dont ++i as we just made the array shorter
}
LOG((" transaction not found in pending queue\n"));
}
if (dispatchedSuccessfully && !considerAll) break;
++i;
}
return dispatchedSuccessfully;
}
uint32_t nsHttpConnectionMgr::MaxPersistConnections(
ConnectionEntry* ent) const {
if (ent->mConnInfo->UsingHttpProxy() && !ent->mConnInfo->UsingConnect()) {
return static_cast<uint32_t>(mMaxPersistConnsPerProxy);
}
return static_cast<uint32_t>(mMaxPersistConnsPerHost);
}
void nsHttpConnectionMgr::PreparePendingQForDispatching(
ConnectionEntry* ent, nsTArray<RefPtr<PendingTransactionInfo>>& pendingQ,
bool considerAll) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
pendingQ.Clear();
uint32_t totalCount = ent->TotalActiveConnections();
uint32_t maxPersistConns = MaxPersistConnections(ent);
uint32_t availableConnections =
maxPersistConns > totalCount ? maxPersistConns - totalCount : 0;
// No need to try dispatching if we reach the active connection limit.
if (!availableConnections) {
return;
}
// Only have to get transactions from the queue whose window id is 0.
if (!gHttpHandler->ActiveTabPriority()) {
ent->AppendPendingQForFocusedWindow(0, pendingQ, availableConnections);
return;
}
uint32_t maxFocusedWindowConnections =
availableConnections * gHttpHandler->FocusedWindowTransactionRatio();
MOZ_ASSERT(maxFocusedWindowConnections < availableConnections);
if (!maxFocusedWindowConnections) {
maxFocusedWindowConnections = 1;
}
// Only need to dispatch transactions for either focused or
// non-focused window because considerAll is false.
if (!considerAll) {
ent->AppendPendingQForFocusedWindow(mCurrentBrowserId, pendingQ,
maxFocusedWindowConnections);
if (pendingQ.IsEmpty()) {
ent->AppendPendingQForNonFocusedWindows(mCurrentBrowserId, pendingQ,
availableConnections);
}
return;
}
uint32_t maxNonFocusedWindowConnections =
availableConnections - maxFocusedWindowConnections;
nsTArray<RefPtr<PendingTransactionInfo>> remainingPendingQ;
ent->AppendPendingQForFocusedWindow(mCurrentBrowserId, pendingQ,
maxFocusedWindowConnections);
if (maxNonFocusedWindowConnections) {
ent->AppendPendingQForNonFocusedWindows(
mCurrentBrowserId, remainingPendingQ, maxNonFocusedWindowConnections);
}
// If the slots for either focused or non-focused window are not filled up
// to the availability, try to use the remaining available connections
// for the other slot (with preference for the focused window).
if (remainingPendingQ.Length() < maxNonFocusedWindowConnections) {
ent->AppendPendingQForFocusedWindow(
mCurrentBrowserId, pendingQ,
maxNonFocusedWindowConnections - remainingPendingQ.Length());
} else if (pendingQ.Length() < maxFocusedWindowConnections) {
ent->AppendPendingQForNonFocusedWindows(
mCurrentBrowserId, remainingPendingQ,
maxFocusedWindowConnections - pendingQ.Length());
}
MOZ_ASSERT(pendingQ.Length() + remainingPendingQ.Length() <=
availableConnections);
LOG(
("nsHttpConnectionMgr::PreparePendingQForDispatching "
"focused window pendingQ.Length()=%zu"
", remainingPendingQ.Length()=%zu\n",
pendingQ.Length(), remainingPendingQ.Length()));
// Append elements in |remainingPendingQ| to |pendingQ|. The order in
// |pendingQ| is like: [focusedWindowTrans...nonFocusedWindowTrans].
pendingQ.AppendElements(std::move(remainingPendingQ));
}
bool nsHttpConnectionMgr::ProcessPendingQForEntry(ConnectionEntry* ent,
bool considerAll) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(
("nsHttpConnectionMgr::ProcessPendingQForEntry "
"[ci=%s ent=%p active=%zu idle=%zu urgent-start-queue=%zu"
" queued=%zu]\n",
ent->mConnInfo->HashKey().get(), ent, ent->ActiveConnsLength(),
ent->IdleConnectionsLength(), ent->UrgentStartQueueLength(),
ent->PendingQueueLength()));
if (LOG_ENABLED()) {
ent->PrintPendingQ();
ent->LogConnections();
}
if (!ent->PendingQueueLength() && !ent->UrgentStartQueueLength()) {
return false;
}
ProcessSpdyPendingQ(ent);
bool dispatchedSuccessfully = false;
if (ent->UrgentStartQueueLength()) {
nsTArray<RefPtr<PendingTransactionInfo>> pendingQ;
ent->AppendPendingUrgentStartQ(pendingQ);
dispatchedSuccessfully = DispatchPendingQ(pendingQ, ent, considerAll);
for (const auto& transactionInfo : Reversed(pendingQ)) {
ent->InsertTransaction(transactionInfo);
}
}
if (dispatchedSuccessfully && !considerAll) {
return dispatchedSuccessfully;
}
nsTArray<RefPtr<PendingTransactionInfo>> pendingQ;
PreparePendingQForDispatching(ent, pendingQ, considerAll);
// The only case that |pendingQ| is empty is when there is no
// connection available for dispatching.
if (pendingQ.IsEmpty()) {
return dispatchedSuccessfully;
}
dispatchedSuccessfully |= DispatchPendingQ(pendingQ, ent, considerAll);
// Put the leftovers into connection entry, in the same order as they
// were before to keep the natural ordering.
for (const auto& transactionInfo : Reversed(pendingQ)) {
ent->InsertTransaction(transactionInfo, true);
}
// Only remove empty pendingQ when considerAll is true.
if (considerAll) {
ent->RemoveEmptyPendingQ();
}
return dispatchedSuccessfully;
}
bool nsHttpConnectionMgr::ProcessPendingQForEntry(nsHttpConnectionInfo* ci) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
ConnectionEntry* ent = mCT.GetWeak(ci->HashKey());
if (ent) return ProcessPendingQForEntry(ent, false);
return false;
}
// we're at the active connection limit if any one of the following conditions
// is true:
// (1) at max-connections
// (2) keep-alive enabled and at max-persistent-connections-per-server/proxy
// (3) keep-alive disabled and at max-connections-per-server
bool nsHttpConnectionMgr::AtActiveConnectionLimit(ConnectionEntry* ent,
uint32_t caps) {
nsHttpConnectionInfo* ci = ent->mConnInfo;
uint32_t totalCount = ent->TotalActiveConnections();
if (ci->IsHttp3()) {
if (ci->GetWebTransport()) {
// TODO: implement this properly in bug 1815735.
return false;
}
return totalCount > 0;
}
uint32_t maxPersistConns = MaxPersistConnections(ent);
LOG(
("nsHttpConnectionMgr::AtActiveConnectionLimit [ci=%s caps=%x,"
"totalCount=%u, maxPersistConns=%u]\n",
ci->HashKey().get(), caps, totalCount, maxPersistConns));
if (caps & NS_HTTP_URGENT_START) {
if (totalCount >= (mMaxUrgentExcessiveConns + maxPersistConns)) {
LOG((
"The number of total connections are greater than or equal to sum of "
"max urgent-start queue length and the number of max persistent "
"connections.\n"));
return true;
}
return false;
}
// update maxconns if potentially limited by the max socket count
// this requires a dynamic reduction in the max socket count to a point
// lower than the max-connections pref.
uint32_t maxSocketCount = gHttpHandler->MaxSocketCount();
if (mMaxConns > maxSocketCount) {
mMaxConns = maxSocketCount;
LOG(("nsHttpConnectionMgr %p mMaxConns dynamically reduced to %u", this,
mMaxConns));
}
// If there are more active connections than the global limit, then we're
// done. Purging idle connections won't get us below it.
if (mNumActiveConns >= mMaxConns) {
LOG((" num active conns == max conns\n"));
return true;
}
bool result = (totalCount >= maxPersistConns);
LOG(("AtActiveConnectionLimit result: %s", result ? "true" : "false"));
return result;
}
// returns NS_OK if a connection was started
// return NS_ERROR_NOT_AVAILABLE if a new connection cannot be made due to
// ephemeral limits
// returns other NS_ERROR on hard failure conditions
nsresult nsHttpConnectionMgr::MakeNewConnection(
ConnectionEntry* ent, PendingTransactionInfo* pendingTransInfo) {
LOG(("nsHttpConnectionMgr::MakeNewConnection %p ent=%p trans=%p", this, ent,
pendingTransInfo->Transaction()));
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
if (ent->FindConnToClaim(pendingTransInfo)) {
return NS_OK;
}
nsHttpTransaction* trans = pendingTransInfo->Transaction();
// If this host is trying to negotiate a SPDY session right now,
// don't create any new connections until the result of the
// negotiation is known.
if (!(trans->Caps() & NS_HTTP_DISALLOW_SPDY) &&
(trans->Caps() & NS_HTTP_ALLOW_KEEPALIVE) && ent->RestrictConnections()) {
LOG(
("nsHttpConnectionMgr::MakeNewConnection [ci = %s] "
"Not Available Due to RestrictConnections()\n",
ent->mConnInfo->HashKey().get()));
return NS_ERROR_NOT_AVAILABLE;
}
// We need to make a new connection. If that is going to exceed the
// global connection limit then try and free up some room by closing
// an idle connection to another host. We know it won't select "ent"
// because we have already determined there are no idle connections
// to our destination
if ((mNumIdleConns + mNumActiveConns + 1 >= mMaxConns) && mNumIdleConns) {
// If the global number of connections is preventing the opening of new
// connections to a host without idle connections, then close them
// regardless of their TTL.
auto iter = mCT.ConstIter();
while (mNumIdleConns + mNumActiveConns + 1 >= mMaxConns && !iter.Done()) {
RefPtr<ConnectionEntry> entry = iter.Data();
entry->CloseIdleConnections((mNumIdleConns + mNumActiveConns + 1) -
mMaxConns);
iter.Next();
}
}
if ((mNumIdleConns + mNumActiveConns + 1 >= mMaxConns) && mNumActiveConns &&
StaticPrefs::network_http_http2_enabled()) {
// If the global number of connections is preventing the opening of new
// connections to a host without idle connections, then close any spdy
// ASAP.
for (const RefPtr<ConnectionEntry>& entry : mCT.Values()) {
while (entry->MakeFirstActiveSpdyConnDontReuse()) {
// Stop on <= (particularly =) because this dontreuse
// causes async close.
if (mNumIdleConns + mNumActiveConns + 1 <= mMaxConns) {
goto outerLoopEnd;
}
}
}
outerLoopEnd:;
}
if (AtActiveConnectionLimit(ent, trans->Caps())) {
return NS_ERROR_NOT_AVAILABLE;
}
nsresult rv = ent->CreateDnsAndConnectSocket(
trans, trans->Caps(), false, false,
trans->GetClassOfService().Flags() & nsIClassOfService::UrgentStart, true,
pendingTransInfo);
if (NS_FAILED(rv)) {
/* hard failure */
LOG(
("nsHttpConnectionMgr::MakeNewConnection [ci = %s trans = %p] "
"CreateDnsAndConnectSocket() hard failure.\n",
ent->mConnInfo->HashKey().get(), trans));
trans->Close(rv);
if (rv == NS_ERROR_NOT_AVAILABLE) rv = NS_ERROR_FAILURE;
return rv;
}
return NS_OK;
}
// returns OK if a connection is found for the transaction
// and the transaction is started.
// returns ERROR_NOT_AVAILABLE if no connection can be found and it
// should be queued until circumstances change
// returns other ERROR when transaction has a hard failure and should
// not remain in the pending queue
nsresult nsHttpConnectionMgr::TryDispatchTransaction(
ConnectionEntry* ent, bool onlyReusedConnection,
PendingTransactionInfo* pendingTransInfo) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
nsHttpTransaction* trans = pendingTransInfo->Transaction();
LOG(
("nsHttpConnectionMgr::TryDispatchTransaction without conn "
"[trans=%p ci=%p ci=%s caps=%x onlyreused=%d active=%zu "
"idle=%zu]\n",
trans, ent->mConnInfo.get(), ent->mConnInfo->HashKey().get(),
uint32_t(trans->Caps()), onlyReusedConnection, ent->ActiveConnsLength(),
ent->IdleConnectionsLength()));
uint32_t caps = trans->Caps();
// 0 - If this should use spdy then dispatch it post haste.
// 1 - If there is connection pressure then see if we can pipeline this on
// a connection of a matching type instead of using a new conn
// 2 - If there is an idle connection, use it!
// 3 - if class == reval or script and there is an open conn of that type
// then pipeline onto shortest pipeline of that class if limits allow
// 4 - If we aren't up against our connection limit,
// then open a new one
// 5 - Try a pipeline if we haven't already - this will be unusual because
// it implies a low connection pressure situation where
// MakeNewConnection() failed.. that is possible, but unlikely, due to
// global limits
// 6 - no connection is available - queue it
RefPtr<HttpConnectionBase> unusedSpdyPersistentConnection;
// step 0
// look for existing spdy connection - that's always best because it is
// essentially pipelining without head of line blocking
RefPtr<HttpConnectionBase> conn = GetH2orH3ActiveConn(
ent,
(!StaticPrefs::network_http_http2_enabled() ||
(caps & NS_HTTP_DISALLOW_SPDY)),
(!nsHttpHandler::IsHttp3Enabled() || (caps & NS_HTTP_DISALLOW_HTTP3)));
if (conn) {
LOG(("TryingDispatchTransaction: an active h2 connection exists"));
WebSocketSupport wsSupp = conn->GetWebSocketSupport();
if (trans->IsWebsocketUpgrade()) {
LOG(("TryingDispatchTransaction: this is a websocket upgrade"));
if (wsSupp == WebSocketSupport::NO_SUPPORT) {
LOG((
"TryingDispatchTransaction: no support for websockets over Http2"));
// This is a websocket transaction and we already have a h2 connection
// that do not support websockets, we should disable h2 for this
// transaction.
trans->DisableSpdy();
caps &= NS_HTTP_DISALLOW_SPDY;
trans->MakeSticky();
} else if (wsSupp == WebSocketSupport::SUPPORTED) {
RefPtr<nsHttpConnection> connTCP = do_QueryObject(conn);
LOG(("TryingDispatchTransaction: websockets over Http2"));
// No limit for number of websockets, dispatch transaction to the tunnel
RefPtr<nsHttpConnection> connToTunnel;
connTCP->CreateTunnelStream(trans, getter_AddRefs(connToTunnel), true);
ent->InsertIntoH2WebsocketConns(connToTunnel);
trans->SetConnection(nullptr);
connToTunnel->SetInSpdyTunnel(); // tells conn it is already in tunnel
trans->SetIsHttp2Websocket(true);
nsresult rv = DispatchTransaction(ent, trans, connToTunnel);
// need to undo NonSticky bypass for transaction reset to continue
// for correct websocket upgrade handling
trans->MakeSticky();
return rv;
} else {
// if we aren't sure that websockets are supported yet or we are
// already at the connection limit then we queue the transaction
LOG(("TryingDispatchTransaction: unsure if websockets over Http2"));
return NS_ERROR_NOT_AVAILABLE;
}
} else {
if ((caps & NS_HTTP_ALLOW_KEEPALIVE) ||
(caps & NS_HTTP_ALLOW_SPDY_WITHOUT_KEEPALIVE) ||
!conn->IsExperienced()) {
LOG((" dispatch to spdy: [conn=%p]\n", conn.get()));
trans->RemoveDispatchedAsBlocking(); /* just in case */
nsresult rv = DispatchTransaction(ent, trans, conn);
NS_ENSURE_SUCCESS(rv, rv);
return NS_OK;
}
unusedSpdyPersistentConnection = conn;
}
}
// If this is not a blocking transaction and the request context for it is
// currently processing one or more blocking transactions then we
// need to just leave it in the queue until those are complete unless it is
// explicitly marked as unblocked.
if (!(caps & NS_HTTP_LOAD_AS_BLOCKING)) {
if (!(caps & NS_HTTP_LOAD_UNBLOCKED)) {
nsIRequestContext* requestContext = trans->RequestContext();
if (requestContext) {
uint32_t blockers = 0;
if (NS_SUCCEEDED(
requestContext->GetBlockingTransactionCount(&blockers)) &&
blockers) {
// need to wait for blockers to clear
LOG((" blocked by request context: [rc=%p trans=%p blockers=%d]\n",
requestContext, trans, blockers));
return NS_ERROR_NOT_AVAILABLE;
}
}
}
} else {
// Mark the transaction and its load group as blocking right now to prevent
// other transactions from being reordered in the queue due to slow syns.
trans->DispatchedAsBlocking();
}
// step 1
// If connection pressure, then we want to favor pipelining of any kind
// h1 pipelining has been removed
// Subject most transactions at high parallelism to rate pacing.
// It will only be actually submitted to the
// token bucket once, and if possible it is granted admission synchronously.
// It is important to leave a transaction in the pending queue when blocked by
// pacing so it can be found on cancel if necessary.
// Transactions that cause blocking or bypass it (e.g. js/css) are not rate
// limited.
if (gHttpHandler->UseRequestTokenBucket()) {
// submit even whitelisted transactions to the token bucket though they will
// not be slowed by it
bool runNow = trans->TryToRunPacedRequest();
if (!runNow) {
if ((mNumActiveConns - mNumSpdyHttp3ActiveConns) <=
gHttpHandler->RequestTokenBucketMinParallelism()) {
runNow = true; // white list it
} else if (caps & (NS_HTTP_LOAD_AS_BLOCKING | NS_HTTP_LOAD_UNBLOCKED)) {
runNow = true; // white list it
}
}
if (!runNow) {
LOG((" blocked due to rate pacing trans=%p\n", trans));
return NS_ERROR_NOT_AVAILABLE;
}
}
// step 2
// consider an idle persistent connection
bool idleConnsAllUrgent = false;
if (caps & NS_HTTP_ALLOW_KEEPALIVE) {
nsresult rv = TryDispatchTransactionOnIdleConn(ent, pendingTransInfo, true,
&idleConnsAllUrgent);
if (NS_SUCCEEDED(rv)) {
LOG((" dispatched step 2 (idle) trans=%p\n", trans));
return NS_OK;
}
}
// step 3
// consider pipelining scripts and revalidations
// h1 pipelining has been removed
// Don't dispatch if this transaction is waiting for HTTPS RR.
// This usually happens when the pref "network.dns.force_waiting_https_rr" is
// true or when echConfig is enabled.
if (trans->WaitingForHTTPSRR()) {
return NS_ERROR_NOT_AVAILABLE;
}
// step 4
if (!onlyReusedConnection) {
nsresult rv = MakeNewConnection(ent, pendingTransInfo);
if (NS_SUCCEEDED(rv)) {
// this function returns NOT_AVAILABLE for asynchronous connects
LOG((" dispatched step 4 (async new conn) trans=%p\n", trans));
return NS_ERROR_NOT_AVAILABLE;
}
if (rv != NS_ERROR_NOT_AVAILABLE) {
// not available return codes should try next step as they are
// not hard errors. Other codes should stop now
LOG((" failed step 4 (%" PRIx32 ") trans=%p\n",
static_cast<uint32_t>(rv), trans));
return rv;
}
// repeat step 2 when there are only idle connections and all are urgent,
// don't respect urgency so that non-urgent transaction will be allowed
// to dispatch on an urgent-start-only marked connection to avoid
// dispatch deadlocks
if (!(trans->GetClassOfService().Flags() &
nsIClassOfService::UrgentStart) &&
idleConnsAllUrgent &&
ent->ActiveConnsLength() < MaxPersistConnections(ent)) {
rv = TryDispatchTransactionOnIdleConn(ent, pendingTransInfo, false);
if (NS_SUCCEEDED(rv)) {
LOG((" dispatched step 2a (idle, reuse urgent) trans=%p\n", trans));
return NS_OK;
}
}
}
// step 5
// previously pipelined anything here if allowed but h1 pipelining has been
// removed
// step 6
if (unusedSpdyPersistentConnection) {
// to avoid deadlocks, we need to throw away this perfectly valid SPDY
// connection to make room for a new one that can service a no KEEPALIVE
// request
unusedSpdyPersistentConnection->DontReuse();
}
LOG((" not dispatched (queued) trans=%p\n", trans));
return NS_ERROR_NOT_AVAILABLE; /* queue it */
}
nsresult nsHttpConnectionMgr::TryDispatchTransactionOnIdleConn(
ConnectionEntry* ent, PendingTransactionInfo* pendingTransInfo,
bool respectUrgency, bool* allUrgent) {
bool onlyUrgent = !!ent->IdleConnectionsLength();
nsHttpTransaction* trans = pendingTransInfo->Transaction();
bool urgentTrans =
trans->GetClassOfService().Flags() & nsIClassOfService::UrgentStart;
LOG(
("nsHttpConnectionMgr::TryDispatchTransactionOnIdleConn, ent=%p, "
"trans=%p, urgent=%d",
ent, trans, urgentTrans));
RefPtr<nsHttpConnection> conn =
ent->GetIdleConnection(respectUrgency, urgentTrans, &onlyUrgent);
if (allUrgent) {
*allUrgent = onlyUrgent;
}
if (conn) {
// This will update the class of the connection to be the class of
// the transaction dispatched on it.
ent->InsertIntoActiveConns(conn);
nsresult rv = DispatchTransaction(ent, trans, conn);
NS_ENSURE_SUCCESS(rv, rv);
return NS_OK;
}
return NS_ERROR_NOT_AVAILABLE;
}
nsresult nsHttpConnectionMgr::DispatchTransaction(ConnectionEntry* ent,
nsHttpTransaction* trans,
HttpConnectionBase* conn) {
uint32_t caps = trans->Caps();
int32_t priority = trans->Priority();
nsresult rv;
LOG(
("nsHttpConnectionMgr::DispatchTransaction "
"[ent-ci=%s %p trans=%p caps=%x conn=%p priority=%d isHttp2=%d "
"isHttp3=%d]\n",
ent->mConnInfo->HashKey().get(), ent, trans, caps, conn, priority,
conn->UsingSpdy(), conn->UsingHttp3()));
// It is possible for a rate-paced transaction to be dispatched independent
// of the token bucket when the amount of parallelization has changed or
// when a muxed connection (e.g. h2) becomes available.
trans->CancelPacing(NS_OK);
TimeStamp now = TimeStamp::Now();
TimeDuration elapsed = now - trans->GetPendingTime();
auto recordPendingTimeForHTTPSRR = [&](nsCString& aKey) {
uint32_t stage = trans->HTTPSSVCReceivedStage();
if (HTTPS_RR_IS_USED(stage)) {
glean::networking::transaction_wait_time_https_rr.AccumulateRawDuration(
elapsed);
} else {
glean::networking::transaction_wait_time.AccumulateRawDuration(elapsed);
}
};
PerfStats::RecordMeasurement(PerfStats::Metric::HttpTransactionWaitTime,
elapsed);
PROFILER_MARKER(
"DispatchTransaction", NETWORK,
MarkerOptions(MarkerThreadId::MainThread(),
MarkerTiming::Interval(trans->GetPendingTime(), now)),
UrlMarker, trans->GetUrl(), elapsed, trans->ChannelId());
nsAutoCString httpVersionkey("h1"_ns);
if (conn->UsingSpdy() || conn->UsingHttp3()) {
LOG(
("Spdy Dispatch Transaction via Activate(). Transaction host = %s, "
"Connection host = %s\n",
trans->ConnectionInfo()->Origin(), conn->ConnectionInfo()->Origin()));
rv = conn->Activate(trans, caps, priority);
if (NS_SUCCEEDED(rv) && !trans->GetPendingTime().IsNull()) {
if (conn->UsingSpdy()) {
httpVersionkey = "h2"_ns;
AccumulateTimeDelta(Telemetry::TRANSACTION_WAIT_TIME_SPDY,
trans->GetPendingTime(), now);
} else {
httpVersionkey = "h3"_ns;
AccumulateTimeDelta(Telemetry::TRANSACTION_WAIT_TIME_HTTP3,
trans->GetPendingTime(), now);
}
recordPendingTimeForHTTPSRR(httpVersionkey);
trans->SetPendingTime(false);
}
return rv;
}
MOZ_ASSERT(conn && !conn->Transaction(),
"DispatchTranaction() on non spdy active connection");
rv = DispatchAbstractTransaction(ent, trans, caps, conn, priority);
if (NS_SUCCEEDED(rv) && !trans->GetPendingTime().IsNull()) {
AccumulateTimeDelta(Telemetry::TRANSACTION_WAIT_TIME_HTTP,
trans->GetPendingTime(), now);
recordPendingTimeForHTTPSRR(httpVersionkey);
trans->SetPendingTime(false);
}
return rv;
}
// Use this method for dispatching nsAHttpTransction's. It can only safely be
// used upon first use of a connection when NPN has not negotiated SPDY vs
// HTTP/1 yet as multiplexing onto an existing SPDY session requires a
// concrete nsHttpTransaction
nsresult nsHttpConnectionMgr::DispatchAbstractTransaction(
ConnectionEntry* ent, nsAHttpTransaction* aTrans, uint32_t caps,
HttpConnectionBase* conn, int32_t priority) {
MOZ_ASSERT(ent);
nsresult rv;
MOZ_ASSERT(!conn->UsingSpdy(),
"Spdy Must Not Use DispatchAbstractTransaction");
LOG(
("nsHttpConnectionMgr::DispatchAbstractTransaction "
"[ci=%s trans=%p caps=%x conn=%p]\n",
ent->mConnInfo->HashKey().get(), aTrans, caps, conn));
RefPtr<nsAHttpTransaction> transaction(aTrans);
RefPtr<ConnectionHandle> handle = new ConnectionHandle(conn);
// give the transaction the indirect reference to the connection.
transaction->SetConnection(handle);
rv = conn->Activate(transaction, caps, priority);
if (NS_FAILED(rv)) {
LOG((" conn->Activate failed [rv=%" PRIx32 "]\n",
static_cast<uint32_t>(rv)));
DebugOnly<nsresult> rv_remove = ent->RemoveActiveConnection(conn);
MOZ_ASSERT(NS_SUCCEEDED(rv_remove));
// sever back references to connection, and do so without triggering
// a call to ReclaimConnection ;-)
transaction->SetConnection(nullptr);
handle->Reset(); // destroy the connection
}
return rv;
}
void nsHttpConnectionMgr::ReportProxyTelemetry(ConnectionEntry* ent) {
enum { PROXY_NONE = 1, PROXY_HTTP = 2, PROXY_SOCKS = 3, PROXY_HTTPS = 4 };
if (!ent->mConnInfo->UsingProxy()) {
Telemetry::Accumulate(Telemetry::HTTP_PROXY_TYPE, PROXY_NONE);
} else if (ent->mConnInfo->UsingHttpsProxy()) {
Telemetry::Accumulate(Telemetry::HTTP_PROXY_TYPE, PROXY_HTTPS);
} else if (ent->mConnInfo->UsingHttpProxy()) {
Telemetry::Accumulate(Telemetry::HTTP_PROXY_TYPE, PROXY_HTTP);
} else {
Telemetry::Accumulate(Telemetry::HTTP_PROXY_TYPE, PROXY_SOCKS);
}
}
nsresult nsHttpConnectionMgr::ProcessNewTransaction(nsHttpTransaction* trans) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
// since "adds" and "cancels" are processed asynchronously and because
// various events might trigger an "add" directly on the socket thread,
// we must take care to avoid dispatching a transaction that has already
// been canceled (see bug 190001).
if (NS_FAILED(trans->Status())) {
LOG((" transaction was canceled... dropping event!\n"));
return NS_OK;
}
// Make sure a transaction is not in a pending queue.
CheckTransInPendingQueue(trans);
trans->SetPendingTime();
PROFILER_MARKER("ProcessNewTransaction", NETWORK,
MarkerThreadId::MainThread(), UrlMarker, trans->GetUrl(),
TimeDuration::Zero(), trans->ChannelId());
RefPtr<Http2PushedStreamWrapper> pushedStreamWrapper =
trans->GetPushedStream();
if (pushedStreamWrapper) {
Http2PushedStream* pushedStream = pushedStreamWrapper->GetStream();
if (pushedStream) {
RefPtr<Http2Session> session = pushedStream->Session();
LOG((" ProcessNewTransaction %p tied to h2 session push %p\n", trans,
session.get()));
return session->AddStream(trans, trans->Priority(), nullptr)
? NS_OK
: NS_ERROR_UNEXPECTED;
}
}
nsresult rv = NS_OK;
nsHttpConnectionInfo* ci = trans->ConnectionInfo();
MOZ_ASSERT(ci);
MOZ_ASSERT(!ci->IsHttp3() || !(trans->Caps() & NS_HTTP_DISALLOW_HTTP3));
bool isWildcard = false;
ConnectionEntry* ent = GetOrCreateConnectionEntry(
ci, trans->Caps() & NS_HTTP_DISALLOW_HTTP2_PROXY,
trans->Caps() & NS_HTTP_DISALLOW_SPDY,
trans->Caps() & NS_HTTP_DISALLOW_HTTP3, &isWildcard);
MOZ_ASSERT(ent);
if (gHttpHandler->EchConfigEnabled(ci->IsHttp3())) {
ent->MaybeUpdateEchConfig(ci);
}
ReportProxyTelemetry(ent);
// Check if the transaction already has a sticky reference to a connection.
// If so, then we can just use it directly by transferring its reference
// to the new connection variable instead of searching for a new one
nsAHttpConnection* wrappedConnection = trans->Connection();
RefPtr<HttpConnectionBase> conn;
RefPtr<PendingTransactionInfo> pendingTransInfo;
if (wrappedConnection) conn = wrappedConnection->TakeHttpConnection();
if (conn) {
MOZ_ASSERT(trans->Caps() & NS_HTTP_STICKY_CONNECTION);
LOG(
("nsHttpConnectionMgr::ProcessNewTransaction trans=%p "
"sticky connection=%p\n",
trans, conn.get()));
if (!ent->IsInActiveConns(conn)) {
LOG(
("nsHttpConnectionMgr::ProcessNewTransaction trans=%p "
"sticky connection=%p needs to go on the active list\n",
trans, conn.get()));
// make sure it isn't on the idle list - we expect this to be an
// unknown fresh connection
MOZ_ASSERT(!ent->IsInIdleConnections(conn));
MOZ_ASSERT(!conn->IsExperienced());
ent->InsertIntoActiveConns(conn); // make it active
}
trans->SetConnection(nullptr);
rv = DispatchTransaction(ent, trans, conn);
} else if (isWildcard) {
// We have a HTTP/2 session to the proxy, create a new tunneled
// connection.
RefPtr<HttpConnectionBase> conn = GetH2orH3ActiveConn(ent, false, true);
RefPtr<nsHttpConnection> connTCP = do_QueryObject(conn);
if (ci->UsingHttpsProxy() && ci->UsingConnect()) {
LOG(("About to create new tunnel conn from [%p]", connTCP.get()));
ConnectionEntry* specificEnt = mCT.GetWeak(ci->HashKey());
if (!specificEnt) {
RefPtr<nsHttpConnectionInfo> clone(ci->Clone());
specificEnt = new ConnectionEntry(clone);
mCT.InsertOrUpdate(clone->HashKey(), RefPtr{specificEnt});
}
ent = specificEnt;
bool atLimit = AtActiveConnectionLimit(ent, trans->Caps());
if (atLimit) {
rv = NS_ERROR_NOT_AVAILABLE;
} else {
RefPtr<nsHttpConnection> newTunnel;
connTCP->CreateTunnelStream(trans, getter_AddRefs(newTunnel));
ent->InsertIntoActiveConns(newTunnel);
trans->SetConnection(nullptr);
newTunnel->SetInSpdyTunnel();
rv = DispatchTransaction(ent, trans, newTunnel);
// need to undo the bypass for transaction reset for proxy
trans->MakeNonRestartable();
}
} else {
rv = DispatchTransaction(ent, trans, connTCP);
}
} else {
if (!ent->AllowHttp2()) {
trans->DisableSpdy();
}
pendingTransInfo = new PendingTransactionInfo(trans);
rv = TryDispatchTransaction(ent, false, pendingTransInfo);
}
if (NS_SUCCEEDED(rv)) {
LOG((" ProcessNewTransaction Dispatch Immediately trans=%p\n", trans));
return rv;
}
if (rv == NS_ERROR_NOT_AVAILABLE) {
if (!pendingTransInfo) {
pendingTransInfo = new PendingTransactionInfo(trans);
}
ent->InsertTransaction(pendingTransInfo);
return NS_OK;
}
LOG((" ProcessNewTransaction Hard Error trans=%p rv=%" PRIx32 "\n", trans,
static_cast<uint32_t>(rv)));
return rv;
}
void nsHttpConnectionMgr::IncrementActiveConnCount() {
mNumActiveConns++;
ActivateTimeoutTick();
}
void nsHttpConnectionMgr::DecrementActiveConnCount(HttpConnectionBase* conn) {
MOZ_DIAGNOSTIC_ASSERT(mNumActiveConns > 0);
if (mNumActiveConns > 0) {
mNumActiveConns--;
}
RefPtr<nsHttpConnection> connTCP = do_QueryObject(conn);
if (!connTCP || connTCP->EverUsedSpdy()) mNumSpdyHttp3ActiveConns--;
ConditionallyStopTimeoutTick();
}
void nsHttpConnectionMgr::StartedConnect() {
mNumActiveConns++;
ActivateTimeoutTick(); // likely disabled by RecvdConnect()
}
void nsHttpConnectionMgr::RecvdConnect() {
MOZ_DIAGNOSTIC_ASSERT(mNumActiveConns > 0);
if (mNumActiveConns > 0) {
mNumActiveConns--;
}
ConditionallyStopTimeoutTick();
}
void nsHttpConnectionMgr::DispatchSpdyPendingQ(
nsTArray<RefPtr<PendingTransactionInfo>>& pendingQ, ConnectionEntry* ent,
HttpConnectionBase* connH2, HttpConnectionBase* connH3) {
if (pendingQ.Length() == 0) {
return;
}
nsTArray<RefPtr<PendingTransactionInfo>> leftovers;
uint32_t index;
// Dispatch all the transactions we can
for (index = 0; index < pendingQ.Length() &&
((connH3 && connH3->CanDirectlyActivate()) ||
(connH2 && connH2->CanDirectlyActivate()));
++index) {
PendingTransactionInfo* pendingTransInfo = pendingQ[index];
// We can not dispatch NS_HTTP_ALLOW_KEEPALIVE transactions.
if (!(pendingTransInfo->Transaction()->Caps() & NS_HTTP_ALLOW_KEEPALIVE)) {
leftovers.AppendElement(pendingTransInfo);
continue;
}
// Try dispatching on HTTP3 first
HttpConnectionBase* conn = nullptr;
if (!(pendingTransInfo->Transaction()->Caps() & NS_HTTP_DISALLOW_HTTP3) &&
connH3 && connH3->CanDirectlyActivate()) {
conn = connH3;
} else if (!(pendingTransInfo->Transaction()->Caps() &
NS_HTTP_DISALLOW_SPDY) &&
connH2 && connH2->CanDirectlyActivate()) {
conn = connH2;
} else {
leftovers.AppendElement(pendingTransInfo);
continue;
}
nsresult rv =
DispatchTransaction(ent, pendingTransInfo->Transaction(), conn);
if (NS_FAILED(rv)) {
// this cannot happen, but if due to some bug it does then
// close the transaction
MOZ_ASSERT(false, "Dispatch SPDY Transaction");
LOG(("ProcessSpdyPendingQ Dispatch Transaction failed trans=%p\n",
pendingTransInfo->Transaction()));
pendingTransInfo->Transaction()->Close(rv);
}
}
// Slurp up the rest of the pending queue into our leftovers bucket (we
// might have some left if conn->CanDirectlyActivate returned false)
for (; index < pendingQ.Length(); ++index) {
PendingTransactionInfo* pendingTransInfo = pendingQ[index];
leftovers.AppendElement(pendingTransInfo);
}
// Put the leftovers back in the pending queue and get rid of the
// transactions we dispatched
pendingQ = std::move(leftovers);
}
// This function tries to dispatch the pending h2 or h3 transactions on
// the connection entry sent in as an argument. It will do so on the
// active h2 or h3 connection either in that same entry or from the
// coalescing hash table
void nsHttpConnectionMgr::ProcessSpdyPendingQ(ConnectionEntry* ent) {
// Look for one HTTP2 and one HTTP3 connection.
// We may have transactions that have NS_HTTP_DISALLOW_SPDY/HTTP3 set
// and we may need an alternative.
HttpConnectionBase* connH3 = GetH2orH3ActiveConn(ent, true, false);
HttpConnectionBase* connH2 = GetH2orH3ActiveConn(ent, false, true);
if ((!connH3 || !connH3->CanDirectlyActivate()) &&
(!connH2 || !connH2->CanDirectlyActivate())) {
return;
}
nsTArray<RefPtr<PendingTransactionInfo>> urgentQ;
ent->AppendPendingUrgentStartQ(urgentQ);
DispatchSpdyPendingQ(urgentQ, ent, connH2, connH3);
for (const auto& transactionInfo : Reversed(urgentQ)) {
ent->InsertTransaction(transactionInfo);
}
if ((!connH3 || !connH3->CanDirectlyActivate()) &&
(!connH2 || !connH2->CanDirectlyActivate())) {
return;
}
nsTArray<RefPtr<PendingTransactionInfo>> pendingQ;
// XXX Get all transactions for SPDY currently.
ent->AppendPendingQForNonFocusedWindows(0, pendingQ);
DispatchSpdyPendingQ(pendingQ, ent, connH2, connH3);
// Put the leftovers back in the pending queue.
for (const auto& transactionInfo : pendingQ) {
ent->InsertTransaction(transactionInfo);
}
}
void nsHttpConnectionMgr::OnMsgProcessAllSpdyPendingQ(int32_t, ARefBase*) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::OnMsgProcessAllSpdyPendingQ\n"));
for (const auto& entry : mCT.Values()) {
ProcessSpdyPendingQ(entry.get());
}
}
// Given a connection entry, return an active h2 or h3 connection
// that can be directly activated or null.
HttpConnectionBase* nsHttpConnectionMgr::GetH2orH3ActiveConn(
ConnectionEntry* ent, bool aNoHttp2, bool aNoHttp3) {
if (aNoHttp2 && aNoHttp3) {
return nullptr;
}
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
MOZ_ASSERT(ent);
// First look at ent. If protocol that ent provides is no forbidden,
// i.e. ent use HTTP3 and !aNoHttp3 or en uses HTTP over TCP and !aNoHttp2.
if ((!aNoHttp3 && ent->IsHttp3()) || (!aNoHttp2 && !ent->IsHttp3())) {
HttpConnectionBase* conn = ent->GetH2orH3ActiveConn();
if (conn) {
return conn;
}
}
nsHttpConnectionInfo* ci = ent->mConnInfo;
// there was no active HTTP2/3 connection in the connection entry, but
// there might be one in the hash table for coalescing
HttpConnectionBase* existingConn =
FindCoalescableConnection(ent, false, aNoHttp2, aNoHttp3);
if (existingConn) {
LOG(
("GetH2orH3ActiveConn() request for ent %p %s "
"found an active connection %p in the coalescing hashtable\n",
ent, ci->HashKey().get(), existingConn));
return existingConn;
}
LOG(
("GetH2orH3ActiveConn() request for ent %p %s "
"did not find an active connection\n",
ent, ci->HashKey().get()));
return nullptr;
}
//-----------------------------------------------------------------------------
void nsHttpConnectionMgr::AbortAndCloseAllConnections(int32_t, ARefBase*) {
if (!OnSocketThread()) {
Unused << PostEvent(&nsHttpConnectionMgr::AbortAndCloseAllConnections);
return;
}
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::AbortAndCloseAllConnections\n"));
for (auto iter = mCT.Iter(); !iter.Done(); iter.Next()) {
RefPtr<ConnectionEntry> ent = iter.Data();
// Close all active connections.
ent->CloseActiveConnections();
// Close all idle connections.
ent->CloseIdleConnections();
// Close websocket "fake" connections
ent->CloseH2WebsocketConnections();
ent->ClosePendingConnections();
// Close all pending transactions.
ent->CancelAllTransactions(NS_ERROR_ABORT);
// Close all half open tcp connections.
ent->CloseAllDnsAndConnectSockets();
MOZ_ASSERT(!ent->mDoNotDestroy);
iter.Remove();
}
mActiveTransactions[false].Clear();
mActiveTransactions[true].Clear();
}
void nsHttpConnectionMgr::OnMsgShutdown(int32_t, ARefBase* param) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::OnMsgShutdown\n"));
gHttpHandler->StopRequestTokenBucket();
AbortAndCloseAllConnections(0, nullptr);
// If all idle connections are removed we can stop pruning dead
// connections.
ConditionallyStopPruneDeadConnectionsTimer();
if (mTimeoutTick) {
mTimeoutTick->Cancel();
mTimeoutTick = nullptr;
mTimeoutTickArmed = false;
}
if (mTimer) {
mTimer->Cancel();
mTimer = nullptr;
}
if (mTrafficTimer) {
mTrafficTimer->Cancel();
mTrafficTimer = nullptr;
}
DestroyThrottleTicker();
mCoalescingHash.Clear();
// signal shutdown complete
nsCOMPtr<nsIRunnable> runnable =
new ConnEvent(this, &nsHttpConnectionMgr::OnMsgShutdownConfirm, 0, param);
NS_DispatchToMainThread(runnable);
}
void nsHttpConnectionMgr::OnMsgShutdownConfirm(int32_t priority,
ARefBase* param) {
MOZ_ASSERT(NS_IsMainThread());
LOG(("nsHttpConnectionMgr::OnMsgShutdownConfirm\n"));
BoolWrapper* shutdown = static_cast<BoolWrapper*>(param);
shutdown->mBool = true;
}
void nsHttpConnectionMgr::OnMsgNewTransaction(int32_t priority,
ARefBase* param) {
nsHttpTransaction* trans = static_cast<nsHttpTransaction*>(param);
LOG(("nsHttpConnectionMgr::OnMsgNewTransaction [trans=%p]\n", trans));
trans->SetPriority(priority);
nsresult rv = ProcessNewTransaction(trans);
if (NS_FAILED(rv)) trans->Close(rv); // for whatever its worth
}
void nsHttpConnectionMgr::OnMsgNewTransactionWithStickyConn(int32_t priority,
ARefBase* param) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
NewTransactionData* data = static_cast<NewTransactionData*>(param);
LOG(
("nsHttpConnectionMgr::OnMsgNewTransactionWithStickyConn "
"[trans=%p, transWithStickyConn=%p, conn=%p]\n",
data->mTrans.get(), data->mTransWithStickyConn.get(),
data->mTransWithStickyConn->Connection()));
MOZ_ASSERT(data->mTransWithStickyConn &&
data->mTransWithStickyConn->Caps() & NS_HTTP_STICKY_CONNECTION);
data->mTrans->SetPriority(data->mPriority);
RefPtr<nsAHttpConnection> conn = data->mTransWithStickyConn->Connection();
if (conn && conn->IsPersistent()) {
// This is so far a workaround to only reuse persistent
// connection for authentication retry. See bug 459620 comment 4
// for details.
LOG((" Reuse connection [%p] for transaction [%p]", conn.get(),
data->mTrans.get()));
data->mTrans->SetConnection(conn);
}
nsresult rv = ProcessNewTransaction(data->mTrans);
if (NS_FAILED(rv)) {
data->mTrans->Close(rv); // for whatever its worth
}
}
void nsHttpConnectionMgr::OnMsgReschedTransaction(int32_t priority,
ARefBase* param) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::OnMsgReschedTransaction [trans=%p]\n", param));
RefPtr<nsHttpTransaction> trans = static_cast<nsHttpTransaction*>(param);
trans->SetPriority(priority);
if (!trans->ConnectionInfo()) {
return;
}
ConnectionEntry* ent = mCT.GetWeak(trans->ConnectionInfo()->HashKey());
if (ent) {
ent->ReschedTransaction(trans);
}
}
void nsHttpConnectionMgr::OnMsgUpdateClassOfServiceOnTransaction(
ClassOfService cos, ARefBase* param) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(
("nsHttpConnectionMgr::OnMsgUpdateClassOfServiceOnTransaction "
"[trans=%p]\n",
param));
nsHttpTransaction* trans = static_cast<nsHttpTransaction*>(param);
ClassOfService previous = trans->GetClassOfService();
trans->SetClassOfService(cos);
// incremental change alone will not trigger a reschedule
if ((previous.Flags() ^ cos.Flags()) &
(NS_HTTP_LOAD_AS_BLOCKING | NS_HTTP_LOAD_UNBLOCKED)) {
Unused << RescheduleTransaction(trans, trans->Priority());
}
}
void nsHttpConnectionMgr::OnMsgCancelTransaction(int32_t reason,
ARefBase* param) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::OnMsgCancelTransaction [trans=%p]\n", param));
nsresult closeCode = static_cast<nsresult>(reason);
// caller holds a ref to param/trans on stack
nsHttpTransaction* trans = static_cast<nsHttpTransaction*>(param);
//
// if the transaction owns a connection and the transaction is not done,
// then ask the connection to close the transaction. otherwise, close the
// transaction directly (removing it from the pending queue first).
//
RefPtr<nsAHttpConnection> conn(trans->Connection());
if (conn && !trans->IsDone()) {
conn->CloseTransaction(trans, closeCode);
} else {
ConnectionEntry* ent = nullptr;
if (trans->ConnectionInfo()) {
ent = mCT.GetWeak(trans->ConnectionInfo()->HashKey());
}
if (ent && ent->RemoveTransFromPendingQ(trans)) {
LOG(
("nsHttpConnectionMgr::OnMsgCancelTransaction [trans=%p]"
" removed from pending queue\n",
trans));
}
trans->Close(closeCode);
// Cancel is a pretty strong signal that things might be hanging
// so we want to cancel any null transactions related to this connection
// entry. They are just optimizations, but they aren't hooked up to
// anything that might get canceled from the rest of gecko, so best
// to assume that's what was meant by the cancel we did receive if
// it only applied to something in the queue.
if (ent) {
ent->CloseAllActiveConnsWithNullTransactcion(closeCode);
}
}
}
void nsHttpConnectionMgr::OnMsgProcessPendingQ(int32_t, ARefBase* param) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
nsHttpConnectionInfo* ci = static_cast<nsHttpConnectionInfo*>(param);
if (!ci) {
LOG(("nsHttpConnectionMgr::OnMsgProcessPendingQ [ci=nullptr]\n"));
// Try and dispatch everything
for (const auto& entry : mCT.Values()) {
Unused << ProcessPendingQForEntry(entry.get(), true);
}
return;
}
LOG(("nsHttpConnectionMgr::OnMsgProcessPendingQ [ci=%s]\n",
ci->HashKey().get()));
// start by processing the queue identified by the given connection info.
ConnectionEntry* ent = mCT.GetWeak(ci->HashKey());
if (!(ent && ProcessPendingQForEntry(ent, false))) {
// if we reach here, it means that we couldn't dispatch a transaction
// for the specified connection info. walk the connection table...
for (const auto& entry : mCT.Values()) {
if (ProcessPendingQForEntry(entry.get(), false)) {
break;
}
}
}
}
nsresult nsHttpConnectionMgr::CancelTransactions(nsHttpConnectionInfo* ci,
nsresult code) {
LOG(("nsHttpConnectionMgr::CancelTransactions %s\n", ci->HashKey().get()));
int32_t intReason = static_cast<int32_t>(code);
return PostEvent(&nsHttpConnectionMgr::OnMsgCancelTransactions, intReason,
ci);
}
void nsHttpConnectionMgr::OnMsgCancelTransactions(int32_t code,
ARefBase* param) {
nsresult reason = static_cast<nsresult>(code);
nsHttpConnectionInfo* ci = static_cast<nsHttpConnectionInfo*>(param);
ConnectionEntry* ent = mCT.GetWeak(ci->HashKey());
LOG(("nsHttpConnectionMgr::OnMsgCancelTransactions %s %p\n",
ci->HashKey().get(), ent));
if (ent) {
ent->CancelAllTransactions(reason);
}
}
void nsHttpConnectionMgr::OnMsgPruneDeadConnections(int32_t, ARefBase*) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::OnMsgPruneDeadConnections\n"));
// Reset mTimeOfNextWakeUp so that we can find a new shortest value.
mTimeOfNextWakeUp = UINT64_MAX;
// check canreuse() for all idle connections plus any active connections on
// connection entries that are using spdy.
if (mNumIdleConns ||
(mNumActiveConns && StaticPrefs::network_http_http2_enabled())) {
for (auto iter = mCT.Iter(); !iter.Done(); iter.Next()) {
RefPtr<ConnectionEntry> ent = iter.Data();
LOG((" pruning [ci=%s]\n", ent->mConnInfo->HashKey().get()));
// Find out how long it will take for next idle connection to not
// be reusable anymore.
uint32_t timeToNextExpire = ent->PruneDeadConnections();
// If time to next expire found is shorter than time to next
// wake-up, we need to change the time for next wake-up.
if (timeToNextExpire != UINT32_MAX) {
uint32_t now = NowInSeconds();
uint64_t timeOfNextExpire = now + timeToNextExpire;
// If pruning of dead connections is not already scheduled to
// happen or time found for next connection to expire is is
// before mTimeOfNextWakeUp, we need to schedule the pruning to
// happen after timeToNextExpire.
if (!mTimer || timeOfNextExpire < mTimeOfNextWakeUp) {
PruneDeadConnectionsAfter(timeToNextExpire);
}
} else {
ConditionallyStopPruneDeadConnectionsTimer();
}
ent->RemoveEmptyPendingQ();
// If this entry is empty, we have too many entries busy then
// we can clean it up and restart
if (mCT.Count() > 125 && ent->IdleConnectionsLength() == 0 &&
ent->ActiveConnsLength() == 0 &&
ent->DnsAndConnectSocketsLength() == 0 &&
ent->PendingQueueLength() == 0 &&
ent->UrgentStartQueueLength() == 0 && !ent->mDoNotDestroy &&
(!ent->mUsingSpdy || mCT.Count() > 300)) {
LOG((" removing empty connection entry\n"));
iter.Remove();
continue;
}
// Otherwise use this opportunity to compact our arrays...
ent->Compact();
}
}
}
void nsHttpConnectionMgr::OnMsgPruneNoTraffic(int32_t, ARefBase*) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::OnMsgPruneNoTraffic\n"));
// Prune connections without traffic
for (const RefPtr<ConnectionEntry>& ent : mCT.Values()) {
// Close the connections with no registered traffic.
ent->PruneNoTraffic();
}
mPruningNoTraffic = false; // not pruning anymore
}
void nsHttpConnectionMgr::OnMsgVerifyTraffic(int32_t, ARefBase*) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::OnMsgVerifyTraffic\n"));
if (mPruningNoTraffic) {
// Called in the time gap when the timeout to prune notraffic
// connections has triggered but the pruning hasn't happened yet.
return;
}
mCoalescingHash.Clear();
// Mark connections for traffic verification
for (const auto& entry : mCT.Values()) {
entry->ResetIPFamilyPreference();
entry->VerifyTraffic();
}
// If the timer is already there. we just re-init it
if (!mTrafficTimer) {
mTrafficTimer = NS_NewTimer();
}
// failure to create a timer is not a fatal error, but dead
// connections will not be cleaned up as nicely
if (mTrafficTimer) {
// Give active connections time to get more traffic before killing
// them off. Default: 5000 milliseconds
mTrafficTimer->Init(this, gHttpHandler->NetworkChangedTimeout(),
nsITimer::TYPE_ONE_SHOT);
} else {
NS_WARNING("failed to create timer for VerifyTraffic!");
}
// Calling ActivateTimeoutTick to ensure the next timeout tick is 1s.
ActivateTimeoutTick();
}
void nsHttpConnectionMgr::OnMsgDoShiftReloadConnectionCleanup(int32_t,
ARefBase* param) {
LOG(("nsHttpConnectionMgr::OnMsgDoShiftReloadConnectionCleanup\n"));
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
mCoalescingHash.Clear();
nsHttpConnectionInfo* ci = static_cast<nsHttpConnectionInfo*>(param);
for (const auto& entry : mCT.Values()) {
entry->ClosePersistentConnections();
}
if (ci) ResetIPFamilyPreference(ci);
}
void nsHttpConnectionMgr::OnMsgDoSingleConnectionCleanup(int32_t,
ARefBase* param) {
LOG(("nsHttpConnectionMgr::OnMsgDoSingleConnectionCleanup\n"));
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
nsHttpConnectionInfo* ci = static_cast<nsHttpConnectionInfo*>(param);
if (!ci) {
return;
}
ConnectionEntry* entry = mCT.GetWeak(ci->HashKey());
if (entry) {
entry->ClosePersistentConnections();
}
ResetIPFamilyPreference(ci);
}
void nsHttpConnectionMgr::OnMsgReclaimConnection(HttpConnectionBase* conn) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
//
// 1) remove the connection from the active list
// 2) if keep-alive, add connection to idle list
// 3) post event to process the pending transaction queue
//
MOZ_ASSERT(conn);
ConnectionEntry* ent = conn->ConnectionInfo()
? mCT.GetWeak(conn->ConnectionInfo()->HashKey())
: nullptr;
if (!ent) {
// this can happen if the connection is made outside of the
// connection manager and is being "reclaimed" for use with
// future transactions. HTTP/2 tunnels work like this.
bool isWildcard = false;
ent = GetOrCreateConnectionEntry(conn->ConnectionInfo(), true, false, false,
&isWildcard);
LOG(
("nsHttpConnectionMgr::OnMsgReclaimConnection conn %p "
"forced new hash entry %s\n",
conn, conn->ConnectionInfo()->HashKey().get()));
}
MOZ_ASSERT(ent);
RefPtr<nsHttpConnectionInfo> ci(ent->mConnInfo);
LOG(("nsHttpConnectionMgr::OnMsgReclaimConnection [ent=%p conn=%p]\n", ent,
conn));
// If the connection is in the active list, remove that entry
// and the reference held by the mActiveConns list.
// This is never the final reference on conn as the event context
// is also holding one that is released at the end of this function.
RefPtr<nsHttpConnection> connTCP = do_QueryObject(conn);
if (!connTCP || connTCP->EverUsedSpdy()) {
// Spdyand Http3 connections aren't reused in the traditional HTTP way in
// the idleconns list, they are actively multplexed as active
// conns. Even when they have 0 transactions on them they are
// considered active connections. So when one is reclaimed it
// is really complete and is meant to be shut down and not
// reused.
conn->DontReuse();
}
// a connection that still holds a reference to a transaction was
// not closed naturally (i.e. it was reset or aborted) and is
// therefore not something that should be reused.
if (conn->Transaction()) {
conn->DontReuse();
}
if (NS_SUCCEEDED(ent->RemoveActiveConnection(conn)) ||
NS_SUCCEEDED(ent->RemovePendingConnection(conn))) {
} else if (!connTCP || connTCP->EverUsedSpdy()) {
LOG(("HttpConnectionBase %p not found in its connection entry, try ^anon",
conn));
// repeat for flipped anon flag as we share connection entries for spdy
// connections.
RefPtr<nsHttpConnectionInfo> anonInvertedCI(ci->Clone());
anonInvertedCI->SetAnonymous(!ci->GetAnonymous());
ConnectionEntry* ent = mCT.GetWeak(anonInvertedCI->HashKey());
if (ent) {
if (NS_SUCCEEDED(ent->RemoveActiveConnection(conn))) {
} else {
LOG(
("HttpConnectionBase %p could not be removed from its entry's "
"active list",
conn));
}
}
}
if (connTCP && connTCP->CanReuse()) {
LOG((" adding connection to idle list\n"));
// Keep The idle connection list sorted with the connections that
// have moved the largest data pipelines at the front because these
// connections have the largest cwnds on the server.
// The linear search is ok here because the number of idleconns
// in a single entry is generally limited to a small number (i.e. 6)
ent->InsertIntoIdleConnections(connTCP);
} else {
if (ent->IsInH2WebsocketConns(conn)) {
ent->RemoveH2WebsocketConns(conn);
}
LOG((" connection cannot be reused; closing connection\n"));
conn->SetCloseReason(ConnectionCloseReason::CANT_REUSED);
conn->Close(NS_ERROR_ABORT);
}
OnMsgProcessPendingQ(0, ci);
}
void nsHttpConnectionMgr::OnMsgCompleteUpgrade(int32_t, ARefBase* param) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
nsresult rv = NS_OK;
nsCompleteUpgradeData* data = static_cast<nsCompleteUpgradeData*>(param);
MOZ_ASSERT(data->mTrans && data->mTrans->Caps() & NS_HTTP_STICKY_CONNECTION);
RefPtr<nsAHttpConnection> conn(data->mTrans->Connection());
LOG(
("nsHttpConnectionMgr::OnMsgCompleteUpgrade "
"conn=%p listener=%p wrapped=%d\n",
conn.get(), data->mUpgradeListener.get(), data->mJsWrapped));
if (!conn) {
// Delay any error reporting to happen in transportAvailableFunc
rv = NS_ERROR_UNEXPECTED;
} else {
MOZ_ASSERT(!data->mSocketTransport);
rv = conn->TakeTransport(getter_AddRefs(data->mSocketTransport),
getter_AddRefs(data->mSocketIn),
getter_AddRefs(data->mSocketOut));
if (NS_FAILED(rv)) {
LOG((" conn->TakeTransport failed with %" PRIx32,
static_cast<uint32_t>(rv)));
}
}
RefPtr<nsCompleteUpgradeData> upgradeData(data);
nsCOMPtr<nsIAsyncInputStream> socketIn;
nsCOMPtr<nsIAsyncOutputStream> socketOut;
// If this is for JS, the input and output sockets need to be piped over the
// socket thread. Otherwise, the JS may attempt to read and/or write the
// sockets on the main thread, which could cause network I/O on the main
// thread. This is particularly bad in the case of TLS connections, because
// PSM and NSS rely on those connections only being used on the socket
// thread.
if (data->mJsWrapped) {
nsCOMPtr<nsIAsyncInputStream> pipeIn;
uint32_t segsize = 0;
uint32_t segcount = 0;
net_ResolveSegmentParams(segsize, segcount);
if (NS_SUCCEEDED(rv)) {
NS_NewPipe2(getter_AddRefs(pipeIn), getter_AddRefs(socketOut), true, true,
segsize, segcount);
rv = NS_AsyncCopy(pipeIn, data->mSocketOut, gSocketTransportService,
NS_ASYNCCOPY_VIA_READSEGMENTS, segsize);
}
nsCOMPtr<nsIAsyncOutputStream> pipeOut;
if (NS_SUCCEEDED(rv)) {
NS_NewPipe2(getter_AddRefs(socketIn), getter_AddRefs(pipeOut), true, true,
segsize, segcount);
rv = NS_AsyncCopy(data->mSocketIn, pipeOut, gSocketTransportService,
NS_ASYNCCOPY_VIA_WRITESEGMENTS, segsize);
}
} else {
socketIn = upgradeData->mSocketIn;
socketOut = upgradeData->mSocketOut;
}
auto transportAvailableFunc = [upgradeData{std::move(upgradeData)}, socketIn,
socketOut, aRv(rv)]() {
// Handle any potential previous errors first
// and call OnUpgradeFailed if necessary.
nsresult rv = aRv;
if (NS_FAILED(rv)) {
rv = upgradeData->mUpgradeListener->OnUpgradeFailed(rv);
if (NS_FAILED(rv)) {
LOG(
("nsHttpConnectionMgr::OnMsgCompleteUpgrade OnUpgradeFailed failed."
" listener=%p\n",
upgradeData->mUpgradeListener.get()));
}
return;
}
rv = upgradeData->mUpgradeListener->OnTransportAvailable(
upgradeData->mSocketTransport, socketIn, socketOut);
if (NS_FAILED(rv)) {
LOG(
("nsHttpConnectionMgr::OnMsgCompleteUpgrade OnTransportAvailable "
"failed. listener=%p\n",
upgradeData->mUpgradeListener.get()));
}
};
if (data->mJsWrapped) {
LOG(
("nsHttpConnectionMgr::OnMsgCompleteUpgrade "
"conn=%p listener=%p wrapped=%d pass to main thread\n",
conn.get(), data->mUpgradeListener.get(), data->mJsWrapped));
NS_DispatchToMainThread(
NS_NewRunnableFunction("net::nsHttpConnectionMgr::OnMsgCompleteUpgrade",
transportAvailableFunc));
} else {
transportAvailableFunc();
}
}
void nsHttpConnectionMgr::OnMsgUpdateParam(int32_t inParam, ARefBase*) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
uint32_t param = static_cast<uint32_t>(inParam);
uint16_t name = ((param) & 0xFFFF0000) >> 16;
uint16_t value = param & 0x0000FFFF;
switch (name) {
case MAX_CONNECTIONS:
mMaxConns = value;
break;
case MAX_URGENT_START_Q:
mMaxUrgentExcessiveConns = value;
break;
case MAX_PERSISTENT_CONNECTIONS_PER_HOST:
mMaxPersistConnsPerHost = value;
break;
case MAX_PERSISTENT_CONNECTIONS_PER_PROXY:
mMaxPersistConnsPerProxy = value;
break;
case MAX_REQUEST_DELAY:
mMaxRequestDelay = value;
break;
case THROTTLING_ENABLED:
SetThrottlingEnabled(!!value);
break;
case THROTTLING_SUSPEND_FOR:
mThrottleSuspendFor = value;
break;
case THROTTLING_RESUME_FOR:
mThrottleResumeFor = value;
break;
case THROTTLING_READ_LIMIT:
mThrottleReadLimit = value;
break;
case THROTTLING_READ_INTERVAL:
mThrottleReadInterval = value;
break;
case THROTTLING_HOLD_TIME:
mThrottleHoldTime = value;
break;
case THROTTLING_MAX_TIME:
mThrottleMaxTime = TimeDuration::FromMilliseconds(value);
break;
case PROXY_BE_CONSERVATIVE:
mBeConservativeForProxy = !!value;
break;
default:
MOZ_ASSERT_UNREACHABLE("unexpected parameter name");
}
}
// Read Timeout Tick handlers
void nsHttpConnectionMgr::ActivateTimeoutTick() {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(
("nsHttpConnectionMgr::ActivateTimeoutTick() "
"this=%p mTimeoutTick=%p\n",
this, mTimeoutTick.get()));
// The timer tick should be enabled if it is not already pending.
// Upon running the tick will rearm itself if there are active
// connections available.
if (mTimeoutTick && mTimeoutTickArmed) {
// make sure we get one iteration on a quick tick
if (mTimeoutTickNext > 1) {
mTimeoutTickNext = 1;
mTimeoutTick->SetDelay(1000);
}
return;
}
if (!mTimeoutTick) {
mTimeoutTick = NS_NewTimer();
if (!mTimeoutTick) {
NS_WARNING("failed to create timer for http timeout management");
return;
}
ReentrantMonitorAutoEnter mon(mReentrantMonitor);
if (!mSocketThreadTarget) {
NS_WARNING("cannot activate timout if not initialized or shutdown");
return;
}
mTimeoutTick->SetTarget(mSocketThreadTarget);
}
if (mIsShuttingDown) { // Atomic
// don't set a timer to generate an event if we're shutting down
// (and mSocketThreadTarget might be null or garbage if we're shutting down)
return;
}
MOZ_ASSERT(!mTimeoutTickArmed, "timer tick armed");
mTimeoutTickArmed = true;
mTimeoutTick->Init(this, 1000, nsITimer::TYPE_REPEATING_SLACK);
}
class UINT64Wrapper : public ARefBase {
public:
explicit UINT64Wrapper(uint64_t aUint64) : mUint64(aUint64) {}
NS_INLINE_DECL_THREADSAFE_REFCOUNTING(UINT64Wrapper, override)
uint64_t GetValue() { return mUint64; }
private:
uint64_t mUint64;
virtual ~UINT64Wrapper() = default;
};
nsresult nsHttpConnectionMgr::UpdateCurrentBrowserId(uint64_t aId) {
RefPtr<UINT64Wrapper> idWrapper = new UINT64Wrapper(aId);
return PostEvent(&nsHttpConnectionMgr::OnMsgUpdateCurrentBrowserId, 0,
idWrapper);
}
void nsHttpConnectionMgr::SetThrottlingEnabled(bool aEnable) {
LOG(("nsHttpConnectionMgr::SetThrottlingEnabled enable=%d", aEnable));
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
mThrottleEnabled = aEnable;
if (mThrottleEnabled) {
EnsureThrottleTickerIfNeeded();
} else {
DestroyThrottleTicker();
ResumeReadOf(mActiveTransactions[false]);
ResumeReadOf(mActiveTransactions[true]);
}
}
bool nsHttpConnectionMgr::InThrottlingTimeWindow() {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
if (mThrottlingWindowEndsAt.IsNull()) {
return true;
}
return TimeStamp::NowLoRes() <= mThrottlingWindowEndsAt;
}
void nsHttpConnectionMgr::TouchThrottlingTimeWindow(bool aEnsureTicker) {
LOG(("nsHttpConnectionMgr::TouchThrottlingTimeWindow"));
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
mThrottlingWindowEndsAt = TimeStamp::NowLoRes() + mThrottleMaxTime;
if (!mThrottleTicker && MOZ_LIKELY(aEnsureTicker) &&
MOZ_LIKELY(mThrottleEnabled)) {
EnsureThrottleTickerIfNeeded();
}
}
void nsHttpConnectionMgr::LogActiveTransactions(char operation) {
if (!LOG_ENABLED()) {
return;
}
nsTArray<RefPtr<nsHttpTransaction>>* trs = nullptr;
uint32_t au, at, bu = 0, bt = 0;
trs = mActiveTransactions[false].Get(mCurrentBrowserId);
au = trs ? trs->Length() : 0;
trs = mActiveTransactions[true].Get(mCurrentBrowserId);
at = trs ? trs->Length() : 0;
for (const auto& data : mActiveTransactions[false].Values()) {
bu += data->Length();
}
bu -= au;
for (const auto& data : mActiveTransactions[true].Values()) {
bt += data->Length();
}
bt -= at;
// Shows counts of:
// - unthrottled transaction for the active tab
// - throttled transaction for the active tab
// - unthrottled transaction for background tabs
// - throttled transaction for background tabs
LOG(("Active transactions %c[%u,%u,%u,%u]", operation, au, at, bu, bt));
}
void nsHttpConnectionMgr::AddActiveTransaction(nsHttpTransaction* aTrans) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
uint64_t tabId = aTrans->BrowserId();
bool throttled = aTrans->EligibleForThrottling();
nsTArray<RefPtr<nsHttpTransaction>>* transactions =
mActiveTransactions[throttled].GetOrInsertNew(tabId);
MOZ_ASSERT(!transactions->Contains(aTrans));
transactions->AppendElement(aTrans);
LOG(("nsHttpConnectionMgr::AddActiveTransaction t=%p tabid=%" PRIx64
"(%d) thr=%d",
aTrans, tabId, tabId == mCurrentBrowserId, throttled));
LogActiveTransactions('+');
if (tabId == mCurrentBrowserId) {
mActiveTabTransactionsExist = true;
if (!throttled) {
mActiveTabUnthrottledTransactionsExist = true;
}
}
// Shift the throttling window to the future (actually, makes sure
// that throttling will engage when there is anything to throttle.)
// The |false| argument means we don't need this call to ensure
// the ticker, since we do it just below. Calling
// EnsureThrottleTickerIfNeeded directly does a bit more than call
// from inside of TouchThrottlingTimeWindow.
TouchThrottlingTimeWindow(false);
if (!mThrottleEnabled) {
return;
}
EnsureThrottleTickerIfNeeded();
}
void nsHttpConnectionMgr::RemoveActiveTransaction(
nsHttpTransaction* aTrans, Maybe<bool> const& aOverride) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
uint64_t tabId = aTrans->BrowserId();
bool forActiveTab = tabId == mCurrentBrowserId;
bool throttled = aOverride.valueOr(aTrans->EligibleForThrottling());
nsTArray<RefPtr<nsHttpTransaction>>* transactions =
mActiveTransactions[throttled].Get(tabId);
if (!transactions || !transactions->RemoveElement(aTrans)) {
// Was not tracked as active, probably just ignore.
return;
}
LOG(("nsHttpConnectionMgr::RemoveActiveTransaction t=%p tabid=%" PRIx64
"(%d) thr=%d",
aTrans, tabId, forActiveTab, throttled));
if (!transactions->IsEmpty()) {
// There are still transactions of the type, hence nothing in the throttling
// conditions has changed and we don't need to update "Exists" caches nor we
// need to wake any now throttled transactions.
LogActiveTransactions('-');
return;
}
// To optimize the following logic, always remove the entry when the array is
// empty.
mActiveTransactions[throttled].Remove(tabId);
LogActiveTransactions('-');
if (forActiveTab) {
// Update caches of the active tab transaction existence, since it's now
// affected
if (!throttled) {
mActiveTabUnthrottledTransactionsExist = false;
}
if (mActiveTabTransactionsExist) {
mActiveTabTransactionsExist =
mActiveTransactions[!throttled].Contains(tabId);
}
}
if (!mThrottleEnabled) {
return;
}
bool unthrottledExist = !mActiveTransactions[false].IsEmpty();
bool throttledExist = !mActiveTransactions[true].IsEmpty();
if (!unthrottledExist && !throttledExist) {
// Nothing active globally, just get rid of the timer completely and we are
// done.
MOZ_ASSERT(!mActiveTabUnthrottledTransactionsExist);
MOZ_ASSERT(!mActiveTabTransactionsExist);
DestroyThrottleTicker();
return;
}
if (mThrottleVersion == 1) {
if (!mThrottlingInhibitsReading) {
// There is then nothing to wake up. Affected transactions will not be
// put to sleep automatically on next tick.
LOG((" reading not currently inhibited"));
return;
}
}
if (mActiveTabUnthrottledTransactionsExist) {
// There are still unthrottled transactions for the active tab, hence the
// state is unaffected and we don't need to do anything (nothing to wake).
LOG((" there are unthrottled for the active tab"));
return;
}
if (mActiveTabTransactionsExist) {
// There are only trottled transactions for the active tab.
// If the last transaction we just removed was a non-throttled for the
// active tab we can wake the throttled transactions for the active tab.
if (forActiveTab && !throttled) {
LOG((" resuming throttled for active tab"));
ResumeReadOf(mActiveTransactions[true].Get(mCurrentBrowserId));
}
return;
}
if (!unthrottledExist) {
// There are no unthrottled transactions for any tab. Resume all throttled,
// all are only for background tabs.
LOG((" delay resuming throttled for background tabs"));
DelayedResumeBackgroundThrottledTransactions();
return;
}
if (forActiveTab) {
// Removing the last transaction for the active tab frees up the unthrottled
// background tabs transactions.
LOG((" delay resuming unthrottled for background tabs"));
DelayedResumeBackgroundThrottledTransactions();
return;
}
LOG((" not resuming anything"));
}
void nsHttpConnectionMgr::UpdateActiveTransaction(nsHttpTransaction* aTrans) {
LOG(("nsHttpConnectionMgr::UpdateActiveTransaction ENTER t=%p", aTrans));
// First remove then add. In case of a download that is the only active
// transaction and has just been marked as download (goes unthrottled to
// throttled), adding first would cause it to be throttled for first few
// milliseconds - becuause it would appear as if there were both throttled
// and unthrottled transactions at the time.
Maybe<bool> reversed;
reversed.emplace(!aTrans->EligibleForThrottling());
RemoveActiveTransaction(aTrans, reversed);
AddActiveTransaction(aTrans);
LOG(("nsHttpConnectionMgr::UpdateActiveTransaction EXIT t=%p", aTrans));
}
bool nsHttpConnectionMgr::ShouldThrottle(nsHttpTransaction* aTrans) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::ShouldThrottle trans=%p", aTrans));
if (mThrottleVersion == 1) {
if (!mThrottlingInhibitsReading || !mThrottleEnabled) {
return false;
}
} else {
if (!mThrottleEnabled) {
return false;
}
}
uint64_t tabId = aTrans->BrowserId();
bool forActiveTab = tabId == mCurrentBrowserId;
bool throttled = aTrans->EligibleForThrottling();
bool stop = [=]() {
if (mActiveTabTransactionsExist) {
if (!tabId) {
// Chrome initiated and unidentified transactions just respect
// their throttle flag, when something for the active tab is happening.
// This also includes downloads.
LOG((" active tab loads, trans is tab-less, throttled=%d", throttled));
return throttled;
}
if (!forActiveTab) {
// This is a background tab request, we want them to always throttle
// when there are transactions running for the ative tab.
LOG((" active tab loads, trans not of the active tab"));
return true;
}
if (mActiveTabUnthrottledTransactionsExist) {
// Unthrottled transactions for the active tab take precedence
LOG((" active tab loads unthrottled, trans throttled=%d", throttled));
return throttled;
}
LOG((" trans for active tab, don't throttle"));
return false;
}
MOZ_ASSERT(!forActiveTab);
if (!mActiveTransactions[false].IsEmpty()) {
// This means there are unthrottled active transactions for background
// tabs. If we are here, there can't be any transactions for the active
// tab. (If there is no transaction for a tab id, there is no entry for it
// in the hashtable.)
LOG((" backround tab(s) load unthrottled, trans throttled=%d",
throttled));
return throttled;
}
// There are only unthrottled transactions for background tabs: don't
// throttle.
LOG((" backround tab(s) load throttled, don't throttle"));
return false;
}();
if (forActiveTab && !stop) {
// This is an active-tab transaction and is allowed to read. Hence,
// prolong the throttle time window to make sure all 'lower-decks'
// transactions will actually throttle.
TouchThrottlingTimeWindow();
return false;
}
// Only stop reading when in the configured throttle max-time (aka time
// window). This window is prolonged (restarted) by a call to
// TouchThrottlingTimeWindow called on new transaction activation or on
// receive of response bytes of an active tab transaction.
bool inWindow = InThrottlingTimeWindow();
LOG((" stop=%d, in-window=%d, delayed-bck-timer=%d", stop, inWindow,
!!mDelayedResumeReadTimer));
if (!forActiveTab) {
// If the delayed background resume timer exists, background transactions
// are scheduled to be woken after a delay, hence leave them throttled.
inWindow = inWindow || mDelayedResumeReadTimer;
}
return stop && inWindow;
}
bool nsHttpConnectionMgr::IsConnEntryUnderPressure(
nsHttpConnectionInfo* connInfo) {
ConnectionEntry* ent = mCT.GetWeak(connInfo->HashKey());
if (!ent) {
// No entry, no pressure.
return false;
}
return ent->PendingQueueLengthForWindow(mCurrentBrowserId) > 0;
}
bool nsHttpConnectionMgr::IsThrottleTickerNeeded() {
LOG(("nsHttpConnectionMgr::IsThrottleTickerNeeded"));
if (mActiveTabUnthrottledTransactionsExist &&
mActiveTransactions[false].Count() > 1) {
LOG((" there are unthrottled transactions for both active and bck"));
return true;
}
if (mActiveTabTransactionsExist && mActiveTransactions[true].Count() > 1) {
LOG((" there are throttled transactions for both active and bck"));
return true;
}
if (!mActiveTransactions[true].IsEmpty() &&
!mActiveTransactions[false].IsEmpty()) {
LOG((" there are both throttled and unthrottled transactions"));
return true;
}
LOG((" nothing to throttle"));
return false;
}
void nsHttpConnectionMgr::EnsureThrottleTickerIfNeeded() {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::EnsureThrottleTickerIfNeeded"));
if (!IsThrottleTickerNeeded()) {
return;
}
// There is a new demand to throttle, hence unschedule delayed resume
// of background throttled transastions.
CancelDelayedResumeBackgroundThrottledTransactions();
if (mThrottleTicker) {
return;
}
mThrottleTicker = NS_NewTimer();
if (mThrottleTicker) {
if (mThrottleVersion == 1) {
MOZ_ASSERT(!mThrottlingInhibitsReading);
mThrottleTicker->Init(this, mThrottleSuspendFor, nsITimer::TYPE_ONE_SHOT);
mThrottlingInhibitsReading = true;
} else {
mThrottleTicker->Init(this, mThrottleReadInterval,
nsITimer::TYPE_ONE_SHOT);
}
}
LogActiveTransactions('^');
}
// Can be called with or without the monitor held
void nsHttpConnectionMgr::DestroyThrottleTicker() {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
// Nothing to throttle, hence no need for this timer anymore.
CancelDelayedResumeBackgroundThrottledTransactions();
MOZ_ASSERT(!mThrottleEnabled || !IsThrottleTickerNeeded());
if (!mThrottleTicker) {
return;
}
LOG(("nsHttpConnectionMgr::DestroyThrottleTicker"));
mThrottleTicker->Cancel();
mThrottleTicker = nullptr;
if (mThrottleVersion == 1) {
mThrottlingInhibitsReading = false;
}
LogActiveTransactions('v');
}
void nsHttpConnectionMgr::ThrottlerTick() {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
if (mThrottleVersion == 1) {
mThrottlingInhibitsReading = !mThrottlingInhibitsReading;
LOG(("nsHttpConnectionMgr::ThrottlerTick inhibit=%d",
mThrottlingInhibitsReading));
// If there are only background transactions to be woken after a delay, keep
// the ticker so that we woke them only for the resume-for interval and then
// throttle them again until the background-resume delay passes.
if (!mThrottlingInhibitsReading && !mDelayedResumeReadTimer &&
(!IsThrottleTickerNeeded() || !InThrottlingTimeWindow())) {
LOG((" last tick"));
mThrottleTicker = nullptr;
}
if (mThrottlingInhibitsReading) {
if (mThrottleTicker) {
mThrottleTicker->Init(this, mThrottleSuspendFor,
nsITimer::TYPE_ONE_SHOT);
}
} else {
if (mThrottleTicker) {
mThrottleTicker->Init(this, mThrottleResumeFor,
nsITimer::TYPE_ONE_SHOT);
}
ResumeReadOf(mActiveTransactions[false], true);
ResumeReadOf(mActiveTransactions[true]);
}
} else {
LOG(("nsHttpConnectionMgr::ThrottlerTick"));
// If there are only background transactions to be woken after a delay, keep
// the ticker so that we still keep the low read limit for that time.
if (!mDelayedResumeReadTimer &&
(!IsThrottleTickerNeeded() || !InThrottlingTimeWindow())) {
LOG((" last tick"));
mThrottleTicker = nullptr;
}
if (mThrottleTicker) {
mThrottleTicker->Init(this, mThrottleReadInterval,
nsITimer::TYPE_ONE_SHOT);
}
ResumeReadOf(mActiveTransactions[false], true);
ResumeReadOf(mActiveTransactions[true]);
}
}
void nsHttpConnectionMgr::DelayedResumeBackgroundThrottledTransactions() {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
if (mThrottleVersion == 1) {
if (mDelayedResumeReadTimer) {
return;
}
} else {
// If the mThrottleTicker doesn't exist, there is nothing currently
// being throttled. Hence, don't invoke the hold time interval.
// This is called also when a single download transaction becomes
// marked as throttleable. We would otherwise block it unnecessarily.
if (mDelayedResumeReadTimer || !mThrottleTicker) {
return;
}
}
LOG(("nsHttpConnectionMgr::DelayedResumeBackgroundThrottledTransactions"));
NS_NewTimerWithObserver(getter_AddRefs(mDelayedResumeReadTimer), this,
mThrottleHoldTime, nsITimer::TYPE_ONE_SHOT);
}
void nsHttpConnectionMgr::CancelDelayedResumeBackgroundThrottledTransactions() {
if (!mDelayedResumeReadTimer) {
return;
}
LOG(
("nsHttpConnectionMgr::"
"CancelDelayedResumeBackgroundThrottledTransactions"));
mDelayedResumeReadTimer->Cancel();
mDelayedResumeReadTimer = nullptr;
}
void nsHttpConnectionMgr::ResumeBackgroundThrottledTransactions() {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::ResumeBackgroundThrottledTransactions"));
mDelayedResumeReadTimer = nullptr;
if (!IsThrottleTickerNeeded()) {
DestroyThrottleTicker();
}
if (!mActiveTransactions[false].IsEmpty()) {
ResumeReadOf(mActiveTransactions[false], true);
} else {
ResumeReadOf(mActiveTransactions[true], true);
}
}
void nsHttpConnectionMgr::ResumeReadOf(
nsClassHashtable<nsUint64HashKey, nsTArray<RefPtr<nsHttpTransaction>>>&
hashtable,
bool excludeForActiveTab) {
for (const auto& entry : hashtable) {
if (excludeForActiveTab && entry.GetKey() == mCurrentBrowserId) {
// These have never been throttled (never stopped reading)
continue;
}
ResumeReadOf(entry.GetWeak());
}
}
void nsHttpConnectionMgr::ResumeReadOf(
nsTArray<RefPtr<nsHttpTransaction>>* transactions) {
MOZ_ASSERT(transactions);
for (const auto& trans : *transactions) {
trans->ResumeReading();
}
}
void nsHttpConnectionMgr::NotifyConnectionOfBrowserIdChange(
uint64_t previousId) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
nsTArray<RefPtr<nsHttpTransaction>>* transactions = nullptr;
nsTArray<RefPtr<nsAHttpConnection>> connections;
auto addConnectionHelper =
[&connections](nsTArray<RefPtr<nsHttpTransaction>>* trans) {
if (!trans) {
return;
}
for (const auto& t : *trans) {
RefPtr<nsAHttpConnection> conn = t->Connection();
if (conn && !connections.Contains(conn)) {
connections.AppendElement(conn);
}
}
};
// Get unthrottled transactions with the previous and current window id.
transactions = mActiveTransactions[false].Get(previousId);
addConnectionHelper(transactions);
transactions = mActiveTransactions[false].Get(mCurrentBrowserId);
addConnectionHelper(transactions);
// Get throttled transactions with the previous and current window id.
transactions = mActiveTransactions[true].Get(previousId);
addConnectionHelper(transactions);
transactions = mActiveTransactions[true].Get(mCurrentBrowserId);
addConnectionHelper(transactions);
for (const auto& conn : connections) {
conn->CurrentBrowserIdChanged(mCurrentBrowserId);
}
}
void nsHttpConnectionMgr::OnMsgUpdateCurrentBrowserId(int32_t aLoading,
ARefBase* param) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
uint64_t id = static_cast<UINT64Wrapper*>(param)->GetValue();
if (mCurrentBrowserId == id) {
// duplicate notification
return;
}
bool activeTabWasLoading = mActiveTabTransactionsExist;
uint64_t previousId = mCurrentBrowserId;
mCurrentBrowserId = id;
if (gHttpHandler->ActiveTabPriority()) {
NotifyConnectionOfBrowserIdChange(previousId);
}
LOG(
("nsHttpConnectionMgr::OnMsgUpdateCurrentBrowserId"
" id=%" PRIx64 "\n",
mCurrentBrowserId));
nsTArray<RefPtr<nsHttpTransaction>>* transactions = nullptr;
// Update the "Exists" caches and resume any transactions that now deserve it,
// changing the active tab changes the conditions for throttling.
transactions = mActiveTransactions[false].Get(mCurrentBrowserId);
mActiveTabUnthrottledTransactionsExist = !!transactions;
if (!mActiveTabUnthrottledTransactionsExist) {
transactions = mActiveTransactions[true].Get(mCurrentBrowserId);
}
mActiveTabTransactionsExist = !!transactions;
if (transactions) {
// This means there are some transactions for this newly activated tab,
// resume them but anything else.
LOG((" resuming newly activated tab transactions"));
ResumeReadOf(transactions);
return;
}
if (!activeTabWasLoading) {
// There were no transactions for the previously active tab, hence
// all remaning transactions, if there were, were all unthrottled,
// no need to wake them.
return;
}
if (!mActiveTransactions[false].IsEmpty()) {
LOG((" resuming unthrottled background transactions"));
ResumeReadOf(mActiveTransactions[false]);
return;
}
if (!mActiveTransactions[true].IsEmpty()) {
LOG((" resuming throttled background transactions"));
ResumeReadOf(mActiveTransactions[true]);
return;
}
DestroyThrottleTicker();
}
void nsHttpConnectionMgr::TimeoutTick() {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
MOZ_ASSERT(mTimeoutTick, "no readtimeout tick");
LOG(("nsHttpConnectionMgr::TimeoutTick active=%d\n", mNumActiveConns));
// The next tick will be between 1 second and 1 hr
// Set it to the max value here, and the TimeoutTick()s can
// reduce it to their local needs.
mTimeoutTickNext = 3600; // 1hr
for (const RefPtr<ConnectionEntry>& ent : mCT.Values()) {
uint32_t timeoutTickNext = ent->TimeoutTick();
mTimeoutTickNext = std::min(mTimeoutTickNext, timeoutTickNext);
}
if (mTimeoutTick) {
mTimeoutTickNext = std::max(mTimeoutTickNext, 1U);
mTimeoutTick->SetDelay(mTimeoutTickNext * 1000);
}
}
// GetOrCreateConnectionEntry finds a ent for a particular CI for use in
// dispatching a transaction according to these rules
// 1] use an ent that matches the ci that can be dispatched immediately
// 2] otherwise use an ent of wildcard(ci) than can be dispatched immediately
// 3] otherwise create an ent that matches ci and make new conn on it
ConnectionEntry* nsHttpConnectionMgr::GetOrCreateConnectionEntry(
nsHttpConnectionInfo* specificCI, bool prohibitWildCard, bool aNoHttp2,
bool aNoHttp3, bool* aIsWildcard, bool* aAvailableForDispatchNow) {
if (aAvailableForDispatchNow) {
*aAvailableForDispatchNow = false;
}
*aIsWildcard = false;
// step 1
ConnectionEntry* specificEnt = mCT.GetWeak(specificCI->HashKey());
if (specificEnt && specificEnt->AvailableForDispatchNow()) {
if (aAvailableForDispatchNow) {
*aAvailableForDispatchNow = true;
}
return specificEnt;
}
// step 1 repeated for an inverted anonymous flag; we return an entry
// only when it has an h2 established connection that is not authenticated
// with a client certificate.
RefPtr<nsHttpConnectionInfo> anonInvertedCI(specificCI->Clone());
anonInvertedCI->SetAnonymous(!specificCI->GetAnonymous());
ConnectionEntry* invertedEnt = mCT.GetWeak(anonInvertedCI->HashKey());
if (invertedEnt) {
HttpConnectionBase* h2orh3conn =
GetH2orH3ActiveConn(invertedEnt, aNoHttp2, aNoHttp3);
if (h2orh3conn && h2orh3conn->IsExperienced() &&
h2orh3conn->NoClientCertAuth()) {
MOZ_ASSERT(h2orh3conn->UsingSpdy() || h2orh3conn->UsingHttp3());
LOG(
("GetOrCreateConnectionEntry is coalescing h2/3 an/onymous "
"connections, ent=%p",
invertedEnt));
return invertedEnt;
}
}
if (!specificCI->UsingHttpsProxy()) {
prohibitWildCard = true;
}
// step 2
if (!prohibitWildCard && aNoHttp3) {
RefPtr<nsHttpConnectionInfo> wildCardProxyCI;
DebugOnly<nsresult> rv =
specificCI->CreateWildCard(getter_AddRefs(wildCardProxyCI));
MOZ_ASSERT(NS_SUCCEEDED(rv));
ConnectionEntry* wildCardEnt = mCT.GetWeak(wildCardProxyCI->HashKey());
if (wildCardEnt && wildCardEnt->AvailableForDispatchNow()) {
if (aAvailableForDispatchNow) {
*aAvailableForDispatchNow = true;
}
*aIsWildcard = true;
return wildCardEnt;
}
}
// step 3
if (!specificEnt) {
RefPtr<nsHttpConnectionInfo> clone(specificCI->Clone());
specificEnt = new ConnectionEntry(clone);
mCT.InsertOrUpdate(clone->HashKey(), RefPtr{specificEnt});
}
return specificEnt;
}
void nsHttpConnectionMgr::DoSpeculativeConnection(
SpeculativeTransaction* aTrans, bool aFetchHTTPSRR) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
MOZ_ASSERT(aTrans);
bool isWildcard = false;
ConnectionEntry* ent = GetOrCreateConnectionEntry(
aTrans->ConnectionInfo(), false, aTrans->Caps() & NS_HTTP_DISALLOW_SPDY,
aTrans->Caps() & NS_HTTP_DISALLOW_HTTP3, &isWildcard);
if (!aFetchHTTPSRR &&
gHttpHandler->EchConfigEnabled(aTrans->ConnectionInfo()->IsHttp3())) {
// This happens when this is called from
// SpeculativeTransaction::OnHTTPSRRAvailable. We have to update this
// entry's echConfig so that the newly created connection can use the latest
// echConfig.
ent->MaybeUpdateEchConfig(aTrans->ConnectionInfo());
}
DoSpeculativeConnectionInternal(ent, aTrans, aFetchHTTPSRR);
}
void nsHttpConnectionMgr::DoSpeculativeConnectionInternal(
ConnectionEntry* aEnt, SpeculativeTransaction* aTrans, bool aFetchHTTPSRR) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
MOZ_ASSERT(aTrans);
MOZ_ASSERT(aEnt);
if (!gHttpHandler->Active()) {
// Do nothing if we are shutting down.
return;
}
ProxyDNSStrategy strategy = GetProxyDNSStrategyHelper(
aEnt->mConnInfo->ProxyType(), aEnt->mConnInfo->ProxyFlag());
// Speculative connections can be triggered by non-Necko consumers,
// so add an extra check to ensure HTTPS RR isn't fetched when a proxy is
// used.
if (aFetchHTTPSRR && strategy == ProxyDNSStrategy::ORIGIN &&
NS_SUCCEEDED(aTrans->FetchHTTPSRR())) {
// nsHttpConnectionMgr::DoSpeculativeConnection will be called again
// when HTTPS RR is available.
return;
}
uint32_t parallelSpeculativeConnectLimit =
aTrans->ParallelSpeculativeConnectLimit()
? *aTrans->ParallelSpeculativeConnectLimit()
: gHttpHandler->ParallelSpeculativeConnectLimit();
bool ignoreIdle = aTrans->IgnoreIdle() ? *aTrans->IgnoreIdle() : false;
bool isFromPredictor =
aTrans->IsFromPredictor() ? *aTrans->IsFromPredictor() : false;
bool allow1918 = aTrans->Allow1918() ? *aTrans->Allow1918() : false;
bool keepAlive = aTrans->Caps() & NS_HTTP_ALLOW_KEEPALIVE;
if (mNumDnsAndConnectSockets < parallelSpeculativeConnectLimit &&
((ignoreIdle &&
(aEnt->IdleConnectionsLength() < parallelSpeculativeConnectLimit)) ||
!aEnt->IdleConnectionsLength()) &&
!(keepAlive && aEnt->RestrictConnections()) &&
!AtActiveConnectionLimit(aEnt, aTrans->Caps())) {
nsresult rv = aEnt->CreateDnsAndConnectSocket(aTrans, aTrans->Caps(), true,
isFromPredictor, false,
allow1918, nullptr);
if (NS_FAILED(rv)) {
glean::networking::speculative_connect_outcome
.Get("aborted_socket_fail"_ns)
.Add(1);
LOG(
("DoSpeculativeConnectionInternal Transport socket creation "
"failure: %" PRIx32 "\n",
static_cast<uint32_t>(rv)));
} else {
glean::networking::speculative_connect_outcome.Get("successful"_ns)
.Add(1);
}
} else {
glean::networking::speculative_connect_outcome
.Get("aborted_socket_limit"_ns)
.Add(1);
LOG(
("DoSpeculativeConnectionInternal Transport ci=%s "
"not created due to existing connection count:%d",
aEnt->mConnInfo->HashKey().get(), parallelSpeculativeConnectLimit));
}
}
void nsHttpConnectionMgr::DoFallbackConnection(SpeculativeTransaction* aTrans,
bool aFetchHTTPSRR) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
MOZ_ASSERT(aTrans);
LOG(("nsHttpConnectionMgr::DoFallbackConnection"));
bool availableForDispatchNow = false;
bool aIsWildcard = false;
ConnectionEntry* ent = GetOrCreateConnectionEntry(
aTrans->ConnectionInfo(), false, aTrans->Caps() & NS_HTTP_DISALLOW_SPDY,
aTrans->Caps() & NS_HTTP_DISALLOW_HTTP3, &aIsWildcard,
&availableForDispatchNow);
if (availableForDispatchNow) {
LOG(
("nsHttpConnectionMgr::DoFallbackConnection fallback connection is "
"ready for dispatching ent=%p",
ent));
aTrans->InvokeCallback();
return;
}
DoSpeculativeConnectionInternal(ent, aTrans, aFetchHTTPSRR);
}
void nsHttpConnectionMgr::OnMsgSpeculativeConnect(int32_t, ARefBase* param) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
SpeculativeConnectArgs* args = static_cast<SpeculativeConnectArgs*>(param);
LOG(
("nsHttpConnectionMgr::OnMsgSpeculativeConnect [ci=%s, "
"mFetchHTTPSRR=%d]\n",
args->mTrans->ConnectionInfo()->HashKey().get(), args->mFetchHTTPSRR));
DoSpeculativeConnection(args->mTrans, args->mFetchHTTPSRR);
}
bool nsHttpConnectionMgr::BeConservativeIfProxied(nsIProxyInfo* proxy) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
if (mBeConservativeForProxy) {
// The pref says to be conservative for proxies.
return true;
}
if (!proxy) {
// There is no proxy, so be conservative by default.
return true;
}
// Be conservative only if there is no proxy host set either.
// This logic was copied from nsSSLIOLayerAddToSocket.
nsAutoCString proxyHost;
proxy->GetHost(proxyHost);
return proxyHost.IsEmpty();
}
// register a connection to receive CanJoinConnection() for particular
// origin keys
void nsHttpConnectionMgr::RegisterOriginCoalescingKey(HttpConnectionBase* conn,
const nsACString& host,
int32_t port) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
nsHttpConnectionInfo* ci = conn ? conn->ConnectionInfo() : nullptr;
if (!ci || !conn->CanDirectlyActivate()) {
return;
}
nsCString newKey;
BuildOriginFrameHashKey(newKey, ci, host, port);
mCoalescingHash.GetOrInsertNew(newKey, 1)->AppendElement(
do_GetWeakReference(static_cast<nsISupportsWeakReference*>(conn)));
LOG(
("nsHttpConnectionMgr::RegisterOriginCoalescingKey "
"Established New Coalescing Key %s to %p %s\n",
newKey.get(), conn, ci->HashKey().get()));
}
bool nsHttpConnectionMgr::GetConnectionData(nsTArray<HttpRetParams>* aArg) {
for (const RefPtr<ConnectionEntry>& ent : mCT.Values()) {
if (ent->mConnInfo->GetPrivate()) {
continue;
}
aArg->AppendElement(ent->GetConnectionData());
}
return true;
}
void nsHttpConnectionMgr::ResetIPFamilyPreference(nsHttpConnectionInfo* ci) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
ConnectionEntry* ent = mCT.GetWeak(ci->HashKey());
if (ent) {
ent->ResetIPFamilyPreference();
}
}
void nsHttpConnectionMgr::ExcludeHttp2(const nsHttpConnectionInfo* ci) {
LOG(("nsHttpConnectionMgr::ExcludeHttp2 excluding ci %s",
ci->HashKey().BeginReading()));
ConnectionEntry* ent = mCT.GetWeak(ci->HashKey());
if (!ent) {
LOG(("nsHttpConnectionMgr::ExcludeHttp2 no entry found?!"));
return;
}
ent->DisallowHttp2();
}
void nsHttpConnectionMgr::ExcludeHttp3(const nsHttpConnectionInfo* ci) {
LOG(("nsHttpConnectionMgr::ExcludeHttp3 exclude ci %s",
ci->HashKey().BeginReading()));
ConnectionEntry* ent = mCT.GetWeak(ci->HashKey());
if (!ent) {
LOG(("nsHttpConnectionMgr::ExcludeHttp3 no entry found?!"));
return;
}
ent->DontReuseHttp3Conn();
}
void nsHttpConnectionMgr::MoveToWildCardConnEntry(
nsHttpConnectionInfo* specificCI, nsHttpConnectionInfo* wildCardCI,
HttpConnectionBase* proxyConn) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
MOZ_ASSERT(specificCI->UsingHttpsProxy());
LOG(
("nsHttpConnectionMgr::MakeConnEntryWildCard conn %p has requested to "
"change CI from %s to %s\n",
proxyConn, specificCI->HashKey().get(), wildCardCI->HashKey().get()));
ConnectionEntry* ent = mCT.GetWeak(specificCI->HashKey());
LOG(
("nsHttpConnectionMgr::MakeConnEntryWildCard conn %p using ent %p (spdy "
"%d)\n",
proxyConn, ent, ent ? ent->mUsingSpdy : 0));
if (!ent || !ent->mUsingSpdy) {
return;
}
bool isWildcard = false;
ConnectionEntry* wcEnt =
GetOrCreateConnectionEntry(wildCardCI, true, false, false, &isWildcard);
if (wcEnt == ent) {
// nothing to do!
return;
}
wcEnt->mUsingSpdy = true;
LOG(
("nsHttpConnectionMgr::MakeConnEntryWildCard ent %p "
"idle=%zu active=%zu half=%zu pending=%zu\n",
ent, ent->IdleConnectionsLength(), ent->ActiveConnsLength(),
ent->DnsAndConnectSocketsLength(), ent->PendingQueueLength()));
LOG(
("nsHttpConnectionMgr::MakeConnEntryWildCard wc-ent %p "
"idle=%zu active=%zu half=%zu pending=%zu\n",
wcEnt, wcEnt->IdleConnectionsLength(), wcEnt->ActiveConnsLength(),
wcEnt->DnsAndConnectSocketsLength(), wcEnt->PendingQueueLength()));
ent->MoveConnection(proxyConn, wcEnt);
}
bool nsHttpConnectionMgr::RemoveTransFromConnEntry(nsHttpTransaction* aTrans,
const nsACString& aHashKey) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
LOG(("nsHttpConnectionMgr::RemoveTransFromConnEntry: trans=%p ci=%s", aTrans,
PromiseFlatCString(aHashKey).get()));
if (aHashKey.IsEmpty()) {
return false;
}
// Step 1: Get the transaction's connection entry.
ConnectionEntry* entry = mCT.GetWeak(aHashKey);
if (!entry) {
return false;
}
// Step 2: Try to find the undispatched transaction.
return entry->RemoveTransFromPendingQ(aTrans);
}
void nsHttpConnectionMgr::IncreaseNumDnsAndConnectSockets() {
mNumDnsAndConnectSockets++;
}
void nsHttpConnectionMgr::DecreaseNumDnsAndConnectSockets() {
MOZ_ASSERT(mNumDnsAndConnectSockets);
if (mNumDnsAndConnectSockets) { // just in case
mNumDnsAndConnectSockets--;
}
}
already_AddRefed<PendingTransactionInfo>
nsHttpConnectionMgr::FindTransactionHelper(bool removeWhenFound,
ConnectionEntry* aEnt,
nsAHttpTransaction* aTrans) {
nsTArray<RefPtr<PendingTransactionInfo>>* pendingQ =
aEnt->GetTransactionPendingQHelper(aTrans);
int32_t index =
pendingQ ? pendingQ->IndexOf(aTrans, 0, PendingComparator()) : -1;
RefPtr<PendingTransactionInfo> info;
if (index != -1) {
info = (*pendingQ)[index];
if (removeWhenFound) {
pendingQ->RemoveElementAt(index);
}
}
return info.forget();
}
already_AddRefed<ConnectionEntry> nsHttpConnectionMgr::FindConnectionEntry(
const nsHttpConnectionInfo* ci) {
return mCT.Get(ci->HashKey());
}
nsHttpConnectionMgr* nsHttpConnectionMgr::AsHttpConnectionMgr() { return this; }
HttpConnectionMgrParent* nsHttpConnectionMgr::AsHttpConnectionMgrParent() {
return nullptr;
}
void nsHttpConnectionMgr::NewIdleConnectionAdded(uint32_t timeToLive) {
mNumIdleConns++;
// If the added connection was first idle connection or has shortest
// time to live among the watched connections, pruning dead
// connections needs to be done when it can't be reused anymore.
if (!mTimer || NowInSeconds() + timeToLive < mTimeOfNextWakeUp) {
PruneDeadConnectionsAfter(timeToLive);
}
}
void nsHttpConnectionMgr::DecrementNumIdleConns() {
MOZ_ASSERT(mNumIdleConns);
mNumIdleConns--;
ConditionallyStopPruneDeadConnectionsTimer();
}
// A structure used to marshall objects necessary for ServerCertificateHashaes
class nsStoreServerCertHashesData : public ARefBase {
public:
nsStoreServerCertHashesData(
nsHttpConnectionInfo* aConnInfo, bool aNoSpdy, bool aNoHttp3,
nsTArray<RefPtr<nsIWebTransportHash>>&& aServerCertHashes)
: mConnInfo(aConnInfo),
mNoSpdy(aNoSpdy),
mNoHttp3(aNoHttp3),
mServerCertHashes(std::move(aServerCertHashes)) {}
NS_INLINE_DECL_THREADSAFE_REFCOUNTING(nsStoreServerCertHashesData, override)
RefPtr<nsHttpConnectionInfo> mConnInfo;
bool mNoSpdy;
bool mNoHttp3;
nsTArray<RefPtr<nsIWebTransportHash>> mServerCertHashes;
private:
virtual ~nsStoreServerCertHashesData() = default;
};
// The connection manager needs to know the hashes used for a WebTransport
// connection authenticated with serverCertHashes
nsresult nsHttpConnectionMgr::StoreServerCertHashes(
nsHttpConnectionInfo* aConnInfo, bool aNoSpdy, bool aNoHttp3,
nsTArray<RefPtr<nsIWebTransportHash>>&& aServerCertHashes) {
RefPtr<nsHttpConnectionInfo> ci = aConnInfo->Clone();
RefPtr<nsStoreServerCertHashesData> data = new nsStoreServerCertHashesData(
ci, aNoSpdy, aNoHttp3, std::move(aServerCertHashes));
return PostEvent(&nsHttpConnectionMgr::OnMsgStoreServerCertHashes, 0, data);
}
void nsHttpConnectionMgr::OnMsgStoreServerCertHashes(int32_t, ARefBase* param) {
MOZ_ASSERT(OnSocketThread(), "not on socket thread");
nsStoreServerCertHashesData* data =
static_cast<nsStoreServerCertHashesData*>(param);
bool isWildcard;
ConnectionEntry* connEnt = GetOrCreateConnectionEntry(
data->mConnInfo, true, data->mNoSpdy, data->mNoHttp3, &isWildcard);
MOZ_ASSERT(!isWildcard, "No webtransport with wildcard");
connEnt->SetServerCertHashes(std::move(data->mServerCertHashes));
}
const nsTArray<RefPtr<nsIWebTransportHash>>*
nsHttpConnectionMgr::GetServerCertHashes(nsHttpConnectionInfo* aConnInfo) {
ConnectionEntry* connEnt = mCT.GetWeak(aConnInfo->HashKey());
if (!connEnt) {
MOZ_ASSERT(0);
return nullptr;
}
return &connEnt->GetServerCertHashes();
}
void nsHttpConnectionMgr::CheckTransInPendingQueue(nsHttpTransaction* aTrans) {
#ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED
// We only do this check on socket thread. When this function is called on
// main thread, the transaction is newly created, so we can skip this check.
if (!OnSocketThread()) {
return;
}
nsAutoCString hashKey;
aTrans->GetHashKeyOfConnectionEntry(hashKey);
if (hashKey.IsEmpty()) {
return;
}
bool foundInPendingQ = RemoveTransFromConnEntry(aTrans, hashKey);
MOZ_DIAGNOSTIC_ASSERT(!foundInPendingQ);
#endif
}
bool nsHttpConnectionMgr::AllowToRetryDifferentIPFamilyForHttp3(
nsHttpConnectionInfo* ci, nsresult aError) {
ConnectionEntry* ent = mCT.GetWeak(ci->HashKey());
if (!ent) {
return false;
}
return ent->AllowToRetryDifferentIPFamilyForHttp3(aError);
}
void nsHttpConnectionMgr::SetRetryDifferentIPFamilyForHttp3(
nsHttpConnectionInfo* ci, uint16_t aIPFamily) {
ConnectionEntry* ent = mCT.GetWeak(ci->HashKey());
if (!ent) {
return;
}
ent->SetRetryDifferentIPFamilyForHttp3(aIPFamily);
}
} // namespace mozilla::net