gecko-dev/ipc/mscom/Interceptor.cpp

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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#define INITGUID
#include "mozilla/mscom/Interceptor.h"
#include <utility>
#include "MainThreadUtils.h"
#include "mozilla/Assertions.h"
#include "mozilla/ThreadLocal.h"
#include "mozilla/Unused.h"
#include "mozilla/mscom/DispatchForwarder.h"
#include "mozilla/mscom/FastMarshaler.h"
#include "mozilla/mscom/InterceptorLog.h"
#include "mozilla/mscom/MainThreadInvoker.h"
#include "mozilla/mscom/Objref.h"
#include "mozilla/mscom/Registration.h"
#include "mozilla/mscom/Utils.h"
#include "nsDirectoryServiceDefs.h"
#include "nsDirectoryServiceUtils.h"
#include "nsPrintfCString.h"
#include "nsRefPtrHashtable.h"
#include "nsThreadUtils.h"
#include "nsXULAppAPI.h"
#define ENSURE_HR_SUCCEEDED(hr) \
MOZ_ASSERT(SUCCEEDED((HRESULT)hr)); \
if (FAILED((HRESULT)hr)) { \
return hr; \
}
namespace mozilla {
namespace mscom {
namespace detail {
class MOZ_CAPABILITY("mutex") LiveSet final {
public:
LiveSet() : mMutex("mozilla::mscom::LiveSet::mMutex") {}
void Lock() MOZ_CAPABILITY_ACQUIRE(mMutex) { mMutex.Lock(); }
void Unlock() MOZ_CAPABILITY_RELEASE(mMutex) { mMutex.Unlock(); }
void Put(IUnknown* aKey, already_AddRefed<IWeakReference> aValue) {
mMutex.AssertCurrentThreadOwns();
mLiveSet.InsertOrUpdate(aKey, RefPtr<IWeakReference>{std::move(aValue)});
}
RefPtr<IWeakReference> Get(IUnknown* aKey) {
mMutex.AssertCurrentThreadOwns();
RefPtr<IWeakReference> result;
mLiveSet.Get(aKey, getter_AddRefs(result));
return result;
}
void Remove(IUnknown* aKey) {
mMutex.AssertCurrentThreadOwns();
mLiveSet.Remove(aKey);
}
private:
Mutex mMutex MOZ_UNANNOTATED;
nsRefPtrHashtable<nsPtrHashKey<IUnknown>, IWeakReference> mLiveSet;
};
/**
* We don't use the normal XPCOM BaseAutoLock because we need the ability
* to explicitly Unlock.
*/
class MOZ_RAII MOZ_SCOPED_CAPABILITY LiveSetAutoLock final {
public:
explicit LiveSetAutoLock(LiveSet& aLiveSet) MOZ_CAPABILITY_ACQUIRE(aLiveSet)
: mLiveSet(&aLiveSet) {
aLiveSet.Lock();
}
~LiveSetAutoLock() MOZ_CAPABILITY_RELEASE() {
if (mLiveSet) {
mLiveSet->Unlock();
}
}
void Unlock() MOZ_CAPABILITY_RELEASE() {
MOZ_ASSERT(mLiveSet);
if (mLiveSet) {
mLiveSet->Unlock();
mLiveSet = nullptr;
}
}
LiveSetAutoLock(const LiveSetAutoLock& aOther) = delete;
LiveSetAutoLock(LiveSetAutoLock&& aOther) = delete;
LiveSetAutoLock& operator=(const LiveSetAutoLock& aOther) = delete;
LiveSetAutoLock& operator=(LiveSetAutoLock&& aOther) = delete;
private:
LiveSet* mLiveSet;
};
class MOZ_RAII ReentrySentinel final {
public:
explicit ReentrySentinel(Interceptor* aCurrent) : mCurInterceptor(aCurrent) {
static const bool kHasTls = tlsSentinelStackTop.init();
MOZ_RELEASE_ASSERT(kHasTls);
mPrevSentinel = tlsSentinelStackTop.get();
tlsSentinelStackTop.set(this);
}
~ReentrySentinel() { tlsSentinelStackTop.set(mPrevSentinel); }
bool IsOutermost() const {
return !(mPrevSentinel && mPrevSentinel->IsMarshaling(mCurInterceptor));
}
ReentrySentinel(const ReentrySentinel&) = delete;
ReentrySentinel(ReentrySentinel&&) = delete;
ReentrySentinel& operator=(const ReentrySentinel&) = delete;
ReentrySentinel& operator=(ReentrySentinel&&) = delete;
private:
bool IsMarshaling(Interceptor* aTopInterceptor) const {
return aTopInterceptor == mCurInterceptor ||
(mPrevSentinel && mPrevSentinel->IsMarshaling(aTopInterceptor));
}
private:
Interceptor* mCurInterceptor;
ReentrySentinel* mPrevSentinel;
static MOZ_THREAD_LOCAL(ReentrySentinel*) tlsSentinelStackTop;
};
MOZ_THREAD_LOCAL(ReentrySentinel*) ReentrySentinel::tlsSentinelStackTop;
class MOZ_RAII LoggedQIResult final {
public:
explicit LoggedQIResult(REFIID aIid)
: mIid(aIid),
mHr(E_UNEXPECTED),
mTarget(nullptr),
mInterceptor(nullptr),
mBegin(TimeStamp::Now()) {}
~LoggedQIResult() {
if (!mTarget) {
return;
}
TimeStamp end(TimeStamp::Now());
TimeDuration total(end - mBegin);
TimeDuration overhead(total - mNonOverheadDuration);
InterceptorLog::QI(mHr, mTarget, mIid, mInterceptor, &overhead,
&mNonOverheadDuration);
}
void Log(IUnknown* aTarget, IUnknown* aInterceptor) {
mTarget = aTarget;
mInterceptor = aInterceptor;
}
void operator=(HRESULT aHr) { mHr = aHr; }
operator HRESULT() { return mHr; }
operator TimeDuration*() { return &mNonOverheadDuration; }
LoggedQIResult(const LoggedQIResult&) = delete;
LoggedQIResult(LoggedQIResult&&) = delete;
LoggedQIResult& operator=(const LoggedQIResult&) = delete;
LoggedQIResult& operator=(LoggedQIResult&&) = delete;
private:
REFIID mIid;
HRESULT mHr;
IUnknown* mTarget;
IUnknown* mInterceptor;
TimeDuration mNonOverheadDuration;
TimeStamp mBegin;
};
} // namespace detail
static detail::LiveSet& GetLiveSet() {
static detail::LiveSet sLiveSet;
return sLiveSet;
}
MOZ_THREAD_LOCAL(bool) Interceptor::tlsCreatingStdMarshal;
/* static */
HRESULT Interceptor::Create(STAUniquePtr<IUnknown> aTarget,
IInterceptorSink* aSink, REFIID aInitialIid,
void** aOutInterface) {
MOZ_ASSERT(aOutInterface && aTarget && aSink);
if (!aOutInterface) {
return E_INVALIDARG;
}
detail::LiveSetAutoLock lock(GetLiveSet());
RefPtr<IWeakReference> existingWeak(GetLiveSet().Get(aTarget.get()));
if (existingWeak) {
RefPtr<IWeakReferenceSource> existingStrong;
if (SUCCEEDED(existingWeak->ToStrongRef(getter_AddRefs(existingStrong)))) {
// QI on existingStrong may touch other threads. Since we now hold a
// strong ref on the interceptor, we may now release the lock.
lock.Unlock();
return existingStrong->QueryInterface(aInitialIid, aOutInterface);
}
}
*aOutInterface = nullptr;
if (!aTarget || !aSink) {
return E_INVALIDARG;
}
RefPtr<Interceptor> intcpt(new Interceptor(aSink));
return intcpt->GetInitialInterceptorForIID(lock, aInitialIid,
std::move(aTarget), aOutInterface);
}
Interceptor::Interceptor(IInterceptorSink* aSink)
: WeakReferenceSupport(WeakReferenceSupport::Flags::eDestroyOnMainThread),
mEventSink(aSink),
mInterceptorMapMutex("mozilla::mscom::Interceptor::mInterceptorMapMutex"),
mStdMarshalMutex("mozilla::mscom::Interceptor::mStdMarshalMutex"),
mStdMarshal(nullptr) {
static const bool kHasTls = tlsCreatingStdMarshal.init();
MOZ_ASSERT(kHasTls);
Unused << kHasTls;
MOZ_ASSERT(aSink);
RefPtr<IWeakReference> weakRef;
if (SUCCEEDED(GetWeakReference(getter_AddRefs(weakRef)))) {
aSink->SetInterceptor(weakRef);
}
}
Interceptor::~Interceptor() {
{ // Scope for lock
detail::LiveSetAutoLock lock(GetLiveSet());
GetLiveSet().Remove(mTarget.get());
}
// This needs to run on the main thread because it releases target interface
// reference counts which may not be thread-safe.
MOZ_ASSERT(NS_IsMainThread());
for (uint32_t index = 0, len = mInterceptorMap.Length(); index < len;
++index) {
MapEntry& entry = mInterceptorMap[index];
entry.mInterceptor = nullptr;
entry.mTargetInterface->Release();
}
}
HRESULT
Interceptor::GetClassForHandler(DWORD aDestContext, void* aDestContextPtr,
CLSID* aHandlerClsid) {
if (aDestContextPtr || !aHandlerClsid ||
aDestContext == MSHCTX_DIFFERENTMACHINE) {
return E_INVALIDARG;
}
MOZ_ASSERT(mEventSink);
return mEventSink->GetHandler(WrapNotNull(aHandlerClsid));
}
REFIID
Interceptor::MarshalAs(REFIID aIid) const {
#if defined(MOZ_MSCOM_REMARSHAL_NO_HANDLER)
return IsCallerExternalProcess() ? aIid : mEventSink->MarshalAs(aIid);
#else
return mEventSink->MarshalAs(aIid);
#endif // defined(MOZ_MSCOM_REMARSHAL_NO_HANDLER)
}
HRESULT
Interceptor::GetUnmarshalClass(REFIID riid, void* pv, DWORD dwDestContext,
void* pvDestContext, DWORD mshlflags,
CLSID* pCid) {
return mStdMarshal->GetUnmarshalClass(MarshalAs(riid), pv, dwDestContext,
pvDestContext, mshlflags, pCid);
}
HRESULT
Interceptor::GetMarshalSizeMax(REFIID riid, void* pv, DWORD dwDestContext,
void* pvDestContext, DWORD mshlflags,
DWORD* pSize) {
detail::ReentrySentinel sentinel(this);
HRESULT hr = mStdMarshal->GetMarshalSizeMax(
MarshalAs(riid), pv, dwDestContext, pvDestContext, mshlflags, pSize);
if (FAILED(hr) || !sentinel.IsOutermost()) {
return hr;
}
#if defined(MOZ_MSCOM_REMARSHAL_NO_HANDLER)
if (XRE_IsContentProcess() && IsCallerExternalProcess()) {
// The caller isn't our chrome process, so we do not provide a handler
// payload. Even though we're only getting the size here, calculating the
// payload size might actually require building the payload.
return hr;
}
#endif // defined(MOZ_MSCOM_REMARSHAL_NO_HANDLER)
DWORD payloadSize = 0;
hr = mEventSink->GetHandlerPayloadSize(WrapNotNull(this),
WrapNotNull(&payloadSize));
if (hr == E_NOTIMPL) {
return S_OK;
}
if (SUCCEEDED(hr)) {
*pSize += payloadSize;
}
return hr;
}
HRESULT
Interceptor::MarshalInterface(IStream* pStm, REFIID riid, void* pv,
DWORD dwDestContext, void* pvDestContext,
DWORD mshlflags) {
detail::ReentrySentinel sentinel(this);
HRESULT hr;
#if defined(MOZ_MSCOM_REMARSHAL_NO_HANDLER)
// Save the current stream position
LARGE_INTEGER seekTo;
seekTo.QuadPart = 0;
ULARGE_INTEGER objrefPos;
hr = pStm->Seek(seekTo, STREAM_SEEK_CUR, &objrefPos);
if (FAILED(hr)) {
return hr;
}
#endif // defined(MOZ_MSCOM_REMARSHAL_NO_HANDLER)
hr = mStdMarshal->MarshalInterface(pStm, MarshalAs(riid), pv, dwDestContext,
pvDestContext, mshlflags);
if (FAILED(hr) || !sentinel.IsOutermost()) {
return hr;
}
#if defined(MOZ_MSCOM_REMARSHAL_NO_HANDLER)
if (XRE_IsContentProcess() && IsCallerExternalProcess()) {
// The caller isn't our chrome process, so do not provide a handler.
// First, save the current position that marks the current end of the
// OBJREF in the stream.
ULARGE_INTEGER endPos;
hr = pStm->Seek(seekTo, STREAM_SEEK_CUR, &endPos);
if (FAILED(hr)) {
return hr;
}
// Now strip out the handler.
if (!StripHandlerFromOBJREF(WrapNotNull(pStm), objrefPos.QuadPart,
endPos.QuadPart)) {
return E_FAIL;
}
return S_OK;
}
#endif // defined(MOZ_MSCOM_REMARSHAL_NO_HANDLER)
hr = mEventSink->WriteHandlerPayload(WrapNotNull(this), WrapNotNull(pStm));
if (hr == E_NOTIMPL) {
return S_OK;
}
return hr;
}
HRESULT
Interceptor::UnmarshalInterface(IStream* pStm, REFIID riid, void** ppv) {
return mStdMarshal->UnmarshalInterface(pStm, riid, ppv);
}
HRESULT
Interceptor::ReleaseMarshalData(IStream* pStm) {
return mStdMarshal->ReleaseMarshalData(pStm);
}
HRESULT
Interceptor::DisconnectObject(DWORD dwReserved) {
mEventSink->DisconnectHandlerRemotes();
return mStdMarshal->DisconnectObject(dwReserved);
}
Interceptor::MapEntry* Interceptor::Lookup(REFIID aIid) {
mInterceptorMapMutex.AssertCurrentThreadOwns();
for (uint32_t index = 0, len = mInterceptorMap.Length(); index < len;
++index) {
if (mInterceptorMap[index].mIID == aIid) {
return &mInterceptorMap[index];
}
}
return nullptr;
}
HRESULT
Interceptor::GetTargetForIID(REFIID aIid,
InterceptorTargetPtr<IUnknown>& aTarget) {
MutexAutoLock lock(mInterceptorMapMutex);
MapEntry* entry = Lookup(aIid);
if (entry) {
aTarget.reset(entry->mTargetInterface);
return S_OK;
}
return E_NOINTERFACE;
}
// CoGetInterceptor requires type metadata to be able to generate its emulated
// vtable. If no registered metadata is available, CoGetInterceptor returns
// kFileNotFound.
static const HRESULT kFileNotFound = HRESULT_FROM_WIN32(ERROR_FILE_NOT_FOUND);
HRESULT
Interceptor::CreateInterceptor(REFIID aIid, IUnknown* aOuter,
IUnknown** aOutput) {
// In order to aggregate, we *must* request IID_IUnknown as the initial
// interface for the interceptor, as that IUnknown is non-delegating.
// This is a fundamental rule for creating aggregated objects in COM.
HRESULT hr = ::CoGetInterceptor(aIid, aOuter, IID_IUnknown, (void**)aOutput);
if (hr != kFileNotFound) {
return hr;
}
// In the case that CoGetInterceptor returns kFileNotFound, we can try to
// explicitly load typelib data from our runtime registration facility and
// pass that into CoGetInterceptorFromTypeInfo.
RefPtr<ITypeInfo> typeInfo;
bool found = RegisteredProxy::Find(aIid, getter_AddRefs(typeInfo));
// If this assert fires then we have omitted registering the typelib for a
// required interface. To fix this, review our calls to mscom::RegisterProxy
// and mscom::RegisterTypelib, and add the additional typelib as necessary.
MOZ_ASSERT(found);
if (!found) {
return kFileNotFound;
}
hr = ::CoGetInterceptorFromTypeInfo(aIid, aOuter, typeInfo, IID_IUnknown,
(void**)aOutput);
// If this assert fires then the interceptor doesn't like something about
// the format of the typelib. One thing in particular that it doesn't like
// is complex types that contain unions.
MOZ_ASSERT(SUCCEEDED(hr));
return hr;
}
HRESULT
Interceptor::PublishTarget(detail::LiveSetAutoLock& aLiveSetLock,
RefPtr<IUnknown> aInterceptor, REFIID aTargetIid,
STAUniquePtr<IUnknown> aTarget)
MOZ_NO_THREAD_SAFETY_ANALYSIS {
// Suppress thread safety analysis as this conditionally releases locks.
RefPtr<IWeakReference> weakRef;
HRESULT hr = GetWeakReference(getter_AddRefs(weakRef));
if (FAILED(hr)) {
return hr;
}
// mTarget is a weak reference to aTarget. This is safe because we transfer
// ownership of aTarget into mInterceptorMap which remains live for the
// lifetime of this Interceptor.
mTarget = ToInterceptorTargetPtr(aTarget);
GetLiveSet().Put(mTarget.get(), weakRef.forget());
// Now we transfer aTarget's ownership into mInterceptorMap.
mInterceptorMap.AppendElement(
MapEntry(aTargetIid, aInterceptor, aTarget.release()));
// Release the live set lock because subsequent operations may post work to
// the main thread, creating potential for deadlocks.
aLiveSetLock.Unlock();
return S_OK;
}
HRESULT
Interceptor::GetInitialInterceptorForIID(
detail::LiveSetAutoLock& aLiveSetLock, REFIID aTargetIid,
STAUniquePtr<IUnknown> aTarget,
void** aOutInterceptor) MOZ_NO_THREAD_SAFETY_ANALYSIS {
// Suppress thread safety analysis as this conditionally releases locks.
MOZ_ASSERT(aOutInterceptor);
MOZ_ASSERT(aTargetIid != IID_IMarshal);
MOZ_ASSERT(!IsProxy(aTarget.get()));
HRESULT hr = E_UNEXPECTED;
auto hasFailed = [&hr]() -> bool { return FAILED(hr); };
MOZ_PUSH_IGNORE_THREAD_SAFETY // Avoid the lambda upsetting analysis.
auto cleanup = [&aLiveSetLock]() -> void { aLiveSetLock.Unlock(); };
MOZ_POP_THREAD_SAFETY
ExecuteWhen<decltype(hasFailed), decltype(cleanup)> onFail(hasFailed,
cleanup);
if (aTargetIid == IID_IUnknown) {
// We must lock mInterceptorMapMutex so that nothing can race with us once
// we have been published to the live set.
MutexAutoLock lock(mInterceptorMapMutex);
hr = PublishTarget(aLiveSetLock, nullptr, aTargetIid, std::move(aTarget));
ENSURE_HR_SUCCEEDED(hr);
hr = QueryInterface(aTargetIid, aOutInterceptor);
ENSURE_HR_SUCCEEDED(hr);
return hr;
}
// Raise the refcount for stabilization purposes during aggregation
WeakReferenceSupport::StabilizeRefCount stabilizer(*this);
RefPtr<IUnknown> unkInterceptor;
hr = CreateInterceptor(aTargetIid, static_cast<WeakReferenceSupport*>(this),
getter_AddRefs(unkInterceptor));
ENSURE_HR_SUCCEEDED(hr);
RefPtr<ICallInterceptor> interceptor;
hr = unkInterceptor->QueryInterface(IID_ICallInterceptor,
getter_AddRefs(interceptor));
ENSURE_HR_SUCCEEDED(hr);
hr = interceptor->RegisterSink(mEventSink);
ENSURE_HR_SUCCEEDED(hr);
// We must lock mInterceptorMapMutex so that nothing can race with us once we
// have been published to the live set.
MutexAutoLock lock(mInterceptorMapMutex);
hr = PublishTarget(aLiveSetLock, unkInterceptor, aTargetIid,
std::move(aTarget));
ENSURE_HR_SUCCEEDED(hr);
if (MarshalAs(aTargetIid) == aTargetIid) {
hr = unkInterceptor->QueryInterface(aTargetIid, aOutInterceptor);
ENSURE_HR_SUCCEEDED(hr);
return hr;
}
hr = GetInterceptorForIID(aTargetIid, aOutInterceptor, &lock);
ENSURE_HR_SUCCEEDED(hr);
return hr;
}
HRESULT
Interceptor::GetInterceptorForIID(REFIID aIid, void** aOutInterceptor) {
return GetInterceptorForIID(aIid, aOutInterceptor, nullptr);
}
/**
* This method contains the core guts of the handling of QueryInterface calls
* that are delegated to us from the ICallInterceptor.
*
* @param aIid ID of the desired interface
* @param aOutInterceptor The resulting emulated vtable that corresponds to
* the interface specified by aIid.
* @param aAlreadyLocked Proof of an existing lock on |mInterceptorMapMutex|,
* if present.
*/
HRESULT
Interceptor::GetInterceptorForIID(REFIID aIid, void** aOutInterceptor,
MutexAutoLock* aAlreadyLocked) {
detail::LoggedQIResult result(aIid);
if (!aOutInterceptor) {
return E_INVALIDARG;
}
if (aIid == IID_IUnknown) {
// Special case: When we see IUnknown, we just provide a reference to this
RefPtr<IInterceptor> intcpt(this);
intcpt.forget(aOutInterceptor);
return S_OK;
}
REFIID interceptorIid = MarshalAs(aIid);
RefPtr<IUnknown> unkInterceptor;
IUnknown* interfaceForQILog = nullptr;
// (1) Check to see if we already have an existing interceptor for
// interceptorIid.
auto doLookup = [&]() -> void {
MapEntry* entry = Lookup(interceptorIid);
if (entry) {
unkInterceptor = entry->mInterceptor;
interfaceForQILog = entry->mTargetInterface;
}
};
if (aAlreadyLocked) {
doLookup();
} else {
MutexAutoLock lock(mInterceptorMapMutex);
doLookup();
}
// (1a) A COM interceptor already exists for this interface, so all we need
// to do is run a QI on it.
if (unkInterceptor) {
// Technically we didn't actually execute a QI on the target interface, but
// for logging purposes we would like to record the fact that this interface
// was requested.
result.Log(mTarget.get(), interfaceForQILog);
result = unkInterceptor->QueryInterface(interceptorIid, aOutInterceptor);
ENSURE_HR_SUCCEEDED(result);
return result;
}
// (2) Obtain a new target interface.
// (2a) First, make sure that the target interface is available
// NB: We *MUST* query the correct interface! ICallEvents::Invoke casts its
// pvReceiver argument directly to the required interface! DO NOT assume
// that COM will use QI or upcast/downcast!
HRESULT hr;
STAUniquePtr<IUnknown> targetInterface;
IUnknown* rawTargetInterface = nullptr;
hr =
QueryInterfaceTarget(interceptorIid, (void**)&rawTargetInterface, result);
targetInterface.reset(rawTargetInterface);
result = hr;
result.Log(mTarget.get(), targetInterface.get());
MOZ_ASSERT(SUCCEEDED(hr) || hr == E_NOINTERFACE);
if (hr == E_NOINTERFACE) {
return hr;
}
ENSURE_HR_SUCCEEDED(hr);
// We *really* shouldn't be adding interceptors to proxies
MOZ_ASSERT(aIid != IID_IMarshal);
// (3) Create a new COM interceptor to that interface that delegates its
// IUnknown to |this|.
// Raise the refcount for stabilization purposes during aggregation
WeakReferenceSupport::StabilizeRefCount stabilizer(*this);
hr = CreateInterceptor(interceptorIid,
static_cast<WeakReferenceSupport*>(this),
getter_AddRefs(unkInterceptor));
ENSURE_HR_SUCCEEDED(hr);
// (4) Obtain the interceptor's ICallInterceptor interface and register our
// event sink.
RefPtr<ICallInterceptor> interceptor;
hr = unkInterceptor->QueryInterface(IID_ICallInterceptor,
(void**)getter_AddRefs(interceptor));
ENSURE_HR_SUCCEEDED(hr);
hr = interceptor->RegisterSink(mEventSink);
ENSURE_HR_SUCCEEDED(hr);
// (5) Now that we have this new COM interceptor, insert it into the map.
auto doInsertion = [&]() -> void {
// We might have raced with another thread, so first check that we don't
// already have an entry for this
MapEntry* entry = Lookup(interceptorIid);
if (entry && entry->mInterceptor) {
// Bug 1433046: Because of aggregation, the QI for |interceptor|
// AddRefed |this|, not |unkInterceptor|. Thus, releasing |unkInterceptor|
// will destroy the object. Before we do that, we must first release
// |interceptor|. Otherwise, |interceptor| would be invalidated when
// |unkInterceptor| is destroyed.
interceptor = nullptr;
unkInterceptor = entry->mInterceptor;
} else {
// MapEntry has a RefPtr to unkInterceptor, OTOH we must not touch the
// refcount for the target interface because we are just moving it into
// the map and its refcounting might not be thread-safe.
IUnknown* rawTargetInterface = targetInterface.release();
mInterceptorMap.AppendElement(
MapEntry(interceptorIid, unkInterceptor, rawTargetInterface));
}
};
if (aAlreadyLocked) {
doInsertion();
} else {
MutexAutoLock lock(mInterceptorMapMutex);
doInsertion();
}
hr = unkInterceptor->QueryInterface(interceptorIid, aOutInterceptor);
ENSURE_HR_SUCCEEDED(hr);
return hr;
}
HRESULT
Interceptor::QueryInterfaceTarget(REFIID aIid, void** aOutput,
TimeDuration* aOutDuration) {
// NB: This QI needs to run on the main thread because the target object
// is probably Gecko code that is not thread-safe. Note that this main
// thread invocation is *synchronous*.
if (!NS_IsMainThread() && tlsCreatingStdMarshal.get()) {
mStdMarshalMutex.AssertCurrentThreadOwns();
// COM queries for special interfaces such as IFastRundown when creating a
// marshaler. We don't want these being dispatched to the main thread,
// since this would cause a deadlock on mStdMarshalMutex if the main
// thread is also querying for IMarshal. If we do need to respond to these
// special interfaces, this should be done before this point; e.g. in
// Interceptor::QueryInterface like we do for INoMarshal.
return E_NOINTERFACE;
}
if (mEventSink->IsInterfaceMaybeSupported(aIid) == E_NOINTERFACE) {
return E_NOINTERFACE;
}
MainThreadInvoker invoker;
HRESULT hr;
auto runOnMainThread = [&]() -> void {
MOZ_ASSERT(NS_IsMainThread());
hr = mTarget->QueryInterface(aIid, aOutput);
};
if (!invoker.Invoke(NS_NewRunnableFunction("Interceptor::QueryInterface",
runOnMainThread))) {
return E_FAIL;
}
if (aOutDuration) {
*aOutDuration = invoker.GetDuration();
}
return hr;
}
HRESULT
Interceptor::QueryInterface(REFIID riid, void** ppv) {
if (riid == IID_INoMarshal) {
// This entire library is designed around marshaling, so there's no point
// propagating this QI request all over the place!
return E_NOINTERFACE;
}
return WeakReferenceSupport::QueryInterface(riid, ppv);
}
HRESULT
Interceptor::WeakRefQueryInterface(REFIID aIid, IUnknown** aOutInterface) {
if (aIid == IID_IStdMarshalInfo) {
detail::ReentrySentinel sentinel(this);
if (!sentinel.IsOutermost()) {
return E_NOINTERFACE;
}
// Do not indicate that this interface is available unless we actually
// support it. We'll check that by looking for a successful call to
// IInterceptorSink::GetHandler()
CLSID dummy;
if (FAILED(mEventSink->GetHandler(WrapNotNull(&dummy)))) {
return E_NOINTERFACE;
}
RefPtr<IStdMarshalInfo> std(this);
std.forget(aOutInterface);
return S_OK;
}
if (aIid == IID_IMarshal) {
MutexAutoLock lock(mStdMarshalMutex);
HRESULT hr;
if (!mStdMarshalUnk) {
MOZ_ASSERT(!tlsCreatingStdMarshal.get());
tlsCreatingStdMarshal.set(true);
if (XRE_IsContentProcess()) {
hr = FastMarshaler::Create(static_cast<IWeakReferenceSource*>(this),
getter_AddRefs(mStdMarshalUnk));
} else {
hr = ::CoGetStdMarshalEx(static_cast<IWeakReferenceSource*>(this),
SMEXF_SERVER, getter_AddRefs(mStdMarshalUnk));
}
tlsCreatingStdMarshal.set(false);
ENSURE_HR_SUCCEEDED(hr);
}
if (!mStdMarshal) {
hr = mStdMarshalUnk->QueryInterface(IID_IMarshal, (void**)&mStdMarshal);
ENSURE_HR_SUCCEEDED(hr);
// mStdMarshal is weak, so drop its refcount
mStdMarshal->Release();
}
RefPtr<IMarshal> marshal(this);
marshal.forget(aOutInterface);
return S_OK;
}
if (aIid == IID_IInterceptor) {
RefPtr<IInterceptor> intcpt(this);
intcpt.forget(aOutInterface);
return S_OK;
}
if (aIid == IID_IDispatch) {
STAUniquePtr<IDispatch> disp;
IDispatch* rawDisp = nullptr;
HRESULT hr = QueryInterfaceTarget(aIid, (void**)&rawDisp);
ENSURE_HR_SUCCEEDED(hr);
disp.reset(rawDisp);
return DispatchForwarder::Create(this, disp, aOutInterface);
}
return GetInterceptorForIID(aIid, (void**)aOutInterface, nullptr);
}
ULONG
Interceptor::AddRef() { return WeakReferenceSupport::AddRef(); }
ULONG
Interceptor::Release() { return WeakReferenceSupport::Release(); }
/* static */
HRESULT Interceptor::DisconnectRemotesForTarget(IUnknown* aTarget) {
MOZ_ASSERT(aTarget);
detail::LiveSetAutoLock lock(GetLiveSet());
// It is not an error if the interceptor doesn't exist, so we return
// S_FALSE instead of an error in that case.
RefPtr<IWeakReference> existingWeak(GetLiveSet().Get(aTarget));
if (!existingWeak) {
return S_FALSE;
}
RefPtr<IWeakReferenceSource> existingStrong;
if (FAILED(existingWeak->ToStrongRef(getter_AddRefs(existingStrong)))) {
return S_FALSE;
}
// Since we now hold a strong ref on the interceptor, we may now release the
// lock.
lock.Unlock();
return ::CoDisconnectObject(existingStrong, 0);
}
} // namespace mscom
} // namespace mozilla