gecko-dev/xpcom/build/IOInterposer.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/. */
#include <algorithm>
#include <vector>
#include "IOInterposer.h"
#include "IOInterposerPrivate.h"
#include "MainThreadIOLogger.h"
#include "mozilla/Atomics.h"
#include "mozilla/Mutex.h"
#include "mozilla/RefPtr.h"
#include "mozilla/StaticPtr.h"
#include "mozilla/ThreadLocal.h"
#include "nscore.h" // for NS_FREE_PERMANENT_DATA
#if !defined(XP_WIN)
#include "NSPRInterposer.h"
#endif // !defined(XP_WIN)
#include "nsXULAppAPI.h"
#include "PoisonIOInterposer.h"
using namespace mozilla;
namespace {
/** Find if a vector contains a specific element */
template<class T>
bool
VectorContains(const std::vector<T>& aVector, const T& aElement)
{
return std::find(aVector.begin(), aVector.end(), aElement) != aVector.end();
}
/** Remove element from a vector */
template<class T>
void
VectorRemove(std::vector<T>& aVector, const T& aElement)
{
typename std::vector<T>::iterator newEnd =
std::remove(aVector.begin(), aVector.end(), aElement);
aVector.erase(newEnd, aVector.end());
}
/** Lists of Observers */
struct ObserverLists
{
private:
~ObserverLists() {}
public:
NS_INLINE_DECL_THREADSAFE_REFCOUNTING(ObserverLists)
ObserverLists() {}
ObserverLists(ObserverLists const& aOther)
: mCreateObservers(aOther.mCreateObservers)
, mReadObservers(aOther.mReadObservers)
, mWriteObservers(aOther.mWriteObservers)
, mFSyncObservers(aOther.mFSyncObservers)
, mStatObservers(aOther.mStatObservers)
, mCloseObservers(aOther.mCloseObservers)
, mStageObservers(aOther.mStageObservers)
{
}
// Lists of observers for I/O events.
// These are implemented as vectors since they are allowed to survive gecko,
// without reporting leaks. This is necessary for the IOInterposer to be used
// for late-write checks.
std::vector<IOInterposeObserver*> mCreateObservers;
std::vector<IOInterposeObserver*> mReadObservers;
std::vector<IOInterposeObserver*> mWriteObservers;
std::vector<IOInterposeObserver*> mFSyncObservers;
std::vector<IOInterposeObserver*> mStatObservers;
std::vector<IOInterposeObserver*> mCloseObservers;
std::vector<IOInterposeObserver*> mStageObservers;
};
class PerThreadData
{
public:
explicit PerThreadData(bool aIsMainThread = false)
: mIsMainThread(aIsMainThread)
, mIsHandlingObservation(false)
, mCurrentGeneration(0)
{
MOZ_COUNT_CTOR(PerThreadData);
}
~PerThreadData()
{
MOZ_COUNT_DTOR(PerThreadData);
}
void CallObservers(IOInterposeObserver::Observation& aObservation)
{
// Prevent recursive reporting.
if (mIsHandlingObservation) {
return;
}
mIsHandlingObservation = true;
// Decide which list of observers to inform
std::vector<IOInterposeObserver*>* observers = nullptr;
switch (aObservation.ObservedOperation()) {
case IOInterposeObserver::OpCreateOrOpen:
observers = &mObserverLists->mCreateObservers;
break;
case IOInterposeObserver::OpRead:
observers = &mObserverLists->mReadObservers;
break;
case IOInterposeObserver::OpWrite:
observers = &mObserverLists->mWriteObservers;
break;
case IOInterposeObserver::OpFSync:
observers = &mObserverLists->mFSyncObservers;
break;
case IOInterposeObserver::OpStat:
observers = &mObserverLists->mStatObservers;
break;
case IOInterposeObserver::OpClose:
observers = &mObserverLists->mCloseObservers;
break;
case IOInterposeObserver::OpNextStage:
observers = &mObserverLists->mStageObservers;
break;
default: {
// Invalid IO operation, see documentation comment for
// IOInterposer::Report()
MOZ_ASSERT(false);
// Just ignore it in non-debug builds.
return;
}
}
MOZ_ASSERT(observers);
// Inform observers
for (auto i = observers->begin(), e = observers->end(); i != e; ++i) {
(*i)->Observe(aObservation);
}
mIsHandlingObservation = false;
}
inline uint32_t GetCurrentGeneration() const { return mCurrentGeneration; }
inline bool IsMainThread() const { return mIsMainThread; }
inline void SetObserverLists(uint32_t aNewGeneration,
RefPtr<ObserverLists>& aNewLists)
{
mCurrentGeneration = aNewGeneration;
mObserverLists = aNewLists;
}
inline void ClearObserverLists()
{
if (mObserverLists) {
mCurrentGeneration = 0;
mObserverLists = nullptr;
}
}
private:
bool mIsMainThread;
bool mIsHandlingObservation;
uint32_t mCurrentGeneration;
RefPtr<ObserverLists> mObserverLists;
};
class MasterList
{
public:
MasterList()
: mObservedOperations(IOInterposeObserver::OpNone)
, mIsEnabled(true)
{
MOZ_COUNT_CTOR(MasterList);
}
~MasterList()
{
MOZ_COUNT_DTOR(MasterList);
}
inline void Disable() { mIsEnabled = false; }
void Register(IOInterposeObserver::Operation aOp,
IOInterposeObserver* aObserver)
{
IOInterposer::AutoLock lock(mLock);
ObserverLists* newLists = nullptr;
if (mObserverLists) {
newLists = new ObserverLists(*mObserverLists);
} else {
newLists = new ObserverLists();
}
// You can register to observe multiple types of observations
// but you'll never be registered twice for the same observations.
if (aOp & IOInterposeObserver::OpCreateOrOpen &&
!VectorContains(newLists->mCreateObservers, aObserver)) {
newLists->mCreateObservers.push_back(aObserver);
}
if (aOp & IOInterposeObserver::OpRead &&
!VectorContains(newLists->mReadObservers, aObserver)) {
newLists->mReadObservers.push_back(aObserver);
}
if (aOp & IOInterposeObserver::OpWrite &&
!VectorContains(newLists->mWriteObservers, aObserver)) {
newLists->mWriteObservers.push_back(aObserver);
}
if (aOp & IOInterposeObserver::OpFSync &&
!VectorContains(newLists->mFSyncObservers, aObserver)) {
newLists->mFSyncObservers.push_back(aObserver);
}
if (aOp & IOInterposeObserver::OpStat &&
!VectorContains(newLists->mStatObservers, aObserver)) {
newLists->mStatObservers.push_back(aObserver);
}
if (aOp & IOInterposeObserver::OpClose &&
!VectorContains(newLists->mCloseObservers, aObserver)) {
newLists->mCloseObservers.push_back(aObserver);
}
if (aOp & IOInterposeObserver::OpNextStage &&
!VectorContains(newLists->mStageObservers, aObserver)) {
newLists->mStageObservers.push_back(aObserver);
}
mObserverLists = newLists;
mObservedOperations =
(IOInterposeObserver::Operation)(mObservedOperations | aOp);
mCurrentGeneration++;
}
void Unregister(IOInterposeObserver::Operation aOp,
IOInterposeObserver* aObserver)
{
IOInterposer::AutoLock lock(mLock);
ObserverLists* newLists = nullptr;
if (mObserverLists) {
newLists = new ObserverLists(*mObserverLists);
} else {
newLists = new ObserverLists();
}
if (aOp & IOInterposeObserver::OpCreateOrOpen) {
VectorRemove(newLists->mCreateObservers, aObserver);
if (newLists->mCreateObservers.empty()) {
mObservedOperations =
(IOInterposeObserver::Operation)(mObservedOperations &
~IOInterposeObserver::OpCreateOrOpen);
}
}
if (aOp & IOInterposeObserver::OpRead) {
VectorRemove(newLists->mReadObservers, aObserver);
if (newLists->mReadObservers.empty()) {
mObservedOperations =
(IOInterposeObserver::Operation)(mObservedOperations &
~IOInterposeObserver::OpRead);
}
}
if (aOp & IOInterposeObserver::OpWrite) {
VectorRemove(newLists->mWriteObservers, aObserver);
if (newLists->mWriteObservers.empty()) {
mObservedOperations =
(IOInterposeObserver::Operation)(mObservedOperations &
~IOInterposeObserver::OpWrite);
}
}
if (aOp & IOInterposeObserver::OpFSync) {
VectorRemove(newLists->mFSyncObservers, aObserver);
if (newLists->mFSyncObservers.empty()) {
mObservedOperations =
(IOInterposeObserver::Operation)(mObservedOperations &
~IOInterposeObserver::OpFSync);
}
}
if (aOp & IOInterposeObserver::OpStat) {
VectorRemove(newLists->mStatObservers, aObserver);
if (newLists->mStatObservers.empty()) {
mObservedOperations =
(IOInterposeObserver::Operation)(mObservedOperations &
~IOInterposeObserver::OpStat);
}
}
if (aOp & IOInterposeObserver::OpClose) {
VectorRemove(newLists->mCloseObservers, aObserver);
if (newLists->mCloseObservers.empty()) {
mObservedOperations =
(IOInterposeObserver::Operation)(mObservedOperations &
~IOInterposeObserver::OpClose);
}
}
if (aOp & IOInterposeObserver::OpNextStage) {
VectorRemove(newLists->mStageObservers, aObserver);
if (newLists->mStageObservers.empty()) {
mObservedOperations =
(IOInterposeObserver::Operation)(mObservedOperations &
~IOInterposeObserver::OpNextStage);
}
}
mObserverLists = newLists;
mCurrentGeneration++;
}
void Update(PerThreadData& aPtd)
{
if (mCurrentGeneration == aPtd.GetCurrentGeneration()) {
return;
}
// If the generation counts don't match then we need to update the current
// thread's observer list with the new master list.
IOInterposer::AutoLock lock(mLock);
aPtd.SetObserverLists(mCurrentGeneration, mObserverLists);
}
inline bool IsObservedOperation(IOInterposeObserver::Operation aOp)
{
// The quick reader may observe that no locks are being employed here,
// hence the result of the operations is truly undefined. However, most
// computers will usually return either true or false, which is good enough.
// It is not a problem if we occasionally report more or less IO than is
// actually occurring.
return mIsEnabled && !!(mObservedOperations & aOp);
}
private:
RefPtr<ObserverLists> mObserverLists;
// Note, we cannot use mozilla::Mutex here as the ObserverLists may be leaked
// (We want to monitor IO during shutdown). Furthermore, as we may have to
// unregister observers during shutdown an OffTheBooksMutex is not an option
// either, as its base calls into sDeadlockDetector which may be nullptr
// during shutdown.
IOInterposer::Mutex mLock;
// Flags tracking which operations are being observed
IOInterposeObserver::Operation mObservedOperations;
// Used for quickly disabling everything by IOInterposer::Disable()
Atomic<bool> mIsEnabled;
// Used to inform threads that the master observer list has changed
Atomic<uint32_t> mCurrentGeneration;
};
// Special observation used by IOInterposer::EnteringNextStage()
class NextStageObservation : public IOInterposeObserver::Observation
{
public:
NextStageObservation()
: IOInterposeObserver::Observation(IOInterposeObserver::OpNextStage,
"IOInterposer", false)
{
mStart = TimeStamp::Now();
mEnd = mStart;
}
};
// List of observers registered
static StaticAutoPtr<MasterList> sMasterList;
static ThreadLocal<PerThreadData*> sThreadLocalData;
} // namespace
IOInterposeObserver::Observation::Observation(Operation aOperation,
const char* aReference,
bool aShouldReport)
: mOperation(aOperation)
, mReference(aReference)
, mShouldReport(IOInterposer::IsObservedOperation(aOperation) &&
aShouldReport)
{
if (mShouldReport) {
mStart = TimeStamp::Now();
}
}
IOInterposeObserver::Observation::Observation(Operation aOperation,
const TimeStamp& aStart,
const TimeStamp& aEnd,
const char* aReference)
: mOperation(aOperation)
, mStart(aStart)
, mEnd(aEnd)
, mReference(aReference)
, mShouldReport(false)
{
}
const char*
IOInterposeObserver::Observation::ObservedOperationString() const
{
switch (mOperation) {
case OpCreateOrOpen:
return "create/open";
case OpRead:
return "read";
case OpWrite:
return "write";
case OpFSync:
return "fsync";
case OpStat:
return "stat";
case OpClose:
return "close";
case OpNextStage:
return "NextStage";
default:
return "unknown";
}
}
void
IOInterposeObserver::Observation::Report()
{
if (mShouldReport) {
mEnd = TimeStamp::Now();
IOInterposer::Report(*this);
}
}
bool
IOInterposer::Init()
{
// Don't initialize twice...
if (sMasterList) {
return true;
}
if (!sThreadLocalData.init()) {
return false;
}
bool isMainThread = true;
RegisterCurrentThread(isMainThread);
sMasterList = new MasterList();
MainThreadIOLogger::Init();
// Now we initialize the various interposers depending on platform
InitPoisonIOInterposer();
// We don't hook NSPR on Windows because PoisonIOInterposer captures a
// superset of the former's events.
#if !defined(XP_WIN)
InitNSPRIOInterposing();
#endif
return true;
}
bool
IOInterposeObserver::IsMainThread()
{
if (!sThreadLocalData.initialized()) {
return false;
}
PerThreadData* ptd = sThreadLocalData.get();
if (!ptd) {
return false;
}
return ptd->IsMainThread();
}
void
IOInterposer::Clear()
{
/* Clear() is a no-op on release builds so that we may continue to trap I/O
until process termination. In leak-checking builds, we need to shut down
IOInterposer so that all references are properly released. */
#ifdef NS_FREE_PERMANENT_DATA
UnregisterCurrentThread();
sMasterList = nullptr;
#endif
}
void
IOInterposer::Disable()
{
if (!sMasterList) {
return;
}
sMasterList->Disable();
}
void
IOInterposer::Report(IOInterposeObserver::Observation& aObservation)
{
PerThreadData* ptd = sThreadLocalData.get();
if (!ptd) {
// In this case the current thread is not registered with IOInterposer.
// Alternatively we could take the slow path and just lock everything if
// we're not registered. That could potentially perform poorly, though.
return;
}
if (!sMasterList) {
// If there is no longer a master list then we should clear the local one.
ptd->ClearObserverLists();
return;
}
sMasterList->Update(*ptd);
// Don't try to report if there's nobody listening.
if (!IOInterposer::IsObservedOperation(aObservation.ObservedOperation())) {
return;
}
ptd->CallObservers(aObservation);
}
bool
IOInterposer::IsObservedOperation(IOInterposeObserver::Operation aOp)
{
return sMasterList && sMasterList->IsObservedOperation(aOp);
}
void
IOInterposer::Register(IOInterposeObserver::Operation aOp,
IOInterposeObserver* aObserver)
{
MOZ_ASSERT(aObserver);
if (!sMasterList || !aObserver) {
return;
}
sMasterList->Register(aOp, aObserver);
}
void
IOInterposer::Unregister(IOInterposeObserver::Operation aOp,
IOInterposeObserver* aObserver)
{
if (!sMasterList) {
return;
}
sMasterList->Unregister(aOp, aObserver);
}
void
IOInterposer::RegisterCurrentThread(bool aIsMainThread)
{
if (!sThreadLocalData.initialized()) {
return;
}
MOZ_ASSERT(!sThreadLocalData.get());
PerThreadData* curThreadData = new PerThreadData(aIsMainThread);
sThreadLocalData.set(curThreadData);
}
void
IOInterposer::UnregisterCurrentThread()
{
if (!sThreadLocalData.initialized()) {
return;
}
PerThreadData* curThreadData = sThreadLocalData.get();
MOZ_ASSERT(curThreadData);
sThreadLocalData.set(nullptr);
delete curThreadData;
}
void
IOInterposer::EnteringNextStage()
{
if (!sMasterList) {
return;
}
NextStageObservation observation;
Report(observation);
}