/* -*- 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/. */ #ifdef DEBUG # define ENABLE_STRING_STATS #endif #include "mozilla/Atomics.h" #include "mozilla/MemoryReporting.h" #ifdef ENABLE_STRING_STATS # include #endif #include #include "nsAString.h" #include "nsString.h" #include "nsStringBuffer.h" #include "nsDependentString.h" #include "nsMemory.h" #include "prprf.h" #include "nsCOMPtr.h" #include "mozilla/IntegerPrintfMacros.h" #ifdef XP_WIN # include # include # define getpid() _getpid() # define pthread_self() GetCurrentThreadId() #else # include # include #endif using mozilla::Atomic; // --------------------------------------------------------------------------- static const char16_t gNullChar = 0; char* const nsCharTraits::sEmptyBuffer = (char*)const_cast(&gNullChar); char16_t* const nsCharTraits::sEmptyBuffer = const_cast(&gNullChar); // --------------------------------------------------------------------------- #ifdef ENABLE_STRING_STATS class nsStringStats { public: nsStringStats() : mAllocCount(0), mReallocCount(0), mFreeCount(0), mShareCount(0) {} ~nsStringStats() { // this is a hack to suppress duplicate string stats printing // in seamonkey as a result of the string code being linked // into seamonkey and libxpcom! :-( if (!mAllocCount && !mAdoptCount) { return; } // Only print the stats if we detect a leak. if (mAllocCount <= mFreeCount && mAdoptCount <= mAdoptFreeCount) { return; } printf("nsStringStats\n"); printf(" => mAllocCount: % 10d\n", int(mAllocCount)); printf(" => mReallocCount: % 10d\n", int(mReallocCount)); printf(" => mFreeCount: % 10d", int(mFreeCount)); if (mAllocCount > mFreeCount) { printf(" -- LEAKED %d !!!\n", mAllocCount - mFreeCount); } else { printf("\n"); } printf(" => mShareCount: % 10d\n", int(mShareCount)); printf(" => mAdoptCount: % 10d\n", int(mAdoptCount)); printf(" => mAdoptFreeCount: % 10d", int(mAdoptFreeCount)); if (mAdoptCount > mAdoptFreeCount) { printf(" -- LEAKED %d !!!\n", mAdoptCount - mAdoptFreeCount); } else { printf("\n"); } printf(" => Process ID: %" PRIuPTR ", Thread ID: %" PRIuPTR "\n", uintptr_t(getpid()), uintptr_t(pthread_self())); } typedef Atomic AtomicInt; AtomicInt mAllocCount; AtomicInt mReallocCount; AtomicInt mFreeCount; AtomicInt mShareCount; AtomicInt mAdoptCount; AtomicInt mAdoptFreeCount; }; static nsStringStats gStringStats; # define STRING_STAT_INCREMENT(_s) (gStringStats.m##_s##Count)++ #else # define STRING_STAT_INCREMENT(_s) #endif // --------------------------------------------------------------------------- void ReleaseData(void* aData, nsAString::DataFlags aFlags) { if (aFlags & nsAString::DataFlags::REFCOUNTED) { nsStringBuffer::FromData(aData)->Release(); } else if (aFlags & nsAString::DataFlags::OWNED) { free(aData); STRING_STAT_INCREMENT(AdoptFree); // Treat this as destruction of a "StringAdopt" object for leak // tracking purposes. MOZ_LOG_DTOR(aData, "StringAdopt", 1); } // otherwise, nothing to do. } // --------------------------------------------------------------------------- // XXX or we could make nsStringBuffer be a friend of nsTAString class nsAStringAccessor : public nsAString { private: nsAStringAccessor(); // NOT IMPLEMENTED public: char_type* data() const { return mData; } size_type length() const { return mLength; } DataFlags flags() const { return mDataFlags; } void set(char_type* aData, size_type aLen, DataFlags aDataFlags) { ReleaseData(mData, mDataFlags); SetData(aData, aLen, aDataFlags); } }; class nsACStringAccessor : public nsACString { private: nsACStringAccessor(); // NOT IMPLEMENTED public: char_type* data() const { return mData; } size_type length() const { return mLength; } DataFlags flags() const { return mDataFlags; } void set(char_type* aData, size_type aLen, DataFlags aDataFlags) { ReleaseData(mData, mDataFlags); SetData(aData, aLen, aDataFlags); } }; // --------------------------------------------------------------------------- void nsStringBuffer::AddRef() { // Memory synchronization is not required when incrementing a // reference count. The first increment of a reference count on a // thread is not important, since the first use of the object on a // thread can happen before it. What is important is the transfer // of the pointer to that thread, which may happen prior to the // first increment on that thread. The necessary memory // synchronization is done by the mechanism that transfers the // pointer between threads. #ifdef NS_BUILD_REFCNT_LOGGING uint32_t count = #endif mRefCount.fetch_add(1, std::memory_order_relaxed) #ifdef NS_BUILD_REFCNT_LOGGING + 1 #endif ; STRING_STAT_INCREMENT(Share); NS_LOG_ADDREF(this, count, "nsStringBuffer", sizeof(*this)); } void nsStringBuffer::Release() { // Since this may be the last release on this thread, we need // release semantics so that prior writes on this thread are visible // to the thread that destroys the object when it reads mValue with // acquire semantics. uint32_t count = mRefCount.fetch_sub(1, std::memory_order_release) - 1; NS_LOG_RELEASE(this, count, "nsStringBuffer"); if (count == 0) { // We're going to destroy the object on this thread, so we need // acquire semantics to synchronize with the memory released by // the last release on other threads, that is, to ensure that // writes prior to that release are now visible on this thread. count = mRefCount.load(std::memory_order_acquire); STRING_STAT_INCREMENT(Free); free(this); // we were allocated with |malloc| } } /** * Alloc returns a pointer to a new string header with set capacity. */ already_AddRefed nsStringBuffer::Alloc(size_t aSize) { NS_ASSERTION(aSize != 0, "zero capacity allocation not allowed"); NS_ASSERTION(sizeof(nsStringBuffer) + aSize <= size_t(uint32_t(-1)) && sizeof(nsStringBuffer) + aSize > aSize, "mStorageSize will truncate"); nsStringBuffer* hdr = (nsStringBuffer*)malloc(sizeof(nsStringBuffer) + aSize); if (hdr) { STRING_STAT_INCREMENT(Alloc); hdr->mRefCount = 1; hdr->mStorageSize = aSize; NS_LOG_ADDREF(hdr, 1, "nsStringBuffer", sizeof(*hdr)); } return dont_AddRef(hdr); } nsStringBuffer* nsStringBuffer::Realloc(nsStringBuffer* aHdr, size_t aSize) { STRING_STAT_INCREMENT(Realloc); NS_ASSERTION(aSize != 0, "zero capacity allocation not allowed"); NS_ASSERTION(sizeof(nsStringBuffer) + aSize <= size_t(uint32_t(-1)) && sizeof(nsStringBuffer) + aSize > aSize, "mStorageSize will truncate"); // no point in trying to save ourselves if we hit this assertion NS_ASSERTION(!aHdr->IsReadonly(), "|Realloc| attempted on readonly string"); // Treat this as a release and addref for refcounting purposes, since we // just asserted that the refcount is 1. If we don't do that, refcount // logging will claim we've leaked all sorts of stuff. NS_LOG_RELEASE(aHdr, 0, "nsStringBuffer"); aHdr = (nsStringBuffer*)realloc(aHdr, sizeof(nsStringBuffer) + aSize); if (aHdr) { NS_LOG_ADDREF(aHdr, 1, "nsStringBuffer", sizeof(*aHdr)); aHdr->mStorageSize = aSize; } return aHdr; } nsStringBuffer* nsStringBuffer::FromString(const nsAString& aStr) { const nsAStringAccessor* accessor = static_cast(&aStr); if (!(accessor->flags() & nsAString::DataFlags::REFCOUNTED)) { return nullptr; } return FromData(accessor->data()); } nsStringBuffer* nsStringBuffer::FromString(const nsACString& aStr) { const nsACStringAccessor* accessor = static_cast(&aStr); if (!(accessor->flags() & nsACString::DataFlags::REFCOUNTED)) { return nullptr; } return FromData(accessor->data()); } void nsStringBuffer::ToString(uint32_t aLen, nsAString& aStr, bool aMoveOwnership) { char16_t* data = static_cast(Data()); nsAStringAccessor* accessor = static_cast(&aStr); MOZ_DIAGNOSTIC_ASSERT(data[aLen] == char16_t(0), "data should be null terminated"); nsAString::DataFlags flags = nsAString::DataFlags::REFCOUNTED | nsAString::DataFlags::TERMINATED; if (!aMoveOwnership) { AddRef(); } accessor->set(data, aLen, flags); } void nsStringBuffer::ToString(uint32_t aLen, nsACString& aStr, bool aMoveOwnership) { char* data = static_cast(Data()); nsACStringAccessor* accessor = static_cast(&aStr); MOZ_DIAGNOSTIC_ASSERT(data[aLen] == char(0), "data should be null terminated"); nsACString::DataFlags flags = nsACString::DataFlags::REFCOUNTED | nsACString::DataFlags::TERMINATED; if (!aMoveOwnership) { AddRef(); } accessor->set(data, aLen, flags); } size_t nsStringBuffer::SizeOfIncludingThisIfUnshared( mozilla::MallocSizeOf aMallocSizeOf) const { return IsReadonly() ? 0 : aMallocSizeOf(this); } size_t nsStringBuffer::SizeOfIncludingThisEvenIfShared( mozilla::MallocSizeOf aMallocSizeOf) const { return aMallocSizeOf(this); } // --------------------------------------------------------------------------- // define nsAString #include "nsTSubstring.cpp" // Provide rust bindings to the nsA[C]String types extern "C" { // This is a no-op on release, so we ifdef it out such that using it in release // results in a linker error. #ifdef DEBUG void Gecko_IncrementStringAdoptCount(void* aData) { MOZ_LOG_CTOR(aData, "StringAdopt", 1); } #elif defined(MOZ_DEBUG_RUST) void Gecko_IncrementStringAdoptCount(void* aData) {} #endif void Gecko_FinalizeCString(nsACString* aThis) { aThis->~nsACString(); } void Gecko_AssignCString(nsACString* aThis, const nsACString* aOther) { aThis->Assign(*aOther); } void Gecko_TakeFromCString(nsACString* aThis, nsACString* aOther) { aThis->Assign(std::move(*aOther)); } void Gecko_AppendCString(nsACString* aThis, const nsACString* aOther) { aThis->Append(*aOther); } void Gecko_SetLengthCString(nsACString* aThis, uint32_t aLength) { aThis->SetLength(aLength); } bool Gecko_FallibleAssignCString(nsACString* aThis, const nsACString* aOther) { return aThis->Assign(*aOther, mozilla::fallible); } bool Gecko_FallibleTakeFromCString(nsACString* aThis, nsACString* aOther) { return aThis->Assign(std::move(*aOther), mozilla::fallible); } bool Gecko_FallibleAppendCString(nsACString* aThis, const nsACString* aOther) { return aThis->Append(*aOther, mozilla::fallible); } bool Gecko_FallibleSetLengthCString(nsACString* aThis, uint32_t aLength) { return aThis->SetLength(aLength, mozilla::fallible); } char* Gecko_BeginWritingCString(nsACString* aThis) { return aThis->BeginWriting(); } char* Gecko_FallibleBeginWritingCString(nsACString* aThis) { return aThis->BeginWriting(mozilla::fallible); } uint32_t Gecko_StartBulkWriteCString(nsACString* aThis, uint32_t aCapacity, uint32_t aUnitsToPreserve, bool aAllowShrinking) { return aThis->StartBulkWriteImpl(aCapacity, aUnitsToPreserve, aAllowShrinking) .unwrapOr(UINT32_MAX); } void Gecko_FinalizeString(nsAString* aThis) { aThis->~nsAString(); } void Gecko_AssignString(nsAString* aThis, const nsAString* aOther) { aThis->Assign(*aOther); } void Gecko_TakeFromString(nsAString* aThis, nsAString* aOther) { aThis->Assign(std::move(*aOther)); } void Gecko_AppendString(nsAString* aThis, const nsAString* aOther) { aThis->Append(*aOther); } void Gecko_SetLengthString(nsAString* aThis, uint32_t aLength) { aThis->SetLength(aLength); } bool Gecko_FallibleAssignString(nsAString* aThis, const nsAString* aOther) { return aThis->Assign(*aOther, mozilla::fallible); } bool Gecko_FallibleTakeFromString(nsAString* aThis, nsAString* aOther) { return aThis->Assign(std::move(*aOther), mozilla::fallible); } bool Gecko_FallibleAppendString(nsAString* aThis, const nsAString* aOther) { return aThis->Append(*aOther, mozilla::fallible); } bool Gecko_FallibleSetLengthString(nsAString* aThis, uint32_t aLength) { return aThis->SetLength(aLength, mozilla::fallible); } char16_t* Gecko_BeginWritingString(nsAString* aThis) { return aThis->BeginWriting(); } char16_t* Gecko_FallibleBeginWritingString(nsAString* aThis) { return aThis->BeginWriting(mozilla::fallible); } uint32_t Gecko_StartBulkWriteString(nsAString* aThis, uint32_t aCapacity, uint32_t aUnitsToPreserve, bool aAllowShrinking) { return aThis->StartBulkWriteImpl(aCapacity, aUnitsToPreserve, aAllowShrinking) .unwrapOr(UINT32_MAX); } } // extern "C"