/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* 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/. */ #ifndef nsCOMPtr_h___ #define nsCOMPtr_h___ /* Having problems? See the User Manual at: http://www.mozilla.org/projects/xpcom/nsCOMPtr.html nsCOMPtr better than a raw pointer for owning objects -- scc */ #include "mozilla/Attributes.h" #include "mozilla/TypeTraits.h" #include "mozilla/Assertions.h" #include "mozilla/NullPtr.h" #include "mozilla/Move.h" // Wrapping includes can speed up compiles (see "Large Scale C++ Software Design") #ifndef nsDebug_h___ #include "nsDebug.h" // for |NS_ABORT_IF_FALSE|, |NS_ASSERTION| #endif #ifndef nsISupportsUtils_h__ #include "nsISupportsUtils.h" // for |nsresult|, |NS_ADDREF|, |NS_GET_TEMPLATE_IID| et al #endif #ifndef nscore_h___ #include "nscore.h" // for |NS_COM_GLUE| #endif #include "nsCycleCollectionNoteChild.h" /* WARNING: This file defines several macros for internal use only. These macros begin with the prefix |NSCAP_|. Do not use these macros in your own code. They are for internal use only for cross-platform compatibility, and are subject to change without notice. */ #ifdef _MSC_VER #define NSCAP_FEATURE_INLINE_STARTASSIGNMENT // under VC++, we win by inlining StartAssignment // Also under VC++, at the highest warning level, we are overwhelmed with warnings // about (unused) inline functions being removed. This is to be expected with // templates, so we disable the warning. #pragma warning( disable: 4514 ) #endif #define NSCAP_FEATURE_USE_BASE #ifdef DEBUG #define NSCAP_FEATURE_TEST_DONTQUERY_CASES #undef NSCAP_FEATURE_USE_BASE //#define NSCAP_FEATURE_TEST_NONNULL_QUERY_SUCCEEDS #endif #ifdef __GNUC__ // Our use of nsCOMPtr_base::mRawPtr violates the C++ standard's aliasing // rules. Mark it with the may_alias attribute so that gcc 3.3 and higher // don't reorder instructions based on aliasing assumptions for // this variable. Fortunately, gcc versions < 3.3 do not do any // optimizations that break nsCOMPtr. #define NS_MAY_ALIAS_PTR(t) t* __attribute__((__may_alias__)) #else #define NS_MAY_ALIAS_PTR(t) t* #endif #if defined(NSCAP_DISABLE_DEBUG_PTR_TYPES) #define NSCAP_FEATURE_USE_BASE #endif /* The following three macros (|NSCAP_ADDREF|, |NSCAP_RELEASE|, and |NSCAP_LOG_ASSIGNMENT|) allow external clients the ability to add logging or other interesting debug facilities. In fact, if you want |nsCOMPtr| to participate in the standard logging facility, you provide (e.g., in "nsISupportsImpl.h") suitable definitions #define NSCAP_ADDREF(this, ptr) NS_ADDREF(ptr) #define NSCAP_RELEASE(this, ptr) NS_RELEASE(ptr) */ #ifndef NSCAP_ADDREF #define NSCAP_ADDREF(this, ptr) (ptr)->AddRef() #endif #ifndef NSCAP_RELEASE #define NSCAP_RELEASE(this, ptr) (ptr)->Release() #endif // Clients can define |NSCAP_LOG_ASSIGNMENT| to perform logging. #ifdef NSCAP_LOG_ASSIGNMENT // Remember that |NSCAP_LOG_ASSIGNMENT| was defined by some client so that we know // to instantiate |~nsGetterAddRefs| in turn to note the external assignment into // the |nsCOMPtr|. #define NSCAP_LOG_EXTERNAL_ASSIGNMENT #else // ...otherwise, just strip it out of the code #define NSCAP_LOG_ASSIGNMENT(this, ptr) #endif #ifndef NSCAP_LOG_RELEASE #define NSCAP_LOG_RELEASE(this, ptr) #endif namespace mozilla { struct unused_t; } // namespace mozilla template struct already_AddRefed /* ...cooperates with |nsCOMPtr| to allow you to assign in a pointer _without_ |AddRef|ing it. You might want to use this as a return type from a function that produces an already |AddRef|ed pointer as a result. See also |getter_AddRefs()|, |dont_AddRef()|, and |class nsGetterAddRefs|. This type should be a nested class inside |nsCOMPtr|. Yes, |already_AddRefed| could have been implemented as an |nsCOMPtr_helper| to avoid adding specialized machinery to |nsCOMPtr| ... but this is the simplest case, and perhaps worth the savings in time and space that its specific implementation affords over the more general solution offered by |nsCOMPtr_helper|. */ { /* * Prohibit all one-argument overloads but already_AddRefed(T*) and * already_AddRefed(decltype(nullptr)), and funnel the nullptr case through * the T* constructor. */ template already_AddRefed(N, typename mozilla::EnableIf::value, int>::Type dummy = 0) : mRawPtr(nullptr) { // nothing else to do here } already_AddRefed( T* aRawPtr ) : mRawPtr(aRawPtr) { // nothing else to do here } // Disallowed. Use move semantics instead. already_AddRefed(const already_AddRefed& aOther) MOZ_DELETE; already_AddRefed(already_AddRefed&& aOther) : mRawPtr(aOther.take()) { // nothing else to do here } ~already_AddRefed() { MOZ_ASSERT(!mRawPtr); } // Specialize the unused operator<< for already_AddRefed, to allow // nsCOMPtr foo; // unused << foo.forget(); friend void operator<<(const mozilla::unused_t& unused, const already_AddRefed& rhs) { auto mutableAlreadyAddRefed = const_cast*>(&rhs); unused << mutableAlreadyAddRefed->take(); } MOZ_WARN_UNUSED_RESULT T* take() { T* rawPtr = mRawPtr; mRawPtr = nullptr; return rawPtr; } /** * This helper is useful in cases like * * already_AddRefed * Foo() * { * nsRefPtr x = ...; * return x.forget(); * } * * The autoconversion allows one to omit the idiom * * nsRefPtr y = x.forget(); * return y.forget(); */ template operator already_AddRefed() { U* tmp = mRawPtr; mRawPtr = nullptr; return already_AddRefed(tmp); } /** * This helper provides a static_cast replacement for already_AddRefed, so * if you have * * already_AddRefed F(); * * you can write * * already_AddRefed * G() * { * return F().downcast(); * } * * instead of * * return dont_AddRef(static_cast(F().get())); */ template already_AddRefed downcast() { U* tmp = static_cast(mRawPtr); mRawPtr = nullptr; return already_AddRefed(tmp); } private: T* mRawPtr; }; template inline already_AddRefed dont_AddRef( T* aRawPtr ) { return already_AddRefed(aRawPtr); } template inline already_AddRefed&& dont_AddRef( already_AddRefed&& aAlreadyAddRefedPtr ) { return mozilla::Move(aAlreadyAddRefedPtr); } class nsCOMPtr_helper /* An |nsCOMPtr_helper| transforms commonly called getters into typesafe forms that are more convenient to call, and more efficient to use with |nsCOMPtr|s. Good candidates for helpers are |QueryInterface()|, |CreateInstance()|, etc. Here are the rules for a helper: - it implements |operator()| to produce an interface pointer - (except for its name) |operator()| is a valid [XP]COM `getter' - the interface pointer that it returns is already |AddRef()|ed (as from any good getter) - it matches the type requested with the supplied |nsIID| argument - its constructor provides an optional |nsresult*| that |operator()| can fill in with an error when it is executed See |class nsGetInterface| for an example. */ { public: virtual nsresult NS_FASTCALL operator()( const nsIID&, void** ) const = 0; }; /* |nsQueryInterface| could have been implemented as an |nsCOMPtr_helper| to avoid adding specialized machinery in |nsCOMPtr|, But |do_QueryInterface| is called often enough that the codesize savings are big enough to warrant the specialcasing. */ class NS_COM_GLUE MOZ_STACK_CLASS nsQueryInterface MOZ_FINAL { public: explicit nsQueryInterface( nsISupports* aRawPtr ) : mRawPtr(aRawPtr) { // nothing else to do here } nsresult NS_FASTCALL operator()( const nsIID& aIID, void** ) const; private: nsISupports* mRawPtr; }; class NS_COM_GLUE nsQueryInterfaceWithError { public: nsQueryInterfaceWithError( nsISupports* aRawPtr, nsresult* error ) : mRawPtr(aRawPtr), mErrorPtr(error) { // nothing else to do here } nsresult NS_FASTCALL operator()( const nsIID& aIID, void** ) const; private: nsISupports* mRawPtr; nsresult* mErrorPtr; }; inline nsQueryInterface do_QueryInterface( nsISupports* aRawPtr ) { return nsQueryInterface(aRawPtr); } inline nsQueryInterfaceWithError do_QueryInterface( nsISupports* aRawPtr, nsresult* error ) { return nsQueryInterfaceWithError(aRawPtr, error); } template inline void do_QueryInterface( already_AddRefed& ) { // This signature exists solely to _stop_ you from doing the bad thing. // Saying |do_QueryInterface()| on a pointer that is not otherwise owned by // someone else is an automatic leak. See . } template inline void do_QueryInterface( already_AddRefed&, nsresult* ) { // This signature exists solely to _stop_ you from doing the bad thing. // Saying |do_QueryInterface()| on a pointer that is not otherwise owned by // someone else is an automatic leak. See . } //////////////////////////////////////////////////////////////////////////// // Using servicemanager with COMPtrs class NS_COM_GLUE nsGetServiceByCID { public: explicit nsGetServiceByCID(const nsCID& aCID) : mCID(aCID) { // nothing else to do } nsresult NS_FASTCALL operator()( const nsIID&, void** ) const; private: const nsCID& mCID; }; class NS_COM_GLUE nsGetServiceByCIDWithError { public: nsGetServiceByCIDWithError( const nsCID& aCID, nsresult* aErrorPtr ) : mCID(aCID), mErrorPtr(aErrorPtr) { // nothing else to do } nsresult NS_FASTCALL operator()( const nsIID&, void** ) const; private: const nsCID& mCID; nsresult* mErrorPtr; }; class NS_COM_GLUE nsGetServiceByContractID { public: explicit nsGetServiceByContractID(const char* aContractID) : mContractID(aContractID) { // nothing else to do } nsresult NS_FASTCALL operator()( const nsIID&, void** ) const; private: const char* mContractID; }; class NS_COM_GLUE nsGetServiceByContractIDWithError { public: nsGetServiceByContractIDWithError(const char* aContractID, nsresult* aErrorPtr) : mContractID(aContractID), mErrorPtr(aErrorPtr) { // nothing else to do } nsresult NS_FASTCALL operator()( const nsIID&, void** ) const; private: const char* mContractID; nsresult* mErrorPtr; }; class nsCOMPtr_base /* ...factors implementation for all template versions of |nsCOMPtr|. This should really be an |nsCOMPtr|, but this wouldn't work because unlike the Here's the way people normally do things like this template class Foo { ... }; template <> class Foo { ... }; template class Foo : private Foo { ... }; */ { public: nsCOMPtr_base( nsISupports* rawPtr = 0 ) : mRawPtr(rawPtr) { // nothing else to do here } NS_COM_GLUE NS_CONSTRUCTOR_FASTCALL ~nsCOMPtr_base() { NSCAP_LOG_RELEASE(this, mRawPtr); if ( mRawPtr ) NSCAP_RELEASE(this, mRawPtr); } NS_COM_GLUE void NS_FASTCALL assign_with_AddRef( nsISupports* ); NS_COM_GLUE void NS_FASTCALL assign_from_qi( const nsQueryInterface, const nsIID& ); NS_COM_GLUE void NS_FASTCALL assign_from_qi_with_error( const nsQueryInterfaceWithError&, const nsIID& ); NS_COM_GLUE void NS_FASTCALL assign_from_gs_cid( const nsGetServiceByCID, const nsIID& ); NS_COM_GLUE void NS_FASTCALL assign_from_gs_cid_with_error( const nsGetServiceByCIDWithError&, const nsIID& ); NS_COM_GLUE void NS_FASTCALL assign_from_gs_contractid( const nsGetServiceByContractID, const nsIID& ); NS_COM_GLUE void NS_FASTCALL assign_from_gs_contractid_with_error( const nsGetServiceByContractIDWithError&, const nsIID& ); NS_COM_GLUE void NS_FASTCALL assign_from_helper( const nsCOMPtr_helper&, const nsIID& ); NS_COM_GLUE void** NS_FASTCALL begin_assignment(); protected: NS_MAY_ALIAS_PTR(nsISupports) mRawPtr; void assign_assuming_AddRef( nsISupports* newPtr ) { /* |AddRef()|ing the new value (before entering this function) before |Release()|ing the old lets us safely ignore the self-assignment case. We must, however, be careful only to |Release()| _after_ doing the assignment, in case the |Release()| leads to our _own_ destruction, which would, in turn, cause an incorrect second |Release()| of our old pointer. Thank for discovering this. */ nsISupports* oldPtr = mRawPtr; mRawPtr = newPtr; NSCAP_LOG_ASSIGNMENT(this, newPtr); NSCAP_LOG_RELEASE(this, oldPtr); if ( oldPtr ) NSCAP_RELEASE(this, oldPtr); } }; // template class nsGetterAddRefs; template class nsCOMPtr MOZ_FINAL #ifdef NSCAP_FEATURE_USE_BASE : private nsCOMPtr_base #endif { #ifdef NSCAP_FEATURE_USE_BASE #define NSCAP_CTOR_BASE(x) nsCOMPtr_base(x) #else #define NSCAP_CTOR_BASE(x) mRawPtr(x) private: void assign_with_AddRef( nsISupports* ); void assign_from_qi( const nsQueryInterface, const nsIID& ); void assign_from_qi_with_error( const nsQueryInterfaceWithError&, const nsIID& ); void assign_from_gs_cid( const nsGetServiceByCID, const nsIID& ); void assign_from_gs_cid_with_error( const nsGetServiceByCIDWithError&, const nsIID& ); void assign_from_gs_contractid( const nsGetServiceByContractID, const nsIID& ); void assign_from_gs_contractid_with_error( const nsGetServiceByContractIDWithError&, const nsIID& ); void assign_from_helper( const nsCOMPtr_helper&, const nsIID& ); void** begin_assignment(); void assign_assuming_AddRef( T* newPtr ) { T* oldPtr = mRawPtr; mRawPtr = newPtr; NSCAP_LOG_ASSIGNMENT(this, newPtr); NSCAP_LOG_RELEASE(this, oldPtr); if ( oldPtr ) NSCAP_RELEASE(this, oldPtr); } private: T* mRawPtr; #endif public: typedef T element_type; #ifndef NSCAP_FEATURE_USE_BASE ~nsCOMPtr() { NSCAP_LOG_RELEASE(this, mRawPtr); if ( mRawPtr ) NSCAP_RELEASE(this, mRawPtr); } #endif #ifdef NSCAP_FEATURE_TEST_DONTQUERY_CASES void Assert_NoQueryNeeded() { if ( mRawPtr ) { nsCOMPtr query_result( do_QueryInterface(mRawPtr) ); NS_ASSERTION(query_result.get() == mRawPtr, "QueryInterface needed"); } } #define NSCAP_ASSERT_NO_QUERY_NEEDED() Assert_NoQueryNeeded(); #else #define NSCAP_ASSERT_NO_QUERY_NEEDED() #endif // Constructors nsCOMPtr() : NSCAP_CTOR_BASE(0) // default constructor { NSCAP_LOG_ASSIGNMENT(this, 0); } nsCOMPtr( const nsCOMPtr& aSmartPtr ) : NSCAP_CTOR_BASE(aSmartPtr.mRawPtr) // copy-constructor { if ( mRawPtr ) NSCAP_ADDREF(this, mRawPtr); NSCAP_LOG_ASSIGNMENT(this, aSmartPtr.mRawPtr); } nsCOMPtr( T* aRawPtr ) : NSCAP_CTOR_BASE(aRawPtr) // construct from a raw pointer (of the right type) { if ( mRawPtr ) NSCAP_ADDREF(this, mRawPtr); NSCAP_LOG_ASSIGNMENT(this, aRawPtr); NSCAP_ASSERT_NO_QUERY_NEEDED(); } nsCOMPtr( already_AddRefed& aSmartPtr ) : NSCAP_CTOR_BASE(aSmartPtr.take()) // construct from |already_AddRefed| { NSCAP_LOG_ASSIGNMENT(this, mRawPtr); NSCAP_ASSERT_NO_QUERY_NEEDED(); } nsCOMPtr( already_AddRefed&& aSmartPtr ) : NSCAP_CTOR_BASE(aSmartPtr.take()) // construct from |otherComPtr.forget()| { NSCAP_LOG_ASSIGNMENT(this, mRawPtr); NSCAP_ASSERT_NO_QUERY_NEEDED(); } template nsCOMPtr( already_AddRefed& aSmartPtr ) : NSCAP_CTOR_BASE(static_cast(aSmartPtr.take())) // construct from |already_AddRefed| { // But make sure that U actually inherits from T static_assert(mozilla::IsBaseOf::value, "U is not a subclass of T"); NSCAP_LOG_ASSIGNMENT(this, static_cast(mRawPtr)); NSCAP_ASSERT_NO_QUERY_NEEDED(); } template nsCOMPtr( already_AddRefed&& aSmartPtr ) : NSCAP_CTOR_BASE(static_cast(aSmartPtr.take())) // construct from |otherComPtr.forget()| { // But make sure that U actually inherits from T static_assert(mozilla::IsBaseOf::value, "U is not a subclass of T"); NSCAP_LOG_ASSIGNMENT(this, static_cast(mRawPtr)); NSCAP_ASSERT_NO_QUERY_NEEDED(); } nsCOMPtr( const nsQueryInterface qi ) : NSCAP_CTOR_BASE(0) // construct from |do_QueryInterface(expr)| { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_qi(qi, NS_GET_TEMPLATE_IID(T)); } nsCOMPtr( const nsQueryInterfaceWithError& qi ) : NSCAP_CTOR_BASE(0) // construct from |do_QueryInterface(expr, &rv)| { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_qi_with_error(qi, NS_GET_TEMPLATE_IID(T)); } nsCOMPtr( const nsGetServiceByCID gs ) : NSCAP_CTOR_BASE(0) // construct from |do_GetService(cid_expr)| { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_gs_cid(gs, NS_GET_TEMPLATE_IID(T)); } nsCOMPtr( const nsGetServiceByCIDWithError& gs ) : NSCAP_CTOR_BASE(0) // construct from |do_GetService(cid_expr, &rv)| { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_gs_cid_with_error(gs, NS_GET_TEMPLATE_IID(T)); } nsCOMPtr( const nsGetServiceByContractID gs ) : NSCAP_CTOR_BASE(0) // construct from |do_GetService(contractid_expr)| { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_gs_contractid(gs, NS_GET_TEMPLATE_IID(T)); } nsCOMPtr( const nsGetServiceByContractIDWithError& gs ) : NSCAP_CTOR_BASE(0) // construct from |do_GetService(contractid_expr, &rv)| { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_gs_contractid_with_error(gs, NS_GET_TEMPLATE_IID(T)); } nsCOMPtr( const nsCOMPtr_helper& helper ) : NSCAP_CTOR_BASE(0) // ...and finally, anything else we might need to construct from // can exploit the |nsCOMPtr_helper| facility { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_helper(helper, NS_GET_TEMPLATE_IID(T)); NSCAP_ASSERT_NO_QUERY_NEEDED(); } // Assignment operators nsCOMPtr& operator=( const nsCOMPtr& rhs ) // copy assignment operator { assign_with_AddRef(rhs.mRawPtr); return *this; } nsCOMPtr& operator=( T* rhs ) // assign from a raw pointer (of the right type) { assign_with_AddRef(rhs); NSCAP_ASSERT_NO_QUERY_NEEDED(); return *this; } template nsCOMPtr& operator=( already_AddRefed& rhs ) // assign from |already_AddRefed| { // Make sure that U actually inherits from T static_assert(mozilla::IsBaseOf::value, "U is not a subclass of T"); assign_assuming_AddRef(static_cast(rhs.take())); NSCAP_ASSERT_NO_QUERY_NEEDED(); return *this; } template nsCOMPtr& operator=( already_AddRefed&& rhs ) // assign from |otherComPtr.forget()| { // Make sure that U actually inherits from T static_assert(mozilla::IsBaseOf::value, "U is not a subclass of T"); assign_assuming_AddRef(static_cast(rhs.take())); NSCAP_ASSERT_NO_QUERY_NEEDED(); return *this; } nsCOMPtr& operator=( const nsQueryInterface rhs ) // assign from |do_QueryInterface(expr)| { assign_from_qi(rhs, NS_GET_TEMPLATE_IID(T)); return *this; } nsCOMPtr& operator=( const nsQueryInterfaceWithError& rhs ) // assign from |do_QueryInterface(expr, &rv)| { assign_from_qi_with_error(rhs, NS_GET_TEMPLATE_IID(T)); return *this; } nsCOMPtr& operator=( const nsGetServiceByCID rhs ) // assign from |do_GetService(cid_expr)| { assign_from_gs_cid(rhs, NS_GET_TEMPLATE_IID(T)); return *this; } nsCOMPtr& operator=( const nsGetServiceByCIDWithError& rhs ) // assign from |do_GetService(cid_expr, &rv)| { assign_from_gs_cid_with_error(rhs, NS_GET_TEMPLATE_IID(T)); return *this; } nsCOMPtr& operator=( const nsGetServiceByContractID rhs ) // assign from |do_GetService(contractid_expr)| { assign_from_gs_contractid(rhs, NS_GET_TEMPLATE_IID(T)); return *this; } nsCOMPtr& operator=( const nsGetServiceByContractIDWithError& rhs ) // assign from |do_GetService(contractid_expr, &rv)| { assign_from_gs_contractid_with_error(rhs, NS_GET_TEMPLATE_IID(T)); return *this; } nsCOMPtr& operator=( const nsCOMPtr_helper& rhs ) // ...and finally, anything else we might need to assign from // can exploit the |nsCOMPtr_helper| facility. { assign_from_helper(rhs, NS_GET_TEMPLATE_IID(T)); NSCAP_ASSERT_NO_QUERY_NEEDED(); return *this; } void swap( nsCOMPtr& rhs ) // ...exchange ownership with |rhs|; can save a pair of refcount operations { #ifdef NSCAP_FEATURE_USE_BASE nsISupports* temp = rhs.mRawPtr; #else T* temp = rhs.mRawPtr; #endif NSCAP_LOG_ASSIGNMENT(&rhs, mRawPtr); NSCAP_LOG_ASSIGNMENT(this, temp); NSCAP_LOG_RELEASE(this, mRawPtr); NSCAP_LOG_RELEASE(&rhs, temp); rhs.mRawPtr = mRawPtr; mRawPtr = temp; // |rhs| maintains the same invariants, so we don't need to |NSCAP_ASSERT_NO_QUERY_NEEDED| } void swap( T*& rhs ) // ...exchange ownership with |rhs|; can save a pair of refcount operations { #ifdef NSCAP_FEATURE_USE_BASE nsISupports* temp = rhs; #else T* temp = rhs; #endif NSCAP_LOG_ASSIGNMENT(this, temp); NSCAP_LOG_RELEASE(this, mRawPtr); rhs = reinterpret_cast(mRawPtr); mRawPtr = temp; NSCAP_ASSERT_NO_QUERY_NEEDED(); } // Other pointer operators already_AddRefed forget() // return the value of mRawPtr and null out mRawPtr. Useful for // already_AddRefed return values. { T* temp = 0; swap(temp); return already_AddRefed(temp); } template void forget( I** rhs ) // Set the target of rhs to the value of mRawPtr and null out mRawPtr. // Useful to avoid unnecessary AddRef/Release pairs with "out" // parameters where rhs bay be a T** or an I** where I is a base class // of T. { NS_ASSERTION(rhs, "Null pointer passed to forget!"); NSCAP_LOG_RELEASE(this, mRawPtr); *rhs = get(); mRawPtr = 0; } T* get() const /* Prefer the implicit conversion provided automatically by |operator T*() const|. Use |get()| to resolve ambiguity or to get a castable pointer. */ { return reinterpret_cast(mRawPtr); } operator T*() const /* ...makes an |nsCOMPtr| act like its underlying raw pointer type whenever it is used in a context where a raw pointer is expected. It is this operator that makes an |nsCOMPtr| substitutable for a raw pointer. Prefer the implicit use of this operator to calling |get()|, except where necessary to resolve ambiguity. */ { return get(); } T* operator->() const { NS_ABORT_IF_FALSE(mRawPtr != 0, "You can't dereference a NULL nsCOMPtr with operator->()."); return get(); } nsCOMPtr* get_address() // This is not intended to be used by clients. See |address_of| // below. { return this; } const nsCOMPtr* get_address() const // This is not intended to be used by clients. See |address_of| // below. { return this; } public: T& operator*() const { NS_ABORT_IF_FALSE(mRawPtr != 0, "You can't dereference a NULL nsCOMPtr with operator*()."); return *get(); } T** StartAssignment() { #ifndef NSCAP_FEATURE_INLINE_STARTASSIGNMENT return reinterpret_cast(begin_assignment()); #else assign_assuming_AddRef(0); return reinterpret_cast(&mRawPtr); #endif } }; /* Specializing |nsCOMPtr| for |nsISupports| allows us to use |nsCOMPtr| the same way people use |nsISupports*| and |void*|, i.e., as a `catch-all' pointer pointing to any valid [XP]COM interface. Otherwise, an |nsCOMPtr| would only be able to point to the single [XP]COM-correct |nsISupports| instance within an object; extra querying ensues. Clients need to be able to pass around arbitrary interface pointers, without hassles, through intermediary code that doesn't know the exact type. */ template <> class nsCOMPtr : private nsCOMPtr_base { public: typedef nsISupports element_type; // Constructors nsCOMPtr() : nsCOMPtr_base(0) // default constructor { NSCAP_LOG_ASSIGNMENT(this, 0); } nsCOMPtr( const nsCOMPtr& aSmartPtr ) : nsCOMPtr_base(aSmartPtr.mRawPtr) // copy constructor { if ( mRawPtr ) NSCAP_ADDREF(this, mRawPtr); NSCAP_LOG_ASSIGNMENT(this, aSmartPtr.mRawPtr); } nsCOMPtr( nsISupports* aRawPtr ) : nsCOMPtr_base(aRawPtr) // construct from a raw pointer (of the right type) { if ( mRawPtr ) NSCAP_ADDREF(this, mRawPtr); NSCAP_LOG_ASSIGNMENT(this, aRawPtr); } nsCOMPtr( already_AddRefed& aSmartPtr ) : nsCOMPtr_base(aSmartPtr.take()) // construct from |already_AddRefed| { NSCAP_LOG_ASSIGNMENT(this, mRawPtr); } nsCOMPtr( already_AddRefed&& aSmartPtr ) : nsCOMPtr_base(aSmartPtr.take()) // construct from |otherComPtr.forget()| { NSCAP_LOG_ASSIGNMENT(this, mRawPtr); } nsCOMPtr( const nsQueryInterface qi ) : nsCOMPtr_base(0) // assign from |do_QueryInterface(expr)| { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_qi(qi, NS_GET_IID(nsISupports)); } nsCOMPtr( const nsQueryInterfaceWithError& qi ) : nsCOMPtr_base(0) // assign from |do_QueryInterface(expr, &rv)| { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_qi_with_error(qi, NS_GET_IID(nsISupports)); } nsCOMPtr( const nsGetServiceByCID gs ) : nsCOMPtr_base(0) // assign from |do_GetService(cid_expr)| { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_gs_cid(gs, NS_GET_IID(nsISupports)); } nsCOMPtr( const nsGetServiceByCIDWithError& gs ) : nsCOMPtr_base(0) // assign from |do_GetService(cid_expr, &rv)| { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_gs_cid_with_error(gs, NS_GET_IID(nsISupports)); } nsCOMPtr( const nsGetServiceByContractID gs ) : nsCOMPtr_base(0) // assign from |do_GetService(contractid_expr)| { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_gs_contractid(gs, NS_GET_IID(nsISupports)); } nsCOMPtr( const nsGetServiceByContractIDWithError& gs ) : nsCOMPtr_base(0) // assign from |do_GetService(contractid_expr, &rv)| { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_gs_contractid_with_error(gs, NS_GET_IID(nsISupports)); } nsCOMPtr( const nsCOMPtr_helper& helper ) : nsCOMPtr_base(0) // ...and finally, anything else we might need to construct from // can exploit the |nsCOMPtr_helper| facility { NSCAP_LOG_ASSIGNMENT(this, 0); assign_from_helper(helper, NS_GET_IID(nsISupports)); } // Assignment operators nsCOMPtr& operator=( const nsCOMPtr& rhs ) // copy assignment operator { assign_with_AddRef(rhs.mRawPtr); return *this; } nsCOMPtr& operator=( nsISupports* rhs ) // assign from a raw pointer (of the right type) { assign_with_AddRef(rhs); return *this; } nsCOMPtr& operator=( already_AddRefed& rhs ) // assign from |already_AddRefed| { assign_assuming_AddRef(rhs.take()); return *this; } nsCOMPtr& operator=( already_AddRefed&& rhs ) // assign from |otherComPtr.forget()| { assign_assuming_AddRef(rhs.take()); return *this; } nsCOMPtr& operator=( const nsQueryInterface rhs ) // assign from |do_QueryInterface(expr)| { assign_from_qi(rhs, NS_GET_IID(nsISupports)); return *this; } nsCOMPtr& operator=( const nsQueryInterfaceWithError& rhs ) // assign from |do_QueryInterface(expr, &rv)| { assign_from_qi_with_error(rhs, NS_GET_IID(nsISupports)); return *this; } nsCOMPtr& operator=( const nsGetServiceByCID rhs ) // assign from |do_GetService(cid_expr)| { assign_from_gs_cid(rhs, NS_GET_IID(nsISupports)); return *this; } nsCOMPtr& operator=( const nsGetServiceByCIDWithError& rhs ) // assign from |do_GetService(cid_expr, &rv)| { assign_from_gs_cid_with_error(rhs, NS_GET_IID(nsISupports)); return *this; } nsCOMPtr& operator=( const nsGetServiceByContractID rhs ) // assign from |do_GetService(contractid_expr)| { assign_from_gs_contractid(rhs, NS_GET_IID(nsISupports)); return *this; } nsCOMPtr& operator=( const nsGetServiceByContractIDWithError& rhs ) // assign from |do_GetService(contractid_expr, &rv)| { assign_from_gs_contractid_with_error(rhs, NS_GET_IID(nsISupports)); return *this; } nsCOMPtr& operator=( const nsCOMPtr_helper& rhs ) // ...and finally, anything else we might need to assign from // can exploit the |nsCOMPtr_helper| facility. { assign_from_helper(rhs, NS_GET_IID(nsISupports)); return *this; } void swap( nsCOMPtr& rhs ) // ...exchange ownership with |rhs|; can save a pair of refcount operations { nsISupports* temp = rhs.mRawPtr; NSCAP_LOG_ASSIGNMENT(&rhs, mRawPtr); NSCAP_LOG_ASSIGNMENT(this, temp); NSCAP_LOG_RELEASE(this, mRawPtr); NSCAP_LOG_RELEASE(&rhs, temp); rhs.mRawPtr = mRawPtr; mRawPtr = temp; } void swap( nsISupports*& rhs ) // ...exchange ownership with |rhs|; can save a pair of refcount operations { nsISupports* temp = rhs; NSCAP_LOG_ASSIGNMENT(this, temp); NSCAP_LOG_RELEASE(this, mRawPtr); rhs = mRawPtr; mRawPtr = temp; } already_AddRefed forget() // return the value of mRawPtr and null out mRawPtr. Useful for // already_AddRefed return values. { nsISupports* temp = 0; swap(temp); return already_AddRefed(temp); } void forget( nsISupports** rhs ) // Set the target of rhs to the value of mRawPtr and null out mRawPtr. // Useful to avoid unnecessary AddRef/Release pairs with "out" // parameters. { NS_ASSERTION(rhs, "Null pointer passed to forget!"); *rhs = 0; swap(*rhs); } // Other pointer operators nsISupports* get() const /* Prefer the implicit conversion provided automatically by |operator nsISupports*() const|. Use |get()| to resolve ambiguity or to get a castable pointer. */ { return reinterpret_cast(mRawPtr); } operator nsISupports*() const /* ...makes an |nsCOMPtr| act like its underlying raw pointer type whenever it is used in a context where a raw pointer is expected. It is this operator that makes an |nsCOMPtr| substitutable for a raw pointer. Prefer the implicit use of this operator to calling |get()|, except where necessary to resolve ambiguity. */ { return get(); } nsISupports* operator->() const { NS_ABORT_IF_FALSE(mRawPtr != 0, "You can't dereference a NULL nsCOMPtr with operator->()."); return get(); } nsCOMPtr* get_address() // This is not intended to be used by clients. See |address_of| // below. { return this; } const nsCOMPtr* get_address() const // This is not intended to be used by clients. See |address_of| // below. { return this; } public: nsISupports& operator*() const { NS_ABORT_IF_FALSE(mRawPtr != 0, "You can't dereference a NULL nsCOMPtr with operator*()."); return *get(); } nsISupports** StartAssignment() { #ifndef NSCAP_FEATURE_INLINE_STARTASSIGNMENT return reinterpret_cast(begin_assignment()); #else assign_assuming_AddRef(0); return reinterpret_cast(&mRawPtr); #endif } }; template inline void ImplCycleCollectionUnlink(nsCOMPtr& aField) { aField = nullptr; } template inline void ImplCycleCollectionTraverse(nsCycleCollectionTraversalCallback& aCallback, nsCOMPtr& aField, const char* aName, uint32_t aFlags = 0) { CycleCollectionNoteChild(aCallback, aField.get(), aName, aFlags); } #ifndef NSCAP_FEATURE_USE_BASE template void nsCOMPtr::assign_with_AddRef( nsISupports* rawPtr ) { if ( rawPtr ) NSCAP_ADDREF(this, rawPtr); assign_assuming_AddRef(reinterpret_cast(rawPtr)); } template void nsCOMPtr::assign_from_qi( const nsQueryInterface qi, const nsIID& aIID ) { void* newRawPtr; if ( NS_FAILED( qi(aIID, &newRawPtr) ) ) newRawPtr = 0; assign_assuming_AddRef(static_cast(newRawPtr)); } template void nsCOMPtr::assign_from_qi_with_error( const nsQueryInterfaceWithError& qi, const nsIID& aIID ) { void* newRawPtr; if ( NS_FAILED( qi(aIID, &newRawPtr) ) ) newRawPtr = 0; assign_assuming_AddRef(static_cast(newRawPtr)); } template void nsCOMPtr::assign_from_gs_cid( const nsGetServiceByCID gs, const nsIID& aIID ) { void* newRawPtr; if ( NS_FAILED( gs(aIID, &newRawPtr) ) ) newRawPtr = 0; assign_assuming_AddRef(static_cast(newRawPtr)); } template void nsCOMPtr::assign_from_gs_cid_with_error( const nsGetServiceByCIDWithError& gs, const nsIID& aIID ) { void* newRawPtr; if ( NS_FAILED( gs(aIID, &newRawPtr) ) ) newRawPtr = 0; assign_assuming_AddRef(static_cast(newRawPtr)); } template void nsCOMPtr::assign_from_gs_contractid( const nsGetServiceByContractID gs, const nsIID& aIID ) { void* newRawPtr; if ( NS_FAILED( gs(aIID, &newRawPtr) ) ) newRawPtr = 0; assign_assuming_AddRef(static_cast(newRawPtr)); } template void nsCOMPtr::assign_from_gs_contractid_with_error( const nsGetServiceByContractIDWithError& gs, const nsIID& aIID ) { void* newRawPtr; if ( NS_FAILED( gs(aIID, &newRawPtr) ) ) newRawPtr = 0; assign_assuming_AddRef(static_cast(newRawPtr)); } template void nsCOMPtr::assign_from_helper( const nsCOMPtr_helper& helper, const nsIID& aIID ) { void* newRawPtr; if ( NS_FAILED( helper(aIID, &newRawPtr) ) ) newRawPtr = 0; assign_assuming_AddRef(static_cast(newRawPtr)); } template void** nsCOMPtr::begin_assignment() { assign_assuming_AddRef(0); union { T** mT; void** mVoid; } result; result.mT = &mRawPtr; return result.mVoid; } #endif template inline nsCOMPtr* address_of( nsCOMPtr& aPtr ) { return aPtr.get_address(); } template inline const nsCOMPtr* address_of( const nsCOMPtr& aPtr ) { return aPtr.get_address(); } template class nsGetterAddRefs /* ... This class is designed to be used for anonymous temporary objects in the argument list of calls that return COM interface pointers, e.g., nsCOMPtr fooP; ...->QueryInterface(iid, getter_AddRefs(fooP)) DO NOT USE THIS TYPE DIRECTLY IN YOUR CODE. Use |getter_AddRefs()| instead. When initialized with a |nsCOMPtr|, as in the example above, it returns a |void**|, a |T**|, or an |nsISupports**| as needed, that the outer call (|QueryInterface| in this case) can fill in. This type should be a nested class inside |nsCOMPtr|. */ { public: explicit nsGetterAddRefs( nsCOMPtr& aSmartPtr ) : mTargetSmartPtr(aSmartPtr) { // nothing else to do } #if defined(NSCAP_FEATURE_TEST_DONTQUERY_CASES) || defined(NSCAP_LOG_EXTERNAL_ASSIGNMENT) ~nsGetterAddRefs() { #ifdef NSCAP_LOG_EXTERNAL_ASSIGNMENT NSCAP_LOG_ASSIGNMENT(reinterpret_cast(address_of(mTargetSmartPtr)), mTargetSmartPtr.get()); #endif #ifdef NSCAP_FEATURE_TEST_DONTQUERY_CASES mTargetSmartPtr.Assert_NoQueryNeeded(); #endif } #endif operator void**() { return reinterpret_cast(mTargetSmartPtr.StartAssignment()); } operator T**() { return mTargetSmartPtr.StartAssignment(); } T*& operator*() { return *(mTargetSmartPtr.StartAssignment()); } private: nsCOMPtr& mTargetSmartPtr; }; template <> class nsGetterAddRefs { public: explicit nsGetterAddRefs( nsCOMPtr& aSmartPtr ) : mTargetSmartPtr(aSmartPtr) { // nothing else to do } #ifdef NSCAP_LOG_EXTERNAL_ASSIGNMENT ~nsGetterAddRefs() { NSCAP_LOG_ASSIGNMENT(reinterpret_cast(address_of(mTargetSmartPtr)), mTargetSmartPtr.get()); } #endif operator void**() { return reinterpret_cast(mTargetSmartPtr.StartAssignment()); } operator nsISupports**() { return mTargetSmartPtr.StartAssignment(); } nsISupports*& operator*() { return *(mTargetSmartPtr.StartAssignment()); } private: nsCOMPtr& mTargetSmartPtr; }; template inline nsGetterAddRefs getter_AddRefs( nsCOMPtr& aSmartPtr ) /* Used around a |nsCOMPtr| when ...makes the class |nsGetterAddRefs| invisible. */ { return nsGetterAddRefs(aSmartPtr); } template inline nsresult CallQueryInterface( T* aSource, nsGetterAddRefs aDestination ) { return CallQueryInterface(aSource, static_cast(aDestination)); } // Comparing two |nsCOMPtr|s template inline bool operator==( const nsCOMPtr& lhs, const nsCOMPtr& rhs ) { return static_cast(lhs.get()) == static_cast(rhs.get()); } template inline bool operator!=( const nsCOMPtr& lhs, const nsCOMPtr& rhs ) { return static_cast(lhs.get()) != static_cast(rhs.get()); } // Comparing an |nsCOMPtr| to a raw pointer template inline bool operator==( const nsCOMPtr& lhs, const U* rhs ) { return static_cast(lhs.get()) == rhs; } template inline bool operator==( const U* lhs, const nsCOMPtr& rhs ) { return lhs == static_cast(rhs.get()); } template inline bool operator!=( const nsCOMPtr& lhs, const U* rhs ) { return static_cast(lhs.get()) != rhs; } template inline bool operator!=( const U* lhs, const nsCOMPtr& rhs ) { return lhs != static_cast(rhs.get()); } // To avoid ambiguities caused by the presence of builtin |operator==|s // creating a situation where one of the |operator==| defined above // has a better conversion for one argument and the builtin has a // better conversion for the other argument, define additional // |operator==| without the |const| on the raw pointer. // See bug 65664 for details. #ifndef NSCAP_DONT_PROVIDE_NONCONST_OPEQ template inline bool operator==( const nsCOMPtr& lhs, U* rhs ) { return static_cast(lhs.get()) == const_cast(rhs); } template inline bool operator==( U* lhs, const nsCOMPtr& rhs ) { return const_cast(lhs) == static_cast(rhs.get()); } template inline bool operator!=( const nsCOMPtr& lhs, U* rhs ) { return static_cast(lhs.get()) != const_cast(rhs); } template inline bool operator!=( U* lhs, const nsCOMPtr& rhs ) { return const_cast(lhs) != static_cast(rhs.get()); } #endif // Comparing an |nsCOMPtr| to |0| class NSCAP_Zero; template inline bool operator==( const nsCOMPtr& lhs, NSCAP_Zero* rhs ) // specifically to allow |smartPtr == 0| { return static_cast(lhs.get()) == reinterpret_cast(rhs); } template inline bool operator==( NSCAP_Zero* lhs, const nsCOMPtr& rhs ) // specifically to allow |0 == smartPtr| { return reinterpret_cast(lhs) == static_cast(rhs.get()); } template inline bool operator!=( const nsCOMPtr& lhs, NSCAP_Zero* rhs ) // specifically to allow |smartPtr != 0| { return static_cast(lhs.get()) != reinterpret_cast(rhs); } template inline bool operator!=( NSCAP_Zero* lhs, const nsCOMPtr& rhs ) // specifically to allow |0 != smartPtr| { return reinterpret_cast(lhs) != static_cast(rhs.get()); } #ifdef HAVE_CPP_TROUBLE_COMPARING_TO_ZERO // We need to explicitly define comparison operators for `int' // because the compiler is lame. template inline bool operator==( const nsCOMPtr& lhs, int rhs ) // specifically to allow |smartPtr == 0| { return static_cast(lhs.get()) == reinterpret_cast(rhs); } template inline bool operator==( int lhs, const nsCOMPtr& rhs ) // specifically to allow |0 == smartPtr| { return reinterpret_cast(lhs) == static_cast(rhs.get()); } #endif // !defined(HAVE_CPP_TROUBLE_COMPARING_TO_ZERO) // Comparing any two [XP]COM objects for identity inline bool SameCOMIdentity( nsISupports* lhs, nsISupports* rhs ) { return nsCOMPtr( do_QueryInterface(lhs) ) == nsCOMPtr( do_QueryInterface(rhs) ); } template inline nsresult CallQueryInterface( nsCOMPtr& aSourcePtr, DestinationType** aDestPtr ) { return CallQueryInterface(aSourcePtr.get(), aDestPtr); } #endif // !defined(nsCOMPtr_h___)