/* * Copyright (c) Facebook, Inc. and its affiliates. * * This source code is licensed under the MIT license found in the * LICENSE file in the root directory of this source tree. */ #pragma once // ASSERT that __cplusplus >= 201103L #include #include #include INFER_NAMESPACE_STD_BEGIN // use inheritance to avoid compilation errors when using // methods / non-member functions that are not modeled // WARNING: if sizeof(shared_ptr) becomes different than 16, it may // lead to compilation errors template class shared_ptr : public std__shared_ptr { // translate shared_ptr as type T* friend class infer_traits::TranslateAsType; // shared_ptr in infer is translated as T*. // Some facts: // 1. shared_ptr* translated as T** // 2. typeof(this) translated as T** // 3. typeof(this) in clang's AST is shared_ptr* // When writing models for shared_ptr, we need to use infer's representation // In order to achieve that and not break compilation, there is some ugly // casting going around. We are using void* and void** to make compilation // happy - infer doesn't care about those types that much since they are // pointers anyway. // Example of model_X function declaration: // static void model_X(infer_shared_ptr_t self, ... params) // model_X are really C functions, but to simplify linking process, they are // defined inside shared_ptr class as static methods. // When using model_X functions, call them like so: // model_X(__cast_to_infer_ptr(this), args) /// type of 'this' in shared_ptr as seen by infer typedef const void** infer_shared_ptr_t; // use it to avoid compilation errors and make infer analyzer happy #define __cast_to_infer_ptr(self) ((infer_shared_ptr_t)self) // provide overload for volatile void* to accommodate for situation when // T is volatile ('volatile int' for example). 'void*' and 'nullptr_t' // overloads are to avoid 'call to model_set is ambiguous' compilation errors static void model_set(infer_shared_ptr_t self, nullptr_t value) { *self = value; } static void model_set(infer_shared_ptr_t self, const void* value) { *self = value; } static void model_set(infer_shared_ptr_t self, volatile void* value) { *self = const_cast(value); } static void model_set(infer_shared_ptr_t self, void* value) { *self = const_cast(value); } static void model_copy(infer_shared_ptr_t self, infer_shared_ptr_t other) { /* TODO - increase refcount*/ *self = *other; } static void model_move(infer_shared_ptr_t self, infer_shared_ptr_t other) { model_copy(self, other); model_set(other, nullptr); } static void model_swap(infer_shared_ptr_t infer_self, infer_shared_ptr_t infer_other) { const void* t = *infer_self; *infer_self = *infer_other; *infer_other = t; } public: // Conversion constructors to allow implicit conversions. // it's here purely to avoid compilation errors template ::value>::type> shared_ptr(const std__shared_ptr& r) {} template shared_ptr(const std__shared_ptr& r, T* p) noexcept {} // constructors: constexpr shared_ptr() noexcept { model_set(__cast_to_infer_ptr(this), nullptr); } shared_ptr(nullptr_t) : shared_ptr() {} // Extra template argument is used to create constructors/assignment overloads // for Y types where it's possible to convert Y* to T*. // typename = typename enable_if::value>::type // thanks to that, clang will not create some functions that would cause // compilation errors. More info: // http://en.cppreference.com/w/cpp/language/sfinae template ::value>::type> explicit shared_ptr(Y* p) { model_set(__cast_to_infer_ptr(this), p); } template ::value>::type> shared_ptr(Y* p, D d) : shared_ptr(p) {} template ::value>::type> shared_ptr(Y* p, D d, A a) : shared_ptr(p) {} template shared_ptr(nullptr_t p, D d) : shared_ptr(p) {} template shared_ptr(nullptr_t p, D d, A a) : shared_ptr(p) {} template shared_ptr(const shared_ptr& r, T* p) noexcept { model_set(__cast_to_infer_ptr(this), p); /* TODO */ } shared_ptr(const shared_ptr& r) noexcept { model_copy(__cast_to_infer_ptr(this), __cast_to_infer_ptr(&r)); } template ::value>::type> shared_ptr(const shared_ptr& r) noexcept { model_copy(__cast_to_infer_ptr(this), __cast_to_infer_ptr(&r)); } shared_ptr(shared_ptr&& r) noexcept { model_move(__cast_to_infer_ptr(this), __cast_to_infer_ptr(&r)); } template ::value>::type> shared_ptr(shared_ptr&& r) noexcept { model_move(__cast_to_infer_ptr(this), __cast_to_infer_ptr(&r)); } template ::value>::type> explicit shared_ptr(const weak_ptr& r) : shared_ptr(std::move(r.lock())) { // TODO: throw if r is empty } /* Because of implementation differences between libc++ and stdlibc++, don't * define this constructor (it will be defined elsewhere in case of * stdlibc++). Because it may be defined elsewhere, don't check whether Y* * converts to T* - otherwise there might be compilation error (out-of-line * definition). * No definition here might cause compilation problems if project is * using auto_ptrs with libc++ */ template shared_ptr(auto_ptr&& r); // {} template ::value>::type> shared_ptr(unique_ptr&& r) : shared_ptr(r.release()) {} // destructor: ~shared_ptr() { reset((T*)nullptr); } // assignment: shared_ptr& operator=(const shared_ptr& r) noexcept { // shared_ptr(r).swap(*this); model_copy(__cast_to_infer_ptr(this), __cast_to_infer_ptr(&r)); return *this; } template ::value>::type> shared_ptr& operator=(const shared_ptr& r) noexcept { // shared_ptr(r).swap(*this); model_copy(__cast_to_infer_ptr(this), __cast_to_infer_ptr(&r)); return *this; } shared_ptr& operator=(shared_ptr&& r) noexcept { // shared_ptr(std::move(r)).swap(*this); model_move(__cast_to_infer_ptr(this), __cast_to_infer_ptr(&r)); return *this; } template ::value>::type> shared_ptr& operator=(shared_ptr&& r) { // shared_ptr(std::move(r)).swap(*this); model_move(__cast_to_infer_ptr(this), __cast_to_infer_ptr(&r)); return *this; } template ::value>::type> shared_ptr& operator=(auto_ptr&& r) { /* ?? */ } template ::value>::type> shared_ptr& operator=(unique_ptr&& r) { // shared_ptr(std::move(r)).swap(*this); return *this; } // modifiers: void swap(shared_ptr& r) noexcept { model_swap(__cast_to_infer_ptr(this), __cast_to_infer_ptr(&r)); } void reset() noexcept { reset((T*)nullptr); } template ::value>::type> void reset(Y* p) { /* if (unique()) { delete __data; } */ model_set(__cast_to_infer_ptr(this), p); // TODO adjust refcounts } template ::value>::type> void reset(Y* p, D d) { reset(p); } template ::value>::type> void reset(Y* p, D d, A a) { reset(p); } // observers: T* get() const noexcept INFER_MODEL_AS_DEREF_FIRST_ARG; typename std::add_lvalue_reference::type operator*() const noexcept INFER_MODEL_AS_DEREF_FIRST_ARG; T* operator->() const noexcept INFER_MODEL_AS_DEREF_FIRST_ARG; long use_count() const noexcept { return 2; /* FIXME */ } bool unique() const noexcept { return use_count() == 1; /* FIXME */ } explicit operator bool() const noexcept { // for some reason analyzer can't cast to bool correctly, trick with two // negations creates right specs for this function return !!(bool)(*__cast_to_infer_ptr(this)); } template bool owner_before(shared_ptr const& b) const { return true; /* FIXME - use non-det*/ } template bool owner_before(weak_ptr const& b) const { return true; /* FIXME - use non-det */ } }; template inline bool operator==(const shared_ptr<_Tp>& __x, const shared_ptr<_Up>& __y) noexcept { return __x.get() == __y.get(); } template inline bool operator!=(const shared_ptr<_Tp>& __x, const shared_ptr<_Up>& __y) noexcept { return !(__x == __y); } template inline bool operator<(const shared_ptr<_Tp>& __x, const shared_ptr<_Up>& __y) noexcept { typedef typename common_type<_Tp*, _Up*>::type _Vp; return less<_Vp>()(__x.get(), __y.get()); } template inline bool operator>(const shared_ptr<_Tp>& __x, const shared_ptr<_Up>& __y) noexcept { return __y < __x; } template inline bool operator<=(const shared_ptr<_Tp>& __x, const shared_ptr<_Up>& __y) noexcept { return !(__y < __x); } template inline bool operator>=(const shared_ptr<_Tp>& __x, const shared_ptr<_Up>& __y) noexcept { return !(__x < __y); } template inline bool operator==(const shared_ptr<_Tp>& __x, nullptr_t) noexcept { return !__x; } template inline bool operator==(nullptr_t, const shared_ptr<_Tp>& __x) noexcept { return !__x; } template inline bool operator!=(const shared_ptr<_Tp>& __x, nullptr_t) noexcept { return static_cast(__x); } template inline bool operator!=(nullptr_t, const shared_ptr<_Tp>& __x) noexcept { return static_cast(__x); } template inline bool operator<(const shared_ptr<_Tp>& __x, nullptr_t) noexcept { return less<_Tp*>()(__x.get(), nullptr); } template inline bool operator<(nullptr_t, const shared_ptr<_Tp>& __x) noexcept { return less<_Tp*>()(nullptr, __x.get()); } template inline bool operator>(const shared_ptr<_Tp>& __x, nullptr_t) noexcept { return nullptr < __x; } template inline bool operator>(nullptr_t, const shared_ptr<_Tp>& __x) noexcept { return __x < nullptr; } template inline bool operator<=(const shared_ptr<_Tp>& __x, nullptr_t) noexcept { return !(nullptr < __x); } template inline bool operator<=(nullptr_t, const shared_ptr<_Tp>& __x) noexcept { return !(__x < nullptr); } template inline bool operator>=(const shared_ptr<_Tp>& __x, nullptr_t) noexcept { return !(__x < nullptr); } template inline bool operator>=(nullptr_t, const shared_ptr<_Tp>& __x) noexcept { return !(nullptr < __x); } template struct hash> : public hash> {}; // shared_ptr casts - call original functions but change return type to // std::shared_ptr template shared_ptr static_pointer_cast(shared_ptr const& r) noexcept { return static_pointer_cast((const std__shared_ptr&)r); } template shared_ptr dynamic_pointer_cast(shared_ptr const& r) noexcept { return dynamic_pointer_cast((const std__shared_ptr&)r); } template shared_ptr const_pointer_cast(shared_ptr const& r) noexcept { return const_pointer_cast((const std__shared_ptr&)r); } template class enable_shared_from_this : public std__enable_shared_from_this { public: shared_ptr shared_from_this() { return std__enable_shared_from_this::shared_from_this(); } shared_ptr shared_from_this() const { return std__enable_shared_from_this::shared_from_this(); } }; template shared_ptr make_shared(Args&&... args) { return shared_ptr(::new T(std::forward(args)...)); } template struct owner_less; template struct owner_less> : binary_function, shared_ptr, bool> { typedef bool result_type; bool operator()(shared_ptr const& x, shared_ptr const& y) const { return x.owner_before(y); } bool operator()(shared_ptr const& x, weak_ptr const& y) const { return x.owner_before(y); } bool operator()(weak_ptr const& x, shared_ptr const& y) const { return x.owner_before(y); } }; #undef __cast_to_infer_ptr INFER_NAMESPACE_STD_END