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7bc752e42b
Also move MOZ_MUST_USE before function declarations' specifiers and return type. While clang and gcc's __attribute__((warn_unused_result)) can appear before, between, or after function specifiers and return types, the [[nodiscard]] attribute must precede the function specifiers. Depends on D108344 Differential Revision: https://phabricator.services.mozilla.com/D108345
653 lines
22 KiB
C++
653 lines
22 KiB
C++
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
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/* vim: set ts=8 sts=2 et sw=2 tw=80: */
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/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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/* Smart pointer managing sole ownership of a resource. */
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#ifndef mozilla_UniquePtr_h
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#define mozilla_UniquePtr_h
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#include <type_traits>
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#include <utility>
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#include "mozilla/Assertions.h"
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#include "mozilla/Attributes.h"
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#include "mozilla/CompactPair.h"
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#include "mozilla/Compiler.h"
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namespace mozilla {
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template <typename T>
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class DefaultDelete;
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template <typename T, class D = DefaultDelete<T>>
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class UniquePtr;
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} // namespace mozilla
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namespace mozilla {
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namespace detail {
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struct HasPointerTypeHelper {
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template <class U>
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static double Test(...);
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template <class U>
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static char Test(typename U::pointer* = 0);
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};
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template <class T>
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class HasPointerType
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: public std::integral_constant<bool, sizeof(HasPointerTypeHelper::Test<T>(
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0)) == 1> {};
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template <class T, class D, bool = HasPointerType<D>::value>
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struct PointerTypeImpl {
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typedef typename D::pointer Type;
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};
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template <class T, class D>
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struct PointerTypeImpl<T, D, false> {
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typedef T* Type;
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};
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template <class T, class D>
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struct PointerType {
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typedef typename PointerTypeImpl<T, std::remove_reference_t<D>>::Type Type;
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};
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} // namespace detail
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/**
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* UniquePtr is a smart pointer that wholly owns a resource. Ownership may be
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* transferred out of a UniquePtr through explicit action, but otherwise the
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* resource is destroyed when the UniquePtr is destroyed.
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*
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* UniquePtr is similar to C++98's std::auto_ptr, but it improves upon auto_ptr
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* in one crucial way: it's impossible to copy a UniquePtr. Copying an auto_ptr
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* obviously *can't* copy ownership of its singly-owned resource. So what
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* happens if you try to copy one? Bizarrely, ownership is implicitly
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* *transferred*, preserving single ownership but breaking code that assumes a
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* copy of an object is identical to the original. (This is why auto_ptr is
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* prohibited in STL containers.)
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*
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* UniquePtr solves this problem by being *movable* rather than copyable.
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* Instead of passing a |UniquePtr u| directly to the constructor or assignment
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* operator, you pass |Move(u)|. In doing so you indicate that you're *moving*
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* ownership out of |u|, into the target of the construction/assignment. After
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* the transfer completes, |u| contains |nullptr| and may be safely destroyed.
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* This preserves single ownership but also allows UniquePtr to be moved by
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* algorithms that have been made move-safe. (Note: if |u| is instead a
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* temporary expression, don't use |Move()|: just pass the expression, because
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* it's already move-ready. For more information see Move.h.)
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*
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* UniquePtr is also better than std::auto_ptr in that the deletion operation is
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* customizable. An optional second template parameter specifies a class that
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* (through its operator()(T*)) implements the desired deletion policy. If no
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* policy is specified, mozilla::DefaultDelete<T> is used -- which will either
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* |delete| or |delete[]| the resource, depending whether the resource is an
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* array. Custom deletion policies ideally should be empty classes (no member
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* fields, no member fields in base classes, no virtual methods/inheritance),
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* because then UniquePtr can be just as efficient as a raw pointer.
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*
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* Use of UniquePtr proceeds like so:
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*
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* UniquePtr<int> g1; // initializes to nullptr
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* g1.reset(new int); // switch resources using reset()
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* g1 = nullptr; // clears g1, deletes the int
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*
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* UniquePtr<int> g2(new int); // owns that int
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* int* p = g2.release(); // g2 leaks its int -- still requires deletion
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* delete p; // now freed
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*
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* struct S { int x; S(int x) : x(x) {} };
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* UniquePtr<S> g3, g4(new S(5));
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* g3 = std::move(g4); // g3 owns the S, g4 cleared
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* S* p = g3.get(); // g3 still owns |p|
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* assert(g3->x == 5); // operator-> works (if .get() != nullptr)
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* assert((*g3).x == 5); // also operator* (again, if not cleared)
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* std::swap(g3, g4); // g4 now owns the S, g3 cleared
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* g3.swap(g4); // g3 now owns the S, g4 cleared
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* UniquePtr<S> g5(std::move(g3)); // g5 owns the S, g3 cleared
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* g5.reset(); // deletes the S, g5 cleared
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*
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* struct FreePolicy { void operator()(void* p) { free(p); } };
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* UniquePtr<int, FreePolicy> g6(static_cast<int*>(malloc(sizeof(int))));
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* int* ptr = g6.get();
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* g6 = nullptr; // calls free(ptr)
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*
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* Now, carefully note a few things you *can't* do:
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*
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* UniquePtr<int> b1;
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* b1 = new int; // BAD: can only assign another UniquePtr
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* int* ptr = b1; // BAD: no auto-conversion to pointer, use get()
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*
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* UniquePtr<int> b2(b1); // BAD: can't copy a UniquePtr
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* UniquePtr<int> b3 = b1; // BAD: can't copy-assign a UniquePtr
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*
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* (Note that changing a UniquePtr to store a direct |new| expression is
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* permitted, but usually you should use MakeUnique, defined at the end of this
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* header.)
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*
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* A few miscellaneous notes:
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*
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* UniquePtr, when not instantiated for an array type, can be move-constructed
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* and move-assigned, not only from itself but from "derived" UniquePtr<U, E>
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* instantiations where U converts to T and E converts to D. If you want to use
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* this, you're going to have to specify a deletion policy for both UniquePtr
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* instantations, and T pretty much has to have a virtual destructor. In other
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* words, this doesn't work:
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*
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* struct Base { virtual ~Base() {} };
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* struct Derived : Base {};
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*
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* UniquePtr<Base> b1;
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* // BAD: DefaultDelete<Base> and DefaultDelete<Derived> don't interconvert
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* UniquePtr<Derived> d1(std::move(b));
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*
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* UniquePtr<Base> b2;
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* UniquePtr<Derived, DefaultDelete<Base>> d2(std::move(b2)); // okay
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*
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* UniquePtr is specialized for array types. Specializing with an array type
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* creates a smart-pointer version of that array -- not a pointer to such an
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* array.
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*
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* UniquePtr<int[]> arr(new int[5]);
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* arr[0] = 4;
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*
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* What else is different? Deletion of course uses |delete[]|. An operator[]
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* is provided. Functionality that doesn't make sense for arrays is removed.
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* The constructors and mutating methods only accept array pointers (not T*, U*
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* that converts to T*, or UniquePtr<U[]> or UniquePtr<U>) or |nullptr|.
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*
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* It's perfectly okay for a function to return a UniquePtr. This transfers
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* the UniquePtr's sole ownership of the data, to the fresh UniquePtr created
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* in the calling function, that will then solely own that data. Such functions
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* can return a local variable UniquePtr, |nullptr|, |UniquePtr(ptr)| where
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* |ptr| is a |T*|, or a UniquePtr |Move()|'d from elsewhere.
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*
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* UniquePtr will commonly be a member of a class, with lifetime equivalent to
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* that of that class. If you want to expose the related resource, you could
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* expose a raw pointer via |get()|, but ownership of a raw pointer is
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* inherently unclear. So it's better to expose a |const UniquePtr&| instead.
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* This prohibits mutation but still allows use of |get()| when needed (but
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* operator-> is preferred). Of course, you can only use this smart pointer as
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* long as the enclosing class instance remains live -- no different than if you
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* exposed the |get()| raw pointer.
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*
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* To pass a UniquePtr-managed resource as a pointer, use a |const UniquePtr&|
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* argument. To specify an inout parameter (where the method may or may not
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* take ownership of the resource, or reset it), or to specify an out parameter
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* (where simply returning a |UniquePtr| isn't possible), use a |UniquePtr&|
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* argument. To unconditionally transfer ownership of a UniquePtr
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* into a method, use a |UniquePtr| argument. To conditionally transfer
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* ownership of a resource into a method, should the method want it, use a
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* |UniquePtr&&| argument.
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*/
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template <typename T, class D>
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class UniquePtr {
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public:
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typedef T ElementType;
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typedef D DeleterType;
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typedef typename detail::PointerType<T, DeleterType>::Type Pointer;
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private:
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mozilla::CompactPair<Pointer, DeleterType> mTuple;
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Pointer& ptr() { return mTuple.first(); }
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const Pointer& ptr() const { return mTuple.first(); }
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DeleterType& del() { return mTuple.second(); }
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const DeleterType& del() const { return mTuple.second(); }
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public:
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/**
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* Construct a UniquePtr containing |nullptr|.
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*/
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constexpr UniquePtr() : mTuple(static_cast<Pointer>(nullptr), DeleterType()) {
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static_assert(!std::is_pointer_v<D>, "must provide a deleter instance");
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static_assert(!std::is_reference_v<D>, "must provide a deleter instance");
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}
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/**
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* Construct a UniquePtr containing |aPtr|.
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*/
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explicit UniquePtr(Pointer aPtr) : mTuple(aPtr, DeleterType()) {
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static_assert(!std::is_pointer_v<D>, "must provide a deleter instance");
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static_assert(!std::is_reference_v<D>, "must provide a deleter instance");
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}
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UniquePtr(Pointer aPtr,
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std::conditional_t<std::is_reference_v<D>, D, const D&> aD1)
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: mTuple(aPtr, aD1) {}
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UniquePtr(Pointer aPtr, std::remove_reference_t<D>&& aD2)
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: mTuple(aPtr, std::move(aD2)) {
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static_assert(!std::is_reference_v<D>,
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"rvalue deleter can't be stored by reference");
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}
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UniquePtr(UniquePtr&& aOther)
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: mTuple(aOther.release(),
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std::forward<DeleterType>(aOther.get_deleter())) {}
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MOZ_IMPLICIT
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UniquePtr(decltype(nullptr)) : mTuple(nullptr, DeleterType()) {
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static_assert(!std::is_pointer_v<D>, "must provide a deleter instance");
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static_assert(!std::is_reference_v<D>, "must provide a deleter instance");
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}
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template <typename U, class E>
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MOZ_IMPLICIT UniquePtr(
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UniquePtr<U, E>&& aOther,
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std::enable_if_t<
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std::is_convertible_v<typename UniquePtr<U, E>::Pointer, Pointer> &&
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!std::is_array_v<U> &&
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(std::is_reference_v<D> ? std::is_same_v<D, E>
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: std::is_convertible_v<E, D>),
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int>
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aDummy = 0)
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: mTuple(aOther.release(), std::forward<E>(aOther.get_deleter())) {}
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~UniquePtr() { reset(nullptr); }
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UniquePtr& operator=(UniquePtr&& aOther) {
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reset(aOther.release());
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get_deleter() = std::forward<DeleterType>(aOther.get_deleter());
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return *this;
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}
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template <typename U, typename E>
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UniquePtr& operator=(UniquePtr<U, E>&& aOther) {
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static_assert(
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std::is_convertible_v<typename UniquePtr<U, E>::Pointer, Pointer>,
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"incompatible UniquePtr pointees");
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static_assert(!std::is_array_v<U>,
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"can't assign from UniquePtr holding an array");
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reset(aOther.release());
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get_deleter() = std::forward<E>(aOther.get_deleter());
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return *this;
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}
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UniquePtr& operator=(decltype(nullptr)) {
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reset(nullptr);
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return *this;
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}
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std::add_lvalue_reference_t<T> operator*() const {
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MOZ_ASSERT(get(), "dereferencing a UniquePtr containing nullptr with *");
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return *get();
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}
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Pointer operator->() const {
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MOZ_ASSERT(get(), "dereferencing a UniquePtr containing nullptr with ->");
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return get();
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}
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explicit operator bool() const { return get() != nullptr; }
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Pointer get() const { return ptr(); }
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DeleterType& get_deleter() { return del(); }
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const DeleterType& get_deleter() const { return del(); }
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[[nodiscard]] Pointer release() {
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Pointer p = ptr();
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ptr() = nullptr;
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return p;
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}
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void reset(Pointer aPtr = Pointer()) {
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Pointer old = ptr();
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ptr() = aPtr;
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if (old != nullptr) {
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get_deleter()(old);
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}
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}
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void swap(UniquePtr& aOther) { mTuple.swap(aOther.mTuple); }
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UniquePtr(const UniquePtr& aOther) = delete; // construct using std::move()!
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void operator=(const UniquePtr& aOther) =
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delete; // assign using std::move()!
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};
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// In case you didn't read the comment by the main definition (you should!): the
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// UniquePtr<T[]> specialization exists to manage array pointers. It deletes
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// such pointers using delete[], it will reject construction and modification
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// attempts using U* or U[]. Otherwise it works like the normal UniquePtr.
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template <typename T, class D>
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class UniquePtr<T[], D> {
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public:
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typedef T* Pointer;
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typedef T ElementType;
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typedef D DeleterType;
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private:
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mozilla::CompactPair<Pointer, DeleterType> mTuple;
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public:
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/**
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* Construct a UniquePtr containing nullptr.
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*/
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constexpr UniquePtr() : mTuple(static_cast<Pointer>(nullptr), DeleterType()) {
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static_assert(!std::is_pointer_v<D>, "must provide a deleter instance");
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static_assert(!std::is_reference_v<D>, "must provide a deleter instance");
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}
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/**
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* Construct a UniquePtr containing |aPtr|.
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*/
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explicit UniquePtr(Pointer aPtr) : mTuple(aPtr, DeleterType()) {
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static_assert(!std::is_pointer_v<D>, "must provide a deleter instance");
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static_assert(!std::is_reference_v<D>, "must provide a deleter instance");
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}
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// delete[] knows how to handle *only* an array of a single class type. For
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// delete[] to work correctly, it must know the size of each element, the
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// fields and base classes of each element requiring destruction, and so on.
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// So forbid all overloads which would end up invoking delete[] on a pointer
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// of the wrong type.
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template <typename U>
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UniquePtr(U&& aU,
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std::enable_if_t<
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std::is_pointer_v<U> && std::is_convertible_v<U, Pointer>, int>
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aDummy = 0) = delete;
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UniquePtr(Pointer aPtr,
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std::conditional_t<std::is_reference_v<D>, D, const D&> aD1)
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: mTuple(aPtr, aD1) {}
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UniquePtr(Pointer aPtr, std::remove_reference_t<D>&& aD2)
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: mTuple(aPtr, std::move(aD2)) {
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static_assert(!std::is_reference_v<D>,
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"rvalue deleter can't be stored by reference");
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}
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// Forbidden for the same reasons as stated above.
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template <typename U, typename V>
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UniquePtr(U&& aU, V&& aV,
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std::enable_if_t<
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std::is_pointer_v<U> && std::is_convertible_v<U, Pointer>, int>
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aDummy = 0) = delete;
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UniquePtr(UniquePtr&& aOther)
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: mTuple(aOther.release(),
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std::forward<DeleterType>(aOther.get_deleter())) {}
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MOZ_IMPLICIT
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UniquePtr(decltype(nullptr)) : mTuple(nullptr, DeleterType()) {
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static_assert(!std::is_pointer_v<D>, "must provide a deleter instance");
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static_assert(!std::is_reference_v<D>, "must provide a deleter instance");
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}
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~UniquePtr() { reset(nullptr); }
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UniquePtr& operator=(UniquePtr&& aOther) {
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reset(aOther.release());
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get_deleter() = std::forward<DeleterType>(aOther.get_deleter());
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return *this;
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}
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UniquePtr& operator=(decltype(nullptr)) {
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reset();
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return *this;
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}
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explicit operator bool() const { return get() != nullptr; }
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T& operator[](decltype(sizeof(int)) aIndex) const { return get()[aIndex]; }
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Pointer get() const { return mTuple.first(); }
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DeleterType& get_deleter() { return mTuple.second(); }
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const DeleterType& get_deleter() const { return mTuple.second(); }
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[[nodiscard]] Pointer release() {
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Pointer p = mTuple.first();
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mTuple.first() = nullptr;
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return p;
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}
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void reset(Pointer aPtr = Pointer()) {
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Pointer old = mTuple.first();
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mTuple.first() = aPtr;
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if (old != nullptr) {
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mTuple.second()(old);
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}
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}
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void reset(decltype(nullptr)) {
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Pointer old = mTuple.first();
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mTuple.first() = nullptr;
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if (old != nullptr) {
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mTuple.second()(old);
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}
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}
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template <typename U>
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void reset(U) = delete;
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void swap(UniquePtr& aOther) { mTuple.swap(aOther.mTuple); }
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UniquePtr(const UniquePtr& aOther) = delete; // construct using std::move()!
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void operator=(const UniquePtr& aOther) =
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delete; // assign using std::move()!
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};
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/**
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* A default deletion policy using plain old operator delete.
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*
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* Note that this type can be specialized, but authors should beware of the risk
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* that the specialization may at some point cease to match (either because it
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* gets moved to a different compilation unit or the signature changes). If the
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* non-specialized (|delete|-based) version compiles for that type but does the
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* wrong thing, bad things could happen.
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*
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* This is a non-issue for types which are always incomplete (i.e. opaque handle
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* types), since |delete|-ing such a type will always trigger a compilation
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* error.
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*/
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template <typename T>
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class DefaultDelete {
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public:
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constexpr DefaultDelete() = default;
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template <typename U>
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MOZ_IMPLICIT DefaultDelete(
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const DefaultDelete<U>& aOther,
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std::enable_if_t<std::is_convertible_v<U*, T*>, int> aDummy = 0) {}
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void operator()(T* aPtr) const {
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static_assert(sizeof(T) > 0, "T must be complete");
|
|
delete aPtr;
|
|
}
|
|
};
|
|
|
|
/** A default deletion policy using operator delete[]. */
|
|
template <typename T>
|
|
class DefaultDelete<T[]> {
|
|
public:
|
|
constexpr DefaultDelete() = default;
|
|
|
|
void operator()(T* aPtr) const {
|
|
static_assert(sizeof(T) > 0, "T must be complete");
|
|
delete[] aPtr;
|
|
}
|
|
|
|
template <typename U>
|
|
void operator()(U* aPtr) const = delete;
|
|
};
|
|
|
|
template <typename T, class D, typename U, class E>
|
|
bool operator==(const UniquePtr<T, D>& aX, const UniquePtr<U, E>& aY) {
|
|
return aX.get() == aY.get();
|
|
}
|
|
|
|
template <typename T, class D, typename U, class E>
|
|
bool operator!=(const UniquePtr<T, D>& aX, const UniquePtr<U, E>& aY) {
|
|
return aX.get() != aY.get();
|
|
}
|
|
|
|
template <typename T, class D>
|
|
bool operator==(const UniquePtr<T, D>& aX, const T* aY) {
|
|
return aX.get() == aY;
|
|
}
|
|
|
|
template <typename T, class D>
|
|
bool operator==(const T* aY, const UniquePtr<T, D>& aX) {
|
|
return aY == aX.get();
|
|
}
|
|
|
|
template <typename T, class D>
|
|
bool operator!=(const UniquePtr<T, D>& aX, const T* aY) {
|
|
return aX.get() != aY;
|
|
}
|
|
|
|
template <typename T, class D>
|
|
bool operator!=(const T* aY, const UniquePtr<T, D>& aX) {
|
|
return aY != aX.get();
|
|
}
|
|
|
|
template <typename T, class D>
|
|
bool operator==(const UniquePtr<T, D>& aX, decltype(nullptr)) {
|
|
return !aX;
|
|
}
|
|
|
|
template <typename T, class D>
|
|
bool operator==(decltype(nullptr), const UniquePtr<T, D>& aX) {
|
|
return !aX;
|
|
}
|
|
|
|
template <typename T, class D>
|
|
bool operator!=(const UniquePtr<T, D>& aX, decltype(nullptr)) {
|
|
return bool(aX);
|
|
}
|
|
|
|
template <typename T, class D>
|
|
bool operator!=(decltype(nullptr), const UniquePtr<T, D>& aX) {
|
|
return bool(aX);
|
|
}
|
|
|
|
// No operator<, operator>, operator<=, operator>= for now because simplicity.
|
|
|
|
namespace detail {
|
|
|
|
template <typename T>
|
|
struct UniqueSelector {
|
|
typedef UniquePtr<T> SingleObject;
|
|
};
|
|
|
|
template <typename T>
|
|
struct UniqueSelector<T[]> {
|
|
typedef UniquePtr<T[]> UnknownBound;
|
|
};
|
|
|
|
template <typename T, decltype(sizeof(int)) N>
|
|
struct UniqueSelector<T[N]> {
|
|
typedef UniquePtr<T[N]> KnownBound;
|
|
};
|
|
|
|
} // namespace detail
|
|
|
|
/**
|
|
* MakeUnique is a helper function for allocating new'd objects and arrays,
|
|
* returning a UniquePtr containing the resulting pointer. The semantics of
|
|
* MakeUnique<Type>(...) are as follows.
|
|
*
|
|
* If Type is an array T[n]:
|
|
* Disallowed, deleted, no overload for you!
|
|
* If Type is an array T[]:
|
|
* MakeUnique<T[]>(size_t) is the only valid overload. The pointer returned
|
|
* is as if by |new T[n]()|, which value-initializes each element. (If T
|
|
* isn't a class type, this will zero each element. If T is a class type,
|
|
* then roughly speaking, each element will be constructed using its default
|
|
* constructor. See C++11 [dcl.init]p7 for the full gory details.)
|
|
* If Type is non-array T:
|
|
* The arguments passed to MakeUnique<T>(...) are forwarded into a
|
|
* |new T(...)| call, initializing the T as would happen if executing
|
|
* |T(...)|.
|
|
*
|
|
* There are various benefits to using MakeUnique instead of |new| expressions.
|
|
*
|
|
* First, MakeUnique eliminates use of |new| from code entirely. If objects are
|
|
* only created through UniquePtr, then (assuming all explicit release() calls
|
|
* are safe, including transitively, and no type-safety casting funniness)
|
|
* correctly maintained ownership of the UniquePtr guarantees no leaks are
|
|
* possible. (This pays off best if a class is only ever created through a
|
|
* factory method on the class, using a private constructor.)
|
|
*
|
|
* Second, initializing a UniquePtr using a |new| expression requires repeating
|
|
* the name of the new'd type, whereas MakeUnique in concert with the |auto|
|
|
* keyword names it only once:
|
|
*
|
|
* UniquePtr<char> ptr1(new char()); // repetitive
|
|
* auto ptr2 = MakeUnique<char>(); // shorter
|
|
*
|
|
* Of course this assumes the reader understands the operation MakeUnique
|
|
* performs. In the long run this is probably a reasonable assumption. In the
|
|
* short run you'll have to use your judgment about what readers can be expected
|
|
* to know, or to quickly look up.
|
|
*
|
|
* Third, a call to MakeUnique can be assigned directly to a UniquePtr. In
|
|
* contrast you can't assign a pointer into a UniquePtr without using the
|
|
* cumbersome reset().
|
|
*
|
|
* UniquePtr<char> p;
|
|
* p = new char; // ERROR
|
|
* p.reset(new char); // works, but fugly
|
|
* p = MakeUnique<char>(); // preferred
|
|
*
|
|
* (And third, although not relevant to Mozilla: MakeUnique is exception-safe.
|
|
* An exception thrown after |new T| succeeds will leak that memory, unless the
|
|
* pointer is assigned to an object that will manage its ownership. UniquePtr
|
|
* ably serves this function.)
|
|
*/
|
|
|
|
template <typename T, typename... Args>
|
|
typename detail::UniqueSelector<T>::SingleObject MakeUnique(Args&&... aArgs) {
|
|
return UniquePtr<T>(new T(std::forward<Args>(aArgs)...));
|
|
}
|
|
|
|
template <typename T>
|
|
typename detail::UniqueSelector<T>::UnknownBound MakeUnique(
|
|
decltype(sizeof(int)) aN) {
|
|
using ArrayType = std::remove_extent_t<T>;
|
|
return UniquePtr<T>(new ArrayType[aN]());
|
|
}
|
|
|
|
template <typename T, typename... Args>
|
|
typename detail::UniqueSelector<T>::KnownBound MakeUnique(Args&&... aArgs) =
|
|
delete;
|
|
|
|
/**
|
|
* WrapUnique is a helper function to transfer ownership from a raw pointer
|
|
* into a UniquePtr<T>. It can only be used with a single non-array type.
|
|
*
|
|
* It is generally used this way:
|
|
*
|
|
* auto p = WrapUnique(new char);
|
|
*
|
|
* It can be used when MakeUnique is not usable, for example, when the
|
|
* constructor you are using is private, or you want to use aggregate
|
|
* initialization.
|
|
*/
|
|
|
|
template <typename T>
|
|
typename detail::UniqueSelector<T>::SingleObject WrapUnique(T* aPtr) {
|
|
return UniquePtr<T>(aPtr);
|
|
}
|
|
|
|
} // namespace mozilla
|
|
|
|
namespace std {
|
|
|
|
template <typename T, class D>
|
|
void swap(mozilla::UniquePtr<T, D>& aX, mozilla::UniquePtr<T, D>& aY) {
|
|
aX.swap(aY);
|
|
}
|
|
|
|
} // namespace std
|
|
|
|
#endif /* mozilla_UniquePtr_h */
|