mirror of
https://github.com/klzgrad/naiveproxy.git
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579 lines
19 KiB
C++
579 lines
19 KiB
C++
// Copyright (c) 2011 The Chromium Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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// This defines a set of argument wrappers and related factory methods that
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// can be used specify the refcounting and reference semantics of arguments
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// that are bound by the Bind() function in base/bind.h.
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//
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// It also defines a set of simple functions and utilities that people want
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// when using Callback<> and Bind().
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//
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//
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// ARGUMENT BINDING WRAPPERS
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//
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// The wrapper functions are base::Unretained(), base::Owned(), base::Passed(),
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// base::ConstRef(), and base::IgnoreResult().
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//
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// Unretained() allows Bind() to bind a non-refcounted class, and to disable
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// refcounting on arguments that are refcounted objects.
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//
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// Owned() transfers ownership of an object to the Callback resulting from
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// bind; the object will be deleted when the Callback is deleted.
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//
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// Passed() is for transferring movable-but-not-copyable types (eg. unique_ptr)
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// through a Callback. Logically, this signifies a destructive transfer of
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// the state of the argument into the target function. Invoking
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// Callback::Run() twice on a Callback that was created with a Passed()
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// argument will CHECK() because the first invocation would have already
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// transferred ownership to the target function.
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//
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// RetainedRef() accepts a ref counted object and retains a reference to it.
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// When the callback is called, the object is passed as a raw pointer.
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//
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// ConstRef() allows binding a constant reference to an argument rather
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// than a copy.
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//
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// IgnoreResult() is used to adapt a function or Callback with a return type to
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// one with a void return. This is most useful if you have a function with,
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// say, a pesky ignorable bool return that you want to use with PostTask or
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// something else that expect a Callback with a void return.
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//
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// EXAMPLE OF Unretained():
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//
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// class Foo {
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// public:
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// void func() { cout << "Foo:f" << endl; }
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// };
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//
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// // In some function somewhere.
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// Foo foo;
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// Closure foo_callback =
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// Bind(&Foo::func, Unretained(&foo));
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// foo_callback.Run(); // Prints "Foo:f".
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//
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// Without the Unretained() wrapper on |&foo|, the above call would fail
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// to compile because Foo does not support the AddRef() and Release() methods.
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//
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//
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// EXAMPLE OF Owned():
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//
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// void foo(int* arg) { cout << *arg << endl }
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//
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// int* pn = new int(1);
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// Closure foo_callback = Bind(&foo, Owned(pn));
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//
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// foo_callback.Run(); // Prints "1"
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// foo_callback.Run(); // Prints "1"
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// *n = 2;
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// foo_callback.Run(); // Prints "2"
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//
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// foo_callback.Reset(); // |pn| is deleted. Also will happen when
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// // |foo_callback| goes out of scope.
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//
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// Without Owned(), someone would have to know to delete |pn| when the last
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// reference to the Callback is deleted.
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//
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// EXAMPLE OF RetainedRef():
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//
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// void foo(RefCountedBytes* bytes) {}
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//
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// scoped_refptr<RefCountedBytes> bytes = ...;
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// Closure callback = Bind(&foo, base::RetainedRef(bytes));
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// callback.Run();
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//
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// Without RetainedRef, the scoped_refptr would try to implicitly convert to
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// a raw pointer and fail compilation:
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//
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// Closure callback = Bind(&foo, bytes); // ERROR!
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//
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//
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// EXAMPLE OF ConstRef():
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//
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// void foo(int arg) { cout << arg << endl }
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//
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// int n = 1;
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// Closure no_ref = Bind(&foo, n);
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// Closure has_ref = Bind(&foo, ConstRef(n));
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//
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// no_ref.Run(); // Prints "1"
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// has_ref.Run(); // Prints "1"
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//
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// n = 2;
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// no_ref.Run(); // Prints "1"
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// has_ref.Run(); // Prints "2"
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//
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// Note that because ConstRef() takes a reference on |n|, |n| must outlive all
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// its bound callbacks.
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//
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//
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// EXAMPLE OF IgnoreResult():
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//
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// int DoSomething(int arg) { cout << arg << endl; }
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//
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// // Assign to a Callback with a void return type.
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// Callback<void(int)> cb = Bind(IgnoreResult(&DoSomething));
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// cb->Run(1); // Prints "1".
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//
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// // Prints "1" on |ml|.
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// ml->PostTask(FROM_HERE, Bind(IgnoreResult(&DoSomething), 1);
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//
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//
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// EXAMPLE OF Passed():
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//
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// void TakesOwnership(std::unique_ptr<Foo> arg) { }
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// std::unique_ptr<Foo> CreateFoo() { return std::unique_ptr<Foo>(new Foo());
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// }
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//
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// std::unique_ptr<Foo> f(new Foo());
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//
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// // |cb| is given ownership of Foo(). |f| is now NULL.
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// // You can use std::move(f) in place of &f, but it's more verbose.
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// Closure cb = Bind(&TakesOwnership, Passed(&f));
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//
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// // Run was never called so |cb| still owns Foo() and deletes
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// // it on Reset().
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// cb.Reset();
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//
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// // |cb| is given a new Foo created by CreateFoo().
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// cb = Bind(&TakesOwnership, Passed(CreateFoo()));
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//
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// // |arg| in TakesOwnership() is given ownership of Foo(). |cb|
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// // no longer owns Foo() and, if reset, would not delete Foo().
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// cb.Run(); // Foo() is now transferred to |arg| and deleted.
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// cb.Run(); // This CHECK()s since Foo() already been used once.
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//
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// Passed() is particularly useful with PostTask() when you are transferring
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// ownership of an argument into a task, but don't necessarily know if the
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// task will always be executed. This can happen if the task is cancellable
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// or if it is posted to a TaskRunner.
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//
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//
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// SIMPLE FUNCTIONS AND UTILITIES.
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//
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// DoNothing() - Useful for creating a Closure that does nothing when called.
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// DeletePointer<T>() - Useful for creating a Closure that will delete a
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// pointer when invoked. Only use this when necessary.
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// In most cases MessageLoop::DeleteSoon() is a better
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// fit.
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#ifndef BASE_BIND_HELPERS_H_
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#define BASE_BIND_HELPERS_H_
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#include <stddef.h>
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#include <type_traits>
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#include <utility>
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#include "base/callback.h"
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#include "base/memory/weak_ptr.h"
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#include "build/build_config.h"
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namespace base {
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template <typename T>
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struct IsWeakReceiver;
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template <typename>
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struct BindUnwrapTraits;
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namespace internal {
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template <typename Functor, typename SFINAE = void>
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struct FunctorTraits;
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template <typename T>
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class UnretainedWrapper {
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public:
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explicit UnretainedWrapper(T* o) : ptr_(o) {}
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T* get() const { return ptr_; }
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private:
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T* ptr_;
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};
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template <typename T>
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class ConstRefWrapper {
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public:
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explicit ConstRefWrapper(const T& o) : ptr_(&o) {}
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const T& get() const { return *ptr_; }
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private:
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const T* ptr_;
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};
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template <typename T>
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class RetainedRefWrapper {
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public:
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explicit RetainedRefWrapper(T* o) : ptr_(o) {}
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explicit RetainedRefWrapper(scoped_refptr<T> o) : ptr_(std::move(o)) {}
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T* get() const { return ptr_.get(); }
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private:
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scoped_refptr<T> ptr_;
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};
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template <typename T>
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struct IgnoreResultHelper {
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explicit IgnoreResultHelper(T functor) : functor_(std::move(functor)) {}
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explicit operator bool() const { return !!functor_; }
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T functor_;
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};
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// An alternate implementation is to avoid the destructive copy, and instead
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// specialize ParamTraits<> for OwnedWrapper<> to change the StorageType to
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// a class that is essentially a std::unique_ptr<>.
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//
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// The current implementation has the benefit though of leaving ParamTraits<>
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// fully in callback_internal.h as well as avoiding type conversions during
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// storage.
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template <typename T>
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class OwnedWrapper {
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public:
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explicit OwnedWrapper(T* o) : ptr_(o) {}
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~OwnedWrapper() { delete ptr_; }
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T* get() const { return ptr_; }
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OwnedWrapper(OwnedWrapper&& other) {
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ptr_ = other.ptr_;
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other.ptr_ = NULL;
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}
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private:
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mutable T* ptr_;
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};
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// PassedWrapper is a copyable adapter for a scoper that ignores const.
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//
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// It is needed to get around the fact that Bind() takes a const reference to
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// all its arguments. Because Bind() takes a const reference to avoid
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// unnecessary copies, it is incompatible with movable-but-not-copyable
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// types; doing a destructive "move" of the type into Bind() would violate
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// the const correctness.
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//
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// This conundrum cannot be solved without either C++11 rvalue references or
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// a O(2^n) blowup of Bind() templates to handle each combination of regular
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// types and movable-but-not-copyable types. Thus we introduce a wrapper type
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// that is copyable to transmit the correct type information down into
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// BindState<>. Ignoring const in this type makes sense because it is only
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// created when we are explicitly trying to do a destructive move.
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//
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// Two notes:
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// 1) PassedWrapper supports any type that has a move constructor, however
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// the type will need to be specifically whitelisted in order for it to be
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// bound to a Callback. We guard this explicitly at the call of Passed()
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// to make for clear errors. Things not given to Passed() will be forwarded
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// and stored by value which will not work for general move-only types.
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// 2) is_valid_ is distinct from NULL because it is valid to bind a "NULL"
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// scoper to a Callback and allow the Callback to execute once.
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template <typename T>
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class PassedWrapper {
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public:
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explicit PassedWrapper(T&& scoper)
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: is_valid_(true), scoper_(std::move(scoper)) {}
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PassedWrapper(PassedWrapper&& other)
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: is_valid_(other.is_valid_), scoper_(std::move(other.scoper_)) {}
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T Take() const {
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CHECK(is_valid_);
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is_valid_ = false;
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return std::move(scoper_);
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}
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private:
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mutable bool is_valid_;
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mutable T scoper_;
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};
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template <typename T>
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using Unwrapper = BindUnwrapTraits<std::decay_t<T>>;
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template <typename T>
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auto Unwrap(T&& o) -> decltype(Unwrapper<T>::Unwrap(std::forward<T>(o))) {
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return Unwrapper<T>::Unwrap(std::forward<T>(o));
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}
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// IsWeakMethod is a helper that determine if we are binding a WeakPtr<> to a
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// method. It is used internally by Bind() to select the correct
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// InvokeHelper that will no-op itself in the event the WeakPtr<> for
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// the target object is invalidated.
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//
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// The first argument should be the type of the object that will be received by
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// the method.
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template <bool is_method, typename... Args>
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struct IsWeakMethod : std::false_type {};
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template <typename T, typename... Args>
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struct IsWeakMethod<true, T, Args...> : IsWeakReceiver<T> {};
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// Packs a list of types to hold them in a single type.
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template <typename... Types>
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struct TypeList {};
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// Used for DropTypeListItem implementation.
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template <size_t n, typename List>
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struct DropTypeListItemImpl;
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// Do not use enable_if and SFINAE here to avoid MSVC2013 compile failure.
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template <size_t n, typename T, typename... List>
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struct DropTypeListItemImpl<n, TypeList<T, List...>>
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: DropTypeListItemImpl<n - 1, TypeList<List...>> {};
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template <typename T, typename... List>
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struct DropTypeListItemImpl<0, TypeList<T, List...>> {
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using Type = TypeList<T, List...>;
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};
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template <>
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struct DropTypeListItemImpl<0, TypeList<>> {
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using Type = TypeList<>;
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};
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// A type-level function that drops |n| list item from given TypeList.
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template <size_t n, typename List>
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using DropTypeListItem = typename DropTypeListItemImpl<n, List>::Type;
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// Used for TakeTypeListItem implementation.
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template <size_t n, typename List, typename... Accum>
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struct TakeTypeListItemImpl;
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// Do not use enable_if and SFINAE here to avoid MSVC2013 compile failure.
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template <size_t n, typename T, typename... List, typename... Accum>
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struct TakeTypeListItemImpl<n, TypeList<T, List...>, Accum...>
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: TakeTypeListItemImpl<n - 1, TypeList<List...>, Accum..., T> {};
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template <typename T, typename... List, typename... Accum>
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struct TakeTypeListItemImpl<0, TypeList<T, List...>, Accum...> {
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using Type = TypeList<Accum...>;
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};
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template <typename... Accum>
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struct TakeTypeListItemImpl<0, TypeList<>, Accum...> {
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using Type = TypeList<Accum...>;
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};
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// A type-level function that takes first |n| list item from given TypeList.
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// E.g. TakeTypeListItem<3, TypeList<A, B, C, D>> is evaluated to
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// TypeList<A, B, C>.
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template <size_t n, typename List>
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using TakeTypeListItem = typename TakeTypeListItemImpl<n, List>::Type;
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// Used for ConcatTypeLists implementation.
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template <typename List1, typename List2>
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struct ConcatTypeListsImpl;
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template <typename... Types1, typename... Types2>
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struct ConcatTypeListsImpl<TypeList<Types1...>, TypeList<Types2...>> {
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using Type = TypeList<Types1..., Types2...>;
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};
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// A type-level function that concats two TypeLists.
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template <typename List1, typename List2>
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using ConcatTypeLists = typename ConcatTypeListsImpl<List1, List2>::Type;
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// Used for MakeFunctionType implementation.
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template <typename R, typename ArgList>
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struct MakeFunctionTypeImpl;
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template <typename R, typename... Args>
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struct MakeFunctionTypeImpl<R, TypeList<Args...>> {
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// MSVC 2013 doesn't support Type Alias of function types.
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// Revisit this after we update it to newer version.
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typedef R Type(Args...);
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};
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// A type-level function that constructs a function type that has |R| as its
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// return type and has TypeLists items as its arguments.
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template <typename R, typename ArgList>
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using MakeFunctionType = typename MakeFunctionTypeImpl<R, ArgList>::Type;
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// Used for ExtractArgs and ExtractReturnType.
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template <typename Signature>
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struct ExtractArgsImpl;
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template <typename R, typename... Args>
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struct ExtractArgsImpl<R(Args...)> {
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using ReturnType = R;
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using ArgsList = TypeList<Args...>;
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};
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// A type-level function that extracts function arguments into a TypeList.
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// E.g. ExtractArgs<R(A, B, C)> is evaluated to TypeList<A, B, C>.
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template <typename Signature>
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using ExtractArgs = typename ExtractArgsImpl<Signature>::ArgsList;
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// A type-level function that extracts the return type of a function.
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// E.g. ExtractReturnType<R(A, B, C)> is evaluated to R.
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template <typename Signature>
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using ExtractReturnType = typename ExtractArgsImpl<Signature>::ReturnType;
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} // namespace internal
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template <typename T>
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static inline internal::UnretainedWrapper<T> Unretained(T* o) {
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return internal::UnretainedWrapper<T>(o);
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}
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template <typename T>
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static inline internal::RetainedRefWrapper<T> RetainedRef(T* o) {
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return internal::RetainedRefWrapper<T>(o);
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}
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template <typename T>
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static inline internal::RetainedRefWrapper<T> RetainedRef(scoped_refptr<T> o) {
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return internal::RetainedRefWrapper<T>(std::move(o));
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}
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template <typename T>
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static inline internal::ConstRefWrapper<T> ConstRef(const T& o) {
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return internal::ConstRefWrapper<T>(o);
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}
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template <typename T>
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static inline internal::OwnedWrapper<T> Owned(T* o) {
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return internal::OwnedWrapper<T>(o);
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}
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// We offer 2 syntaxes for calling Passed(). The first takes an rvalue and
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// is best suited for use with the return value of a function or other temporary
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// rvalues. The second takes a pointer to the scoper and is just syntactic sugar
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// to avoid having to write Passed(std::move(scoper)).
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//
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// Both versions of Passed() prevent T from being an lvalue reference. The first
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// via use of enable_if, and the second takes a T* which will not bind to T&.
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template <typename T,
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std::enable_if_t<!std::is_lvalue_reference<T>::value>* = nullptr>
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static inline internal::PassedWrapper<T> Passed(T&& scoper) {
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return internal::PassedWrapper<T>(std::move(scoper));
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}
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template <typename T>
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static inline internal::PassedWrapper<T> Passed(T* scoper) {
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return internal::PassedWrapper<T>(std::move(*scoper));
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}
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template <typename T>
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static inline internal::IgnoreResultHelper<T> IgnoreResult(T data) {
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return internal::IgnoreResultHelper<T>(std::move(data));
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}
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BASE_EXPORT void DoNothing();
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template<typename T>
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void DeletePointer(T* obj) {
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delete obj;
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}
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// An injection point to control |this| pointer behavior on a method invocation.
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// If IsWeakReceiver<> is true_type for |T| and |T| is used for a receiver of a
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// method, base::Bind cancels the method invocation if the receiver is tested as
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// false.
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// E.g. Foo::bar() is not called:
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// struct Foo : base::SupportsWeakPtr<Foo> {
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// void bar() {}
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// };
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//
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// WeakPtr<Foo> oo = nullptr;
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// base::Bind(&Foo::bar, oo).Run();
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template <typename T>
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struct IsWeakReceiver : std::false_type {};
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template <typename T>
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struct IsWeakReceiver<internal::ConstRefWrapper<T>> : IsWeakReceiver<T> {};
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template <typename T>
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struct IsWeakReceiver<WeakPtr<T>> : std::true_type {};
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|
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// An injection point to control how bound objects passed to the target
|
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// function. BindUnwrapTraits<>::Unwrap() is called for each bound objects right
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// before the target function is invoked.
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template <typename>
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struct BindUnwrapTraits {
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template <typename T>
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static T&& Unwrap(T&& o) { return std::forward<T>(o); }
|
|
};
|
|
|
|
template <typename T>
|
|
struct BindUnwrapTraits<internal::UnretainedWrapper<T>> {
|
|
static T* Unwrap(const internal::UnretainedWrapper<T>& o) {
|
|
return o.get();
|
|
}
|
|
};
|
|
|
|
template <typename T>
|
|
struct BindUnwrapTraits<internal::ConstRefWrapper<T>> {
|
|
static const T& Unwrap(const internal::ConstRefWrapper<T>& o) {
|
|
return o.get();
|
|
}
|
|
};
|
|
|
|
template <typename T>
|
|
struct BindUnwrapTraits<internal::RetainedRefWrapper<T>> {
|
|
static T* Unwrap(const internal::RetainedRefWrapper<T>& o) {
|
|
return o.get();
|
|
}
|
|
};
|
|
|
|
template <typename T>
|
|
struct BindUnwrapTraits<internal::OwnedWrapper<T>> {
|
|
static T* Unwrap(const internal::OwnedWrapper<T>& o) {
|
|
return o.get();
|
|
}
|
|
};
|
|
|
|
template <typename T>
|
|
struct BindUnwrapTraits<internal::PassedWrapper<T>> {
|
|
static T Unwrap(const internal::PassedWrapper<T>& o) {
|
|
return o.Take();
|
|
}
|
|
};
|
|
|
|
// CallbackCancellationTraits allows customization of Callback's cancellation
|
|
// semantics. By default, callbacks are not cancellable. A specialization should
|
|
// set is_cancellable = true and implement an IsCancelled() that returns if the
|
|
// callback should be cancelled.
|
|
template <typename Functor, typename BoundArgsTuple, typename SFINAE = void>
|
|
struct CallbackCancellationTraits {
|
|
static constexpr bool is_cancellable = false;
|
|
};
|
|
|
|
// Specialization for method bound to weak pointer receiver.
|
|
template <typename Functor, typename... BoundArgs>
|
|
struct CallbackCancellationTraits<
|
|
Functor,
|
|
std::tuple<BoundArgs...>,
|
|
std::enable_if_t<
|
|
internal::IsWeakMethod<internal::FunctorTraits<Functor>::is_method,
|
|
BoundArgs...>::value>> {
|
|
static constexpr bool is_cancellable = true;
|
|
|
|
template <typename Receiver, typename... Args>
|
|
static bool IsCancelled(const Functor&,
|
|
const Receiver& receiver,
|
|
const Args&...) {
|
|
return !receiver;
|
|
}
|
|
};
|
|
|
|
// Specialization for a nested bind.
|
|
template <typename Signature, typename... BoundArgs>
|
|
struct CallbackCancellationTraits<OnceCallback<Signature>,
|
|
std::tuple<BoundArgs...>> {
|
|
static constexpr bool is_cancellable = true;
|
|
|
|
template <typename Functor>
|
|
static bool IsCancelled(const Functor& functor, const BoundArgs&...) {
|
|
return functor.IsCancelled();
|
|
}
|
|
};
|
|
|
|
template <typename Signature, typename... BoundArgs>
|
|
struct CallbackCancellationTraits<RepeatingCallback<Signature>,
|
|
std::tuple<BoundArgs...>> {
|
|
static constexpr bool is_cancellable = true;
|
|
|
|
template <typename Functor>
|
|
static bool IsCancelled(const Functor& functor, const BoundArgs&...) {
|
|
return functor.IsCancelled();
|
|
}
|
|
};
|
|
|
|
} // namespace base
|
|
|
|
#endif // BASE_BIND_HELPERS_H_
|