587 lines
19 KiB
C++
587 lines
19 KiB
C++
// Copyright (c) 2014 Marshall A. Greenblatt. Portions copyright (c) 2011
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// Google Inc. All rights reserved.
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//
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// Redistribution and use in source and binary forms, with or without
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// modification, are permitted provided that the following conditions are
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// met:
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//
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// * Redistributions of source code must retain the above copyright
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// notice, this list of conditions and the following disclaimer.
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// * Redistributions in binary form must reproduce the above
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// copyright notice, this list of conditions and the following disclaimer
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// in the documentation and/or other materials provided with the
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// distribution.
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// * Neither the name of Google Inc. nor the name Chromium Embedded
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// Framework nor the names of its contributors may be used to endorse
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// or promote products derived from this software without specific prior
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// written permission.
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//
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// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
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// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
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// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
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// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
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// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
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// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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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. scoped_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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// 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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//
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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(scoped_ptr<Foo> arg) { }
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// scoped_ptr<Foo> CreateFoo() { return scoped_ptr<Foo>(new Foo()); }
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//
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// scoped_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 f.Pass() 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 MessageLoopProxy.
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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 CEF_INCLUDE_BASE_CEF_BIND_HELPERS_H_
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#define CEF_INCLUDE_BASE_CEF_BIND_HELPERS_H_
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#pragma once
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#if defined(BASE_BIND_HELPERS_H_)
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// Do nothing if the Chromium header has already been included.
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// This can happen in cases where Chromium code is used directly by the
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// client application. When using Chromium code directly always include
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// the Chromium header first to avoid type conflicts.
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#elif defined(USING_CHROMIUM_INCLUDES)
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// When building CEF include the Chromium header directly.
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#include "base/bind_helpers.h"
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#else // !USING_CHROMIUM_INCLUDES
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// The following is substantially similar to the Chromium implementation.
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// If the Chromium implementation diverges the below implementation should be
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// updated to match.
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#include "include/base/cef_basictypes.h"
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#include "include/base/cef_callback.h"
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#include "include/base/cef_template_util.h"
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#include "include/base/cef_weak_ptr.h"
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namespace base {
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namespace cef_internal {
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// Use the Substitution Failure Is Not An Error (SFINAE) trick to inspect T
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// for the existence of AddRef() and Release() functions of the correct
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// signature.
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//
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// http://en.wikipedia.org/wiki/Substitution_failure_is_not_an_error
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// http://stackoverflow.com/questions/257288/is-it-possible-to-write-a-c-template-to-check-for-a-functions-existence
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// http://stackoverflow.com/questions/4358584/sfinae-approach-comparison
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// http://stackoverflow.com/questions/1966362/sfinae-to-check-for-inherited-member-functions
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//
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// The last link in particular show the method used below.
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//
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// For SFINAE to work with inherited methods, we need to pull some extra tricks
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// with multiple inheritance. In the more standard formulation, the overloads
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// of Check would be:
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//
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// template <typename C>
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// Yes NotTheCheckWeWant(Helper<&C::TargetFunc>*);
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//
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// template <typename C>
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// No NotTheCheckWeWant(...);
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//
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// static const bool value = sizeof(NotTheCheckWeWant<T>(0)) == sizeof(Yes);
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//
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// The problem here is that template resolution will not match
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// C::TargetFunc if TargetFunc does not exist directly in C. That is, if
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// TargetFunc in inherited from an ancestor, &C::TargetFunc will not match,
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// |value| will be false. This formulation only checks for whether or
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// not TargetFunc exist directly in the class being introspected.
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//
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// To get around this, we play a dirty trick with multiple inheritance.
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// First, We create a class BaseMixin that declares each function that we
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// want to probe for. Then we create a class Base that inherits from both T
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// (the class we wish to probe) and BaseMixin. Note that the function
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// signature in BaseMixin does not need to match the signature of the function
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// we are probing for; thus it's easiest to just use void(void).
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//
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// Now, if TargetFunc exists somewhere in T, then &Base::TargetFunc has an
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// ambiguous resolution between BaseMixin and T. This lets us write the
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// following:
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//
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// template <typename C>
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// No GoodCheck(Helper<&C::TargetFunc>*);
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//
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// template <typename C>
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// Yes GoodCheck(...);
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//
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// static const bool value = sizeof(GoodCheck<Base>(0)) == sizeof(Yes);
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//
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// Notice here that the variadic version of GoodCheck() returns Yes here
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// instead of No like the previous one. Also notice that we calculate |value|
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// by specializing GoodCheck() on Base instead of T.
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//
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// We've reversed the roles of the variadic, and Helper overloads.
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// GoodCheck(Helper<&C::TargetFunc>*), when C = Base, fails to be a valid
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// substitution if T::TargetFunc exists. Thus GoodCheck<Base>(0) will resolve
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// to the variadic version if T has TargetFunc. If T::TargetFunc does not
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// exist, then &C::TargetFunc is not ambiguous, and the overload resolution
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// will prefer GoodCheck(Helper<&C::TargetFunc>*).
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//
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// This method of SFINAE will correctly probe for inherited names, but it cannot
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// typecheck those names. It's still a good enough sanity check though.
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//
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// Works on gcc-4.2, gcc-4.4, and Visual Studio 2008.
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//
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// TODO(ajwong): Move to ref_counted.h or template_util.h when we've vetted
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// this works well.
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//
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// TODO(ajwong): Make this check for Release() as well.
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// See http://crbug.com/82038.
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template <typename T>
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class SupportsAddRefAndRelease {
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typedef char Yes[1];
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typedef char No[2];
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struct BaseMixin {
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void AddRef();
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};
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// MSVC warns when you try to use Base if T has a private destructor, the
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// common pattern for refcounted types. It does this even though no attempt to
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// instantiate Base is made. We disable the warning for this definition.
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#if defined(OS_WIN)
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#pragma warning(push)
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#pragma warning(disable:4624)
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#endif
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struct Base : public T, public BaseMixin {
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};
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#if defined(OS_WIN)
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#pragma warning(pop)
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#endif
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template <void(BaseMixin::*)(void)> struct Helper {};
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template <typename C>
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static No& Check(Helper<&C::AddRef>*);
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template <typename >
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static Yes& Check(...);
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public:
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static const bool value = sizeof(Check<Base>(0)) == sizeof(Yes);
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};
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// Helpers to assert that arguments of a recounted type are bound with a
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// scoped_refptr.
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template <bool IsClasstype, typename T>
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struct UnsafeBindtoRefCountedArgHelper : false_type {
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};
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template <typename T>
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struct UnsafeBindtoRefCountedArgHelper<true, T>
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: integral_constant<bool, SupportsAddRefAndRelease<T>::value> {
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};
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template <typename T>
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struct UnsafeBindtoRefCountedArg : false_type {
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};
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template <typename T>
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struct UnsafeBindtoRefCountedArg<T*>
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: UnsafeBindtoRefCountedArgHelper<is_class<T>::value, T> {
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};
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template <typename T>
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class HasIsMethodTag {
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typedef char Yes[1];
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typedef char No[2];
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template <typename U>
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static Yes& Check(typename U::IsMethod*);
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template <typename U>
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static No& Check(...);
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public:
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static const bool value = sizeof(Check<T>(0)) == sizeof(Yes);
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};
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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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struct IgnoreResultHelper {
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explicit IgnoreResultHelper(T functor) : functor_(functor) {}
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T functor_;
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};
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template <typename T>
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struct IgnoreResultHelper<Callback<T> > {
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explicit IgnoreResultHelper(const Callback<T>& functor) : functor_(functor) {}
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const Callback<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 scoped_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(const 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 "Pass()" function.
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// This is intentional. The whitelisting of which specific types we
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// support is maintained by CallbackParamTraits<>.
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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) : is_valid_(true), scoper_(scoper.Pass()) {}
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PassedWrapper(const PassedWrapper& other)
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: is_valid_(other.is_valid_), scoper_(other.scoper_.Pass()) {
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}
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T Pass() const {
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CHECK(is_valid_);
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is_valid_ = false;
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return scoper_.Pass();
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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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// Unwrap the stored parameters for the wrappers above.
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template <typename T>
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struct UnwrapTraits {
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typedef const T& ForwardType;
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static ForwardType Unwrap(const T& o) { return o; }
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};
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template <typename T>
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struct UnwrapTraits<UnretainedWrapper<T> > {
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typedef T* ForwardType;
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static ForwardType Unwrap(UnretainedWrapper<T> unretained) {
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return unretained.get();
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}
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};
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template <typename T>
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struct UnwrapTraits<ConstRefWrapper<T> > {
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typedef const T& ForwardType;
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static ForwardType Unwrap(ConstRefWrapper<T> const_ref) {
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return const_ref.get();
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}
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};
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template <typename T>
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struct UnwrapTraits<scoped_refptr<T> > {
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typedef T* ForwardType;
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static ForwardType Unwrap(const scoped_refptr<T>& o) { return o.get(); }
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};
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template <typename T>
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struct UnwrapTraits<WeakPtr<T> > {
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typedef const WeakPtr<T>& ForwardType;
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static ForwardType Unwrap(const WeakPtr<T>& o) { return o; }
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};
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template <typename T>
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struct UnwrapTraits<OwnedWrapper<T> > {
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typedef T* ForwardType;
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static ForwardType Unwrap(const OwnedWrapper<T>& o) {
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return o.get();
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}
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};
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template <typename T>
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struct UnwrapTraits<PassedWrapper<T> > {
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typedef T ForwardType;
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static T Unwrap(PassedWrapper<T>& o) {
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return o.Pass();
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}
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};
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// Utility for handling different refcounting semantics in the Bind()
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// function.
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template <bool is_method, typename T>
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struct MaybeRefcount;
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template <typename T>
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struct MaybeRefcount<false, T> {
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static void AddRef(const T&) {}
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static void Release(const T&) {}
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};
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template <typename T, size_t n>
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struct MaybeRefcount<false, T[n]> {
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static void AddRef(const T*) {}
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static void Release(const T*) {}
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|
};
|
|
|
|
template <typename T>
|
|
struct MaybeRefcount<true, T> {
|
|
static void AddRef(const T&) {}
|
|
static void Release(const T&) {}
|
|
};
|
|
|
|
template <typename T>
|
|
struct MaybeRefcount<true, T*> {
|
|
static void AddRef(T* o) { o->AddRef(); }
|
|
static void Release(T* o) { o->Release(); }
|
|
};
|
|
|
|
// No need to additionally AddRef() and Release() since we are storing a
|
|
// scoped_refptr<> inside the storage object already.
|
|
template <typename T>
|
|
struct MaybeRefcount<true, scoped_refptr<T> > {
|
|
static void AddRef(const scoped_refptr<T>& o) {}
|
|
static void Release(const scoped_refptr<T>& o) {}
|
|
};
|
|
|
|
template <typename T>
|
|
struct MaybeRefcount<true, const T*> {
|
|
static void AddRef(const T* o) { o->AddRef(); }
|
|
static void Release(const T* o) { o->Release(); }
|
|
};
|
|
|
|
// IsWeakMethod is a helper that determine if we are binding a WeakPtr<> to a
|
|
// method. It is used internally by Bind() to select the correct
|
|
// InvokeHelper that will no-op itself in the event the WeakPtr<> for
|
|
// the target object is invalidated.
|
|
//
|
|
// P1 should be the type of the object that will be received of the method.
|
|
template <bool IsMethod, typename P1>
|
|
struct IsWeakMethod : public false_type {};
|
|
|
|
template <typename T>
|
|
struct IsWeakMethod<true, WeakPtr<T> > : public true_type {};
|
|
|
|
template <typename T>
|
|
struct IsWeakMethod<true, ConstRefWrapper<WeakPtr<T> > > : public true_type {};
|
|
|
|
} // namespace cef_internal
|
|
|
|
template <typename T>
|
|
static inline cef_internal::UnretainedWrapper<T> Unretained(T* o) {
|
|
return cef_internal::UnretainedWrapper<T>(o);
|
|
}
|
|
|
|
template <typename T>
|
|
static inline cef_internal::ConstRefWrapper<T> ConstRef(const T& o) {
|
|
return cef_internal::ConstRefWrapper<T>(o);
|
|
}
|
|
|
|
template <typename T>
|
|
static inline cef_internal::OwnedWrapper<T> Owned(T* o) {
|
|
return cef_internal::OwnedWrapper<T>(o);
|
|
}
|
|
|
|
// We offer 2 syntaxes for calling Passed(). The first takes a temporary and
|
|
// is best suited for use with the return value of a function. The second
|
|
// takes a pointer to the scoper and is just syntactic sugar to avoid having
|
|
// to write Passed(scoper.Pass()).
|
|
template <typename T>
|
|
static inline cef_internal::PassedWrapper<T> Passed(T scoper) {
|
|
return cef_internal::PassedWrapper<T>(scoper.Pass());
|
|
}
|
|
template <typename T>
|
|
static inline cef_internal::PassedWrapper<T> Passed(T* scoper) {
|
|
return cef_internal::PassedWrapper<T>(scoper->Pass());
|
|
}
|
|
|
|
template <typename T>
|
|
static inline cef_internal::IgnoreResultHelper<T> IgnoreResult(T data) {
|
|
return cef_internal::IgnoreResultHelper<T>(data);
|
|
}
|
|
|
|
template <typename T>
|
|
static inline cef_internal::IgnoreResultHelper<Callback<T> >
|
|
IgnoreResult(const Callback<T>& data) {
|
|
return cef_internal::IgnoreResultHelper<Callback<T> >(data);
|
|
}
|
|
|
|
void DoNothing();
|
|
|
|
template<typename T>
|
|
void DeletePointer(T* obj) {
|
|
delete obj;
|
|
}
|
|
|
|
} // namespace base
|
|
|
|
#endif // !USING_CHROMIUM_INCLUDES
|
|
|
|
#endif // CEF_INCLUDE_BASE_CEF_BIND_HELPERS_H_
|