base/bind.h - gn - Git at Google

 // Copyright (c) 2011 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef BASE_BIND_H_
 #define BASE_BIND_H_

 #include <utility>

 #include "base/bind_internal.h"

 // -----------------------------------------------------------------------------
 // Usage documentation
 // -----------------------------------------------------------------------------
 //
 // Overview:
 // base::BindOnce() and base::BindRepeating() are helpers for creating
 // base::OnceCallback and base::RepeatingCallback objects respectively.
 //
 // For a runnable object of n-arity, the base::Bind*() family allows partial
 // application of the first m arguments. The remaining n - m arguments must be
 // passed when invoking the callback with Run().
 //
 //   // The first argument is bound at callback creation; the remaining
 //   // two must be passed when calling Run() on the callback object.
 //   base::OnceCallback<void(int, long)> cb = base::BindOnce(
 //       [](short x, int y, long z) { return x * y * z; }, 42);
 //
 // When binding to a method, the receiver object must also be specified at
 // callback creation time. When Run() is invoked, the method will be invoked on
 // the specified receiver object.
 //
 //   class C : public base::RefCounted<C> { void F(); };
 //   auto instance = base::MakeRefCounted<C>();
 //   auto cb = base::BindOnce(&C::F, instance);
 //   cb.Run();  // Identical to instance->F()
 //
 // base::Bind is currently a type alias for base::BindRepeating(). In the
 // future, we expect to flip this to default to base::BindOnce().
 //
 // See //docs/callback.md for the full documentation.
 //
 // -----------------------------------------------------------------------------
 // Implementation notes
 // -----------------------------------------------------------------------------
 //
 // If you're reading the implementation, before proceeding further, you should
 // read the top comment of base/bind_internal.h for a definition of common
 // terms and concepts.

 namespace base {

 namespace internal {

 // IsOnceCallback<T> is a std::true_type if |T| is a OnceCallback.
 template <typename T>
 struct IsOnceCallback : std::false_type {};

 template <typename Signature>
 struct IsOnceCallback<OnceCallback<Signature>> : std::true_type {};

 // Helper to assert that parameter |i| of type |Arg| can be bound, which means:
 // - |Arg| can be retained internally as |Storage|.
 // - |Arg| can be forwarded as |Unwrapped| to |Param|.
 template <size_t i,
           typename Arg,
           typename Storage,
           typename Unwrapped,
           typename Param>
 struct AssertConstructible {
  private:
   static constexpr bool param_is_forwardable =
       std::is_constructible<Param, Unwrapped>::value;
   // Unlike the check for binding into storage below, the check for
   // forwardability drops the const qualifier for repeating callbacks. This is
   // to try to catch instances where std::move()--which forwards as a const
   // reference with repeating callbacks--is used instead of base::Passed().
   static_assert(
       param_is_forwardable ||
           !std::is_constructible<Param, std::decay_t<Unwrapped>&&>::value,
       "Bound argument |i| is move-only but will be forwarded by copy. "
       "Ensure |Arg| is bound using base::Passed(), not std::move().");
   static_assert(
       param_is_forwardable,
       "Bound argument |i| of type |Arg| cannot be forwarded as "
       "|Unwrapped| to the bound functor, which declares it as |Param|.");

   static constexpr bool arg_is_storable =
       std::is_constructible<Storage, Arg>::value;
   static_assert(arg_is_storable ||
                     !std::is_constructible<Storage, std::decay_t<Arg>&&>::value,
                 "Bound argument |i| is move-only but will be bound by copy. "
                 "Ensure |Arg| is mutable and bound using std::move().");
   static_assert(arg_is_storable,
                 "Bound argument |i| of type |Arg| cannot be converted and "
                 "bound as |Storage|.");
 };

 // Takes three same-length TypeLists, and applies AssertConstructible for each
 // triples.
 template <typename Index,
           typename Args,
           typename UnwrappedTypeList,
           typename ParamsList>
 struct AssertBindArgsValidity;

 template <size_t... Ns,
           typename... Args,
           typename... Unwrapped,
           typename... Params>
 struct AssertBindArgsValidity<std::index_sequence<Ns...>,
                               TypeList<Args...>,
                               TypeList<Unwrapped...>,
                               TypeList<Params...>>
     : AssertConstructible<Ns, Args, std::decay_t<Args>, Unwrapped, Params>... {
   static constexpr bool ok = true;
 };

 // The implementation of TransformToUnwrappedType below.
 template <bool is_once, typename T>
 struct TransformToUnwrappedTypeImpl;

 template <typename T>
 struct TransformToUnwrappedTypeImpl<true, T> {
   using StoredType = std::decay_t<T>;
   using ForwardType = StoredType&&;
   using Unwrapped = decltype(Unwrap(std::declval<ForwardType>()));
 };

 template <typename T>
 struct TransformToUnwrappedTypeImpl<false, T> {
   using StoredType = std::decay_t<T>;
   using ForwardType = const StoredType&;
   using Unwrapped = decltype(Unwrap(std::declval<ForwardType>()));
 };

 // Transform |T| into `Unwrapped` type, which is passed to the target function.
 // Example:
 //   In is_once == true case,
 //     `int&&` -> `int&&`,
 //     `const int&` -> `int&&`,
 //     `OwnedWrapper<int>&` -> `int*&&`.
 //   In is_once == false case,
 //     `int&&` -> `const int&`,
 //     `const int&` -> `const int&`,
 //     `OwnedWrapper<int>&` -> `int* const &`.
 template <bool is_once, typename T>
 using TransformToUnwrappedType =
     typename TransformToUnwrappedTypeImpl<is_once, T>::Unwrapped;

 // Transforms |Args| into `Unwrapped` types, and packs them into a TypeList.
 // If |is_method| is true, tries to dereference the first argument to support
 // smart pointers.
 template <bool is_once, bool is_method, typename... Args>
 struct MakeUnwrappedTypeListImpl {
   using Type = TypeList<TransformToUnwrappedType<is_once, Args>...>;
 };

 // Performs special handling for this pointers.
 // Example:
 //   int* -> int*,
 //   std::unique_ptr<int> -> int*.
 template <bool is_once, typename Receiver, typename... Args>
 struct MakeUnwrappedTypeListImpl<is_once, true, Receiver, Args...> {
   using UnwrappedReceiver = TransformToUnwrappedType<is_once, Receiver>;
   using Type = TypeList<decltype(&*std::declval<UnwrappedReceiver>()),
                         TransformToUnwrappedType<is_once, Args>...>;
 };

 template <bool is_once, bool is_method, typename... Args>
 using MakeUnwrappedTypeList =
     typename MakeUnwrappedTypeListImpl<is_once, is_method, Args...>::Type;

 }  // namespace internal

 // Bind as OnceCallback.
 template <typename Functor, typename... Args>
 inline OnceCallback<MakeUnboundRunType<Functor, Args...>> BindOnce(
     Functor&& functor,
     Args&&... args) {
   static_assert(!internal::IsOnceCallback<std::decay_t<Functor>>() ||
                     (std::is_rvalue_reference<Functor&&>() &&
                      !std::is_const<std::remove_reference_t<Functor>>()),
                 "BindOnce requires non-const rvalue for OnceCallback binding."
                 " I.e.: base::BindOnce(std::move(callback)).");

   // This block checks if each |args| matches to the corresponding params of the
   // target function. This check does not affect the behavior of Bind, but its
   // error message should be more readable.
   using Helper = internal::BindTypeHelper<Functor, Args...>;
   using FunctorTraits = typename Helper::FunctorTraits;
   using BoundArgsList = typename Helper::BoundArgsList;
   using UnwrappedArgsList =
       internal::MakeUnwrappedTypeList<true, FunctorTraits::is_method,
                                       Args&&...>;
   using BoundParamsList = typename Helper::BoundParamsList;
   static_assert(internal::AssertBindArgsValidity<
                     std::make_index_sequence<Helper::num_bounds>, BoundArgsList,
                     UnwrappedArgsList, BoundParamsList>::ok,
                 "The bound args need to be convertible to the target params.");

   using BindState = internal::MakeBindStateType<Functor, Args...>;
   using UnboundRunType = MakeUnboundRunType<Functor, Args...>;
   using Invoker = internal::Invoker<BindState, UnboundRunType>;
   using CallbackType = OnceCallback<UnboundRunType>;

   // Store the invoke func into PolymorphicInvoke before casting it to
   // InvokeFuncStorage, so that we can ensure its type matches to
   // PolymorphicInvoke, to which CallbackType will cast back.
   using PolymorphicInvoke = typename CallbackType::PolymorphicInvoke;
   PolymorphicInvoke invoke_func = &Invoker::RunOnce;

   using InvokeFuncStorage = internal::BindStateBase::InvokeFuncStorage;
   return CallbackType(new BindState(
       reinterpret_cast<InvokeFuncStorage>(invoke_func),
       std::forward<Functor>(functor), std::forward<Args>(args)...));
 }

 // Bind as RepeatingCallback.
 template <typename Functor, typename... Args>
 inline RepeatingCallback<MakeUnboundRunType<Functor, Args...>> BindRepeating(
     Functor&& functor,
     Args&&... args) {
   static_assert(
       !internal::IsOnceCallback<std::decay_t<Functor>>(),
       "BindRepeating cannot bind OnceCallback. Use BindOnce with std::move().");

   // This block checks if each |args| matches to the corresponding params of the
   // target function. This check does not affect the behavior of Bind, but its
   // error message should be more readable.
   using Helper = internal::BindTypeHelper<Functor, Args...>;
   using FunctorTraits = typename Helper::FunctorTraits;
   using BoundArgsList = typename Helper::BoundArgsList;
   using UnwrappedArgsList =
       internal::MakeUnwrappedTypeList<false, FunctorTraits::is_method,
                                       Args&&...>;
   using BoundParamsList = typename Helper::BoundParamsList;
   static_assert(internal::AssertBindArgsValidity<
                     std::make_index_sequence<Helper::num_bounds>, BoundArgsList,
                     UnwrappedArgsList, BoundParamsList>::ok,
                 "The bound args need to be convertible to the target params.");

   using BindState = internal::MakeBindStateType<Functor, Args...>;
   using UnboundRunType = MakeUnboundRunType<Functor, Args...>;
   using Invoker = internal::Invoker<BindState, UnboundRunType>;
   using CallbackType = RepeatingCallback<UnboundRunType>;

   // Store the invoke func into PolymorphicInvoke before casting it to
   // InvokeFuncStorage, so that we can ensure its type matches to
   // PolymorphicInvoke, to which CallbackType will cast back.
   using PolymorphicInvoke = typename CallbackType::PolymorphicInvoke;
   PolymorphicInvoke invoke_func = &Invoker::Run;

   using InvokeFuncStorage = internal::BindStateBase::InvokeFuncStorage;
   return CallbackType(new BindState(
       reinterpret_cast<InvokeFuncStorage>(invoke_func),
       std::forward<Functor>(functor), std::forward<Args>(args)...));
 }

 // Unannotated Bind.
 // TODO(tzik): Deprecate this and migrate to OnceCallback and
 // RepeatingCallback, once they get ready.
 template <typename Functor, typename... Args>
 inline Callback<MakeUnboundRunType<Functor, Args...>> Bind(Functor&& functor,
                                                            Args&&... args) {
   return base::BindRepeating(std::forward<Functor>(functor),
                              std::forward<Args>(args)...);
 }

 // Special cases for binding to a base::Callback without extra bound arguments.
 template <typename Signature>
 OnceCallback<Signature> BindOnce(OnceCallback<Signature> closure) {
   return closure;
 }

 template <typename Signature>
 RepeatingCallback<Signature> BindRepeating(
     RepeatingCallback<Signature> closure) {
   return closure;
 }

 template <typename Signature>
 Callback<Signature> Bind(Callback<Signature> closure) {
   return closure;
 }

 // Unretained() allows Bind() to bind a non-refcounted class, and to disable
 // refcounting on arguments that are refcounted objects.
 //
 // EXAMPLE OF Unretained():
 //
 //   class Foo {
 //    public:
 //     void func() { cout << "Foo:f" << endl; }
 //   };
 //
 //   // In some function somewhere.
 //   Foo foo;
 //   Closure foo_callback =
 //       Bind(&Foo::func, Unretained(&foo));
 //   foo_callback.Run();  // Prints "Foo:f".
 //
 // Without the Unretained() wrapper on |&foo|, the above call would fail
 // to compile because Foo does not support the AddRef() and Release() methods.
 template <typename T>
 static inline internal::UnretainedWrapper<T> Unretained(T* o) {
   return internal::UnretainedWrapper<T>(o);
 }

 // RetainedRef() accepts a ref counted object and retains a reference to it.
 // When the callback is called, the object is passed as a raw pointer.
 //
 // EXAMPLE OF RetainedRef():
 //
 //    void foo(RefCountedBytes* bytes) {}
 //
 //    scoped_refptr<RefCountedBytes> bytes = ...;
 //    Closure callback = Bind(&foo, base::RetainedRef(bytes));
 //    callback.Run();
 //
 // Without RetainedRef, the scoped_refptr would try to implicitly convert to
 // a raw pointer and fail compilation:
 //
 //    Closure callback = Bind(&foo, bytes); // ERROR!
 template <typename T>
 static inline internal::RetainedRefWrapper<T> RetainedRef(T* o) {
   return internal::RetainedRefWrapper<T>(o);
 }
 template <typename T>
 static inline internal::RetainedRefWrapper<T> RetainedRef(scoped_refptr<T> o) {
   return internal::RetainedRefWrapper<T>(std::move(o));
 }

 // ConstRef() allows binding a constant reference to an argument rather
 // than a copy.
 //
 // EXAMPLE OF ConstRef():
 //
 //   void foo(int arg) { cout << arg << endl }
 //
 //   int n = 1;
 //   Closure no_ref = Bind(&foo, n);
 //   Closure has_ref = Bind(&foo, ConstRef(n));
 //
 //   no_ref.Run();  // Prints "1"
 //   has_ref.Run();  // Prints "1"
 //
 //   n = 2;
 //   no_ref.Run();  // Prints "1"
 //   has_ref.Run();  // Prints "2"
 //
 // Note that because ConstRef() takes a reference on |n|, |n| must outlive all
 // its bound callbacks.
 template <typename T>
 static inline internal::ConstRefWrapper<T> ConstRef(const T& o) {
   return internal::ConstRefWrapper<T>(o);
 }

 // Owned() transfers ownership of an object to the Callback resulting from
 // bind; the object will be deleted when the Callback is deleted.
 //
 // EXAMPLE OF Owned():
 //
 //   void foo(int* arg) { cout << *arg << endl }
 //
 //   int* pn = new int(1);
 //   Closure foo_callback = Bind(&foo, Owned(pn));
 //
 //   foo_callback.Run();  // Prints "1"
 //   foo_callback.Run();  // Prints "1"
 //   *n = 2;
 //   foo_callback.Run();  // Prints "2"
 //
 //   foo_callback.Reset();  // |pn| is deleted.  Also will happen when
 //                          // |foo_callback| goes out of scope.
 //
 // Without Owned(), someone would have to know to delete |pn| when the last
 // reference to the Callback is deleted.
 template <typename T>
 static inline internal::OwnedWrapper<T> Owned(T* o) {
   return internal::OwnedWrapper<T>(o);
 }

 // Passed() is for transferring movable-but-not-copyable types (eg. unique_ptr)
 // through a Callback. Logically, this signifies a destructive transfer of
 // the state of the argument into the target function.  Invoking
 // Callback::Run() twice on a Callback that was created with a Passed()
 // argument will CHECK() because the first invocation would have already
 // transferred ownership to the target function.
 //
 // Note that Passed() is not necessary with BindOnce(), as std::move() does the
 // same thing. Avoid Passed() in favor of std::move() with BindOnce().
 //
 // EXAMPLE OF Passed():
 //
 //   void TakesOwnership(std::unique_ptr<Foo> arg) { }
 //   std::unique_ptr<Foo> CreateFoo() { return std::make_unique<Foo>();
 //   }
 //
 //   auto f = std::make_unique<Foo>();
 //
 //   // |cb| is given ownership of Foo(). |f| is now NULL.
 //   // You can use std::move(f) in place of &f, but it's more verbose.
 //   Closure cb = Bind(&TakesOwnership, Passed(&f));
 //
 //   // Run was never called so |cb| still owns Foo() and deletes
 //   // it on Reset().
 //   cb.Reset();
 //
 //   // |cb| is given a new Foo created by CreateFoo().
 //   cb = Bind(&TakesOwnership, Passed(CreateFoo()));
 //
 //   // |arg| in TakesOwnership() is given ownership of Foo(). |cb|
 //   // no longer owns Foo() and, if reset, would not delete Foo().
 //   cb.Run();  // Foo() is now transferred to |arg| and deleted.
 //   cb.Run();  // This CHECK()s since Foo() already been used once.
 //
 // We offer 2 syntaxes for calling Passed().  The first takes an rvalue and
 // is best suited for use with the return value of a function or other temporary
 // rvalues. The second takes a pointer to the scoper and is just syntactic sugar
 // to avoid having to write Passed(std::move(scoper)).
 //
 // Both versions of Passed() prevent T from being an lvalue reference. The first
 // via use of enable_if, and the second takes a T* which will not bind to T&.
 template <typename T,
           std::enable_if_t<!std::is_lvalue_reference<T>::value>* = nullptr>
 static inline internal::PassedWrapper<T> Passed(T&& scoper) {
   return internal::PassedWrapper<T>(std::move(scoper));
 }
 template <typename T>
 static inline internal::PassedWrapper<T> Passed(T* scoper) {
   return internal::PassedWrapper<T>(std::move(*scoper));
 }

 // IgnoreResult() is used to adapt a function or Callback with a return type to
 // one with a void return. This is most useful if you have a function with,
 // say, a pesky ignorable bool return that you want to use with PostTask or
 // something else that expect a Callback with a void return.
 //
 // EXAMPLE OF IgnoreResult():
 //
 //   int DoSomething(int arg) { cout << arg << endl; }
 //
 //   // Assign to a Callback with a void return type.
 //   Callback<void(int)> cb = Bind(IgnoreResult(&DoSomething));
 //   cb->Run(1);  // Prints "1".
 //
 //   // Prints "1" on |ml|.
 //   ml->PostTask(FROM_HERE, Bind(IgnoreResult(&DoSomething), 1);
 template <typename T>
 static inline internal::IgnoreResultHelper<T> IgnoreResult(T data) {
   return internal::IgnoreResultHelper<T>(std::move(data));
 }

 }  // namespace base

 #endif  // BASE_BIND_H_
	// Copyright (c) 2011 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef BASE_BIND_H_
	#define BASE_BIND_H_

	#include <utility>

	#include "base/bind_internal.h"

	// -----------------------------------------------------------------------------
	// Usage documentation
	// -----------------------------------------------------------------------------
	//
	// Overview:
	// base::BindOnce() and base::BindRepeating() are helpers for creating
	// base::OnceCallback and base::RepeatingCallback objects respectively.
	//
	// For a runnable object of n-arity, the base::Bind*() family allows partial
	// application of the first m arguments. The remaining n - m arguments must be
	// passed when invoking the callback with Run().
	//
	// // The first argument is bound at callback creation; the remaining
	// // two must be passed when calling Run() on the callback object.
	// base::OnceCallback<void(int, long)> cb = base::BindOnce(
	// [](short x, int y, long z) { return x * y * z; }, 42);
	//
	// When binding to a method, the receiver object must also be specified at
	// callback creation time. When Run() is invoked, the method will be invoked on
	// the specified receiver object.
	//
	// class C : public base::RefCounted<C> { void F(); };
	// auto instance = base::MakeRefCounted<C>();
	// auto cb = base::BindOnce(&C::F, instance);
	// cb.Run(); // Identical to instance->F()
	//
	// base::Bind is currently a type alias for base::BindRepeating(). In the
	// future, we expect to flip this to default to base::BindOnce().
	//
	// See //docs/callback.md for the full documentation.
	//
	// -----------------------------------------------------------------------------
	// Implementation notes
	// -----------------------------------------------------------------------------
	//
	// If you're reading the implementation, before proceeding further, you should
	// read the top comment of base/bind_internal.h for a definition of common
	// terms and concepts.

	namespace base {

	namespace internal {

	// IsOnceCallback<T> is a std::true_type if \|T\| is a OnceCallback.
	template <typename T>
	struct IsOnceCallback : std::false_type {};

	template <typename Signature>
	struct IsOnceCallback<OnceCallback<Signature>> : std::true_type {};

	// Helper to assert that parameter \|i\| of type \|Arg\| can be bound, which means:
	// - \|Arg\| can be retained internally as \|Storage\|.
	// - \|Arg\| can be forwarded as \|Unwrapped\| to \|Param\|.
	template <size_t i,
	typename Arg,
	typename Storage,
	typename Unwrapped,
	typename Param>
	struct AssertConstructible {
	private:
	static constexpr bool param_is_forwardable =
	std::is_constructible<Param, Unwrapped>::value;
	// Unlike the check for binding into storage below, the check for
	// forwardability drops the const qualifier for repeating callbacks. This is
	// to try to catch instances where std::move()--which forwards as a const
	// reference with repeating callbacks--is used instead of base::Passed().
	static_assert(
	param_is_forwardable \|\|
	!std::is_constructible<Param, std::decay_t<Unwrapped>&&>::value,
	"Bound argument \|i\| is move-only but will be forwarded by copy. "
	"Ensure \|Arg\| is bound using base::Passed(), not std::move().");
	static_assert(
	param_is_forwardable,
	"Bound argument \|i\| of type \|Arg\| cannot be forwarded as "
	"\|Unwrapped\| to the bound functor, which declares it as \|Param\|.");

	static constexpr bool arg_is_storable =
	std::is_constructible<Storage, Arg>::value;
	static_assert(arg_is_storable \|\|
	!std::is_constructible<Storage, std::decay_t<Arg>&&>::value,
	"Bound argument \|i\| is move-only but will be bound by copy. "
	"Ensure \|Arg\| is mutable and bound using std::move().");
	static_assert(arg_is_storable,
	"Bound argument \|i\| of type \|Arg\| cannot be converted and "
	"bound as \|Storage\|.");
	};

	// Takes three same-length TypeLists, and applies AssertConstructible for each
	// triples.
	template <typename Index,
	typename Args,
	typename UnwrappedTypeList,
	typename ParamsList>
	struct AssertBindArgsValidity;

	template <size_t... Ns,
	typename... Args,
	typename... Unwrapped,
	typename... Params>
	struct AssertBindArgsValidity<std::index_sequence<Ns...>,
	TypeList<Args...>,
	TypeList<Unwrapped...>,
	TypeList<Params...>>
	: AssertConstructible<Ns, Args, std::decay_t<Args>, Unwrapped, Params>... {
	static constexpr bool ok = true;
	};

	// The implementation of TransformToUnwrappedType below.
	template <bool is_once, typename T>
	struct TransformToUnwrappedTypeImpl;

	template <typename T>
	struct TransformToUnwrappedTypeImpl<true, T> {
	using StoredType = std::decay_t<T>;
	using ForwardType = StoredType&&;
	using Unwrapped = decltype(Unwrap(std::declval<ForwardType>()));
	};

	template <typename T>
	struct TransformToUnwrappedTypeImpl<false, T> {
	using StoredType = std::decay_t<T>;
	using ForwardType = const StoredType&;
	using Unwrapped = decltype(Unwrap(std::declval<ForwardType>()));
	};

	// Transform \|T\| into `Unwrapped` type, which is passed to the target function.
	// Example:
	// In is_once == true case,
	// `int&&` -> `int&&`,
	// `const int&` -> `int&&`,
	// `OwnedWrapper<int>&` -> `int*&&`.
	// In is_once == false case,
	// `int&&` -> `const int&`,
	// `const int&` -> `const int&`,
	// `OwnedWrapper<int>&` -> `int* const &`.
	template <bool is_once, typename T>
	using TransformToUnwrappedType =
	typename TransformToUnwrappedTypeImpl<is_once, T>::Unwrapped;

	// Transforms \|Args\| into `Unwrapped` types, and packs them into a TypeList.
	// If \|is_method\| is true, tries to dereference the first argument to support
	// smart pointers.
	template <bool is_once, bool is_method, typename... Args>
	struct MakeUnwrappedTypeListImpl {
	using Type = TypeList<TransformToUnwrappedType<is_once, Args>...>;
	};

	// Performs special handling for this pointers.
	// Example:
	// int* -> int*,
	// std::unique_ptr<int> -> int*.
	template <bool is_once, typename Receiver, typename... Args>
	struct MakeUnwrappedTypeListImpl<is_once, true, Receiver, Args...> {
	using UnwrappedReceiver = TransformToUnwrappedType<is_once, Receiver>;
	using Type = TypeList<decltype(&*std::declval<UnwrappedReceiver>()),
	TransformToUnwrappedType<is_once, Args>...>;
	};

	template <bool is_once, bool is_method, typename... Args>
	using MakeUnwrappedTypeList =
	typename MakeUnwrappedTypeListImpl<is_once, is_method, Args...>::Type;

	} // namespace internal

	// Bind as OnceCallback.
	template <typename Functor, typename... Args>
	inline OnceCallback<MakeUnboundRunType<Functor, Args...>> BindOnce(
	Functor&& functor,
	Args&&... args) {
	static_assert(!internal::IsOnceCallback<std::decay_t<Functor>>() \|\|
	(std::is_rvalue_reference<Functor&&>() &&
	!std::is_const<std::remove_reference_t<Functor>>()),
	"BindOnce requires non-const rvalue for OnceCallback binding."
	" I.e.: base::BindOnce(std::move(callback)).");

	// This block checks if each \|args\| matches to the corresponding params of the
	// target function. This check does not affect the behavior of Bind, but its
	// error message should be more readable.
	using Helper = internal::BindTypeHelper<Functor, Args...>;
	using FunctorTraits = typename Helper::FunctorTraits;
	using BoundArgsList = typename Helper::BoundArgsList;
	using UnwrappedArgsList =
	internal::MakeUnwrappedTypeList<true, FunctorTraits::is_method,
	Args&&...>;
	using BoundParamsList = typename Helper::BoundParamsList;
	static_assert(internal::AssertBindArgsValidity<
	std::make_index_sequence<Helper::num_bounds>, BoundArgsList,
	UnwrappedArgsList, BoundParamsList>::ok,
	"The bound args need to be convertible to the target params.");

	using BindState = internal::MakeBindStateType<Functor, Args...>;
	using UnboundRunType = MakeUnboundRunType<Functor, Args...>;
	using Invoker = internal::Invoker<BindState, UnboundRunType>;
	using CallbackType = OnceCallback<UnboundRunType>;

	// Store the invoke func into PolymorphicInvoke before casting it to
	// InvokeFuncStorage, so that we can ensure its type matches to
	// PolymorphicInvoke, to which CallbackType will cast back.
	using PolymorphicInvoke = typename CallbackType::PolymorphicInvoke;
	PolymorphicInvoke invoke_func = &Invoker::RunOnce;

	using InvokeFuncStorage = internal::BindStateBase::InvokeFuncStorage;
	return CallbackType(new BindState(
	reinterpret_cast<InvokeFuncStorage>(invoke_func),
	std::forward<Functor>(functor), std::forward<Args>(args)...));
	}

	// Bind as RepeatingCallback.
	template <typename Functor, typename... Args>
	inline RepeatingCallback<MakeUnboundRunType<Functor, Args...>> BindRepeating(
	Functor&& functor,
	Args&&... args) {
	static_assert(
	!internal::IsOnceCallback<std::decay_t<Functor>>(),
	"BindRepeating cannot bind OnceCallback. Use BindOnce with std::move().");

	// This block checks if each \|args\| matches to the corresponding params of the
	// target function. This check does not affect the behavior of Bind, but its
	// error message should be more readable.
	using Helper = internal::BindTypeHelper<Functor, Args...>;
	using FunctorTraits = typename Helper::FunctorTraits;
	using BoundArgsList = typename Helper::BoundArgsList;
	using UnwrappedArgsList =
	internal::MakeUnwrappedTypeList<false, FunctorTraits::is_method,
	Args&&...>;
	using BoundParamsList = typename Helper::BoundParamsList;
	static_assert(internal::AssertBindArgsValidity<
	std::make_index_sequence<Helper::num_bounds>, BoundArgsList,
	UnwrappedArgsList, BoundParamsList>::ok,
	"The bound args need to be convertible to the target params.");

	using BindState = internal::MakeBindStateType<Functor, Args...>;
	using UnboundRunType = MakeUnboundRunType<Functor, Args...>;
	using Invoker = internal::Invoker<BindState, UnboundRunType>;
	using CallbackType = RepeatingCallback<UnboundRunType>;

	// Store the invoke func into PolymorphicInvoke before casting it to
	// InvokeFuncStorage, so that we can ensure its type matches to
	// PolymorphicInvoke, to which CallbackType will cast back.
	using PolymorphicInvoke = typename CallbackType::PolymorphicInvoke;
	PolymorphicInvoke invoke_func = &Invoker::Run;

	using InvokeFuncStorage = internal::BindStateBase::InvokeFuncStorage;
	return CallbackType(new BindState(
	reinterpret_cast<InvokeFuncStorage>(invoke_func),
	std::forward<Functor>(functor), std::forward<Args>(args)...));
	}

	// Unannotated Bind.
	// TODO(tzik): Deprecate this and migrate to OnceCallback and
	// RepeatingCallback, once they get ready.
	template <typename Functor, typename... Args>
	inline Callback<MakeUnboundRunType<Functor, Args...>> Bind(Functor&& functor,
	Args&&... args) {
	return base::BindRepeating(std::forward<Functor>(functor),
	std::forward<Args>(args)...);
	}

	// Special cases for binding to a base::Callback without extra bound arguments.
	template <typename Signature>
	OnceCallback<Signature> BindOnce(OnceCallback<Signature> closure) {
	return closure;
	}

	template <typename Signature>
	RepeatingCallback<Signature> BindRepeating(
	RepeatingCallback<Signature> closure) {
	return closure;
	}

	template <typename Signature>
	Callback<Signature> Bind(Callback<Signature> closure) {
	return closure;
	}

	// Unretained() allows Bind() to bind a non-refcounted class, and to disable
	// refcounting on arguments that are refcounted objects.
	//
	// EXAMPLE OF Unretained():
	//
	// class Foo {
	// public:
	// void func() { cout << "Foo:f" << endl; }
	// };
	//
	// // In some function somewhere.
	// Foo foo;
	// Closure foo_callback =
	// Bind(&Foo::func, Unretained(&foo));
	// foo_callback.Run(); // Prints "Foo:f".
	//
	// Without the Unretained() wrapper on \|&foo\|, the above call would fail
	// to compile because Foo does not support the AddRef() and Release() methods.
	template <typename T>
	static inline internal::UnretainedWrapper<T> Unretained(T* o) {
	return internal::UnretainedWrapper<T>(o);
	}

	// RetainedRef() accepts a ref counted object and retains a reference to it.
	// When the callback is called, the object is passed as a raw pointer.
	//
	// EXAMPLE OF RetainedRef():
	//
	// void foo(RefCountedBytes* bytes) {}
	//
	// scoped_refptr<RefCountedBytes> bytes = ...;
	// Closure callback = Bind(&foo, base::RetainedRef(bytes));
	// callback.Run();
	//
	// Without RetainedRef, the scoped_refptr would try to implicitly convert to
	// a raw pointer and fail compilation:
	//
	// Closure callback = Bind(&foo, bytes); // ERROR!
	template <typename T>
	static inline internal::RetainedRefWrapper<T> RetainedRef(T* o) {
	return internal::RetainedRefWrapper<T>(o);
	}
	template <typename T>
	static inline internal::RetainedRefWrapper<T> RetainedRef(scoped_refptr<T> o) {
	return internal::RetainedRefWrapper<T>(std::move(o));
	}

	// ConstRef() allows binding a constant reference to an argument rather
	// than a copy.
	//
	// EXAMPLE OF ConstRef():
	//
	// void foo(int arg) { cout << arg << endl }
	//
	// int n = 1;
	// Closure no_ref = Bind(&foo, n);
	// Closure has_ref = Bind(&foo, ConstRef(n));
	//
	// no_ref.Run(); // Prints "1"
	// has_ref.Run(); // Prints "1"
	//
	// n = 2;
	// no_ref.Run(); // Prints "1"
	// has_ref.Run(); // Prints "2"
	//
	// Note that because ConstRef() takes a reference on \|n\|, \|n\| must outlive all
	// its bound callbacks.
	template <typename T>
	static inline internal::ConstRefWrapper<T> ConstRef(const T& o) {
	return internal::ConstRefWrapper<T>(o);
	}

	// Owned() transfers ownership of an object to the Callback resulting from
	// bind; the object will be deleted when the Callback is deleted.
	//
	// EXAMPLE OF Owned():
	//
	// void foo(int* arg) { cout << *arg << endl }
	//
	// int* pn = new int(1);
	// Closure foo_callback = Bind(&foo, Owned(pn));
	//
	// foo_callback.Run(); // Prints "1"
	// foo_callback.Run(); // Prints "1"
	// *n = 2;
	// foo_callback.Run(); // Prints "2"
	//
	// foo_callback.Reset(); // \|pn\| is deleted. Also will happen when
	// // \|foo_callback\| goes out of scope.
	//
	// Without Owned(), someone would have to know to delete \|pn\| when the last
	// reference to the Callback is deleted.
	template <typename T>
	static inline internal::OwnedWrapper<T> Owned(T* o) {
	return internal::OwnedWrapper<T>(o);
	}

	// Passed() is for transferring movable-but-not-copyable types (eg. unique_ptr)
	// through a Callback. Logically, this signifies a destructive transfer of
	// the state of the argument into the target function. Invoking
	// Callback::Run() twice on a Callback that was created with a Passed()
	// argument will CHECK() because the first invocation would have already
	// transferred ownership to the target function.
	//
	// Note that Passed() is not necessary with BindOnce(), as std::move() does the
	// same thing. Avoid Passed() in favor of std::move() with BindOnce().
	//
	// EXAMPLE OF Passed():
	//
	// void TakesOwnership(std::unique_ptr<Foo> arg) { }
	// std::unique_ptr<Foo> CreateFoo() { return std::make_unique<Foo>();
	// }
	//
	// auto f = std::make_unique<Foo>();
	//
	// // \|cb\| is given ownership of Foo(). \|f\| is now NULL.
	// // You can use std::move(f) in place of &f, but it's more verbose.
	// Closure cb = Bind(&TakesOwnership, Passed(&f));
	//
	// // Run was never called so \|cb\| still owns Foo() and deletes
	// // it on Reset().
	// cb.Reset();
	//
	// // \|cb\| is given a new Foo created by CreateFoo().
	// cb = Bind(&TakesOwnership, Passed(CreateFoo()));
	//
	// // \|arg\| in TakesOwnership() is given ownership of Foo(). \|cb\|
	// // no longer owns Foo() and, if reset, would not delete Foo().
	// cb.Run(); // Foo() is now transferred to \|arg\| and deleted.
	// cb.Run(); // This CHECK()s since Foo() already been used once.
	//
	// We offer 2 syntaxes for calling Passed(). The first takes an rvalue and
	// is best suited for use with the return value of a function or other temporary
	// rvalues. The second takes a pointer to the scoper and is just syntactic sugar
	// to avoid having to write Passed(std::move(scoper)).
	//
	// Both versions of Passed() prevent T from being an lvalue reference. The first
	// via use of enable_if, and the second takes a T* which will not bind to T&.
	template <typename T,
	std::enable_if_t<!std::is_lvalue_reference<T>::value>* = nullptr>
	static inline internal::PassedWrapper<T> Passed(T&& scoper) {
	return internal::PassedWrapper<T>(std::move(scoper));
	}
	template <typename T>
	static inline internal::PassedWrapper<T> Passed(T* scoper) {
	return internal::PassedWrapper<T>(std::move(*scoper));
	}

	// IgnoreResult() is used to adapt a function or Callback with a return type to
	// one with a void return. This is most useful if you have a function with,
	// say, a pesky ignorable bool return that you want to use with PostTask or
	// something else that expect a Callback with a void return.
	//
	// EXAMPLE OF IgnoreResult():
	//
	// int DoSomething(int arg) { cout << arg << endl; }
	//
	// // Assign to a Callback with a void return type.
	// Callback<void(int)> cb = Bind(IgnoreResult(&DoSomething));
	// cb->Run(1); // Prints "1".
	//
	// // Prints "1" on \|ml\|.
	// ml->PostTask(FROM_HERE, Bind(IgnoreResult(&DoSomething), 1);
	template <typename T>
	static inline internal::IgnoreResultHelper<T> IgnoreResult(T data) {
	return internal::IgnoreResultHelper<T>(std::move(data));
	}

	} // namespace base

	#endif // BASE_BIND_H_