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5.1.0_r3
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external
chromium_org
base
bind_internal.h
// This file was GENERATED by command: // pump.py bind_internal.h.pump // DO NOT EDIT BY HAND!!! // 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_INTERNAL_H_ #define BASE_BIND_INTERNAL_H_ #include "base/bind_helpers.h" #include "base/callback_internal.h" #include "base/memory/raw_scoped_refptr_mismatch_checker.h" #include "base/memory/weak_ptr.h" #include "base/template_util.h" #include "build/build_config.h" #if defined(OS_WIN) #include "base/bind_internal_win.h" #endif namespace base { namespace internal { // See base/callback.h for user documentation. // // // CONCEPTS: // Runnable -- A type (really a type class) that has a single Run() method // and a RunType typedef that corresponds to the type of Run(). // A Runnable can declare that it should treated like a method // call by including a typedef named IsMethod. The value of // this typedef is NOT inspected, only the existence. When a // Runnable declares itself a method, Bind() will enforce special // refcounting + WeakPtr handling semantics for the first // parameter which is expected to be an object. // Functor -- A copyable type representing something that should be called. // All function pointers, Callback<>, and Runnables are functors // even if the invocation syntax differs. // RunType -- A function type (as opposed to function _pointer_ type) for // a Run() function. Usually just a convenience typedef. // (Bound)ArgsType -- A function type that is being (ab)used to store the // types of set of arguments. The "return" type is always // void here. We use this hack so that we do not need // a new type name for each arity of type. (eg., // BindState1, BindState2). This makes forward // declarations and friending much much easier. // // Types: // RunnableAdapter<> -- Wraps the various "function" pointer types into an // object that adheres to the Runnable interface. // There are |3*ARITY| RunnableAdapter types. // FunctionTraits<> -- Type traits that unwrap a function signature into a // a set of easier to use typedefs. Used mainly for // compile time asserts. // There are |ARITY| FunctionTraits types. // ForceVoidReturn<> -- Helper class for translating function signatures to // equivalent forms with a "void" return type. // There are |ARITY| ForceVoidReturn types. // FunctorTraits<> -- Type traits used determine the correct RunType and // RunnableType for a Functor. This is where function // signature adapters are applied. // There are |ARITY| ForceVoidReturn types. // MakeRunnable<> -- Takes a Functor and returns an object in the Runnable // type class that represents the underlying Functor. // There are |O(1)| MakeRunnable types. // InvokeHelper<> -- Take a Runnable + arguments and actully invokes it. // Handle the differing syntaxes needed for WeakPtr<> support, // and for ignoring return values. This is separate from // Invoker to avoid creating multiple version of Invoker<> // which grows at O(n^2) with the arity. // There are |k*ARITY| InvokeHelper types. // Invoker<> -- Unwraps the curried parameters and executes the Runnable. // There are |(ARITY^2 + ARITY)/2| Invoketypes. // BindState<> -- Stores the curried parameters, and is the main entry point // into the Bind() system, doing most of the type resolution. // There are ARITY BindState types. // RunnableAdapter<> // // The RunnableAdapter<> templates provide a uniform interface for invoking // a function pointer, method pointer, or const method pointer. The adapter // exposes a Run() method with an appropriate signature. Using this wrapper // allows for writing code that supports all three pointer types without // undue repetition. Without it, a lot of code would need to be repeated 3 // times. // // For method pointers and const method pointers the first argument to Run() // is considered to be the received of the method. This is similar to STL's // mem_fun(). // // This class also exposes a RunType typedef that is the function type of the // Run() function. // // If and only if the wrapper contains a method or const method pointer, an // IsMethod typedef is exposed. The existence of this typedef (NOT the value) // marks that the wrapper should be considered a method wrapper. template
class RunnableAdapter; // Function: Arity 0. template
class RunnableAdapter
{ public: typedef R (RunType)(); explicit RunnableAdapter(R(*function)()) : function_(function) { } R Run() { return function_(); } private: R (*function_)(); }; // Method: Arity 0. template
class RunnableAdapter
{ public: typedef R (RunType)(T*); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)()) : method_(method) { } R Run(T* object) { return (object->*method_)(); } private: R (T::*method_)(); }; // Const Method: Arity 0. template
class RunnableAdapter
{ public: typedef R (RunType)(const T*); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)() const) : method_(method) { } R Run(const T* object) { return (object->*method_)(); } private: R (T::*method_)() const; }; // Function: Arity 1. template
class RunnableAdapter
{ public: typedef R (RunType)(A1); explicit RunnableAdapter(R(*function)(A1)) : function_(function) { } R Run(typename CallbackParamTraits
::ForwardType a1) { return function_(CallbackForward(a1)); } private: R (*function_)(A1); }; // Method: Arity 1. template
class RunnableAdapter
{ public: typedef R (RunType)(T*, A1); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1)) : method_(method) { } R Run(T* object, typename CallbackParamTraits
::ForwardType a1) { return (object->*method_)(CallbackForward(a1)); } private: R (T::*method_)(A1); }; // Const Method: Arity 1. template
class RunnableAdapter
{ public: typedef R (RunType)(const T*, A1); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1) const) : method_(method) { } R Run(const T* object, typename CallbackParamTraits
::ForwardType a1) { return (object->*method_)(CallbackForward(a1)); } private: R (T::*method_)(A1) const; }; // Function: Arity 2. template
class RunnableAdapter
{ public: typedef R (RunType)(A1, A2); explicit RunnableAdapter(R(*function)(A1, A2)) : function_(function) { } R Run(typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2) { return function_(CallbackForward(a1), CallbackForward(a2)); } private: R (*function_)(A1, A2); }; // Method: Arity 2. template
class RunnableAdapter
{ public: typedef R (RunType)(T*, A1, A2); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1, A2)) : method_(method) { } R Run(T* object, typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2) { return (object->*method_)(CallbackForward(a1), CallbackForward(a2)); } private: R (T::*method_)(A1, A2); }; // Const Method: Arity 2. template
class RunnableAdapter
{ public: typedef R (RunType)(const T*, A1, A2); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1, A2) const) : method_(method) { } R Run(const T* object, typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2) { return (object->*method_)(CallbackForward(a1), CallbackForward(a2)); } private: R (T::*method_)(A1, A2) const; }; // Function: Arity 3. template
class RunnableAdapter
{ public: typedef R (RunType)(A1, A2, A3); explicit RunnableAdapter(R(*function)(A1, A2, A3)) : function_(function) { } R Run(typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3) { return function_(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3)); } private: R (*function_)(A1, A2, A3); }; // Method: Arity 3. template
class RunnableAdapter
{ public: typedef R (RunType)(T*, A1, A2, A3); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1, A2, A3)) : method_(method) { } R Run(T* object, typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3) { return (object->*method_)(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3)); } private: R (T::*method_)(A1, A2, A3); }; // Const Method: Arity 3. template
class RunnableAdapter
{ public: typedef R (RunType)(const T*, A1, A2, A3); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1, A2, A3) const) : method_(method) { } R Run(const T* object, typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3) { return (object->*method_)(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3)); } private: R (T::*method_)(A1, A2, A3) const; }; // Function: Arity 4. template
class RunnableAdapter
{ public: typedef R (RunType)(A1, A2, A3, A4); explicit RunnableAdapter(R(*function)(A1, A2, A3, A4)) : function_(function) { } R Run(typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3, typename CallbackParamTraits
::ForwardType a4) { return function_(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4)); } private: R (*function_)(A1, A2, A3, A4); }; // Method: Arity 4. template
class RunnableAdapter
{ public: typedef R (RunType)(T*, A1, A2, A3, A4); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1, A2, A3, A4)) : method_(method) { } R Run(T* object, typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3, typename CallbackParamTraits
::ForwardType a4) { return (object->*method_)(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4)); } private: R (T::*method_)(A1, A2, A3, A4); }; // Const Method: Arity 4. template
class RunnableAdapter
{ public: typedef R (RunType)(const T*, A1, A2, A3, A4); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1, A2, A3, A4) const) : method_(method) { } R Run(const T* object, typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3, typename CallbackParamTraits
::ForwardType a4) { return (object->*method_)(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4)); } private: R (T::*method_)(A1, A2, A3, A4) const; }; // Function: Arity 5. template
class RunnableAdapter
{ public: typedef R (RunType)(A1, A2, A3, A4, A5); explicit RunnableAdapter(R(*function)(A1, A2, A3, A4, A5)) : function_(function) { } R Run(typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3, typename CallbackParamTraits
::ForwardType a4, typename CallbackParamTraits
::ForwardType a5) { return function_(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5)); } private: R (*function_)(A1, A2, A3, A4, A5); }; // Method: Arity 5. template
class RunnableAdapter
{ public: typedef R (RunType)(T*, A1, A2, A3, A4, A5); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1, A2, A3, A4, A5)) : method_(method) { } R Run(T* object, typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3, typename CallbackParamTraits
::ForwardType a4, typename CallbackParamTraits
::ForwardType a5) { return (object->*method_)(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5)); } private: R (T::*method_)(A1, A2, A3, A4, A5); }; // Const Method: Arity 5. template
class RunnableAdapter
{ public: typedef R (RunType)(const T*, A1, A2, A3, A4, A5); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1, A2, A3, A4, A5) const) : method_(method) { } R Run(const T* object, typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3, typename CallbackParamTraits
::ForwardType a4, typename CallbackParamTraits
::ForwardType a5) { return (object->*method_)(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5)); } private: R (T::*method_)(A1, A2, A3, A4, A5) const; }; // Function: Arity 6. template
class RunnableAdapter
{ public: typedef R (RunType)(A1, A2, A3, A4, A5, A6); explicit RunnableAdapter(R(*function)(A1, A2, A3, A4, A5, A6)) : function_(function) { } R Run(typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3, typename CallbackParamTraits
::ForwardType a4, typename CallbackParamTraits
::ForwardType a5, typename CallbackParamTraits
::ForwardType a6) { return function_(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5), CallbackForward(a6)); } private: R (*function_)(A1, A2, A3, A4, A5, A6); }; // Method: Arity 6. template
class RunnableAdapter
{ public: typedef R (RunType)(T*, A1, A2, A3, A4, A5, A6); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1, A2, A3, A4, A5, A6)) : method_(method) { } R Run(T* object, typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3, typename CallbackParamTraits
::ForwardType a4, typename CallbackParamTraits
::ForwardType a5, typename CallbackParamTraits
::ForwardType a6) { return (object->*method_)(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5), CallbackForward(a6)); } private: R (T::*method_)(A1, A2, A3, A4, A5, A6); }; // Const Method: Arity 6. template
class RunnableAdapter
{ public: typedef R (RunType)(const T*, A1, A2, A3, A4, A5, A6); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1, A2, A3, A4, A5, A6) const) : method_(method) { } R Run(const T* object, typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3, typename CallbackParamTraits
::ForwardType a4, typename CallbackParamTraits
::ForwardType a5, typename CallbackParamTraits
::ForwardType a6) { return (object->*method_)(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5), CallbackForward(a6)); } private: R (T::*method_)(A1, A2, A3, A4, A5, A6) const; }; // Function: Arity 7. template
class RunnableAdapter
{ public: typedef R (RunType)(A1, A2, A3, A4, A5, A6, A7); explicit RunnableAdapter(R(*function)(A1, A2, A3, A4, A5, A6, A7)) : function_(function) { } R Run(typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3, typename CallbackParamTraits
::ForwardType a4, typename CallbackParamTraits
::ForwardType a5, typename CallbackParamTraits
::ForwardType a6, typename CallbackParamTraits
::ForwardType a7) { return function_(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5), CallbackForward(a6), CallbackForward(a7)); } private: R (*function_)(A1, A2, A3, A4, A5, A6, A7); }; // Method: Arity 7. template
class RunnableAdapter
{ public: typedef R (RunType)(T*, A1, A2, A3, A4, A5, A6, A7); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1, A2, A3, A4, A5, A6, A7)) : method_(method) { } R Run(T* object, typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3, typename CallbackParamTraits
::ForwardType a4, typename CallbackParamTraits
::ForwardType a5, typename CallbackParamTraits
::ForwardType a6, typename CallbackParamTraits
::ForwardType a7) { return (object->*method_)(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5), CallbackForward(a6), CallbackForward(a7)); } private: R (T::*method_)(A1, A2, A3, A4, A5, A6, A7); }; // Const Method: Arity 7. template
class RunnableAdapter
{ public: typedef R (RunType)(const T*, A1, A2, A3, A4, A5, A6, A7); typedef true_type IsMethod; explicit RunnableAdapter(R(T::*method)(A1, A2, A3, A4, A5, A6, A7) const) : method_(method) { } R Run(const T* object, typename CallbackParamTraits
::ForwardType a1, typename CallbackParamTraits
::ForwardType a2, typename CallbackParamTraits
::ForwardType a3, typename CallbackParamTraits
::ForwardType a4, typename CallbackParamTraits
::ForwardType a5, typename CallbackParamTraits
::ForwardType a6, typename CallbackParamTraits
::ForwardType a7) { return (object->*method_)(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5), CallbackForward(a6), CallbackForward(a7)); } private: R (T::*method_)(A1, A2, A3, A4, A5, A6, A7) const; }; // FunctionTraits<> // // Breaks a function signature apart into typedefs for easier introspection. template
struct FunctionTraits; template
struct FunctionTraits
{ typedef R ReturnType; }; template
struct FunctionTraits
{ typedef R ReturnType; typedef A1 A1Type; }; template
struct FunctionTraits
{ typedef R ReturnType; typedef A1 A1Type; typedef A2 A2Type; }; template
struct FunctionTraits
{ typedef R ReturnType; typedef A1 A1Type; typedef A2 A2Type; typedef A3 A3Type; }; template
struct FunctionTraits
{ typedef R ReturnType; typedef A1 A1Type; typedef A2 A2Type; typedef A3 A3Type; typedef A4 A4Type; }; template
struct FunctionTraits
{ typedef R ReturnType; typedef A1 A1Type; typedef A2 A2Type; typedef A3 A3Type; typedef A4 A4Type; typedef A5 A5Type; }; template
struct FunctionTraits
{ typedef R ReturnType; typedef A1 A1Type; typedef A2 A2Type; typedef A3 A3Type; typedef A4 A4Type; typedef A5 A5Type; typedef A6 A6Type; }; template
struct FunctionTraits
{ typedef R ReturnType; typedef A1 A1Type; typedef A2 A2Type; typedef A3 A3Type; typedef A4 A4Type; typedef A5 A5Type; typedef A6 A6Type; typedef A7 A7Type; }; // ForceVoidReturn<> // // Set of templates that support forcing the function return type to void. template
struct ForceVoidReturn; template
struct ForceVoidReturn
{ typedef void(RunType)(); }; template
struct ForceVoidReturn
{ typedef void(RunType)(A1); }; template
struct ForceVoidReturn
{ typedef void(RunType)(A1, A2); }; template
struct ForceVoidReturn
{ typedef void(RunType)(A1, A2, A3); }; template
struct ForceVoidReturn
{ typedef void(RunType)(A1, A2, A3, A4); }; template
struct ForceVoidReturn
{ typedef void(RunType)(A1, A2, A3, A4, A5); }; template
struct ForceVoidReturn
{ typedef void(RunType)(A1, A2, A3, A4, A5, A6); }; template
struct ForceVoidReturn
{ typedef void(RunType)(A1, A2, A3, A4, A5, A6, A7); }; // FunctorTraits<> // // See description at top of file. template
struct FunctorTraits { typedef RunnableAdapter
RunnableType; typedef typename RunnableType::RunType RunType; }; template
struct FunctorTraits
> { typedef typename FunctorTraits
::RunnableType RunnableType; typedef typename ForceVoidReturn< typename RunnableType::RunType>::RunType RunType; }; template
struct FunctorTraits
> { typedef Callback
RunnableType; typedef typename Callback
::RunType RunType; }; // MakeRunnable<> // // Converts a passed in functor to a RunnableType using type inference. template
typename FunctorTraits
::RunnableType MakeRunnable(const T& t) { return RunnableAdapter
(t); } template
typename FunctorTraits
::RunnableType MakeRunnable(const IgnoreResultHelper
& t) { return MakeRunnable(t.functor_); } template
const typename FunctorTraits
>::RunnableType& MakeRunnable(const Callback
& t) { DCHECK(!t.is_null()); return t; } // InvokeHelper<> // // There are 3 logical InvokeHelper<> specializations: normal, void-return, // WeakCalls. // // The normal type just calls the underlying runnable. // // We need a InvokeHelper to handle void return types in order to support // IgnoreResult(). Normally, if the Runnable's RunType had a void return, // the template system would just accept "return functor.Run()" ignoring // the fact that a void function is being used with return. This piece of // sugar breaks though when the Runnable's RunType is not void. Thus, we // need a partial specialization to change the syntax to drop the "return" // from the invocation call. // // WeakCalls similarly need special syntax that is applied to the first // argument to check if they should no-op themselves. template
struct InvokeHelper; template
struct InvokeHelper
{ static ReturnType MakeItSo(Runnable runnable) { return runnable.Run(); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable) { runnable.Run(); } }; template
struct InvokeHelper
{ static ReturnType MakeItSo(Runnable runnable, A1 a1) { return runnable.Run(CallbackForward(a1)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, A1 a1) { runnable.Run(CallbackForward(a1)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, BoundWeakPtr weak_ptr) { if (!weak_ptr.get()) { return; } runnable.Run(weak_ptr.get()); } }; template
struct InvokeHelper
{ static ReturnType MakeItSo(Runnable runnable, A1 a1, A2 a2) { return runnable.Run(CallbackForward(a1), CallbackForward(a2)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, A1 a1, A2 a2) { runnable.Run(CallbackForward(a1), CallbackForward(a2)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, BoundWeakPtr weak_ptr, A2 a2) { if (!weak_ptr.get()) { return; } runnable.Run(weak_ptr.get(), CallbackForward(a2)); } }; template
struct InvokeHelper
{ static ReturnType MakeItSo(Runnable runnable, A1 a1, A2 a2, A3 a3) { return runnable.Run(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, A1 a1, A2 a2, A3 a3) { runnable.Run(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, BoundWeakPtr weak_ptr, A2 a2, A3 a3) { if (!weak_ptr.get()) { return; } runnable.Run(weak_ptr.get(), CallbackForward(a2), CallbackForward(a3)); } }; template
struct InvokeHelper
{ static ReturnType MakeItSo(Runnable runnable, A1 a1, A2 a2, A3 a3, A4 a4) { return runnable.Run(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, A1 a1, A2 a2, A3 a3, A4 a4) { runnable.Run(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, BoundWeakPtr weak_ptr, A2 a2, A3 a3, A4 a4) { if (!weak_ptr.get()) { return; } runnable.Run(weak_ptr.get(), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4)); } }; template
struct InvokeHelper
{ static ReturnType MakeItSo(Runnable runnable, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5) { return runnable.Run(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5) { runnable.Run(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, BoundWeakPtr weak_ptr, A2 a2, A3 a3, A4 a4, A5 a5) { if (!weak_ptr.get()) { return; } runnable.Run(weak_ptr.get(), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5)); } }; template
struct InvokeHelper
{ static ReturnType MakeItSo(Runnable runnable, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6) { return runnable.Run(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5), CallbackForward(a6)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6) { runnable.Run(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5), CallbackForward(a6)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, BoundWeakPtr weak_ptr, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6) { if (!weak_ptr.get()) { return; } runnable.Run(weak_ptr.get(), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5), CallbackForward(a6)); } }; template
struct InvokeHelper
{ static ReturnType MakeItSo(Runnable runnable, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7) { return runnable.Run(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5), CallbackForward(a6), CallbackForward(a7)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, A1 a1, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7) { runnable.Run(CallbackForward(a1), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5), CallbackForward(a6), CallbackForward(a7)); } }; template
struct InvokeHelper
{ static void MakeItSo(Runnable runnable, BoundWeakPtr weak_ptr, A2 a2, A3 a3, A4 a4, A5 a5, A6 a6, A7 a7) { if (!weak_ptr.get()) { return; } runnable.Run(weak_ptr.get(), CallbackForward(a2), CallbackForward(a3), CallbackForward(a4), CallbackForward(a5), CallbackForward(a6), CallbackForward(a7)); } }; #if !defined(_MSC_VER) template
struct InvokeHelper
{ // WeakCalls are only supported for functions with a void return type. // Otherwise, the function result would be undefined if the the WeakPtr<> // is invalidated. COMPILE_ASSERT(is_void
::value, weak_ptrs_can_only_bind_to_methods_without_return_values); }; #endif // Invoker<> // // See description at the top of the file. template
struct Invoker; // Arity 0 -> 0. template
struct Invoker<0, StorageType, R()> { typedef R(RunType)(BindStateBase*); typedef R(UnboundRunType)(); static R Run(BindStateBase* base) { StorageType* storage = static_cast
(base); // Local references to make debugger stepping easier. If in a debugger, // you really want to warp ahead and step through the // InvokeHelper<>::MakeItSo() call below. return InvokeHelper
::MakeItSo(storage->runnable_); } }; // Arity 1 -> 1. template
struct Invoker<0, StorageType, R(X1)> { typedef R(RunType)(BindStateBase*, typename CallbackParamTraits
::ForwardType); typedef R(UnboundRunType)(X1); static R Run(BindStateBase* base, typename CallbackParamTraits
::ForwardType x1) { StorageType* storage = static_cast
(base); // Local references to make debugger stepping easier. If in a debugger, // you really want to warp ahead and step through the // InvokeHelper<>::MakeItSo() call below. return InvokeHelper
::ForwardType x1)> ::MakeItSo(storage->runnable_, CallbackForward(x1)); } }; // Arity 1 -> 0. template
struct Invoker<1, StorageType, R(X1)> { typedef R(RunType)(BindStateBase*); typedef R(UnboundRunType)(); static R Run(BindStateBase* base) { StorageType* storage = static_cast
(base); // Local references to make debugger stepping easier. If in a debugger, // you really want to warp ahead and step through the // InvokeHelper<>::MakeItSo() call below. typedef typename StorageType::Bound1UnwrapTraits Bound1UnwrapTraits; typename Bound1UnwrapTraits::ForwardType x1 = Bound1UnwrapTraits::Unwrap(storage->p1_); return InvokeHelper
::MakeItSo(storage->runnable_, CallbackForward(x1)); } }; // Arity 2 -> 2. template
struct Invoker<0, StorageType, R(X1, X2)> { typedef R(RunType)(BindStateBase*, typename CallbackParamTraits
::ForwardType, typename CallbackParamTraits
::ForwardType); typedef R(UnboundRunType)(X1, X2); static R Run(BindStateBase* base, typename CallbackParamTraits
::ForwardType x1, typename CallbackParamTraits
::ForwardType x2) { StorageType* storage = static_cast
(base); // Local references to make debugger stepping easier. If in a debugger, // you really want to warp ahead and step through the // InvokeHelper<>::MakeItSo() call below. return InvokeHelper