base/tuple.h - external/github.com/flutter/engine - 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.

 // A Tuple is a generic templatized container, similar in concept to std::pair
 // and std::tuple.  The convenient MakeTuple() function takes any number of
 // arguments and will construct and return the appropriate Tuple object.  The
 // functions DispatchToMethod and DispatchToFunction take a function pointer or
 // instance and method pointer, and unpack a tuple into arguments to the call.
 //
 // Tuple elements are copied by value, and stored in the tuple.  See the unit
 // tests for more details of how/when the values are copied.
 //
 // Example usage:
 //   // These two methods of creating a Tuple are identical.
 //   Tuple<int, const char*> tuple_a(1, "wee");
 //   Tuple<int, const char*> tuple_b = MakeTuple(1, "wee");
 //
 //   void SomeFunc(int a, const char* b) { }
 //   DispatchToFunction(&SomeFunc, tuple_a);  // SomeFunc(1, "wee")
 //   DispatchToFunction(
 //       &SomeFunc, MakeTuple(10, "foo"));    // SomeFunc(10, "foo")
 //
 //   struct { void SomeMeth(int a, int b, int c) { } } foo;
 //   DispatchToMethod(&foo, &Foo::SomeMeth, MakeTuple(1, 2, 3));
 //   // foo->SomeMeth(1, 2, 3);

 #ifndef BASE_TUPLE_H_
 #define BASE_TUPLE_H_

 #include "base/bind_helpers.h"

 namespace base {

 // Index sequences
 //
 // Minimal clone of the similarly-named C++14 functionality.

 template <size_t...>
 struct IndexSequence {};

 template <size_t... Ns>
 struct MakeIndexSequenceImpl;

 #if defined(_PREFAST_) && defined(OS_WIN)

 // Work around VC++ 2013 /analyze internal compiler error:
 // https://connect.microsoft.com/VisualStudio/feedback/details/1053626

 template <> struct MakeIndexSequenceImpl<0> {
   using Type = IndexSequence<>;
 };
 template <> struct MakeIndexSequenceImpl<1> {
   using Type = IndexSequence<0>;
 };
 template <> struct MakeIndexSequenceImpl<2> {
   using Type = IndexSequence<0,1>;
 };
 template <> struct MakeIndexSequenceImpl<3> {
   using Type = IndexSequence<0,1,2>;
 };
 template <> struct MakeIndexSequenceImpl<4> {
   using Type = IndexSequence<0,1,2,3>;
 };
 template <> struct MakeIndexSequenceImpl<5> {
   using Type = IndexSequence<0,1,2,3,4>;
 };
 template <> struct MakeIndexSequenceImpl<6> {
   using Type = IndexSequence<0,1,2,3,4,5>;
 };
 template <> struct MakeIndexSequenceImpl<7> {
   using Type = IndexSequence<0,1,2,3,4,5,6>;
 };
 template <> struct MakeIndexSequenceImpl<8> {
   using Type = IndexSequence<0,1,2,3,4,5,6,7>;
 };
 template <> struct MakeIndexSequenceImpl<9> {
   using Type = IndexSequence<0,1,2,3,4,5,6,7,8>;
 };
 template <> struct MakeIndexSequenceImpl<10> {
   using Type = IndexSequence<0,1,2,3,4,5,6,7,8,9>;
 };
 template <> struct MakeIndexSequenceImpl<11> {
   using Type = IndexSequence<0,1,2,3,4,5,6,7,8,9,10>;
 };
 template <> struct MakeIndexSequenceImpl<12> {
   using Type = IndexSequence<0,1,2,3,4,5,6,7,8,9,10,11>;
 };
 template <> struct MakeIndexSequenceImpl<13> {
   using Type = IndexSequence<0,1,2,3,4,5,6,7,8,9,10,11,12>;
 };

 #else  // defined(WIN) && defined(_PREFAST_)

 template <size_t... Ns>
 struct MakeIndexSequenceImpl<0, Ns...> {
   using Type = IndexSequence<Ns...>;
 };

 template <size_t N, size_t... Ns>
 struct MakeIndexSequenceImpl<N, Ns...>
     : MakeIndexSequenceImpl<N - 1, N - 1, Ns...> {};

 #endif  // defined(WIN) && defined(_PREFAST_)

 template <size_t N>
 using MakeIndexSequence = typename MakeIndexSequenceImpl<N>::Type;

 // Traits ----------------------------------------------------------------------
 //
 // A simple traits class for tuple arguments.
 //
 // ValueType: the bare, nonref version of a type (same as the type for nonrefs).
 // RefType: the ref version of a type (same as the type for refs).
 // ParamType: what type to pass to functions (refs should not be constified).

 template <class P>
 struct TupleTraits {
   typedef P ValueType;
   typedef P& RefType;
   typedef const P& ParamType;
 };

 template <class P>
 struct TupleTraits<P&> {
   typedef P ValueType;
   typedef P& RefType;
   typedef P& ParamType;
 };

 // Tuple -----------------------------------------------------------------------
 //
 // This set of classes is useful for bundling 0 or more heterogeneous data types
 // into a single variable.  The advantage of this is that it greatly simplifies
 // function objects that need to take an arbitrary number of parameters; see
 // RunnableMethod and IPC::MessageWithTuple.
 //
 // Tuple<> is supplied to act as a 'void' type.  It can be used, for example,
 // when dispatching to a function that accepts no arguments (see the
 // Dispatchers below).
 // Tuple<A> is rarely useful.  One such use is when A is non-const ref that you
 // want filled by the dispatchee, and the tuple is merely a container for that
 // output (a "tier").  See MakeRefTuple and its usages.

 template <typename IxSeq, typename... Ts>
 struct TupleBaseImpl;
 template <typename... Ts>
 using TupleBase = TupleBaseImpl<MakeIndexSequence<sizeof...(Ts)>, Ts...>;
 template <size_t N, typename T>
 struct TupleLeaf;

 template <typename... Ts>
 struct Tuple : TupleBase<Ts...> {
   Tuple() : TupleBase<Ts...>() {}
   explicit Tuple(typename TupleTraits<Ts>::ParamType... args)
       : TupleBase<Ts...>(args...) {}
 };

 // Avoids ambiguity between Tuple's two constructors.
 template <>
 struct Tuple<> {};

 template <size_t... Ns, typename... Ts>
 struct TupleBaseImpl<IndexSequence<Ns...>, Ts...> : TupleLeaf<Ns, Ts>... {
   TupleBaseImpl() : TupleLeaf<Ns, Ts>()... {}
   explicit TupleBaseImpl(typename TupleTraits<Ts>::ParamType... args)
       : TupleLeaf<Ns, Ts>(args)... {}
 };

 template <size_t N, typename T>
 struct TupleLeaf {
   TupleLeaf() {}
   explicit TupleLeaf(typename TupleTraits<T>::ParamType x) : x(x) {}

   T& get() { return x; }
   const T& get() const { return x; }

   T x;
 };

 // Tuple getters --------------------------------------------------------------
 //
 // Allows accessing an arbitrary tuple element by index.
 //
 // Example usage:
 //   base::Tuple<int, double> t2;
 //   base::get<0>(t2) = 42;
 //   base::get<1>(t2) = 3.14;

 template <size_t I, typename T>
 T& get(TupleLeaf<I, T>& leaf) {
   return leaf.get();
 }

 template <size_t I, typename T>
 const T& get(const TupleLeaf<I, T>& leaf) {
   return leaf.get();
 }

 // Tuple types ----------------------------------------------------------------
 //
 // Allows for selection of ValueTuple/RefTuple/ParamTuple without needing the
 // definitions of class types the tuple takes as parameters.

 template <typename T>
 struct TupleTypes;

 template <typename... Ts>
 struct TupleTypes<Tuple<Ts...>> {
   using ValueTuple = Tuple<typename TupleTraits<Ts>::ValueType...>;
   using RefTuple = Tuple<typename TupleTraits<Ts>::RefType...>;
   using ParamTuple = Tuple<typename TupleTraits<Ts>::ParamType...>;
 };

 // Tuple creators -------------------------------------------------------------
 //
 // Helper functions for constructing tuples while inferring the template
 // argument types.

 template <typename... Ts>
 inline Tuple<Ts...> MakeTuple(const Ts&... arg) {
   return Tuple<Ts...>(arg...);
 }

 // The following set of helpers make what Boost refers to as "Tiers" - a tuple
 // of references.

 template <typename... Ts>
 inline Tuple<Ts&...> MakeRefTuple(Ts&... arg) {
   return Tuple<Ts&...>(arg...);
 }

 // Dispatchers ----------------------------------------------------------------
 //
 // Helper functions that call the given method on an object, with the unpacked
 // tuple arguments.  Notice that they all have the same number of arguments,
 // so you need only write:
 //   DispatchToMethod(object, &Object::method, args);
 // This is very useful for templated dispatchers, since they don't need to know
 // what type |args| is.

 // Non-Static Dispatchers with no out params.

 template <typename ObjT, typename Method, typename A>
 inline void DispatchToMethod(ObjT* obj, Method method, const A& arg) {
   (obj->*method)(base::internal::UnwrapTraits<A>::Unwrap(arg));
 }

 template <typename ObjT, typename Method, typename... Ts, size_t... Ns>
 inline void DispatchToMethodImpl(ObjT* obj,
                                  Method method,
                                  const Tuple<Ts...>& arg,
                                  IndexSequence<Ns...>) {
   (obj->*method)(base::internal::UnwrapTraits<Ts>::Unwrap(get<Ns>(arg))...);
 }

 template <typename ObjT, typename Method, typename... Ts>
 inline void DispatchToMethod(ObjT* obj,
                              Method method,
                              const Tuple<Ts...>& arg) {
   DispatchToMethodImpl(obj, method, arg, MakeIndexSequence<sizeof...(Ts)>());
 }

 // Static Dispatchers with no out params.

 template <typename Function, typename A>
 inline void DispatchToMethod(Function function, const A& arg) {
   (*function)(base::internal::UnwrapTraits<A>::Unwrap(arg));
 }

 template <typename Function, typename... Ts, size_t... Ns>
 inline void DispatchToFunctionImpl(Function function,
                                    const Tuple<Ts...>& arg,
                                    IndexSequence<Ns...>) {
   (*function)(base::internal::UnwrapTraits<Ts>::Unwrap(get<Ns>(arg))...);
 }

 template <typename Function, typename... Ts>
 inline void DispatchToFunction(Function function, const Tuple<Ts...>& arg) {
   DispatchToFunctionImpl(function, arg, MakeIndexSequence<sizeof...(Ts)>());
 }

 // Dispatchers with out parameters.

 template <typename ObjT,
           typename Method,
           typename In,
           typename... OutTs,
           size_t... OutNs>
 inline void DispatchToMethodImpl(ObjT* obj,
                                  Method method,
                                  const In& in,
                                  Tuple<OutTs...>* out,
                                  IndexSequence<OutNs...>) {
   (obj->*method)(base::internal::UnwrapTraits<In>::Unwrap(in),
                  &get<OutNs>(*out)...);
 }

 template <typename ObjT, typename Method, typename In, typename... OutTs>
 inline void DispatchToMethod(ObjT* obj,
                              Method method,
                              const In& in,
                              Tuple<OutTs...>* out) {
   DispatchToMethodImpl(obj, method, in, out,
                        MakeIndexSequence<sizeof...(OutTs)>());
 }

 template <typename ObjT,
           typename Method,
           typename... InTs,
           typename... OutTs,
           size_t... InNs,
           size_t... OutNs>
 inline void DispatchToMethodImpl(ObjT* obj,
                                  Method method,
                                  const Tuple<InTs...>& in,
                                  Tuple<OutTs...>* out,
                                  IndexSequence<InNs...>,
                                  IndexSequence<OutNs...>) {
   (obj->*method)(base::internal::UnwrapTraits<InTs>::Unwrap(get<InNs>(in))...,
                  &get<OutNs>(*out)...);
 }

 template <typename ObjT, typename Method, typename... InTs, typename... OutTs>
 inline void DispatchToMethod(ObjT* obj,
                              Method method,
                              const Tuple<InTs...>& in,
                              Tuple<OutTs...>* out) {
   DispatchToMethodImpl(obj, method, in, out,
                        MakeIndexSequence<sizeof...(InTs)>(),
                        MakeIndexSequence<sizeof...(OutTs)>());
 }

 }  // namespace base

 #endif  // BASE_TUPLE_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.

	// A Tuple is a generic templatized container, similar in concept to std::pair
	// and std::tuple. The convenient MakeTuple() function takes any number of
	// arguments and will construct and return the appropriate Tuple object. The
	// functions DispatchToMethod and DispatchToFunction take a function pointer or
	// instance and method pointer, and unpack a tuple into arguments to the call.
	//
	// Tuple elements are copied by value, and stored in the tuple. See the unit
	// tests for more details of how/when the values are copied.
	//
	// Example usage:
	// // These two methods of creating a Tuple are identical.
	// Tuple<int, const char*> tuple_a(1, "wee");
	// Tuple<int, const char*> tuple_b = MakeTuple(1, "wee");
	//
	// void SomeFunc(int a, const char* b) { }
	// DispatchToFunction(&SomeFunc, tuple_a); // SomeFunc(1, "wee")
	// DispatchToFunction(
	// &SomeFunc, MakeTuple(10, "foo")); // SomeFunc(10, "foo")
	//
	// struct { void SomeMeth(int a, int b, int c) { } } foo;
	// DispatchToMethod(&foo, &Foo::SomeMeth, MakeTuple(1, 2, 3));
	// // foo->SomeMeth(1, 2, 3);

	#ifndef BASE_TUPLE_H_
	#define BASE_TUPLE_H_

	#include "base/bind_helpers.h"

	namespace base {

	// Index sequences
	//
	// Minimal clone of the similarly-named C++14 functionality.

	template <size_t...>
	struct IndexSequence {};

	template <size_t... Ns>
	struct MakeIndexSequenceImpl;

	#if defined(_PREFAST_) && defined(OS_WIN)

	// Work around VC++ 2013 /analyze internal compiler error:
	// https://connect.microsoft.com/VisualStudio/feedback/details/1053626

	template <> struct MakeIndexSequenceImpl<0> {
	using Type = IndexSequence<>;
	};
	template <> struct MakeIndexSequenceImpl<1> {
	using Type = IndexSequence<0>;
	};
	template <> struct MakeIndexSequenceImpl<2> {
	using Type = IndexSequence<0,1>;
	};
	template <> struct MakeIndexSequenceImpl<3> {
	using Type = IndexSequence<0,1,2>;
	};
	template <> struct MakeIndexSequenceImpl<4> {
	using Type = IndexSequence<0,1,2,3>;
	};
	template <> struct MakeIndexSequenceImpl<5> {
	using Type = IndexSequence<0,1,2,3,4>;
	};
	template <> struct MakeIndexSequenceImpl<6> {
	using Type = IndexSequence<0,1,2,3,4,5>;
	};
	template <> struct MakeIndexSequenceImpl<7> {
	using Type = IndexSequence<0,1,2,3,4,5,6>;
	};
	template <> struct MakeIndexSequenceImpl<8> {
	using Type = IndexSequence<0,1,2,3,4,5,6,7>;
	};
	template <> struct MakeIndexSequenceImpl<9> {
	using Type = IndexSequence<0,1,2,3,4,5,6,7,8>;
	};
	template <> struct MakeIndexSequenceImpl<10> {
	using Type = IndexSequence<0,1,2,3,4,5,6,7,8,9>;
	};
	template <> struct MakeIndexSequenceImpl<11> {
	using Type = IndexSequence<0,1,2,3,4,5,6,7,8,9,10>;
	};
	template <> struct MakeIndexSequenceImpl<12> {
	using Type = IndexSequence<0,1,2,3,4,5,6,7,8,9,10,11>;
	};
	template <> struct MakeIndexSequenceImpl<13> {
	using Type = IndexSequence<0,1,2,3,4,5,6,7,8,9,10,11,12>;
	};

	#else // defined(WIN) && defined(_PREFAST_)

	template <size_t... Ns>
	struct MakeIndexSequenceImpl<0, Ns...> {
	using Type = IndexSequence<Ns...>;
	};

	template <size_t N, size_t... Ns>
	struct MakeIndexSequenceImpl<N, Ns...>
	: MakeIndexSequenceImpl<N - 1, N - 1, Ns...> {};

	#endif // defined(WIN) && defined(_PREFAST_)

	template <size_t N>
	using MakeIndexSequence = typename MakeIndexSequenceImpl<N>::Type;

	// Traits ----------------------------------------------------------------------
	//
	// A simple traits class for tuple arguments.
	//
	// ValueType: the bare, nonref version of a type (same as the type for nonrefs).
	// RefType: the ref version of a type (same as the type for refs).
	// ParamType: what type to pass to functions (refs should not be constified).

	template <class P>
	struct TupleTraits {
	typedef P ValueType;
	typedef P& RefType;
	typedef const P& ParamType;
	};

	template <class P>
	struct TupleTraits<P&> {
	typedef P ValueType;
	typedef P& RefType;
	typedef P& ParamType;
	};

	// Tuple -----------------------------------------------------------------------
	//
	// This set of classes is useful for bundling 0 or more heterogeneous data types
	// into a single variable. The advantage of this is that it greatly simplifies
	// function objects that need to take an arbitrary number of parameters; see
	// RunnableMethod and IPC::MessageWithTuple.
	//
	// Tuple<> is supplied to act as a 'void' type. It can be used, for example,
	// when dispatching to a function that accepts no arguments (see the
	// Dispatchers below).
	// Tuple<A> is rarely useful. One such use is when A is non-const ref that you
	// want filled by the dispatchee, and the tuple is merely a container for that
	// output (a "tier"). See MakeRefTuple and its usages.

	template <typename IxSeq, typename... Ts>
	struct TupleBaseImpl;
	template <typename... Ts>
	using TupleBase = TupleBaseImpl<MakeIndexSequence<sizeof...(Ts)>, Ts...>;
	template <size_t N, typename T>
	struct TupleLeaf;

	template <typename... Ts>
	struct Tuple : TupleBase<Ts...> {
	Tuple() : TupleBase<Ts...>() {}
	explicit Tuple(typename TupleTraits<Ts>::ParamType... args)
	: TupleBase<Ts...>(args...) {}
	};

	// Avoids ambiguity between Tuple's two constructors.
	template <>
	struct Tuple<> {};

	template <size_t... Ns, typename... Ts>
	struct TupleBaseImpl<IndexSequence<Ns...>, Ts...> : TupleLeaf<Ns, Ts>... {
	TupleBaseImpl() : TupleLeaf<Ns, Ts>()... {}
	explicit TupleBaseImpl(typename TupleTraits<Ts>::ParamType... args)
	: TupleLeaf<Ns, Ts>(args)... {}
	};

	template <size_t N, typename T>
	struct TupleLeaf {
	TupleLeaf() {}
	explicit TupleLeaf(typename TupleTraits<T>::ParamType x) : x(x) {}

	T& get() { return x; }
	const T& get() const { return x; }

	T x;
	};

	// Tuple getters --------------------------------------------------------------
	//
	// Allows accessing an arbitrary tuple element by index.
	//
	// Example usage:
	// base::Tuple<int, double> t2;
	// base::get<0>(t2) = 42;
	// base::get<1>(t2) = 3.14;

	template <size_t I, typename T>
	T& get(TupleLeaf<I, T>& leaf) {
	return leaf.get();
	}

	template <size_t I, typename T>
	const T& get(const TupleLeaf<I, T>& leaf) {
	return leaf.get();
	}

	// Tuple types ----------------------------------------------------------------
	//
	// Allows for selection of ValueTuple/RefTuple/ParamTuple without needing the
	// definitions of class types the tuple takes as parameters.

	template <typename T>
	struct TupleTypes;

	template <typename... Ts>
	struct TupleTypes<Tuple<Ts...>> {
	using ValueTuple = Tuple<typename TupleTraits<Ts>::ValueType...>;
	using RefTuple = Tuple<typename TupleTraits<Ts>::RefType...>;
	using ParamTuple = Tuple<typename TupleTraits<Ts>::ParamType...>;
	};

	// Tuple creators -------------------------------------------------------------
	//
	// Helper functions for constructing tuples while inferring the template
	// argument types.

	template <typename... Ts>
	inline Tuple<Ts...> MakeTuple(const Ts&... arg) {
	return Tuple<Ts...>(arg...);
	}

	// The following set of helpers make what Boost refers to as "Tiers" - a tuple
	// of references.

	template <typename... Ts>
	inline Tuple<Ts&...> MakeRefTuple(Ts&... arg) {
	return Tuple<Ts&...>(arg...);
	}

	// Dispatchers ----------------------------------------------------------------
	//
	// Helper functions that call the given method on an object, with the unpacked
	// tuple arguments. Notice that they all have the same number of arguments,
	// so you need only write:
	// DispatchToMethod(object, &Object::method, args);
	// This is very useful for templated dispatchers, since they don't need to know
	// what type \|args\| is.

	// Non-Static Dispatchers with no out params.

	template <typename ObjT, typename Method, typename A>
	inline void DispatchToMethod(ObjT* obj, Method method, const A& arg) {
	(obj->*method)(base::internal::UnwrapTraits<A>::Unwrap(arg));
	}

	template <typename ObjT, typename Method, typename... Ts, size_t... Ns>
	inline void DispatchToMethodImpl(ObjT* obj,
	Method method,
	const Tuple<Ts...>& arg,
	IndexSequence<Ns...>) {
	(obj->*method)(base::internal::UnwrapTraits<Ts>::Unwrap(get<Ns>(arg))...);
	}

	template <typename ObjT, typename Method, typename... Ts>
	inline void DispatchToMethod(ObjT* obj,
	Method method,
	const Tuple<Ts...>& arg) {
	DispatchToMethodImpl(obj, method, arg, MakeIndexSequence<sizeof...(Ts)>());
	}

	// Static Dispatchers with no out params.

	template <typename Function, typename A>
	inline void DispatchToMethod(Function function, const A& arg) {
	(*function)(base::internal::UnwrapTraits<A>::Unwrap(arg));
	}

	template <typename Function, typename... Ts, size_t... Ns>
	inline void DispatchToFunctionImpl(Function function,
	const Tuple<Ts...>& arg,
	IndexSequence<Ns...>) {
	(*function)(base::internal::UnwrapTraits<Ts>::Unwrap(get<Ns>(arg))...);
	}

	template <typename Function, typename... Ts>
	inline void DispatchToFunction(Function function, const Tuple<Ts...>& arg) {
	DispatchToFunctionImpl(function, arg, MakeIndexSequence<sizeof...(Ts)>());
	}

	// Dispatchers with out parameters.

	template <typename ObjT,
	typename Method,
	typename In,
	typename... OutTs,
	size_t... OutNs>
	inline void DispatchToMethodImpl(ObjT* obj,
	Method method,
	const In& in,
	Tuple<OutTs...>* out,
	IndexSequence<OutNs...>) {
	(obj->*method)(base::internal::UnwrapTraits<In>::Unwrap(in),
	&get<OutNs>(*out)...);
	}

	template <typename ObjT, typename Method, typename In, typename... OutTs>
	inline void DispatchToMethod(ObjT* obj,
	Method method,
	const In& in,
	Tuple<OutTs...>* out) {
	DispatchToMethodImpl(obj, method, in, out,
	MakeIndexSequence<sizeof...(OutTs)>());
	}

	template <typename ObjT,
	typename Method,
	typename... InTs,
	typename... OutTs,
	size_t... InNs,
	size_t... OutNs>
	inline void DispatchToMethodImpl(ObjT* obj,
	Method method,
	const Tuple<InTs...>& in,
	Tuple<OutTs...>* out,
	IndexSequence<InNs...>,
	IndexSequence<OutNs...>) {
	(obj->*method)(base::internal::UnwrapTraits<InTs>::Unwrap(get<InNs>(in))...,
	&get<OutNs>(*out)...);
	}

	template <typename ObjT, typename Method, typename... InTs, typename... OutTs>
	inline void DispatchToMethod(ObjT* obj,
	Method method,
	const Tuple<InTs...>& in,
	Tuple<OutTs...>* out) {
	DispatchToMethodImpl(obj, method, in, out,
	MakeIndexSequence<sizeof...(InTs)>(),
	MakeIndexSequence<sizeof...(OutTs)>());
	}

	} // namespace base

	#endif // BASE_TUPLE_H_