问题
Suppose we have this code:
template <class T, void (*u)(T&)>
void Foo()
{
// store the function u internally . . .
}
There are reasons to do something like this and I won't attempt to go into them. However, is there any way to avoid having to specify type T when calling Foo()? For example, to compile, one normally needs:
Foo<int, MyIntFunction>();
But if this int can be deduced from the function pointer, is this possible:
Foo<MyIntFunction>();
EDIT I'm aware of the solution to pass the actual function pointer in as a function parameter, however this is not desired here as it has some perf drawbacks in intensive loop.
回答1:
In this example u is not a function pointer, it's a type (the signature of a function pointer). If you want to store a function pointer you need to pass it.
template<class T, class F = void(*)(T&)>
void Foo(F f)
{
// store the function pointer f here
}
called like so:
struct SomeType {};
void bar(SomeType& x);
Foo(&bar);
Is this what you mean to do?
回答2:
Short answer: I don't think it is possible.
Long one.. When calling a template function, you cannot omit the first parameter and specify the second: the compiler would try to match your MyIntFunction to the template parameter T. Generally, you can specify the first, but omit the second if the compiler can infer the second template parameter. In this case, this is not an option however, because you want to specify the second parameter explicitly.
The second template parameter has a dependency (T) on the first template parameter. Therefore, reversing the order of the template parameters is also not an option.
Your best bet would be to define it in a way similar to what Richard suggested:
template<class T>
void Foo(T f)
{
int a(1);
f(a); // this forces f to be a function taking an int as parameter
}
回答3:
Here is a dirty implementation which basically does what the OP was asking for. It depends on too many assumptions, but could be at least something to discuss. The idea is to specify in advance all possible types which can serve as function argument, and then deduce this type.
#include<iostream>
template<typename T>
struct TD; //type display
template<typename FunctionType, typename T, typename ... Ts>
struct ArgumentDeduction
{
typedef typename std::conditional<std::is_same<void, typename std::result_of<FunctionType(T)>::type>::value
, T
, typename ArgumentDeduction<FunctionType, Ts ...>::type
>::type type;
};
template<typename FunctionType, typename T>
struct ArgumentDeduction<FunctionType, T>
{
typedef typename std::conditional<std::is_same<void, typename std::result_of<FunctionType(T)>::type>::value
, T
, void
>::type type;
};
template<typename FunctionType
, typename T = typename ArgumentDeduction<FunctionType, int, double>::type >
void foo()
{
TD<T>();
}
struct AvoidConversion
{
struct DummyType{};
template<typename T> DummyType operator()(T x) { return DummyType(); }
};
struct Bar : public AvoidConversion
{
using AvoidConversion::operator();
void operator()(int x);
//void operator()(double x); //try also this
};
int main()
{
foo<Bar>(); //calls the foo<Bar,int> version
}
One main assumption here is the form of the Bar functor, which in principle accepts any type, but has a relevant implementation of type void only for the single allowed type.
Again, I don't think this is rather useful, but I guess this comes closest to the OP's question up to now.
DEMO
EDIT: Otherwise, i.e. without AvoidConversion in the code above, the compiler will perform an implicit conversion and the argument deduction gives true for all types which are convertible into each other (such that, e.g., int is deduced when there is only a function taking double).
If someone sees a way to avoid this ugly AvoidConversion hack and deduce the parameter type somehow more elegant, I would be interested in seeing that.
来源:https://stackoverflow.com/questions/27112501/avoid-specifying-redundant-template-parameters-which-contain-templated-function