I'm playing with some code and I am a little puzzled about some stuff. Here's a simplified example:

I have `Nodes`

that perform arithmetical operations (addition, subtraction, etc). I have a container with the different operations that are available in my program. Here's an example:

```
typedef std::binary_function<double, std::vector<double>&, std::vector<Node*>& > my_binary_function;
auto const & product = [](double v, Node* n){ return v * n->GetEvaluation(); };
struct addition : public my_binary_function {
double
operator()(std::vector<double>& weights, std::vector<Node*>& subtrees) {
return std::inner_product(weights.begin(), weights.end(),
subtrees.begin(), 0, std::plus<double>(), product);
}
};
```

Now, at this point there are two choices:

1) use a function type:

```
typedef double (*my_function)(std::vector<double>&, std::vector<Node*>&);
```

Then use the following templated function to convert the functors:

```
template<typename F> typename F::result_type
func(typename F::first_argument_type arg1, typename F::second_argument_type arg2) {
return F()(arg1, arg2);
}
```

2) use a function wrapper type, namely `std::function`

, so that I have

```
typedef std::function<double (std::vector<double>&, std::vector<Node*>&)> my_function;
```

It all boils down to something like this:

```
LoadDefaultFunctions() {
int minArity = 2;
int maxArity = 2;
function_set_.AddFunction("Add", func<addition> , minArity, maxArity, 1.0); // case 1
OR
function_set_.AddFunction("Add", addition(), minArity, maxArity, 1.0); // case 2
```

And now the problems:

a) If I use Method 1, I get this compilation error:

```
error: invalid initialization of non-const reference of type
'std::binary_function<double, std::vector<double>&,
std::vector<Node*>&>::result_type {aka std::vector<Node*>&}'
from an rvalue of type 'double'
```

The error goes away if I change the template (notice how the arguments don't really make sense now):

```
template <typename F> typename F::first_argument_type
func1(typename F::second_argument_type arg1, typename F::result_type arg2) {
return F()(arg1, arg2);
}
```

I find it very strange, because for other types such as `binary_op<double, double, double>`

, the first form works fine. So, what's happening?

b) 1) is faster than 2) (by a small margin). I'm thinking I'm probably missing some neat trick of passing the functor by reference or in some way that would enable `std::function`

to wrap it more efficiently. Any ideas?

c) If I use the typedef from 2) but additionally I still use `func`

to produce a function out of the functor, and let `std::function`

deal with it, it's still faster than 2). That is:

```
`my_function = func<addition>` is faster than `my_function = addition()`
```

I would really appreciate it if someone could help me understand the mechanics behind all of this.

Thanks.

`std::result_of`

to obtain the result type ofanycallable entity generically. – Kerrek SB May 19 '12 at 21:56`std::binary_function`

is a bit off (a matter of the order of parameters, notice how`result_type`

isn't`double`

in the message). Rather than fix that though, can you simply not use it? It's been deprecated in favor of`std::result_of`

(as KerrekSB points out), which only has to be used by clients of`addition`

, and not in the implementation of`addition`

itself. – Luc Danton May 19 '12 at 22:18