Consider the following two snippets:

**Exhibit A**:

```
template<typename CalcFuncT>
int perform_calc(CalcFuncT&& calcfunc)
{
precalc();
int const calc = calcfunc();
postcalc();
return calc;
}
int main()
{
perform_calc([]{ return 5 * foobar_x() + 3; }); // toFuture
perform_calc([]{ return 5 * foobar_y() - 9; }); // toPast
}
```

**Exhibit B**:

```
template<typename CalcFuncT>
int perform_calc(CalcFuncT&& calcfunc)
{
precalc();
int const calc = std::forward<CalcFuncT>(calcfunc)();
postcalc();
return calc;
}
int main()
{
perform_calc([]{ return 5 * foobar_x() + 3; }); // toFuture
perform_calc([]{ return 5 * foobar_y() - 9; }); // toPast
}
```

**Diff**:

```
precalc();
- int const calc = calcfunc();
+ int const calc = std::forward<CalcFuncT>(calcfunc)();
postcalc();
```

What will be the difference (if any) between the generated code of these two pieces of code?

In other words what effect is the std::forward having in the above, if any?

Note this question is not asking what std::forward does in general - only what does it do in the above context?

`std::forward<>`

there because the caller may not necessarily always be a lambda (it may be a functor with overloaded`operator()`

s); if the callerisalways a lambda, then there's no point in using`std::forward<>`

. – ildjarn Mar 28 '12 at 23:48`operator()`

s, which can only be member functions, to differentiate on an rvalue`this`

vs a lvalue`this`

? – Andrew Tomazos Mar 28 '12 at 23:58`&`

and`&&`

can be used as member function decorators (in addition to the usual`const`

and`volatile`

) to allow overloading based on the rvalue-ness or lvalue-ness of the object on which the member function is being invoked. – ildjarn Mar 29 '12 at 0:01