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Given a pointer to a function object:

std::shared_ptr<std::function<double(double)>> f;

is there a built-in construct in C++11 that allows be to use this pointer in a std::bind statement? For example:

std::function<double()> g = std::bind(built_in(f), 0.0);

What I am doing is to use variadic template as:

template<typename Ret, typename... Args>
std::function<Ret(Args...)> get_fn(const std::shared_ptr<std::function<Ret(Args...)>>& f)
    return [=](Args... args) -> Ret { return (*f)(args...); };

This allows me to write:

std::function<double()> g = std::bind(get_fn(f), 0.0);

Thanks in advance.

Edit: I should have been clearer. I need to use the instance of the function object inside the shared pointer for optimization purposes.

share|improve this question
What is built_in? –  KnowItAllWannabe Oct 25 '12 at 19:54
@KnowItAllWannabe The built-in command in the language that I am looking for, but it seems there is not such thing. –  Allan Oct 25 '12 at 20:28

2 Answers 2

up vote 4 down vote accepted

If we had a Standard function object for the dereference operator (much like std::plus<T> is for adding T with T) then we could involve a nested bind expression, but that is not the case -- plus we'd need a call operator because the usual substitutions that take place during the evaluation of nested bind expressions don't apply to the first argument! Your solution introduces an additional std::function, so I'm proposing some alternatives that don't.

Write your own call and dereference operators:

struct call {
    template<typename Callable, typename... Args>
    auto operator()(Callable&& callable, Args&&... args) const
    // don't use std::result_of
    -> decltype( std::declval<Callable>()(std::declval<Args>()...) )
    { return std::forward<Callable>(callable)(std::forward<Args>(args)...); }

struct dereference {
    template<typename T>
    auto operator()(T&& t) const
    -> decltype( *std::declval<T>() )
    { return *std::forward<T>(t); }

template<typename IndirectCallable, typename... Args>
auto indirect_bind(IndirectCallable&& f, Args&&... args)
-> decltype( std::bind(call {}
                       , std::bind(dereference {}, std::declval<IndirectCallable>())
                       , std::declval<Args>()... ) )
{ return std::bind(call {}
                   , std::bind(dereference {}, std::forward<IndirectCallable>(f))
                   , std::forward<Args>()... ); }

You can then do auto g = indirect_bind(f, 0.0);. Here's a proof-of-concept that also shows how placeholders are appropriately dealt with.

I mention the above solution because functors like call and dereference are useful bricks -- I personally have them among my tools. My preferred solution however would be to write a polymorphic functor that does the indirection and call in one go:

template<typename Indirect>
struct indirect_callable_type {
    // Encapsulation left as an exercise
    Indirect f;

    template<typename... Args>
    auto operator()(Args&&... args)
    // don't use std::result_of
    -> decltype( std::declval<Indirect&>()(std::declval<Args>()...) )
    { return f(std::forward<Args>(args)...); }

    template<typename... Args>
    auto operator()(Args&&... args) const
    // don't use std::result_of
    -> decltype( std::declval<Indirect const&>()(std::declval<Args>()...) )
    { return f(std::forward<Args>(args)...); }

    // Lvalue and rvalue *this version also left as an exercise

template<typename T>
indirect_callable_type<typename std::decay<T>::type>
make_indirect_callable(T&& t)
{ return { std::forward<T>(t) }; }

which you can, in fact, use as auto g = std::bind(make_indirect_callable(f), 0.0);.

I should mention that unlike your solution, those requires writing some types out-of-line. This is an unfortunate situation due to the inherent limitations of lambda expressions. Should you wish to stick with what you currently have, I have a minor recommendation that inside the lambda you std::forward<Args>(args)... the parameters. This might prove useful if you ever deal with move-only types.

share|improve this answer
Could you please show me how your suggestion on the std::forward<Args>(args)... would fit in my approach? –  Allan Oct 25 '12 at 21:29
@Allan In the return statement inside the lambda. –  Luc Danton Oct 25 '12 at 21:32
Like this return [=](Args... args) -> Ret { return (*f)(std::forward<Args>(args)...); }; you mean. A new world to be discovered now with C++11. –  Allan Oct 25 '12 at 21:35
@Allan That's it yes. –  Luc Danton Oct 25 '12 at 21:38

There's a nice little hack you can use here, which is that INVOKE on a pointer to member function automatically indirects its object argument when passed a pointer or (even) a smart pointer (20.8.2p1 second bullet, definition of INVOKE):

#include <functional>
#include <memory>
#include <iostream>

int main() {
    std::shared_ptr<std::function<double(double)>> f
        = std::make_shared<std::function<double(double)>>(
            [](double d) { return d + 10.0; });
    std::function<double()> g = std::bind(
        &std::function<double(double)>::operator(), f, 0.0);
    std::cout << g() << std::endl;

If you don't want to mention explicitly the type of f:

std::function<double()> g = std::bind(
    &std::remove_reference<decltype(*f)>::type::operator(), f, 0.0);
share|improve this answer
Interesting; I knew std::men_fn, but what was concerning me was the need to state the function type, which can be quite long. Your second approach, which avoids the explicit declaration of the function type is better in my opinion. –  Allan Oct 25 '12 at 22:24
@Allan I was searching my head trying to remember which facility performs the automatic indirection; I found it in mem_fn but then discovered you don't even need to use mem_fn; a bind is enough! –  ecatmur Oct 25 '12 at 22:26
If we write std::bind(f, 0.0), I believe the result type cannot be cast to std::function<double()>. Can you confirm this? –  Allan Oct 26 '12 at 8:39
Although std::bind(f, 0.0) works, it does not result in a function type convertible to std::function<double()>. This is a simplification of my real case, of course, where a predefined function type exists and the result of the bind operation needs to conform to it. –  Allan Oct 26 '12 at 8:52
@Allan std::bind is non-strict; almost anything will appear to work. It won't check whether the bind actually makes sense until you try to call it (or convert it to std::function, which is pretty much the same thing). That's why you have to use &std::remove_reference<decltype(*f)>::type::operator(), even if mem_fn isn't required. –  ecatmur Oct 26 '12 at 8:56

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