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C++11 has both lambda's and std::function<>, but unfortunately, they have different types. One consequence is that one cannot directly use lambda's in higher order functions such as map in lisp. For example, in the following code

 #include <vector>
 #include <functional>
 using namespace std;

 template <typename A,typename B> 
 vector<B> map(std::function<B (A)> f, vector<A> arr) {
       vector<B> res;
       for (int i=0;i<arr.size();i++) res.push_back(f(arr[i]));
       return res;
}

int main () {
    vector<int> a = {1,2,3};
    map([](int x) -> int { return x;},a); //not OK

    auto id_l = [](int x) -> int { return x;};
    map(id_l,a); //not OK;

    function<int (int)> id_f = id_l;
    map(id_f,a); //OK
return 0;
}

, directly using lambda as in line 2 of main() won't work. g++ -std=c++11 testfunc.cpp returns `... testfunc.cpp:14:37: note: 'main()::__lambda0' is not derived from 'std::function'.

C++11 type inferencing fails as well, as you can see if one stores the lambda to an auto variable and then use it, the type information is still lost, probably due to type erasure and reasons of small performance penalty (as I was told: why do lambda functions in C++11 not have function<> types?).

What does work is to store the lambda in a std:function<> typed variable and use that variable. This is rather inconvenient and kind of defeats the purpose of using lambda's in functional programming in C++11. For example, one cannot manipulate lambda's in place with stuff like bind or flip, and instead has to store the lambda to a variable first.

My question is, is it possible (and how) to overcome this issue and make line#2 of main() legal, e.g. by overwriting some typecast operators? (Of course, this means I don't care about the small performance penalty involved with using/not using type erasure.)

thanks in advance.

--- EDIT ---

To clarify, the reason I use std::function rather than a generic type parameter for the functional parameter is that std::function has exact type information, while a generic type parameter as in template <typename F> map(F f, ...) contains no type information. Also, as I finally figured out, each lambda is its own type. So type erasure wasn't even a issue in the incompatibility between a lambda and its matching std::function object.

---Update---

There are already two answers about how to make the map function above work or how to improve them. Just to clarify. My question isn't about how to make map work. There are plenty of other use cases involving using the std::function<> typed parameters, which I think can at least make the code more readable and make type inferencing easy. The answers so far are about how not to use std::function<> as parameters. My question was about how to make such a function (with std::function<> typed parameters) accept lambda's automatically.

-- Update 2 ---

In response to comments, here is a example of practical case where the type information in std::function<> COULD be useful. Suppose we want to implement a C++ equivalent of fold_right : ('a -> 'b -> 'b) -> 'a list -> 'b -> 'b in OCaml (http://caml.inria.fr/pub/docs/manual-ocaml/libref/List.html).

With std::function<>, one can do

 //approach#1
 template <typename A,typename B> 
 B fold_right(std::function<B (A, B)> f, vector<A> arr, B b) {
     ...
 }

It is clear from above what f is, and what it can or cannot take. Maybe, one can also use

 //approach#2
 template <typename A,typename B, typename F> 
 auto fold_right2(F f, vector<A> arr, B b) -> decltype(f(???)) {
      ...
 }

But, this is becoming kind of ugly as you try to figure out what to put in the decltype. Also, what exactly does f take, and what's the correct way to use f? From the point view of readability, I guess the reader of the code can only figure out what is f (a function or scalar) and the signature of f by INTERPRETING the implementation in the function body.

That is what I don't like and that's where my question comes from. How to make approach#1 work conveniently. For example, if f represents addition of two numbers, approach#1 works if you create a function object first:

std::function<int (int, int)> add = [](int x, int y) -> int { return x + y; }
fold_right(add,{1,2,3},0);

Efficiency issues aside, the above code is inconvenient BECAUSE std::function cannot accept lambda's. So,

fold_right([](int x, int y) -> int { return x + y; },{1,2,3},0);

will not work currently in C++11. My question is specifically about if it is possible to make functions like fold_right defined above accept lambda's directly. Maybe it's too much to hope for. I hope this clarifies the question.

share|improve this question
    
This looks like an X/Y problem. You can look at one of my previous (albeit outdated) implementations of map if you're curious –  Rapptz Dec 21 '13 at 19:56
    
All of your examples are poor situations in which to use std::function<A(B)>. Produce a good situation to use a deduced std::function<A(B)> prior to asserting that one exists. Good stack overflow questions are practical problems. std::function is a type erasure object: a deduced type erasure object is (almost?) always a bad idea, because you could have instead deduced the non-erased type. –  Yakk Dec 22 '13 at 3:10
    
Regarding your update. The effect of deducing the type, if it could have been made to work, is to restrict the second argument to exactly a vector<A> instead of a vector of any type that can be converted to the input type of f. That's not usually a good thing. I don't think it's clear that "there are plenty of other use cases". It might turn out that all of them are like this one: you're trying to deduce more than you need, you can get what you need with decltype, and you could accept a generic functor instead of specifically a function. –  Steve Jessop Dec 22 '13 at 10:31
    
@Yakk Yes, I realize that unfortunately, we have type-erasure, which in my opinion, cripples std::function<>. Looking at your statement the other way, if there is no good situation in which std::function could be put to good use, why does the c++11 standard bother to come up with this new feature? Is it just supposed to store callable things without any practice use? This is what my question is really about: how to or if it is possible to make it useful. –  Ting L Jan 3 at 12:14
    
@SteveJessop The effect of type inference is, of course, to infer that function f is unary and take a B and returns a A. This information is what the decltype approach can't provide. Restricting to vector<A> is clearly an artifact of making an example. –  Ting L Jan 3 at 12:24
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4 Answers 4

Your map function is broken. Do not use std::function unless you cannot use a template; and in this instance, you most assuredly can. You don't need B as a template parameter because decltype can give it to you, and you don't need the argument type to actually be a std::function at all.

template <typename A, typename F> auto map(F f, vector<A> arr) -> std::vector<decltype(f(arr.front())> {
    std::vector<decltype(f(arr.front())> res;
    for (int i=0;i<arr.size();i++) res.push_back(f(arr[i]));
    return res;
}

For the record, this is ignoring everything else wrong with your map function.

share|improve this answer
    
No, my map function is not broken, if you use line#6 and 7 in the main function. The other two use cases are what I intend to make working. I am ware of your method, which basically says F can be any type and relies on caller to provide the correct type for F. There is no type inference or safety at all. So, you method works perfectly fine. But it is not related to my question, which is about fixing the link between lambda and std::function<>. –  Ting L Dec 22 '13 at 1:26
1  
@TingL No type inference? "Broken" is a bit strong but it's not generic enough to work with your desired set of argument types. The solution is to be more generic, which this answer demonstrates. You should probably also get rid of the explicit specification of std::vector. –  Potatoswatter Dec 22 '13 at 1:45
    
Please see the update. The solution in the answer is probably more generic. But it does not address the question itself. The use of vector<> is just to illustrate the question. I don't think the example is the best way to write a map function. But it did work and served to illustrate the question. Telling me how to write it a different way to circumvent the question does not answer it. I surely know there are other ways to write map's. –  Ting L Dec 22 '13 at 1:51
add comment

Why would you want to create a dynamic indirection via std::function<...> in the first place? Just templatize on the function object and you are sorted:

template <typename A, typename F> 
auto map(F f, std::vector<A> arr) -> std::vector<decltype(f(arr[0]))> {
    std::vector<decltype(f(arr[0]))> res;
    for (int i=0; i<arr.size(); ++i)
        res.push_back(f(arr[i]));
    return res;
}

In fact, there isn't really any need for nailing the container type either and you probably want to pass it by [const] reference as well:

template <typename C, typename F> 
auto map(F f, C const& c) -> std::vector<decltype(f(*c.begin()))> {
    std::vector<decltype(f(*c.begin()))> res;
    for (auto const& value: c)
        res.push_back(f(value));
    return res;
}

Finally, please note that the standard C++ library already as a "map" function. It just happens to be spelled std::transform() and has an interface which fits the generic approach in C++ better:

std::vector<int> result;
std::transform(a.begin(), a.end(), std::back_inserter(result),
               [](int x){ return x;});
share|improve this answer
    
Maybe to minimise the interface you use, it could be *std::begin(c) rather than c.front(). This would allow containers other than sequences. I'm unsure though: the name lookup done by a range-based for loop is slightly magical and I suspect that imitating it is difficult. –  Steve Jessop Dec 21 '13 at 20:06
    
@SteveJessop: I'll change the code to use a compromise: *c.begin() as I don't know how to do using std::begin; *begin(c); in a decltype()... –  Dietmar Kühl Dec 21 '13 at 20:09
    
Thanks for your answer. std::transform() is indeed an alternative way. However, I wanted to use the function<> type because it contains complete type signature (type and parity), which can be easily used to reason about types when combined with other higher ordered functions. That's why I came up with the question and why I want to do type conversion from lambda's to std::functions<>. Both contain complete type info. The only reason I heard why lambda do not convert to std::function<> is on the basis of small performance costs. My question is how to type convert if performance is noncritical. –  Ting L Dec 22 '13 at 1:23
1  
@TingL: I understand what you try to do (deduce the argument types of a lambda expression) and as stated above I don't think it is possible in general. For the specific case you have above, it should be possible by jumping through a function which takes a function point but as soon as the lambda has a capture that won't be possible. –  Dietmar Kühl Dec 22 '13 at 1:52
1  
@Dietmar: "I'm not sure if you can determine the arguments of a general lambda at all" certainly you won't be able to once generic lambdas arrive, because such lambdas do not have parameter types :-) –  Steve Jessop Jan 3 at 13:07
show 4 more comments

My question was about how to make such a function (with std::function<> typed parameters) accept lambda's automatically.

You can't. Why do you suppose this is possible? std::function is part of the standard library, and it has no capabilities beyond what is possible with other class types.

Moreover, by artificially restricting the solution space to function calls with a lambda as the argument and a std::function<T> as the parameter with deduced T, there is nothing to possibly change. The argument will not match the parameter, and you've arbitrarily decided to forbid changing either.

Given a function dynamic_function_from_lambda to encapsulate any lambda in a std::function, you could perform the conversion explicitly either in the function call or the body of a function accepting lambda objects by deduction.

Alternative A:

map( dynamic_function_from_lambda( []( int a ){ return a + 1 } ), v );

Alternative B:

template< typename F, typename V >
std::vector< typename std::result_of< F( typename V::value_type ) >::type >
map( F f, V v )
    { return map( dynamic_function_from_lambda( f ), std::move( v ) ); }

The whole point of std::function is runtime polymorphism though, so if you're not using that, it is just wastefully inefficient.

share|improve this answer
    
You are missing the point. 1) std::string can take const char * automatically with type conversion. That's why you can declare a function f(string s,...) and called it with f("Hi",...). There is nothing impossible here. –  Ting L Jan 8 at 14:00
    
2) I don't see how your answer helps in achieving the same thing for std::function<> like the std::string case above. –  Ting L Jan 8 at 14:08
    
@TingL By design, the language will not perform conversion and deduction simultaneously. You can convert a lambda to a given concrete std::function<foo> type, but you cannot convert a lambda, or anything else, to template<typename T> std::function<T>. –  Potatoswatter Jan 8 at 23:54
    
Frankly, I see no strong reason why a lambda cannot auto-convert to std::function as a const char* can convert to std::string. Probably this is more by accident than by design, as I don't see a good reason to forbid this conversion. I only arguments I heard so far is that there is type erasure and lambda's do not support templates. None of these are core to the concept of C++. I heard that lambda is going to support templates in C++14. –  Ting L Jan 9 at 3:04
    
Regarding c++ not performing conversion and deduction simultaneously, I can see currently many things involving templates are not supported. typedef's did not support templates so they came up with using. Is there a fundamental reason why new features cannot be added to allow conversion operators with templates? –  Ting L Jan 9 at 3:15
show 3 more comments
up vote 3 down vote accepted

Finally figured out a generic wrapper function make_function (in current c++11) for converting any lambda to its corresponding std::function object with type deduction. Now instead of using ctor:

map(function<int (int)>( [](int x) -> int { return x;} ), {1,2,3});

which requires giving the same type information twice, the following succinct form works

map(make_function([](int x) -> int { return x;}),a); //now OK

Code is below:

 #include <vector>
 #include <functional>
 using namespace std;

 template <typename T>
 struct function_traits
    : public function_traits<decltype(&T::operator())>
 {};

 template <typename ClassType, typename ReturnType, typename... Args>
 struct function_traits<ReturnType(ClassType::*)(Args...) const> {
    typedef function<ReturnType (Args...)> f_type;
 };

 template <typename L> 
 typename function_traits<L>::f_type make_function(L l){
   return (typename function_traits<L>::f_type)(l);
 }

 template <typename A,typename B> 
 vector<B> map(std::function<B (A)> f, vector<A> arr) {
       vector<B> res;
       for (int i=0;i<arr.size();i++) res.push_back(f(arr[i]));
       return res;
}

int main () {
    vector<int> a = {1,2,3};
    map(make_function([](int x) -> int { return x;}),a); //now OK
    return 0;
}

--original answer--

To answer my own question after a couple of weeks' search (and getting chastised for using std::function<> as parameters), probably the best way I can find to have function<>-typed parameters accept lambda's (in c++11) is simply via explicit cast:

map((function<int (int)>) ([](int x) -> int { return x;} ), {1,2,3});

Or using ctor:

map(function<int (int)>( [](int x) -> int { return x;} ), {1,2,3});

For comparison, if you have a function taking std::string (e.g. void ff(string s) {...}), it can take const char* automatically. (ff("Hi") would work). The automatic conversion from lambda to std::function<> does not similarly work in c++11 (, which is unfortunate, IMO).

Hopefully, things will improve in c++14/1y when lambdas can be properly typed or better type-deduced.

share|improve this answer
    
The specifications of lambdas, std::function, conversion, and deduction are unlikely to change. You simply implemented my dynamic_function_from_lambda suggestion, except doing the work manually instead of making a generic function. –  Potatoswatter Jan 9 at 0:03
    
@Potatoswatter Yes, you can view the std::function<> ctor as a function. In that sense, the type conversion operator I mentioned is also a function. Your suggestion did not add much to that. Mine answer does not add much either, except that my answer shows that the std::function ctor suffices, and there is no need to write such a function. –  Ting L Jan 9 at 2:48
    
@The true answer I was looking for, as evident in the title of the original question, is to find a way to eliminate the explicit type conversion. In that sense, most answers including yours suggested using something else such as decltype or result_of to replace what std::function does in my question. –  Ting L Jan 9 at 2:50
    
decltype and result_of are perfectly fine, and probably more efficient. But there are apparently a different way of programming (for type deduction) than simple deduction using the explicit type parameters in std::function<>. That's why I think the rest of your answer (except that type conversion can be a function) does not apply to the question directly. –  Ting L Jan 9 at 2:57
    
Just in reply to the first comment here, a dynamic_function_from_lambda function is different from a function constructor in that it can perform deduction and avoid the explicit <int (int)> as in your code. –  Potatoswatter Jan 10 at 1:42
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