300

Is it possible to pass a lambda function as a function pointer? If so, I must be doing something incorrectly because I am getting a compile error.

Consider the following example

using DecisionFn = bool(*)();

class Decide
{
public:
    Decide(DecisionFn dec) : _dec{dec} {}
private:
    DecisionFn _dec;
};

int main()
{
    int x = 5;
    Decide greaterThanThree{ [x](){ return x > 3; } };
    return 0;
}

When I try to compile this, I get the following compilation error:

In function 'int main()':
17:31: error: the value of 'x' is not usable in a constant expression
16:9:  note: 'int x' is not const
17:53: error: no matching function for call to 'Decide::Decide(<brace-enclosed initializer list>)'
17:53: note: candidates are:
9:5:   note: Decide::Decide(DecisionFn)
9:5:   note: no known conversion for argument 1 from 'main()::<lambda()>' to 'DecisionFn {aka bool (*)()}'
6:7:   note: constexpr Decide::Decide(const Decide&)
6:7:   note: no known conversion for argument 1 from 'main()::<lambda()>' to 'const Decide&'
6:7:   note: constexpr Decide::Decide(Decide&&)
6:7:   note: no known conversion for argument 1 from 'main()::<lambda()>' to 'Decide&&'

That's one heck of an error message to digest, but I think what I'm getting out of it is that the lambda cannot be treated as a constexpr so therefore I cannot pass it as a function pointer? I've tried making x constexpr as well, but that doesn't seem to help.

4

10 Answers 10

269

A lambda can only be converted to a function pointer if it does not capture, from the draft C++11 standard section 5.1.2 [expr.prim.lambda] says (emphasis mine):

The closure type for a lambda-expression with no lambda-capture has a public non-virtual non-explicit const conversion function to pointer to function having the same parameter and return types as the closure type’s function call operator. The value returned by this conversion function shall be the address of a function that, when invoked, has the same effect as invoking the closure type’s function call operator.

Note, cppreference also covers this in their section on Lambda functions.

So the following alternatives would work:

typedef bool(*DecisionFn)(int);

Decide greaterThanThree{ []( int x ){ return x > 3; } };

and so would this:

typedef bool(*DecisionFn)();

Decide greaterThanThree{ [](){ return true ; } };

and as 5gon12eder points out, you can also use std::function, but note that std::function is heavy weight, so it is not a cost-less trade-off.

1
  • 6
    Side note: One common solution used by C stuff is to pass a void* as the sole parameter. It's normally called a "user pointer". It's relatively lightweight, too, but does tend to require that you malloc out some space.
    – Nic
    Nov 17, 2018 at 0:00
133

Shafik Yaghmour's answer correctly explains why the lambda cannot be passed as a function pointer if it has a capture. I'd like to show two simple fixes for the problem.

  1. Use std::function instead of raw function pointers.

    This is a very clean solution. Note however that it includes some additional overhead for the type erasure (probably a virtual function call).

    #include <functional>
    #include <utility>
    
    struct Decide
    {
      using DecisionFn = std::function<bool()>;
      Decide(DecisionFn dec) : dec_ {std::move(dec)} {}
      DecisionFn dec_;
    };
    
    int
    main()
    {
      int x = 5;
      Decide greaterThanThree { [x](){ return x > 3; } };
    }
    
  2. Use a lambda expression that doesn't capture anything.

    Since your predicate is really just a boolean constant, the following would quickly work around the current issue. See this answer for a good explanation why and how this is working.

    // Your 'Decide' class as in your post.
    
    int
    main()
    {
      int x = 5;
      Decide greaterThanThree {
        (x > 3) ? [](){ return true; } : [](){ return false; }
      };
    }
    
5
  • 4
    @T.C. See this question for details why it works Feb 27, 2015 at 1:56
  • Note that in general, if you know the capture data at compile time, you can convert it to type data and then you're back to having a lambda with no capture - see this answer that I just wrote to another question (thanks to @5gon12eder's answer here).
    – dan-man
    Nov 11, 2015 at 0:31
  • Shouldn't the object have a longer lifespan than the pointer function then? I would like to use it for glutReshapeFunc.
    – ar2015
    Aug 31, 2018 at 12:21
  • i don't recommend this suggestion, things that tend to work magically, introduce new errors. and practices that go along with those errors. if you want to use std::function, you should see all kinds of ways that std::function can be used. because some ways maybe something that you don't want. Jul 7, 2019 at 19:19
  • 3
    This doesn't answer the question. If one could use std::function or a lambda — why wouldn't they? At the very least it's a more readable syntax. Usually one needs to use a function pointer to interact with C libraries (actually, with any external library), and sure you can't go modify it to accept an std::function or lambda.
    – Hi-Angel
    Aug 15, 2019 at 15:04
59

Lambda expressions, even captured ones, can be handled as a function pointer (pointer to member function).

It is tricky because an lambda expression is not a simple function. It is actually an object with an operator().

When you are creative, you can use this! Think of an "function" class in style of std::function. If you save the object you also can use the function pointer.

To use the function pointer, you can use the following:

int first = 5;
auto lambda = [=](int x, int z) {
    return x + z + first;
};
int(decltype(lambda)::*ptr)(int, int)const = &decltype(lambda)::operator();
std::cout << "test = " << (lambda.*ptr)(2, 3) << std::endl;

To build a class that can start working like a "std::function", first you need a class/struct than can store object and function pointer. Also you need an operator() to execute it:

// OT => Object Type
// RT => Return Type
// A ... => Arguments
template<typename OT, typename RT, typename ... A>
struct lambda_expression {
    OT _object;
    RT(OT::*_function)(A...)const;

    lambda_expression(const OT & object)
        : _object(object), _function(&decltype(_object)::operator()) {}

    RT operator() (A ... args) const {
        return (_object.*_function)(args...);
    }
};

With this you can now run captured, non-captured lambdas, just like you are using the original:

auto capture_lambda() {
    int first = 5;
    auto lambda = [=](int x, int z) {
        return x + z + first;
    };
    return lambda_expression<decltype(lambda), int, int, int>(lambda);
}

auto noncapture_lambda() {
    auto lambda = [](int x, int z) {
        return x + z;
    };
    return lambda_expression<decltype(lambda), int, int, int>(lambda);
}

void refcapture_lambda() {
    int test;
    auto lambda = [&](int x, int z) {
        test = x + z;
    };
    lambda_expression<decltype(lambda), void, int, int>f(lambda);
    f(2, 3);

    std::cout << "test value = " << test << std::endl;
}

int main(int argc, char **argv) {
    auto f_capture = capture_lambda();
    auto f_noncapture = noncapture_lambda();

    std::cout << "main test = " << f_capture(2, 3) << std::endl;
    std::cout << "main test = " << f_noncapture(2, 3) << std::endl;

    refcapture_lambda();

    system("PAUSE");
    return 0;
}

This code works with VS2015

Update 04.07.17:

template <typename CT, typename ... A> struct function
: public function<decltype(&CT::operator())(A...)> {};

template <typename C> struct function<C> {
private:
    C mObject;

public:
    function(const C & obj)
        : mObject(obj) {}

    template<typename... Args> typename 
    std::result_of<C(Args...)>::type operator()(Args... a) {
        return this->mObject.operator()(a...);
    }

    template<typename... Args> typename 
    std::result_of<const C(Args...)>::type operator()(Args... a) const {
        return this->mObject.operator()(a...);
    }
};

namespace make {
    template<typename C> auto function(const C & obj) {
        return ::function<C>(obj);
    }
}

int main(int argc, char ** argv) {
   auto func = make::function([](int y, int x) { return x*y; });
   std::cout << func(2, 4) << std::endl;
   system("PAUSE");
   return 0;
}
15
  • 3
    I've added a short version of my own code. this should be working with a simple auto f = make::function(lambda); But i'm quite shure you will find plenty of situation my code will not work. std::function is way more well constructed than this and should be the go to when you are working. This here is for education and personal use.
    – Noxxer
    Jul 4, 2017 at 20:34
  • 18
    This solution involves calling the lambda via an operator() implementation, so if I'm reading it right I don't think it would work to call the lambda using a C-style function pointer, would it? That is what the the original question asked for. Jul 28, 2017 at 3:48
  • 21
    You claimed that lambdas can be handled as function pointers, which you didn't do. You created another object to hold a lambda, which does nothing, you could've just used the original lambda.
    – Passer By
    Aug 1, 2017 at 12:47
  • 20
    This is not "passing capturing lambda as function pointer". This is "passing capturing lambda as an object that contains a function pointer among other things". There is a world of difference. Nov 10, 2018 at 14:36
  • 2
    This is not an answer, because you cannot pass that lambda.*ptr to the API that needs a function pointer. You would get error: invalid use of non-static member function of type. Sep 27, 2021 at 4:46
24

Capturing lambdas cannot be converted to function pointers, as this answer pointed out.

However, it is often quite a pain to supply a function pointer to an API that only accepts one. The most often cited method to do so is to provide a function and call a static object with it.

static Callable callable;
static bool wrapper()
{
    return callable();
}

This is tedious. We take this idea further and automate the process of creating wrapper and make life much easier.

#include<type_traits>
#include<utility>

template<typename Callable>
union storage
{
    storage() {}
    std::decay_t<Callable> callable;
};

template<int, typename Callable, typename Ret, typename... Args>
auto fnptr_(Callable&& c, Ret (*)(Args...))
{
    static bool used = false;
    static storage<Callable> s;
    using type = decltype(s.callable);

    if(used)
        s.callable.~type();
    new (&s.callable) type(std::forward<Callable>(c));
    used = true;

    return [](Args... args) -> Ret {
        return Ret(s.callable(std::forward<Args>(args)...));
    };
}

template<typename Fn, int N = 0, typename Callable>
Fn* fnptr(Callable&& c)
{
    return fnptr_<N>(std::forward<Callable>(c), (Fn*)nullptr);
}

And use it as

void foo(void (*fn)())
{
    fn();   
}

int main()
{
    int i = 42;
    auto fn = fnptr<void()>([i]{std::cout << i;});
    foo(fn);  // compiles!
}

Live

This is essentially declaring an anonymous function at each occurrence of fnptr.

Note that invocations of fnptr overwrite the previously written callable given callables of the same type. We remedy this, to a certain degree, with the int parameter N.

std::function<void()> func1, func2;
auto fn1 = fnptr<void(), 1>(func1);
auto fn2 = fnptr<void(), 2>(func2);  // different function
1
  • 1
    forcing the N integer to be declared would be an elegant way to remember the client to avoid overwriting the function pointers at compile time. Jul 23, 2019 at 10:43
3

Not a direct answer, but a slight variation to use the "functor" template pattern to hide away the specifics of the lambda type and keeps the code nice and simple.

I was not sure how you wanted to use the decide class so I had to extend the class with a function that uses it. See full example here: https://godbolt.org/z/jtByqE

The basic form of your class might look like this:

template <typename Functor>
class Decide
{
public:
    Decide(Functor dec) : _dec{dec} {}
private:
    Functor _dec;
};

Where you pass the type of the function in as part of the class type used like:

auto decide_fc = [](int x){ return x > 3; };
Decide<decltype(decide_fc)> greaterThanThree{decide_fc};

Again, I was not sure why you are capturing x it made more sense (to me) to have a parameter that you pass in to the lambda) so you can use like:

int result = _dec(5); // or whatever value

See the link for a complete example

2

A shortcut for using a lambda with as a C function pointer is this:

"auto fun = +[](){}"

Using Curl as exmample (curl debug info)

auto callback = +[](CURL* handle, curl_infotype type, char* data, size_t size, void*){ //add code here :-) };
curl_easy_setopt(curlHande, CURLOPT_VERBOSE, 1L);
curl_easy_setopt(curlHande,CURLOPT_DEBUGFUNCTION,callback);
1
  • 10
    That lambda doesn't have a capture. The OP's issue is the capture, not having to deduce the function pointer type (which is what the + trick gets you).
    – Sneftel
    May 15, 2019 at 9:07
1

A simular answer but i made it so you don't have to specify the type of returned pointer (note that the generic version requires C++20):

#include <iostream>


template<typename Function>
struct function_traits;

template <typename Ret, typename... Args>
struct function_traits<Ret(Args...)> {
    typedef Ret(*ptr)(Args...);
};

template <typename Ret, typename... Args>
struct function_traits<Ret(*const)(Args...)> : function_traits<Ret(Args...)> {};

template <typename Cls, typename Ret, typename... Args>
struct function_traits<Ret(Cls::*)(Args...) const> : function_traits<Ret(Args...)> {};

using voidfun = void(*)();

template <typename F>
voidfun lambda_to_void_function(F lambda) {
    static auto lambda_copy = lambda;

    return []() {
        lambda_copy();
    };
}

// requires C++20
template <typename F>
auto lambda_to_pointer(F lambda) -> typename function_traits<decltype(&F::operator())>::ptr {
    static auto lambda_copy = lambda;
    
    return []<typename... Args>(Args... args) {
        return lambda_copy(args...);
    };
}



int main() {
    int num;

    void(*foo)() = lambda_to_void_function([&num]() {
        num = 1234;
    });
    foo();
    std::cout << num << std::endl; // 1234

    int(*bar)(int) = lambda_to_pointer([&](int a) -> int {
        num = a;
        return a;
    });
    std::cout << bar(4321) << std::endl; // 4321
    std::cout << num << std::endl; // 4321
}
3
  • static auto lambda_copy = lambda; static means that there is always only ever one copy of the lambda
    – Moritz
    Oct 7, 2021 at 11:56
  • Is there a way to make this thread safe?
    – vlovero
    Nov 29, 2021 at 16:08
  • You say it means there is only one copy of the lambda, but in my code (single thread) I am able to call lambda_to_pointer multiple times, save the results, and call the results with no mixing. What am I missing?
    – benathon
    Aug 12 at 3:09
0

Here is another variation of the solution. C++14 (can be turned into C++11) Supports return values, non-copyable and mutable lambdas. If mutable lambdas not needed, can be even shorter by removing specialization matching non-const version and embedding impl_impl.

For those who wonder, it works because each lambda is unique (is distinct class) and thus invocation of to_f generates unique for this lambda static and corresponding C-style function which can access it.

template <class L, class R, class... Args> static auto impl_impl(L l) {
  static_assert(!std::is_same<L, std::function<R(Args...)>>::value,
                "Only lambdas are supported, it is unsafe to use "
                "std::function or other non-lambda callables");

    static L lambda_s = std::move(l);
    return +[](Args... args) -> R { return lambda_s(args...); };
}

template <class L>
struct to_f_impl : public to_f_impl<decltype(&L::operator())> {};
template <class ClassType, class R, class... Args>
struct to_f_impl<R (ClassType::*)(Args...) const> {
  template <class L> static auto impl(L l) {
    return impl_impl<L, R, Args...>(std::move(l));
  }
};
template <class ClassType, class R, class... Args>
struct to_f_impl<R (ClassType::*)(Args...)> {
  template <class L> static auto impl(L l) {
    return impl_impl<L, R, Args...>(std::move(l));
  }
};

template <class L> auto to_f(L l) { return to_f_impl<L>::impl(std::move(l)); }

Note, this also tend to work for other callable objects like std::function but it would be better if it didn't work because unlike lambdas, std::function like objects do not generate unique type so inner template and its inner static will be reused for/shared by all functions with same signature, which most probably is not what we want from it. I've specifically disallowed std::function but there exist more which I don't know how to disallow in generic way.

-1

While the template approach is clever for various reasons, it is important to remember the lifecycle of the lambda and the captured variables. If any form of a lambda pointer is is going to be used and the lambda is not a downward continuation, then only a copying [=] lambda should used. I.e., even then, capturing a pointer to a variable on the stack is UNSAFE if the lifetime of those captured pointers (stack unwind) is shorter than the lifetime of the lambda.

A simpler solution for capturing a lambda as a pointer is:

auto pLamdba = new std::function<...fn-sig...>([=](...fn-sig...){...});

e.g., new std::function<void()>([=]() -> void {...}

Just remember to later delete pLamdba so ensure that you don't leak the lambda memory. Secret to realize here is that lambdas can capture lambdas (ask yourself how that works) and also that in order for std::function to work generically the lambda implementation needs to contain sufficient internal information to provide access to the size of the lambda (and captured) data (which is why the delete should work [running destructors of captured types]).

2
  • 4
    Why bother with the new -- std::function already stores the lambda on the heap AND avoids needing to remember calling delete.
    – Chris Dodd
    Jun 23, 2020 at 15:51
  • 2
    By "capture a lambda as a pointer", you mean type-erase inside std::function... but OP clearly wanted a free function pointer. Having a pointer to std::function, by advising the pointless antipattern of raw new, doesn't qualify as relevant to the Q. Jun 24, 2021 at 20:27
-4

As it was mentioned by the others you can substitute Lambda function instead of function pointer. I am using this method in my C++ interface to F77 ODE solver RKSUITE.

//C interface to Fortran subroutine UT
extern "C"  void UT(void(*)(double*,double*,double*),double*,double*,double*,
double*,double*,double*,int*);

// C++ wrapper which calls extern "C" void UT routine
static  void   rk_ut(void(*)(double*,double*,double*),double*,double*,double*,
double*,double*,double*,int*);

//  Call of rk_ut with lambda passed instead of function pointer to derivative
//  routine
mathlib::RungeKuttaSolver::rk_ut([](double* T,double* Y,double* YP)->void{YP[0]=Y[1]; YP[1]= -Y[0];}, TWANT,T,Y,YP,YMAX,WORK,UFLAG);
1
  • 1
    Is this a joke? double*, double* double* double* double* ... Unreadable. Dec 21, 2020 at 15:15

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