164

I want to pass an overloaded function to the std::for_each() algorithm. For example,

class A {
    void f(char c);
    void f(int i);

    void scan(const std::string& s) {
        std::for_each(s.begin(), s.end(), f);
    }
};

I'd expect the compiler to resolve f() by the iterator type. Apparently, it (GCC 4.1.2) doesn't do it. So, how can I specify which f() I want?

1

6 Answers 6

161

You can use static_cast<>() to specify which f to use according to the function signature implied by the function pointer type:

// Uses the void f(char c); overload
std::for_each(s.begin(), s.end(), static_cast<void (*)(char)>(&f));
// Uses the void f(int i); overload
std::for_each(s.begin(), s.end(), static_cast<void (*)(int)>(&f)); 

Or, you can also do this:

// The compiler will figure out which f to use according to
// the function pointer declaration.
void (*fpc)(char) = &f;
std::for_each(s.begin(), s.end(), fpc); // Uses the void f(char c); overload
void (*fpi)(int) = &f;
std::for_each(s.begin(), s.end(), fpi); // Uses the void f(int i); overload

If f is a member function, then you need to use mem_fun, or for your case, use the solution presented in this Dr. Dobb's article.

10
  • 1
    thanks! I still have a problem, though, probably due to the fact that f() is a member of a class (see the edited example above)
    – davka
    May 31, 2010 at 9:09
  • 15
    @the_drow: The second method is actually much safer, if one of the overloads goes away the first method silently gives undefined behavior, while the second catches the problem at compile time.
    – Ben Voigt
    May 31, 2011 at 4:36
  • 4
    @BenVoigt Hmm, I tested this on vs2010 and couldn't find a case where the static_cast wouldn't catch the problem at compile time. It gave a C2440 with "None of the functions with this name in scope match the target type". Can you clarify? May 23, 2012 at 16:33
  • 7
    @Nathan: It's possible I was thinking of reinterpret_cast. Most often I see C-style casts used for this. My rule is just that casts on function pointers are dangerous and unnecessary (as the second code snippet shows, an implicit conversion exists).
    – Ben Voigt
    May 23, 2012 at 21:51
  • 4
    For member functions: std::for_each(s.begin(), s.end(), static_cast<void (A::*)(char)>(&A::f));
    – sam-w
    May 7, 2014 at 13:49
40

Lambdas to the rescue! (note: C++11 required)

std::for_each(s.begin(), s.end(), [&](char a){ return f(a); });

Or using decltype for the lambda parameter:

std::for_each(s.begin(), s.end(), [&](decltype(*s.begin()) a){ return f(a); });

With polymorphic lambdas (C++14):

std::for_each(s.begin(), s.end(), [&](auto a){ return f(a); });

Or disambiguate by removing overloading (only works for free functions):

void f_c(char i)
{
    return f(i);
}
    
void scan(const std::string& s)
{
    std::for_each(s.begin(), s.end(), f_c);
}
4
  • 1
    Hurray for lambdas! Indeed, an excellent solution to the overload resolution problem. (I thought of this also, but decided to leave it out of my answer so as not to muddy the waters.)
    – aldo
    Feb 17, 2014 at 21:20
  • 2
    More code for the same result. I think that's not what the lambdas were made for. Jan 27, 2016 at 17:15
  • 2
    @TomášZato The difference is that this answer works, and the accepted one doesn't (for the example posted by OP - you also need to use mem_fn and bind, which, BTW. are also C++11). Also, if we want to get really pedantic [&](char a){ return f(a); } is 28 characters, and static_cast<void (A::*)(char)>(&f) is 35 characters. Jan 27, 2016 at 17:42
  • 1
    @TomášZato There you go coliru.stacked-crooked.com/a/1faad53c4de6c233 not sure how to make this more clear Jan 27, 2016 at 18:01
25

Why doesn't it work

I'd expect the compiler to resolve f() by the iterator type. Apparently, it (gcc 4.1.2) doesn't do it.

It'd be great if that were the case! However, for_each is a function template, declared as:

template <class InputIterator, class UnaryFunction>
UnaryFunction for_each(InputIterator, InputIterator, UnaryFunction );

Template deduction needs to select a type for UnaryFunction at the point of the call. But f doesn't have a specific type - it's an overloaded function, there are many fs each with different types. There is no current way for for_each to aid the template deduction process by stating which f it wants, so template deduction simply fails. In order to have the template deduction succeed, you need to do more work on the call site.

Generic solution to fixing it

Hopping in here a few years and C++14 later. Rather than use a static_cast (which would allow template deduction to succeed by "fixing" which f we want to use, but requires you to manually do overload resolution to "fix" the correct one), we want to make the compiler work for us. We want to call f on some args. In the most generic way possible, that's:

[&](auto&&... args) -> decltype(auto) { return f(std::forward<decltype(args)>(args)...); }

That's a lot to type, but this sort of problem comes up annoyingly frequently, so we can just wrap that in a macro (sigh):

#define AS_LAMBDA(func) [&](auto&&... args) -> decltype(func(std::forward<decltype(args)>(args)...)) { return func(std::forward<decltype(args)>(args)...); }

and then just use it:

void scan(const std::string& s) {
    std::for_each(s.begin(), s.end(), AS_LAMBDA(f));
}

This will do exactly what you wish the compiler did - perform overload resolution on the name f itself and just do the right thing. This will work regardless of whether f is a free function or a member function.

3
  • Since it took me a second, for member functions you can use std::mem_fn.
    – Kostas
    Sep 30, 2023 at 1:19
  • 1
    @Kostas No, you can't use std::mem_fn if the member function is overloaded (which is what the question is asking for).
    – Barry
    Sep 30, 2023 at 1:23
  • Thank you for the response. Could you please help illustrate if this is at all possible with a method, which also has a private overload?
    – Kostas
    Sep 30, 2023 at 1:32
6

The problem here seems to be not overload resolution but in fact template parameter deduction. While the excellent answer from @In silico will solve an ambiguous overloading problem in general, it seems the best fix when dealing with std::for_each (or similar) is to explicitly specify its template parameters:

// Simplified to use free functions instead of class members.

#include <algorithm>
#include <iostream>
#include <string>

void f( char c )
{
  std::cout << c << std::endl;
}

void f( int i )
{
  std::cout << i << std::endl;
}

void scan( std::string const& s )
{
  // The problem:
  //   error C2914: 'std::for_each' : cannot deduce template argument as function argument is ambiguous
  // std::for_each( s.begin(), s.end(), f );

  // Excellent solution from @In silico (see other answer):
  //   Declare a pointer of the desired type; overload resolution occurs at time of assignment
  void (*fpc)(char) = f;
  std::for_each( s.begin(), s.end(), fpc );
  void (*fpi)(int)  = f;
  std::for_each( s.begin(), s.end(), fpi );

  // Explicit specification (first attempt):
  //   Specify template parameters to std::for_each
  std::for_each< std::string::const_iterator, void(*)(char) >( s.begin(), s.end(), f );
  std::for_each< std::string::const_iterator, void(*)(int)  >( s.begin(), s.end(), f );

  // Explicit specification (improved):
  //   Let the first template parameter be derived; specify only the function type
  std::for_each< decltype( s.begin() ), void(*)(char) >( s.begin(), s.end(), f );
  std::for_each< decltype( s.begin() ), void(*)(int)  >( s.begin(), s.end(), f );
}

void main()
{
  scan( "Test" );
}
6

If you don't mind using C++11, here's a clever helper that is similar to (but less ugly than) the static cast:

template<class... Args, class T, class R>
auto resolve(R (T::*m)(Args...)) -> decltype(m)
{ return m; }

template<class T, class R>
auto resolve(R (T::*m)(void)) -> decltype(m)
{ return m; }

(Works for member functions; should be obvious how to modify it to work for freestanding functions, and you should be able to provide both versions and the compiler will select the right one for you.)

With thanks to Miro Knejp for suggesting: see also https://groups.google.com/a/isocpp.org/d/msg/std-discussion/rLVGeGUXsK0/IGj9dKmSyx4J.

5
  • OP's problem is not being able to pass an overloaded name into a function template, and your solution involves passing an overloaded name into a function template? This is just exactly the same problem.
    – Barry
    Apr 22, 2016 at 13:03
  • 1
    @Barry Not the same problem. Template argument deduction succeeds in this case. It works (with a few minor tweaks).
    – Oktalist
    Aug 12, 2016 at 13:12
  • @Oktalist Because you're providing R, it's not deduced. There's also no mention of that in this answer.
    – Barry
    Aug 12, 2016 at 13:29
  • 1
    @Barry I'm not providing R, I'm providing Args. R and T are deduced. It's true the answer could be improved. (There is no T in my example though, because it's not a pointer-to-member, because that wouldn't work with std::for_each.)
    – Oktalist
    Aug 12, 2016 at 13:32
  • I upvoted this earlier. It's a nice approach, however I now discover it doesn't generalize. E.g., resolve<> won't resolve a zero-argument function, and so on. (For an approach that does work, check out pybind11's overload_cast.)
    – TooTone
    Nov 25, 2023 at 12:10
5

Not to answer your question, but am I the only one that finds

for ( int i = 0; i < s.size(); i++ ) {
   f( s[i] );
}

both simpler and shorter than the for_each alternative suggested by in silico in this case?

8
  • 2
    probably, but it's boring :) also, if I want to use iterator to avoid the [] operator, this becomes longer...
    – davka
    May 31, 2010 at 9:25
  • 3
    @Davka Boring is what we want. Also, iterators are typically no faster (may be slower) than using op[, if that is your concern.
    – anon
    May 31, 2010 at 9:28
  • 9
    Algorithms should be preferred to for loops, since they're less error prone and can have better opportunities for optimisation. There's an article on that somewhere... here it is: drdobbs.com/184401446 May 31, 2010 at 9:43
  • 5
    @Ashley Until I see some objective stats on the "less error prone" I see no need to believe it. And Meyers in the article appears to talking about loops that use iterators - I'm talking about the efficiency of loops that DON'T use iterators - my own benchmarks tend to suggest that these are marginally faster when optimised - certainly no slower.
    – anon
    May 31, 2010 at 9:52
  • 2
    -1: At least write the damn thing correctly ! Use the correct type (size_t) and cache the size: for(size_t i=0,n=s.size();i<n;++i){f(s[i]);} or use a range base for loop: for(const auto&item:s){f(item);}
    – Arnaud
    Nov 24, 2018 at 14:27

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