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My disclaimer here is that I started teaching myself C++ about a week ago and my former experience with programming has been with dynamic languages (Python, javascript).

I'm trying to iterate though the contents of a vector using a generic function to print out the items:

#include <iostream>
#include <algorithm>
#include <vector>

using std::vector;
using std::cout;

template <class T>
void p(T x){
    cout << x;
}

int main () {

    vector<int> myV;

    for(int i = 0; i < 10; i++){
        myV.push_back(i);
    }

    vector<int>::const_iterator iter = myV.begin();

    for_each(iter, myV.end(), p);

    return 0;
}

The code doesn't compile. Would someone explain why?

Edit: The compiler error:

error: no matching function for call to 'for_each(_gnu_debug::_Safe_iterator<__gnu_cxx::__normal_iterator<const int, _gnu_norm::vector<int, std::allocator<int> > >, __gnu_debug_def::vector<int, std::allocator<int> > >&, __gnu_debug::_Safe_iterator<__gnu_cxx::__normal_iterator<int, __gnu_norm::vector<int, std::allocator<int> > >, __gnu_debug_def::vector<int, std::allocator<int> > >, <unknown type>)'

Thanks!

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5  
What compiler errors are you getting? –  Doug T. Oct 20 '09 at 18:52

4 Answers 4

up vote 13 down vote accepted

Try:

for_each(myV.begin(), myV.end(), p<int>);

There were two mistakes in your code:

  • The iterators were not the same type
  • The function pointer was not actually a pointer.
    • Normally templated functions can be deduced from there parameters. But in this case you are not actually using it you are passing it (or its address) to a function (thus the normal rules on template function deduction did not work). As the compiler can not deduce which version of the function 'p' you need to use you must be explicit.

There is also a nice output iterator that does this:

std::copy(myV.begin(),myV.end(), std::ostream_iterator<int>(std::cout));

Also note that very few compilers can optimise code across a function pointer call.
Though most are able to optimise the call if it is an functor object. Thus the following may have been a viable alternative to a function pointer:

template<typename T>
struct P
{
    void operator()(T const& value) const
    {
        std::cout << value;
    }
};

....

for_each(myV.begin(), myV.end(), P<int>());

Another note:
When you use templated methods/functions it is usually better to pass by const reference than value. If the Type is expensive to copy then passing by value will generate a copy construction which may not be what you expected.

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4  
Might add that p<int> denotes a specific function, which the compiler can produce code for. Just writing p doesn't say which type T is (int, float or rhubarb_pie?), and the c++ type-system doesn't infer that much (loosely formulated, it tends to go top-down, not bottom up). –  Macke Oct 20 '09 at 18:56
    
Read Marcus's comment above for why :-) –  Loki Astari Oct 20 '09 at 19:07
1  
I would also be possible to have struct P { template <class T> void oeprator()(const T& value) const { std::cout << value; } }; coupled with for_each(myV.begin(), myV.end(), P());. Would it be more or less efficient ? –  Matthieu M. Oct 21 '09 at 10:58
    
@Martin: there's a typo in your code > you should use an upper case P in the for_each to invoke your struct. (delete when edited if you wish to avoid cluttering) –  Matthieu M. Oct 21 '09 at 10:59
    
@Matthieu: Haveing the class or method templated, which is more effecient. I have no idea. I suspect it would not make much difference but this is an area for profiling. I would say it is 6 of one half a dozen of the other. –  Loki Astari Oct 21 '09 at 16:24

The reason that Martin's solution works and yours doesn't is that p is a function template, and not an actual function. A template function doesn't have an address that you can take, or pass to a function. You have to instantiate a template function, to create an actual function you can use.

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I think it has more to do with the compiler not being abel to deduce the type of P (because it is template). You can manually instanciate multiple versions of p. But there is not enough context here for the compiler to determine which version of p to use. If you call 'p' compiler would have deduced the type and thus the address based on the parameters. ie p(5); is a valid call. –  Loki Astari Oct 20 '09 at 19:28
    
Function templates do not have a type. They simply don't exist until instantiated. In the same way class templates aren't types, but the instantiations are. –  cdiggins Oct 20 '09 at 19:32
    
Correct. Each version of the function is unique. But the compiler tries to deduce what function to call even though there are multiple versions, but in this context there is not enough information to determin which instancuation to use. –  Loki Astari Oct 21 '09 at 4:20
    
@Martin: In the context of calling std::for_Each, there is no function call so there's nothing for the compiler to deduce. –  sbi Oct 21 '09 at 8:19
    
@Martin: You are still incorrect. There are no functions instantiated from the template in the original poster's code. –  cdiggins Oct 21 '09 at 14:19

You problem is that you have to pass some "callable entity" to std::for_each. That could be a function object (that's a class overloading the function call operator) or a function pointer. (Wherever a function pointer is needed you can pass in the name of a function with a matching prototype - functions names implicitly convert into function addresses.)

However, your p isn't a function, it's a function template. And a function template is just that: a template to create functions from. You need to pass such a created function instead of the template's name. The mechanism to let the compiler create a function from a function template is often called template instantiation. So you need an instance of the template. That is created by the compiler implicitly whenever you use such an instance.

So, as others have already said, you need to explicitly pass p<int> to std::foreach:

std::for_each(myV.begin(), myV.end(), p<int>);
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I haven't used for_each in C++, but I would write same cycle so:

vector<int>::iterator iter;

for(iter = myV.begin(); iter != myV.end(); iter++) {
    p(iter);
}
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3  
prefer prefix increment: ++iter –  Loki Astari Oct 20 '09 at 18:55
    
What's the difference, I think in this situation it's matter of programmer's coding style. –  giolekva Oct 20 '09 at 18:59
1  
Postfix increment makes a copy, which can cause performance issues. –  Fred Larson Oct 20 '09 at 19:02
    
@giolekva: Typical post-increment implementation: T operator++(int) {T result(*this); operator++(); return result;} That's up to three copies. If this is built-ins, the compiler will optimize them away. If it is an iterator into a linked list, I wouldn't want to bet my job on it. –  sbi Oct 20 '09 at 19:11
    
In this situation there is no difference (as long as you assume the code will never be modified). It is just a habbit that you should get into so that when it does matter the problem will not affect your code. Most refactoring happens at the type level leaving the algorithm unchanged (thus an algorithm that is OK with the current types may suddenly become burdensome when the underlying container type is changed). Thus prefer the prefix version. –  Loki Astari Oct 20 '09 at 19:23

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