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I know that the below code is a partial specialization of a class:

template <typename T1, typename T2> 
class MyClass { 
  … 
}; 


// partial specialization: both template parameters have same type 
template <typename T> 
class MyClass<T,T> { 
  … 
}; 

Also I know that C++ does not allow function template partial specialization (only full is allowed). But does my code means that I have partially specialized my function template for one/same type arguments? Because it works for Microsoft Visual Studio 2010 Express! If no, then could you please explain the partial specialization concept?

#include <iostream>
using std::cin;
using std::cout;
using std::endl;

template <typename T1, typename T2> 
inline T1 max (T1 const& a, T2 const& b) 
{ 
    return a < b ? b : a; 
} 

template <typename T> 
inline T const& max (T const& a, T const& b)
{
    return 10;
}


int main ()
{
    cout << max(4,4.2) << endl;;
    cout << max(5,5) << endl;
    int z;
    cin>>z;
}
share|improve this question
    
Look for that analogy of class specialization. If it is called class specialization, then why I should consider the same thing for function as overloading?? –  Narek Nov 9 '11 at 7:15
    
No, specialization syntax is different. Look at the (supposed) function specialization syntax in my answer below. –  iammilind Nov 9 '11 at 7:19

4 Answers 4

up vote 32 down vote accepted

In the example, you are actually overloading (not specializing) the max<T1,T2> function. Partial specialization syntax should have looked somewhat like below (had it been allowed):

//Partial specialization is not allowed by the spec, though!
template <typename T> 
inline T const& max<T,T> (T const& a, T const& b)
{                  ^^^^^ <--- specializing here
    return 10;
}

[Note: in the case of a function template, only full specialization is allowed by the C++ standard (excluding the compiler extensions).]

share|improve this answer
    
It is not allow because it could confuse the compiler for confusing the right specialized version of the function, no? If it is true, the what will be confusing for compiler if the function was not overloaded by the way I have written but it was specialized by the way you have written (in a not allowed way)? –  Narek Nov 9 '11 at 7:18
1  
@Narek, Partial function specialization is not part of standard (for whatsoever reasons). I think MSVC supports it as an extension. May be after sometime, it would be allowed by other compilers also. –  iammilind Nov 9 '11 at 7:29
    
@iammilind: Edited the post, and +1. –  Nawaz Nov 9 '11 at 8:11
    
@Nawaz, no problem, In the last line I actually wanted to mention as in the case of *classes* only **specialization** is allowed (as overloading is meant only for functions). However I missed classes and messed up the sentence. –  iammilind Nov 9 '11 at 8:27
1  
@iammilind: No problem. He already seems to know that. That is why he is trying that for function template as well. So I edited it again, making it clear now. –  Nawaz Nov 9 '11 at 8:43

What is specialization ?

If you really want to understand templates, you should take a look at functional languages. The world of templates in C++ is a purely functional sublanguage of its own.

In functional languages, selections are done using Pattern Matching:

-- An instance of Maybe is either nothing (None) or something (Just a)
-- where a is any type
data Maybe a = None | Just a

-- declare function isJust, which takes a Maybe
-- and checks whether it's None or Just
isJust :: Maybe a -> Bool

-- definition: two cases (_ is a wildcard)
isJust None = False
isJust Just _ = True

As you can see, we overload the definition of isJust.

Well, C++ class templates work exactly the same way. You provide a main declaration, that states the number and nature of the parameters. It can be just a declaration, or also acts as a definition (your choice), and then you can (if you so wish) provide specializations of the pattern and associate to them a different (otherwise it would be silly) version of the class.

For template functions, specialization is somewhat more awkward: it conflicts somewhat with overload resolution. As such, it has been decided that a specialization would relate to a non-specialized version, and specializations would not be considered during overload resolution. Therefore, the algorithm for selecting the right function becomes:

  1. Perform overload resolution, among regular functions and non-specialized templates
  2. If a non-specialized template is selected, check if a specialization exist for it that would be a better match

(for on in-depth treatment, see GotW #49)

As such, template specialization of functions is a second-zone citizen (literally). As far as I am concerned, we would be better off without them: I have yet to encounter a case where a template specialization use could not be solved with overloading instead.

Is this a template specialization ?

No, it is simply an overload, and this is fine. In fact, overloads usually work as we expect them to, while specializations can be surprising (remember the GotW article I linked).

share|improve this answer
    
"As such, template specialization of functions is a second-zone citizen (literally). As far as I am concerned, we would be better off without them: I have yet to encounter a case where a template specialization use could not be solved with overloading instead." How about with non type template parameters? –  Julius Jul 24 '13 at 22:50
    
@Julius: you can still use overloading, albeit by introducing a dummy parameter such as boost::mpl::integral_c<unsigned, 3u>. Another solution could also be to use enable_if/disable_if, though it's a different story. –  Matthieu M. Jul 25 '13 at 8:51

Since partial specialization is not allowed -- as other answers pointed --, you could work around it using std::is_same and std::enable_if, as below:

template <typename T, class F>
inline typename std::enable_if<std::is_same<T, int>::value, void>::type
typed_foo(const F& f) {
    std::cout << ">>> messing with ints! " << f << std::endl;
}

template <typename T, class F>
inline typename std::enable_if<std::is_same<T, float>::value, void>::type
typed_foo(const F& f) {
    std::cout << ">>> messing with floats! " << f << std::endl;
}

int main(int argc, char *argv[]) {
    typed_foo<int>("works");
    typed_foo<float>(2);
}

Output:

$ ./a.out 
>>> messing with ints! works
>>> messing with floats! 2

Edit: In case you need to be able to treat all the other cases left, you could add a definition which states that already treated cases should not match -- otherwise you'd fall into ambiguous definitions. The definition could be:

template <typename T, class F>
inline typename std::enable_if<(not std::is_same<T, int>::value)
    and (not std::is_same<T, float>::value), void>::type
typed_foo(const F& f) {
    std::cout << ">>> messing with unknown stuff! " << f << std::endl;
}

int main(int argc, char *argv[]) {
    typed_foo<int>("works");
    typed_foo<float>(2);
    typed_foo<std::string>("either");
}

Which produces:

$ ./a.out 
>>> messing with ints! works
>>> messing with floats! 2
>>> messing with unknown stuff! either

Although this all-cases thing looks a bit boring, since you have to tell the compiler everything you've already done, it's quite doable to treat up to 5 or a few more specializations.

share|improve this answer
    
There really isn't any need to do this as this can be handled by function overloading in a much simpler and clearer fashion. –  Adrian Jan 5 at 4:45
    
@Adrian I really can't think of any other function overloading approach to solve this. You noticed partial overloading is not allowed, right? Share with us your solution, if you think it is clearer. –  Rubens Jan 9 at 10:24

No. For example, you can legally specialize std::swap, but you cannot legally define your own overload. That means that you cannot make std::swap work for your own custom class template.

Overloading and partial specialization can have the same effect in some cases, but far from all.

share|improve this answer
1  
That's why you put your swap overload in your namespace. –  jpalecek Nov 9 '11 at 9:41

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