I know the language specification forbids partial specialization of function template.

I would like to know the rationale why it forbids it? Are they not useful?

template<typename T, typename U> void f() {}   //allowed!
template<> void f<int, char>()            {}   //allowed!
template<typename T> void f<char, T>()    {}   //not allowed!
template<typename T> void f<T, int>()     {}   //not allowed!
  • For template<typename T, typename U> void f(T t, U u) {} also template<> void f(int t, char u) {} is allowed.
    – dashesy
    Jul 22, 2016 at 21:46
  • 15
    I find it interesting that people keep providing workarounds when the question is not "how can I achieve a similar goal" but "what's the rationale behind this behavior"... I myself do not know the reason of this choice, but I assume the committee must have had a reason to forbid function template partial specialization. So far the "closest" explanation is the link posted by Georgy, which only points out the potential "risks" of function template partial specialization when overloads are present. However, I don't think that's a reason to forbid this feature, so I assume there is more to this..
    – bartgol
    Oct 3, 2017 at 19:58

5 Answers 5


AFAIK that's changed in C++0x.

I guess it was just an oversight (considering that you can always get the partial specialization effect with more verbose code, by placing the function as a static member of a class).

You might look up the relevant DR (Defect Report), if there is one.

EDIT: checking this, I find that others have also believed that, but no-one is able to find any such support in the draft standard. This SO thread seems to indicate that partial specialization of function templates is not supported in C++0x.

EDIT 2: just an example of what I meant by "placing the function as a static member of a class":

#include <iostream>
using namespace std;

// template<typename T, typename U> void f() {}   //allowed!
// template<> void f<int, char>()            {}   //allowed!
// template<typename T> void f<char, T>()    {}   //not allowed!
// template<typename T> void f<T, int>()     {}   //not allowed!

void say( char const s[] ) { std::cout << s << std::endl; }

namespace detail {
    template< class T, class U >
    struct F {
        static void impl() { say( "1. primary template" ); }

    struct F<int, char> {
        static void impl() { say( "2. <int, char> explicit specialization" ); }

    template< class T >
    struct F< char, T > {
        static void impl() { say( "3. <char, T> partial specialization" ); }

    template< class T >
    struct F< T, int > {
        static void impl() { say( "4. <T, int> partial specialization" ); }
}  // namespace detail

template< class T, class U >
void f() { detail::F<T, U>::impl(); }    

int main() {
    f<char const*, double>();       // 1
    f<int, char>();                 // 2
    f<char, double>();              // 3
    f<double, int>();               // 4
  • do you have the standard in n3225 ? I did a quick search but could not find it :/ Feb 24, 2011 at 8:14
  • 1
    ah sorry... a word was missing. I have the document, but could not find the particular paragraph. Though given your edit, I guess it's simply because it's not in there :) Feb 24, 2011 at 9:25
  • 3
    This is not changed in C++0x. I also doubt its utility. You can always overload the template and make use of partial ordering. Feb 24, 2011 at 9:35
  • 2
    Late update: did not change even in C++17 eight years later, and doesn't seem to enter C++20 either. Cannot see any reason for, though...
    – Aconcagua
    Jun 29, 2019 at 12:29
  • This is by far the most comprehensive implementation of the concept, I believe
    – Victor
    Nov 24, 2019 at 8:46

Well, you really can't do partial function/method specialization however you can do overloading.

template <typename T, typename U>
T fun(U pObj){...}

// acts like partial specialization <T, int> AFAIK 
// (based on Modern C++ Design by Alexandrescu)
template <typename T>
T fun(int pObj){...} 

It is the way but I do not know if it satisfy you.

  • 3
    Wow my mind was filled with templates such that I really forgot how simple things could be :)
    – Johannes
    Feb 1, 2017 at 14:28
  • 2
    Unfortunately it's not the case when you want to pass variadic arguments after partially specializing the function.. :( May 9, 2019 at 1:59
  • Im not sure what was meant by passing variadic templates, so I'd like to know how it is different from a partial specialization. Could you please provide more details? Jun 27, 2019 at 17:45
  • What if you want just two functions for all integral and float types? Jun 2, 2020 at 20:10

In general, it's not recommended to specialize function templates at all, because of troubles with overloading. Here's a good article from the C/C++ Users Journal: http://www.gotw.ca/publications/mill17.htm

And it contains an honest answer to your question:

For one thing, you can't partially specialize them -- pretty much just because the language says you can't.

  • 3
    The article is not about partial specialization besides that it is mentioned once. Oct 17, 2017 at 13:52

Since you can partially specialize classes, you can use a functor:

#include <iostream>

template <typename dtype, int k> struct fun
    int operator()()
        return k;

template <typename dtype> struct fun <dtype, 0>
    int operator()()
        return 42;

int main ( int argc , char * argv[] )
     std::cout << fun<float, 5>()() << std::endl;
     std::cout << fun<float, 0>()() << std::endl;
  • 1
    You can then use a single function template to make the calls, getting rid of the ugly ()() syntax.
    – tmr232
    Dec 4, 2016 at 15:47

Partial specializations of function templates would be extremely problematic for two reasons.

Syntactical ambiguity with function template overloading

Consider the syntax of a full specialization:

template <typename T>
void foo(T);

template <>
void foo(int); // full specialization; we could optionally write foo<int>(int)

From the template <> syntax, it is clear that this is a full specialization, not a non-template overload. However, it would not be so clear for a partial specialization:

template <typename T>
void foo(std::complex<T>);

This could either be interpreted as a second overload, or as a partial specialization foo<std::complex<T>>(std::complex<T>). This ambiguity would be extremely confusing if it existed in the language.

Even full specializations can be confusing when there are multiple overloads; see Which overload is selected when defining an explicit specialization of a function template?

Specializations don't participate in overload resolution

template <typename T>
void foo();                                   // (0) primary template

template <>
void foo(std::complex<int>);                  // (1) full specialization

template <typename T>
void foo(std::complex<T>);                    // (2) overload

If we call this with an argument of type std::complex<int>, then (2) is called, not (1), because specializations don't participate in overload resolution. This is counter-intuitive because std::complex<int> is "more specialized" than std::complex<T>.

Full specializations and hypothetical partial specializations of function templates behave contrary to intuition. Function template overloading is a much more useful feature, and should be preferred in most cases.

Workaround - Overloading, or partial specializations of class templates

In most cases, you can simply use function template overloading instead. If you need to closely imitate partial specializations, you can write function objects instead:

// primary template
template <typename T>
struct foo_object {
    void operator()(T) const { /* ... */ }

// partial specialization
template <typename T>
struct foo_object<std::complex<T>> {
    void operator()(std::complex<T>) const { /* ... */ }

// convenience function
template <typename T>
void foo(T t) {
    return foo_object<T>{}(t);

It may seem pointless compared to function template overloading at first, but partial specializations can delegate to each other through inheritance, which may be useful.

Such a pattern is a viable alternative to tag dispatch.

See Also

Herb Sutter's article Why Not Specialize Function Templates? explains issues regarding explicit specializations in great detail. Those equally apply to hypothetical partial specializations.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.