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When I try to use float as a template parameter, the compiler cries for this code, while int works fine.

Is it because I cannot use float as a template parameter?

using namespace std;

template <class T, T defaultValue>
class GenericClass
    T value;
        value = defaultValue;

    T returnVal()
        return value;

int main()
    GenericClass <int, 10> gcInteger;
    GenericClass < float, 4.6f> gcFlaot;

    cout << "\n sum of integer is "<<gcInteger.returnVal();
    cout << "\n sum of float is "<<gcFlaot.returnVal();

    return 0;       


main.cpp: In function `int main()':
main.cpp:25: error: `float' is not a valid type for a template constant parameter
main.cpp:25: error: invalid type in declaration before ';' token

main.cpp:28: error: request for member `returnVal' in `gcFlaot',
                    which is of non-class type `int'

I am reading "Data Structures for Game Programmers" by Ron Penton, the author passes a float, but when I try it it doesn't seem to compile.

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Does the author really use float as a non-type template parameter? In what chapter is that? –  K-ballo Jun 8 '13 at 17:53
Found it, it is at "Using Values as Template Parameters"... –  K-ballo Jun 8 '13 at 17:58

6 Answers 6

up vote 17 down vote accepted

The current C++ standard does not allow float (i.e. real number) or character string literals to be used as template non-type parameters. You can of course use the float and char * types as normal arguments.

Perhaps the author is using a compiler that doesn't follow the current standard?

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Please provide a link to or copy of relevant section from the standard –  thecoshman Jul 17 '12 at 8:37
@thecoshman the relevant section of the standard + more information is available in my (newly posted) answer. –  Filip Roséen - refp Jul 17 '12 at 10:10


The standard doesn't allow floating points as non-type template-arguments, which can be read about in the following section of the C++11 standard;

14.3.2/1      Template non-type arguments      [temp.arg.nontype]

A template-argument for a non-type, non-template template-parameter shall be one of:

  • for a non-type template-parameter of integral or enumeration type, a converted constant expression (5.19) of the type of the template-parameter;

  • the name of a non-type template-parameter; or

  • a constant expression (5.19) that designates the address of an object with static storage duration and external or internal linkage or a function with external or internal linkage, including function templates and function template-ids but excluding non-static class members, expressed (ignoring parentheses) as & id-expression, except that the & may be omitted if the name refers to a function or array and shall be omitted if the corresponding template-parameter is a reference; or

  • a constant expression that evaluates to a null pointer value (4.10); or

  • a constant expression that evaluates to a null member pointer value (4.11); or

  • a pointer to member expressed as described in 5.3.1.

But.. but.. WHY!?

It is probably due to the fact that floating points cannot be represented in an exact manner. If it was allowed it could/would result in erroneous/weird behavior when doing something as this;

func<1/3.f> (); 
func<2/6.f> ();

We meant to call the same function twice but this might not be the case since the floating point representation of the two calculations isn't guaranteed to be exactly the same.

How would I represent floating point values as template arguments?

With C++11 you could write some pretty advanced constant-expressions (constexpr) that would calculate the numerator/denominator of a floating value compile time and then pass these two as separate integer arguments.

Remember to define some sort of threshold so that floating point values close to each other yields the same numerator/denomitor, otherwise it's kinda pointless since it will then yield the same result previously mentioned as a reason not to allow floating point values as non-type template arguments.

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The C++11 solution is <ratio>, described by §20.10 as "Compile-time rational arithmetic". Which cuts right to your example. –  Potatoswatter Jul 17 '12 at 10:45
@Potatoswatter afaik there isn't any method in the STL to convert a float into numerator/denominator using <ratio>? –  Filip Roséen - refp Jul 17 '12 at 11:16
This may have some relevance: stackoverflow.com/questions/95727/… –  Gearoid Murphy Nov 25 '12 at 17:54
This doesn't really give a convincing explanation. The whole point of floating-point is that it does represent values exactly. You're free to treat the numbers you have as approximations to something else, and it's often useful to do so, but the numbers themselves are exact. –  tmyklebu Jan 22 at 14:25

Just to provide one of the reasons why this is a limitation (in the current standard at least).

When matching template specializations, the compiler matches the template arguments, including non-type arguments.

By their very nature, floating point values are not exact and their implementation is not specified by the C++ standard. As a result, it is difficult to decide when two floating point non type arguments really match:

template <float f> void foo () ;

void bar () {
    foo< (1.0/3.0) > ();
    foo< (7.0/21.0) > ();

These expressions do not necessarily produce the same "bit pattern" and so it would not be possible to guarantee that they used the same specialization - without special wording to cover this.

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Indeed, you can't use float literals as template parameters. See section 14.1 ("A non-type template-parameter shall have one of the following (optionally cv-qualified) types...") of the standard.

You can use a reference to the float as a template parameter:

template <class T, T const &defaultValue>
class GenericClass


float const c_four_point_six = 4.6; // at global scope


GenericClass < float, c_four_point_six> gcFlaot;
share|improve this answer
You can. but it doesn't do the same thing. You can't use the reference as a compile-time constant. –  anon Feb 2 '10 at 10:17

If you only want to represent a fixed precision, then you can use a technique like this to convert a float parameter into an int.

For example an array with a growth factor of 1.75 could be created as follows assuming 2 digits of precision (divide by 100).

template <typename _Kind_, int _Factor_=175>
class Array
    static const float Factor;
    _Kind_ * Data;
    int Size;

    // ...

    void Resize()
         _Kind_ * data = new _Kind_[(Size*Factor)+1];

         // ...

template<typename _Kind_, int _Factor_>
const float Array<_kind_,_Factor_>::Factor = _Factor_/100;

If you dont like the representation of 1.75 as 175 in the template argument list then you could always wrap it in some macro.

#define FloatToIntPrecision(f,p) (f*(10^p))

template <typename _Kind_, int _Factor_=FloatToIntPrecision(1.75,2)>
// ...
share|improve this answer
it should be ...::Factor = _Factor_/100.0; otherwise it will be integer division. –  alfC Nov 6 '14 at 0:19

You can always fake it...

#include <iostream>

template <int NUM, int DEN>
struct Float
    static constexpr float value() { return (float)NUM / (float)DEN; }
    static constexpr float VALUE = value();

template <class GRAD, class CONST>
struct LinearFunc
    static float func(float x) { return GRAD::VALUE*x + CONST::VALUE; }

int main()
    // Y = 0.333 x + 0.2
    // x=2, y=0.866
    std::cout << " func(2) = "
              << LinearFunc<Float<1,3>, Float<1,5> > ::func(2) << std::endl;

Ref: http://code-slim-jim.blogspot.jp/2013/06/c11-no-floats-in-templates-wtf.html

share|improve this answer
A float != rational number. The two are very separate ideas. One is calculated via a mantissa & an exponent, the other is, well, a rational - not every value representable by a rational is representable by a float. –  Richard J. Ross III Jun 8 '13 at 17:52

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