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I have a matrix class like below:

template <size_t M, size_t N, typename T>
class Matrix
{
public:
    Matrix<M, N, T> operator +(const Matrix<M, N, T>& B) const;
    template <size_t P> Matrix<M,P,T> operator*(const Matrix<N, P, T>& B) const;
    template <typename T2> operator T2() const;  

private:
  T data[M][N];
};

// ... the body is in header file too  ...//

The body has written fine, and everything works well. When I define two Matrices as below:

Matrix < 10, 10, int> m1;
Matrix < 10, 10, float> m2;

m1 + m2;  // OK
m1 * m2;  // error: no match for 'operator*' in 'm1 * m2'

The first '+' operator works well, because an implicit casting has performed on it. but for second '*' operator for different value types, an error occurs.

error: no match for 'operator*' in 'm1 * m2'

Any idea ?!

UPDATE: All code is in header file. I have no problem but for '*' operator.

What you can say about '+' operator? I know everything about template/operators/casting... but this problem is like a bug for my gcc compiler!? I wrote a cast-operator and this operator calls before '+' operator, but i dont know why it dose not perform for '*' operator!

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3  
Templates generally need to be defined entirely in the header. It looks like you've written only the declarations. Also, using a double underscore at the beginning of your identifiers is incorrect. This is reserved at any scope. See here for details. –  Cody Gray Dec 21 '11 at 8:44
    
@CodyGray: In fact, identifiers using a double underscore anywhere are reserved for the implementation. –  Charles Bailey Dec 21 '11 at 8:48
    
@CodyGray: Do really read the question?!!!! –  M M. Dec 21 '11 at 8:51
1  
@CodyGray: The all codes are in header file. I said everything works well but '*'. Do you really want solve my problem or something else? –  M M. Dec 21 '11 at 8:54
1  
Yeah, I want something else. Perhaps you should reconsider how you respond to people who are trying to be helpful? Yes, I read the question. This is a common area of confusion for a lot of people with templates. It obviously wasn't clear to me that you provided the full definition of all those functions in the header. If you did, well then good on you. Give yourself a pat on the back. –  Cody Gray Dec 21 '11 at 9:09

2 Answers 2

up vote 6 down vote accepted

The problem is more or less classic. The overload resolution starts by building a list of possible functions; in this case, functions named operator*. To do this, it adds all operator* functions which are in scope to the list, and it tries to instantiate all function templates by applying type deduction; if type deduction succeeds, it adds the instantiation of the template to the list. (A function template is not a function. An instantiation of the function template is a function.)

The rules for template type deduction are different than those used in overload resolution. In particular, only a very small set of conversions are considered. User defined conversion operators are not considered. The result is that in m1 * m2, type deduction for operator* fails (since it would require a conversion which isn't considered). So no instantiation of the function template is added to the list, and there is no other operator*.

More generally: you're operator T2() wouldn't allow type deduction even if it were allowed; there are a infinite number of conversions which would match operator*. I suspect, in fact, that you've made it too general; that you want an operator Matrix<M, N, T2>(). (Not that this will help here, but there are contexts where it might eliminate an ambiguity.)

You might be able to make it work by defining a:

template<size_t P, tyepname OtherT>
Matrix<M, P, T> operator*( Matrix<N, P, T> const& rhs ) const;

, then doing the conversion inside the operator*. (I haven't tried it, and am not sure, but I think your existing operator* should be considered “more specialized”, and thus be chosen when type deduction succeeds for both.)

Having said this, I think the way you're doing it is the wrong approach. Do you really want the return types of m1 * m2 and m2 * m1 to be different. For starters, I'd require the client code to make the conversion explicit (which is the case in your current code); if you do want to support the implicit conversions, I think you need to make the operator* a global, use some sort of simple meta-programming to determine the correct return type (i.e. given Matrices of long and unsigned, you might want to have a return type of unsigned long, since this is what mixed type arithmetic with these types gives otherwise), convert both sides to the target type, and do the arithmetic on it. A lot of work for what is probably not a very important or useful feature. (Just my opinion, of course. If your clients really want the mixed type arithmetic, and are willing to pay for it...)

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The implicit cast is the culprit in your example (m1 * m1 works). While I am not language-firm enough to tell you exactly why, I suspect that the combination of a templated operator* method (which doesn't specify the type exactly) and a necessary type conversion has too much ambiguity. The compiler is told that it can convert your matrix into any type, and that a templated family of types could be valid arguments for operator*. I would have problems determining which operator* to call from these methods. Inserting a static_cast as m1 * static_cast< Matrix<10,10,int> >(m2) confirms this suspicion.

The Eigen library is a fairly mature and very good matrix library, and they also don't make implicit scalar conversions. Rather, they have used a cast method:

template <typename Scalar> Matrix<M,N,Scalar> cast() const;

In your example, you'd write:

m1.cast<float>() * m2;  
share|improve this answer
    
Yes, i tried something like m1.cast<float>() before, and it was good. but the benefit of implicit-casting is casting like float->float can dropped by compiler. but when i use cast<float>() the casting will run even for float->float. –  M M. Dec 21 '11 at 9:15
    
@MasoudM: Add a specialization for unnecessary casts. boost::is_same<Scalar,T> is your friend. –  thiton Dec 21 '11 at 9:17

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