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I'm trying to make a universal vector class, both for the sake of my own snippet library and to practice with templated classes. Essentially, the Vector class is templated to allow you to chose whether its precision is float, double, long double, etc.

The issue I've run into is with overloading the * operator for the purpose of scaling the vector. With all working overloads and member functions excluded, the class definition looks like this:

#pragma once

#include <math.h>   //  for sqrt function when normalizing

template <typename T> class Vector;
template <typename T> Vector<T> operator*(const Vector<T>& obj);

template <typename T> class Vector {
private:
    //  Attributes:
    static const int DIMS = 3;
    T component[DIMS];

public:
    enum { 
        X, Y, Z
    };

public:
    //  Constructors:
    Vector(void) {
        for (int i=0; i<DIMS; ++i) {
            component[i] = T();
        }
    }
    Vector(T x, T y, T z) {
        component[X] = x;
        component[Y] = y;
        component[Z] = z;
    }

    //  Destructor:
    ~Vector(void) { }

    //  Scaling:
    friend Vector<T> operator*(const Vector<T>& obj);
    Vector operator*(const T scale) {
        Vector<T> result = Vector<T>();

        for (int i=0; i<DIMS; ++i) {
            result.component[i] = component[i] * scale;
        }

        return result;
    }
};

template <typename T>
Vector<T> operator*(const Vector<T>& obj) {
    Vector<T> result = Vector<T>();

    for (int i=0; i<DIMS; ++i) {
        result.component[i] = obj.component[i] * this*;
    }

    return result;
}

In my main method, I have the following lines of code:

Vector<float> testVector1 = Vector<float>(1.0f, 0.0f, 0.0f);
Vector<float> testVector2 = Vector<float>(0.0f, 1.0f, 0.0f);
Vector<float> testVector3 = 10.0f * testVector1;
Vector<float> testVector4 = testVector2 * 10.0f;

Everything compiles fine except for one error: While the fourth line in main() works fine (multiplying the vector by a scalar) the third (multiplying a scalar into the vector) gives me the error:

Error 1 error C2677: binary '*' : no global operator found which takes type 'Vector<T>' (or there is no acceptable conversion)

My best guess on the issue is that the compiler doesn't know which primitive's * operator I'm trying to overload, and I can't directly tell it since the class won't know the type until it's passed into the template. Is there a way to accomplish what I'm trying to do, or must the template always follow the class for operator overloading?

Update: So I caught the bad attempt at a left-handed overload thanks to jwismar and others. The definition for the function within the class is now:

friend Vector<T> operator*(T scalar, const Vector<T>& obj);

And it's implementation is:

template <typename T> 
Vector<T> operator*(T scalar, const Vector<T>& obj) {
    Vector<T> result = Vector<T>();

    for (int i=0; i<DIMS; ++i) {
        result.component[i] = obj.component[i] * scalar;
    }

    return result;
}

The initial declaration of the overload above the class is now template <typename T> Vector<T> operator*(T scalar, const Vector<T>& obj);, but I get the same error regardless of whether it's commented out or not.

Now I'm on to a more specific question regarding templates and operator overloading. The compiler now balks at compile, though the error is now an unresolved external:

Error 1 error LNK2019: unresolved external symbol "class Vector<float> __cdecl operator*(float,class Vector<float> const &)" (??D@YA?AV?$Vector@M@@MABV0@@Z) referenced in function _main C:\Users\D03457489\Desktop\UVCTester\UVCTester\main.obj UVCTester

So the compiler is telling me it can find a definition for operator*(float, Vector<float>) but can't find the implementation. So the new question is: is that the result of another basic oversight on my part, or is it just not possible to use templates in this way to generate operator overloads where the left side of the operand is unknown?

share|improve this question
    
You should do a search for operator overloading in SO or in google and read more about it before starting. –  David Rodríguez - dribeas Aug 2 '12 at 1:46
    
Having spent two hours researching both operator overloading and template classes before writing this question, that is not a very helpful response. Everything I could find on Stack Overflow dealing with both concepts at once involved applying the operator to two objects of the templated class, rather than a primitive and an object of the templated class. –  J W Aug 2 '12 at 21:12
    
@J W: stackoverflow.com/questions/3633549/…, for example has an example of operator overloaded for two different types. And that is just one of the first results of searching for 'operator overloading [c++]' in SO –  David Rodríguez - dribeas Aug 2 '12 at 21:34
    
But that result also doesn't answer my question, since it doesn't have anything to do with the situation I'm trying to account for: overloading an operator when the left side is an unknown type due to the class in question being templated. I already know how to overload non-template classes. –  J W Aug 2 '12 at 22:36
    
@J W: No, it does not exactly provide the code for your problem, but it provides the information that you need to build your own solution. At any rate, the comment was specific to this line of code friend Vector<T> operator*(const Vector<T>& obj);, that clearly indicates that you have not yet understood operator overloading basics (overloading as a member with one N-1 arguments or as a free function with N arguments for an N-ary operator) and that is present in all basic tutorials on operator overloading. –  David Rodríguez - dribeas Aug 2 '12 at 23:27

4 Answers 4

up vote 0 down vote accepted

Try this function signature instead (not tested):

template <typename T, typename F>
Vector<T> operator*(const F &lhs, const Vector<T>& rhs);

It should allow for statements like:

auto vec = f * other_vec;

for any type F which has a defined operator of the kind:

template <typename F, typename T>
undetermined operator*(const F& lhs, const T &rhs);

where T is the type used for the Vector<T>, and the returned type can implicitly cast to T.

So the following would probably work:

long l;
float f;
int i;
//.......

Vector<float> v1;
v2 = l * v1;
v3 = f * v2;
v4 = i * v3;
share|improve this answer
    
This would work; I could overload a version for float, double, and long double, and think of a clever way to handle casting to the various precisions within the overload implementations. I was more interested in finding a more general, template-based solution, though to be honest I'm not even sure that's possible. –  J W Aug 3 '12 at 5:27
    
Something like this? Let me know if it works. No compiler handy right now. –  anthony-arnold Aug 3 '12 at 7:01
    
Managed to get it working as template <typename F> friend Vector<T> operator*(F scalar, const Vector<T>& obj) with the implementation inline. For some reason separating the implementation from the class definition causes the compiler to complain that the operator is ambiguous and is implemented twice: it points to the definition within class declaring the function a friend, and the implementation down at the end, and seems to think they're both implementations. At any rate, I've got it working well enough for my purposes, so thank you for your time and patience! –  J W Aug 6 '12 at 20:30
    
@JW: Consider looking this answer as to how you should declare friendship inside templates, the different options and semantics. –  David Rodríguez - dribeas Aug 6 '12 at 20:42
    
@JW, seeing as you accepted this as your answer, how about an upvote? ;) –  anthony-arnold Aug 22 '12 at 2:03

It's not the 4th line that has the error, it's the 3rd one. The compiler is looking for a built in that takes a float on the left-hand side, and it can't find one. You're going to need to define a free function like:

template <typename T> Vector<T> operator*(T scalar, const Vector<T>& obj);
share|improve this answer
    
Yeah, like I said in the original question, I know it's the 3rd line that is causing the error. At any rate, I changed the definitions and implementation of the overload to what you said, and now I get: Error 1 error LNK2019: unresolved external symbol "class Vector<float> __cdecl operator*(float,class Vector<float> const &)" (??D@YA?AV?$Vector@M@@MABV0@@Z) referenced in function _main C:\Users\D03457489\Desktop\UVCTester\UVCTester\main.obj UVCTester I think it's a step in the right direction, but now the compiler doesn't seem to want to match the definition to the implementation. –  J W Aug 2 '12 at 21:14
    
Sorry, I mis-read which line you thought was in error. I thought I saw "The fourth line in main gives me an error." So now, you have a linker error instead of a compiler error. This means that the compiler is perfectly happy with the function declarations you have, but it's not able to locate a definition for one of the functions that you have declared. In this case, it can't find a function template instance where typename T = float. –  jwismar Aug 3 '12 at 18:03
    
Try adding an explicit intantiation of your free operator* for float. The declaration you add will look like: template Vector<float> operator*<float>(float scalar, const Vector<float>& obj); –  jwismar Aug 3 '12 at 18:12

operator* is a binary operator, it needs two arguments, which means that you can implement it as either a member function that is applied to the left hand side and takes an argument (the right hand side) or as a free function that takes two arguments. It is usually better to implement it as a free function. More so when you want to be able to implement double*Vector<T> since the left hand side is not a class. The signature of that overload would be:

template <typename T>
Vector<T> operator*( T d, Vector<T> v );

To which you might want to add:

template <typename T>
Vector<T> operator*( Vector<T> v, T d );
share|improve this answer

You need to define a function that allows a scalar on the LHS of the *. This is relatively easy to implement, fortunately:

template <typename T>
Vector<T> operator*(const T scale, const Vector<T> &v) {
    Vector<T> result = v;
    return result * scale;
}

Your other function that did component wise multiplication between two Vectors was improperly declared and implemented. It doesn't need to be a friend:

/*friend*/ Vector<T> operator*(const Vector<T>& obj);

And you implement it as a method of the class:

template <typename T>
Vector<T> Vector<T>::operator*(const Vector<T>& obj) {
    Vector<T> result = Vector<T>();

    for (int i=0; i<DIMS; ++i) {
        result.component[i] = obj.component[i] * component[i];
    }

    return result;
}
share|improve this answer
    
I don't have a function doing component-wise multiplication of two Vectors. I have a dot product and cross product function that wasn't listed in the question's code, but those both work fine and are correctly implemented. I think you're confusing Vector * Vector with the * overload for multiplying by a scalar. –  J W Aug 2 '12 at 21:24
    
@JW: Sorry, I make assumptions about the code I read when i don't fully understand it. The last function in the source listing you provided doesn't compile, and seems out of place, and if it is supposed to do a cross product, it needs to return a matrix, not a vector. Regards –  jxh Aug 2 '12 at 21:32
    
Yeah, the function implemented outside of the class definition was my first attempt at overloading operator*(T, Vector<T>) which is implemented improperly. I've since changed it based on jwismar's suggestion, and am now trying to resolve a related issue. I can see how that could be confusing; in hindsight it does look like I was trying to multiply to vectors. In semi-related semantics, the cross product of two vectors returns a vector perpendicular to both source vectors, not a matrix. Though, technically a vector can be considered a one-dimensional matrix, so you're right in a way. :) –  J W Aug 2 '12 at 22:51
    
@JW: Doh! You're right, I always have this visual image of the determinant, and keep thinking its a matrix. Regards –  jxh Aug 2 '12 at 22:54

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