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Example:

I have a function that works with vectors:

double interpolate2d(const vector<double> & xvals, const vector<double> & yvals, double xv, double yv, const vector<vector<double> > &fvals) {
    int xhi, xlo, yhi, ylo;
    double xphi, yphi;
    bracketval(xvals,xv,xhi,xlo,xphi);
    bracketval(yvals,yv,yhi,ylo,yphi);
    return (fvals[xhi][yhi]*xphi+fvals[xlo][yhi]*(1.-xphi))*yphi + (fvals[xhi][ylo]*xphi+fvals[xlo][ylo]*(1.-xphi))*(1.-yphi);
}

But now I want to call it with boost::array elements for the first 2 arguments (same with bracketval()), if std::vector and boost::array were self-implemented, I would be able to derive both from a common base class (interface-like) enforcing an implementation of operator[], since both are library-provided, is there any way to cast/specify such a restriction?

I can always resort to plain c-arrays, but it's not very neat.

Edit: FWIW, here is the original bracketval implementation:

void bracketval(const vector<double> &vals, double v, int &hi, int &lo, double &prophi){
    hi=vals.size()-1;
    lo=0;
    while(abs(hi-lo)>1) {
        int md = (hi+lo)/2;
        if(vals[md]>v) hi=md; else lo=md;
    }
    if(vals[hi]!=vals[lo])
        prophi = (v-vals[lo])/(vals[hi]-vals[lo]);
    else
        prophi = 0.5;

}
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3 Answers 3

up vote 1 down vote accepted

This works with std::vector, boost::array, built-in arrays an generally with anything that is indexable. I've also included a suggestion of how you should implement the bracketval function:

template<class Vec>
void bracketval(Vec const & xvals, double xv, int xhi, int xlo, double xphi)
{
}

template <class Vec, class VecOfVecs>
double interpolate2d(Vec const & xvals, Vec const & yvals, 
                     double xv, double yv,
                     VecOfVecs const & fvals)
{
    int xhi, xlo, yhi, ylo;
    double xphi, yphi;
    bracketval(xvals,xv,xhi,xlo,xphi);
    bracketval(yvals,yv,yhi,ylo,yphi);
    return (fvals[xhi][yhi]*xphi+fvals[xlo][yhi]*(1.-xphi))
             *yphi + (fvals[xhi][ylo]*xphi+fvals[xlo][ylo]
             *(1.-xphi))*(1.-yphi);
}

int main()
{
    {
        std::vector<double> v, w;
        std::vector<std::vector<double> > vv;
        interpolate2d(v, w, 1., 2., vv);
    }
    {
        boost::array<double, 4> v, w;
        boost::array<boost::array<double, 4>, 4> vv;
        interpolate2d(v, w, 1., 2., vv);
    }
    {
        double v[4], w[4];
        double vv[4][4];
        interpolate2d(v, w, 1., 2., vv);
    }    
}

You can even add an extra template parameter if you envision the possibility that the second vector could be of a different type that the first (e.g., the first a vector and the second a boost::array):

template <class VecX, class VecY, class VecOfVecs>
double interpolate2d(VecX const & xvals, VecY const & yvals, 
                     double xv, double yv,
                     VecOfVecs const & fvals)
share|improve this answer
    
Much clearer than mine (even if mine had worked), and close to what I meant to post in the first place - I don't know what got into me :-) –  anon Feb 10 '10 at 14:46

While this is probably overkill for your specific problem, in general you can check wether template parameters implement a certain interface by explicitly checking wether certain members are provided and some expressions are valid.
Boosts concept check library gives you a clean way to do that, but the container checking classes it provides don't help you here because Boost.Array only supports a certain subset of the sequence requirements.

What you could do though if you need a clean way to put restrictions is modelling the requirements yourself, either utilizing Boosts utilities or a similar custom approach.

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There is no way to put type restrictions on template parameters. What you could is, is define your own interface and create adaptors for all types you want to support.

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while technically true, there are ways to enforce template parameter types. For example, you can assign it to a base class, if, at compile time, this fails, it isn't a subclass of said base class and you've effectively put a restriction similar to extends in java. –  falstro Feb 10 '10 at 13:40
    
Do you know SFINAE or enable_if-paradigms? –  phresnel Feb 10 '10 at 13:51
    
@roe: well, to test inheritance you want to use pointers. An object can be assignable to another type without being a subclass, for example if it has a conversion operator overload, or the type assigned to has a non-explicit 1-arg constructor, or the types are built-in and have a standard conversion: float f = 'A'; –  Steve Jessop Feb 10 '10 at 13:52
    
@Steve: I was merely making a point, although perhaps not waterproof. There are a lot more elaborate schemes as well. Not to mention the duck-typing aspect, as it won't compile unless it contains the required methods / operators / whatever. Although, I suppose whatever solution you chose, there's no way around the utterly miserable compile errors you'll get out of it, if there's something wrong.. :) –  falstro Feb 10 '10 at 15:25

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