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For some strange reason, I can't get the template arguments in this one piece of code to implicitly cast to a compatible type.

#include <type_traits>

template <typename T, unsigned D>
struct vec;

template <>
struct vec<float, 2> {
    typedef float scalar;
    static constexpr unsigned dimension = 2;

    float x, y;
    float&       operator[] (unsigned i)       { return (&x)[i]; }
    float const& operator[] (unsigned i) const { return (&x)[i]; }
};


template <typename L, typename R>
struct add;

template <typename L, typename R, unsigned D>
struct add<vec<L, D>, vec<R, D>> {
    typedef vec<L, D> left_type;
    typedef vec<R, D> right_type;
    typedef vec<typename std::common_type<L, R>::type, D> return_type;

    add(left_type l, right_type r)
        : left(l),
          right(r)
    {}

    operator return_type() const
    {
        return_type result;
        for (unsigned i = 0; i < D; ++i)
            result[i] = left[i] + right[i];
        return result;
    }

    left_type  left;
    right_type right;
};


template <typename L, typename R, unsigned D>
add<vec<L, D>, vec<R, D>>
operator+(vec<L, D> const& lhs, vec<R, D> const& rhs)
{
    return {lhs, rhs};
}


int main()
{
    vec<float, 2> a, b, c;
    vec<float, 2> result = a + b + c;
}

Fails with:

prog.cpp: In function 'int main()':
prog.cpp:55:36: error: no match for 'operator+' in 'operator+ [with L = float, R = float, unsigned int D = 2u](((const vec<float, 2u>&)((const vec<float, 2u>*)(& a))), ((const vec<float, 2u>&)((const vec<float, 2u>*)(& b)))) + c'

So if I'm correct, the compiler should see the code in the main function as this:

  • ((a + b) + c)
  • compute a + b
  • cast the result of a + b from add<...> to vec<float, 2> using the conversion operator in add<...>
  • compute (a + b) + c

But it never does the implicit cast. If I explicitly cast the result of (a + b) to a vec, the code works fine.

share|improve this question
    
That is an awful lot of code to wade through. Are you able to simplify your example? –  Oliver Charlesworth Jun 21 '11 at 22:21
    
@Oli I'll see what I can do. –  vedosity Jun 21 '11 at 22:28
5  
@Oli: Actually this is a pretty much boiled-down and straight-forward expression template implementation. This contains almost no algorithmic code, it's mostly the mechanics to make this work. I really don't see what's to criticize here. –  sbi Jun 21 '11 at 22:31
    
@sbi: The problem is that I'd like to help, but I'm tired and really don't want to read all that code! Oh well... –  Oliver Charlesworth Jun 21 '11 at 22:32
    
@sbi I've actually been trying to figure out exactly what this is called. I knew I had seen it before, but I couldn't remember the name. Thanks! –  vedosity Jun 21 '11 at 22:44

2 Answers 2

up vote 5 down vote accepted

I'm going to side-step your actual problem and instead make a recommendation: Rather than writing all of this complicated boilerplate from scratch, have a look at Boost.Proto, which has taken care of all the tricky details for you:

Proto is a framework for building Domain Specific Embedded Languages in C++. It provides tools for constructing, type-checking, transforming and executing expression templates. More specifically, Proto provides:

  • An expression tree data structure.
  • A mechanism for giving expressions additional behaviors and members.
  • Operator overloads for building the tree from an expression.
  • Utilities for defining the grammar to which an expression must conform.
  • An extensible mechanism for immediately executing an expression template.
  • An extensible set of tree transformations to apply to expression trees.

See also the library author's Expressive C++ series of articles, which more-or-less serve as an (excellent) in-depth Boost.Proto tutorial.

share|improve this answer
    
I'll take a look at it, but it looks quite intimidating. All I want to do is provide specializations of certain operations so that I can optimize them. Like, for example, (a * b) + (c * d) can be optimized with SIMD. So, I would override add<mul<vec, vec>, mul<vec, vec>> to call vDSP_vmma (I'm using vDSP for SIMD optimizations). –  vedosity Jun 22 '11 at 0:54
    
@franticfantom : Intimidating compared to writing expression templates from scratch? ;-] If you follow the tutorial, I think you'll find the number of lines of code for a Proto-based implementation to be an order of magnitude less than a hand-written expression template, plus you'll run into far fewer idiosyncrasies like the one that prompted this question to begin with. :-] –  ildjarn Jun 22 '11 at 1:15
1  
@franticfantom : Also, you should bug Joel Falcou about the current state of NT2, which I understand is being rewritten around Boost.Proto and may consequently perfectly solve your problem. –  ildjarn Jun 22 '11 at 1:16
    
@ildjarn: I, too, often preferred template error messages from my own mess over those which some boost code would vomit at me. –  sbi Jun 22 '11 at 7:49
    
@sbi : Given that Eric Niebler is leading the crusade to improve library error messages, I'll warrant that Boost.Proto yields easier to understand errors than anyone else's expression template code. "Bad template errors are library bugs and should be reported as such." Indeed, ease of debugging (via well-commented, well-placed static assertions) is touted as one of the primary reasons to use Boost.Proto in the first place. No offense regarding your own code implied. ;-] –  ildjarn Jun 22 '11 at 13:19

Most conversions are not used during template argument deduction.

You rely on template argument deduction when you call your operator+ overload: it is only callable where both arguments are of type vec<...>, but when you try to call it the left-hand argument is of type add<...>. The compiler is not able to figure out that you really mean for that overload to be called (and it isn't allowed to guess), hence the error.

share|improve this answer
    
aka, write the operator+ twice. :/ –  Xeo Jun 21 '11 at 22:41
    
Four times: (1) vec + vec, (2) vec + add, (3) add + vec, (4) add + add. All four combinations are possible: v + v, (v + v) + v, v + (v + v), and (v + v) + (v + v). Alternatively (and preferably), if you have your classes in a namespace, you should be able to relax the restrictions on the template (i.e., have your operator+ take any arbitrary T and U instead of vec<...> and a vec<...>) and let ADL do the right thing. –  James McNellis Jun 21 '11 at 22:43
    
@James The first method becomes impossible when I add subtract, multiply, divide, etc. The latter I've had a little bit of trouble with, but I still have some approaches left to try. If I make operator+ take T and U, that means I need to specialize add<L, R> to simplify expressions on the left and right side, correct? –  vedosity Jun 21 '11 at 22:54
    
I'll have to think about this a bit. For a quick answer, someone else would know better than me (anyone else, probably :(). I've not really used expression templates. I'll think about it though. (You might want to unaccept this if you want to get a better answer to the "what should I do to make this work?" question; a lot of people avoid answering questions with an accepted answer.) –  James McNellis Jun 21 '11 at 22:59
1  
@Alf: Well, I'm not an expert on the subject and the important thing is that the OP gets the best possible answer. I have enough "points" as it is :-). –  James McNellis Jun 22 '11 at 3:03

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