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Is this undefined behavior?

std::array<int, 5> x = {3, 5, 1, 2, 3};
std::array<int, 3>& y = *reinterpret_cast<std::array<int, 3>*>(&x[1]);
for(int i = 0; i != 3; i++) {
    std::cout << y[i] << "\n";
}

Maybe yes, but I really feel like there should be a safe way to slice std::arrays.

EDIT: Following Radek's suggestion:

template<unsigned N, unsigned start, unsigned end, typename T>
std::array<T, end - start>& array_slice(std::array<T, N>& x)
{
    static_assert(start <= end, "start <= end");
    static_assert(end <= N-1, "end <= N");
    return *reinterpret_cast<std::array<T, end - start>*>(&x[start]);
}

EDIT: Ok, I decided that I'm unhappy with std::arrays and will move to something else, any ideas?

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but I really feel like there should be a safe way to slice std::arrays write a template function array_cast. –  user1203803 May 25 '12 at 20:13

2 Answers 2

Yes, that is undefined behavior. You're taking one type and reinterpret_casting it to another. Indeed, the use of the reinterpret_cast should be a big red flag for "here there be dragons!"

As for slicing arrays, that's not going to happen. A std::array contains values; a slice of this would contain references to part of that array. And therefore, it would not be a std::array. You can copy slices of arrays, but not using std::array. You would need to use std::vector, since it allows the calling of constructors, as well as construction from a range of values. Remember: std::array is just a nicer wrapper around a C-style array.

The committee is looking into a template array_ref<T> class, which is exactly what it says: a reference to some segment of an array of type T. This could be a regular C-style array, a std::vector, a std::array, or just some memory allocated with new T[]. There are some library implementations of the class already, but nothing is standardized yet.


Following Radek's suggestion:

Hiding the undefined behavior in a function does not make it defined behavior. You can try to pretend that it isn't undefined, but it still is. The moment you use that reinterpret_cast, you willingly give up living in C++-land.

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I agree with what you say, but I think std::array in the standard is basically broken without slicing. –  Giovanni Funchal May 25 '12 at 20:33
1  
@Giovanni: It's broken only if you're trying to use it for something it's not meant to be used for. It's like saying that std::list is broken because its elements are not stored contiguously, or that std::map is broken because it doesn't offer O(1) lookup. You're expecting a hammer to function as a screwdriver. –  Nicol Bolas May 25 '12 at 20:40
3  
@Giovanni: "something that was perfectly valid with C arrays is not valid with C++ ones" No, it wasn't. It was only "valid" with C arrays when those arrays decayed into pointers. At which point they stop being arrays; they're pointers. You cannot take an int[5] and turn it into an int[3]; you can turn it into an int*, but that's a different construct. What std::array does is remove the decaying into pointers, so that arrays remain arrays at all times (unless you explicitly decay them, at which point you willingly give up safety). That's what array_ref is all about. –  Nicol Bolas May 25 '12 at 22:07
2  
@Giovanni: This discussion is about C++11, not C99. And in C++11, casting from int[5] to int[3] is undefined behavior. –  Nicol Bolas May 26 '12 at 3:05
1  
@GiovanniFunchal Are you referencing 6.5.6 Additive Operators? If so, this doesn't support that casting from int[5] to int[3] is well-defined in C99. –  Luc Danton May 26 '12 at 6:30

What about a placement new?

#include <array>
#include <iostream>
#include <iterator>

template<typename T, std::size_t N>
struct array_slice : public std::array<T,N> {
    ~array_slice() = delete; 
};

int main() {
    std::array<double,4> x_mu{0.,3.14,-1.,1.};
    std:: cout << &x_mu << std::endl;

    {
        auto slicer = [] (std::array<double,4>& ref) {
            array_slice<double,3>* p = new (&ref) array_slice<double,3>;
            return p;
        };    

        std::array<double,3>& x_  = *slicer(x_mu);
        std::copy(x_.begin(),x_.end(),
              std::ostream_iterator<float>(std::cout," "));
        std:: cout << std::endl;
        std:: cout << &x_ << std::endl;
    }

    std::copy(x_mu.begin(),x_mu.end(),
              std::ostream_iterator<float>(std::cout," "));
}
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