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I'm currently in the process of changing the way I access my data structures, and I'm reviewing one of two solutions in the general case for vectors of vectors.

My incentive is simple; I want cache locality without giving up my interfaces.

I know the max-size of my vectors at compile time, but they won't always be reaching the max. Common case is about 80%, and the total size of each vector is to be relatively small. If I reach that max, I have made an error in logic somewhere, and want it to throw an error.

The first solution that came to mind, was to use a Pool allocator with std::vector, seemed like a good idea, but maybe a bit messy; having not used allocators properly before, I wasn't too sure of the solution. I'm not much of a fan for storing the data separate to its owners, and I want the implementation to be as transparent as possible.

The second solution works great for me at the moment, but I want to make it a little bit less in line. At the moment, it is thus:

class Foo {
public:
        std::array<Bar, 10> bars;
        size_t used;

        // std::vector<Bar> bars; // reserved to 10... maybe

        void add(int var1, int var2) {
                if (used >= bars.size()) throw "Error";
                bars[used] = Bar(var1, var2);
                ++used;

                // std::vector alternative
                // bars.push_back(Bar(var1, var2));
        }
        void remove(size_t idx) {
                bars[idx] = bars.back();
                --used;

                // bars.back().~Bar(); // should happen, not sure if safe

                // std::vector alternative
                // bars[idx] = bars.back();
                // bars.pop_back();
        }
}

Which, as mentioned, works great. However, if I wanted to move this solution elsewhere, I'd rather not have to implement it again, and have proper semantics in terms of destruction (similar to that of an actual vector).

So, I was wondering what a good solution could be? Currently, I've started wrapping an std::array, but it is starting to get messy, and I'm sure this is solved problem.

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1  
By letting your interfaces take a vector, which they cannot add to, you break them. They should not take a vector in the first place but array. Or am I missing something? –  stijn Jul 4 '12 at 9:35
    
At the moment, I am using a std::vector with the necessary space reserved. The point is they can add/remove at their will, but should never go over the max limit. This isn't strictly enforced at the moment, as it doesn't really matter, its just something I can take advantage of. –  dcousens Jul 4 '12 at 9:37
    
So I guess "change your interface" is not a desirable solution? –  Oliver Charlesworth Jul 4 '12 at 9:37
    
@Oli Charlesworth, given the current switch over effort between solutions is simply changing to the std::array from std::vector and adding a count for the number of elements used; I was hoping to not have to do anything more; but if I want to do this elsewhere in future, this would be a great asset to use; as I know many cases where I know the max size at runtime, wanting the flexibility of a vector, but the locality of an array (especially if encapsulated in an object, among 1000's of others which are iterated often, therein thrashing the cache if allocated everywhere). –  dcousens Jul 4 '12 at 9:40
1  
Your use of decltype is fine; that's a sensible style for a wrapper template. Your use of throw is problematic; surely you can throw proper exceptions? Your calling destructors (this->back().~T();) is wrong; you should be keeping the elements in a valid state and using this->back() = T() to reset to a default-initialized state. –  ecatmur Jul 4 '12 at 9:54

2 Answers 2

up vote 2 down vote accepted

See this link for several options for fixed-size data structures with a vector-like interface. In particular, boost::auto_buffer and eastl::fixed_vector seem viable options for your code.

Yet another alternative is to use Hinnant's stack allocator with the regular std::vector, but MSVC++ has some trouble compiling it.

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Boost has a MultiArray class intended for this purpose.

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