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In my code, I have to consider an array of arrays, where the inner arrays are of a fixed dimension. In order to make use of STL algorithms, it is useful to actually store the data as array of arrays, but I also need to pass that data to a C library, which takes a flattened C-style array.

It would be great to be able to convert (i.e. flatten) the multi-dimensional array cheaply and in a portable way. I will stick to a very simple case, the real problem is more general.

struct my_inner_array { int data[3]; };
std::vector<my_inner_array> x(15);

Is

&(x[0].data[0])

a pointer to a continuous block of memory of size 45*sizeof(int) containing the same entries as x? Or do I have to worry about alignment? I am afraid that this will work for me (at least for certain data types and inner array sizes) but that it is not portable.

  1. Is this code portable?
  2. If not, is there a way to make it work?
  3. If not, do you have any suggestions what I could do?
  4. Does it change anything at all if my_inner_array is not a POD struct, but contains some methods (as long as the class does not contain any virtual methods)?
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Is it appropriate to use such a big, flat array in the first place and pass [p, p + stride) chunks of it where appropriate? Standard algorithms make the point to abstract whether they operate on a whole array or parts of it. –  Luc Danton Apr 11 '12 at 10:42
    
@LucDanton: For example, I would like to apply a function to an array of vertices. I would like to use std::transform(coord.begin(), coord.end(), values.begin(), f); where f is a std::function<double (my_inner_array const&)>. I see no other way to apply std::transform or other STL algorithms directly. –  Markus Mayr Apr 11 '12 at 11:03
    
std::transform(coord.begin(), coord.end(), values.begin(), adapt(f)) where adapt(f) returns a functor that fetches the begin and end parts of the element ranges to feed them to f (assuming it can be written to write with pairs of iterators and not just arrays to begin with). Or perhaps you can write a generic f that can deal with that itself. If you use something like Boost.Range then you don't need the adapt step either. –  Luc Danton Apr 11 '12 at 11:21
    
@LucDanton: Ah, that's quite a nice approach. I thought about writing a custom iterator instead, but this approach looks quite clean. Thank you! I also must check out Boost.Range. –  Markus Mayr Apr 11 '12 at 11:48
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1 Answer 1

up vote 2 down vote accepted

1 Theoretically no. The compiler may decide to add padding to my_inner_array. In practice, I don't see a reason why the compiler would add padding to a struct that has an array in it. In such a case there's no alignment problem creating an array of such structs. You can use a compile time assert:

typedef int my_inner_array_array[3];
BOOST_STATIC_ASSERT(sizeof(my_inner_array) == sizeof(my_inner_array_array));

4 If there are no virtual methods it shouldn't make any difference.

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