# Indexing a 3 dimensional array using a single contiguous block of memory

vector<bool> working_lattice(box.rect.length * box.rect.height * box.rect.width);

How do I access working_lattice[1][5][3] using the style of declaration above?

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I know it would look more like working_lattice[? * ? * ? + ?]. But how? –  unixman83 Apr 14 '12 at 6:02
Ignoring, for the moment, the oddities associated with vector<bool>, I showed a 3D matrix that you can access using matrix[a][b][c] notation in an old answer. For the moment, it passes the size as a template parameter, but it wouldn't take a huge amount to pass it as a ctor parameter instead. If I were writing it today, I'd undoubtedly use an std::vector instead of an actual 3D array, which would make it trivial to pass the size to the ctor. –  Jerry Coffin Apr 14 '12 at 6:10
Three nested vectors would be stored as one contiguous block of memory as well, since each vector itself is stored in a contiguous block of memory. This would also let the machine do the multiplication work for figuring out the offset for you. –  Frerich Raabe Apr 14 '12 at 6:28

You need to access it as

(i * length * height) + (j * height) + k

working_lattice[(i * box.rect.length * box.rect.height) + (j * box.rect.height) + k);

or

working_lattice[(1 * box.rect.length * box.rect.height) + (5 * box.rect.height) + 3);

EDIT: Since you mentioned x, y, z elsewhere

working_lattice[(x * box.rect.length * box.rect.height) + (y * box.rect.height) + z);
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Can the downvoter comment as to why? He already accepted it as the answer too –  josephthomas Apr 15 '12 at 0:59

This depends on whether you're using row-major or column-major ordering. Row-major is more typical in C/C++, but you can do either if you're doing it manually.

In row-major ordering, to get to the i, j, k'th element, you need to go through box.rect.height * box.rect.width * i elements to get up to the ith row, plus box.rect.width * j elements to get to the jth column of that row, plus k to get back to the kth element depthwise. To be super-explicit:

const size_t n_x = box.rect.length;
const size_t n_y = box.rect.height;
const size_t n_z = box.rect.width;
working_lattice[1 * n_x * n_z + 5 * n_z + 3]

This is obviously pretty annoying, so you might want to define an inline function or something to help out.

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