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# C++ Filling an 1D array to represent a n-dimensional object based on a straight line segment

READ FIRST: I have rewritten this question with the help of a friend to be hopefully more specific in what is required. It can be found here

I'm not very clear on n-cubes, but I believe they are what I am referring to as the square family.

New Question Wording:
Perhaps I wasn't clear enough. What I'm asking, is how to set a 1D array to hold data for a cloud of a number of evenly-spaced points that form the most complete representation of the space occupied by an n-cube of n dimensions.

In 1D this would simply fill the array with a series of 1D co-ordinates creating a line segment. A 1-cube.

In 2D however this would fill every first co-ordinate to the x value and the every second to the y, generating the most complete square possible for that spacing and number of particles. The most complete possible 2-cube.

In 3D, this would fill ever first with x, every second with y and every third with z, generating the most complete possible cube for that spacing and number of particles. The most complete possible 3-cube.

I wish to be able to do this for any reasonable combination of number of particles, spacing and dimensions. Ideally I could do at least up to a 4-cube using a generic fill algorithm for all n-cubes initialised to double * parts_

Yet another definition of what kind of object I'm trying to represent:
In 1D its a line. Sweep it through the second dimension it becomes a square. Sweep that square through the third, it becomes a cube. I presume this behaviour extends past three dimensions and wish to store a cloud of points representing the space taken up by one of these objects of any reasonable dimension, spacing and number of points in a 1D array.

The original wording of the question:
I'm struggling to find a good way to put this question but here goes. I'm making a system that uses a 1D array implemented as double * parts_ = new double[some_variable];. I want to use this to hold co-ordinates for a particle system that can run in various dimensions.

What I want to be able to do is write a generic fill algorithm for filling this in n-dimensions with a common increment in all direction to a variable size. Examples will serve best I think.

Consider the case where the number of particles stored by the array is 4

In 1D this produces 4 elements in the array because each particle only has one co-ordinate.
1D:
{0, 25, 50, 75};
In 2D this produces 8 elements in the array because each particle has two co-ordinates..
2D:
{0, 0, 0, 25, 25, 0, 25, 25}
In 3D this produces 12 elements in the array because each particle now has three co-ordinates
{0, 0, 0, 0, 0, 25, 0, 0, 50, ... }

These examples are still not quite accurate, but they hopefully will suffice.

The way I would do this normally for two dimensions:

int i = 0;
for(int x = 0; x < parts_size_ / dims_ / dims_ * 25; x += 25) {
for(int y = 0; y < parts_size_ / dims_ / dims_ * 25; y += 25) {
parts_[i] = x;
parts_[i+1] = y;
i+=2;
}
}


How can I implement this for n-dimensions where 25 can be any number?

The straight line part is because it seems to me logical that a line is a somewhat regular shape in 1D, as is a square in 2D, and a cube in 3D. It seems to me that it would follow that there would be similar shapes in this family that could be implemented for 4D and higher dimensions via a similar fill pattern. This is the shape I wish to set my array to represent.

EDIT: Apparently I'm trying to fill this array to represent the n-cube with the fewest missing elements for the given n, spacing and number of elements. If that makes my goal any clearer.

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Please format your code using the 101010 button on the edit page. – sbi Jun 9 '10 at 6:21
Cheers. That's a lot easier than what I was trying to do with block quotes/escapes. – Ben Jun 9 '10 at 6:29
Why do you want to store a multi dimension array in a single dimension array, and not use an array with the appropriate dimension count? – Rudi Jun 9 '10 at 6:39
Because I want a generic data member (and filling method, which is what the question is about) for all the possible particle sets that I stated, not a single example. – Ben Jun 9 '10 at 6:40
Please use std::vector instead of raw arrays. – avakar Jun 9 '10 at 6:48

As I understand it, you aren't sure how to process every element in multi-dimensional array (stored as 1D array), where N is arbitrary number of dimensions.

Processing of multidimensional array with arbitrary number of dimensions goes like this:

#include <stdio.h>
#include <vector>
using std::vector;

int main(int argc, char** argv){
int index = 0;
const int numDimensions = 10;
vector<int> counters;
vector<int> dimensionSizes;
counters.resize(numDimensions);
dimensionSizes.resize(numDimensions);

for (int i = 0; i < numDimensions; i++){
counters[i] = 0;
dimensionSizes[i] = 13;
}

long long arraySize = 1;
for (int i = 0; i < numDimensions; i++)
arraySize *= dimensionSizes[i];

printf("%d\n", arraySize);
for (int elementIndex = 0; elementIndex < arraySize; elementIndex++){
fprintf(stderr, "element %08d: ", elementIndex);
for (int i = 0; i < numDimensions; i++)
fprintf(stderr, "%04d ", counters[i]);
fprintf(stderr, "\n");
//at this point you have 1D element index
//AND all n-dimensional coordinates stored in counters array.
//Just use them to for your data
//"counters" is N-dimensional coord. XYZW etc.

for (int i = 0; i < numDimensions; i++){
counters[i] = counters[i] + 1;
if (counters[i] < dimensionSizes[i])
break;
else
counters[i] = 0;
}
}

return 0;
}


Just make an array of structs you need to access in N dimensions, and access them using calculated index somewhere after comment. It is better to use array of structs representing the data you want to be stored in N dimensionals. If you don't want to do that, you'll have to multiply elementIndex by number of doubles per element.

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Not really the question I asked. Thanks for your solution however. I rewrote my question in hopes of being clear. It's just hard when you can grasp a concept but do not know the correct name for it. I think n-cubes is right though. – Ben Jun 9 '10 at 6:55