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I would like to be able to iterate through the grid elements with a set step size. The fun part of this problem is that the grid will be rotated. I have developed an algorithm to do this and it is successful for some cases. The image below specifies the problem:

enter image description here

The conditions of the problem are that a grid spacing will be provided that is a factor of the grid length and width (As a side note the grid can be rectangular). The Algorithm must iterate through the grid and print out where it is. Here is some code and an example of it working:

int main() {
vector< vector<double> > bound;
vector<double> point;

point[0] = 6; point[1] = 10;
point[0] = 4; point[1] = 0;
point[0] = 10; point[1] = 6;

double d = 0.5;
double x, y;
int countx = 0, county = 0;
for (double i = bound[0][0]; i < bound[2][0]; i+=d) {
    //std::cout << "I: " << i << std::endl;
    for (double j = bound[0][1]; j < bound[1][1]; j+=d) {
        //std::cout << "J: " << j << std::endl;
        x = i+d+(double)county*d;
        y = j-(double)countx*d;
        std::cout << "i, j, x and y: " << i << "\t" << j << "\t" << x << "\t" << y << std::endl;
    std::cout << "new Row--------------------\n";
    county = 0;

The code above works and prints correctly the grid elements, ie:

x and y: 4, 0.5
x and y: 4.5, 1

However when trying a rectangle with bounds:

[(0.5, 6), (3, 8.5), (5.5, 1), (8, 3.5)]

and a step size (d) of 1

It iterates to outside the rectangle bounds. I can see why this is happening, the iterator condition in the for loop will not contain it because of the extra +d.

My question is, is there a better way to approach this problem and how would i go about it?

Does anyone know if this has been implemented before and has some source code?

Cheers for the help.


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Are all the points on the grid at integer values or do you need to use double values here? Have you considered modelling this as a x-y grid of integer values that is rotated and transformed. You could use a matrix to describe the transformation that the grid is in and then do your calculations pushing the 2d vector through the transformation matrix before printing it's value. –  Will Apr 30 '12 at 7:24
Hi, thanks for the advice i am considering that. Also is this question really not worth any up votes? I thought i made it quite detailed and provided a reasonably intriguing question? –  Ben Apr 30 '12 at 22:45
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2 Answers

I think you need to split it up into parts. And it may be easier to define a 2D Point structure and an std::vector (or std::array if the size is known at compile time).

struct Point { 
  // you may or may not want to make sure these are initialized to 0. by default
  double x;
  double y;
std::vector<Point> rotatedPoints;

Then, define a function that performs the rotation in each point:

void rotate(Point& point) { .... }

Then, do the loop over your chosen (x,y) coordinates, creating a Point, rotating it, and inserting it into the vector or array. This way, you create a rotated grid, and iterate through it. You can also chose to create the grid first, iterate through it and rotate each time.

The nice way to do this would be to define a point rotation type (matrix or so) and define the appropriate multiplication operators.

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So do you mean basically, make a non rotated grid and then use a homogeneous rotation matrix to transform the points? –  Ben Apr 30 '12 at 22:36
@ben yeah, but the main point is to split the problem up. That allows you to test your rotation on single points, and to decide whether you want to generate non-rotated points, rotate them and store them, store two grids, store a non-rotated one and only rotate when you want to look at one of the points, etc. It is important to have floating points numbers for the coords though, integers won't do. –  juanchopanza May 1 '12 at 4:54
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up vote 0 down vote accepted

The Way I ended up going about it was to calculate the length and width of the rectangle by Pythagoras rule on two of the sides. I then made a grid on a virtual rectangle which is aligned with its bottom corner at the origin. Then by using a pre-developed library for matrix rotations and translations, I transformed the points individually by translating them to by the displacement to the bottom left corner and rotating them to the calculated angle of the rectangle.

This is similar to the above solution but uses a full transformation matrix. The answer ended up being simpler then I thought it would be.

Thanks for the help.

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