# Algorithm to access the tiles in a matrix (game map) that are in a disc

I am developping a tile mapped game.
I need to access the tiles that are in a disc, with a given radius and centered on a given point.

Accessing the tiles that are in a square is easy, we only need to use two loops :

``````for(int i=xmin; i<xmax; ++i)
for(int j=ymin; j<ymax; ++j)
// the tile map[i][j] is in the square
``````

But how do you access the tiles that are in a given disc (full circle) ?

EDIT:
I mean, I could process each tile in a bounding rectangle (bounding the disc), and determine whether or not a tile in that rectangle is in the disk, by using `(x-x0)²+(y-y0)²<R²`, but with that algorithm, we would explore useless tiles.
When using a large radius, there are many tiles to process, and it will be slow because calculating `(x-x0)²+(y-y0)²<R²` many times is heavy
What I want is an algorithm more efficient than this one.

EDIT2:
I don't need a perfect disk

-
You must determine the correspondence of a square tile to a tile in the circle; what is the area of the circle that is equal to a given square tile? – Rubens Dec 25 '12 at 23:14
Are x0, y0 integers? – Alexander Chertov Dec 26 '12 at 6:59
yes x0 and y0 are integers – user1493046 Dec 26 '12 at 14:44

You can use the Bresenham's circle Algorithm (section 3.3, Scan Converting Circles) (it uses integer arithmetic only, is very accurate and process fourth part of the whole circle to produce the entire circumference) in your tile matrix to detect those tiles that forms the circumference, then trace lines between them from up-to-down (or left-to-right):

The following is a pseudo implementation of the circle algorithm:

``````static void circle(int x0, int y0, int x1, int y1) {
// Bresenham's Circle Algorithm
int x, y, d, deltaE, deltaSE;
bool change_x = false;
bool change_y = false;

if( x0 > x1 ) {
// swap x values
x = x0;
x0 = x1;
x1 = x;
change_x = true;
}
if( y0 > y1 ) {
// swap y values
y = y0;
y0 = y1;
y1 = y;
change_y = true;
}

int dx = x1 - x0;
int dy = y1 - y0;

radius = dx > dy ? (dy >> 1) : (dx >> 1);

x = 0;
deltaE = 3;
// -2 * radius + 5
deltaSE = -(radius << 1) + 5;

while(y > x) {
if(d < 0) {
d += deltaE;
deltaE  += 2;
deltaSE += 2;
x++;
} else {
d += deltaSE;
deltaE  += 2;
deltaSE += 4;
x++;
y--;
}
checkTiles(x, y, center_x, center_y);
}
}

void checkTiles(int x, int y, int center_x, int center_y) {
// here, you iterate tiles up-to-down from ( x + center_x, -y + center_y) to (x + center_x, y + center_y)
// in one straigh line using a for loop
for (int j = -y + center_y; j < y + center_y; ++j)
checkTileAt(x + center_x, j);

// Iterate tiles up-to-down from ( y + center_x, -x + center_y) to ( y + center_x,  x + center_y)
for (int j = -x + center_y; j < x + center_y; ++j)
checkTileAt(y + center_x, j);

// Iterate tiles up-to-down from (-x + center_x, -y + center_y) to (-x + center_x,  y + center_y)
for (int j = -y + center_y; j < y + center_y; ++j)
checkTileAt(-x + center_x, j);

// here, you iterate tiles up-to-down from (-y + center_x, -x + center_y) to (-y + center_x, x + center_y)
for (int j = -x + center_y; j < x + center_y; ++j)
checkTileAt(-y + center_x, j);
}
``````

With this technique you should process only the required tiles (and after processing only a quarter of the circle), none unnecessary tiles would be checked. Beside that, it uses integer arithmetic only, wich makes it really fast (the deduction and explanation can be found in the provided book link) and the generated circumference is proven to be the best approximation for the real one.

-

We can do a linear scan through `x`, calculating the range of `y`. Then we only have to scan through the tiles that are in the circle, like in this badly drawn picture. (Christmas colors?)

If we have a circle with radius `r` and an x-position `x`, we can figure out the maximum length of `y`:

``````y = sqrt(r * r - x * x);
``````

So the code for iterating through the tiles would look like:

``````int center_x = (xmin + xmax) / 2;
int center_y = (ymin + ymax) / 2;

for(int x = xmin; x <= xmax; x++) {
int ydist = sqrt(r * r - (center_x - x) * (center_x - x));
for(int y = center_y - ydist; y <= center_y + ydist; y++) {
// these are the tiles in the disc
}
}
``````

Here's some Python code:

``````from Tkinter import *
from math import *

tk = Tk()
g = Canvas(tk, width=500, height=500)
g.pack()

x0 = 25 # x center
y0 = 25 # y center
t = 10  # tile side length

for x in range(x0 - r, x0 + r + 1):
ydist = int(round(sqrt(r**2 - (x0 - x)**2), 1))
for y in range(y0 - ydist, y0 + ydist + 1):
g.create_rectangle(x * t, y * t, x * t + t, y * t + t
, fill='#'
+ '0123456789ABCDEF'[15 - int(15 * sqrt((x0 - x)**2 + (y0 - y)**2) / r)]
+ '0123456789ABCDEF'[int(15 * sqrt((x0 - x)**2 + (y0 - y)**2) / r)]
+ '0')

g.create_oval((x0 - r) * t, (y0 - r) * t, (x0 + r) * t + t, (y0 + r) * t + t, outline="red", width=2)

mainloop()
``````

And the resulting disk:

Not perfect at the ends, but I hope it works well enough for you (or you can modify it).

-
Unfortunatly, this will be too slow to do what I need to do. I really need something fast. Your answer might help other people though. Thanks. – user1493046 Dec 26 '12 at 15:02
@user1493046 You do want to access every tile in the disc, right? Is it the `sqrt` that's too slow? – irrelephant Dec 26 '12 at 15:08
@user1493046 Accessing every tile in the disc is inevitably `O(R^2)`, R = radius, since there are approximately pi * R^2 tiles. – irrelephant Dec 26 '12 at 15:14

Excluding tiles outside the square wont be much faster. I would just use a square but ignore tiles outside the circle. (e.g. by checking how far the tile is from the circle center)

``````for(int i=xmin; i<xmax; ++i):
for(int j=ymin; j<ymax; ++j):
if map[i][j] not in the circle:
break
// the tile map[i][j] is in the square
``````

A rough estimate on performance overhead:

``````Area Square = 2*r*2*r
Area Circle = pi*r*r

Area Square / Area Circle = 4/pi = 1.27
``````

This means using a square instead of a circle is only `1.27 times slower` (assuming using a circle doesn't have its own inefficiencies)

Also because you will likely perform some operation on the tiles, (making the iterations involving tiles in the circle much slower) it means the performance gain will go down to almost 0 using a circle layout instead of a square layout.

-

Use a bounding octagon. It's the bounding square with corners cut off. You need these tests for if a point (any corner of a tile) is in that shape. Put this inside the 2D loop.

``````abs(x) < R
abs(y) < R
abs(x)+abs(y) < sqrt(2)*R
``````

Precalculate sqrt(2)*R, of course.

This isn't the same as a circle, obviously, but cuts down nicely the amount of wasted space compared to a square.

It'll be hard to generate a loop that goes over only the tile centers or tile corners perfectly, without needing some sort of test in the loop. Any hope for writing such loops would be from use Bresenham's algorithm.

-
So if I understood you, I have to use a code to explore a square, then insert your conditions into that code to narrow the area to an octagon, and then use the condition x²+y²<R² to now if a square is in the disc ? That's a greedy solution, isn't it? – user1493046 Dec 26 '12 at 0:47