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I am using the midpoint circle algorithm, also known as Bresenham's, to draw concentric circles. The difference between each circle's radius and that of the next is always 1, so the final result should be a full circular area.

However, some pixels are left empty, as shown in the attached image.

I'm using Javascript to paint on an HTML5 canvas, manipulating the canvas.getContext("2d").getImageData(...).data array.

The circles are alternatively white and red, and the empty pixels are black. You might have to zoom in in order to see what I mean properly.

Bresenham concentric circles

I'm trying to add some code to the algorithm so that those pixels are filled when drawing the corresponding arc. There seems to be no reason for any of those pixels to belong to one arc rather than the next one, so I don't care if they are filled along with arcs that have an even radius or with arcs that have an odd radius (I hope I'm making myself clear).

The pixels seem to be following a pattern, but I'm clueless about what could that be. Could anyone help me find it?

function drawCircles(radius, x, y){
    var f = 1 - radius;
    var ddF_x = 1;
    var ddF_y = -2 * radius;
    var x = 0;
    var y = radius;

    //Colors
    var red = 255;       
    var green = radius%2==0?255:0;       
    var blue = radius%2==0?255:0;        

    paintPixel(x, y + radius, red, green, blue);
    paintPixel(x, y - radius, red, green, blue);
    paintPixel(x + radius, y, red, green, blue);
    paintPixel(x - radius, y, red, green, blue);    

    while(x < y){
        // ddF_x == 2 * x + 1;
        // ddF_y == -2 * y;
        // f == x*x + y*y - radius*radius + 2*x - y + 1;
        if(f >= 0) 
        {
            y--;
            ddF_y += 2;
            f += ddF_y;
        }
        x++;
        ddF_x += 2;
        f += ddF_x;    
        paintPixel(x + x, y + y, red, green, blue);
        paintPixel(x - x, y + y, red, green, blue);
        paintPixel(x + x, y - y, red, green, blue);
        paintPixel(x - x, y - y, red, green, blue);
        paintPixel(x + y, y + x, red, green, blue);
        paintPixel(x - y, y + x, red, green, blue);
        paintPixel(x + y, y - x, red, green, blue);
        paintPixel(x - y, y - x, red, green, blue);
    }

}

function paintPixel(x, y, red, green, blue){
    imageData.data[grid[y][x]] = red;
    imageData.data[grid[y][x]+1] = green;
    imageData.data[grid[y][x]+2] = blue;
    imageData.data[grid[y][x]+3] = 255; //Alpha
}
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1  
Could you post your code? –  Bergi Aug 30 '12 at 17:02
3  
That's an expected outcome, if it's not clear. –  Pointy Aug 30 '12 at 17:02
    
Since you're drawing on a canvas, you might see if it helps to make the stroke more than a pixel wide. –  Pointy Aug 30 '12 at 17:03
    
If you're drawing outward in, you could fill said arcs. –  Shmiddty Aug 30 '12 at 17:06
    
Are you drawing your circle with the center at integer coordinates? If so, what happens when you move the center by 0.5 in x and y? –  Ted Hopp Aug 30 '12 at 17:46

4 Answers 4

Bresenham's is designed to plot a line using one pixel by n-pixel areas. At 45 degrees, it will plot one pixel then another (+1,+1) to it. This gives an average thickness between the centres of the two pixels of 1/√2. An exact plot of a one pixel thick line has a thickness of 1. The black dots are due to this difference between the thickness of the Bresenham algorithm line and the true thickness.

If you extend the pixels plotted to include all pixels the centre of the true line crosses, it should not have any gaps, as its thickness will never be less than one. One way of doing this is to uses Bresenham's twice with inside and outside radii, and plotting pixels based on the difference between the two.

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To add to this -- if you were to draw a series of concentric shapes, each one exactly a single pixel wide, you'd end up with a set of diamonds, not circles. –  duskwuff Aug 30 '12 at 17:47
    
@Pete Kirkham Actually, my goal is to figure out the pattern that determines the positions of those empty pixels to increase the complexity as little as possible. There is a workaround to my problem that consists of going through the algorithm all over again adding +1 to one of the coordinates, but I'd like to avoid that. Wouldn't your suggestion increase the necessary calculations considerably as well? –  broncoAbierto Aug 30 '12 at 19:36

If you design your Bresenham-style circle drawer to compute boundary outlines instead of pixels, you can generate circles that nest perfectly. Conceptually, a boundary outline is a list of pixel edges, instead of pixel centers. This fits well with Bresenham-style operations: register a horizontal edge when incrementing the x-coordinate, and a vertical edge when incrementing the y-coordinate.

For each circle, compute two outlines: one for outer_radius, and again for (outer_radius - pen_diameter). Draw the pixels between the two outlines: with a bit of cleverness, you should be able to run both outline generators in the same loop, and do the pixel drawing online.

Of course, circles drawn with this boundary technique will look different from circles generated directly. However, IIRC, the boundary technique may be more robust than the direct technique, anyway...

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This looks like an aliasing problem for sure. Since the missing pixels seem to be more dense at 45° angles, I suspect that the root problem has to do with the distance calculations. Along the diagonal, the distance across a pixel is about 41% more than when measured along the axes. This can cause the pixel center to be further from either circle. Without seeing your code, it's hard to say more.

One fix might be to simply solid-fill the circle with one circle color and then just draw the other circle color.

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1  
Well Bresenham's algorithm is an integer pixel-by-pixel way of drawing circular curves. I don't think there are distance calculations involved, but my memory is hazy. –  Pointy Aug 30 '12 at 17:05
    
Filling the circle first is a good idea, although it won't work in other cases, where I want the colors to fade outward from the center. –  broncoAbierto Aug 30 '12 at 17:15
<canvas width="500" height="500" style="background:#000;">
</canvas>​

var canvas = $("canvas")[0];
var cen = $("canvas").width()/2;
var len = cen, i = len;
var ctx = canvas.getContext("2d");
var red = "#f00";
var white = "#fff";


for (; i > 0; i--){
    ctx.beginPath();
    ctx.arc(cen, cen, i, 0, 2 * Math.PI, false);
    ctx.fillStyle = i % 2 ? red : white;
    ctx.fill();
}​

http://jsfiddle.net/RmHC3/

No black dots. :)

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1  
Of course, the output might be different than desired with your algorithm. –  Shmiddty Aug 30 '12 at 17:16
    
The thing is that the circles are drawn as part of an animation (I should have said that before...). If I use the context drawing tools the circles are indeed rendered properly, but, since all circles must be processed on each frame, the performance drops quite a lot. That's because the image data is drawn on each frame. –  broncoAbierto Aug 30 '12 at 17:20
    
@broncoAbierto Something like this? jsfiddle.net/RmHC3/2 I'm simply alternating the color of each line, which is a relatively simple process. Is the animation more complex? –  Shmiddty Aug 30 '12 at 17:48
    
The circle grows outward. The nature of the script requires the whole image to be drawn at each frame, so I must take advantage of that and try to draw everything that way. With the context method it gets much slower. –  broncoAbierto Aug 30 '12 at 18:58
    
@broncoAbierto Perchance you could set up a fiddle to demonstrate what you've tried. That way we might be able to optimize it. –  Shmiddty Aug 30 '12 at 19:01

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