I am using Bresenham's circle algorithm for fast circle drawing. However, I also want to (at the request of the user) draw a filled circle.

Is there a fast and efficient way of doing this? Something along the same lines of Bresenham?

The language I am using is C.

10 Answers 10


Having read the Wikipedia page on Bresenham's (also 'Midpoint') circle algorithm, it would appear that the easiest thing to do would be to modify its actions, such that instead of

setPixel(x0 + x, y0 + y);
setPixel(x0 - x, y0 + y);

and similar, each time you instead do

lineFrom(x0 - x, y0 + y, x0 + x, y0 + y);

That is, for each pair of points (with the same y) that Bresenham would you have you plot, you instead connect with a line.

| improve this answer | |
  • does that really work ? i tried it .. it doesn't totally fill the circle. Am I missing something ? In any case, there are some correct answers below. – AJed Jun 24 '13 at 15:39
  • 1
    @AJed To know if you're missing something, we'd need to see your code, in a new question of your own – AakashM Jul 3 '13 at 11:06
  • 1
    Wouldn't this cause scan lines in the 2nd/3rd and 6th/7th quadrants to be repeated? In those x changes at every step and the decision variable governs y. – Tommy Apr 17 '14 at 18:12
  • @AakashM ok it seems I have misread the answer , it seems like a scan line algorithm which would do. I dont remember exactly but i think had connected the symmetric point 180 deg apart to make the lines and that doesnt work as lot of them overlap. Make some edit to answer so that I can remove by downvote. – Vikram Bhat Jan 16 '15 at 9:41
  • I am trying to have for border a color, and for fill another color. I to exactly what you said and after i construct the border with the basic command for the algorithm. the problem is that in the upper and bottom parts of the circle, the border is covered by the fill color, Any idea why ? – ALex Nov 9 '17 at 16:00

Just use brute force. This method iterates over a few too many pixels, but it only uses integer multiplications and additions. You completely avoid the complexity of Bresenham and the possible bottleneck of sqrt.

for(int y=-radius; y<=radius; y++)
    for(int x=-radius; x<=radius; x++)
        if(x*x+y*y <= radius*radius)
            setpixel(origin.x+x, origin.y+y);
| improve this answer | |
  • 1
    I like this answer because it solves the problem in a very direct way. The only problem with this is that it generates a different circle than the midpoint circle algorithm. These circles are "thinner" than the equivalent in midpoint, which appear to be the more correct shape. Any way to fix that? – Dwight Mar 1 '12 at 17:31
  • 4
    This sounds horrible, but I found that in most cases I can get the exact same circle from this algorithm as midpoint if I modify the check slightly. Those times it doesn't exactly match up, it's pretty close. The modification to the check is: x * x + y * y <= range * range + range * 0.8f – Dwight Mar 1 '12 at 18:25
  • 3
    I had the same issue as Dwight, but to avoid the float cast just replaced the if statement with this one: if(x*x+y*y < radius*radius + radius) also to get just the circle (ring) you can do this if(x*x+y*y > radius*radius - radius && x*x+y*y < radius*radius + radius) – Marcin Oct 7 '17 at 0:28

Here's a C# rough guide (shouldn't be that hard to get the right idea for C) - this is the "raw" form without using Bresenham to eliminate repeated square-roots.

Bitmap bmp = new Bitmap(200, 200);

int r = 50; // radius
int ox = 100, oy = 100; // origin

for (int x = -r; x < r ; x++)
    int height = (int)Math.Sqrt(r * r - x * x);

    for (int y = -height; y < height; y++)
        bmp.SetPixel(x + ox, y + oy, Color.Red);

| improve this answer | |
  • 1
    Or loop on y and draw horizonal lines. Occasionally there is a reason to choose one or the other, but in most cases it does not matter. Either way you use the same Bresenham logic to find the endpoints quickly. – dmckee --- ex-moderator kitten Jul 29 '09 at 15:58
  • 1
    No, but you can use Bresenham to avoid that. The basic idea is to "join the dots" between the upper and lower points at each x coordinate covered by the circle. – Daniel Earwicker Jul 29 '09 at 16:02
  • 1
    Profile to see which is best. If there's a difference at all, going horizontal should be better. It gets rid of a multiplication by stride and may result in fewer faults. – colithium Jul 29 '09 at 16:05
  • 5
    "All those Math.Sqrts aren't going to be especially fast" - the disassembly shows that the C#/JIT combo emits the inlined SQRTSD instruction on my 64-bit machine, and so it's little wonder that it runs blazingly fast. I can't measure a different between Math.Sqrt and a simple addition. So I think your comment is probably based on pre-FP instruction set guessing! – Daniel Earwicker Jul 29 '09 at 16:22
  • 5
    That perennial problem - what to do with one's carefully-tuned educated-guesswork engine when the fundamentals change? – AakashM Jul 29 '09 at 16:45

You can use this:

void DrawFilledCircle(int x0, int y0, int radius)
    int x = radius;
    int y = 0;
    int xChange = 1 - (radius << 1);
    int yChange = 0;
    int radiusError = 0;

    while (x >= y)
        for (int i = x0 - x; i <= x0 + x; i++)
            SetPixel(i, y0 + y);
            SetPixel(i, y0 - y);
        for (int i = x0 - y; i <= x0 + y; i++)
            SetPixel(i, y0 + x);
            SetPixel(i, y0 - x);

        radiusError += yChange;
        yChange += 2;
        if (((radiusError << 1) + xChange) > 0)
            radiusError += xChange;
            xChange += 2;
| improve this answer | |

I like palm3D's answer. For being brute force, this is an amazingly fast solution. There are no square root or trigonometric functions to slow it down. Its one weakness is the nested loop.

Converting this to a single loop makes this function almost twice as fast.

int r2 = r * r;
int area = r2 << 2;
int rr = r << 1;

for (int i = 0; i < area; i++)
    int tx = (i % rr) - r;
    int ty = (i / rr) - r;

    if (tx * tx + ty * ty <= r2)
        SetPixel(x + tx, y + ty, c);

This single loop solution rivals the efficiency of a line drawing solution.

            int r2 = r * r;
            for (int cy = -r; cy <= r; cy++)
                int cx = (int)(Math.Sqrt(r2 - cy * cy) + 0.5);
                int cyy = cy + y;

                lineDDA(x - cx, cyy, x + cx, cyy, c);
| improve this answer | |
  • 2
    I'm a bit surprised that your solution is faster than palm3d. Did you measure it ? do you have numbers ? – Florian Prud'homme Jan 18 '18 at 9:08
  • This algorithm draws less pixels than the original. For a radius of 10, it does 41 loops less.. On my laptop, running 100,000,000 tests of this function and the original, we get: ORIGINAL: 43ns. THIS: 42ns on a good run.. On a bad run: ORIGINAL: 87ns. THIS: 54ns.. but these are nano-seconds so in terms of efficiency, there's virtually no difference. Tested on: Intel(R) Core(TM) i7-4980HQ CPU @ 2.80GHz – Brandon Nov 10 '19 at 20:05
  • Hmm, am quite confused to where this is supposed to be faster.. Am currently trying all variants in quick-bench.com/VtgMOwU8IQoa7biFNHFZ2ws5hlk and it is much, much slower. That doe snot really surprise me though because divisions are often very slow. – AlexGeorg Dec 6 '19 at 10:02

Here's how I'm doing it:
I'm using fixed point values with two bits precision (we have to manage half points and square values of half points)
As mentionned in a previous answer, I'm also using square values instead of square roots.
First, I'm detecting border limit of my circle in a 1/8th portion of the circle. I'm using symetric of these points to draw the 4 "borders" of the circle. Then I'm drawing the square inside the circle.

Unlike the midpoint circle algorith, this one will work with even diameters (and with real numbers diameters too, with some little changes).

Please forgive me if my explanations were not clear, I'm french ;)

void DrawFilledCircle(int circleDiameter, int circlePosX, int circlePosY)
    const int FULL = (1 << 2);
    const int HALF = (FULL >> 1);

    int size = (circleDiameter << 2);// fixed point value for size
    int ray = (size >> 1);
    int dY2;
    int ray2 = ray * ray;
    int posmin,posmax;
    int Y,X;
    int x = ((circleDiameter&1)==1) ? ray : ray - HALF;
    int y = HALF;
    circlePosX -= (circleDiameter>>1);
    circlePosY -= (circleDiameter>>1);

    for (;; y+=FULL)
        dY2 = (ray - y) * (ray - y);

        for (;; x-=FULL)
            if (dY2 + (ray - x) * (ray - x) <= ray2) continue;

            if (x < y)
                Y = (y >> 2);
                posmin = Y;
                posmax = circleDiameter - Y;

                // Draw inside square and leave
                while (Y < posmax)
                    for (X = posmin; X < posmax; X++)
                        setPixel(circlePosX+X, circlePosY+Y);
                // Just for a better understanding, the while loop does the same thing as:
                // DrawSquare(circlePosX+Y, circlePosY+Y, circleDiameter - 2*Y);

            // Draw the 4 borders
            X = (x >> 2) + 1;
            Y = y >> 2;
            posmax = circleDiameter - X;
            int mirrorY = circleDiameter - Y - 1;

            while (X < posmax)
                setPixel(circlePosX+X, circlePosY+Y);
                setPixel(circlePosX+X, circlePosY+mirrorY);
                setPixel(circlePosX+Y, circlePosY+X);
                setPixel(circlePosX+mirrorY, circlePosY+X);
            // Just for a better understanding, the while loop does the same thing as:
            // int lineSize = circleDiameter - X*2;
            // Upper border:
            // DrawHorizontalLine(circlePosX+X, circlePosY+Y, lineSize);
            // Lower border:
            // DrawHorizontalLine(circlePosX+X, circlePosY+mirrorY, lineSize);
            // Left border:
            // DrawVerticalLine(circlePosX+Y, circlePosY+X, lineSize);
            // Right border:
            // DrawVerticalLine(circlePosX+mirrorY, circlePosY+X, lineSize);


void DrawSquare(int x, int y, int size)
    for( int i=0 ; i<size ; i++ )
        DrawHorizontalLine(x, y+i, size);

void DrawHorizontalLine(int x, int y, int width)
    for(int i=0 ; i<width ; i++ )
        SetPixel(x+i, y);

void DrawVerticalLine(int x, int y, int height)
    for(int i=0 ; i<height ; i++ )
        SetPixel(x, y+i);

To use non-integer diameter, you can increase precision of fixed point or use double values. It should even be possible to make a sort of anti-alias depending on the difference between dY2 + (ray - x) * (ray - x) and ray2 (dx² + dy² and r²)

| improve this answer | |

palm3D's brute-force algorithm I found to be a good starting point. This method uses the same premise, however it includes a couple of ways to skip checking most of the pixels.

First, here's the code:

int largestX = circle.radius;
for (int y = 0; y <= radius; ++y) {
    for (int x = largestX; x >= 0; --x) {
        if ((x * x) + (y * y) <= (circle.radius * circle.radius)) {
            drawLine(circle.center.x - x, circle.center.x + x, circle.center.y + y);
            drawLine(circle.center.x - x, circle.center.x + x, circle.center.y - y);
            largestX = x;
            break; // go to next y coordinate

Next, the explanation.

The first thing to note is that if you find the minimum x coordinate that is within the circle for a given horizontal line, you immediately know the maximum x coordinate. This is due to the symmetry of the circle. If the minimum x coordinate is 10 pixels ahead of the left of the bounding box of the circle, then the maximum x is 10 pixels behind the right of the bounding box of the circle.

The reason to iterate from high x values to low x values, is that the minimum x value will be found with less iterations. This is because the minimum x value is closer to the left of the bounding box than the centre x coordinate of the circle for most lines, due to the circle being curved outwards, as seen on this image The next thing to note is that since the circle is also symmetric vertically, each line you find gives you a free second line to draw, each time you find a line in the top half of the circle, you get one on the bottom half at the radius-y y coordinate. Therefore, when any line is found, two can be drawn and only the top half of the y values needs to be iterated over.

The last thing to note is that is that if you start from a y value that is at the centre of the circle and then move towards the top for y, then the minimum x value for each next line must be closer to the centre x coordinate of the circle than the last line. This is also due to the circle curving closer towards the centre x value as you go up the circle. Here is a visual on how that is the case.

In summary:

  1. If you find the minimum x coordinate of a line, you get the maximum x coordinate for free.
  2. Every line you find to draw on the top half of the circle gives you a line on the bottom half of the circle for free.
  3. Every minimum x coordinate has to be closer to the centre of the circle than the previous x coordinate for each line when iterating from the centre y coordinate to the top.

You can also store the value of (radius * radius), and also (y * y) instead of calculating them multiple times.

| improve this answer | |

If you want a fast algorithm, consider drawing a polygon with N sides, the higher is N, the more precise will be the circle.

| improve this answer | |
  • this would probably require some kind of hardware acceleration to be fastest – Spikolynn Nov 11 '14 at 17:58

Great ideas here! Since I'm at a project that requires many thousands of circles to be drawn, I have evaluated all suggestions here (and improved a few by precomputing the square of the radius):


enter image description here

The Rev variants just have x and y swapped because consecutive access along the y axis are faster with the way my grid/canvas structure works.

The clear winner is Daniel Earwicker's method ( DrawCircleBruteforcePrecalc ) that precomputes the Y value to avoid unnecessary radius checks. Somewhat surprisingly that negates the additional computation caused by the sqrt call.

Some comments suggest that kmillen's variant (DrawCircleSingleLoop) that works with a single loop should be very fast, but it's the slowest here. I assume that is because of all the divisions. But perhaps I have adapted it wrong to the global variables in that code. Would be great if someone takes a look.

EDIT: After looking for the first time since college years at some assembler code, I managed find that the final additions of the circle's origin are a culprit. Precomputing those, I improved the fastest method by a factor of another 3.7-3.9 according to the bench! http://quick-bench.com/7ZYitwJIUgF_OkDUgnyMJY4lGlA Amazing.

This being my code:

for (int x = -radius; x < radius ; x++)
    int hh = (int)std::sqrt(radius_sqr - x * x);
    int rx = center_x + x;
    int ph = center_y + hh;

    for (int y = center_y-hh; y < ph; y++)
        canvas[rx][y] = 1;
| improve this answer | |

I would just generate a list of points and then use a polygon draw function for the rendering.

| improve this answer | |
  • 1
    If he has implemented Bresenham for the open version, he is working at a lower layer then using an API...either for learning purposes or to implement an API. – dmckee --- ex-moderator kitten Jul 29 '09 at 16:00

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.