# Calculating random x,y coordinate within circle

How do I calculate random points inside a circle (somewhat evenly distributed)?

I have found this answer (the one by Udo Klein): Use X,Y coordinates to plot points inside a circle and my Objective C implementation looks like this:

``````-(CGPoint)getRandomPointInCircle:(CGPoint)cCenter radius:(float)cRadius {
float r = cRadius * sqrtf(arc4random());
float angle = sqrtf(2 * M_PI);
float x = cCenter.x + r * cosf(angle);
float y = cCenter.y + r * sinf(angle);
CCLOG(@"--> rand point: %f,%f", x, y);
return ccp(x,y);
}``````

Now with a given circle with center 5000,5000 and radius of 7100 it gives me crazy values like this: -324893408.000000,239372544.000000

/Søren

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Seems to me you need a random angle. And, of course, your RNG needs to generate a float between 0 and 1, vs between 0 and 2 billion. –  Hot Licks Sep 20 '13 at 11:22

Your problem is that you didn't put `arc4random`'s output into a range, but you also didn't randomise the angle.

First, the mathematics of a random distribution within a circle:

For each radius `a`, the probability of a random point within a circle of radius `r` being within the circle of radius `a` is `pi*a^2 / pi*r^2` = `(a/r)^2`.

`arc4random` gives us a uniformly distributed random number, but we want one which is biased according to the distribution (cumulative probability) which we just calculated. A method exists for this: http://en.wikipedia.org/wiki/Inverse_transform_sampling

The inverse of our cumulative probability is `a = sqrt(p*(r^2))` (where `p` is within `[0 1]`). This simplifies to `a = r * sqrt( p )`. (which is what you already had, so congratulations! I calculated that needlessly)

The angle is much easier; we just need a uniform distribution within `[-pi pi)` or `[0 pi*2)`, etc.

``````float r = cRadius * sqrtf( arc4random( ) / (float) 0xFFFFFFFFul );
float angle = arc4random( ) * (float) (M_PI * 2) / (float) 0x100000000ul;
``````

Note that I use `0xFFFFFFFFul` (=2^32-1, as an unsigned long just so it fits during compilation) for the inclusive range and `0x100000000ul` (=2^32) for the exclusive range. It's a tiny difference which you'd never notice, but mathematically this is the most correct way to transform the distributions.

Which randomisation function you use is up to you, but `arc4random` is generally recommended in Objective C, because it doesn't need seeding (it will be "more random" than a distribution seeded with the current time).

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Thank you @Dave :) –  Neigaard Sep 20 '13 at 12:02

`arc4random()` returns int between 0 to (2**32)-1 as described in here: https://developer.apple.com/library/mac/documentation/Darwin/Reference/ManPages/man3/arc4random.3.html

For float value is best to use `drand48()`, but it needs seed:

``````srand48(time(0));
float r = (float)drand48();
``````

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Right wrong use of random gen :) What about the implementation in my own answer? –  Neigaard Sep 20 '13 at 11:40
Its seems to be fine apart from the fact that you also need random angle. –  Kirsteins Sep 20 '13 at 11:43

The points on a circle of radius R and center (x0,y0) are all (x,y) such that:

x = x0 + R*cos(theta)

y = y0 + R*sin(theta)

with theta spanning from 0 to 2*PI.

If you want points that are inside the circle, you want the points:

x = x0 + r*cos(theta)

y = y0 + r*sin(theta)

with theta spanning from 0 to 2*PI and r spanning from 0 to R.

So all you need to do is generate random values for r in [0,R] and random values for theta in [0,2*PI]!

In objective-C:

``````-(CGPoint)getRandomPointInCircle:(CGPoint)cCenter radius:(float)cRadius {

// Since it's a 2D problem, you want to generate two different random numbers to have a
// uniform distribution. So generate a number in [0,R] and another between [0,2*PI],
// without forgetting to seed.
srand48(time(0));
float angle = (float)(drand48()*2*M_PI);

// Now use the equations above!
float x = cCenter.x + r * cosf(angle);
float y = cCenter.y + r * sinf(angle);

CCLOG(@"--> rand point: %f,%f", x, y);

return ccp(x,y);
}
``````

Cheers!

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Damn, beat me to it by a few seconds. :) –  ipmcc Sep 20 '13 at 11:41
Ha yes sorry did not see it before my own attempt, it does however have a high concentration in the center, any idea there? –  Neigaard Sep 20 '13 at 11:44
No it doesn't! The points are evenly distributed from center border as r is chosen uniformly between 0 (the center) and cRadius (the border)! –  raladdin Sep 20 '13 at 11:46
@raladdin nope. This will have a high concentration at the centre of the circle. Try it and see. Then try to guess why ;) –  Dave Sep 20 '13 at 11:49
For why: imagine you only have 3 circles, of radius 1, 2 and 3. Pick one at random (1/3 chance for each), then pick a random point within it. The circle with radius 1 will have just as many points as the one of radius 3, but it is smaller, so the points will be more closely packed. As for how to fix it, see my answer for the full mathematical solution. –  Dave Sep 20 '13 at 11:56

Easiest way would be to use `arc4random` as others have suggested to generate two random numbers and then map those onto the ranges of R and theta. Like:

``````#import <tgmath.h>
// ...
CGFloat r = ((CGFloat)arc4random())  * cRadius / ((CGFloat)UINT32_MAX);
CGFloat theta = ((CGFloat)arc4random())  * (M_PI + M_PI) / ((CGFloat)UINT32_MAX);
CGPoint randomXY = CGPointMake(cCenter.x + r * cos(theta), cCenter.y + r * sin(theta));
``````
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Nice and concise, but using cos&sin instead of cosf&sinf depends upon what CGFloat is defined to be. Can be checked with CGFLOAT_IS_DOUBLE. –  fresidue Sep 20 '13 at 11:50
Use `tgmath.h` and it won't matter. <editing> :) –  ipmcc Sep 20 '13 at 11:57
cool. will try it. –  fresidue Sep 20 '13 at 15:00

Generate points from rect that size is radius*radius and return point only if its inside the circle:

``````- (CGPoint)getRandomPointInCircle:(CGPoint)cCenter radius:(float)cRadius {
while (1) {
float x = cCenter.x + ((float)arc4random() / 0x100000000) * cRadius;
float y = cCenter.y + ((float)arc4random() / 0x100000000) * cRadius;

float dx = absf(cCenter.x - x);
float dy = absf(cCenter.y - y);
float pointsDistanceFromCenter = sqrtf(dx * dx + dy * dy);

// if point is not in circle generate new x, y
continue;
}

CCLOG(@"--> rand point: %f,%f", x, y);
return ccp(x,y);
}
}
``````
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no need to iterate and risk an algorithm which isn't guaranteed to terminate in reasonable (or even finite) time. This problem can be solved by pure mathematics! –  Dave Sep 20 '13 at 12:04
This while loop will return value 79% of time its is executed, so there is no risk for infinite loop. It is also straightforward while other implementations need some checking to prove that they are correct. –  Kirsteins Sep 20 '13 at 12:14
"there is no risk for infinite loop". Yes, there is. It's tiny, and is almost certain to never happen, but the chance is there. More practically, there is a risk of this stalling for an arbitrary length of time. I wouldn't want to be driving a car who's computer could freeze for a few seconds just because it's trying to pick a suitable random number as part of the pedestrian detection code. Seriously, don't play around with inefficient code like this when just a few minutes' thought can create a problem-free version. A programmer's job is to think, and prove correctness. –  Dave Sep 20 '13 at 12:28
also, your code actually isn't correct, since it will only return points which are both within the circle and within the box from [0,0] to [radius,radius]. Which means that if your circle is too far away from the origin, the infinite loop I mentioned will be all-too-real. Maybe you should have checked it to prove it was correct :P –  Dave Sep 20 '13 at 12:34
@Dave, if it's more likely that the CPU or a memory module fails than the algorithm takes more than 1000 iterations to stop, should you really worry about the algorithm? Besides, if implemented correctly, the expected number of iterations is less than 2. This means that on average it is more efficient than an alternative algorithm that spends time computing square roots and trigonometric functions. –  Joni Sep 20 '13 at 13:53