# Algorithm for creating rounded corners in a polygon

I'm looking for an algorithm that allows me to create rounded corners from a polygon. In Input, I get an array of points that represents the polygon (red line) and in output, an array of points that represents the polygon with rounded corner (black line).

I would also like to have a way to control the radius of each corner. I already tried to use Bezier and Subdivision but it's not what I'm looking for. Bezier and Subdivision are smoothing all the polygon. What I want, it's only make the corners rounded.

Somebody knows any good algorithm for doing that? I'm working in C# but the code has to be independent from any .NET libraries. • Given R, find the circle that is tangent to the two neighboring line segments. The center is on the angle bisector, `t=R/sin(a/2)`, where `t` is the distance from the center to the angle point, `a` is the angle. – xiaofeng.li Jul 16 '14 at 3:58

## Some geometry with Paint:

0. You have a corner: 1. You know the coordinates of corner points, let it be P1, P2 and P: 2. Now you can get vectors from points and angle between vectors: `angle = atan(PY - P1Y, PX - P1X) - atan(PY - P2Y, PX - P2X)`

3. Get the length of segment between angular point and the points of intersection with the circle. `segment = PC1 = PC2 = radius / |tan(angle / 2)|`

4. Here you need to check the length of segment and the minimal length from PP1 and PP2: Length of PP1:

`PP1 = sqrt((PX - P1X)2 + (PY - P1Y)2)`

Length of PP2:

`PP2 = sqrt((PX - P2X)2 + (PY - P2Y)2)`

If segment > PP1 or segment > PP2 then you need to decrease the radius:

```min = Min(PP1, PP2) (for polygon is better to divide this value by 2)
segment > min ?
segment = min
radius = segment * |tan(angle / 2)|```

5. Get the length of PO:

`PO = sqrt(radius2 + segment2)`

6. Get the C1X and C1Y by the proportion between the coordinates of the vector, length of vector and the length of the segment: Proportion:

`(PX - C1X) / (PX - P1X) = PC1 / PP1`

So:

`C1X = PX - (PX - P1X) * PC1 / PP1`

The same for C1Y:

`C1Y = PY - (PY - P1Y) * PC1 / PP1`

7. Get the C2X and C2Y by the same way:

```C2X = PX - (PX - P2X) * PC2 / PP2
C2Y = PY - (PY - P2Y) * PC2 / PP2```

8. Now you can use the addition of vectors PC1 and PC2 to find the centre of circle by the same way by proportion: ```(PX - OX) / (PX - CX) = PO / PC
(PY - OY) / (PY - CY) = PO / PC```

Here:

```CX = C1X + C2X - PX
CY = C1Y + C2Y - PY
PC = sqrt((PX - CX)2 + (PY - CY)2)```

Let:

```dx = PX - CX = PX * 2 - C1X - C2X
dy = PY - CY = PY * 2 - C1Y - C2Y```

So:

```PC = sqrt(dx2 + dy2)

OX = PX - dx * PO / PC
OY = PY - dy * PO / PC```

9. Here you can draw an arc. For this you need to get start angle and end angle of arc: Found it here:

```startAngle = atan((C1Y - OY) / (C1X - OX))
endAngle = atan((C2Y - OY) / (C2X - OX))```

10. At last you need to get a sweep angle and make some checks for it: ``````sweepAngle = endAngle - startAngle
``````

If sweepAngle < 0 then swap startAngle and endAngle, and invert sweepAngle:

``````sweepAngle < 0 ?
sweepAngle = - sweepAngle
startAngle = endAngle
``````

Check if sweepAngle > 180 degrees:

``````sweepAngle > 180 ?
sweepAngle = 180 - sweepAngle
``````

11. And now you can draw a rounded corner: ## Some geometry with c#:

``````private void DrawRoundedCorner(Graphics graphics, PointF angularPoint,
PointF p1, PointF p2, float radius)
{
//Vector 1
double dx1 = angularPoint.X - p1.X;
double dy1 = angularPoint.Y - p1.Y;

//Vector 2
double dx2 = angularPoint.X - p2.X;
double dy2 = angularPoint.Y - p2.Y;

//Angle between vector 1 and vector 2 divided by 2
double angle = (Math.Atan2(dy1, dx1) - Math.Atan2(dy2, dx2)) / 2;

// The length of segment between angular point and the
// points of intersection with the circle of a given radius
double tan = Math.Abs(Math.Tan(angle));
double segment = radius / tan;

//Check the segment
double length1 = GetLength(dx1, dy1);
double length2 = GetLength(dx2, dy2);

double length = Math.Min(length1, length2);

if (segment > length)
{
segment = length;
}

// Points of intersection are calculated by the proportion between
// the coordinates of the vector, length of vector and the length of the segment.
var p1Cross = GetProportionPoint(angularPoint, segment, length1, dx1, dy1);
var p2Cross = GetProportionPoint(angularPoint, segment, length2, dx2, dy2);

// Calculation of the coordinates of the circle
// center by the addition of angular vectors.
double dx = angularPoint.X * 2 - p1Cross.X - p2Cross.X;
double dy = angularPoint.Y * 2 - p1Cross.Y - p2Cross.Y;

double L = GetLength(dx, dy);

var circlePoint = GetProportionPoint(angularPoint, d, L, dx, dy);

//StartAngle and EndAngle of arc
var startAngle = Math.Atan2(p1Cross.Y - circlePoint.Y, p1Cross.X - circlePoint.X);
var endAngle = Math.Atan2(p2Cross.Y - circlePoint.Y, p2Cross.X - circlePoint.X);

//Sweep angle
var sweepAngle = endAngle - startAngle;

if (sweepAngle < 0)
{
startAngle = endAngle;
sweepAngle = -sweepAngle;
}

if (sweepAngle > Math.PI)
sweepAngle = Math.PI - sweepAngle;

//Draw result using graphics
var pen = new Pen(Color.Black);

graphics.Clear(Color.White);
graphics.SmoothingMode = SmoothingMode.AntiAlias;

graphics.DrawLine(pen, p1, p1Cross);
graphics.DrawLine(pen, p2, p2Cross);

var left = circlePoint.X - radius;
var top = circlePoint.Y - radius;
var diameter = 2 * radius;
var degreeFactor = 180 / Math.PI;

graphics.DrawArc(pen, left, top, diameter, diameter,
(float)(startAngle * degreeFactor),
(float)(sweepAngle * degreeFactor));
}

private double GetLength(double dx, double dy)
{
return Math.Sqrt(dx * dx + dy * dy);
}

private PointF GetProportionPoint(PointF point, double segment,
double length, double dx, double dy)
{
double factor = segment / length;

return new PointF((float)(point.X - dx * factor),
(float)(point.Y - dy * factor));
}
``````

To get points of arc you can use this:

``````//One point for each degree. But in some cases it will be necessary
// to use more points. Just change a degreeFactor.
int pointsCount = (int)Math.Abs(sweepAngle * degreeFactor);
int sign = Math.Sign(sweepAngle);

PointF[] points = new PointF[pointsCount];

for (int i = 0; i < pointsCount; ++i)
{
var pointX =
(float)(circlePoint.X
+ Math.Cos(startAngle + sign * (double)i / degreeFactor)

var pointY =
(float)(circlePoint.Y
+ Math.Sin(startAngle + sign * (double)i / degreeFactor)

points[i] = new PointF(pointX, pointY);
}
``````
• Thank you! It works perfectly! Answer of dbc explains the way, and your answer gives the implementation. It's a shame I can't valid your two answers. For those who wants to generate points and not draw an arc using graphics library, here is the code: `PointF[] points = new PointF[pointsCount]; for(int i=0; i<pointsCount; ++i) { points[i] = new PointF(circleRadius.x + Math.Cos(startAngle + i * sweepAngle / pointsCount) * radius, circleRadius.y + Math.Sin(startAngle + i * sweepAngle / pointsCount) * radius); }` – ZouBi Jul 17 '14 at 3:25
• @ZouBi I corrected mistake in additional checks of sweepAngle (check the new code), and updated my answer with your code with some changes. My algorithm is differs from dbc's algorithm. – nempoBu4 Jul 17 '14 at 4:38
• @ZouBi I have updated my answer with explanation of my algorithm. – nempoBu4 Jul 17 '14 at 9:29
• Thank you, your comment is clear, explains everything and gives an implementation in c#. I marked you as right answer. – ZouBi Jul 18 '14 at 3:46
• Seems there is small issue with the latest function which draws arc: if sign is negative pointsCount should be calculated different way. By the way, for source points (20, 0) and (20, 20) arc will be rendered partially as pointCount will be calculated as 45 but we need 135 (180 - 45) – Ilya Builuk Feb 13 '15 at 23:40

You are looking for an arc tangent to two connected line segments, of a given radius, given by some sequential array of points. The algorithm to find this arc is as follows:

1. For each segment, construct a normal vector.

1. If you are working in 2d, you can just subtract the two endpoints to get a tangent vector (X, Y). In that case, normal vectors will be plus or minus (-Y, X). Normalize the normal vector to length one. Finally, choose the direction with a positive dot product with the tangent vector of the next segment. (See update below).

2. If you are working in 3d not 2d, to get the normal, cross the tangent vectors of the two segments at the vertex you wish to round to get a perpendicular vector to the plane of the lines. If the perpendicular has length zero, the segments are parallel and no round can be required. Otherwise, normalize it, then cross the perpendicular with the tangent to get the normal.)

2. Using the normal vectors, offset each line segment towards the interior of the polygon by your desired radius. To offset a segment, offset its endpoints using the normal vector N you just computed, like so: P' = P + r * N (a linear combination).

3. Intersect the two offset lines to find the center. (This works because a radius vector of a circle is always perpendicular to its tangent.)

4. To find the point at which the circle intersects each segment, offset the circle center backwards to each original segment. These will be the endpoints of your arc.

5. Make sure the arc endpoints are inside each segment, otherwise you will be creating a self-intersecting polygon.

6. Create an arc through both endpoints with center & radius you determined.

I don't have any proper drafting software at hand, but this diagram sort of shows the idea: At this point you will need either to introduce classes to represent a figure consisting of line and arc segments, or polygonize the arc to an appropriate accuracy and add all the segments to the polygon.

Update: I have updated the image, labeling the points P1, P2, and P3, and normal vectors Norm12 and Norm23. The normalized normals are unique only up to flipping direction, and you should choose the flips as follows:

• The dot product of Norm12 with (P3 - P2) must be positive. If it is negative, multiple Norm12 by -1.0. If it is zero, the points are collinear and no rounded corner need be created. This is because you want to offset towards P3.

• The dot product of Norm23 with (P1 - P2) must also be positive since you are offsetting towards P1.

• Thank you, I understand the way you want me to do it. But I have one question for now: how do I offset a line towards the interior of the polygon? – ZouBi Jul 16 '14 at 6:02
• @ZouBi Basically this line would always intersect with the other two lines. Maybe you could check for that. – チーズパン Jul 16 '14 at 7:13
• dbc, Thank you for your edit. I think it's the best answer and I will try to write the code for doing that. – ZouBi Jul 16 '14 at 7:17
• @JakeStelman - I notice your edit got rejected, but you could add your Matlab code as a separate answer, if you wanted. It looks pretty useful! – dbc Jul 20 '15 at 3:14

``````typedef enum {
path_move_to,
path_line_to
} Path_command;

static inline CGFloat sqr (CGFloat a)
{
return a * a;
}

static inline CGFloat positive_angle (CGFloat angle)
{
return angle < 0 ? angle + 2 * (CGFloat) M_PI : angle;
}

{
// 2
CGFloat angle = positive_angle (atan2f (p.y - p1.y, p.x - p1.x) - atan2f (p.y - p2.y, p.x - p2.x));

// 3
CGFloat segment = radius / fabsf (tanf (angle / 2));
CGFloat p_c1 = segment;
CGFloat p_c2 = segment;

// 4
CGFloat p_p1 = sqrtf (sqr (p.x - p1.x) + sqr (p.y - p1.y));
CGFloat p_p2 = sqrtf (sqr (p.x - p2.x) + sqr (p.y - p2.y));
CGFloat min = MIN(p_p1, p_p2);
if (segment > min) {
segment = min;
radius = segment * fabsf (tanf (angle / 2));
}

// 5
CGFloat p_o = sqrtf (sqr (radius) + sqr (segment));

// 6
CGPoint c1;
c1.x = (CGFloat) (p.x - (p.x - p1.x) * p_c1 / p_p1);
c1.y = (CGFloat) (p.y - (p.y - p1.y) * p_c1 / p_p1);

//  7
CGPoint c2;
c2.x = (CGFloat) (p.x - (p.x - p2.x) * p_c2 / p_p2);
c2.y = (CGFloat) (p.y - (p.y - p2.y) * p_c2 / p_p2);

// 8
CGFloat dx = p.x * 2 - c1.x - c2.x;
CGFloat dy = p.y * 2 - c1.y - c2.y;

CGFloat p_c = sqrtf (sqr (dx) + sqr (dy));

CGPoint o;
o.x = p.x - dx * p_o / p_c;
o.y = p.y - dy * p_o / p_c;

// 9
CGFloat start_angle = positive_angle (atan2f ((c1.y - o.y), (c1.x - o.x)));
CGFloat end_angle = positive_angle (atan2f ((c2.y - o.y), (c2.x - o.x)));

[path moveToPoint: c1];
}
else {
}
}

UIBezierPath* path_with_rounded_corners (NSArray<NSValue*>* points, CGFloat corner_radius)
{
UIBezierPath* path = [UIBezierPath bezierPath];
NSUInteger count = points.count;
for (NSUInteger i = 0; i < count; ++i) {
CGPoint prev = points[i > 0 ? i - 1 : count - 1].CGPointValue;
CGPoint p = points[i].CGPointValue;
CGPoint next = points[i + 1 < count ? i + 1 : 0].CGPointValue;
add_corner (path, prev, p, next, corner_radius, i == 0 ? path_move_to : path_line_to);
}
[path closePath];
return path;
}
``````
• This is a C# question, not an objective C question. – Teepeemm Feb 5 '16 at 18:54
• @Teepeemm, you are right about C#, but brilliant answer from nempoBu4 helps me in my iOS development. Many iOS and Mac OS developers, like me, visit this page from google search. Our goal is to help them, I think. – Michael Vlasov Feb 6 '16 at 7:40
• meta.stackoverflow.com/q/290046/2336725 could be a useful reference. I don't know either language to know how different are Objective C and C#. Does your implementation add anything other than a simple change of programming language? Also, you may want to remove all the extra blank lines. – Teepeemm Feb 6 '16 at 20:03
• My adaptation introduce minor changes to original algorithm: 1) angles converted to positive values; 2) iOs uses different way to define arcs (start, end angles and clockwise flag) vs .Net (start, sweep angles). 3) My algorithm builds full closed graphics path with rounded corners instead of drawing arcs in corners. – Michael Vlasov Feb 8 '16 at 8:07

Here is a way using some geometry :-

1. the two lines are tangent to circle inscribed
2. The normal to the tangent meet at centre of the circle.
3. Let angle between lines be X
4. Angle subtended at centre of the circle will be K = 360-90*2-X = 180-X
5. Lets decide the two point of tangents as (x1,y) and (x2,y)
6. The chord joining the points has length l = (x2-x1)
7. Inside the circle, the chord and two normals of length r (radius) form isosceles triangle
8. The pendicular divide the traingle in to equal halved right angled triangles.
9. One of angle is K/2 and side is l/2
10. using properties of right angle triangle sin(K/2) = (l/2)/r
11. r = (l/2)/sin(K/2)
12. but K = 180-X so r = (l/2)/sin(90-X/2) = (l/2)/cos(X/2)
13. hence r = (x2-x1)/(2*cos(X/2))
14. Now simply draw a arc from (x1,y) to (x2,y) using radius r

Note:-

The above is explained for only for lines which meet at origin and the Y axis divides the angle between them into half. But it is equally applicable for all corner just need to apply a rotation and translation before applying the above. Moreover you need to select some x values of intersection from where you want to draw the arc . The values should not be too far or close to origin

• Thank you for taking time but I barely understand your way and how to implement it... – ZouBi Jul 16 '14 at 6:08
• try imagine your corner vertex at origin and line towards the positive y axis with Y axis bisecting the angle between them. – Vikram Bhat Jul 16 '14 at 6:12
• Sorry i cannot explain without a image but will try to add one. – Vikram Bhat Jul 16 '14 at 6:13
• The solution is constant time if you understand it , moreover you can rotate and translate other vertices and do the steps and reverse the translation and rotation. – Vikram Bhat Jul 16 '14 at 6:15

Here is my realisation of dbc's idea on c#:

``````/// <summary>
/// Round polygon corners
/// </summary>
/// <param name="points">Vertices array</param>
/// <returns></returns>
static public GraphicsPath RoundCorners(PointF[] points, float radius) {
GraphicsPath retval = new GraphicsPath();
if (points.Length < 3) {
throw new ArgumentException();
}
rects = new RectangleF[points.Length];
PointF pt1, pt2;
//Vectors for polygon sides and normal vectors
Vector v1, v2, n1 = new Vector(), n2 = new Vector();
//Rectangle that bounds arc
//Arc center
PointF center = new PointF();

for (int i = 0; i < points.Length; i++) {
pt1 = points[i];//First vertex
pt2 = points[i == points.Length - 1 ? 0 : i + 1];//Second vertex
v1 = new Vector(pt2.X, pt2.Y) - new Vector(pt1.X, pt1.Y);//One vector
pt2 = points[i == 0 ? points.Length - 1 : i - 1];//Third vertex
v2 = new Vector(pt2.X, pt2.Y) - new Vector(pt1.X, pt1.Y);//Second vector
//Angle between vectors
float sweepangle = (float)Vector.AngleBetween(v1, v2);
//Direction for normal vectors
if (sweepangle < 0) {
n1 = new Vector(v1.Y, -v1.X);
n2 = new Vector(-v2.Y, v2.X);
}
else {
n1 = new Vector(-v1.Y, v1.X);
n2 = new Vector(v2.Y, -v2.X);
}

n1.Normalize(); n2.Normalize();
/// Points for lines which intersect in the arc center
PointF pt = points[i];
pt1 = new PointF((float)(pt.X + n1.X), (float)(pt.Y + n1.Y));
pt2 = new PointF((float)(pt.X + n2.X), (float)(pt.Y + n2.Y));
double m1 = v1.Y / v1.X, m2 = v2.Y / v2.X;
//Arc center
if (v1.X == 0) {// first line is parallel OY
center.X = pt1.X;
center.Y = (float)(m2 * (pt1.X - pt2.X) + pt2.Y);
}
else if (v1.Y == 0) {// first line is parallel OX
center.X = (float)((pt1.Y - pt2.Y) / m2 + pt2.X);
center.Y = pt1.Y;
}
else if (v2.X == 0) {// second line is parallel OY
center.X = pt2.X;
center.Y = (float)(m1 * (pt2.X - pt1.X) + pt1.Y);
}
else if (v2.Y == 0) {//second line is parallel OX
center.X = (float)((pt2.Y - pt1.Y) / m1 + pt1.X);
center.Y = pt2.Y;
}
else {
center.X = (float)((pt2.Y - pt1.Y + m1 * pt1.X - m2 * pt2.X) / (m1 - m2));
center.Y = (float)(pt1.Y + m1 * (center.X - pt1.X));
}
rects[i] = new RectangleF(center.X - 2, center.Y - 2, 4, 4);
//Tangent points on polygon sides
n1.Negate(); n2.Negate();
pt1 = new PointF((float)(center.X + n1.X), (float)(center.Y + n1.Y));
pt2 = new PointF((float)(center.X + n2.X), (float)(center.Y + n2.Y));
//Rectangle that bounds tangent arc
RectangleF rect = new RectangleF(new PointF(center.X - radius, center.Y - radius), size);
sweepangle = (float)Vector.AngleBetween(n2, n1);
retval.AddArc(rect, (float)Vector.AngleBetween(new Vector(1, 0), n2), sweepangle);
}
retval.CloseAllFigures();
return retval;
}
``````