# How to check intersection between 2 rotated rectangles?

Can someone explain how to check if one rotated rectangle intersect other rectangle?

• Have a look at "Separating axis theorem" :) – Stefan Fandler Jun 9 '12 at 15:52
• Is it always a rectangle? What is the axis of rotation? Is the axis fixed? – Hari Menon Jun 9 '12 at 15:59
• I have one rotated rectangle and one fixed and i need to know if they intersect – Buron Jun 9 '12 at 16:26

1. For each edge in both polygons, check if it can be used as a separating line. If so, you are done: No intersection.
2. If no separation line was found, you have an intersection.
``````/// Checks if the two polygons are intersecting.
bool IsPolygonsIntersecting(Polygon a, Polygon b)
{
foreach (var polygon in new[] { a, b })
{
for (int i1 = 0; i1 < polygon.Points.Count; i1++)
{
int i2 = (i1 + 1) % polygon.Points.Count;
var p1 = polygon.Points[i1];
var p2 = polygon.Points[i2];

var normal = new Point(p2.Y - p1.Y, p1.X - p2.X);

double? minA = null, maxA = null;
foreach (var p in a.Points)
{
var projected = normal.X * p.X + normal.Y * p.Y;
if (minA == null || projected < minA)
minA = projected;
if (maxA == null || projected > maxA)
maxA = projected;
}

double? minB = null, maxB = null;
foreach (var p in b.Points)
{
var projected = normal.X * p.X + normal.Y * p.Y;
if (minB == null || projected < minB)
minB = projected;
if (maxB == null || projected > maxB)
maxB = projected;
}

if (maxA < minB || maxB < minA)
return false;
}
}
return true;
}
``````

NB: The algorithm only works for convex polygons, specified in either clockwise, or counterclockwise order.

• Just to note, this code doesn't seem to work if one polygon is completely contained within the other. – xioxox Apr 19 '14 at 11:32
• @xioxox, Could you give an example which gives the wrong result? You could fork this code: ideone.com/H7DWOO – Markus Jarderot Apr 19 '14 at 17:00
• It looks like I made a bug in my conversion to C++. It works now - pastebin.com/03BigiCn – xioxox Apr 20 '14 at 17:53
• Here's a Java version if anybody is interested. pastebin.com/GvxvEQnA – Sri Harsha Chilakapati Dec 5 '14 at 5:31
• @PaulVincentCraven Your polygons are specified in the wrong order. As they stand, they form two time-glass shapes. The algorithm is only guaranteed to work for convex polygons, specified in either clockwise or counterclockwise order. -- Flip the last two coordinates in each polygon to make them into rectangles. – Markus Jarderot Dec 27 '15 at 16:48

In javascript, the exact same algorithm is (for convenience):

``````/**
* Helper function to determine whether there is an intersection between the two polygons described
* by the lists of vertices. Uses the Separating Axis Theorem
*
* @param a an array of connected points [{x:, y:}, {x:, y:},...] that form a closed polygon
* @param b an array of connected points [{x:, y:}, {x:, y:},...] that form a closed polygon
* @return true if there is any intersection between the 2 polygons, false otherwise
*/
function doPolygonsIntersect (a, b) {
var polygons = [a, b];
var minA, maxA, projected, i, i1, j, minB, maxB;

for (i = 0; i < polygons.length; i++) {

// for each polygon, look at each edge of the polygon, and determine if it separates
// the two shapes
var polygon = polygons[i];
for (i1 = 0; i1 < polygon.length; i1++) {

// grab 2 vertices to create an edge
var i2 = (i1 + 1) % polygon.length;
var p1 = polygon[i1];
var p2 = polygon[i2];

// find the line perpendicular to this edge
var normal = { x: p2.y - p1.y, y: p1.x - p2.x };

minA = maxA = undefined;
// for each vertex in the first shape, project it onto the line perpendicular to the edge
// and keep track of the min and max of these values
for (j = 0; j < a.length; j++) {
projected = normal.x * a[j].x + normal.y * a[j].y;
if (isUndefined(minA) || projected < minA) {
minA = projected;
}
if (isUndefined(maxA) || projected > maxA) {
maxA = projected;
}
}

// for each vertex in the second shape, project it onto the line perpendicular to the edge
// and keep track of the min and max of these values
minB = maxB = undefined;
for (j = 0; j < b.length; j++) {
projected = normal.x * b[j].x + normal.y * b[j].y;
if (isUndefined(minB) || projected < minB) {
minB = projected;
}
if (isUndefined(maxB) || projected > maxB) {
maxB = projected;
}
}

// if there is no overlap between the projects, the edge we are looking at separates the two
// polygons, and we know there is no overlap
if (maxA < minB || maxB < minA) {
CONSOLE("polygons don't intersect!");
return false;
}
}
}
return true;
};
``````

Hope this helps someone.

• Its worth noting that this is a general algorithm for convex polygons, rather than just rectangles (for rectangles you can reduce the number of sides and points looped over since you know the sides are parallel). – Michael Anderson Sep 25 '12 at 7:06
• THANKS for Javascript – super Mar 27 '14 at 21:05
• thanks, works pretty nicely: jsfiddle.net/2VXXP/6 – Alex Jul 31 '14 at 14:43
• When using this, does anyone know if I need to add an extra point for the test? So for example when using a triangle there are 3 points: `first`, `second` and `last`. Which means param `a` and/or `b` would have an array of 3 items, or would you need a fourth item which would be the starting point. So basically do you need the the first point at the beginning and end of the array? – Get Off My Lawn Oct 7 '16 at 15:00
• @GetOffMyLawn I think not. All it needs is your points, you don't need to 'close' the shape off by adding the starting point at the end. – Sven Oct 8 '16 at 9:54

Here's the same algorithm in Java if anybody is interested.

``````boolean isPolygonsIntersecting(Polygon a, Polygon b)
{
for (int x=0; x<2; x++)
{
Polygon polygon = (x==0) ? a : b;

for (int i1=0; i1<polygon.getPoints().length; i1++)
{
int   i2 = (i1 + 1) % polygon.getPoints().length;
Point p1 = polygon.getPoints()[i1];
Point p2 = polygon.getPoints()[i2];

Point normal = new Point(p2.y - p1.y, p1.x - p2.x);

double minA = Double.POSITIVE_INFINITY;
double maxA = Double.NEGATIVE_INFINITY;

for (Point p : a.getPoints())
{
double projected = normal.x * p.x + normal.y * p.y;

if (projected < minA)
minA = projected;
if (projected > maxA)
maxA = projected;
}

double minB = Double.POSITIVE_INFINITY;
double maxB = Double.NEGATIVE_INFINITY;

for (Point p : b.getPoints())
{
double projected = normal.x * p.x + normal.y * p.y;

if (projected < minB)
minB = projected;
if (projected > maxB)
maxB = projected;
}

if (maxA < minB || maxB < minA)
return false;
}
}

return true;
}
``````
• That algorithm didn't work when I used triangles as polygons. It detected intersections when there were none. However, it works when you don't use Double.MAX_VALUE and Double.MIN_VALUE and instead use null and checks for null like Markus Jarderot did in his example. – Roland Mar 6 '16 at 8:38
• Right, I forgot that `Double.MIN_VALUE` is the smallest possible positive number and that is why this example fails. I think they should be fixed by changing them to `POSITIVE_INFINITY` and `NEGATIVE_INFINITY`. – Sri Harsha Chilakapati Mar 6 '16 at 8:47
• Yes, that works. Thanks a lot for your help! – Roland Mar 6 '16 at 8:53

Check out the method designed by Oren Becker to detect intersection of rotated rectangles with form:

``````struct _Vector2D
{
float x, y;
};

// C:center; S: size (w,h); ang: in radians,
// rotate the plane by [-ang] to make the second rectangle axis in C aligned (vertical)
struct _RotRect
{
_Vector2D C;
_Vector2D S;
float ang;
};
``````

And calling the following function will return whether two rotated rectangles intersect or not:

``````// Rotated Rectangles Collision Detection, Oren Becker, 2001
bool check_two_rotated_rects_intersect(_RotRect * rr1, _RotRect * rr2)
{
_Vector2D A, B,   // vertices of the rotated rr2
C,      // center of rr2
BL, TR; // vertices of rr2 (bottom-left, top-right)

float ang = rr1->ang - rr2->ang, // orientation of rotated rr1
cosa = cos(ang),           // precalculated trigonometic -
sina = sin(ang);           // - values for repeated use

float t, x, a;      // temporary variables for various uses
float dx;           // deltaX for linear equations
float ext1, ext2;   // min/max vertical values

// move rr2 to make rr1 cannonic
C = rr2->C;
SubVectors2D(&C, &rr1->C);

// rotate rr2 clockwise by rr2->ang to make rr2 axis-aligned
RotateVector2DClockwise(&C, rr2->ang);

// calculate vertices of (moved and axis-aligned := 'ma') rr2
BL = TR = C;
/*SubVectors2D(&BL, &rr2->S);

//-----------------------------------
BL.x -= rr2->S.x/2;    BL.y -= rr2->S.y/2;
TR.x += rr2->S.x/2;    TR.y += rr2->S.y/2;

// calculate vertices of (rotated := 'r') rr1
A.x = -(rr1->S.y/2)*sina; B.x = A.x; t = (rr1->S.x/2)*cosa; A.x += t; B.x -= t;
A.y =  (rr1->S.y/2)*cosa; B.y = A.y; t = (rr1->S.x/2)*sina; A.y += t; B.y -= t;
//---------------------------------------

//// calculate vertices of (rotated := 'r') rr1
//A.x = -rr1->S.y*sina; B.x = A.x; t = rr1->S.x*cosa; A.x += t; B.x -= t;
//A.y =  rr1->S.y*cosa; B.y = A.y; t = rr1->S.x*sina; A.y += t; B.y -= t;

t = sina*cosa;

// verify that A is vertical min/max, B is horizontal min/max
if (t < 0)
{
t = A.x; A.x = B.x; B.x = t;
t = A.y; A.y = B.y; B.y = t;
}

// verify that B is horizontal minimum (leftest-vertex)
if (sina < 0) { B.x = -B.x; B.y = -B.y; }

// if rr2(ma) isn't in the horizontal range of
// colliding with rr1(r), collision is impossible
if (B.x > TR.x || B.x > -BL.x) return 0;

// if rr1(r) is axis-aligned, vertical min/max are easy to get
if (t == 0) {ext1 = A.y; ext2 = -ext1; }
// else, find vertical min/max in the range [BL.x, TR.x]
else
{
x = BL.x-A.x; a = TR.x-A.x;
ext1 = A.y;
// if the first vertical min/max isn't in (BL.x, TR.x), then
// find the vertical min/max on BL.x or on TR.x
if (a*x > 0)
{
dx = A.x;
if (x < 0) { dx -= B.x; ext1 -= B.y; x = a; }
else       { dx += B.x; ext1 += B.y; }
ext1 *= x; ext1 /= dx; ext1 += A.y;
}

x = BL.x+A.x; a = TR.x+A.x;
ext2 = -A.y;
// if the second vertical min/max isn't in (BL.x, TR.x), then
// find the local vertical min/max on BL.x or on TR.x
if (a*x > 0)
{
dx = -A.x;
if (x < 0) { dx -= B.x; ext2 -= B.y; x = a; }
else       { dx += B.x; ext2 += B.y; }
ext2 *= x; ext2 /= dx; ext2 -= A.y;
}
}

// check whether rr2(ma) is in the vertical range of colliding with rr1(r)
// (for the horizontal range of rr2)
return !((ext1 < BL.y && ext2 < BL.y) ||
(ext1 > TR.y && ext2 > TR.y));
}

inline void AddVectors2D(_Vector2D * v1, _Vector2D * v2)
{
v1->x += v2->x; v1->y += v2->y;
}

inline void SubVectors2D(_Vector2D * v1, _Vector2D * v2)
{
v1->x -= v2->x; v1->y -= v2->y;
}

inline void RotateVector2DClockwise(_Vector2D * v, float ang)
{
float t, cosa = cos(ang), sina = sin(ang);
t = v->x;
v->x = t*cosa + v->y*sina;
v->y = -t*sina + v->y*cosa;
}
``````

Maybe it will help someone. The same algorithm in PHP:

``````function isPolygonsIntersecting(\$a, \$b) {
\$polygons = array(\$a, \$b);

for (\$i = 0; \$i < count(\$polygons); \$i++) {
\$polygon = \$polygons[\$i];

for (\$i1 = 0; \$i1 < count(\$polygon); \$i1++) {
\$i2 = (\$i1 + 1) % count(\$polygon);
\$p1 = \$polygon[\$i1];
\$p2 = \$polygon[\$i2];

\$normal = array(
"x" => \$p2["y"] - \$p1["y"],
"y" => \$p1["x"] - \$p2["x"]
);

\$minA = NULL; \$maxA = NULL;
for (\$j = 0; \$j < count(\$a); \$j++) {
\$projected = \$normal["x"] * \$a[\$j]["x"] + \$normal["y"] * \$a[\$j]["y"];
if (!isset(\$minA) || \$projected < \$minA) {
\$minA = \$projected;
}
if (!isset(\$maxA) || \$projected > \$maxA) {
\$maxA = \$projected;
}
}

\$minB = NULL; \$maxB = NULL;
for (\$j = 0; \$j < count(\$b); \$j++) {
\$projected = \$normal["x"] * \$b[\$j]["x"] + \$normal["y"] * \$b[\$j]["y"];
if (!isset(\$minB) || \$projected < \$minB) {
\$minB = \$projected;
}
if (!isset(\$maxB) || \$projected > \$maxB) {
\$maxB = \$projected;
}
}

if (\$maxA < \$minB || \$maxB < \$minA) {
return false;
}
}
}
return true;
}
``````

You can also use Rect.IntersectsWith().

For example, in WPF if you have two UIElements, with RenderTransform and placed on a Canvas, and you want to find out if they intersect you can use something similar:

``````bool IsIntersecting(UIElement element1, UIElement element2)
{
Rect area1 = new Rect(
(double)element1.GetValue(Canvas.TopProperty),
(double)element1.GetValue(Canvas.LeftProperty),
(double)element1.GetValue(Canvas.WidthProperty),
(double)element1.GetValue(Canvas.HeightProperty));

Rect area2 = new Rect(
(double)element2.GetValue(Canvas.TopProperty),
(double)element2.GetValue(Canvas.LeftProperty),
(double)element2.GetValue(Canvas.WidthProperty),
(double)element2.GetValue(Canvas.HeightProperty));

Transform transform1 = element1.RenderTransform as Transform;
Transform transform2 = element2.RenderTransform as Transform;

if (transform1 != null)
{
area1.Transform(transform1.Value);
}

if (transform2 != null)
{
area2.Transform(transform2.Value);
}

return area1.IntersectsWith(area2);
}
``````

A Type(Java)Script implementation with a toggle to (ex)include "Touch" situations:

``````class Position {
private _x: number;
private _y: number;

public constructor(x: number = null, y: number = null) {
this._x = x;
this._y = y;
}

public get x() { return this._x; }
public set x(value: number) { this._x = value; }

public get y() { return this._y; }
public set y(value: number) { this._y = value; }
}

class Polygon {
private _positions: Array<Position>;

public constructor(positions: Array<Position> = null) {
this._positions = positions;
}

if (!position) {
return;
}

if (!this._positions) {
this._positions = new Array<Position>();
}

this._positions.push(position);
}

public get positions(): ReadonlyArray<Position> { return this._positions; }

/**
* https://stackoverflow.com/a/12414951/468910
*
* Helper function to determine whether there is an intersection between the two polygons described
* by the lists of vertices. Uses the Separating Axis Theorem
*
* @param polygonToCompare a polygon to compare with
* @param allowTouch consider it an intersection when polygons only "touch"
* @return true if there is any intersection between the 2 polygons, false otherwise
*/
public isIntersecting(polygonToCompare: Polygon, allowTouch: boolean = true): boolean {
const polygons: Array<ReadonlyArray<Position>> = [this.positions, polygonToCompare.positions]

let minA, maxA, projected, i, i1, j, minB, maxB;

for (i = 0; i < polygons.length; i++) {

// for each polygon, look at each edge of the polygon, and determine if it separates
// the two shapes
const polygon = polygons[i];
for (i1 = 0; i1 < polygon.length; i1++) {

// grab 2 vertices to create an edge
const i2 = (i1 + 1) % polygon.length;
const p1 = polygon[i1];
const p2 = polygon[i2];

// find the line perpendicular to this edge
const normal = {
x: p2.y - p1.y,
y: p1.x - p2.x
};

minA = maxA = undefined;
// for each vertex in the first shape, project it onto the line perpendicular to the edge
// and keep track of the min and max of these values
for (j = 0; j < firstPolygonPositions.length; j++) {
projected = normal.x * firstPolygonPositions[j].x + normal.y * firstPolygonPositions[j].y;

if (!minA || projected < minA || (!allowTouch && projected === minA)) {
minA = projected;
}

if (!maxA || projected > maxA || (!allowTouch && projected === maxA)) {
maxA = projected;
}
}

// for each vertex in the second shape, project it onto the line perpendicular to the edge
// and keep track of the min and max of these values
minB = maxB = undefined;
for (j = 0; j < secondPolygonPositions.length; j++) {
projected = normal.x * secondPolygonPositions[j].x + normal.y * secondPolygonPositions[j].y;

if (!minB || projected < minB || (!allowTouch && projected === minB)) {
minB = projected;
}

if (!maxB || projected > maxB || (!allowTouch && projected === maxB)) {
maxB = projected;
}
}

// if there is no overlap between the projects, the edge we are looking at separates the two
// polygons, and we know there is no overlap
if (maxA < minB || (!allowTouch && maxA === minB) || maxB < minA || (!allowTouch && maxB === minA)) {
return false;
}
}
}

return true;
}
``````

Lua implementation built in love2d framework. Collision detection function works in pure lua anyway

``````math.inf = 1e309
pol = {{0, 0}, {30, 2}, {8, 30}}
pol2 = {{60, 60}, {90, 61}, {98, 100}, {80, 100}}
end
function love.draw()
for k,v in ipairs(pol) do
love.graphics.line(pol[k][1], pol[k][2], pol[k % #pol + 1][1], pol[k % #pol + 1][2])
end
for k,v in ipairs(pol2) do
love.graphics.line(pol2[k][1], pol2[k][2], pol2[k % #pol2 + 1][1], pol2[k % #pol2 + 1][2])
end
end

function love.update(dt)
pol[1][1] = love.mouse.getX()
pol[1][2] = love.mouse.getY()
pol[2][1] = pol[1][1] + 30
pol[2][2] = pol[1][2] + 2
pol[3][1] = pol[1][1] + 8
pol[3][2] = pol[1][2] + 30

--lazy way to see that's function works
print(doPolygonsIntersect(pol, pol2))
end
-------------------------------------------------------------------------
function doPolygonsIntersect(a,b)
polygons = {a,b}
for i=1, #polygons do
polygon = polygons[i]
for i1=1, #polygon do
i2 = i1 % #polygon + 1
p1 = polygon[i1]
p2 = polygon[i2]

nx,ny = p2[2] - p1[2], p1[1] - p2[1]

minA = math.inf
maxA = -math.inf
for j=1, #a do
projected = nx * a[j][1] + ny * a[j][2]
if projected < minA then minA = projected end
if projected > maxA then maxA = projected end
end

minB = math.inf
maxB = -math.inf
for j=1, #b do
projected = nx * b[j][1] + ny * b[j][2]
if projected < minB then minB = projected end
if projected > maxB then maxB = projected end
end

if maxA < minB or maxB < minA then return false end
end
end
return true
end
``````

In Python:

``````def do_polygons_intersect(a, b):
"""
* Helper function to determine whether there is an intersection between the two polygons described
* by the lists of vertices. Uses the Separating Axis Theorem
*
* @param a an ndarray of connected points [[x_1, y_1], [x_2, y_2],...] that form a closed polygon
* @param b an ndarray of connected points [[x_1, y_1], [x_2, y_2],...] that form a closed polygon
* @return true if there is any intersection between the 2 polygons, false otherwise
"""

polygons = [a, b];
minA, maxA, projected, i, i1, j, minB, maxB = None, None, None, None, None, None, None, None

for i in range(len(polygons)):

# for each polygon, look at each edge of the polygon, and determine if it separates
# the two shapes
polygon = polygons[i];
for i1 in range(len(polygon)):

# grab 2 vertices to create an edge
i2 = (i1 + 1) % len(polygon);
p1 = polygon[i1];
p2 = polygon[i2];

# find the line perpendicular to this edge
normal = { 'x': p2[1] - p1[1], 'y': p1[0] - p2[0] };

minA, maxA = None, None
# for each vertex in the first shape, project it onto the line perpendicular to the edge
# and keep track of the min and max of these values
for j in range(len(a)):
projected = normal['x'] * a[j][0] + normal['y'] * a[j][1];
if (minA is None) or (projected < minA):
minA = projected

if (maxA is None) or (projected > maxA):
maxA = projected

# for each vertex in the second shape, project it onto the line perpendicular to the edge
# and keep track of the min and max of these values
minB, maxB = None, None
for j in range(len(b)):
projected = normal['x'] * b[j][0] + normal['y'] * b[j][1]
if (minB is None) or (projected < minB):
minB = projected

if (maxB is None) or (projected > maxB):
maxB = projected

# if there is no overlap between the projects, the edge we are looking at separates the two
# polygons, and we know there is no overlap
if (maxA < minB) or (maxB < minA):
print("polygons don't intersect!")
return False;

return True
``````