I'm looking for an algorithm to detect if two rectangles intersect (one at an arbitrary angle, the other with only vertical/horizontal lines).

Testing if a corner of one is in the other ALMOST works. It fails if the rectangles form a cross-like shape.

It seems like a good idea to avoid using slopes of the lines, which would require special cases for vertical lines.

  • what if you add to your corner check, a check to see if the second rectangle is inside the bounds (rectangular) of the angled rectangle?
    – Wes P
    Sep 22, 2008 at 15:19
  • What language are you gonna do this in? Because in Java there are built-in classes that let you do this.
    – Martijn
    Sep 22, 2008 at 15:21
  • I think graphics api and most GUI libraries(like swing) has this implemented.
    – l_39217_l
    Sep 22, 2008 at 15:21
  • that can miss cases where they overlap but no corner is inside any rectangle Sep 22, 2008 at 15:21
  • 1
    This question is almost the same as: stackoverflow.com/questions/306316/…. Although, this is looking for a solution that is particularly for C++. The accepted answer is also pretty simple and straightforward. Dec 28, 2013 at 3:51

20 Answers 20


The standard method would be to do the separating axis test (do a google search on that).

In short:

  • Two objects don't intersect if you can find a line that separates the two objects. e.g. the objects / all points of an object are on different sides of the line.

The fun thing is, that it's sufficient to just check all edges of the two rectangles. If the rectangles don't overlap one of the edges will be the separating axis.

In 2D you can do this without using slopes. An edge is simply defined as the difference between two vertices, e.g.

  edge = v(n) - v(n-1)

You can get a perpendicular to this by rotating it by 90°. In 2D this is easy as:

  rotated.x = -unrotated.y
  rotated.y =  unrotated.x

So no trigonometry or slopes involved. Normalizing the vector to unit-length is not required either.

If you want to test if a point is on one or another side of the line you can just use the dot-product. the sign will tell you which side you're on:

  // rotated: your rotated edge
  // v(n-1) any point from the edge.
  // testpoint: the point you want to find out which side it's on.

  side = sign (rotated.x * (testpoint.x - v(n-1).x) + 
               rotated.y * (testpoint.y - v(n-1).y);

Now test all points of rectangle A against the edges of rectangle B and vice versa. If you find a separating edge the objects don't intersect (providing all other points in B are on the other side of the edge being tested for - see drawing below). If you find no separating edge either the rectangles are intersecting or one rectangle is contained in the other.

The test works with any convex polygons btw..

Amendment: To identify a separating edge, it is not enough to test all points of one rectangle against each edge of the other. The candidate-edge E (below) would as such be identified as a separating edge, as all points in A are in the same half-plane of E. However, it isn't a separating edge because the vertices Vb1 and Vb2 of B are also in that half-plane. It would only have been a separating edge if that had not been the case http://www.iassess.com/collision.png

  • 2
    This algorithm doesn't work for all cases. It is possible to place the second rectangle rotated 45 degrees to the first rectangle and offset along the diagonal so that it fulfills the above intersection tests but doesn't intersect.
    – Skizz
    Sep 22, 2008 at 21:22
  • 6
    Skizz, check all eight edges. If the objects don't intersect one of the eight edges will separate them. Why don't you post an image showing your case? I can show you the axis.. Sep 22, 2008 at 22:39
  • 2
    My mistake, it does cope with that condition.
    – Skizz
    Sep 22, 2008 at 22:50
  • 2
    The image is dead now (nov 2012) Nov 25, 2012 at 12:24
  • 4
    I had a lot of trouble visualizing this so I re-created what I think the image being referenced looked like. imgur.com/bNwrzsv
    – Rjdlee
    Jun 22, 2015 at 4:17

Basically look at the following picture:

If the two boxes collide, the lines A and B will overlap.

Note that this will have to be done on both the X and the Y axis, and both need to overlap for the rectangles to collide.

There is a good article in gamasutra.com which answers the question (the picture is from the article). I did similar algorithm 5 years ago and I have to find my code snippet to post it here later

Amendment: The Separating Axis Theorem states that two convex shapes do not overlap if a separating axis exists (i.e. one where the projections as shown do not overlap). So "A separating axis exists" => "No overlap". This is not a bi-implication so you cannot conclude the converse.

  • 1
    Obviously, as two squares (0,0,1,1) and (0,3,1,4) do not overlap but their projections on the x axis completely overlap. Both tests are necessary, the combination is sufficient.
    – MSalters
    Oct 3, 2008 at 11:30
  • 19
    It is not sufficient for the x and y projections to overlap : take eg the rectangles [(0,0), (0,3), (3,3), (3,0)] and [(2,5), (5,2), (7,4), (4,7)]. Jan 19, 2009 at 9:18
  • 4
    I agree with @Joel in Gö. This method misses a large set of cases where the rectangles do not overlap, yet their projected radii do in both x and y.
    – Scottie T
    Apr 14, 2009 at 17:38
  • 5
    This answer is not wrong, but it is misleading. It is true that: If the two boxes collide, the lines A and B will overlap. but it is also true that: If the lines A and B overlap, the two boxes may or may not be colliding
    – matt burns
    Jan 20, 2010 at 10:58
  • 8
    @floater: I would say it's not only wrong, but also misleading, which is even worse. Jan 26, 2010 at 18:59

In Cocoa you could easily detect whether the selectedArea rect intersects your rotated NSView's frame rect. You don't even need to calculate polygons, normals an such. Just add these methods to your NSView subclass. For instance, the user selects an area on the NSView's superview, then you call the method DoesThisRectSelectMe passing the selectedArea rect. The API convertRect: will do that job. The same trick works when you click on the NSView to select it. In that case simply override the hitTest method as below. The API convertPoint: will do that job ;-)

- (BOOL)DoesThisRectSelectMe:(NSRect)selectedArea
    NSRect localArea = [self convertRect:selectedArea fromView:self.superview];

    return NSIntersectsRect(localArea, self.bounds);

- (NSView *)hitTest:(NSPoint)aPoint
    NSPoint localPoint = [self convertPoint:aPoint fromView:self.superview];
    return NSPointInRect(localPoint, self.bounds) ? self : nil;
  • 2
    That code only works for rectangles that are square to the screen. That's a trivial case. The assumption is that we're dealing with rectangles that are not at 90 degree angles to the screen or each other.
    – Duncan C
    May 10, 2013 at 23:47
  • As I have checked and used in my applications, that code works on any rotated rectangle. No matter the rotation degree.
    – Leonardo
    Oct 14, 2014 at 10:47
  • This doesn't describe the algorithm, though, it just mentions a library that already uses it.
    – Ben Voigt
    Dec 4, 2014 at 19:34

m_pGladiator's answer is right and I prefer to it. Separating axis test is simplest and standard method to detect rectangle overlap. A line for which the projection intervals do not overlap we call a separating axis. Nils Pipenbrinck's solution is too general. It use dot product to check whether one shape is totally on the one side of the edge of the other. This solution is actually could induce to n-edge convex polygons. However, it is not optmized for two rectangles.

the critical point of m_pGladiator's answer is that we should check two rectangles' projection on both axises (x and y). If two projections are overlapped, then we could say these two rectangles are overlapped. So the comments above to m_pGladiator's answer are wrong.

for the simple situation, if two rectangles are not rotated, we present a rectangle with structure:

struct Rect {
    x, // the center in x axis
    y, // the center in y axis

we name rectangle A, B with rectA, rectB.

    if Math.abs(rectA.x - rectB.x) < (Math.abs(rectA.width + rectB.width) / 2) 
&& (Math.abs(rectA.y - rectB.y) < (Math.abs(rectA.height + rectB.height) / 2))
        // A and B collide
    end if

if any one of the two rectangles are rotated, It may needs some efforts to determine the projection of them on x and y axises. Define struct RotatedRect as following:

struct RotatedRect : Rect {
    double angle; // the rotating angle oriented to its center

the difference is how the width' is now a little different: widthA' for rectA: Math.sqrt(rectA.width*rectA.width + rectA.height*rectA.height) * Math.cos(rectA.angle) widthB' for rectB: Math.sqrt(rectB.width*rectB.width + rectB.height*rectB.height) * Math.cos(rectB.angle)

    if Math.abs(rectA.x - rectB.x) < (Math.abs(widthA' + widthB') / 2) 
&& (Math.abs(rectA.y - rectB.y) < (Math.abs(heightA' + heightB') / 2))
        // A and B collide
    end if

Could refer to a GDC(Game Development Conference 2007) PPT www.realtimecollisiondetection.net/pubs/GDC07_Ericson_Physics_Tutorial_SAT.ppt

  • Why do you need Math.abs() in "Math.abs(rectA.width + rectB.width)", to handle negative widths?
    – AlexWien
    Feb 6, 2013 at 21:52
  • The separating axis is not necessarily a compass direction, it can have any angle.
    – Ben Voigt
    Dec 4, 2014 at 19:35
  • Non-rotated rectangles rectA(x=0, y=0, width=1, height=1) and rectB(x=2, y=0, width=100, height=1) don't intersect but your method says they intersect. Am I doing something wrong? Oct 11, 2017 at 0:32
  • This answer is also wrong. If both projections in x and y axis overlap, that does not imply the rectangles overlap. See for example: imgur.com/a/HyorpQc
    – Puco4
    Oct 1, 2020 at 12:11

The accepted answer about the separating axis test was very illuminating but I still felt it was not trivial to apply. I will share the pseudo-code I thought, "optimizing" first with the bounding circle test (see this other answer), in case it might help other people. I considered two rectangles A and B of the same size (but it is straightforward to consider the general situation).

1 Bounding circle test:

enter image description here

    function isRectangleACollidingWithRectangleB:
      if d > 2 * R:
         return False

Computationally is much faster than the separating axis test. You only need to consider the separating axis test in the situation that both circles collide.

2 Separating axis test

enter image description here

The main idea is:

  • Consider one rectangle. Cycle along its vertices V(i).

  • Calculate the vector Si+1: V(i+1) - V(i).

  • Calculate the vector Ni using Si+1: Ni = (-Si+1.y, Si+1.x). This vector is the blue from the image. The sign of the dot product between the vectors from V(i) to the other vertices and Ni will define the separating axis (magenta dashed line).

  • Calculate the vector Si-1: V(i-1) - V(i). The sign of the dot product between Si-1 and Ni will define the location of the first rectangle with respect to the separating axis. In the example of the picture, they go in different directions, so the sign will be negative.

  • Cycle for all vertices j of the second square and calculate the vector Sij = V(j) - V(i).

  • If for any vertex V(j), the sign of the dot product of the vector Sij with Ni is the same as with the dot product of the vector Si-1 with Ni, this means both vertices V(i) and V(j) are on the same side of the magenta dashed line and, thus, vertex V(i) does not have a separating axis. So we can just skip vertex V(i) and repeat for the next vertex V(i+1). But first we update Si-1 = - Si+1. When we reach the last vertex (i = 4), if we have not found a separating axis, we repeat for the other rectangle. And if we still do not find a separating axis, this implies there is no separating axis and both rectangles collide.

  • If for a given vertex V(i) and all vertices V(j), the sign of the dot product of the vector Sij with Ni is different than with the vector Si-1 with Ni (as occurs in the image), this means we have found the separating axis and the rectangles do not collide.

In pseudo-code:

    function isRectangleACollidingWithRectangleB:
      #Consider first rectangle A:
      Si-1 = Vertex_A[4] - Vertex_A[1]
      for i in Vertex_A:
         Si+1 = Vertex_A[i+1] - Vertex_A[i]
         Ni = [- Si+1.y, Si+1.x ]
         sgn_i = sign( dot_product(Si-1, Ni) ) #sgn_i is the sign of rectangle A with respect the separating axis

         for j in Vertex_B:
            sij = Vertex_B[j] - Vertex_A[i]
            sgn_j = sign( dot_product(sij, Ni) ) #sgnj is the sign of vertex j of square B with respect the separating axis
            if sgn_i * sgn_j > 0: #i.e., we have the same sign
                break #Vertex i does not define separating axis
                if j == 4: #we have reached the last vertex so vertex i defines the separating axis
                   return False
        Si-1 = - Si+1

      #Repeat for rectangle B

      #If we do not find any separating axis
      return True 

You can find the code in Python here.

Note: In this other answer they also suggest for optimization to try before the separating axis test whether the vertices of one rectangle are inside the other as a sufficient condition for colliding. However, in my trials I found this intermediate step to actually be less efficient.


Check to see if any of the lines from one rectangle intersect any of the lines from the other. Naive line segment intersection is easy to code up.

If you need more speed, there are advanced algorithms for line segment intersection (sweep-line). See http://en.wikipedia.org/wiki/Line_segment_intersection

  • 4
    Careful! Don't forget the case where one rectangle completely encloses another
    – Pitarou
    Sep 22, 2008 at 15:35

One solution is to use something called a No Fit Polygon. This polygon is calculated from the two polygons (conceptually by sliding one around the other) and it defines the area for which the polygons overlap given their relative offset. Once you have this NFP then you simply have to do an inclusion test with a point given by the relative offset of the two polygons. This inclusion test is quick and easy but you do have to create the NFP first.

Have a search for No Fit Polygon on the web and see if you can find an algorithm for convex polygons (it gets MUCH more complex if you have concave polygons).


Here is what I think will take care of all possible cases. Do the following tests.

  1. Check any of the vertices of rectangle 1 reside inside rectangle 2 and vice versa. Anytime you find a vertex that resides inside the other rectangle you can conclude that they intersect and stop the search. THis will take care of one rectangle residing completely inside the other.
  2. If the above test is inconclusive find the intersecting points of each line of 1 rectangle with each line of the other rectangle. Once a point of intersection is found check if it resides between inside the imaginary rectangle created by the corresponding 4 points. When ever such a point is found conclude that they intersect and stop the search.

If the above 2 tests return false then these 2 rectangles do not overlap.


If you're using Java, all implementations of the Shape interface have an intersects method that take a rectangle.

  • Unfortunately I'm using C#. The Rectangle class has a Contains () method, but it's only for non-rotated rectangles.
    – user20493
    Sep 22, 2008 at 18:53
  • intersects() method is pretty useless since it returns boolean instead of intersection I guess.
    – ZZ 5
    Oct 27, 2015 at 15:02

You could find the intersection of each side of the angled rectangle with each side of the axis-aligned one. Do this by finding the equation of the infinite line on which each side lies (i.e. v1 + t(v2-v1) and v'1 + t'(v'2-v'1) basically), finding the point at which the lines meet by solving for t when those two equations are equal (if they're parallel, you can test for that) and then testing whether that point lies on the line segment between the two vertices, i.e. is it true that 0 <= t <= 1 and 0 <= t' <= 1.

However, this doesn't cover the case when one rectangle completely covers the other. That you can cover by testing whether all four points of either rectangle lie inside the other rectangle.


This is what I would do, for the 3D version of this problem:

Model the 2 rectangles as planes described by equation P1 and P2, then write P1=P2 and derive from that the line of intersection equation, which won't exist if the planes are parallel (no intersection), or are in the same plane, in which case you get 0=0. In that case you will need to employ a 2D rectangle intersection algorithm.

Then I would see if that line, which is in the plane of both rectangles, passes through both rectangles. If it does, then you have an intersection of 2 rectangles, otherwise you don't (or shouldn't, I might have missed a corner case in my head).

To find if a line passes through a rectangle in the same plane, I would find the 2 points of intersection of the line and the sides of the rectangle (modelling them using line equations), and then make sure the points of intersections are with in range.

That is the mathematical descriptions, unfortunately I have no code to do the above.

  • You missed the part where if you find the planar intersect line, you have to ensure that a portion of it exists within both rectangles. Mar 7, 2013 at 16:50

Another way to do the test which is slightly faster than using the separating axis test, is to use the winding numbers algorithm (on quadrants only - not angle-summation which is horrifically slow) on each vertex of either rectangle (arbitrarily chosen). If any of the vertices have a non-zero winding number, the two rectangles overlap.

This algorithm is somewhat more long-winded than the separating axis test, but is faster because it only require a half-plane test if edges are crossing two quadrants (as opposed to up to 32 tests using the separating axis method)

The algorithm has the further advantage that it can be used to test overlap of any polygon (convex or concave). As far as I know, the algorithm only works in 2D space.

  • 3
    I may be wrong, but doesn't that just check if the vertices of one rectangle are inside another? If yes, it's not enough because rectangles may overlap without any vertices inside.
    – sinelaw
    Oct 10, 2011 at 19:45
  • Can they, with rectangles? How? It seems to me that in order for 2 rectangles to intersect, at least one vertex of one of the rectangles must lie on the other rectangle.
    – Duncan C
    May 10, 2013 at 23:51
  • @DuncanC: Yes, they can. The counterexample is a cross, and it was even listed in the original question.
    – Ben Voigt
    Dec 4, 2014 at 19:41
  • @BenVoigt This is a very old thread, but you're absolutely right.
    – Duncan C
    Dec 4, 2014 at 21:21

Either I am missing something else why make this so complicated?

if (x1,y1) and (X1,Y1) are corners of the rectangles, then to find intersection do:

    xIntersect = false;
    yIntersect = false;
    if (!(Math.min(x1, x2, x3, x4) > Math.max(X1, X2, X3, X4) || Math.max(x1, x2, x3, x4) < Math.min(X1, X2, X3, X4))) xIntersect = true;
    if (!(Math.min(y1, y2, y3, y4) > Math.max(Y1, Y2, Y3, Y4) || Math.max(y1, y2, y3, y4) < Math.min(Y1, Y2, Y3, Y4))) yIntersect = true;
    if (xIntersect && yIntersect) {alert("Intersect");}
  • 3
    You are missing that he wants one to be rotated by an arbitrary angle.
    – Robotbugs
    Mar 16, 2013 at 17:16

I implemented it like this:

bool rectCollision(const CGRect &boundsA, const Matrix3x3 &mB, const CGRect &boundsB)
    float Axmin = boundsA.origin.x;
    float Axmax = Axmin + boundsA.size.width;
    float Aymin = boundsA.origin.y;
    float Aymax = Aymin + boundsA.size.height;

    float Bxmin = boundsB.origin.x;
    float Bxmax = Bxmin + boundsB.size.width;
    float Bymin = boundsB.origin.y;
    float Bymax = Bymin + boundsB.size.height;

    // find location of B corners in A space
    float B0x = mB(0,0) * Bxmin + mB(0,1) * Bymin + mB(0,2);
    float B0y = mB(1,0) * Bxmin + mB(1,1) * Bymin + mB(1,2);

    float B1x = mB(0,0) * Bxmax + mB(0,1) * Bymin + mB(0,2);
    float B1y = mB(1,0) * Bxmax + mB(1,1) * Bymin + mB(1,2);

    float B2x = mB(0,0) * Bxmin + mB(0,1) * Bymax + mB(0,2);
    float B2y = mB(1,0) * Bxmin + mB(1,1) * Bymax + mB(1,2);

    float B3x = mB(0,0) * Bxmax + mB(0,1) * Bymax + mB(0,2);
    float B3y = mB(1,0) * Bxmax + mB(1,1) * Bymax + mB(1,2);

    if(B0x<Axmin && B1x<Axmin && B2x<Axmin && B3x<Axmin)
        return false;
    if(B0x>Axmax && B1x>Axmax && B2x>Axmax && B3x>Axmax)
        return false;
    if(B0y<Aymin && B1y<Aymin && B2y<Aymin && B3y<Aymin)
        return false;
    if(B0y>Aymax && B1y>Aymax && B2y>Aymax && B3y>Aymax)
        return false;

    float det = mB(0,0)*mB(1,1) - mB(0,1)*mB(1,0);
    float dx = mB(1,2)*mB(0,1) - mB(0,2)*mB(1,1);
    float dy = mB(0,2)*mB(1,0) - mB(1,2)*mB(0,0);

    // find location of A corners in B space
    float A0x = (mB(1,1) * Axmin - mB(0,1) * Aymin + dx)/det;
    float A0y = (-mB(1,0) * Axmin + mB(0,0) * Aymin + dy)/det;

    float A1x = (mB(1,1) * Axmax - mB(0,1) * Aymin + dx)/det;
    float A1y = (-mB(1,0) * Axmax + mB(0,0) * Aymin + dy)/det;

    float A2x = (mB(1,1) * Axmin - mB(0,1) * Aymax + dx)/det;
    float A2y = (-mB(1,0) * Axmin + mB(0,0) * Aymax + dy)/det;

    float A3x = (mB(1,1) * Axmax - mB(0,1) * Aymax + dx)/det;
    float A3y = (-mB(1,0) * Axmax + mB(0,0) * Aymax + dy)/det;

    if(A0x<Bxmin && A1x<Bxmin && A2x<Bxmin && A3x<Bxmin)
        return false;
    if(A0x>Bxmax && A1x>Bxmax && A2x>Bxmax && A3x>Bxmax)
        return false;
    if(A0y<Bymin && A1y<Bymin && A2y<Bymin && A3y<Bymin)
        return false;
    if(A0y>Bymax && A1y>Bymax && A2y>Bymax && A3y>Bymax)
        return false;

    return true;

The matrix mB is any affine transform matrix that converts points in the B space to points in the A space. This includes simple rotation and translation, rotation plus scaling, and full affine warps, but not perspective warps.

It may not be as optimal as possible. Speed was not a huge concern. However it seems to work ok for me.


Here is a matlab implementation of the accepted answer:

function olap_flag = ol(A,B,sub)

%A and B should be 4 x 2 matrices containing the xy coordinates of the corners in clockwise order

if nargin == 2
  olap_flag = ol(A,B,1) && ol(B,A,1);

urdl = diff(A([1:4 1],:));
s = sum(urdl .* A, 2);
sdiff = B * urdl' - repmat(s,[1 4]);

olap_flag = ~any(max(sdiff)<0);

This is the conventional method, go line by line and check whether the lines are intersecting. This is the code in MATLAB.

C1 = [0, 0];    % Centre of rectangle 1 (x,y)
C2 = [1, 1];    % Centre of rectangle 2 (x,y)
W1 = 5; W2 = 3; % Widths of rectangles 1 and 2
H1 = 2; H2 = 3; % Heights of rectangles 1 and 2
% Define the corner points of the rectangles using the above
R1 = [C1(1) + [W1; W1; -W1; -W1]/2, C1(2) + [H1; -H1; -H1; H1]/2];
R2 = [C2(1) + [W2; W2; -W2; -W2]/2, C2(2) + [H2; -H2; -H2; H2]/2];

R1 = [R1 ; R1(1,:)] ;
R2 = [R2 ; R2(1,:)] ;

hold on

%% lines of Rectangles 
L1 = [R1(1:end-1,:) R1(2:end,:)] ;
L2 = [R2(1:end-1,:) R2(2:end,:)] ;
%% GEt intersection points
P = zeros(2,[]) ;
count = 0 ;
for i = 1:4
    line1 = reshape(L1(i,:),2,2) ;
    for j = 1:4
        line2 = reshape(L2(j,:),2,2) ;
        point = InterX(line1,line2) ;
        if ~isempty(point)
            count = count+1 ;
            P(:,count) = point ;
if ~isempty(P)
    fprintf('Given rectangles intersect at %d points:\n',size(P,2))

the function InterX can be downloaded from: https://in.mathworks.com/matlabcentral/fileexchange/22441-curve-intersections?focused=5165138&tab=function


I have a simplier method of my own, if we have 2 rectangles:

R1 = (min_x1, max_x1, min_y1, max_y1)

R2 = (min_x2, max_x2, min_y2, max_y2)

They overlap if and only if:

Overlap = (max_x1 > min_x2) and (max_x2 > min_x1) and (max_y1 > min_y2) and (max_y2 > min_y1)

You can do it for 3D boxes too, actually it works for any number of dimensions.


Enough has been said in other answers, so I'll just add pseudocode one-liner:

!(a.left > b.right || b.left > a.right || a.top > b.bottom || b.top > a.bottom);

Check if the center of mass of all the vertices of both rectangles lies within one of the rectangles.


Well, the brute force method is to walk the edges of the horizontal rectangle and check each point along the edge to see if it falls on or in the other rectangle.

The mathematical answer is to form equations describing each edge of both rectangles. Now you can simply find if any of the four lines from rectangle A intersect any of the lines of rectangle B, which should be a simple (fast) linear equation solver.

  • 2
    The problem with equations is when you have a vertical line, which has infinite slope.
    – user20493
    Sep 22, 2008 at 18:56
  • There are corner cases for every solution.
    – Adam Davis
    Sep 23, 2008 at 5:36
  • 2
    and one square entirely enclosing the other. Jan 16, 2009 at 19:14

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