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How can I check if 2 segments intersect?

I've the following data:

Segment1 [ {x1,y1}, {x2,y2} ]
Segment2 [ {x1,y1}, {x2,y2} ] 

I need to write a small algorithm in python to detect if the 2 lines are intersecting.

Update:
alt text

share|improve this question
    
do your data define a line or a segment ? –  PierrOz Oct 1 '10 at 10:26
    
because unless running exactly parallel, two lines will always intersect, in the end, at some point.. –  Jochem Oct 1 '10 at 10:28
    
even if they're parallel, they intersect at infinity. pep 326 would have come in handy here. –  aaronasterling Oct 1 '10 at 10:30
    
@PierrOz @Jochem @AaronMcSmooth They are SEGMENTS :) sorry –  Patrick Oct 1 '10 at 10:32
    
@S.Lott ok Done –  Patrick Oct 1 '10 at 10:45

13 Answers 13

up vote 19 down vote accepted

The formula for a line is:

f(x) = A*x + b = y

For a segment, it is exactly the same, except that x is included into an interval I.

If you have two segments, defined as follow:

Segment1 = {(X1, Y1), (X2, Y2)}
Segment2 = {(X3, Y3), (X4, Y4)}

The abcisse Xa of the potential point of intersection (Xa,Ya) must be contained in both interval I1 and I2, defined as follow :

I1 = [MIN(X1,X2), MAX(X1,X2)]
I2 = [MIN(X3,X4), MAX(X3,X4)]

And we could say that Xa is included into :

Ia = [MAX( MIN(X1,X2), MIN(X3,X4) ), MIN( MAX(X1,X2), MAX(X3,X4)] )]

Now, you need to check that this interval Ia exists :

if (MAX(X1,X2) < MIN(X3,X4))
    return false; // There is no mutual abcisses

So, you got two line formula, and a mutual interval. Your line formulas are:

f1(x) = A1*x + b1 = y
f2(x) = A2*x + b2 = y

As we got two points by segment, we are able to determine A1, A2, b1 and b2:

A1 = (Y1-Y2)/(X1-X2) // Pay attention to not dividing by zero
A2 = (Y3-Y4)/(X3-X4) // Pay attention to not dividing by zero
b1 = Y1-A1*X1 = Y2-A1*X2
b2 = Y3-A2*X3 = Y4-A2*X4

If the segments are parallel, then A1 == A2 :

if (A1 == A2)
    return false; // Parallel segments

A point (Xa,Ya) standing on both line must verify both formulas f1 and f2:

Ya = A1 * Xa + b1
Ya = A2 * Xa + b2
A1 * Xa + b1 = A2 * Xa + b2
Xa = (b2 - b1) / (A1 - A2) // Once again, pay attention to not dividing by zero

The last thing to do is check that Xa is included into Ia:

if ( (Xa < MAX( MIN(X1,X2), MIN(X3,X4) )) ||
  (Xa > MIN( MAX(X1,X2), MAX(X3,X4) )) )
    return false; // intersection is out of bound
else
    return true;

In addition to this, you may check at startup that two of the four provided points are not equals to avoid all that testing.

share|improve this answer
    
Segments, they are segments, sorry. Could you update your answer given segments ? –  Patrick Oct 1 '10 at 10:33
    
ok thanks I will go through the code. Wow isn't complicated ? I thought it was not that long solution. But if it's the only one.. well let's do it. –  Patrick Oct 1 '10 at 13:28
4  
This is not so complicated, i wrote a lots of (unessential ?) intermediate steps in a comprehension purpose. The main points to implements are just : Check mutual interval existence, calculate A1, A2, b1, b2, and Xa, and then check that Xa is included in the mutual interval. That's all :) –  OMG_peanuts Oct 1 '10 at 13:36
    
you are right, sorry it's many years I don't handle math :) –  Patrick Oct 2 '10 at 9:30
1  
A1 - A2 will never be zero because if(A1 == A2) would have returned before this calculation in that case. –  inkredibl Oct 22 '12 at 17:49

User @i_4_got points to this page with a very efficent solution in Python. I reproduce it here for convenience (since it would have made me happy to have it here):

def ccw(A,B,C):
    return (C.y-A.y) * (B.x-A.x) > (B.y-A.y) * (C.x-A.x)

# Return true if line segments AB and CD intersect
def intersect(A,B,C,D):
    return ccw(A,C,D) != ccw(B,C,D) and ccw(A,B,C) != ccw(A,B,D)
share|improve this answer
2  
Very simple and elegant, but it does not deal well with colinearity, and thus more code needed for that purpose. –  charles Jun 3 '13 at 8:44
2  
For a solution that also handles collinearity check out geeksforgeeks.org/check-if-two-given-line-segments-intersect –  Zsolt Safrany Nov 10 '14 at 10:34

You don't have to compute exactly where does the segments intersect, but only understand whether they intersect at all. This will simplify the solution.

The idea is to treat one segment as the "anchor" and separate the second segment into 2 points.
Now, you will have to find the relative position of each point to the "anchored" segment (OnLeft, OnRight or Collinear).
After doing so for both points, check that one of the points is OnLeft and the other is OnRight (or perhaps include Collinear position, if you wish to include improper intersections as well).

You must then repeat the process with the roles of anchor and separated segments.

An intersection exists if, and only if, one of the points is OnLeft and the other is OnRight. See this link for a more detailed explanation with example images for each possible case.

Implementing such method will be much easier than actually implementing a method that finds the intersection point (given the many corner cases which you will have to handle as well).

Update

The following functions should illustrate the idea (source: Computational Geometry in C).
Remark: This sample assumes the usage of integers. If you're using some floating-point representation instead (which could obviously complicate things), then you should determine some epsilon value to indicate "equality" (mostly for the IsCollinear evaluation).

// points "a" and "b" forms the anchored segment.
// point "c" is the evaluated point
bool IsOnLeft(Point a, Point b, Point c)
{
     return Area2(a, b, c) > 0;
}

bool IsOnRight(Point a, Point b, Point c)
{
     return Area2(a, b, c) < 0;
}

bool IsCollinear(Point a, Point b, Point c)
{
     return Area2(a, b, c) == 0;
}

// calculates the triangle's size (formed by the "anchor" segment and additional point)
int Area2(Point a, Point b, Point c)
{
     return (b.X - a.X) * (c.Y - a.Y) -
            (c.X - a.X) * (b.Y - a.Y);
}

Of course, when using these function, one must remember to check that each segment lays "between" the other segment (since these are finite segments, and not infinite lines).

Also, using these function you can understand whether you've got a proper or improper intersection.

  • Proper: There are no collinear points. The segments crosses each other "from side to side".
  • Improper: One segment only "touches" the other (at least one of the points is collinear to the anchored segment).
share|improve this answer
    
+1 Pretty much my idea too. If you just think about where the points are in relation to each other, you can decide if their segments must to intersect or not, without calculating anything. –  Jochen Ritzel Oct 1 '10 at 19:12
    
and @THC4k Uhm, it is actually not clear. FOr example check the image I've added to the question: the 2 points are "OnLeft" and "OnRight" but the 2 segments are not intersecting. –  Patrick Oct 2 '10 at 9:11
    
@Patrick, actually no. Depending on which of the segments is the "anchor", then both points are either OnLeft or OnRight in this case. (See my updated answer). –  Liran Oct 2 '10 at 10:58
    
+1 I've seen dozens of answers to this problem, but this is by far the clearest, simplest, and most efficient that I've seen. :) –  Miguel Oct 15 '11 at 1:15

Suppose the two segments have endpoints A,B and C,D. The numerically robust way to determine intersection is to check the sign of the four determinants:

| Ax-Cx  Bx-Cx |    | Ax-Dx  Bx-Dx |
| Ay-Cy  By-Cy |    | Ay-Dy  By-Dy |

| Cx-Ax  Dx-Ax |    | Cx-Bx  Dx-Bx |
| Cy-Ay  Dy-Ay |    | Cy-By  Dy-By |

For intersection, each determinant on the left must have the opposite sign of the one to the right, but there need not be any relationship between the two lines. You are basically checking each point of a segment against the other segment to make sure they lie on opposite sides of the line defined by the other segment.

See here: http://www.cs.cmu.edu/~quake/robust.html

share|improve this answer

You have two line segments. Define one segment by endpoints A & B and the second segment by endpoints C & D. There is a nice trick to show that they must intersect, WITHIN the bounds of the segments. (Note that the lines themselves may intersect beyond the bounds of the segments, so you must be careful. Good code will also watch for parallel lines.)

The trick is to test that points A and B must line on opposite sides of line CD, AND that points C and D must lie on opposite sides of line AB.

Since this is homework, I won't give you an explicit solution. But a simple test to see which side of a line a point falls on, is to use a dot product. Thus, for a given line CD, compute the normal vector to that line (I'll call it N_C.) Now, simply test the signs of these two results:

dot(A-C,N_C)

and

dot(B-C,N_C)

If those results have opposite signs, then A and B are opposite sides of line CD. Now do the same test for the other line, AB. It has normal vector N_A. Compare the signs of

dot(C-A,N_A)

and

dot(D-A,N_A)

I'll leave it to you to figure out how to compute a normal vector. (In 2-d, that is trivial, but will your code worry about whether A and B are distinct points? Likewise, are C and D distinct?)

You still need to worry about line segments that lie along the same infinite line, or if one point actually falls on the other line segment itself. Good code will cater to every possible problem.

share|improve this answer

Based on Liran's and Grumdrig's excellent answers here is a complete Python code to verify if closed segments do intersect. Works for collinear segments, segments parallel to axis Y, degenerate segments (devil is in details). Assumes integer coordinates. Floating point coordinates require a modification to points equality test.

def side(a,b,c):
    """ Returns a position of the point c relative to the line going through a and b
        Points a, b are expected to be different
    """
    d = (c[1]-a[1])*(b[0]-a[0]) - (b[1]-a[1])*(c[0]-a[0])
    return 1 if d > 0 else (-1 if d < 0 else 0)

def is_point_in_closed_segment(a, b, c):
    """ Returns True if c is inside closed segment, False otherwise.
        a, b, c are expected to be collinear
    """
    if a[0] < b[0]:
        return a[0] <= c[0] and c[0] <= b[0]
    if b[0] < a[0]:
        return b[0] <= c[0] and c[0] <= a[0]

    if a[1] < b[1]:
        return a[1] <= c[1] and c[1] <= b[1]
    if b[1] < a[1]:
        return b[1] <= c[1] and c[1] <= a[1]

    return a[0] == c[0] and a[1] == c[1]

#
def closed_segment_intersect(a,b,c,d):
    """ Verifies if closed segments a, b, c, d do intersect.
    """
    if a == b:
        return a == c or a == d
    if c == d:
        return c == a or c == b

    s1 = side(a,b,c)
    s2 = side(a,b,d)

    # All points are collinear
    if s1 == 0 and s2 == 0:
        return \
            is_point_in_closed_segment(a, b, c) or is_point_in_closed_segment(a, b, d) or \
            is_point_in_closed_segment(c, d, a) or is_point_in_closed_segment(c, d, b)

    # No touching and on the same side
    if s1 and s1 == s2:
        return False

    s1 = side(c,d,a)
    s2 = side(c,d,b)

    # No touching and on the same side
    if s1 and s1 == s2:
        return False

    return True
share|improve this answer

if your data define line you just have to prove that they are not parallel. To do this you can compute

alpha = float(y2 - y1) / (x2 - x1).

If this coefficient is equal for both Line1 and Line2, it means the line are parallel. If not, it means they will intersect.

If they are parallel you then have to prove that they are not the same. For that, you compute

beta = y1 - alpha*x1

If beta is the same for Line1 and Line2,it means you line intersect as they are equal

If they are segment, you still have to compute alpha and beta as described above for each Line. Then you have to check that (beta1 - beta2) / (alpha1 - alpha2) is greater than Min(x1_line1, x2_line1) and less than Max(x1_line1, x2_line1)

share|improve this answer
    
Segments, they are segments, sorry. Could you update your answer given segments ? –  Patrick Oct 1 '10 at 10:34

Calculate the intersection point of the lines laying on your segments (it means basically to solve a linear equation system), then check whether is it between the starting and ending points of your segments.

share|improve this answer

This is what I've got for AS3, don't know much about python but the concept is there

    public function getIntersectingPointF($A:Point, $B:Point, $C:Point, $D:Point):Number {
        var A:Point = $A.clone();
        var B:Point = $B.clone();
        var C:Point = $C.clone();
        var D:Point = $D.clone();
        var f_ab:Number = (D.x - C.x) * (A.y - C.y) - (D.y - C.y) * (A.x - C.x);

        // are lines parallel
        if (f_ab == 0) { return Infinity };

        var f_cd:Number = (B.x - A.x) * (A.y - C.y) - (B.y - A.y) * (A.x - C.x);
        var f_d:Number = (D.y - C.y) * (B.x - A.x) - (D.x - C.x) * (B.y - A.y);
        var f1:Number = f_ab/f_d
        var f2:Number = f_cd / f_d
        if (f1 == Infinity || f1 <= 0 || f1 >= 1) { return Infinity };
        if (f2 == Infinity || f2 <= 0 || f2 >= 1) { return Infinity };
        return f1;
    }

    public function getIntersectingPoint($A:Point, $B:Point, $C:Point, $D:Point):Point
    {
        var f:Number = getIntersectingPointF($A, $B, $C, $D);
        if (f == Infinity || f <= 0 || f >= 1) { return null };

        var retPoint:Point = Point.interpolate($A, $B, 1 - f);
        return retPoint.clone();
    }
share|improve this answer

for segments AB and CD, find the slope of CD

slope=(Dy-Cy)/(Dx-Cx)

extend CD over A and B, and take the distance to CD going straight up

dist1=slope*(Cx-Ax)+Ay-Cy
dist2=slope*(Dx-Ax)+Ay-Dy

check if they are on opposite sides

return dist1*dist2<0
share|improve this answer

Implemented in JAVA. However It seems that it does not work for co-linear lines (aka line segments that exist within each other L1(0,0)(10,10) L2(1,1)(2,2)

public class TestCode
{

  public class Point
  {
    public double x = 0;
    public double y = 0;
    public Point(){}
  }

  public class Line
  {
    public Point p1, p2;
    public Line( double x1, double y1, double x2, double y2) 
    {
      p1 = new Point();
      p2 = new Point();
      p1.x = x1;
      p1.y = y1;
      p2.x = x2;
      p2.y = y2;
    }
  }

  //line segments
  private static Line s1;
  private static Line s2;

  public TestCode()
  {
    s1 = new Line(0,0,0,10);
    s2 = new Line(-1,0,0,10);
  }

  public TestCode(double x1, double y1, 
    double x2, double y2,
    double x3, double y3,
    double x4, double y4)
  {
    s1 = new Line(x1,y1, x2,y2);
    s2 = new Line(x3,y3, x4,y4);
  }

  public static void main(String args[])
  {
     TestCode code  = null;
////////////////////////////
     code = new TestCode(0,0,0,10,
                         0,1,0,5);
     if( intersect(code) )
     { System.out.println( "OK COLINEAR: INTERSECTS" ); }
     else
     { System.out.println( "ERROR COLINEAR: DO NOT INTERSECT" ); }
////////////////////////////
     code = new TestCode(0,0,0,10,
                         0,1,0,10);
     if( intersect(code) )
     { System.out.println( "OK COLINEAR: INTERSECTS" ); }
     else
     { System.out.println( "ERROR COLINEAR: DO NOT INTERSECT" ); }
////////////////////////////
     code = new TestCode(0,0,10,0,
                         5,0,15,0);
     if( intersect(code) )
     { System.out.println( "OK COLINEAR: INTERSECTS" ); }
     else
     { System.out.println( "ERROR COLINEAR: DO NOT INTERSECT" ); }
////////////////////////////
     code = new TestCode(0,0,10,0,
                         0,0,15,0);
     if( intersect(code) )
     { System.out.println( "OK COLINEAR: INTERSECTS" ); }
     else
     { System.out.println( "ERROR COLINEAR: DO NOT INTERSECT" ); }

////////////////////////////
     code = new TestCode(0,0,10,10,
                         1,1,5,5);
     if( intersect(code) )
     { System.out.println( "OK COLINEAR: INTERSECTS" ); }
     else
     { System.out.println( "ERROR COLINEAR: DO NOT INTERSECT" ); }
////////////////////////////
     code = new TestCode(0,0,0,10,
                         -1,-1,0,10);
     if( intersect(code) )
     { System.out.println( "OK SLOPE END: INTERSECTS" ); }
     else
     { System.out.println( "ERROR SLOPE END: DO NOT INTERSECT" ); }
////////////////////////////
     code = new TestCode(-10,-10,10,10,
                         -10,10,10,-10);
     if( intersect(code) )
     { System.out.println( "OK SLOPE Intersect(0,0): INTERSECTS" ); }
     else
     { System.out.println( "ERROR SLOPE Intersect(0,0): DO NOT INTERSECT" ); }
////////////////////////////
     code = new TestCode(-10,-10,10,10,
                         -3,-2,50,-2);
     if( intersect(code) )
     { System.out.println( "OK SLOPE Line2 VERTIAL: INTERSECTS" ); }
     else
     { System.out.println( "ERROR SLOPE Line2 VERTICAL: DO NOT INTERSECT" ); }
////////////////////////////
     code = new TestCode(-10,-10,10,10,
                         50,-2,-3,-2);
     if( intersect(code) )
     { System.out.println( "OK SLOPE Line2 (reversed) VERTIAL: INTERSECTS" ); }
     else
     { System.out.println( "ERROR SLOPE Line2 (reversed) VERTICAL: DO NOT INTERSECT" ); }
////////////////////////////
     code = new TestCode(0,0,0,10,
                         1,0,1,10);
     if( intersect(code) )
     { System.out.println( "ERROR PARALLEL VERTICAL: INTERSECTS" ); }
     else
     { System.out.println( "OK PARALLEL VERTICAL: DO NOT INTERSECT" ); }
////////////////////////////
     code = new TestCode(0,2,10,2,
                         0,10,10,10);
     if( intersect(code) )
     { System.out.println( "ERROR PARALLEL HORIZONTAL: INTERSECTS" ); }
     else
     { System.out.println( "OK PARALLEL HORIZONTAL: DO NOT INTERSECT" ); }
////////////////////////////
     code = new TestCode(0,10,5,13.75,
                         0,18.75,10,15);
     if( intersect(code) )
     { System.out.println( "ERROR PARALLEL SLOPE=.75: INTERSECTS" ); }
     else
     { System.out.println( "OK PARALLEL SLOPE=.75: DO NOT INTERSECT" ); }
////////////////////////////
     code = new TestCode(0,0,1,1,
                         2,-1,2,10);
     if( intersect(code) )
     { System.out.println( "ERROR SEPERATE SEGMENTS: INTERSECTS" ); }
     else
     { System.out.println( "OK SEPERATE SEGMENTS: DO NOT INTERSECT" ); }
////////////////////////////
     code = new TestCode(0,0,1,1,
                         -1,-10,-5,10);
     if( intersect(code) )
     { System.out.println( "ERROR SEPERATE SEGMENTS 2: INTERSECTS" ); }
     else
     { System.out.println( "OK SEPERATE SEGMENTS 2: DO NOT INTERSECT" ); }
  }

  public static boolean intersect( TestCode code )
  {
    return intersect( code.s1, code.s2);
  }

  public static boolean intersect( Line line1, Line line2 )
  {
    double i1min = Math.min(line1.p1.x, line1.p2.x);
    double i1max = Math.max(line1.p1.x, line1.p2.x);
    double i2min = Math.min(line2.p1.x, line2.p2.x);
    double i2max = Math.max(line2.p1.x, line2.p2.x);

    double iamax = Math.max(i1min, i2min);
    double iamin = Math.min(i1max, i2max);

    if( Math.max(line1.p1.x, line1.p2.x) < Math.min(line2.p1.x, line2.p2.x) )
      return false;

    double m1 = (line1.p2.y - line1.p1.y) / (line1.p2.x - line1.p1.x );
    double m2 = (line2.p2.y - line2.p1.y) / (line2.p2.x - line2.p1.x );

    if( m1 == m2 )
        return false;

    //b1 = line1[0][1] - m1 * line1[0][0]
    //b2 = line2[0][1] - m2 * line2[0][0]
    double b1 = line1.p1.y - m1 * line1.p1.x;
    double b2 = line2.p1.y - m2 * line2.p1.x;
    double x1 = (b2 - b1) / (m1 - m2);
    if( (x1 < Math.max(i1min, i2min)) || (x1 > Math.min(i1max, i2max)) )
        return false;
    return true;
  }
}

Output thus far is

ERROR COLINEAR: DO NOT INTERSECT
ERROR COLINEAR: DO NOT INTERSECT
ERROR COLINEAR: DO NOT INTERSECT
ERROR COLINEAR: DO NOT INTERSECT
ERROR COLINEAR: DO NOT INTERSECT
OK SLOPE END: INTERSECTS
OK SLOPE Intersect(0,0): INTERSECTS
OK SLOPE Line2 VERTIAL: INTERSECTS
OK SLOPE Line2 (reversed) VERTIAL: INTERSECTS
OK PARALLEL VERTICAL: DO NOT INTERSECT
OK PARALLEL HORIZONTAL: DO NOT INTERSECT
OK PARALLEL SLOPE=.75: DO NOT INTERSECT
OK SEPERATE SEGMENTS: DO NOT INTERSECT
OK SEPERATE SEGMENTS 2: DO NOT INTERSECT
share|improve this answer

Here is C code to check if two points are on the opposite sides of the line segment. Using this code you can check if two segments intersect as well.

// true if points p1, p2 lie on the opposite sides of segment s1--s2
bool oppositeSide (Point2f s1, Point2f s2, Point2f p1, Point2f p2) {

//calculate normal to the segment
Point2f vec = s1-s2;
Point2f normal(vec.y, -vec.x); // no need to normalize

// vectors to the points
Point2f v1 = p1-s1;
Point2f v2 = p2-s1;

// compare signs of the projections of v1, v2 onto the normal
float proj1 = v1.dot(normal);
float proj2 = v2.dot(normal);
if (proj1==0 || proj2==0)
        cout<<"collinear points"<<endl;

return(SIGN(proj1) != SIGN(proj2));

}

share|improve this answer

Resolved but still why not with python... :)

def islineintersect(line1, line2):
    i1 = [min(line1[0][0], line1[1][0]), max(line1[0][0], line1[1][0])]
    i2 = [min(line2[0][0], line2[1][0]), max(line2[0][0], line2[1][0])]
    ia = [max(i1[0], i2[0]), min(i1[1], i2[1])]
    if max(line1[0][0], line1[1][0]) < min(line2[0][0], line2[1][0]):
        return False
    m1 = (line1[1][1] - line1[0][1]) * 1. / (line1[1][0] - line1[0][0]) * 1.
    m2 = (line2[1][1] - line2[0][1]) * 1. / (line2[1][0] - line2[0][0]) * 1.
    if m1 == m2:
        return False
    b1 = line1[0][1] - m1 * line1[0][0]
    b2 = line2[0][1] - m2 * line2[0][0]
    x1 = (b2 - b1) / (m1 - m2)
    if (x1 < max(i1[0], i2[0])) or (x1 > min(i1[1], i2[1])):
        return False
    return True

This:

print islineintersect([(15, 20), (100, 200)], [(210, 5), (23, 119)])

Output:

True

And this:

print islineintersect([(15, 20), (100, 200)], [(-1, -5), (-5, -5)])

Output:

False
share|improve this answer
    
Python or not still it doesn't work in all cases –  dmitri Aug 30 '13 at 2:23

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