# Determining if two line segments intersect? [duplicate]

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How do you detect where two line segments intersect?

Can someone provide an algorithm or C code for determining if two line segments intersect?

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## marked as duplicate by Bart Kiers, Greg Hewgill, zengr, Paul R, Eugene Mayevski 'EldoS CorpFeb 12 '11 at 10:44

i am using C language – user420878 Feb 12 '11 at 10:13
On a plane or 3d space? – galymzhan Feb 12 '11 at 10:17
if its an interview question for google .. you should find it on google and maybe that job is not for you :) AND .. google tells me that stackoverflow.com/questions/563198/… it is already answered. – akira Feb 12 '11 at 10:23
No offense but if it's you doing the interview, shouldn't you be the one to write "teh codez"? – Bart Kiers Feb 12 '11 at 10:24
Determining where two lines intersects is not the same question as whether two lines intersect - even if the answer is the same to both questions. – Minthos Dec 11 '12 at 11:13

You could build an equation for two lines, find the point of intersection and then check if it belongs to those segments.

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how to do that in C? can u write down part of the code plz? – user420878 Feb 12 '11 at 10:26

That really depends on how the lines are represented. I'm going to assume that you have them represented in the parametric form

x0(t) = u0 + t v0

x1(t) = u1 + t v1

Here, the x's, u's, and v's are vectors (further denoted in bold) in 2 and t ∈ [0, 1].

These two points intersect if there's some point that's on both of these line segments. Thus if there is some point p so that there's a t where

p = x0(t) = u0 + t v0

and an s such that

p = x1(s) = u1 + s v1

And moreover, both s, t ∈ [0, 1], then the two lines intersect. Otherwise, they do not.

If we combine the two equalities, we get

u0 + t v0 = u1 + s v1

Or, equivalently,

u0 - u1 = s v1 - t v0

u0 = (x00, y00)

u1 = (x10, y10)

v0 = (x01, y01)

v1 = (x11, y11)

If we rewrite the above expression in matrix form, we now have that

``````| x00 - x10 |   | x11 |      | x01 |
| y00 - y10 | = | y11 | s -  | y01 | t
``````

This is in turn equivalent to the matrix expression

``````| x00 - x10 |   | x11  x01 | | s|
| y00 - y10 | = | y11  y01 | |-t|
``````

Now, we have two cases to consider. First, if this left-hand side is the zero vector, then there's a trivial solution - just set s = t = 0 and the points intersect. Otherwise, there's a unique solution only if the right-hand matrix is invertible. If we let

``````        | x11  x01 |
d = det(| y11  y01 |) = x11 y01 - x01 y11
``````

Then the inverse of the matrix

``````| x11  x01 |
| y11  y01 |
``````

is given by

``````      |  y01   -x01 |
(1/d) | -y11    x11 |
``````

Note that this matrix isn't defined if the determinant is zero, but if that's true it means that the lines are parallel and thus don't intersect.

If the matrix is invertible, then we can solve the above linear system by left-multiplying by this matrix:

`````` | s|         |  y01   -x01 | | x00 - x10 |
|-t| = (1/d) | -y11    x11 | | y00 - y10 |

|  (x00 - x10) y01 - (y00 - y10) x01 |
= (1/d) | -(x00 - x10) y11 + (y00 - y10) x11 |
``````

So this means that

``````s = (1/d)  ((x00 - x10) y01 - (y00 - y10) x01)
t = (1/d) -(-(x00 - x10) y11 + (y00 - y10) x11)
``````

If both of these values are in the range [0, 1], then the two line segments intersect and you can compute the intersection point. Otherwise, they do not intersect. Additionally, if d is zero then the two lines are parallel, which may or may not be of interest to you. Coding this up in C shouldn't be too bad; you just need to make sure to be careful not to divide by zero.

Hope this helps! If anyone can double-check the math, that would be great.

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Very good answer, shame you probably won't get much recognition for it. – Skurmedel Feb 12 '11 at 20:33
Pretty sure StackOverflow is here to communicate answers to readers, not to show off how cleverly you can obscure the information. -1. – Ed Plunkett Feb 1 '15 at 17:28
@EdPlunkett I'm sorry this answer wasn't useful. I was actually hoping to make the answer as clear as possible by showing off the derivation of the solution, which is the way I tend to learn best. I guess we just have different styles. – templatetypedef Feb 1 '15 at 17:50
@templatetypedef I have the same learning style as you and I can see that at this stage 54 people share my opinion. Let me be the 55th to confirm the same. – nonsensickle Sep 30 '15 at 0:42
you don't appear to have covered the case where the two line segments are parallel and on top of each other. – Dave Moten Nov 11 '15 at 22:07