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I've tried searching for a javascript function that will detect if two lines intersect each other.

The function will take the x,y values of both the start end points for each line (we'll call them line A and line B).

Is to return true if they intersect, otherwise false.

Example of the function. I'm happy if the answer uses a vector object instead.

Function isIntersect (lineAp1x, lineAp1y, lineAp2x, lineAp2y, lineBp1x, lineBp1y, lineBp2x, lineBp2y) 

    // JavaScript line intersecting test here. 


Some background info: this code is for a game I'm trying to make in html5 canvas, and is part of my collision detection.

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possible duplicate of stackoverflow.com/questions/563198/… – Gagandeep Singh Jan 28 '12 at 8:09
This question appears to be off-topic because it is about school math – Nakilon Jun 24 '14 at 16:57
@Nakilon Yes... or collision detection algorithm for game development. – Jarrod Jun 24 '14 at 21:36
@Nakilon - since when does high school math cover normalisation of equations to reduce computational overhead? Jarrod may not have explicitly asked for this, but it is implicit in the use-case he presents. (My answer is directly equivalent to the accepted one, it is simply better optimised.) – Peter Wone Jul 3 '14 at 8:52
up vote 19 down vote accepted
function lineIntersect(x1,y1,x2,y2, x3,y3,x4,y4) {
    var x=((x1*y2-y1*x2)*(x3-x4)-(x1-x2)*(x3*y4-y3*x4))/((x1-x2)*(y3-y4)-(y1-y2)*(x3-x4));
    var y=((x1*y2-y1*x2)*(y3-y4)-(y1-y2)*(x3*y4-y3*x4))/((x1-x2)*(y3-y4)-(y1-y2)*(x3-x4));
    if (isNaN(x)||isNaN(y)) {
        return false;
    } else {
        if (x1>=x2) {
            if (!(x2<=x&&x<=x1)) {return false;}
        } else {
            if (!(x1<=x&&x<=x2)) {return false;}
        if (y1>=y2) {
            if (!(y2<=y&&y<=y1)) {return false;}
        } else {
            if (!(y1<=y&&y<=y2)) {return false;}
        if (x3>=x4) {
            if (!(x4<=x&&x<=x3)) {return false;}
        } else {
            if (!(x3<=x&&x<=x4)) {return false;}
        if (y3>=y4) {
            if (!(y4<=y&&y<=y3)) {return false;}
        } else {
            if (!(y3<=y&&y<=y4)) {return false;}
    return true;

The wiki page I found the answer from.

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Caution: This function fails to recognize an intersection where one indeed exists for the following arguments: "67.1999999998311, 80.0499999999588, 5.351339640030417, 1102.1804922619292, 55.24999999990314, 141.54999999989604, 71.24999999990314, 141.54999999989604" ... Here's a function which seems to be more reliable: gist.github.com/Joncom/e8e8d18ebe7fe55c3894 – Joncom Aug 24 '14 at 12:21
This worked for me, but I had to add/subtract a tiny epsilon to deal with floating point inaccuracy for horizontal/vertical lines where e.g. x1===x2. (I needed the coordinates so I couldn't use the @Joncom version.) gist.github.com/gordonwoodhull/50eb65d2f048789f9558 – Gordon Oct 9 '15 at 20:12

Although it is useful to be able to find the intersection point, testing for whether line segments intersect is most often used for polygon hit-testing, and given the usual applications of that, you need to do it fast. Therefore I suggest you do it like this, using only subtraction, multiplication, comparison and AND. Turn computes the direction of the change in slope between the two edges described by the three points: 1 means counter-clockwise, 0 means no turn and -1 means clockwise.

This code expects points expressed as GLatLng objects but can be trivially rewritten to other systems of representation. The slope comparison has been normalised to epsilon tolerance to damp floating point errors.

function Turn(p1, p2, p3) {
  a = p1.lng(); b = p1.lat(); 
  c = p2.lng(); d = p2.lat();
  e = p3.lng(); f = p3.lat();
  A = (f - b) * (c - a);
  B = (d - b) * (e - a);
  return (A > B + Number.EPSILON) ? 1 : (A + Number.EPSILON < B) ? -1 : 0;

function isIntersect(p1, p2, p3, p4) {
  return (Turn(p1, p3, p4) != Turn(p2, p3, p4)) && (Turn(p1, p2, p3) != Turn(p1, p2, p4));
share|improve this answer
This seems to work great but I don't really follow why it works. A link with some explanation would be appreciated. – urraka Oct 21 '13 at 23:39
Every graphics text and every undergraduate degree graphics subject since the dawn of time has explained this method in mind numbing detail. If you really want to understand it then I suggest you get some graph paper, make up some test cases, label the points p1, p2, p3, p4, and step through the computation. What does it mean when p1 -> p3 -> p4 turns a different way to p2 -> p3 -> p4 and p1 -> p2 -> p3 turns a different way to p1 -> p2 -> p4? Fairly obviously this can only be true when they intersect! – Peter Wone Oct 25 '13 at 14:27
I'm not sure what will happen when the segments are co-linear. Perhaps you can check and enlighten me. – Peter Wone Oct 25 '13 at 14:31
Thanks, it's indeed easy to see it after drawing some lines. If my math is right this wouldn't handle co-linear cases, since the CCW test is basically testing the cross product AxB > 0. Given that AxB will be 0 for the co-linear case it will return false every time. I tested with some simple co-linear cases and verified isIntersect returns false, although this would be up to the float precision for non-simple cases i guess. – urraka Nov 10 '13 at 21:22
@QuolonelQuestions - because (a) I didn't feel like it, (b) cut and paste from working code does not introduce translation errors, (c) the Google Maps API is hardly obscure, and (d) anyone too thick to mentally translate will not understand the answer anyway. – Peter Wone Jan 1 '15 at 14:45

Peter Wone's answer is a great solution, but it lacks an explanation. I spent the last hour or so understanding how it works and think I understand enough to explain it as well. See his answer for details: http://stackoverflow.com/a/16725715/697477

I've also included a solution for the co-linear lines in the code below.

Using Rotational Directions to check for intersection

To explain the answer, let's look at something common about every intersection of two lines. Given the picture below, we can see that P1 to IP to P4 rotates counter clockwise. We can see that it's complimentary sides rotate clockwise. Now, we don't know if it intersects, so we don't know the intersection point. But we can also see that P1 to P2 to P4 also rotates counter clockwise. Additionally, P1 to P2 to P3 rotates clock wise. We can use this knowledge to determine whether two lines intersect or not.

Stretching the face

Intersection Example

Line intersection Line Intersection

You'll notice that intersecting lines create four faces that point opposite directions. Since they face opposite directions, we know that the direction of P1 to P2 to P3 rotates a direction different than P1 to P2 to P4. We also know that P1 to P3 to P4 rotates a different direction than P2 to P3 to P4.

Non-Intersection Example

Line No Intersection Line No Intersection

In this example, you should notice that following the same pattern for the intersection test, the two faces rotate the same direction. Since they face the same direction, we know that they do not intersect.

Code Sample

So, we can implement this into the original code supplied by Peter Wone.

// Check the direction these three points rotate
function RotationDirection(p1x, p1y, p2x, p2y, p3x, p3y) {
  if (((p3y - p1y) * (p2x - p1x)) > ((p2y - p1y) * (p3x - p1x)))
    return 1;
  else if (((p3y - p1y) * (p2x - p1x)) == ((p2y - p1y) * (p3x - p1x)))
    return 0;
  return -1;

function checkIntersection() {
  // Grab the values
  var x1 = parseInt($('#p1x').val());
  var y1 = parseInt($('#p1y').val());
  var x2 = parseInt($('#p2x').val());
  var y2 = parseInt($('#p2y').val());
  var x3 = parseInt($('#p3x').val());
  var y3 = parseInt($('#p3y').val());
  var x4 = parseInt($('#p4x').val());
  var y4 = parseInt($('#p4y').val());

  // Determine the direction they rotate. (You can combine this all into one step.)
  var face1CounterClockwise = RotationDirection(x1, y1, x2, y2, x4, y4);
  var face2CounterClockwise = RotationDirection(x1, y1, x2, y2, x3, y3);
  var face3CounterClockwise = RotationDirection(x1, y1, x3, y3, x4, y4);
  var face4CounterClockwise = RotationDirection(x2, y2, x3, y3, x4, y4);

  // If face 1 and face 2 rotate different directions and face 3 and face 4 rotate different directions, 
  // then the lines intersect.
  var intersect = face1CounterClockwise != face2CounterClockwise && face3CounterClockwise != face4CounterClockwise;
  // If lines are on top of each other.
  if (face1CounterClockwise == 0 && face2CounterClockwise == 0 && face3CounterClockwise == 0 && face4CounterClockwise == 0)
    intersect = true;

  // Output the results.
  var output = "Face 1 (P1, P2, P4) Rotates: " + ((face1CounterClockwise > 0) ? "counterClockWise" : ((face1CounterClockwise == 0) ? "Linear" : "clockwise")) + "<br />";
  var output = output + "Face 2 (P1, P2, P3) Rotates: " + ((face2CounterClockwise > 0) ? "counterClockWise" : ((face2CounterClockwise == 0) ? "Linear" : "clockwise")) + "<br />";
  var output = output + "Face 3 (P1, P3, P4) Rotates: " + ((face3CounterClockwise > 0) ? "counterClockWise" : ((face3CounterClockwise == 0) ? "Linear" : "clockwise")) + "<br />";
  var output = output + "Face 4 (P2, P3, P4) Rotates: " + ((face4CounterClockwise > 0) ? "counterClockWise" : ((face4CounterClockwise == 0) ? "Linear" : "clockwise")) + "<br />";
  var output = output + "Intersection: " + ((intersect) ? "Yes" : "No") + "<br />";

  // Draw the lines.
  var canvas = $("#canvas");
  var context = canvas.get(0).getContext('2d');
  context.clearRect(0, 0, canvas.get(0).width, canvas.get(0).height);
  context.moveTo(x1, y1);
  context.lineTo(x2, y2);
  context.moveTo(x3, y3);
  context.lineTo(x4, y4);

<script src="https://ajax.googleapis.com/ajax/libs/jquery/2.1.1/jquery.min.js"></script>

<canvas id="canvas" width="200" height="200" style="border: 2px solid #000000; float: right;"></canvas>
<div style="float: left;">
  <div style="float: left;">
    <b>Line 1:</b>
    <br />P1 x:
    <input type="number" min="0" max="200" id="p1x" style="width: 40px;" onChange="checkIntersection();" value="0">y:
    <input type="number" min="0" max="200" id="p1y" style="width: 40px;" onChange="checkIntersection();" value="20">
    <br />P2 x:
    <input type="number" min="0" max="200" id="p2x" style="width: 40px;" onChange="checkIntersection();" value="100">y:
    <input type="number" min="0" max="200" id="p2y" style="width: 40px;" onChange="checkIntersection();" value="20">
    <br />
  <div style="float: left;">
    <b>Line 2:</b>
    <br />P3 x:
    <input type="number" min="0" max="200" id="p3x" style="width: 40px;" onChange="checkIntersection();" value="150">y:
    <input type="number" min="0" max="200" id="p3y" style="width: 40px;" onChange="checkIntersection();" value="100">
    <br />P4 x:
    <input type="number" min="0" max="200" id="p4x" style="width: 40px;" onChange="checkIntersection();" value="0">y:
    <input type="number" min="0" max="200" id="p4y" style="width: 40px;" onChange="checkIntersection();" value="0">
    <br />
  <br style="clear: both;" />
  <br />
  <div style="float: left; border: 1px solid #EEEEEE; padding: 2px;" id="result"></div>

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does this method work with the float numbers? – msc87 Jan 25 at 12:37
@msc87 I don't see any reason it wouldn't. Easiest way to find out is to try it. Take the above code sample and plug decimal values into it. – Tom Jan 25 at 15:55
Well, actually I tried it but I am not sure if it's my code or the method. I snap to a point on a line and then use turf.js to find intersections. It sometimes finds the intersection and sometimes can't. Seems the problem to be with the float numbers as I see your code here can easily detect even the lines that touch each other. – msc87 Jan 25 at 19:07
In other words, my lines may not intersect as the float numbers' precision may vary time to time. – msc87 Jan 25 at 19:09
@msc87 - the classic solution is epsilon comparison. Instead of a==b use Math.abs(a-b) < epsilon. For explanation and a suggested epsilon value read this msdn.microsoft.com/en-us/library/… – Peter Wone Jul 20 at 6:02
// returns true iff the line from (a,b)->(c,d) intersects with (p,q)->(r,s)
function intersects(a,b,c,d,p,q,r,s) {
  var det, gamma, lambda;
  det = (c - a) * (s - q) - (r - p) * (d - b);
  if (det === 0) {
    return false;
  } else {
    lambda = ((s - q) * (r - a) + (p - r) * (s - b)) / det;
    gamma = ((b - d) * (r - a) + (c - a) * (s - b)) / det;
    return (0 < lambda && lambda < 1) && (0 < gamma && gamma < 1);

Explanation: (vectors, a matrix and a cheeky determinant)

Lines can be described by some initial vector, v, and a direction vector, d:

r = v + lambda*d 

We use one point (a,b) as the initial vector and the difference between them (c-a,d-b) as the direction vector. Likewise for our second line.

If our two lines intersect, then there must be a point, X, that is reachable by travelling some distance, lambda, along our first line and also reachable by travelling gamma units along our second line. This gives us two simultaneous equations for the coordinates of X:

X = v1 + lambda*d1 
X = v2 + gamma *d2

These equations can be represented in matrix form. We check that the determinant is non-zero to see if the intersection X even exists.

If there is an intersection, then we must check that the intersection actually lies between both sets of points. If lambda is greater than 1, the intersection is beyond the second point. If lambda is less than 0, the intersection is before the first point.

Hence, 0<lambda<1 && 0<gamma<1 indicates that the two lines intersect!

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Beautiful solution! – sergeyz Dec 27 '14 at 0:27
Be carefull: if the determinant is zero, it means that the two lines are parallel. Either they are equal (and all points are "intersection points") or "strictly" parallel (and no intersection). – oliverpool May 11 '15 at 6:51

First, find intersection coordinates - here it's described in detail: http://www.mathopenref.com/coordintersection.html

Then check if the x-coordinate for intersection falls within the x ranges for one of the lines (or do the same with y-coordinate, if you prefer), i.e. if xIntersection is between lineAp1x and lineAp2x, then they intersect.

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I've rewritten Peter Wone's answer to a single function using x/y instead of lat()/long()

function isIntersecting(p1, p2, p3, p4) {
    function CCW(p1, p2, p3) {
        return (p3.y - p1.y) * (p2.x - p1.x) > (p2.y - p1.y) * (p3.x - p1.x);
    return (CCW(p1, p3, p4) != CCW(p2, p3, p4)) && (CCW(p1, p2, p3) != CCW(p1, p2, p4));

You can put the CCW function outside the isIntersecting function to increase performance.

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Here's a version based on this gist with some more concise variable names, and some Coffee.

JavaScript version

var lineSegmentsIntersect = (x1, y1, x2, y2, x3, y3, x4, y4)=> {
    var a_dx = x2 - x1;
    var a_dy = y2 - y1;
    var b_dx = x4 - x3;
    var b_dy = y4 - y3;
    var s = (-a_dy * (x1 - x3) + a_dx * (y1 - y3)) / (-b_dx * a_dy + a_dx * b_dy);
    var t = (+b_dx * (y1 - y3) - b_dy * (x1 - x3)) / (-b_dx * a_dy + a_dx * b_dy);
    return (s >= 0 && s <= 1 && t >= 0 && t <= 1);

CoffeeScript version

lineSegmentsIntersect = (x1, y1, x2, y2, x3, y3, x4, y4)->
    a_dx = x2 - x1
    a_dy = y2 - y1
    b_dx = x4 - x3
    b_dy = y4 - y3
    s = (-a_dy * (x1 - x3) + a_dx * (y1 - y3)) / (-b_dx * a_dy + a_dx * b_dy)
    t = (+b_dx * (y1 - y3) - b_dy * (x1 - x3)) / (-b_dx * a_dy + a_dx * b_dy)
    (0 <= s <= 1 and 0 <= t <= 1)
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