I have a set of points. I want to separate them into 2 distinct sets. To do this, I choose two points (a and b) and draw an imaginary line between them. Now I want to have all points that are left from this line in one set and those that are right from this line in the other set.

How can I tell for any given point z whether it is in the left or in the right set? I tried to calculate the angle between a-z-b – angles smaller than 180 are on the right hand side, greater than 180 on the left hand side – but because of the definition of ArcCos, the calculated angles are always smaller than 180°. Is there a formula to calculate angles greater than 180° (or any other formula to chose right or left side)?

  • How is right or left defined? A) in terms of looking from P1 to P2 or B) left or right of the line in the plane. – phkahler Aug 11 '10 at 18:58
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    To clarify, to the second part of your question, you can use atan2() instead of acos() to calculate the correct angle. However, using a cross product is the best solution to this as Eric Bainville pointed out. – dionyziz Sep 4 '11 at 12:20
  • Many of the solutions below don't work because they give opposite answers if you interchange points a and b (the points that we are using to define our line). I give a solution in Clojure that sorts the two points lexicographically first before comparing them to the third point. – Purplejacket Feb 23 '15 at 0:28

13 Answers 13


Use the sign of the determinant of vectors (AB,AM), where M(X,Y) is the query point:

position = sign((Bx - Ax) * (Y - Ay) - (By - Ay) * (X - Ax))

It is 0 on the line, and +1 on one side, -1 on the other side.

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    +1 nice, with one thing to be aware of: rounding error can be a concern when the point is very nearly on the line. Not a problem for most uses, but it does bite people from time to time. – Stephen Canon Oct 13 '09 at 14:18
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    Should you find yourself in a situation where rounding error on this test is causing you problems, you will want to look up Jon Shewchuk's "Fast Robust Predicates for Computational Geometry". – Stephen Canon Oct 13 '09 at 15:13
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    For clarification, this is the same as the Z-component of the cross product between the the line (b-a) and the vector to the point from a (m-a). In your favorite vector-class: position = sign((b-a).cross(m-a)[2]) – larsmoa Feb 9 '10 at 22:52
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    wouldn’t swapping A & B keep the same line, but change the sign of positions? – Jayen Jun 10 '14 at 9:07
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    Yes. A,B defines the orientation, as in "to your left when standing at A and looking at B". – Eric Bainville Jun 10 '14 at 22:27

Try this code which makes use of a cross product:

public bool isLeft(Point a, Point b, Point c){
     return ((b.X - a.X)*(c.Y - a.Y) - (b.Y - a.Y)*(c.X - a.X)) > 0;

Where a = line point 1; b = line point 2; c = point to check against.

If the formula is equal to 0, the points are colinear.

If the line is horizontal, then this returns true if the point is above the line.

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    If line is vertical then? – Tofeeq Feb 29 '12 at 10:31
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    do you mean dot product? – Baiyan Huang May 16 '12 at 23:01
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    @lzprgmr: No, this is a cross product, equivalently the determinant of a 2D matrix. Consider the 2D matrix defined by rows (a,b) and (c,d). The determinant is ad - bc. The form above is transforming a line represented by 2 points into a one vector, (a,b), and then defining another vector using PointA and PointC to get (c, d): (a,b) = (PointB.x - PointA.x, PointB.y - PointA.y) (c,d) = (PointC.x - PointA.x, PointC.y - PointA.y) The determinant is therefore just as its stated in the post. – AndyG Jun 5 '13 at 18:59
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    I think the confusion over whether this is a cross product or dot product is because it is in two dimensions. It is the cross product, in two dimensions: mathworld.wolfram.com/CrossProduct.html – brianmearns Sep 4 '13 at 0:53
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    For what it's worth, this can be slightly simplified to return (b.x - a.x)*(c.y - a.y) > (b.y - a.y)*(c.x - a.x);, but the compiler probably optimizes that anyway. – Nicu Stiurca Oct 7 '13 at 20:16

You look at the sign of the determinant of

| x2-x1  x3-x1 |
| y2-y1  y3-y1 |

It will be positive for points on one side, and negative on the other (and zero for points on the line itself).


The vector (y1 - y2, x2 - x1) is perpendicular to the line, and always pointing right (or always pointing left, if you plane orientation is different from mine).

You can then compute the dot product of that vector and (x3 - x1, y3 - y1) to determine if the point lies on the same side of the line as the perpendicular vector (dot product > 0) or not.


I implemented this in java and ran a unit test (source below). None of the above solutions work. This code passes the unit test. If anyone finds a unit test that does not pass, please let me know.

Code: NOTE: nearlyEqual(double,double) returns true if the two numbers are very close.

 * @return integer code for which side of the line ab c is on.  1 means
 * left turn, -1 means right turn.  Returns
 * 0 if all three are on a line
public static int findSide(
        double ax, double ay, 
        double bx, double by,
        double cx, double cy) {
    if (nearlyEqual(bx-ax,0)) { // vertical line
        if (cx < bx) {
            return by > ay ? 1 : -1;
        if (cx > bx) {
            return by > ay ? -1 : 1;
        return 0;
    if (nearlyEqual(by-ay,0)) { // horizontal line
        if (cy < by) {
            return bx > ax ? -1 : 1;
        if (cy > by) {
            return bx > ax ? 1 : -1;
        return 0;
    double slope = (by - ay) / (bx - ax);
    double yIntercept = ay - ax * slope;
    double cSolution = (slope*cx) + yIntercept;
    if (slope != 0) {
        if (cy > cSolution) {
            return bx > ax ? 1 : -1;
        if (cy < cSolution) {
            return bx > ax ? -1 : 1;
        return 0;
    return 0;

Here's the unit test:

@Test public void testFindSide() {
    assertTrue("1", 1 == Utility.findSide(1, 0, 0, 0, -1, -1));
    assertTrue("1.1", 1 == Utility.findSide(25, 0, 0, 0, -1, -14));
    assertTrue("1.2", 1 == Utility.findSide(25, 20, 0, 20, -1, 6));
    assertTrue("1.3", 1 == Utility.findSide(24, 20, -1, 20, -2, 6));

    assertTrue("-1", -1 == Utility.findSide(1, 0, 0, 0, 1, 1));
    assertTrue("-1.1", -1 == Utility.findSide(12, 0, 0, 0, 2, 1));
    assertTrue("-1.2", -1 == Utility.findSide(-25, 0, 0, 0, -1, -14));
    assertTrue("-1.3", -1 == Utility.findSide(1, 0.5, 0, 0, 1, 1));

    assertTrue("2.1", -1 == Utility.findSide(0,5, 1,10, 10,20));
    assertTrue("2.2", 1 == Utility.findSide(0,9.1, 1,10, 10,20));
    assertTrue("2.3", -1 == Utility.findSide(0,5, 1,10, 20,10));
    assertTrue("2.4", -1 == Utility.findSide(0,9.1, 1,10, 20,10));

    assertTrue("vertical 1", 1 == Utility.findSide(1,1, 1,10, 0,0));
    assertTrue("vertical 2", -1 == Utility.findSide(1,10, 1,1, 0,0));
    assertTrue("vertical 3", -1 == Utility.findSide(1,1, 1,10, 5,0));
    assertTrue("vertical 3", 1 == Utility.findSide(1,10, 1,1, 5,0));

    assertTrue("horizontal 1", 1 == Utility.findSide(1,-1, 10,-1, 0,0));
    assertTrue("horizontal 2", -1 == Utility.findSide(10,-1, 1,-1, 0,0));
    assertTrue("horizontal 3", -1 == Utility.findSide(1,-1, 10,-1, 0,-9));
    assertTrue("horizontal 4", 1 == Utility.findSide(10,-1, 1,-1, 0,-9));

    assertTrue("positive slope 1", 1 == Utility.findSide(0,0, 10,10, 1,2));
    assertTrue("positive slope 2", -1 == Utility.findSide(10,10, 0,0, 1,2));
    assertTrue("positive slope 3", -1 == Utility.findSide(0,0, 10,10, 1,0));
    assertTrue("positive slope 4", 1 == Utility.findSide(10,10, 0,0, 1,0));

    assertTrue("negative slope 1", -1 == Utility.findSide(0,0, -10,10, 1,2));
    assertTrue("negative slope 2", -1 == Utility.findSide(0,0, -10,10, 1,2));
    assertTrue("negative slope 3", 1 == Utility.findSide(0,0, -10,10, -1,-2));
    assertTrue("negative slope 4", -1 == Utility.findSide(-10,10, 0,0, -1,-2));

    assertTrue("0", 0 == Utility.findSide(1, 0, 0, 0, -1, 0));
    assertTrue("1", 0 == Utility.findSide(0,0, 0, 0, 0, 0));
    assertTrue("2", 0 == Utility.findSide(0,0, 0,1, 0,2));
    assertTrue("3", 0 == Utility.findSide(0,0, 2,0, 1,0));
    assertTrue("4", 0 == Utility.findSide(1, -2, 0, 0, -1, 2));
  • what was your unit of measure for nearlyEquals? – spy Jan 4 '16 at 3:35
  • i can't find the code for nearlyEqual :( – Renjith Aug 13 '16 at 20:14

Using the equation of the line ab, get the x-coordinate on the line at the same y-coordinate as the point to be sorted.

  • If point's x > line's x, the point is to the right of the line.
  • If point's x < line's x, the point is to the left of the line.
  • If point's x == line's x, the point is on the line.
  • This is wrong, because as you can see from Aaginor's comment on the first answer, we don't want to figure out whether the point is on the left or right of the DIRECTED line AB, i.e. if you're standing on A and looking towards B is it on your left or on your right? – dionyziz Sep 4 '11 at 12:18
  • @dionyziz - Huh? My answer does not assign a "direction" to the line through AB. My answer assumes "left" is the -x direction of the corrdinate system. The accepted answer chose to define a vector AB, and define left using cross product. The original question does not specify what is meant by "left". – mbeckish Sep 6 '11 at 19:29
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    NOTE: If you use this approach (rather than the cross-product one that was approved as answer), be aware of a pitfall as the line approaches horizontal. Math errors increase, and hits infinity if exactly horizontal. The solution is to use whichever axis has the greater delta between the two points. (Or maybe smaller delta .. this is off the top of my head.) – ToolmakerSteve Jul 10 '13 at 5:20
  • this is totally what i was looking for. i don't want to know if A is above or below B. i just want to know if it's left (negative x direction) of the line! – Jayen Jun 10 '14 at 9:22

First check if you have a vertical line:

if (x2-x1) == 0
  if x3 < x2
     it's on the left
  if x3 > x2
     it's on the right
     it's on the line

Then, calculate the slope: m = (y2-y1)/(x2-x1)

Then, create an equation of the line using point slope form: y - y1 = m*(x-x1) + y1. For the sake of my explanation, simplify it to slope-intercept form (not necessary in your algorithm): y = mx+b.

Now plug in (x3, y3) for x and y. Here is some pseudocode detailing what should happen:

if m > 0
  if y3 > m*x3 + b
    it's on the left
  else if y3 < m*x3 + b
    it's on the right
    it's on the line
else if m < 0
  if y3 < m*x3 + b
    it's on the left
  if y3 > m*x3+b
    it's on the right
    it's on the line
  horizontal line; up to you what you do
  • 3
    Fail: Slope calculation invalid for vertical lines. Endless if/else stuff. Not sure if that's what the OP meant by left/right - if so looking at it rotated 90 degrees would cut this code in half since "above" would be right or left. – phkahler Aug 11 '10 at 18:57
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    This answer has several problems. Vertical lines cause a divide by zero. Worse, it fails because it does not worry about whether the slope of the line is positive or negative. – user85109 Aug 12 '10 at 3:36
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    @phkahler, fixed the vertical line issue. Definitely not a failure for forgetting one test case but thanks for the kind words. "Endless if/else" is to explain the mathematical theory; nothing in OP's question mentions programming. @woodchips, fixed the vertical line issue. The slope is the variable m; I do check when it is positive or negative. – maksim Aug 12 '10 at 22:46

basically, I think that there is a solution which is much easier and straight forward, for any given polygon, lets say consist of four vertices(p1,p2,p3,p4), find the two extreme opposite vertices in the polygon, in another words, find the for example the most top left vertex (lets say p1) and the opposite vertex which is located at most bottom right (lets say ). Hence, given your testing point C(x,y), now you have to make double check between C and p1 and C and p4:

if cx > p1x AND cy > p1y ==> means that C is lower and to right of p1 next if cx < p2x AND cy < p2y ==> means that C is upper and to left of p4

conclusion, C is inside the rectangle.

Thanks :)

  • (1) Answers a different question than was asked? Sounds like "bounding box" test, when a rectangle is aligned with both axes. (2) In more detail: makes assumption about the possible relationships between 4 points. For example, take a rectangle, and rotate it 45 degrees, so that you have a diamond. There is no such thing as a "top-left point" in that diamond. The leftmost point is neither topmost or bottom most. And of course, 4 points can form even stranger shapes. For example, 3 points could be far off in one direction, and the 4th point in another direction. Keep trying! – ToolmakerSteve Jul 10 '13 at 5:28

Assuming the points are (Ax,Ay) (Bx,By) and (Cx,Cy), you need to compute:

(Bx - Ax) * (Cy - Ay) - (By - Ay) * (Cx - Ax)

This will equal zero if the point C is on the line formed by points A and B, and will have a different sign depending on the side. Which side this is depends on the orientation of your (x,y) coordinates, but you can plug test values for A,B and C into this formula to determine whether negative values are to the left or to the right.

  • 2
    That's basically a copy of the accepted answer? – bummzack Mar 19 '13 at 13:53
  • Thank you VERY much for your respose...this was very helpfull..keep on the great work :) - 1 vote from me :D – MSA Jun 25 '13 at 8:10

@AVB's answer in ruby

det = Matrix[
  [(x2 - x1), (x3 - x1)],
  [(y2 - y1), (y3 - y1)]

If det is positive its above, if negative its below. If 0, its on the line.


Here's a version, again using the cross product logic, written in Clojure.

(defn is-left? [line point]
  (let [[[x1 y1] [x2 y2]] (sort line)
        [x-pt y-pt] point]
    (> (* (- x2 x1) (- y-pt y1)) (* (- y2 y1) (- x-pt x1)))))

Example usage:

(is-left? [[-3 -1] [3 1]] [0 10])

Which is to say that the point (0, 10) is to the left of the line determined by (-3, -1) and (3, 1).

NOTE: This implementation solves a problem that none of the others (so far) does! Order matters when giving the points that determine the line. I.e., it's a "directed line", in a certain sense. So with the above code, this invocation also produces the result of true:

(is-left? [[3 1] [-3 -1]] [0 10])

That's because of this snippet of code:

(sort line)

Finally, as with the other cross product based solutions, this solution returns a boolean, and does not give a third result for collinearity. But it will give a result that makes sense, e.g.:

(is-left? [[1 1] [3 1]] [10 1])

I wanted to provide with a solution inspired by physics.

Imagine a force applied along the line and you are measuring the torque of the force about the point. If the torque is positive (counterclockwise) then the point is to the "left" of the line, but if the torque is negative the point is the "right" of the line.

So if the force vector equals the span of the two points defining the line

fx = x_2 - x_1
fy = y_2 - y_1

you test for the side of a point (px,py) based on the sign of the following test

var torque = fx*(py-y_1)-fy*(px-x_1)
if  torque>0  then
     "point on left side"
else if torque <0 then
     "point on right side"  
     "point on line"
end if

An alternative way of getting a feel of solutions provided by netters is to understand a little geometry implications.

Let pqr=[P,Q,R] are points that forms a plane that is divided into 2 sides by line [P,R]. We are to find out if two points on pqr plane, A,B, are on the same side.

Any point T on pqr plane can be represented with 2 vectors: v = P-Q and u = R-Q, as:

T' = T-Q = i * v + j * u

Now the geometry implications:

  1. i+j =1: T on pr line
  2. i+j <1: T on Sq
  3. i+j >1: T on Snq
  4. i+j =0: T = Q
  5. i+j <0: T on Sq and beyond Q.

i+j: <0 0 <1 =1 >1 ---------Q------[PR]--------- <== this is PQR plane ^ pr line

In general,

  • i+j is a measure of how far T is away from Q or line [P,R], and
  • the sign of i+j-1 implicates T's sideness.

The other geometry significances of i and j (not related to this solution) are:

  • i,j are the scalars for T in a new coordinate system where v,u are the new axes and Q is the new origin;
  • i, j can be seen as pulling force for P,R, respectively. The larger i, the farther T is away from R (larger pull from P).

The value of i,j can be obtained by solving the equations:

i*vx + j*ux = T'x
i*vy + j*uy = T'y
i*vz + j*uz = T'z

So we are given 2 points, A,B on the plane:

A = a1 * v + a2 * u B = b1 * v + b2 * u

If A,B are on the same side, this will be true:

sign(a1+a2-1) = sign(b1+b2-1)

Note that this applies also to the question: Are A,B in the same side of plane [P,Q,R], in which:

T = i * P + j * Q + k * R

and i+j+k=1 implies that T is on the plane [P,Q,R] and the sign of i+j+k-1 implies its sideness. From this we have:

A = a1 * P + a2 * Q + a3 * R B = b1 * P + b2 * Q + b3 * R

and A,B are on the same side of plane [P,Q,R] if

sign(a1+a2+a3-1) = sign(b1+b2+b3-1)

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