# Determine which side of a line a point lies

I've got a line through points (x1,y1) and (x2, y2). I'd like to see if point (x3, y3) lies to the "left" or "right" of said line. How would I do so?

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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
possible duplicate of How to tell wether a point is right or left of a line –  starblue Aug 12 '10 at 8:02

Try this code it make use of 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 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? –  Sameer Feb 29 '12 at 10:31
do you mean dot product? –  lzprgmr May 16 '12 at 23:01
@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 at 18:59
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 –  sh1ftst0rm Sep 4 at 0:53
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. –  SchighSchagh Oct 7 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).

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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.

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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
else
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
else
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
else
it's on the line
else
horizontal line; up to you what you do
``````
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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
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
@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

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));
}
``````
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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.

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

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

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

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Say if your line is defined as `f(x) = ax + b` and you want to test it against the point (x1,y1) you can make something like this in pseudo-code:

``````int test(int x, int y)
return f(x) - y
end
``````

Negative values are points below the line, positive are above and 0 means the point belongs to the line.

Hope to have helped

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That's not how his line is defined. It's also a poor choice for representing lines since it brakes down for vertical lines. –  phkahler Aug 11 '10 at 18:52
Yeah I'm guilty of having assumed too much :) thanks for the correction –  lfzawacki Aug 12 '10 at 4:01