# How to tell whether a point is to the right or left of a line

I have a set of points. I want to separate them into 2 distinct sets. To do this, I chose 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.

My question is: How can I tell for any given point z wheter 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 angels are always smaller than 180°. Is there a formula to calculate angels greater than 180° (or any other formula to chose right or left side)?

-
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
possible duplicate of Determine which side of a line a point lies –  Anko Feb 20 at 17:14
@Anko I don't get it: your link is older that that question –  manuell Feb 20 at 18:30
@manuell All I was thinking was these two are the same question. I didn't consider the creation times at all. Is there some convention? –  Anko Feb 21 at 0:17
@Anko I have no idea about conventions, but it seems more logical to make the newer a duplicate of the older than the opposite. –  manuell Feb 21 at 8:55

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.

-
+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
Great! This is a nice one, without sinus, arccos and such :) Rounding errors are not a problem here, as I use the separating in an algorithm to calculate the convex hull of the pointset and draw a polyline around them. If a point is just outside the hull, it is no big problem. –  Aaginor Oct 13 '09 at 14:53
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
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]) –  larsm Feb 9 '10 at 22:52
Also, this is the perp dot product, that is, `dot(perp(A), B))`. The sign is that of the sine of the angle from A to B. –  Electro Jul 20 '13 at 11:21

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
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

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