The polygon is given as a list of Vector2I objects (2 dimensional, integer coordinates). How can i test if a given point is inside? All implementations i found on the web fail for some trivial counterexample. It really seems to be hard to write a correct implementation. The language does not matter as i will port it myself.

A comment. If it is an interview problem, you are expected to get a O(log n) solution because convex polygon is a special case. Use a binary search along with the idea given in ufukgun's answer.– Yin ZhuMar 23, 2010 at 9:45

5The answers here are surprisingly bad. This article by Eric Haines describes many methods for doing this, and also provides references to well known texts.– boboboboJun 18, 2013 at 17:01

possible duplicate of Point in Polygon aka hit test– boboboboJun 18, 2013 at 17:40
9 Answers
If it is convex, a trivial way to check it is that the point is laying on the same side of all the segments (if traversed in the same order).
You can check that easily with the dot product (as it is proportional to the cosine of the angle formed between the segment and the point, if we calculate it with the normal of the edge, those with positive sign would lay on the right side and those with negative sign on the left side).
Here is the code in Python:
RIGHT = "RIGHT"
LEFT = "LEFT"
def inside_convex_polygon(point, vertices):
previous_side = None
n_vertices = len(vertices)
for n in xrange(n_vertices):
a, b = vertices[n], vertices[(n+1)%n_vertices]
affine_segment = v_sub(b, a)
affine_point = v_sub(point, a)
current_side = get_side(affine_segment, affine_point)
if current_side is None:
return False #outside or over an edge
elif previous_side is None: #first segment
previous_side = current_side
elif previous_side != current_side:
return False
return True
def get_side(a, b):
x = cosine_sign(a, b)
if x < 0:
return LEFT
elif x > 0:
return RIGHT
else:
return None
def v_sub(a, b):
return (a[0]b[0], a[1]b[1])
def cosine_sign(a, b):
return a[0]*b[1]a[1]*b[0]

7Hacking something together when there are well known solutions will almost always miss some edge cases.– EricJul 14, 2009 at 6:38

What happens for points on the edge? Say k = 0, it should give a ZeroDivisionError.– stefanoJan 7, 2012 at 15:02

@stefano well, if that is a possible case then we'll have to decide if that means inside or outside (the boundary is open or closed)– fortranJan 8, 2012 at 12:08

@fortran true, but don't you think it would be opportune to make a test to check if k==0 before the division by abs(k), to avoid the error?– stefanoJan 8, 2012 at 15:19

1^ rendering of above polygon from @jolly : wolframalpha.com/input/…– JonathanFeb 27, 2019 at 12:16
The Ray Casting or Winding methods are the most common for this problem. See the Wikipedia article for details.
Also, Check out this page for a welldocumented solution in C.

For integer coordinates, wrf's code snippet will be more than sufficient.– EricJul 13, 2009 at 14:13

1It's the most common... but if you already know the polygon is CONVEX, like this case, the fortran is supposed to be faster! Aug 15, 2013 at 18:42

2
If the polygon is convex, then in C#, the following implements the "test if always on same side" method, and runs at most at O(n of polygon points):
public static bool IsInConvexPolygon(Point testPoint, List<Point> polygon)
{
//Check if a triangle or higher ngon
Debug.Assert(polygon.Length >= 3);
//n>2 Keep track of cross product sign changes
var pos = 0;
var neg = 0;
for (var i = 0; i < polygon.Count; i++)
{
//If point is in the polygon
if (polygon[i] == testPoint)
return true;
//Form a segment between the i'th point
var x1 = polygon[i].X;
var y1 = polygon[i].Y;
//And the i+1'th, or if i is the last, with the first point
var i2 = (i+1)%polygon.Count;
var x2 = polygon[i2].X;
var y2 = polygon[i2].Y;
var x = testPoint.X;
var y = testPoint.Y;
//Compute the cross product
var d = (x  x1)*(y2  y1)  (y  y1)*(x2  x1);
if (d > 0) pos++;
if (d < 0) neg++;
//If the sign changes, then point is outside
if (pos > 0 && neg > 0)
return false;
}
//If no change in direction, then on same side of all segments, and thus inside
return true;
}

1Sorry if this seems a bit pedantic, but you should probably just fail (or even assert) if the list's length is less than 3. This is a test for polygons, not a test to see if a point is equal to another point, or that a point is on a line. Handling those cases is a great way to get huge headaches later when something you expect to go one way is going another without telling you that you did something wrong. Also the method name doesn't imply that it covers those cases very well. Jul 23, 2016 at 14:02

very helpful! if that helps anyone, i've modified & ported that code in another answer: stackoverflow.com/a/48941131/516188 maybe someone finds my version clearer. Feb 23, 2018 at 4:40

1very helpful! I just tested this function on a homebrew gamedev of mine : a point & click adventure for the Amiga computer. It simply works straight out of the box, converted into C89, compiled & running on the good old 68000. Thanks! (C version is here : github.com/ResistanceVault/rpage/blob/master/rpage/utils.c#L119)– AstrofraNov 23, 2019 at 9:47
The pointPolygonTest function in openCV " determines whether the point is inside a contour, outside, or lies on an edge": http://docs.opencv.org/modules/imgproc/doc/structural_analysis_and_shape_descriptors.html?highlight=pointpolygontest#pointpolygontest

OpenCV is a really large library. You really don't want to be using it just for this. May 4, 2021 at 21:07
fortran's answer almost worked for me except I found I had to translate the polygon so that the point you're testing is the same as the origin. Here is the JavaScript that I wrote to make this work:
function Vec2(x, y) {
return [x, y]
}
Vec2.nsub = function (v1, v2) {
return Vec2(v1[0]v2[0], v1[1]v2[1])
}
// aka the "scalar cross product"
Vec2.perpdot = function (v1, v2) {
return v1[0]*v2[1]  v1[1]*v2[0]
}
// Determine if a point is inside a polygon.
//
// point  A Vec2 (2element Array).
// polyVerts  Array of Vec2's (2element Arrays). The vertices that make
// up the polygon, in clockwise order around the polygon.
//
function coordsAreInside(point, polyVerts) {
var i, len, v1, v2, edge, x
// First translate the polygon so that `point` is the origin. Then, for each
// edge, get the angle between two vectors: 1) the edge vector and 2) the
// vector of the first vertex of the edge. If all of the angles are the same
// sign (which is negative since they will be counterclockwise) then the
// point is inside the polygon; otherwise, the point is outside.
for (i = 0, len = polyVerts.length; i < len; i++) {
v1 = Vec2.nsub(polyVerts[i], point)
v2 = Vec2.nsub(polyVerts[i+1 > len1 ? 0 : i+1], point)
edge = Vec2.nsub(v1, v2)
// Note that we could also do this by using the normal + dot product
x = Vec2.perpdot(edge, v1)
// If the point lies directly on an edge then count it as in the polygon
if (x < 0) { return false }
}
return true
}
the way i know is something like that.
you pick a point somewhere outside the polygon it may be far away from the geometry. then you draw a line from this point. i mean you create a line equation with these two points.
then for every line in this polygon, you check if they intersect.
them sum of number of intersected lines give you it is inside or not.
if it is odd : inside
if it is even : outside

i just learned : it is Ray casting algorithm where eJames has already talked about– ufukgunJul 13, 2009 at 14:40

I find your explanation difficult to follow... what's the other point of the line?– fortranJul 13, 2009 at 15:28

Ray casting is generally a bad solution, it doesn't deal well with points that are near a vertex where the cast ray would be close to a side. Winding rule is much more robust and faster, especially for convex shapes Jul 13, 2009 at 18:30


"what's the other point of the line?" any point which is garanteed to be outside of the polygon. for example: find minimum x and y for all points. pick x100, y100 is a point outside of the polygon.– ufukgunJul 14, 2009 at 6:46
You have to check that the point to test maintains it's orientation relative to all segments of the convex polygon. If so, it's inside. To do this for each segment check if the determinant of the segment vector say AB and the point's vector say AP preserves it's sign. If the determinant is zero than the point is on the segment.
To expose this in C# code,
public bool IsPointInConvexPolygon(...)
{
Point pointToTest = new Point(...);
Point pointA = new Point(...);
//....
var polygon = new List<Point> { pointA, pointB, pointC, pointD ... };
double prevPosition = 0;
// assuming polygon is convex.
for (var i = 0; i < polygon.Count; i++)
{
var startPointSegment = polygon[i];
// end point is first point if the start point is the last point in the list
// (closing the polygon)
var endPointSegment = polygon[i < polygon.Count  1 ? i + 1 : 0];
if (pointToTest.HasEqualCoordValues(startPointSegment) 
pointToTest.HasEqualCoordValues(endPointSegment))
return true;
var position = GetPositionRelativeToSegment(pointToTest, startPointSegment, endPointSegment);
if (position == 0) // point position is zero so we are on the segment, we're on the polygon.
return true;
// after we checked the test point's position relative to the first segment, the position of the point
// relative to all other segments must be the same as the first position. If not it means the point
// is not inside the convex polygon.
if (i > 0 && prevPosition != position)
return false;
prevPosition = position;
}
return true;
}
The determinant calculus,
public double GetPositionRelativeToSegment(Point pointToTest, Point segmentStart, Point segmentEnd)
{
return Math.Sign((pointToTest.X  segmentStart.X) * (segmentEnd.Y  segmentStart.Y) 
(pointToTest.Y  segmentStart.Y) * (segmentEnd.X  segmentStart.X));
}
Or from the man that wrote the book see  geometry page
Specifically this page, he discusses why winding rule is generally better than ray crossing.
edit  Sorry this isn't Jospeh O'Rourke who wrote the excellent book Computational Geometry in C, it's Paul Bourke but still a very very good source of geometry algorithms.
Here is the version I use in my project. It's very elegant and concise. Works for every kind of polygons.
http://www.eecs.umich.edu/courses/eecs380/HANDOUTS/PROJ2/InsidePoly.html
The following code is by Randolph Franklin, it returns 1 for interior points and 0 for exterior points.
int pnpoly(int npol, float *xp, float *yp, float x, float y)
{
int i, j, c = 0;
for (i = 0, j = npol1; i < npol; j = i++) {
if ((((yp[i] <= y) && (y < yp[j])) 
((yp[j] <= y) && (y < yp[i]))) &&
(x < (xp[j]  xp[i]) * (y  yp[i]) / (yp[j]  yp[i]) + xp[i]))
c = !c;
}
return c;
}