I saw the below algorithm works to check if a point is in a given polygon from this link:

int pnpoly(int nvert, float *vertx, float *verty, float testx, float testy)
  int i, j, c = 0;
  for (i = 0, j = nvert-1; i < nvert; j = i++) {
    if ( ((verty[i]>testy) != (verty[j]>testy)) &&
     (testx < (vertx[j]-vertx[i]) * (testy-verty[i]) / (verty[j]-verty[i]) + vertx[i]) )
       c = !c;
  return c;

I tried this algorithm and it actually works just perfect. But sadly I cannot understand it well after spending some time trying to get the idea of it.

So if someone is able to understand this algorithm, please explain it to me a little.

Thank you.


13 Answers 13


The algorithm is ray-casting to the right. Each iteration of the loop, the test point is checked against one of the polygon's edges. The first line of the if-test succeeds if the point's y-coord is within the edge's scope. The second line checks whether the test point is to the left of the line (I think - I haven't got any scrap paper to hand to check). If that is true the line drawn rightwards from the test point crosses that edge.

By repeatedly inverting the value of c, the algorithm counts how many times the rightward line crosses the polygon. If it crosses an odd number of times, then the point is inside; if an even number, the point is outside.

I would have concerns with a) the accuracy of floating-point arithmetic, and b) the effects of having a horizontal edge, or a test point with the same y-coord as a vertex, though.

  • 1
    Would the ordering of the vertices matter for this test?
    – paulm
    Jan 27, 2014 at 23:33
  • @paulm - yes; in the code above, the polygon is formed by joining vertex 0 to vertex 1 to vertex 2... to vertex 0.
    – Chowlett
    Jan 28, 2014 at 8:55
  • Sorry - I mean would the winding ordering matter?
    – paulm
    Jan 28, 2014 at 9:28
  • @paulm - I'm afraid I don't follow; what do you mean by the "winding ordering"?
    – Chowlett
    Jan 28, 2014 at 9:56
  • 1
    @paulm - Ah, I see. It... shouldn't do. I haven't checked the algorithm in depth to make sure, but each step only cares about one edge, at which point clockwise/anti-clockwise has no meaning.
    – Chowlett
    Jan 28, 2014 at 13:18

Edit 1/30/2022: I wrote this answer 9 years ago when I was in college. People in the chat conversation are indicating it's not accurate. You should probably look elsewhere. 🤷‍♂️

Chowlett is correct in every way, shape, and form. The algorithm assumes that if your point is on the line of the polygon, then that is outside - for some cases, this is false. Changing the two '>' operators to '>=' and changing '<' to '<=' will fix that.

bool PointInPolygon(Point point, Polygon polygon) {
  vector<Point> points = polygon.getPoints();
  int i, j, nvert = points.size();
  bool c = false;
  for(i = 0, j = nvert - 1; i < nvert; j = i++) {
    if( ( (points[i].y >= point.y ) != (points[j].y >= point.y) ) &&
        (point.x <= (points[j].x - points[i].x) * (point.y - points[i].y) / (points[j].y - points[i].y) + points[i].x)
      c = !c;
  return c;
  • Is there a more efficient way of doing the Point in Polygon? MySQL spatial extension takes about 50ms to query a table of 100 polygons.. this function in PHP takes about 100ms.
    – kouton
    Mar 29, 2013 at 8:22
  • 1
    @Reddox MySQL probably uses native (compiled) code, while PHP is interpreted, and not known for its speed...
    – PhiLho
    Jul 8, 2013 at 12:15
  • 2
    @Josh, You answer is confusing. There is only one '<' operator in the code (apart from the for loop). You have also changed the two '>' operators to '>=' as well as the single '<' to '<='. I am writing unit tests to check this for points on the line, and the test with point(100,100) and polygon 100,100 -> 200,100 -> 200,200 -> 100,200 fails.
    – Ash
    Apr 2, 2014 at 3:40
  • 7
    This answer is not correct despite the up-voting. By having point.x <= ... means that you consider a point on the edge as having a ray that crosses that edge to the right. This will count points that fall on rightmost edges as "in" and points that fall on edges to the left as "out". The obvious correction would be to explicitly test for the equality and exit the loop.
    – Ecuador
    Aug 19, 2014 at 16:49
  • 2
    Like @Ecuador says, this is not a correct answer. The original pnpoly algorithm, and the point on an edge case, is described here by its author. TL;DR, if the point is on the edge between two polygons, the pnpoly algorithm will consistently classify the point as inside one polygon, and outside the other polygon.
    – alondono
    May 4, 2017 at 1:59

I changed the original code to make it a little more readable (also this uses Eigen). The algorithm is identical.

// This uses the ray-casting algorithm to decide whether the point is inside
// the given polygon. See https://en.wikipedia.org/wiki/Point_in_polygon#Ray_casting_algorithm
bool pnpoly(const Eigen::MatrixX2d &poly, float x, float y)
    // If we never cross any lines we're inside.
    bool inside = false;

    // Loop through all the edges.
    for (int i = 0; i < poly.rows(); ++i)
        // i is the index of the first vertex, j is the next one.
        // The original code uses a too-clever trick for this.
        int j = (i + 1) % poly.rows();

        // The vertices of the edge we are checking.
        double xp0 = poly(i, 0);
        double yp0 = poly(i, 1);
        double xp1 = poly(j, 0);
        double yp1 = poly(j, 1);

        // Check whether the edge intersects a line from (-inf,y) to (x,y).

        // First check if the line crosses the horizontal line at y in either direction.
        if ((yp0 <= y) && (yp1 > y) || (yp1 <= y) && (yp0 > y))
            // If so, get the point where it crosses that line. This is a simple solution
            // to a linear equation. Note that we can't get a division by zero here -
            // if yp1 == yp0 then the above if will be false.
            double cross = (xp1 - xp0) * (y - yp0) / (yp1 - yp0) + xp0;

            // Finally check if it crosses to the left of our test point. You could equally
            // do right and it should give the same result.
            if (cross < x)
                inside = !inside;
    return inside;

To expand on the "too-clever trick". We want to iterate over all adjacent vertices, like this (imagine there are 4 vertices):

i j
0 1
1 2
2 3
3 0

My code above does it the simple obvious way - j = (i + 1) % num_vertices. However this uses integer division which is much much slower than all other operations. So if this is performance critical (e.g. in an AAA game) you want to avoid it.

The original code changes the order of iteration a bit:

i j
0 3
1 0
2 1
3 2

This is still totally valid since we're still iterating over every vertex pair and it doesn't really matter whether you go clockwise or anticlockwise, or where you start. However now it lets us avoid the integer division. In easy-to-understand form:

int i = 0;
int j = num_vertices - 1; // 3
while (i < num_vertices) { // 4
  j = i;  

Or in very terse C style:

for (int i = 0, j = num_vertices - 1; i < num_vertices; j = i++) {
  • you seem to be the only one mentioning the zero division case ;)
    – Baedsch
    Dec 13, 2018 at 16:02

This might be as detailed as it might get for explaining the ray-tracing algorithm in actual code. It might not be optimized but that must always come after a complete grasp of the system.

    //method to check if a Coordinate is located in a polygon
public boolean checkIsInPolygon(ArrayList<Coordinate> poly){
    //this method uses the ray tracing algorithm to determine if the point is in the polygon
    int nPoints=poly.size();
    int j=-999;
    int i=-999;
    boolean locatedInPolygon=false;
        //repeat loop for all sets of points
            //if i is the last vertex, let j be the first vertex
            j= 0;
            //for all-else, let j=(i+1)th vertex

        float vertY_i= (float)poly.get(i).getY();
        float vertX_i= (float)poly.get(i).getX();
        float vertY_j= (float)poly.get(j).getY();
        float vertX_j= (float)poly.get(j).getX();
        float testX  = (float)this.getX();
        float testY  = (float)this.getY();

        // following statement checks if testPoint.Y is below Y-coord of i-th vertex
        boolean belowLowY=vertY_i>testY;
        // following statement checks if testPoint.Y is below Y-coord of i+1-th vertex
        boolean belowHighY=vertY_j>testY;

        /* following statement is true if testPoint.Y satisfies either (only one is possible) 
        -->(i).Y < testPoint.Y < (i+1).Y        OR  
        -->(i).Y > testPoint.Y > (i+1).Y

        Both of the conditions indicate that a point is located within the edges of the Y-th coordinate
        of the (i)-th and the (i+1)- th vertices of the polygon. If neither of the above
        conditions is satisfied, then it is assured that a semi-infinite horizontal line draw 
        to the right from the testpoint will NOT cross the line that connects vertices i and i+1 
        of the polygon
        boolean withinYsEdges= belowLowY != belowHighY;

        if( withinYsEdges){
            // this is the slope of the line that connects vertices i and i+1 of the polygon
            float slopeOfLine   = ( vertX_j-vertX_i )/ (vertY_j-vertY_i) ;

            // this looks up the x-coord of a point lying on the above line, given its y-coord
            float pointOnLine   = ( slopeOfLine* (testY - vertY_i) )+vertX_i;

            //checks to see if x-coord of testPoint is smaller than the point on the line with the same y-coord
            boolean isLeftToLine= testX < pointOnLine;

                //this statement changes true to false (and vice-versa)
                locatedInPolygon= !locatedInPolygon;
            }//end if (isLeftToLine)
        }//end if (withinYsEdges

    return locatedInPolygon;

Just one word about optimization: It isn't true that the shortest (and/or the tersest) code is the fastest implemented. It is a much faster process to read and store an element from an array and use it (possibly) many times within the execution of the block of code than to access the array each time it is required. This is especially significant if the array is extremely large. In my opinion, by storing each term of an array in a well-named variable, it is also easier to assess its purpose and thus form a much more readable code. Just my two cents...


The algorithm is stripped down to the most necessary elements. After it was developed and tested all unnecessary stuff has been removed. As result you can't undertand it easily but it does the job and also in very good performance.

I took the liberty to translate it to ActionScript-3:

// not optimized yet (nvert could be left out)
public static function pnpoly(nvert: int, vertx: Array, verty: Array, x: Number, y: Number): Boolean
    var i: int, j: int;
    var c: Boolean = false;
    for (i = 0, j = nvert - 1; i < nvert; j = i++)
        if (((verty[i] > y) != (verty[j] > y)) && (x < (vertx[j] - vertx[i]) * (y - verty[i]) / (verty[j] - verty[i]) + vertx[i]))
            c = !c;
    return c;

This algorithm works in any closed polygon as long as the polygon's sides don't cross. Triangle, pentagon, square, even a very curvy piecewise-linear rubber band that doesn't cross itself.

1) Define your polygon as a directed group of vectors. By this it is meant that every side of the polygon is described by a vector that goes from vertex an to vertex an+1. The vectors are so directed so that the head of one touches the tail of the next until the last vector touches the tail of the first.

2) Select the point to test inside or outside of the polygon.

3) For each vector Vn along the perimeter of the polygon find vector Dn that starts on the test point and ends at the tail of Vn. Calculate the vector Cn defined as DnXVn/DN*VN (X indicates cross product; * indicates dot product). Call the magnitude of Cn by the name Mn.

4) Add all Mn and call this quantity K.

5) If K is zero, the point is outside the polygon.

6) If K is not zero, the point is inside the polygon.

Theoretically, a point lying ON the edge of the polygon will produce an undefined result.

The geometrical meaning of K is the total angle that the flea sitting on our test point "saw" the ant walking at the edge of the polygon walk to the left minus the angle walked to the right. In a closed circuit, the ant ends where it started. Outside of the polygon, regardless of location, the answer is zero.
Inside of the polygon, regardless of location, the answer is "one time around the point".


This method check whether the ray from the point (testx, testy) to O (0,0) cut the sides of the polygon or not .

There's a well-known conclusion here: if a ray from 1 point and cut the sides of a polygon for a odd time, that point will belong to the polygon, otherwise that point will be outside the polygon.


To expand on @chowlette's answer where the second line checks if the point is to the left of the line, No derivation is given but this is what I worked out: First it helps to imagine 2 basic cases:

  • the point is left of the line . / or
  • the point is right of the line / .

If our point were to shoot a ray out horizontally where would it strike the line segment. Is our point to the left or right of it? Inside or out? We know its y coordinate because it's by definition the same as the point. What would the x coordinate be?

Take your traditional line formula y = mx + b. m is the rise over the run. Here, instead we are trying to find the x coordinate of the point on that line segment that has the same height (y) as our point.

So we solve for x: x = (y - b)/m. m is rise over run, so this becomes run over rise or (yj - yi)/(xj - xi) becomes (xj - xi)/(yj - yi). b is the offset from origin. If we assume yi as the base for our coordinate system, b becomes yi. Our point testy is our input, subtracting yi turns the whole formula into an offset from yi.

We now have (xj - xi)/(yj - yi) or 1/m times y or (testy - yi): (xj - xi)(testy - yi)/(yj - yi) but testx isn't based to yi so we add it back in order to compare the two ( or zero testx as well )


I think the basic idea is to calculate vectors from the point, one per edge of the polygon. If vector crosses one edge, then the point is within the polygon. By concave polygons if it crosses an odd number of edges it is inside as well (disclaimer: although not sure if it works for all concave polygons).


This is the algorithm I use, but I added a bit of preprocessing trickery to speed it up. My polygons have ~1000 edges and they don't change, but I need to look up whether the cursor is inside one on every mouse move.

I basically split the height of the bounding rectangle to equal length intervals and for each of these intervals I compile the list of edges that lie within/intersect with it.

When I need to look up a point, I can calculate - in O(1) time - which interval it is in and then I only need to test those edges that are in the interval's list.

I used 256 intervals and this reduced the number of edges I need to test to 2-10 instead of ~1000.


Here's a php implementation of this:

class Point2D {

    public $x;
    public $y;

    function __construct($x, $y) {
        $this->x = $x;
        $this->y = $y;

    function x() {
        return $this->x;

    function y() {
        return $this->y;


class Point {

    protected $vertices;

    function __construct($vertices) {

        $this->vertices = $vertices;

    //Determines if the specified point is within the polygon. 
    function pointInPolygon($point) {
        /* @var $point Point2D */
    $poly_vertices = $this->vertices;
    $num_of_vertices = count($poly_vertices);

    $edge_error = 1.192092896e-07;
    $r = false;

    for ($i = 0, $j = $num_of_vertices - 1; $i < $num_of_vertices; $j = $i++) {
        /* @var $current_vertex_i Point2D */
        /* @var $current_vertex_j Point2D */
        $current_vertex_i = $poly_vertices[$i];
        $current_vertex_j = $poly_vertices[$j];

        if (abs($current_vertex_i->y - $current_vertex_j->y) <= $edge_error && abs($current_vertex_j->y - $point->y) <= $edge_error && ($current_vertex_i->x >= $point->x) != ($current_vertex_j->x >= $point->x)) {
            return true;

        if ($current_vertex_i->y > $point->y != $current_vertex_j->y > $point->y) {
            $c = ($current_vertex_j->x - $current_vertex_i->x) * ($point->y - $current_vertex_i->y) / ($current_vertex_j->y - $current_vertex_i->y) + $current_vertex_i->x;

            if (abs($point->x - $c) <= $edge_error) {
                return true;

            if ($point->x < $c) {
                $r = !$r;

    return $r;

Test Run:

        $vertices = array();

        array_push($vertices, new Point2D(120, 40));
        array_push($vertices, new Point2D(260, 40));
        array_push($vertices, new Point2D(45, 170));
        array_push($vertices, new Point2D(335, 170));
        array_push($vertices, new Point2D(120, 300));
        array_push($vertices, new Point2D(260, 300));

        $Point = new Point($vertices);
        $point_to_find = new Point2D(190, 170);
        $isPointInPolygon = $Point->pointInPolygon($point_to_find);
        echo $isPointInPolygon;

I modified the code to check whether the point is in a polygon, including the point is on an edge.

bool point_in_polygon_check_edge(const vec<double, 2>& v, vec<double, 2> polygon[], int point_count, double edge_error = 1.192092896e-07f)
    const static int x = 0;
    const static int y = 1;
    int i, j;
    bool r = false;
    for (i = 0, j = point_count - 1; i < point_count; j = i++)
        const vec<double, 2>& pi = polygon[i);
        const vec<double, 2>& pj = polygon[j];
        if (fabs(pi[y] - pj[y]) <= edge_error && fabs(pj[y] - v[y]) <= edge_error && (pi[x] >= v[x]) != (pj[x] >= v[x]))
            return true;

        if ((pi[y] > v[y]) != (pj[y] > v[y]))
            double c = (pj[x] - pi[x]) * (v[y] - pi[y]) / (pj[y] - pi[y]) + pi[x];
            if (fabs(v[x] - c) <= edge_error)
                return true;
            if (v[x] < c)
                r = !r;
    return r;
  • Changes are simple, If the point is on the edge, Check it as the point is in the polygon. If pi[y] == pj[y] == v[y] and v[x] is in between pi[x] and pj[x], point is on the edge of horizontal line of the polygon. if c == v[x] and v[y] is in between pi[y] and pj[y], the point is on the edge of vertical line of the polygon.
    – rawdev
    Jan 26, 2015 at 2:30
  • @rawdew your algorithm is quirky
    – Daniel
    May 19, 2015 at 3:06

The answers above use floating point division to calculate the intersection of an edge and the infinite ray pointing right from the point. But the exact location of the intersection is actually not needed. It suffices to known if the intersection is on the left or right hand side of an edge. Cross product gives this information, so floating point arithmetic is not needed.

Often in practice it does not matter what the result is if the point is on an edge. Example of such a "fast and dirty" integer code:

#include <vector>

struct Point
    using T = int; // ..or float or double
    T x, y;

/** Checks if a point is inside a simple polygon.
 * The vertices are given as a coordinate vector.
 * Note that this concise version does not give consistent
 * answers for points which are on an edge.
bool const pointInPolygon(const Point& p, const std::vector<Point>& vertex)
    if (vertex.size() < 3)
        return false;

    bool isInside = false;
    auto prev = vertex.size() - 1u;
    for (decltype(prev) next = 0; next < vertex.size(); prev = next++)
        if ((vertex[prev].y > p.y) != (vertex[next].y > p.y)) {
            // Now an infinitely long ray stretching right from the point
            // may intersect the edge between vertices prev and next.

            auto diffVertexX = vertex[next].x - vertex[prev].x;
            auto diffVertexY = vertex[next].y - vertex[prev].y;
            auto diffPointX = p.x - vertex[prev].x;
            auto diffPointY = p.y - vertex[prev].y;

            // Use the sign of the cross product of the differences
            // to determine the side on which the point lies compared to the edge.
            // Calculate the two parts of the cross product separately.
            auto crossProductXY = diffVertexX * diffPointY;
            auto crossProductYX = diffVertexY * diffPointX;

            // Switch the sign of the cross product depending on whether the edge
            // is pointing upwards or downwards.
            if (diffVertexY < 0)
                isInside = isInside ^ (crossProductYX > crossProductXY);
                isInside = isInside ^ (crossProductXY > crossProductYX);
    return isInside;

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