42

I have a class describing a Point (has 2 coordinates x and y) and a class describing a Polygon which has a list of Points which correspond to corners (self.corners) I need to check if a Point is in a Polygon

Here is the function that is supposed to check if the Point is in the Polygon. I am using the Ray Casting Method

def in_me(self, point):
        result = False
        n = len(self.corners)
        p1x = int(self.corners[0].x)
        p1y = int(self.corners[0].y)
        for i in range(n+1):
            p2x = int(self.corners[i % n].x)
            p2y = int(self.corners[i % n].y)
            if point.y > min(p1y,p2y):
                if point.x <= max(p1x,p2x):
                    if p1y != p2y:
                        xinters = (point.y-p1y)*(p2x-p1x)/(p2y-p1y)+p1x
                        print xinters
                    if p1x == p2x or point.x <= xinters:
                        result = not result
            p1x,p1y = p2x,p2y
         return result

I run a test with following shape and point:

PG1 = (0,0), (0,2), (2,2), (2,0)
point = (1,1)

The script happily returns False even though the point it within the line. I am unable to find the mistake

5
  • 1
    Might be because you're using "/" on integers, which returns an integer (rounded down). You should do all computations with floats instead. Also, if p1y == p2y, xinters might not be defined but still used just afterwards.
    – Armin Rigo
    May 18, 2013 at 15:04
  • Better yet: don't divide at all. Instead of computing xinters, check if (point.x - p1x)*(p2y-p1y) <= (point.y-p1y)*(p2x-p1x). However, casting the vertex coordinates to integers could introduce errors if they aren't already integers to start with.
    – chepner
    May 18, 2013 at 16:19
  • 1
    ...or use Python 3, which doesn't truncate to integers on division. May 18, 2013 at 16:56
  • how would using (point.x - p1x)*(p2y-p1y) <= (point.y-p1y)*(p2x-p1x) make the actual code look like? Since it is a homework assignment, then we have to use Python 2.7 :(
    – Helena
    May 18, 2013 at 17:41
  • @Ulrich & helena: Python 3 division can be enabled in Python 2 using from __future__ import division. Another alternative is to just float() either the numerator or denominator (or a term in one of them in this case).
    – martineau
    Jul 14, 2014 at 13:22

4 Answers 4

62

I would suggest using the Path class from matplotlib

import matplotlib.path as mplPath
import numpy as np

poly = [190, 50, 500, 310]
bbPath = mplPath.Path(np.array([[poly[0], poly[1]],
                     [poly[1], poly[2]],
                     [poly[2], poly[3]],
                     [poly[3], poly[0]]]))

bbPath.contains_point((200, 100))

(There is also a contains_points function if you want to test for multiple points)

7
  • 3
    For this to work, you must first import numpy as np Mar 6, 2015 at 16:54
  • 5
    Anyone checked performance of contains_points against a pure Python implementation ? Jul 11, 2016 at 8:18
  • 1
    Something's wrong, using array = [[100,100],[200,100],[200,200],[100,200],[100,100]] it gives False for point 100,100 and true for point 200,200
    – Maciek
    Mar 10, 2018 at 12:00
  • 1
    Why the variable name 'bbPath'? if (Does 'bb' abbreviate something?): what does 'bb' abbreviate?
    – nda
    Feb 7, 2019 at 2:46
  • 1
    bb means bounding box even though the polygon very like wont be a box :)
    – P.R.
    Feb 11, 2019 at 12:07
3

I'd like to suggest some other changes there:

def contains(self, point):
    if not self.corners:
        return False

    def lines():
        p0 = self.corners[-1]
        for p1 in self.corners:
            yield p0, p1
            p0 = p1

    for p1, p2 in lines():
        ... # perform actual checks here

Notes:

  • A polygon with 5 corners also has 5 bounding lines, not 6, your loop is one off.
  • Using a separate generator expression makes clear that you are checking each line in turn.
  • Checking for an empty number of lines was added. However, how to treat zero-length lines and polygons with a single corner is still open.
  • I'd also consider making the lines() function a normal member instead of a nested utility.
  • Instead of the many nested if structures, you could also check for the inverse and then continue or use and.
0

Steps:

  • Iterate over all the segments in the polygon
  • Check whether they intersect with a ray going in the increasing-x direction

Using the intersect function from This SO Question

def ccw(A,B,C):
    return (C.y-A.y) * (B.x-A.x) > (B.y-A.y) * (C.x-A.x)

# Return true if line segments AB and CD intersect
def intersect(A,B,C,D):
    return ccw(A,C,D) != ccw(B,C,D) and ccw(A,B,C) != ccw(A,B,D)

def point_in_polygon(pt, poly, inf):
    result = False
    for i in range(len(poly.corners)-1):
        if intersect((poly.corners[i].x, poly.corners[i].y), ( poly.corners[i+1].x, poly.corners[i+1].y), (pt.x, pt.y), (inf, pt.y)):
            result = not result
    if intersect((poly.corners[-1].x, poly.corners[-1].y), (poly.corners[0].x, poly.corners[0].y), (pt.x, pt.y), (inf, pt.y)):
        result = not result
    return result

Please note that the inf parameter should be the maximum point in the x axis in your figure.

1
  • This is incorrect, doesn't work for point [2, 5] with polygon [8, 6], [11, 10], [16, 5], [11, 3] Edit: The issue is probably that the ray goes directly through a point of the polygon, causing two polygon line segments to be toggling result, turning it back to its previous state
    – h345k34cr
    Jul 4, 2017 at 12:35
0

I was trying to solve the same problem for my project and I got this code from someone in my network.

#!/usr/bin/env python
#
# routine for performing the "point in polygon" inclusion test

# Copyright 2001, softSurfer (www.softsurfer.com)
# This code may be freely used and modified for any purpose
# providing that this copyright notice is included with it.
# SoftSurfer makes no warranty for this code, and cannot be held
# liable for any real or imagined damage resulting from its use.
# Users of this code must verify correctness for their application.

# translated to Python by Maciej Kalisiak <mac@dgp.toronto.edu>

#   a Point is represented as a tuple: (x,y)

#===================================================================

# is_left(): tests if a point is Left|On|Right of an infinite line.

#   Input: three points P0, P1, and P2
#   Return: >0 for P2 left of the line through P0 and P1
#           =0 for P2 on the line
#           <0 for P2 right of the line
#   See: the January 2001 Algorithm "Area of 2D and 3D Triangles and Polygons"

def is_left(P0, P1, P2):
    return (P1[0] - P0[0]) * (P2[1] - P0[1]) - (P2[0] - P0[0]) * (P1[1] - P0[1])

#===================================================================

# cn_PnPoly(): crossing number test for a point in a polygon
#     Input:  P = a point,
#             V[] = vertex points of a polygon
#     Return: 0 = outside, 1 = inside
# This code is patterned after [Franklin, 2000]

def cn_PnPoly(P, V):
    cn = 0    # the crossing number counter

    # repeat the first vertex at end
    V = tuple(V[:])+(V[0],)

    # loop through all edges of the polygon
    for i in range(len(V)-1):   # edge from V[i] to V[i+1]
        if ((V[i][1] <= P[1] and V[i+1][1] > P[1])   # an upward crossing
            or (V[i][1] > P[1] and V[i+1][1] <= P[1])):  # a downward crossing
            # compute the actual edge-ray intersect x-coordinate
            vt = (P[1] - V[i][1]) / float(V[i+1][1] - V[i][1])
            if P[0] < V[i][0] + vt * (V[i+1][0] - V[i][0]): # P[0] < intersect
                cn += 1  # a valid crossing of y=P[1] right of P[0]

    return cn % 2   # 0 if even (out), and 1 if odd (in)

#===================================================================

# wn_PnPoly(): winding number test for a point in a polygon
#     Input:  P = a point,
#             V[] = vertex points of a polygon
#     Return: wn = the winding number (=0 only if P is outside V[])

def wn_PnPoly(P, V):
    wn = 0   # the winding number counter

    # repeat the first vertex at end
    V = tuple(V[:]) + (V[0],)

    # loop through all edges of the polygon
    for i in range(len(V)-1):     # edge from V[i] to V[i+1]
        if V[i][1] <= P[1]:        # start y <= P[1]
            if V[i+1][1] > P[1]:     # an upward crossing
                if is_left(V[i], V[i+1], P) > 0: # P left of edge
                    wn += 1           # have a valid up intersect
        else:                      # start y > P[1] (no test needed)
            if V[i+1][1] <= P[1]:    # a downward crossing
                if is_left(V[i], V[i+1], P) < 0: # P right of edge
                    wn -= 1           # have a valid down intersect
    return wn

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