# Where to find Python implementation of Chaikin's corner cutting algorithm?

I am looking for Chaikin's corner cutting algorithm (link1, link2) implemented in Python 2.7.X but can't find it.

Maybe someone have it and able share the code?

• But algorithm looks pretty simple. Have you tried to implement it? – MBo Nov 2 '17 at 6:17

Ok, it wasn't so hard, here is the code:

``````import math

# visualisation
import matplotlib.pyplot as plt
import matplotlib.lines as lines
# visualisation

def Sum_points(P1, P2):
x1, y1 = P1
x2, y2 = P2
return x1+x2, y1+y2

def Multiply_point(multiplier, P):
x, y = P
return float(x)*float(multiplier), float(y)*float(multiplier)

def Check_if_object_is_polygon(Cartesian_coords_list):
if Cartesian_coords_list[0] == Cartesian_coords_list[len(Cartesian_coords_list)-1]:
return True
else:
return False

class Object():

def __init__(self, Cartesian_coords_list):
self.Cartesian_coords_list = Cartesian_coords_list

def Find_Q_point_position(self, P1, P2):
Summand1 = Multiply_point(float(3)/float(4), P1)
Summand2 = Multiply_point(float(1)/float(4), P2)
Q = Sum_points(Summand1, Summand2)
return Q

def Find_R_point_position(self, P1, P2):
Summand1 = Multiply_point(float(1)/float(4), P1)
Summand2 = Multiply_point(float(3)/float(4), P2)
R = Sum_points(Summand1, Summand2)
return R

def Smooth_by_Chaikin(self, number_of_refinements):
refinement = 1
copy_first_coord = Check_if_object_is_polygon(self.Cartesian_coords_list)
while refinement <= number_of_refinements:
self.New_cartesian_coords_list = []

for num, tuple in enumerate(self.Cartesian_coords_list):
if num+1 == len(self.Cartesian_coords_list):
pass
else:
P1, P2 = (tuple, self.Cartesian_coords_list[num+1])
Q = obj.Find_Q_point_position(P1, P2)
R = obj.Find_R_point_position(P1, P2)
self.New_cartesian_coords_list.append(Q)
self.New_cartesian_coords_list.append(R)

if copy_first_coord:
self.New_cartesian_coords_list.append(self.New_cartesian_coords_list[0])

self.Cartesian_coords_list = self.New_cartesian_coords_list
refinement += 1
return self.Cartesian_coords_list

if __name__ == "__main__":
Cartesian_coords_list = [(1,1),
(1,3),
(4,5),
(5,1),
(2,0.5),
(1,1),
]

obj = Object(Cartesian_coords_list)
Smoothed_obj = obj.Smooth_by_Chaikin(number_of_refinements = 5)

# visualisation
x1 = [i for i,j in Smoothed_obj]
y1 = [j for i,j in Smoothed_obj]
x2 = [i for i,j in Cartesian_coords_list]
y2 = [j for i,j in Cartesian_coords_list]
plt.plot(range(7),range(7),'w', alpha=0.7)
myline = lines.Line2D(x1,y1,color='r')
mynewline = lines.Line2D(x2,y2,color='b')
plt.show()
``````

Mr. Che answer will work, but here is a much shorter version that is slightly more efficient.

``````import numpy as np

def chaikins_corner_cutting(coords, refinements=5):
coords = np.array(coords)

for _ in range(refinements):
L = coords.repeat(2, axis=0)
R = np.empty_like(L)
R[0] = L[0]
R[2::2] = L[1:-1:2]
R[1:-1:2] = L[2::2]
R[-1] = L[-1]
coords = L * 0.75 + R * 0.25

return coords
``````

# How does it work?

For every two points, we need to take the lower part and the upper part in the line between them using the ratio 1:3:

``````LOWER-POINT = P1 * 0.25 + P2 * 0.75
UPPER-POINT = P1 * 0.75 + P2 * 0.25
``````

and add them both to the new points list. We also need to add the edge points, so the line will not shrink.

We build two arrays L and R in a certain way that if we will multiply them as follows it will yield the new points list.

``````NEW-POINTS = L * 0.75 + R * 0.25
``````

For example, if we have array of 4 points:

``````P = 0 1 2 3
``````

the L and R arrays will be as follows:

``````L = 0 0 1 1 2 2 3 3
R = 0 1 0 2 1 3 2 3
``````

where each number corresponds to a point.

• This should be standard method in Shapely! Thanks – Marjan Moderc Jan 17 '18 at 8:11