# Python : Ramer-Douglas-Peucker (RDP) algorithm with number of points instead of epsilon

I would like to modify this following python script for RDP algorithm with the purpose of not using epsilon but to choose the number of points I want to keep at the final :

``````class DPAlgorithm():

def distance(self,  a, b):
return  sqrt((a[0] - b[0]) ** 2 + (a[1] - b[1]) ** 2)

def point_line_distance(self,  point, start, end):
if (start == end):
return self.distance(point, start)
else:
n = abs(
(end[0] - start[0]) * (start[1] - point[1]) - (start[0] - point[0]) * (end[1] - start[1])
)
d = sqrt(
(end[0] - start[0]) ** 2 + (end[1] - start[1]) ** 2
)
return n / d

def rdp(self, points, epsilon):
"""
Reduces a series of points to a simplified version that loses detail, but
maintains the general shape of the series.
"""
dmax = 0.0
index = 0
i=1
for i in range(1, len(points) - 1):
d = self.point_line_distance(points[i], points[0], points[-1])
if d > dmax :
index = i
dmax = d

if dmax >= epsilon :
results = self.rdp(points[:index+1], epsilon)[:-1] + self.rdp(points[index:], epsilon)
else:
results = [points[0], points[-1]]
return results
``````

I found a Java script in that spirit : https://gist.github.com/msbarry/9152218

Does anyone know a version for Python 3.X ?

Thanks Momow

Ported JS code from the link above to Python [2.7]:

``````# -*- coding: utf-8 -*-

import math
import time

def timenow():
return int(time.time() * 1000)

def sqr(x):
return x*x

def distSquared(p1, p2):
return sqr(p1[0] - p2[0]) + sqr(p1[1] - p2[1])

class Line(object):
def __init__(self, p1, p2):
self.p1 = p1
self.p2 = p2
self.lengthSquared = distSquared(self.p1, self.p2)

def getRatio(self, point):
segmentLength = self.lengthSquared
if segmentLength == 0:
return distSquared(point, p1);
return ((point[0] - self.p1[0]) * (self.p2[0] - self.p1[0]) + \
(point[1] - self.p1[1]) * (self.p2[1] - self.p1[1])) / segmentLength

def distanceToSquared(self, point):
t = self.getRatio(point)

if t < 0:
return distSquared(point, self.p1)
if t > 1:
return distSquared(point, self.p2)

return distSquared(point, [
self.p1[0] + t * (self.p2[0] - self.p1[0]),
self.p1[1] + t * (self.p2[1] - self.p1[1])
])

def distanceTo(self, point):
return math.sqrt(self.distanceToSquared(point))

def simplifyDouglasPeucker(points, pointsToKeep):
weights = []
length = len(points)

def douglasPeucker(start, end):
if (end > start + 1):
line = Line(points[start], points[end])
maxDist = -1
maxDistIndex = 0

for i in range(start + 1, end):
dist = line.distanceToSquared(points[i])
if dist > maxDist:
maxDist = dist
maxDistIndex = i

weights.insert(maxDistIndex, maxDist)

douglasPeucker(start, maxDistIndex)
douglasPeucker(maxDistIndex, end)

douglasPeucker(0, length - 1)
weights.insert(0, float("inf"))
weights.append(float("inf"))

weightsDescending = weights
weightsDescending = sorted(weightsDescending, reverse=True)

maxTolerance = weightsDescending[pointsToKeep - 1]
result = [
point for i, point in enumerate(points) if weights[i] >= maxTolerance
]

return result
``````