import math
import numpy as np
from analyzer.epoint import EPoint, homogenize
from analyzer.grid import transformPoint
class Line():
def __init__(self,a,b):
self.a=a
self.b=b
self.points={a,b}
def getSortedPoints(self):
return tuple(sorted(self.points))
def computeAngle(self,line):
ab=self.a-self.b
cd=line.a-line.b
alpha=math.atan(ab.y/ab.x)
gamma=math.atan(cd.y/cd.x)
fi=max(alpha,gamma)-min(alpha,gamma)
return min(fi,math.pi-fi)
def intersect(self,line):
p=self.toProjective()
q=line.toProjective()
return EPoint.fromProjective(np.cross(p,q))
def toProjective(self):
return homogenize(np.cross(self.a.toProjective(),self.b.toProjective()))
def transform(self,matrix):
a=EPoint.fromProjective(transformPoint(self.a.toProjective(),matrix))
b=EPoint.fromProjective(transformPoint(self.b.toProjective(),matrix))
if a is None or b is None: return None
return Line(a,b)
def score(self,points):
score=len(self.points)
for a in self.points:
closest=sorted(points,key=lambda b: a.dist(b))[:4]
score+=sum(0.01 for b in closest if b in self.points)
return score
def __str__(self): return "({0},{1})".format(self.a,self.b)
def __repr__(self): return "Line({0},{1})".format(repr(self.a),repr(self.b))
def point2lineDistance(a,b,p):
# https://en.wikipedia.org/wiki/Point-line_distance#Line_defined_by_two_points
ab=b-a
num=abs(ab.y*p.x - ab.x*p.y + b.x*a.y - a.x*b.y)
denum=math.sqrt(ab.y**2+ab.x**2)
return num/denum # double_area / side_length == height
def angleDiff(alpha,beta):
diff=abs(alpha-beta)
if diff>math.pi: diff=2*math.pi-diff
return diff