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####################################################################################################
#
# Patro - A Python library to make patterns for fashion design
# Copyright (C) 2017 Fabrice Salvaire
#
# This program is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <http://www.gnu.org/licenses/>.
#
####################################################################################################
####################################################################################################
from Patro.Common.Math.Root import quadratic_root, cubic_root
from .Interpolation import interpolate_two_points
from .Line import Line2D
from .Primitive import Primitive3P, Primitive4P, Primitive2DMixin
from .Transformation import AffineTransformation
from .Vector import Vector2D
####################################################################################################
# Fixme: implement intersection
####################################################################################################
class QuadraticBezier2D(Primitive2DMixin, Primitive3P):
"""Class to implements 2D Quadratic Bezier Curve."""
LineInterpolationPrecision = 0.05
##############################################
def __init__(self, p0, p1, p2):
##############################################
def __repr__(self):
return self.__class__.__name__ + '({0._p0}, {0._p1}, {0._p2})'.format(self)
##############################################
@property
def length(self):
# Algorithm:
#
# http://www.gamedev.net/topic/551455-length-of-a-generalized-quadratic-bezier-curve-in-3d
# Dave Eberly Posted October 25, 2009
#
# The quadratic Bezier is
# (x(t),y(t)) = (1-t)^2*(x0,y0) + 2*t*(1-t)*(x1,y1) + t^2*(x2,y2)
#
# The derivative is
# (x'(t),y'(t)) = -2*(1-t)*(x0,y0) + (2-4*t)*(x1,y1) + 2*t*(x2,y2)
#
# The length of the curve for 0 <= t <= 1 is
# Integral[0,1] sqrt((x'(t))^2 + (y'(t))^2) dt
# The integrand is of the form sqrt(c*t^2 + b*t + a)
#
# You have three separate cases: c = 0, c > 0, or c < 0.
# * The case c = 0 is easy.
# * For the case c > 0, an antiderivative is
# (2*c*t+b)*sqrt(c*t^2+b*t+a)/(4*c) + (0.5*k)*log(2*sqrt(c*(c*t^2+b*t+a)) + 2*c*t + b)/sqrt(c)
# where k = 4*c/q with q = 4*a*c - b*b.
# * For the case c < 0, an antiderivative is
# (2*c*t+b)*sqrt(c*t^2+b*t+a)/(4*c) - (0.5*k)*arcsin((2*c*t+b)/sqrt(-q))/sqrt(-c)
A0 = self._p1 - self._p0
A1 = self._p0 - self._p1 * 2 + self._p2
if A1.magnitude_square() != 0:
c = 4 * A1.dot(A1)
b = 8 * A0.dot(A1)
a = 4 * A0.dot(A0)
q = 4 * a * c - b * b
two_cb = 2 * c + b
sum_cba = c + b + a
m0 = 0.25 / c
m1 = q / (8 * c**1.5)
return (m0 * (two_cb * sqrt(sum_cba) - b * sqrt(a)) +
m1 * (log(2 * sqrt(c * sum_cba) + two_cb) - log(2 * sqrt(c * a) + b)))
else:
return 2 * A0.magnitude()
##############################################
# Length of the curve obtained via line interpolation
if dt is None:
dt = self.LineInterpolationPrecision / (self.end_point - self.start_point).magnitude()
length = 0
t = 0
while t < 1:
t0 = t
t = min(t + dt, 1)
length += (self.point_at_t(t) - self.point_at_t(t0)).magnitude()
return length
##############################################
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def length_at_t(self, t, cache=False):
"""Compute the length of the curve at *t*."""
if cache: # lookup cache
if not hasattr(self, '_length_cache'):
self._length_cache = {}
length = self._length_cache.get(t, None)
if length is not None:
return length
length = self.split_at_t(t).length
if cache: # save
self._length_cache[t] = length
return length
##############################################
def t_at_length(self, length, precision=1e-6):
"""Compute t for the given length. Length must lie in [0, curve length] range]. """
if length < 0:
raise ValueError('Negative length')
if length == 0:
return 0
curve_length = self.length # Fixme: cache ?
if (curve_length - length) <= precision:
return 1
if length > curve_length:
raise ValueError('Out of length')
# Search t for length using dichotomy
# convergence rate :
# 10 iterations corresponds to curve length / 1024
# 16 / 65536
# start range
inf = 0
sup = 1
while True:
middle = (sup + inf) / 2
length_at_middle = self.length_at_t(middle, cache=True) # Fixme: out of memory, use LRU ???
# exit condition
if abs(length_at_middle - length) <= precision:
return middle
elif length_at_middle < length:
inf = middle
else: # length < length_at_middle
sup = middle
##############################################
def point_at_t(self, t):
# if 0 < t or 1 < t:
# raise ValueError()
u = 1 - t
return self._p0 * u**2 + self._p1 * 2 * t * u + self._p2 * t**2
##############################################
def split_at_t(self, t):
if t <= 0:
return None, self
elif t >= 1:
return self, None
else:
p01 = interpolate_two_points(self._p0, self._p1, t)
p12 = interpolate_two_points(self._p1, self._p2, t)
p = interpolate_two_points(p01, p12, t) # p = p012
# p = self.point_at_t(t)
return (QuadraticBezier2D(self._p0, p01, p), QuadraticBezier2D(p, p12, self._p2))
##############################################
def split_at_two_t(self, t1, t2):
if t1 == t2:
return self.point_at_t(t1)
if t2 < t1:
# Fixme: raise ?
t1, t2 = t2, t1
# curve = self
# if t1 > 0:
curve = self.split_at_t(t1)[1] # right
if t2 < 1:
# Interpolate the parameter at t2 in the new curve
t = (t2 - t1) / (1 - t1)
curve = curve.split_at_t(t)[0] # left
return curve
##############################################
@property
def tangent0(self):
return (self._p1 - self._p0).normalise()
##############################################
@property
def tangent1(self):
return (self._p2 - self._p1).normalise()
##############################################
@property
def normal0(self):
return self.tangent0.normal()
##############################################
@property
def tangent1(self):
return self.tangent1.normal()
##############################################
def tangent_at(self, t):
u = 1 - t
return (self._p1 - self._p0) * u + (self._p2 - self._p1) * t
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##############################################
def _map_to_line(self, line):
transformation = AffineTransformation.Rotation(-line.v.orientation)
# Fixme: use __vector_cls__
transformation *= AffineTransformation.Translation(Vector2D(0, -line.p.y))
# Fixme: better API ?
return self.clone().transform(transformation)
##############################################
def intersect_line(self, line):
"""Find the intersections of the curve with a line."""
# Algorithm:
# Apply a transformation to the curve that maps the line onto the X-axis.
# Then we only need to test the Y-values for a zero.
# t, p0, p1, p2, p3 = symbols('t p0 p1 p2 p3')
# u = 1 - t
# B = p0 * u**2 + p1 * 2*t*u + p2 * t**2
# collect(expand(B), t)
# solveset(B, t)
curve = self._map_to_line(line)
p0 = curve.p0.y
p1 = curve.p1.y
p2 = curve.p2.y
return quadratic_root(
p2 - 2*p1 + p0, # t**2
2*(p1 - p0), # t
p0,
)
### a = p0 - 2*p1 + p2 # t**2
### # b = 2*(-p0 + p1) # t
### b = -p0 + p1 # was / 2 !!!
### c = p0
###
### # discriminant = b**2 - 4*a*c
### # discriminant = 4 * (p1**2 - p0*p2)
### discriminant = p1**2 - p0*p2 # was / 4 !!!
###
### if discriminant < 0:
### return None
### elif discriminant == 0:
### return -b / a # dropped 2
### else:
### # dropped 2
### y1 = (-b - sqrt(discriminant)) / a
### y2 = (-b + sqrt(discriminant)) / a
### return y1, y2
##############################################
def fat_line(self):
line = Line2D.from_two_points(self._p0, self._p3)
d1 = line.distance_to_line(self._p1)
d_min = min(0, d1 / 2)
d_max = max(0, d1 / 2)
return (line, d_min, d_max)
##############################################
def non_parametric_curve(self, line):
"""Return the non-parametric Bezier curve D(ti, di(t)) where di(t) is the distance of the curve from
the baseline of the fat-line, ti is equally spaced in [0, 1].
"""
ts = np.arange(0, 1, 1/(self.number_of_points-1))
distances = [line.distance_to_line(p) for p in self.points]
points = [Vector2D(t, d) for t, f in zip(ts, distances)]
return self.__class__(*points)
####################################################################################################
_Sqrt3 = sqrt(3)
_Div18Sqrt3 = 18 / _Sqrt3
_OneThird = 1 / 3
_Sqrt3Div36 = _Sqrt3 / 36
class CubicBezier2D(Primitive4P, QuadraticBezier2D):
"""Class to implements 2D Cubic Bezier Curve."""
InterpolationPrecision = 0.001
#######################################
def __init__(self, p0, p1, p2, p3):
##############################################
def __repr__(self):
return self.__class__.__name__ + '({0._p0}, {0._p1}, {0._p2}, {0._p3})'.format(self)
##############################################
@property
def length(self):
return self.adaptive_length_approximation()
##############################################
def point_at_t(self, t):
# if 0 < t or 1 < t:
# raise ValueError()
return (self._p0 +
(self._p1 - self._p0) * 3 * t +
(self._p2 - self._p1 * 2 + self._p0) * 3 * t**2 +
(self._p3 - self._p2 * 3 + self._p1 * 3 - self._p0) * t**3)
##############################################
def _q_point(self):
"""Return the control point for mid-point quadratic approximation"""
return (self._p2 * 3 - self._p3 + self._p1 * 3 - self._p0) / 4
##############################################
def mid_point_quadratic_approximation(self):
"""Return the mid-point quadratic approximation"""
p1 = self._q_point()
return QuadraticBezier2D(self._p0, p1, self._p3)
##############################################
def split_at_t(self, t):
p01 = interpolate_two_points(self._p0, self._p1, t)
p12 = interpolate_two_points(self._p1, self._p2, t)
p23 = interpolate_two_points(self._p2, self._p3, t)
p012 = interpolate_two_points(p01, p12, t)
p123 = interpolate_two_points(p12, p23, t)
p = interpolate_two_points(p012, p123, t) # p = p0123
# p = self.point_at_t(t)
return (CubicBezier2D(self._p0, p01, p012, p), CubicBezier2D(p, p123, p23, self._p3))
##############################################
def _d01(self):
"""Return the distance between 0 and 1 quadratic aproximations"""
return (self._p3 - self._p2 * 3 + self._p1 * 3 - self._p0).magnitude() / 2
##############################################
def _t_max(self):
"""Return the split point for adaptive quadratic approximation"""
return (_Div18Sqrt3 * self.InterpolationPrecision / self._d01())**_OneThird
##############################################
def q_length(self):
"""Return the length of the mid-point quadratic approximation"""
return self.mid_point_quadratic_approximation().length
##############################################
def adaptive_length_approximation(self):
"""Return the length of the adaptive quadratic approximation"""
segments = []
segment = self
t_max = segment._t_max()
while t_max < 1:
split = segment.split_at_t(t_max)
segments.append(split[0])
segment = split[1]
t_max = segment._t_max()
segments.append(segment)
return sum([segment.q_length() for segment in segments])
##############################################
@property
def tangent1(self):
return (self._p3 - self._p2).normalise()
##############################################
def tangent_at(self, t):
u = 1 - t
return (self._p1 - self._p0) * u**2 + (self._p2 - self._p1) * 2 * t * u + (self._p3 - self._p2) * t**2
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##############################################
def intersect_line(self, line):
"""Find the intersections of the curve with a line."""
# Algorithm: same as for quadratic
# t, p0, p1, p2, p3, p4 = symbols('t p0 p1 p2 p3 p4')
# u = 1 - t
# B = p0 * u**3 +
# p1 * 3 * u**2 * t +
# p2 * 3 * u * t**2 +
# p3 * t**3
# B = p0 +
# (p1 - p0) * 3 * t +
# (p2 - p1 * 2 + p0) * 3 * t**2 +
# (p3 - p2 * 3 + p1 * 3 - p0) * t**3
# solveset(B, t)
curve = self._map_to_line(line)
p0 = curve.p0.y
p1 = curve.p1.y
p2 = curve.p2.y
p3 = curve.p3.y
return cubic_root(
p3 - 3*p2 + 3*p1 - p0,
3 * (p2 - p1 * 2 + p0),
3 * (p1 - p0),
p0,
)
##############################################
def fat_line(self):
line = Line2D.from_two_points(self._p0, self._p3)
d1 = line.distance_to_line(self._p1)
d2 = line.distance_to_line(self._p2)
if d1*d2 > 0:
factor = 3 / 4
else:
factor = 4 / 9
d_min = factor * min(0, d1, d2)
d_max = factor * max(0, d1, d2)
return (line, d_min, d_max)
##############################################
def _clipping_convex_hull(self):
line_03 = Line2D(self._p0, self._p3)
d1 = line_03.distance_to_line(self._p1)
d2 = line_03.distance_to_line(self._p2)
# Check if p1 and p2 are on the same side of the line [p0, p3]
if d1 * d2 < 0:
# p1 and p2 lie on different sides of [p0, p3].
# The hull is a quadrilateral and line [p0, p3] is not part of the hull.
# The top part includes p1, we will reverse it later if that is not the case.
hull = [
[self._p0, self._p1, self._p3], # top part
[self._p0, self._p2, self._p3] # bottom part
]
flip = d1 < 0
else:
# p1 and p2 lie on the same sides of [p0, p3]. The hull can be a triangle or a
# quadrilateral and line [p0, p3] is part of the hull. Check if the hull is a triangle
# or a quadrilateral. Also, if at least one of the distances for p1 or p2, from line
# [p0, p3] is zero then hull must at most have 3 vertices.
# Fixme: check cross product
y0, y1, y2, y3 = [p.y for p in self.points]
if abs(d1) < abs(d2):
pmax = p2;
# apex is y0 in this case, and the other apex point is y3
# vector yapex -> yapex2 or base vector which is already part of the hull
# V30xV10 * V10xV20
cross_product = ((y1 - y0) - (y3 - y0)/3) * (2*(y1 - y0) - (y2 - y0)) /3
else:
pmax = p1;
# apex is y3 and the other apex point is y0
# vector yapex -> yapex2 or base vector which is already part of the hull
# V32xV30 * V32xV31
cross_product = ((y3 - y2) - (y3 - y0)/3) * (2*(y3 - y2) - (y3 + y1)) /3
# Compare cross products of these vectors to determine if the point is in the triangle
# [p3, pmax, p0], or if it is a quadrilateral.
has_null_distance = d1 == 0 or d2 == 0 # Fixme: don't need to compute cross_product
if cross_product < 0 or has_null_distance:
# hull is a triangle
hull = [
[self._p0, pmax, self._p3], # top part is a triangle
[self._p0, self._p3], # bottom part is just an edge
]
else:
hull = [
[self._p0, self._p1, self._p2, self._p3], # top part is a quadrilateral
[self._p0, self._p3], # bottom part is just an edge
]
flip = d1 < 0 if d1 else d2 < 0
if flip:
hull.reverse()
return hull
##############################################
@staticmethod
def _clip_convex_hull(hull_top, hull_bottom, d_min, d_max) :
# Top /----
# / ---/
# / /
# d_max -------------------*---
# / / t_max
# t_min / /
# d_min -------*---------------
# / /
# / ----/ Bottom
# p0 /----
if (hull_top[0].y < d_min):
# Left of hull is below d_min,
# walk through the hull until it enters the region between d_min and d_max
return self._clip_convex_hull_part(hull_top, True, d_min);
elif (hull_bottom[0].y > d_max) :
# Left of hull is above d_max,
# walk through the hull until it enters the region between d_min and d_max
return self._clip_convex_hull_part(hull_bottom, False, d_max);
else :
# Left of hull is between d_min and d_max, no clipping possible
return hull_top[0].x; # Fixme: 0 ???
##############################################
@staticmethod
def _clip_convex_hull_part(part, top, threshold) :
"""Clip the bottom or top part of the convex hull.
*part* is a list of points, *top* is a boolean flag to indicate if it corresponds to the top
part, *threshold* is d_min if top part else d_max.
"""
# Walk on the edges
px = part[0].x;
py = part[0].y;
for i in range(1, len(part)):
qx = part[i].x;
qy = part[i].y;
if (qy >= threshold if top else qy <= threshold):
# compute a linear interpolation
# threshold = s * (t - px) + py
# t = (threshold - py) / s + px
return px + (threshold - py) * (qx - px) / (qy - py);
px = qx;
py = qy;
return None; # no intersection
##############################################
@staticmethod
def _instersect_curve(
curve1, curve2,
t_min=0, t_max=1,
u_min=0, u_max=1,
old_delta_t=1,
reverse=False, # flag to indicate that 1 <-> 2 when we store locations
recursion=0, # number of recursions
recursion_limit=32,
t_limit=0.8,
locations=[],
) :
# Code inspired from
# https://github.com/paperjs/paper.js/blob/master/src/path/Curve.js
# http://nbviewer.jupyter.org/gist/hkrish/0a128f21a5b9e5a7a914 The Bezier Clipping Algorithm
# https://gist.github.com/hkrish/5ef0f2da7f9882341ee5 hkrish/bezclip_manual.py
# Note:
# see https://github.com/paperjs/paper.js/issues/565
# It was determined that more than 20 recursions are needed sometimes, depending on the
# delta_t threshold values further below when determining which curve converges the
# least. He also recommended a threshold of 0.5 instead of the initial 0.8
if recursion > recursion_limit:
return
tolerance = 1e-5
epsilon = 1e-10
# t_min_new = 0.
# t_max_new = 0.
# delta_t = 0.
# NOTE: the recursion threshold of 4 is needed to prevent this issue from occurring:
# https://github.com/paperjs/paper.js/issues/571
# when two curves share an end point
if curve1.p0.x == curve1.p3.x and u_max - u_min <= epsilon and recursion > 4:
# The fat-line of curve1 has converged to a point, the clipping is not reliable.
# Return the value we have even though we will miss the precision.
t_max_new = t_min_new = (t_max + t_min) / 2
delta_t = 0
else :
# Compute the fat-line for curve1:
# a baseline and two offsets which completely encloses the curve
fatline, d_min, d_max = curve1.fat_line()
# Calculate a non-parametric bezier curve D(ti, di(t)) where di(t) is the distance of curve2 from
# the baseline, ti is equally spaced in [0, 1]
non_parametric_curve = curve2.non_parametric_curve(fatline)
# Get the top and bottom parts of the convex-hull
top, bottom = non_parametric_curve._clip_convex_hull()
# Clip the convex-hull with d_min and d_max
t_min_clip = self.clip_convex_hull(top, bottom, d_min, d_max);
top.reverse()
bottom.reverse()
t_max_clip = clipConvexHull(top, bottom, d_min, d_max);
# No intersections if one of the t values is None
if t_min_clip is None or t_max_clip is None:
return
# Clip curve2 with the fat-line for curve1
curve2 = curve2.split_at_two_t(t_min_clip, t_max_clip)
delta_t = t_max_clip - t_min_clip
# t_min and t_max are within the range [0, 1]
# We need to project it to the original parameter range
t_min_new = t_max * t_min_clip + t_min * (1 - t_min_clip)
t_max_new = t_max * t_max_clip + t_min * (1 - t_max_clip)
delta_t_new = t_max_new - t_min_new
delta_u = u_max - u_min
# Check if we need to subdivide the curves
if old_delta_t > t_limit and delta_t > t_limit:
# Subdivide the curve which has converged the least.
args = (delta_t, not reverse, recursion+1, recursion_limit, t_limit, locations)
if delta_u < delta_t_new: # curve2 < curve1
parts = curve1.split_at_t(0.5)
t = t_min_new + delta_t_new / 2
self._intersect_curve(curve2, parts[0], u_min, u_max, t_min_new, t, *args)
self._intersect_curve(curve2, parts[1], u_min, u_max, t, t_max_new, *args)
else :
parts = curve2.split_at_t(0.5)
t = u_min + delta_u / 2
self._intersect_curve(parts[0], curve1, u_min, t, t_min_new, t_max_new, *args)
self._intersect_curve(parts[1], curve1, t, u_max, t_min_new, t_max_new, *args)
elif max(delta_u, delta_t_new) < tolerance:
# We have isolated the intersection with sufficient precision
t1 = t_min_new + delta_t_new / 2
t2 = u_min + delta_u / 2
if reverse:
t1, t2 = t2, t1
p1 = curve1.point_at_t(t1)
p2 = curve2.point_at_t(t2)
locations.append([t1, point1, t2, point2])
else:
args = (delta_t, not reverse, recursion+1, recursion_limit, t_limit)
self._intersect_curve(curve2, curve1, locations, u_min, u_max, t_min_new, t_max_new, *args)
##############################################
def is_flat_enough(self, flatness):
"""Determines if a curve is sufficiently flat, meaning it appears as a straight line and has
curve-time that is enough linear, as specified by the given *flatness* parameter.
*flatness* is the maximum error allowed for the straight line to deviate from the curve.
"""
# Reference:
# Kaspar Fischer and Roger Willcocks http://hcklbrrfnn.files.wordpress.com/2012/08/bez.pdf
# PostScript Language Reference. Addison- Wesley, third edition, 1999
# We define the flatness of the curve as the argmax of the distance from the curve to the
# line passing by the start and stop point.
#
# flatness = argmax(d(t)) for t in [0, 1] where d(t) = | B(t) - L(t) |
#
# L = (1-t)*P0 + t*P1
#
# Let
# u = 3*P1 - 2*P0 - P3
# v = 3*P2 - P0 - 2*P3
#
# d(t) = (1-t)**2 * t * (3*P1 - 2*P0 - P3) + (1-t) * t**2 * (3*P2 - P0 - 2*P3)
# = (1-t)**2 * t * u + (1-t) * t**2 * v
#
# d(t)**2 = (1 - t)**2 * t**2 * (((1 - t)*ux + t*vx)**2 + ((1 - t)*uy + t*vy)**2
#
# argmax((1 - t)**2 * t**2) = 1/16
# argmax((1 - t)*a + t*b) = argmax(a, b)
#
# flatness**2 = argmax(d(t)**2) <= 1/16 * (argmax(ux**2, vx**2) + argmax(uy**2, vy**2))
#
# argmax(ux**2, vx**2) + argmax(uy**2, vy**2) is thus an upper bound of 16 * flatness**2
# x0, y0 = list(self._p0)
# x1, y1 = list(self._p1)
# x2, y2 = list(self._p2)
# x3, y3 = list(self._p3)
# ux = 3*x1 - 2*x0 - x3
# uy = 3*y1 - 2*y0 - y3
# vx = 3*x2 - 2*x3 - x0
# vy = 3*y2 - 2*y3 - y0
u = 3*P1 - 2*P0 - P3
v = 3*P2 - 2*P3 - P0
return max(u.x**2, v.x**2) + max(u.y**2, v.y**2) <= 16 * flatness**2
##############################################
@property
def area(self):
"""Compute the area delimited by the curve and the segment across the start and stop point."""
# Reference: http://objectmix.com/graphics/133553-area-closed-bezier-curve.html BUT DEAD LINK
# Proof using divergence theorem ???
# Fixme: any proof !
x0, y0 = list(self._p0)
x1, y1 = list(self._p1)
x2, y2 = list(self._p2)
x3, y3 = list(self._p3)
return (3 * ((y3 - y0) * (x1 + x2) - (x3 - x0) * (y1 + y2)
+ y1 * (x0 - x2) - x1 * (y0 - y2)
+ y3 * (x2 + x0 / 3) - x3 * (y2 + y0 / 3)) / 20)