665 lines
26 KiB
Python
665 lines
26 KiB
Python
from sympy.core.numbers import (Float, Rational, oo, pi)
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from sympy.core.singleton import S
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from sympy.core.symbol import (Symbol, symbols)
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from sympy.functions.elementary.complexes import Abs
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from sympy.functions.elementary.miscellaneous import sqrt
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from sympy.functions.elementary.trigonometric import (acos, cos, sin)
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from sympy.functions.elementary.trigonometric import tan
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from sympy.geometry import (Circle, Ellipse, GeometryError, Point, Point2D,
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Polygon, Ray, RegularPolygon, Segment, Triangle,
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are_similar, convex_hull, intersection, Line, Ray2D)
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from sympy.testing.pytest import raises, slow, warns
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from sympy.core.random import verify_numerically
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from sympy.geometry.polygon import rad, deg
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from sympy.integrals.integrals import integrate
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def feq(a, b):
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"""Test if two floating point values are 'equal'."""
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t_float = Float("1.0E-10")
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return -t_float < a - b < t_float
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@slow
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def test_polygon():
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x = Symbol('x', real=True)
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y = Symbol('y', real=True)
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q = Symbol('q', real=True)
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u = Symbol('u', real=True)
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v = Symbol('v', real=True)
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w = Symbol('w', real=True)
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x1 = Symbol('x1', real=True)
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half = S.Half
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a, b, c = Point(0, 0), Point(2, 0), Point(3, 3)
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t = Triangle(a, b, c)
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assert Polygon(Point(0, 0)) == Point(0, 0)
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assert Polygon(a, Point(1, 0), b, c) == t
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assert Polygon(Point(1, 0), b, c, a) == t
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assert Polygon(b, c, a, Point(1, 0)) == t
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# 2 "remove folded" tests
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assert Polygon(a, Point(3, 0), b, c) == t
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assert Polygon(a, b, Point(3, -1), b, c) == t
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# remove multiple collinear points
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assert Polygon(Point(-4, 15), Point(-11, 15), Point(-15, 15),
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Point(-15, 33/5), Point(-15, -87/10), Point(-15, -15),
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Point(-42/5, -15), Point(-2, -15), Point(7, -15), Point(15, -15),
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Point(15, -3), Point(15, 10), Point(15, 15)) == \
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Polygon(Point(-15, -15), Point(15, -15), Point(15, 15), Point(-15, 15))
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p1 = Polygon(
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Point(0, 0), Point(3, -1),
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Point(6, 0), Point(4, 5),
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Point(2, 3), Point(0, 3))
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p2 = Polygon(
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Point(6, 0), Point(3, -1),
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Point(0, 0), Point(0, 3),
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Point(2, 3), Point(4, 5))
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p3 = Polygon(
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Point(0, 0), Point(3, 0),
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Point(5, 2), Point(4, 4))
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p4 = Polygon(
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Point(0, 0), Point(4, 4),
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Point(5, 2), Point(3, 0))
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p5 = Polygon(
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Point(0, 0), Point(4, 4),
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Point(0, 4))
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p6 = Polygon(
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Point(-11, 1), Point(-9, 6.6),
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Point(-4, -3), Point(-8.4, -8.7))
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p7 = Polygon(
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Point(x, y), Point(q, u),
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Point(v, w))
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p8 = Polygon(
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Point(x, y), Point(v, w),
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Point(q, u))
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p9 = Polygon(
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Point(0, 0), Point(4, 4),
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Point(3, 0), Point(5, 2))
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p10 = Polygon(
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Point(0, 2), Point(2, 2),
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Point(0, 0), Point(2, 0))
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p11 = Polygon(Point(0, 0), 1, n=3)
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p12 = Polygon(Point(0, 0), 1, 0, n=3)
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r = Ray(Point(-9, 6.6), Point(-9, 5.5))
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#
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# General polygon
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#
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assert p1 == p2
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assert len(p1.args) == 6
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assert len(p1.sides) == 6
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assert p1.perimeter == 5 + 2*sqrt(10) + sqrt(29) + sqrt(8)
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assert p1.area == 22
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assert not p1.is_convex()
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assert Polygon((-1, 1), (2, -1), (2, 1), (-1, -1), (3, 0)
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).is_convex() is False
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# ensure convex for both CW and CCW point specification
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assert p3.is_convex()
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assert p4.is_convex()
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dict5 = p5.angles
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assert dict5[Point(0, 0)] == pi / 4
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assert dict5[Point(0, 4)] == pi / 2
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assert p5.encloses_point(Point(x, y)) is None
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assert p5.encloses_point(Point(1, 3))
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assert p5.encloses_point(Point(0, 0)) is False
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assert p5.encloses_point(Point(4, 0)) is False
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assert p1.encloses(Circle(Point(2.5, 2.5), 5)) is False
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assert p1.encloses(Ellipse(Point(2.5, 2), 5, 6)) is False
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assert p5.plot_interval('x') == [x, 0, 1]
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assert p5.distance(
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Polygon(Point(10, 10), Point(14, 14), Point(10, 14))) == 6 * sqrt(2)
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assert p5.distance(
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Polygon(Point(1, 8), Point(5, 8), Point(8, 12), Point(1, 12))) == 4
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with warns(UserWarning, \
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match="Polygons may intersect producing erroneous output"):
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Polygon(Point(0, 0), Point(1, 0), Point(1, 1)).distance(
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Polygon(Point(0, 0), Point(0, 1), Point(1, 1)))
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assert hash(p5) == hash(Polygon(Point(0, 0), Point(4, 4), Point(0, 4)))
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assert hash(p1) == hash(p2)
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assert hash(p7) == hash(p8)
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assert hash(p3) != hash(p9)
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assert p5 == Polygon(Point(4, 4), Point(0, 4), Point(0, 0))
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assert Polygon(Point(4, 4), Point(0, 4), Point(0, 0)) in p5
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assert p5 != Point(0, 4)
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assert Point(0, 1) in p5
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assert p5.arbitrary_point('t').subs(Symbol('t', real=True), 0) == \
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Point(0, 0)
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raises(ValueError, lambda: Polygon(
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Point(x, 0), Point(0, y), Point(x, y)).arbitrary_point('x'))
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assert p6.intersection(r) == [Point(-9, Rational(-84, 13)), Point(-9, Rational(33, 5))]
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assert p10.area == 0
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assert p11 == RegularPolygon(Point(0, 0), 1, 3, 0)
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assert p11 == p12
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assert p11.vertices[0] == Point(1, 0)
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assert p11.args[0] == Point(0, 0)
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p11.spin(pi/2)
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assert p11.vertices[0] == Point(0, 1)
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#
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# Regular polygon
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#
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p1 = RegularPolygon(Point(0, 0), 10, 5)
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p2 = RegularPolygon(Point(0, 0), 5, 5)
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raises(GeometryError, lambda: RegularPolygon(Point(0, 0), Point(0,
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1), Point(1, 1)))
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raises(GeometryError, lambda: RegularPolygon(Point(0, 0), 1, 2))
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raises(ValueError, lambda: RegularPolygon(Point(0, 0), 1, 2.5))
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assert p1 != p2
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assert p1.interior_angle == pi*Rational(3, 5)
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assert p1.exterior_angle == pi*Rational(2, 5)
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assert p2.apothem == 5*cos(pi/5)
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assert p2.circumcenter == p1.circumcenter == Point(0, 0)
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assert p1.circumradius == p1.radius == 10
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assert p2.circumcircle == Circle(Point(0, 0), 5)
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assert p2.incircle == Circle(Point(0, 0), p2.apothem)
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assert p2.inradius == p2.apothem == (5 * (1 + sqrt(5)) / 4)
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p2.spin(pi / 10)
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dict1 = p2.angles
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assert dict1[Point(0, 5)] == 3 * pi / 5
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assert p1.is_convex()
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assert p1.rotation == 0
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assert p1.encloses_point(Point(0, 0))
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assert p1.encloses_point(Point(11, 0)) is False
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assert p2.encloses_point(Point(0, 4.9))
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p1.spin(pi/3)
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assert p1.rotation == pi/3
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assert p1.vertices[0] == Point(5, 5*sqrt(3))
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for var in p1.args:
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if isinstance(var, Point):
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assert var == Point(0, 0)
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else:
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assert var in (5, 10, pi / 3)
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assert p1 != Point(0, 0)
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assert p1 != p5
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# while spin works in place (notice that rotation is 2pi/3 below)
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# rotate returns a new object
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p1_old = p1
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assert p1.rotate(pi/3) == RegularPolygon(Point(0, 0), 10, 5, pi*Rational(2, 3))
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assert p1 == p1_old
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assert p1.area == (-250*sqrt(5) + 1250)/(4*tan(pi/5))
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assert p1.length == 20*sqrt(-sqrt(5)/8 + Rational(5, 8))
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assert p1.scale(2, 2) == \
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RegularPolygon(p1.center, p1.radius*2, p1._n, p1.rotation)
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assert RegularPolygon((0, 0), 1, 4).scale(2, 3) == \
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Polygon(Point(2, 0), Point(0, 3), Point(-2, 0), Point(0, -3))
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assert repr(p1) == str(p1)
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#
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# Angles
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#
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angles = p4.angles
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assert feq(angles[Point(0, 0)].evalf(), Float("0.7853981633974483"))
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assert feq(angles[Point(4, 4)].evalf(), Float("1.2490457723982544"))
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assert feq(angles[Point(5, 2)].evalf(), Float("1.8925468811915388"))
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assert feq(angles[Point(3, 0)].evalf(), Float("2.3561944901923449"))
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angles = p3.angles
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assert feq(angles[Point(0, 0)].evalf(), Float("0.7853981633974483"))
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assert feq(angles[Point(4, 4)].evalf(), Float("1.2490457723982544"))
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assert feq(angles[Point(5, 2)].evalf(), Float("1.8925468811915388"))
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assert feq(angles[Point(3, 0)].evalf(), Float("2.3561944901923449"))
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#
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# Triangle
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#
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p1 = Point(0, 0)
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p2 = Point(5, 0)
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p3 = Point(0, 5)
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t1 = Triangle(p1, p2, p3)
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t2 = Triangle(p1, p2, Point(Rational(5, 2), sqrt(Rational(75, 4))))
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t3 = Triangle(p1, Point(x1, 0), Point(0, x1))
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s1 = t1.sides
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assert Triangle(p1, p2, p1) == Polygon(p1, p2, p1) == Segment(p1, p2)
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raises(GeometryError, lambda: Triangle(Point(0, 0)))
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# Basic stuff
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assert Triangle(p1, p1, p1) == p1
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assert Triangle(p2, p2*2, p2*3) == Segment(p2, p2*3)
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assert t1.area == Rational(25, 2)
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assert t1.is_right()
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assert t2.is_right() is False
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assert t3.is_right()
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assert p1 in t1
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assert t1.sides[0] in t1
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assert Segment((0, 0), (1, 0)) in t1
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assert Point(5, 5) not in t2
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assert t1.is_convex()
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assert feq(t1.angles[p1].evalf(), pi.evalf()/2)
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assert t1.is_equilateral() is False
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assert t2.is_equilateral()
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assert t3.is_equilateral() is False
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assert are_similar(t1, t2) is False
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assert are_similar(t1, t3)
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assert are_similar(t2, t3) is False
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assert t1.is_similar(Point(0, 0)) is False
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assert t1.is_similar(t2) is False
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# Bisectors
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bisectors = t1.bisectors()
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assert bisectors[p1] == Segment(
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p1, Point(Rational(5, 2), Rational(5, 2)))
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assert t2.bisectors()[p2] == Segment(
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Point(5, 0), Point(Rational(5, 4), 5*sqrt(3)/4))
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p4 = Point(0, x1)
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assert t3.bisectors()[p4] == Segment(p4, Point(x1*(sqrt(2) - 1), 0))
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ic = (250 - 125*sqrt(2))/50
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assert t1.incenter == Point(ic, ic)
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# Inradius
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assert t1.inradius == t1.incircle.radius == 5 - 5*sqrt(2)/2
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assert t2.inradius == t2.incircle.radius == 5*sqrt(3)/6
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assert t3.inradius == t3.incircle.radius == x1**2/((2 + sqrt(2))*Abs(x1))
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# Exradius
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assert t1.exradii[t1.sides[2]] == 5*sqrt(2)/2
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# Excenters
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assert t1.excenters[t1.sides[2]] == Point2D(25*sqrt(2), -5*sqrt(2)/2)
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# Circumcircle
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assert t1.circumcircle.center == Point(2.5, 2.5)
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# Medians + Centroid
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m = t1.medians
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assert t1.centroid == Point(Rational(5, 3), Rational(5, 3))
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assert m[p1] == Segment(p1, Point(Rational(5, 2), Rational(5, 2)))
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assert t3.medians[p1] == Segment(p1, Point(x1/2, x1/2))
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assert intersection(m[p1], m[p2], m[p3]) == [t1.centroid]
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assert t1.medial == Triangle(Point(2.5, 0), Point(0, 2.5), Point(2.5, 2.5))
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# Nine-point circle
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assert t1.nine_point_circle == Circle(Point(2.5, 0),
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Point(0, 2.5), Point(2.5, 2.5))
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assert t1.nine_point_circle == Circle(Point(0, 0),
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Point(0, 2.5), Point(2.5, 2.5))
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# Perpendicular
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altitudes = t1.altitudes
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assert altitudes[p1] == Segment(p1, Point(Rational(5, 2), Rational(5, 2)))
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assert altitudes[p2].equals(s1[0])
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assert altitudes[p3] == s1[2]
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assert t1.orthocenter == p1
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t = S('''Triangle(
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Point(100080156402737/5000000000000, 79782624633431/500000000000),
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Point(39223884078253/2000000000000, 156345163124289/1000000000000),
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Point(31241359188437/1250000000000, 338338270939941/1000000000000000))''')
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assert t.orthocenter == S('''Point(-780660869050599840216997'''
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'''79471538701955848721853/80368430960602242240789074233100000000000000,'''
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'''20151573611150265741278060334545897615974257/16073686192120448448157'''
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'''8148466200000000000)''')
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# Ensure
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assert len(intersection(*bisectors.values())) == 1
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assert len(intersection(*altitudes.values())) == 1
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assert len(intersection(*m.values())) == 1
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# Distance
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p1 = Polygon(
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Point(0, 0), Point(1, 0),
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Point(1, 1), Point(0, 1))
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p2 = Polygon(
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Point(0, Rational(5)/4), Point(1, Rational(5)/4),
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Point(1, Rational(9)/4), Point(0, Rational(9)/4))
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p3 = Polygon(
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Point(1, 2), Point(2, 2),
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Point(2, 1))
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p4 = Polygon(
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Point(1, 1), Point(Rational(6)/5, 1),
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Point(1, Rational(6)/5))
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pt1 = Point(half, half)
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pt2 = Point(1, 1)
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'''Polygon to Point'''
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assert p1.distance(pt1) == half
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assert p1.distance(pt2) == 0
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assert p2.distance(pt1) == Rational(3)/4
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assert p3.distance(pt2) == sqrt(2)/2
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'''Polygon to Polygon'''
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# p1.distance(p2) emits a warning
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with warns(UserWarning, \
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match="Polygons may intersect producing erroneous output"):
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assert p1.distance(p2) == half/2
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assert p1.distance(p3) == sqrt(2)/2
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# p3.distance(p4) emits a warning
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with warns(UserWarning, \
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match="Polygons may intersect producing erroneous output"):
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assert p3.distance(p4) == (sqrt(2)/2 - sqrt(Rational(2)/25)/2)
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def test_convex_hull():
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p = [Point(-5, -1), Point(-2, 1), Point(-2, -1), Point(-1, -3), \
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Point(0, 0), Point(1, 1), Point(2, 2), Point(2, -1), Point(3, 1), \
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Point(4, -1), Point(6, 2)]
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ch = Polygon(p[0], p[3], p[9], p[10], p[6], p[1])
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#test handling of duplicate points
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p.append(p[3])
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#more than 3 collinear points
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another_p = [Point(-45, -85), Point(-45, 85), Point(-45, 26), \
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Point(-45, -24)]
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ch2 = Segment(another_p[0], another_p[1])
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assert convex_hull(*another_p) == ch2
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assert convex_hull(*p) == ch
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assert convex_hull(p[0]) == p[0]
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assert convex_hull(p[0], p[1]) == Segment(p[0], p[1])
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# no unique points
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assert convex_hull(*[p[-1]]*3) == p[-1]
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# collection of items
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assert convex_hull(*[Point(0, 0), \
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Segment(Point(1, 0), Point(1, 1)), \
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RegularPolygon(Point(2, 0), 2, 4)]) == \
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Polygon(Point(0, 0), Point(2, -2), Point(4, 0), Point(2, 2))
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def test_encloses():
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# square with a dimpled left side
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s = Polygon(Point(0, 0), Point(1, 0), Point(1, 1), Point(0, 1), \
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Point(S.Half, S.Half))
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# the following is True if the polygon isn't treated as closing on itself
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assert s.encloses(Point(0, S.Half)) is False
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assert s.encloses(Point(S.Half, S.Half)) is False # it's a vertex
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assert s.encloses(Point(Rational(3, 4), S.Half)) is True
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def test_triangle_kwargs():
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assert Triangle(sss=(3, 4, 5)) == \
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Triangle(Point(0, 0), Point(3, 0), Point(3, 4))
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assert Triangle(asa=(30, 2, 30)) == \
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Triangle(Point(0, 0), Point(2, 0), Point(1, sqrt(3)/3))
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assert Triangle(sas=(1, 45, 2)) == \
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Triangle(Point(0, 0), Point(2, 0), Point(sqrt(2)/2, sqrt(2)/2))
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assert Triangle(sss=(1, 2, 5)) is None
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assert deg(rad(180)) == 180
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def test_transform():
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pts = [Point(0, 0), Point(S.Half, Rational(1, 4)), Point(1, 1)]
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pts_out = [Point(-4, -10), Point(-3, Rational(-37, 4)), Point(-2, -7)]
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assert Triangle(*pts).scale(2, 3, (4, 5)) == Triangle(*pts_out)
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assert RegularPolygon((0, 0), 1, 4).scale(2, 3, (4, 5)) == \
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Polygon(Point(-2, -10), Point(-4, -7), Point(-6, -10), Point(-4, -13))
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# Checks for symmetric scaling
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assert RegularPolygon((0, 0), 1, 4).scale(2, 2) == \
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RegularPolygon(Point2D(0, 0), 2, 4, 0)
|
|
|
|
def test_reflect():
|
|
x = Symbol('x', real=True)
|
|
y = Symbol('y', real=True)
|
|
b = Symbol('b')
|
|
m = Symbol('m')
|
|
l = Line((0, b), slope=m)
|
|
p = Point(x, y)
|
|
r = p.reflect(l)
|
|
dp = l.perpendicular_segment(p).length
|
|
dr = l.perpendicular_segment(r).length
|
|
|
|
assert verify_numerically(dp, dr)
|
|
|
|
assert Polygon((1, 0), (2, 0), (2, 2)).reflect(Line((3, 0), slope=oo)) \
|
|
== Triangle(Point(5, 0), Point(4, 0), Point(4, 2))
|
|
assert Polygon((1, 0), (2, 0), (2, 2)).reflect(Line((0, 3), slope=oo)) \
|
|
== Triangle(Point(-1, 0), Point(-2, 0), Point(-2, 2))
|
|
assert Polygon((1, 0), (2, 0), (2, 2)).reflect(Line((0, 3), slope=0)) \
|
|
== Triangle(Point(1, 6), Point(2, 6), Point(2, 4))
|
|
assert Polygon((1, 0), (2, 0), (2, 2)).reflect(Line((3, 0), slope=0)) \
|
|
== Triangle(Point(1, 0), Point(2, 0), Point(2, -2))
|
|
|
|
def test_bisectors():
|
|
p1, p2, p3 = Point(0, 0), Point(1, 0), Point(0, 1)
|
|
p = Polygon(Point(0, 0), Point(2, 0), Point(1, 1), Point(0, 3))
|
|
q = Polygon(Point(1, 0), Point(2, 0), Point(3, 3), Point(-1, 5))
|
|
poly = Polygon(Point(3, 4), Point(0, 0), Point(8, 7), Point(-1, 1), Point(19, -19))
|
|
t = Triangle(p1, p2, p3)
|
|
assert t.bisectors()[p2] == Segment(Point(1, 0), Point(0, sqrt(2) - 1))
|
|
assert p.bisectors()[Point2D(0, 3)] == Ray2D(Point2D(0, 3), \
|
|
Point2D(sin(acos(2*sqrt(5)/5)/2), 3 - cos(acos(2*sqrt(5)/5)/2)))
|
|
assert q.bisectors()[Point2D(-1, 5)] == \
|
|
Ray2D(Point2D(-1, 5), Point2D(-1 + sqrt(29)*(5*sin(acos(9*sqrt(145)/145)/2) + \
|
|
2*cos(acos(9*sqrt(145)/145)/2))/29, sqrt(29)*(-5*cos(acos(9*sqrt(145)/145)/2) + \
|
|
2*sin(acos(9*sqrt(145)/145)/2))/29 + 5))
|
|
assert poly.bisectors()[Point2D(-1, 1)] == Ray2D(Point2D(-1, 1), \
|
|
Point2D(-1 + sin(acos(sqrt(26)/26)/2 + pi/4), 1 - sin(-acos(sqrt(26)/26)/2 + pi/4)))
|
|
|
|
def test_incenter():
|
|
assert Triangle(Point(0, 0), Point(1, 0), Point(0, 1)).incenter \
|
|
== Point(1 - sqrt(2)/2, 1 - sqrt(2)/2)
|
|
|
|
def test_inradius():
|
|
assert Triangle(Point(0, 0), Point(4, 0), Point(0, 3)).inradius == 1
|
|
|
|
def test_incircle():
|
|
assert Triangle(Point(0, 0), Point(2, 0), Point(0, 2)).incircle \
|
|
== Circle(Point(2 - sqrt(2), 2 - sqrt(2)), 2 - sqrt(2))
|
|
|
|
def test_exradii():
|
|
t = Triangle(Point(0, 0), Point(6, 0), Point(0, 2))
|
|
assert t.exradii[t.sides[2]] == (-2 + sqrt(10))
|
|
|
|
def test_medians():
|
|
t = Triangle(Point(0, 0), Point(1, 0), Point(0, 1))
|
|
assert t.medians[Point(0, 0)] == Segment(Point(0, 0), Point(S.Half, S.Half))
|
|
|
|
def test_medial():
|
|
assert Triangle(Point(0, 0), Point(1, 0), Point(0, 1)).medial \
|
|
== Triangle(Point(S.Half, 0), Point(S.Half, S.Half), Point(0, S.Half))
|
|
|
|
def test_nine_point_circle():
|
|
assert Triangle(Point(0, 0), Point(1, 0), Point(0, 1)).nine_point_circle \
|
|
== Circle(Point2D(Rational(1, 4), Rational(1, 4)), sqrt(2)/4)
|
|
|
|
def test_eulerline():
|
|
assert Triangle(Point(0, 0), Point(1, 0), Point(0, 1)).eulerline \
|
|
== Line(Point2D(0, 0), Point2D(S.Half, S.Half))
|
|
assert Triangle(Point(0, 0), Point(10, 0), Point(5, 5*sqrt(3))).eulerline \
|
|
== Point2D(5, 5*sqrt(3)/3)
|
|
assert Triangle(Point(4, -6), Point(4, -1), Point(-3, 3)).eulerline \
|
|
== Line(Point2D(Rational(64, 7), 3), Point2D(Rational(-29, 14), Rational(-7, 2)))
|
|
|
|
def test_intersection():
|
|
poly1 = Triangle(Point(0, 0), Point(1, 0), Point(0, 1))
|
|
poly2 = Polygon(Point(0, 1), Point(-5, 0),
|
|
Point(0, -4), Point(0, Rational(1, 5)),
|
|
Point(S.Half, -0.1), Point(1, 0), Point(0, 1))
|
|
|
|
assert poly1.intersection(poly2) == [Point2D(Rational(1, 3), 0),
|
|
Segment(Point(0, Rational(1, 5)), Point(0, 0)),
|
|
Segment(Point(1, 0), Point(0, 1))]
|
|
assert poly2.intersection(poly1) == [Point(Rational(1, 3), 0),
|
|
Segment(Point(0, 0), Point(0, Rational(1, 5))),
|
|
Segment(Point(1, 0), Point(0, 1))]
|
|
assert poly1.intersection(Point(0, 0)) == [Point(0, 0)]
|
|
assert poly1.intersection(Point(-12, -43)) == []
|
|
assert poly2.intersection(Line((-12, 0), (12, 0))) == [Point(-5, 0),
|
|
Point(0, 0), Point(Rational(1, 3), 0), Point(1, 0)]
|
|
assert poly2.intersection(Line((-12, 12), (12, 12))) == []
|
|
assert poly2.intersection(Ray((-3, 4), (1, 0))) == [Segment(Point(1, 0),
|
|
Point(0, 1))]
|
|
assert poly2.intersection(Circle((0, -1), 1)) == [Point(0, -2),
|
|
Point(0, 0)]
|
|
assert poly1.intersection(poly1) == [Segment(Point(0, 0), Point(1, 0)),
|
|
Segment(Point(0, 1), Point(0, 0)), Segment(Point(1, 0), Point(0, 1))]
|
|
assert poly2.intersection(poly2) == [Segment(Point(-5, 0), Point(0, -4)),
|
|
Segment(Point(0, -4), Point(0, Rational(1, 5))),
|
|
Segment(Point(0, Rational(1, 5)), Point(S.Half, Rational(-1, 10))),
|
|
Segment(Point(0, 1), Point(-5, 0)),
|
|
Segment(Point(S.Half, Rational(-1, 10)), Point(1, 0)),
|
|
Segment(Point(1, 0), Point(0, 1))]
|
|
assert poly2.intersection(Triangle(Point(0, 1), Point(1, 0), Point(-1, 1))) \
|
|
== [Point(Rational(-5, 7), Rational(6, 7)), Segment(Point2D(0, 1), Point(1, 0))]
|
|
assert poly1.intersection(RegularPolygon((-12, -15), 3, 3)) == []
|
|
|
|
|
|
def test_parameter_value():
|
|
t = Symbol('t')
|
|
sq = Polygon((0, 0), (0, 1), (1, 1), (1, 0))
|
|
assert sq.parameter_value((0.5, 1), t) == {t: Rational(3, 8)}
|
|
q = Polygon((0, 0), (2, 1), (2, 4), (4, 0))
|
|
assert q.parameter_value((4, 0), t) == {t: -6 + 3*sqrt(5)} # ~= 0.708
|
|
|
|
raises(ValueError, lambda: sq.parameter_value((5, 6), t))
|
|
raises(ValueError, lambda: sq.parameter_value(Circle(Point(0, 0), 1), t))
|
|
|
|
|
|
def test_issue_12966():
|
|
poly = Polygon(Point(0, 0), Point(0, 10), Point(5, 10), Point(5, 5),
|
|
Point(10, 5), Point(10, 0))
|
|
t = Symbol('t')
|
|
pt = poly.arbitrary_point(t)
|
|
DELTA = 5/poly.perimeter
|
|
assert [pt.subs(t, DELTA*i) for i in range(int(1/DELTA))] == [
|
|
Point(0, 0), Point(0, 5), Point(0, 10), Point(5, 10),
|
|
Point(5, 5), Point(10, 5), Point(10, 0), Point(5, 0)]
|
|
|
|
|
|
def test_second_moment_of_area():
|
|
x, y = symbols('x, y')
|
|
# triangle
|
|
p1, p2, p3 = [(0, 0), (4, 0), (0, 2)]
|
|
p = (0, 0)
|
|
# equation of hypotenuse
|
|
eq_y = (1-x/4)*2
|
|
I_yy = integrate((x**2) * (integrate(1, (y, 0, eq_y))), (x, 0, 4))
|
|
I_xx = integrate(1 * (integrate(y**2, (y, 0, eq_y))), (x, 0, 4))
|
|
I_xy = integrate(x * (integrate(y, (y, 0, eq_y))), (x, 0, 4))
|
|
|
|
triangle = Polygon(p1, p2, p3)
|
|
|
|
assert (I_xx - triangle.second_moment_of_area(p)[0]) == 0
|
|
assert (I_yy - triangle.second_moment_of_area(p)[1]) == 0
|
|
assert (I_xy - triangle.second_moment_of_area(p)[2]) == 0
|
|
|
|
# rectangle
|
|
p1, p2, p3, p4=[(0, 0), (4, 0), (4, 2), (0, 2)]
|
|
I_yy = integrate((x**2) * integrate(1, (y, 0, 2)), (x, 0, 4))
|
|
I_xx = integrate(1 * integrate(y**2, (y, 0, 2)), (x, 0, 4))
|
|
I_xy = integrate(x * integrate(y, (y, 0, 2)), (x, 0, 4))
|
|
|
|
rectangle = Polygon(p1, p2, p3, p4)
|
|
|
|
assert (I_xx - rectangle.second_moment_of_area(p)[0]) == 0
|
|
assert (I_yy - rectangle.second_moment_of_area(p)[1]) == 0
|
|
assert (I_xy - rectangle.second_moment_of_area(p)[2]) == 0
|
|
|
|
|
|
r = RegularPolygon(Point(0, 0), 5, 3)
|
|
assert r.second_moment_of_area() == (1875*sqrt(3)/S(32), 1875*sqrt(3)/S(32), 0)
|
|
|
|
|
|
def test_first_moment():
|
|
a, b = symbols('a, b', positive=True)
|
|
# rectangle
|
|
p1 = Polygon((0, 0), (a, 0), (a, b), (0, b))
|
|
assert p1.first_moment_of_area() == (a*b**2/8, a**2*b/8)
|
|
assert p1.first_moment_of_area((a/3, b/4)) == (-3*a*b**2/32, -a**2*b/9)
|
|
|
|
p1 = Polygon((0, 0), (40, 0), (40, 30), (0, 30))
|
|
assert p1.first_moment_of_area() == (4500, 6000)
|
|
|
|
# triangle
|
|
p2 = Polygon((0, 0), (a, 0), (a/2, b))
|
|
assert p2.first_moment_of_area() == (4*a*b**2/81, a**2*b/24)
|
|
assert p2.first_moment_of_area((a/8, b/6)) == (-25*a*b**2/648, -5*a**2*b/768)
|
|
|
|
p2 = Polygon((0, 0), (12, 0), (12, 30))
|
|
assert p2.first_moment_of_area() == (S(1600)/3, -S(640)/3)
|
|
|
|
|
|
def test_section_modulus_and_polar_second_moment_of_area():
|
|
a, b = symbols('a, b', positive=True)
|
|
x, y = symbols('x, y')
|
|
rectangle = Polygon((0, b), (0, 0), (a, 0), (a, b))
|
|
assert rectangle.section_modulus(Point(x, y)) == (a*b**3/12/(-b/2 + y), a**3*b/12/(-a/2 + x))
|
|
assert rectangle.polar_second_moment_of_area() == a**3*b/12 + a*b**3/12
|
|
|
|
convex = RegularPolygon((0, 0), 1, 6)
|
|
assert convex.section_modulus() == (Rational(5, 8), sqrt(3)*Rational(5, 16))
|
|
assert convex.polar_second_moment_of_area() == 5*sqrt(3)/S(8)
|
|
|
|
concave = Polygon((0, 0), (1, 8), (3, 4), (4, 6), (7, 1))
|
|
assert concave.section_modulus() == (Rational(-6371, 429), Rational(-9778, 519))
|
|
assert concave.polar_second_moment_of_area() == Rational(-38669, 252)
|
|
|
|
|
|
def test_cut_section():
|
|
# concave polygon
|
|
p = Polygon((-1, -1), (1, Rational(5, 2)), (2, 1), (3, Rational(5, 2)), (4, 2), (5, 3), (-1, 3))
|
|
l = Line((0, 0), (Rational(9, 2), 3))
|
|
p1 = p.cut_section(l)[0]
|
|
p2 = p.cut_section(l)[1]
|
|
assert p1 == Polygon(
|
|
Point2D(Rational(-9, 13), Rational(-6, 13)), Point2D(1, Rational(5, 2)), Point2D(Rational(24, 13), Rational(16, 13)),
|
|
Point2D(Rational(12, 5), Rational(8, 5)), Point2D(3, Rational(5, 2)), Point2D(Rational(24, 7), Rational(16, 7)),
|
|
Point2D(Rational(9, 2), 3), Point2D(-1, 3), Point2D(-1, Rational(-2, 3)))
|
|
assert p2 == Polygon(Point2D(-1, -1), Point2D(Rational(-9, 13), Rational(-6, 13)), Point2D(Rational(24, 13), Rational(16, 13)),
|
|
Point2D(2, 1), Point2D(Rational(12, 5), Rational(8, 5)), Point2D(Rational(24, 7), Rational(16, 7)), Point2D(4, 2), Point2D(5, 3),
|
|
Point2D(Rational(9, 2), 3), Point2D(-1, Rational(-2, 3)))
|
|
|
|
# convex polygon
|
|
p = RegularPolygon(Point2D(0, 0), 6, 6)
|
|
s = p.cut_section(Line((0, 0), slope=1))
|
|
assert s[0] == Polygon(Point2D(-3*sqrt(3) + 9, -3*sqrt(3) + 9), Point2D(3, 3*sqrt(3)),
|
|
Point2D(-3, 3*sqrt(3)), Point2D(-6, 0), Point2D(-9 + 3*sqrt(3), -9 + 3*sqrt(3)))
|
|
assert s[1] == Polygon(Point2D(6, 0), Point2D(-3*sqrt(3) + 9, -3*sqrt(3) + 9),
|
|
Point2D(-9 + 3*sqrt(3), -9 + 3*sqrt(3)), Point2D(-3, -3*sqrt(3)), Point2D(3, -3*sqrt(3)))
|
|
|
|
# case where line does not intersects but coincides with the edge of polygon
|
|
a, b = 20, 10
|
|
t1, t2, t3, t4 = [(0, b), (0, 0), (a, 0), (a, b)]
|
|
p = Polygon(t1, t2, t3, t4)
|
|
p1, p2 = p.cut_section(Line((0, b), slope=0))
|
|
assert p1 == None
|
|
assert p2 == Polygon(Point2D(0, 10), Point2D(0, 0), Point2D(20, 0), Point2D(20, 10))
|
|
|
|
p3, p4 = p.cut_section(Line((0, 0), slope=0))
|
|
assert p3 == Polygon(Point2D(0, 10), Point2D(0, 0), Point2D(20, 0), Point2D(20, 10))
|
|
assert p4 == None
|
|
|
|
# case where the line does not intersect with a polygon at all
|
|
raises(ValueError, lambda: p.cut_section(Line((0, a), slope=0)))
|
|
|
|
def test_type_of_triangle():
|
|
# Isoceles triangle
|
|
p1 = Polygon(Point(0, 0), Point(5, 0), Point(2, 4))
|
|
assert p1.is_isosceles() == True
|
|
assert p1.is_scalene() == False
|
|
assert p1.is_equilateral() == False
|
|
|
|
# Scalene triangle
|
|
p2 = Polygon (Point(0, 0), Point(0, 2), Point(4, 0))
|
|
assert p2.is_isosceles() == False
|
|
assert p2.is_scalene() == True
|
|
assert p2.is_equilateral() == False
|
|
|
|
# Equilateral triagle
|
|
p3 = Polygon(Point(0, 0), Point(6, 0), Point(3, sqrt(27)))
|
|
assert p3.is_isosceles() == True
|
|
assert p3.is_scalene() == False
|
|
assert p3.is_equilateral() == True
|
|
|
|
def test_do_poly_distance():
|
|
# Non-intersecting polygons
|
|
square1 = Polygon (Point(0, 0), Point(0, 1), Point(1, 1), Point(1, 0))
|
|
triangle1 = Polygon(Point(1, 2), Point(2, 2), Point(2, 1))
|
|
assert square1._do_poly_distance(triangle1) == sqrt(2)/2
|
|
|
|
# Polygons which sides intersect
|
|
square2 = Polygon(Point(1, 0), Point(2, 0), Point(2, 1), Point(1, 1))
|
|
with warns(UserWarning, \
|
|
match="Polygons may intersect producing erroneous output", test_stacklevel=False):
|
|
assert square1._do_poly_distance(square2) == 0
|
|
|
|
# Polygons which bodies intersect
|
|
triangle2 = Polygon(Point(0, -1), Point(2, -1), Point(S.Half, S.Half))
|
|
with warns(UserWarning, \
|
|
match="Polygons may intersect producing erroneous output", test_stacklevel=False):
|
|
assert triangle2._do_poly_distance(square1) == 0
|