Traktor/myenv/Lib/site-packages/sympy/geometry/tests/test_util.py

from sympy.core.function import (Derivative, Function)
from sympy.core.singleton import S
from sympy.core.symbol import Symbol
from sympy.functions import exp, cos, sin, tan, cosh, sinh
from sympy.functions.elementary.miscellaneous import sqrt
from sympy.geometry import Point, Point2D, Line, Polygon, Segment, convex_hull,\
    intersection, centroid, Point3D, Line3D
from sympy.geometry.util import idiff, closest_points, farthest_points, _ordered_points, are_coplanar
from sympy.solvers.solvers import solve
from sympy.testing.pytest import raises


def test_idiff():
    x = Symbol('x', real=True)
    y = Symbol('y', real=True)
    t = Symbol('t', real=True)
    f = Function('f')
    g = Function('g')
    # the use of idiff in ellipse also provides coverage
    circ = x**2 + y**2 - 4
    ans = -3*x*(x**2/y**2 + 1)/y**3
    assert ans == idiff(circ, y, x, 3), idiff(circ, y, x, 3)
    assert ans == idiff(circ, [y], x, 3)
    assert idiff(circ, y, x, 3) == ans
    explicit  = 12*x/sqrt(-x**2 + 4)**5
    assert ans.subs(y, solve(circ, y)[0]).equals(explicit)
    assert True in [sol.diff(x, 3).equals(explicit) for sol in solve(circ, y)]
    assert idiff(x + t + y, [y, t], x) == -Derivative(t, x) - 1
    assert idiff(f(x) * exp(f(x)) - x * exp(x), f(x), x) == (x + 1)*exp(x)*exp(-f(x))/(f(x) + 1)
    assert idiff(f(x) - y * exp(x), [f(x), y], x) == (y + Derivative(y, x))*exp(x)
    assert idiff(f(x) - y * exp(x), [y, f(x)], x) == -y + Derivative(f(x), x)*exp(-x)
    assert idiff(f(x) - g(x), [f(x), g(x)], x) == Derivative(g(x), x)
    # this should be fast
    fxy = y - (-10*(-sin(x) + 1/x)**2 + tan(x)**2 + 2*cosh(x/10))
    assert idiff(fxy, y, x) == -20*sin(x)*cos(x) + 2*tan(x)**3 + \
        2*tan(x) + sinh(x/10)/5 + 20*cos(x)/x - 20*sin(x)/x**2 + 20/x**3


def test_intersection():
    assert intersection(Point(0, 0)) == []
    raises(TypeError, lambda: intersection(Point(0, 0), 3))
    assert intersection(
            Segment((0, 0), (2, 0)),
            Segment((-1, 0), (1, 0)),
            Line((0, 0), (0, 1)), pairwise=True) == [
        Point(0, 0), Segment((0, 0), (1, 0))]
    assert intersection(
            Line((0, 0), (0, 1)),
            Segment((0, 0), (2, 0)),
            Segment((-1, 0), (1, 0)), pairwise=True) == [
        Point(0, 0), Segment((0, 0), (1, 0))]
    assert intersection(
            Line((0, 0), (0, 1)),
            Segment((0, 0), (2, 0)),
            Segment((-1, 0), (1, 0)),
            Line((0, 0), slope=1), pairwise=True) == [
        Point(0, 0), Segment((0, 0), (1, 0))]


def test_convex_hull():
    raises(TypeError, lambda: convex_hull(Point(0, 0), 3))
    points = [(1, -1), (1, -2), (3, -1), (-5, -2), (15, -4)]
    assert convex_hull(*points, **{"polygon": False}) == (
        [Point2D(-5, -2), Point2D(1, -1), Point2D(3, -1), Point2D(15, -4)],
        [Point2D(-5, -2), Point2D(15, -4)])


def test_centroid():
    p = Polygon((0, 0), (10, 0), (10, 10))
    q = p.translate(0, 20)
    assert centroid(p, q) == Point(20, 40)/3
    p = Segment((0, 0), (2, 0))
    q = Segment((0, 0), (2, 2))
    assert centroid(p, q) == Point(1, -sqrt(2) + 2)
    assert centroid(Point(0, 0), Point(2, 0)) == Point(2, 0)/2
    assert centroid(Point(0, 0), Point(0, 0), Point(2, 0)) == Point(2, 0)/3


def test_farthest_points_closest_points():
    from sympy.core.random import randint
    from sympy.utilities.iterables import subsets

    for how in (min, max):
        if how == min:
            func = closest_points
        else:
            func = farthest_points

        raises(ValueError, lambda: func(Point2D(0, 0), Point2D(0, 0)))

        # 3rd pt dx is close and pt is closer to 1st pt
        p1 = [Point2D(0, 0), Point2D(3, 0), Point2D(1, 1)]
        # 3rd pt dx is close and pt is closer to 2nd pt
        p2 = [Point2D(0, 0), Point2D(3, 0), Point2D(2, 1)]
        # 3rd pt dx is close and but pt is not closer
        p3 = [Point2D(0, 0), Point2D(3, 0), Point2D(1, 10)]
        # 3rd pt dx is not closer and it's closer to 2nd pt
        p4 = [Point2D(0, 0), Point2D(3, 0), Point2D(4, 0)]
        # 3rd pt dx is not closer and it's closer to 1st pt
        p5 = [Point2D(0, 0), Point2D(3, 0), Point2D(-1, 0)]
        # duplicate point doesn't affect outcome
        dup = [Point2D(0, 0), Point2D(3, 0), Point2D(3, 0), Point2D(-1, 0)]
        # symbolic
        x = Symbol('x', positive=True)
        s = [Point2D(a) for a in ((x, 1), (x + 3, 2), (x + 2, 2))]

        for points in (p1, p2, p3, p4, p5, dup, s):
            d = how(i.distance(j) for i, j in subsets(set(points), 2))
            ans = a, b = list(func(*points))[0]
            assert a.distance(b) == d
            assert ans == _ordered_points(ans)

        # if the following ever fails, the above tests were not sufficient
        # and the logical error in the routine should be fixed
        points = set()
        while len(points) != 7:
            points.add(Point2D(randint(1, 100), randint(1, 100)))
        points = list(points)
        d = how(i.distance(j) for i, j in subsets(points, 2))
        ans = a, b = list(func(*points))[0]
        assert a.distance(b) == d
        assert ans == _ordered_points(ans)

    # equidistant points
    a, b, c = (
        Point2D(0, 0), Point2D(1, 0), Point2D(S.Half, sqrt(3)/2))
    ans = {_ordered_points((i, j))
        for i, j in subsets((a, b, c), 2)}
    assert closest_points(b, c, a) == ans
    assert farthest_points(b, c, a) == ans

    # unique to farthest
    points = [(1, 1), (1, 2), (3, 1), (-5, 2), (15, 4)]
    assert farthest_points(*points) == {
        (Point2D(-5, 2), Point2D(15, 4))}
    points = [(1, -1), (1, -2), (3, -1), (-5, -2), (15, -4)]
    assert farthest_points(*points) == {
        (Point2D(-5, -2), Point2D(15, -4))}
    assert farthest_points((1, 1), (0, 0)) == {
        (Point2D(0, 0), Point2D(1, 1))}
    raises(ValueError, lambda: farthest_points((1, 1)))


def test_are_coplanar():
    a = Line3D(Point3D(5, 0, 0), Point3D(1, -1, 1))
    b = Line3D(Point3D(0, -2, 0), Point3D(3, 1, 1))
    c = Line3D(Point3D(0, -1, 0), Point3D(5, -1, 9))
    d = Line(Point2D(0, 3), Point2D(1, 5))

    assert are_coplanar(a, b, c) == False
    assert are_coplanar(a, d) == False
losowanie zdjec 2024-05-26 05:12:46 +02:00			`from sympy.core.function import (Derivative, Function)`
			`from sympy.core.singleton import S`
			`from sympy.core.symbol import Symbol`
			`from sympy.functions import exp, cos, sin, tan, cosh, sinh`
			`from sympy.functions.elementary.miscellaneous import sqrt`
			`from sympy.geometry import Point, Point2D, Line, Polygon, Segment, convex_hull,\`
			`intersection, centroid, Point3D, Line3D`
			`from sympy.geometry.util import idiff, closest_points, farthest_points, _ordered_points, are_coplanar`
			`from sympy.solvers.solvers import solve`
			`from sympy.testing.pytest import raises`


			`def test_idiff():`
			`x = Symbol('x', real=True)`
			`y = Symbol('y', real=True)`
			`t = Symbol('t', real=True)`
			`f = Function('f')`
			`g = Function('g')`
			`# the use of idiff in ellipse also provides coverage`
			`circ = x2 + y2 - 4`
			`ans = -3x(x2/y2 + 1)/y**3`
			`assert ans == idiff(circ, y, x, 3), idiff(circ, y, x, 3)`
			`assert ans == idiff(circ, [y], x, 3)`
			`assert idiff(circ, y, x, 3) == ans`
			`explicit = 12x/sqrt(-x2 + 4)*5`
			`assert ans.subs(y, solve(circ, y)[0]).equals(explicit)`
			`assert True in [sol.diff(x, 3).equals(explicit) for sol in solve(circ, y)]`
			`assert idiff(x + t + y, [y, t], x) == -Derivative(t, x) - 1`
			`assert idiff(f(x) * exp(f(x)) - x * exp(x), f(x), x) == (x + 1)exp(x)exp(-f(x))/(f(x) + 1)`
			`assert idiff(f(x) - y * exp(x), [f(x), y], x) == (y + Derivative(y, x))*exp(x)`
			`assert idiff(f(x) - y * exp(x), [y, f(x)], x) == -y + Derivative(f(x), x)*exp(-x)`
			`assert idiff(f(x) - g(x), [f(x), g(x)], x) == Derivative(g(x), x)`
			`# this should be fast`
			`fxy = y - (-10(-sin(x) + 1/x)2 + tan(x)2 + 2cosh(x/10))`
			`assert idiff(fxy, y, x) == -20sin(x)cos(x) + 2tan(x)*3 + \`
			`2tan(x) + sinh(x/10)/5 + 20cos(x)/x - 20sin(x)/x2 + 20/x*3`


			`def test_intersection():`
			`assert intersection(Point(0, 0)) == []`
			`raises(TypeError, lambda: intersection(Point(0, 0), 3))`
			`assert intersection(`
			`Segment((0, 0), (2, 0)),`
			`Segment((-1, 0), (1, 0)),`
			`Line((0, 0), (0, 1)), pairwise=True) == [`
			`Point(0, 0), Segment((0, 0), (1, 0))]`
			`assert intersection(`
			`Line((0, 0), (0, 1)),`
			`Segment((0, 0), (2, 0)),`
			`Segment((-1, 0), (1, 0)), pairwise=True) == [`
			`Point(0, 0), Segment((0, 0), (1, 0))]`
			`assert intersection(`
			`Line((0, 0), (0, 1)),`
			`Segment((0, 0), (2, 0)),`
			`Segment((-1, 0), (1, 0)),`
			`Line((0, 0), slope=1), pairwise=True) == [`
			`Point(0, 0), Segment((0, 0), (1, 0))]`


			`def test_convex_hull():`
			`raises(TypeError, lambda: convex_hull(Point(0, 0), 3))`
			`points = [(1, -1), (1, -2), (3, -1), (-5, -2), (15, -4)]`
			`assert convex_hull(points, *{"polygon": False}) == (`
			`[Point2D(-5, -2), Point2D(1, -1), Point2D(3, -1), Point2D(15, -4)],`
			`[Point2D(-5, -2), Point2D(15, -4)])`


			`def test_centroid():`
			`p = Polygon((0, 0), (10, 0), (10, 10))`
			`q = p.translate(0, 20)`
			`assert centroid(p, q) == Point(20, 40)/3`
			`p = Segment((0, 0), (2, 0))`
			`q = Segment((0, 0), (2, 2))`
			`assert centroid(p, q) == Point(1, -sqrt(2) + 2)`
			`assert centroid(Point(0, 0), Point(2, 0)) == Point(2, 0)/2`
			`assert centroid(Point(0, 0), Point(0, 0), Point(2, 0)) == Point(2, 0)/3`


			`def test_farthest_points_closest_points():`
			`from sympy.core.random import randint`
			`from sympy.utilities.iterables import subsets`

			`for how in (min, max):`
			`if how == min:`
			`func = closest_points`
			`else:`
			`func = farthest_points`

			`raises(ValueError, lambda: func(Point2D(0, 0), Point2D(0, 0)))`

			`# 3rd pt dx is close and pt is closer to 1st pt`
			`p1 = [Point2D(0, 0), Point2D(3, 0), Point2D(1, 1)]`
			`# 3rd pt dx is close and pt is closer to 2nd pt`
			`p2 = [Point2D(0, 0), Point2D(3, 0), Point2D(2, 1)]`
			`# 3rd pt dx is close and but pt is not closer`
			`p3 = [Point2D(0, 0), Point2D(3, 0), Point2D(1, 10)]`
			`# 3rd pt dx is not closer and it's closer to 2nd pt`
			`p4 = [Point2D(0, 0), Point2D(3, 0), Point2D(4, 0)]`
			`# 3rd pt dx is not closer and it's closer to 1st pt`
			`p5 = [Point2D(0, 0), Point2D(3, 0), Point2D(-1, 0)]`
			`# duplicate point doesn't affect outcome`
			`dup = [Point2D(0, 0), Point2D(3, 0), Point2D(3, 0), Point2D(-1, 0)]`
			`# symbolic`
			`x = Symbol('x', positive=True)`
			`s = [Point2D(a) for a in ((x, 1), (x + 3, 2), (x + 2, 2))]`

			`for points in (p1, p2, p3, p4, p5, dup, s):`
			`d = how(i.distance(j) for i, j in subsets(set(points), 2))`
			`ans = a, b = list(func(*points))[0]`
			`assert a.distance(b) == d`
			`assert ans == _ordered_points(ans)`

			`# if the following ever fails, the above tests were not sufficient`
			`# and the logical error in the routine should be fixed`
			`points = set()`
			`while len(points) != 7:`
			`points.add(Point2D(randint(1, 100), randint(1, 100)))`
			`points = list(points)`
			`d = how(i.distance(j) for i, j in subsets(points, 2))`
			`ans = a, b = list(func(*points))[0]`
			`assert a.distance(b) == d`
			`assert ans == _ordered_points(ans)`

			`# equidistant points`
			`a, b, c = (`
			`Point2D(0, 0), Point2D(1, 0), Point2D(S.Half, sqrt(3)/2))`
			`ans = {_ordered_points((i, j))`
			`for i, j in subsets((a, b, c), 2)}`
			`assert closest_points(b, c, a) == ans`
			`assert farthest_points(b, c, a) == ans`

			`# unique to farthest`
			`points = [(1, 1), (1, 2), (3, 1), (-5, 2), (15, 4)]`
			`assert farthest_points(*points) == {`
			`(Point2D(-5, 2), Point2D(15, 4))}`
			`points = [(1, -1), (1, -2), (3, -1), (-5, -2), (15, -4)]`
			`assert farthest_points(*points) == {`
			`(Point2D(-5, -2), Point2D(15, -4))}`
			`assert farthest_points((1, 1), (0, 0)) == {`
			`(Point2D(0, 0), Point2D(1, 1))}`
			`raises(ValueError, lambda: farthest_points((1, 1)))`


			`def test_are_coplanar():`
			`a = Line3D(Point3D(5, 0, 0), Point3D(1, -1, 1))`
			`b = Line3D(Point3D(0, -2, 0), Point3D(3, 1, 1))`
			`c = Line3D(Point3D(0, -1, 0), Point3D(5, -1, 9))`
			`d = Line(Point2D(0, 3), Point2D(1, 5))`

			`assert are_coplanar(a, b, c) == False`
			`assert are_coplanar(a, d) == False`