Traktor/myenv/Lib/site-packages/sympy/sets/handlers/union.py

from sympy.core.singleton import S
from sympy.core.sympify import sympify
from sympy.functions.elementary.miscellaneous import Min, Max
from sympy.sets.sets import (EmptySet, FiniteSet, Intersection,
    Interval, ProductSet, Set, Union, UniversalSet)
from sympy.sets.fancysets import (ComplexRegion, Naturals, Naturals0,
    Integers, Rationals, Reals)
from sympy.multipledispatch import Dispatcher


union_sets = Dispatcher('union_sets')


@union_sets.register(Naturals0, Naturals)
def _(a, b):
    return a

@union_sets.register(Rationals, Naturals)
def _(a, b):
    return a

@union_sets.register(Rationals, Naturals0)
def _(a, b):
    return a

@union_sets.register(Reals, Naturals)
def _(a, b):
    return a

@union_sets.register(Reals, Naturals0)
def _(a, b):
    return a

@union_sets.register(Reals, Rationals)
def _(a, b):
    return a

@union_sets.register(Integers, Set)
def _(a, b):
    intersect = Intersection(a, b)
    if intersect == a:
        return b
    elif intersect == b:
        return a

@union_sets.register(ComplexRegion, Set)
def _(a, b):
    if b.is_subset(S.Reals):
        # treat a subset of reals as a complex region
        b = ComplexRegion.from_real(b)

    if b.is_ComplexRegion:
        # a in rectangular form
        if (not a.polar) and (not b.polar):
            return ComplexRegion(Union(a.sets, b.sets))
        # a in polar form
        elif a.polar and b.polar:
            return ComplexRegion(Union(a.sets, b.sets), polar=True)
    return None

@union_sets.register(EmptySet, Set)
def _(a, b):
    return b


@union_sets.register(UniversalSet, Set)
def _(a, b):
    return a

@union_sets.register(ProductSet, ProductSet)
def _(a, b):
    if b.is_subset(a):
        return a
    if len(b.sets) != len(a.sets):
        return None
    if len(a.sets) == 2:
        a1, a2 = a.sets
        b1, b2 = b.sets
        if a1 == b1:
            return a1 * Union(a2, b2)
        if a2 == b2:
            return Union(a1, b1) * a2
    return None

@union_sets.register(ProductSet, Set)
def _(a, b):
    if b.is_subset(a):
        return a
    return None

@union_sets.register(Interval, Interval)
def _(a, b):
    if a._is_comparable(b):
        # Non-overlapping intervals
        end = Min(a.end, b.end)
        start = Max(a.start, b.start)
        if (end < start or
           (end == start and (end not in a and end not in b))):
            return None
        else:
            start = Min(a.start, b.start)
            end = Max(a.end, b.end)

            left_open = ((a.start != start or a.left_open) and
                         (b.start != start or b.left_open))
            right_open = ((a.end != end or a.right_open) and
                          (b.end != end or b.right_open))
            return Interval(start, end, left_open, right_open)

@union_sets.register(Interval, UniversalSet)
def _(a, b):
    return S.UniversalSet

@union_sets.register(Interval, Set)
def _(a, b):
    # If I have open end points and these endpoints are contained in b
    # But only in case, when endpoints are finite. Because
    # interval does not contain oo or -oo.
    open_left_in_b_and_finite = (a.left_open and
                                     sympify(b.contains(a.start)) is S.true and
                                     a.start.is_finite)
    open_right_in_b_and_finite = (a.right_open and
                                      sympify(b.contains(a.end)) is S.true and
                                      a.end.is_finite)
    if open_left_in_b_and_finite or open_right_in_b_and_finite:
        # Fill in my end points and return
        open_left = a.left_open and a.start not in b
        open_right = a.right_open and a.end not in b
        new_a = Interval(a.start, a.end, open_left, open_right)
        return {new_a, b}
    return None

@union_sets.register(FiniteSet, FiniteSet)
def _(a, b):
    return FiniteSet(*(a._elements | b._elements))

@union_sets.register(FiniteSet, Set)
def _(a, b):
    # If `b` set contains one of my elements, remove it from `a`
    if any(b.contains(x) == True for x in a):
        return {
            FiniteSet(*[x for x in a if b.contains(x) != True]), b}
    return None

@union_sets.register(Set, Set)
def _(a, b):
    return None
dodanie neuralnetwork 2024-05-23 01:57:24 +02:00			`from sympy.core.singleton import S`
			`from sympy.core.sympify import sympify`
			`from sympy.functions.elementary.miscellaneous import Min, Max`
			`from sympy.sets.sets import (EmptySet, FiniteSet, Intersection,`
			`Interval, ProductSet, Set, Union, UniversalSet)`
			`from sympy.sets.fancysets import (ComplexRegion, Naturals, Naturals0,`
			`Integers, Rationals, Reals)`
			`from sympy.multipledispatch import Dispatcher`


			`union_sets = Dispatcher('union_sets')`


			`@union_sets.register(Naturals0, Naturals)`
			`def _(a, b):`
			`return a`

			`@union_sets.register(Rationals, Naturals)`
			`def _(a, b):`
			`return a`

			`@union_sets.register(Rationals, Naturals0)`
			`def _(a, b):`
			`return a`

			`@union_sets.register(Reals, Naturals)`
			`def _(a, b):`
			`return a`

			`@union_sets.register(Reals, Naturals0)`
			`def _(a, b):`
			`return a`

			`@union_sets.register(Reals, Rationals)`
			`def _(a, b):`
			`return a`

			`@union_sets.register(Integers, Set)`
			`def _(a, b):`
			`intersect = Intersection(a, b)`
			`if intersect == a:`
			`return b`
			`elif intersect == b:`
			`return a`

			`@union_sets.register(ComplexRegion, Set)`
			`def _(a, b):`
			`if b.is_subset(S.Reals):`
			`# treat a subset of reals as a complex region`
			`b = ComplexRegion.from_real(b)`

			`if b.is_ComplexRegion:`
			`# a in rectangular form`
			`if (not a.polar) and (not b.polar):`
			`return ComplexRegion(Union(a.sets, b.sets))`
			`# a in polar form`
			`elif a.polar and b.polar:`
			`return ComplexRegion(Union(a.sets, b.sets), polar=True)`
			`return None`

			`@union_sets.register(EmptySet, Set)`
			`def _(a, b):`
			`return b`


			`@union_sets.register(UniversalSet, Set)`
			`def _(a, b):`
			`return a`

			`@union_sets.register(ProductSet, ProductSet)`
			`def _(a, b):`
			`if b.is_subset(a):`
			`return a`
			`if len(b.sets) != len(a.sets):`
			`return None`
			`if len(a.sets) == 2:`
			`a1, a2 = a.sets`
			`b1, b2 = b.sets`
			`if a1 == b1:`
			`return a1 * Union(a2, b2)`
			`if a2 == b2:`
			`return Union(a1, b1) * a2`
			`return None`

			`@union_sets.register(ProductSet, Set)`
			`def _(a, b):`
			`if b.is_subset(a):`
			`return a`
			`return None`

			`@union_sets.register(Interval, Interval)`
			`def _(a, b):`
			`if a._is_comparable(b):`
			`# Non-overlapping intervals`
			`end = Min(a.end, b.end)`
			`start = Max(a.start, b.start)`
			`if (end < start or`
			`(end == start and (end not in a and end not in b))):`
			`return None`
			`else:`
			`start = Min(a.start, b.start)`
			`end = Max(a.end, b.end)`

			`left_open = ((a.start != start or a.left_open) and`
			`(b.start != start or b.left_open))`
			`right_open = ((a.end != end or a.right_open) and`
			`(b.end != end or b.right_open))`
			`return Interval(start, end, left_open, right_open)`

			`@union_sets.register(Interval, UniversalSet)`
			`def _(a, b):`
			`return S.UniversalSet`

			`@union_sets.register(Interval, Set)`
			`def _(a, b):`
			`# If I have open end points and these endpoints are contained in b`
			`# But only in case, when endpoints are finite. Because`
			`# interval does not contain oo or -oo.`
			`open_left_in_b_and_finite = (a.left_open and`
			`sympify(b.contains(a.start)) is S.true and`
			`a.start.is_finite)`
			`open_right_in_b_and_finite = (a.right_open and`
			`sympify(b.contains(a.end)) is S.true and`
			`a.end.is_finite)`
			`if open_left_in_b_and_finite or open_right_in_b_and_finite:`
			`# Fill in my end points and return`
			`open_left = a.left_open and a.start not in b`
			`open_right = a.right_open and a.end not in b`
			`new_a = Interval(a.start, a.end, open_left, open_right)`
			`return {new_a, b}`
			`return None`

			`@union_sets.register(FiniteSet, FiniteSet)`
			`def _(a, b):`
			`return FiniteSet(*(a._elements \| b._elements))`

			`@union_sets.register(FiniteSet, Set)`
			`def _(a, b):`
			# If `b` set contains one of my elements, remove it from `a`
			`if any(b.contains(x) == True for x in a):`
			`return {`
			`FiniteSet(*[x for x in a if b.contains(x) != True]), b}`
			`return None`

			`@union_sets.register(Set, Set)`
			`def _(a, b):`
			`return None`