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test_baseclasses.py
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test_baseclasses.py
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from sympy.categories import (Object, Morphism, IdentityMorphism,
NamedMorphism, CompositeMorphism,
Diagram, Category)
from sympy.categories.baseclasses import Class
from sympy.utilities.pytest import XFAIL, raises
from sympy import FiniteSet, EmptySet, Dict, Tuple
def test_morphisms():
A = Object("A")
B = Object("B")
C = Object("C")
D = Object("D")
# Test the base morphism.
f = NamedMorphism(A, B, "f")
assert f.domain == A
assert f.codomain == B
assert f == NamedMorphism(A, B, "f")
# Test identities.
id_A = IdentityMorphism(A)
id_B = IdentityMorphism(B)
assert id_A.domain == A
assert id_A.codomain == A
assert id_A == IdentityMorphism(A)
assert id_A != id_B
# Test named morphisms.
g = NamedMorphism(B, C, "g")
assert g.name == "g"
assert g != f
assert g == NamedMorphism(B, C, "g")
assert g != NamedMorphism(B, C, "f")
# Test composite morphisms.
assert f == CompositeMorphism(f)
k = g.compose(f)
assert k.domain == A
assert k.codomain == C
assert k.components == Tuple(f, g)
assert g * f == k
assert CompositeMorphism(f, g) == k
assert CompositeMorphism(g * f) == g * f
# Test the associativity of composition.
h = NamedMorphism(C, D, "h")
p = h * g
u = h * g * f
assert h * k == u
assert p * f == u
assert CompositeMorphism(f, g, h) == u
# Test flattening.
u2 = u.flatten("u")
assert isinstance(u2, NamedMorphism)
assert u2.name == "u"
assert u2.domain == A
assert u2.codomain == D
# Test identities.
assert f * id_A == f
assert id_B * f == f
assert id_A * id_A == id_A
assert CompositeMorphism(id_A) == id_A
# Test bad compositions.
raises(ValueError, lambda: f * g)
raises(TypeError, lambda: f.compose(None))
raises(TypeError, lambda: id_A.compose(None))
raises(TypeError, lambda: f * None)
raises(TypeError, lambda: id_A * None)
raises(TypeError, lambda: CompositeMorphism(f, None, 1))
raises(ValueError, lambda: NamedMorphism(A, B, ""))
raises(NotImplementedError, lambda: Morphism(A, B))
def test_diagram():
A = Object("A")
B = Object("B")
C = Object("C")
f = NamedMorphism(A, B, "f")
g = NamedMorphism(B, C, "g")
id_A = IdentityMorphism(A)
id_B = IdentityMorphism(B)
empty = EmptySet()
# Test the addition of identities.
d1 = Diagram([f])
assert d1.objects == FiniteSet(A, B)
assert d1.hom(A, B) == (FiniteSet(f), empty)
assert d1.hom(A, A) == (FiniteSet(id_A), empty)
assert d1.hom(B, B) == (FiniteSet(id_B), empty)
# Test the addition of composites.
d2 = Diagram([f, g])
homAC = d2.hom(A, C)[0]
assert d2.objects == FiniteSet(A, B, C)
assert g * f in d2.premises.keys()
assert homAC == FiniteSet(g * f)
# Test equality, inequality and hash.
d11 = Diagram([f])
assert d1 == d11
assert d1 != d2
assert hash(d1) == hash(d11)
d11 = Diagram({f:"unique"})
assert d1 != d11
# Make sure that (re-)adding composites (with new properties)
# works as expected.
d = Diagram([f, g], {g * f:"unique"})
assert d.conclusions[g * f] == FiniteSet("unique")
# Check how the properties of composite morphisms are computed.
d = Diagram({f:["unique", "isomorphism"], g:"unique"})
assert d.premises[g * f] == FiniteSet("unique")
# Check that conclusion morphisms with new objects are not allowed.
d = Diagram([f], [g])
assert d.conclusions == Dict({})
# Test an empty diagram.
d = Diagram()
assert d.premises == Dict({})
assert d.conclusions == Dict({})
assert d.objects == empty
# Check a SymPy Dict object.
d = Diagram(Dict({f:FiniteSet("unique", "isomorphism"), g:"unique"}))
assert d.premises[g * f] == FiniteSet("unique")
def test_category():
A = Object("A")
B = Object("B")
C = Object("C")
f = NamedMorphism(A, B, "f")
g = NamedMorphism(B, C, "g")
d1 = Diagram([f, g])
d2 = Diagram([f])
objects = d1.objects | d2.objects
K = Category("K", objects, commutative_diagrams=[d1, d2])
assert K.objects == Class(objects)
assert K.commutative_diagrams == FiniteSet(d1, d2)