def test_schreier_sims_random():
assert sorted(tetra.pgroup.base) == [0, 1]
S = SymmetricGroup(3)
base = [0, 1]
strong_gens = [Permutation([1, 2, 0]), Permutation([1, 0, 2]),
Permutation([0, 2, 1])]
assert S.schreier_sims_random(base, strong_gens, 5) == (base, strong_gens)
S = SymmetricGroup(5)
_random_prec = {'g': [Permutation(1, 4), Permutation(0, 3)(1, 4),
Permutation(0, 1, 2, 3, 4), Permutation(0, 1, 2)(3, 4),
Permutation(4)(0, 1)(2, 3), Permutation(0, 1, 4, 3),
Permutation(0, 1)(2, 4), Permutation(0, 3, 4, 2, 1),
Permutation(0, 4, 1)(2, 3)]}
base, strong_gens = S.schreier_sims_random(consec_succ=5,
_random_prec=_random_prec)
assert _verify_bsgs(S, base, strong_gens) is True
D = DihedralGroup(3)
_random_prec = {'g': [Permutation([2, 0, 1]), Permutation([1, 2, 0]),
Permutation([1, 0, 2])]}
base = [0, 1]
strong_gens = [Permutation([1, 2, 0]), Permutation([2, 1, 0]),
Permutation([0, 2, 1])]
assert D.schreier_sims_random([], D.generators, 2,
_random_prec=_random_prec) == (base, strong_gens)
def test_is_alt_sym():
G = DihedralGroup(10)
assert G.is_alt_sym() is False
S = SymmetricGroup(10)
N_eps = 10
_random_prec = {'N_eps': N_eps,
0: Permutation([[2], [1, 4], [0, 6, 7, 8, 9, 3, 5]]),
1: Permutation([[1, 8, 7, 6, 3, 5, 2, 9], [0, 4]]),
2: Permutation([[5, 8], [4, 7], [0, 1, 2, 3, 6, 9]]),
3: Permutation([[3], [0, 8, 2, 7, 4, 1, 6, 9, 5]]),
4: Permutation([[8], [4, 7, 9], [3, 6], [0, 5, 1, 2]]),
5: Permutation([[6], [0, 2, 4, 5, 1, 8, 3, 9, 7]]),
6: Permutation([[6, 9, 8], [4, 5], [1, 3, 7], [0, 2]]),
7: Permutation([[4], [0, 2, 9, 1, 3, 8, 6, 5, 7]]),
8: Permutation([[1, 5, 6, 3], [0, 2, 7, 8, 4, 9]]),
9: Permutation([[8], [6, 7], [2, 3, 4, 5], [0, 1, 9]])}
assert S.is_alt_sym(_random_prec=_random_prec) is True
A = AlternatingGroup(10)
_random_prec = {'N_eps': N_eps,
0: Permutation([[1, 6, 4, 2, 7, 8, 5, 9, 3], [0]]),
1: Permutation([[1], [0, 5, 8, 4, 9, 2, 3, 6, 7]]),
2: Permutation([[1, 9, 8, 3, 2, 5], [0, 6, 7, 4]]),
3: Permutation([[6, 8, 9], [4, 5], [1, 3, 7, 2], [0]]),
4: Permutation([[8], [5], [4], [2, 6, 9, 3], [1], [0, 7]]),
5: Permutation([[3, 6], [0, 8, 1, 7, 5, 9, 4, 2]]),
6: Permutation([[5], [2, 9], [1, 8, 3], [0, 4, 7, 6]]),
7: Permutation([[1, 8, 4, 7, 2, 3], [0, 6, 9, 5]]),
8: Permutation([[5, 8, 7], [3], [1, 4, 2, 6], [0, 9]]),
9: Permutation([[4, 9, 6], [3, 8], [1, 2], [0, 5, 7]])}
assert A.is_alt_sym(_random_prec=_random_prec) is False
def test_normal_closure():
# the normal closure of the trivial group is trivial
S = SymmetricGroup(3)
identity = Permutation([0, 1, 2])
closure = S.normal_closure(identity)
assert closure.is_trivial
# the normal closure of the entire group is the entire group
A = AlternatingGroup(4)
assert A.normal_closure(A).is_subgroup(A)
# brute-force verifications for subgroups
for i in (3, 4, 5):
S = SymmetricGroup(i)
A = AlternatingGroup(i)
D = DihedralGroup(i)
C = CyclicGroup(i)
for gp in (A, D, C):
assert _verify_normal_closure(S, gp)
# brute-force verifications for all elements of a group
for i in range(10):
S = SymmetricGroup(5)
elements = list(S.generate_dimino())
for element in elements:
assert _verify_normal_closure(S, element)
# small groups
small = []
for i in (1, 2, 3):
small.append(SymmetricGroup(i))
small.append(AlternatingGroup(i))
small.append(DihedralGroup(i))
small.append(CyclicGroup(i))
for gp in small:
for gp2 in small:
if gp2.is_subgroup(gp, 0) and gp2.degree == gp.degree:
assert _verify_normal_closure(gp, gp2)
def test_orbit_rep():
G = DihedralGroup(6)
assert G.orbit_rep(1, 3) in [
Permutation([2, 3, 4, 5, 0, 1]),
Permutation([4, 3, 2, 1, 0, 5])
]
H = CyclicGroup(4) * G
assert H.orbit_rep(1, 5) is False
def test_schreier_vector():
G = CyclicGroup(50)
v = [0]*50
v[23] = -1
assert G.schreier_vector(23) == v
H = DihedralGroup(8)
assert H.schreier_vector(2) == [0, 1, -1, 0, 0, 1, 0, 0]
L = SymmetricGroup(4)
assert L.schreier_vector(1) == [1, -1, 0, 0]
def test_minimal_block():
D = DihedralGroup(6)
block_system = D.minimal_block([0, 3])
for i in range(3):
assert block_system[i] == block_system[i + 3]
S = SymmetricGroup(6)
assert S.minimal_block([0, 1]) == [0, 0, 0, 0, 0, 0]
assert tetra.pgroup.minimal_block([0, 1]) == [0, 0, 0, 0]
def test_handle_precomputed_bsgs():
A = AlternatingGroup(5)
A.schreier_sims()
base = A.base
strong_gens = A.strong_gens
result = _handle_precomputed_bsgs(base, strong_gens)
strong_gens_distr = _distribute_gens_by_base(base, strong_gens)
assert strong_gens_distr == result[2]
transversals = result[0]
orbits = result[1]
base_len = len(base)
for i in range(base_len):
for el in orbits[i]:
assert transversals[i][el](base[i]) == el
for j in range(i):
assert transversals[i][el](base[j]) == base[j]
order = 1
for i in range(base_len):
order *= len(orbits[i])
assert A.order() == order
_, transversals = _orbits_transversals_from_bsgs(base, strong_gens_distr)
assert transversals == _handle_precomputed_bsgs(base, strong_gens,
transversals)[0]
assert transversals == _handle_precomputed_bsgs(
base,
strong_gens,
transversals,
basic_orbits=transversals,
strong_gens_distr=strong_gens_distr)[0]
D = DihedralGroup(3)
D.schreier_sims()
assert (_handle_precomputed_bsgs(D.base,
D.strong_gens,
basic_orbits=D.basic_orbits) == ([{
0:
Permutation(2),
1:
Permutation(0, 1, 2),
2:
Permutation(0, 2)
}, {
1:
Permutation(2),
2:
Permutation(1, 2)
}], [[0, 1, 2], [1, 2]], [[
Permutation(0, 1, 2),
Permutation(0, 2),
Permutation(1, 2)
], [Permutation(1, 2)]]))
def test_random_pr():
D = DihedralGroup(6)
r = 11
n = 3
_random_prec_n = {}
_random_prec_n[0] = {'s': 7, 't': 3, 'x': 2, 'e': -1}
_random_prec_n[1] = {'s': 5, 't': 5, 'x': 1, 'e': -1}
_random_prec_n[2] = {'s': 3, 't': 4, 'x': 2, 'e': 1}
D._random_pr_init(r, n, _random_prec_n=_random_prec_n)
assert D._random_gens[11] == [0, 1, 2, 3, 4, 5]
_random_prec = {'s': 2, 't': 9, 'x': 1, 'e': -1}
assert D.random_pr(_random_prec=_random_prec) == \
Permutation([0, 5, 4, 3, 2, 1])
def test_PermutationGroup():
assert PermutationGroup() == PermutationGroup(Permutation())
a = Permutation(1, 2)
b = Permutation(2, 3, 1)
G = PermutationGroup(a, b, degree=5)
assert G.contains(G[0])
A = AlternatingGroup(4)
A.schreier_sims()
assert A.base == [0, 1]
assert A.basic_stabilizers == [
PermutationGroup(Permutation(0, 1, 2), Permutation(1, 2, 3)),
PermutationGroup(Permutation(1, 2, 3))
]
D = DihedralGroup(12)
assert D.is_primitive(randomized=False) is False
D = DihedralGroup(10)
assert D.is_primitive() is False
p = Permutation(0, 1, 2, 3, 4, 5)
G1 = PermutationGroup([Permutation(0, 1, 2), Permutation(0, 1)])
G2 = PermutationGroup([Permutation(0, 2), Permutation(0, 1, 2)])
G3 = PermutationGroup([p, p**2])
assert G1.order() == G2.order() == G3.order() == 6
assert G1.is_subgroup(G2) is True
assert G1.is_subgroup(G3) is False
a, b = [Permutation([1, 0, 3, 2]), Permutation([1, 3, 0, 2])]
G = PermutationGroup([a, b])
assert G.make_perm([0, 1, 0]) == Permutation(0, 2, 3, 1)
S = SymmetricGroup(5)
base, strong_gens = S.schreier_sims_random()
assert _verify_bsgs(S, base, strong_gens)
D = DihedralGroup(4)
assert D.strong_gens == [
Permutation(0, 1, 2, 3),
Permutation(0, 3)(1, 2),
Permutation(1, 3)
]
a = Permutation([1, 2, 0])
b = Permutation([1, 0, 2])
G = PermutationGroup([a, b])
assert G.transitivity_degree == 3
a = Permutation([1, 2, 0, 4, 5, 6, 3])
G = PermutationGroup([a])
assert G.orbit(0) == {0, 1, 2}
assert G.orbit([0, 4], 'union') == {0, 1, 2, 3, 4, 5, 6}
assert G.orbit([0, 4], 'sets') == {(0, 3), (0, 4), (0, 5), (0, 6), (1, 3),
(1, 4), (1, 5), (1, 6), (2, 3), (2, 4),
(2, 5), (2, 6)}
assert G.orbit([0, 4], 'tuples') == {(0, 3), (0, 4), (0, 5), (0, 6),
(1, 3), (1, 4), (1, 5), (1, 6),
(2, 3), (2, 4), (2, 5), (2, 6)}
def test_center():
# the center of the dihedral group D_n is of order 2 for even n
for i in (4, 6, 10):
D = DihedralGroup(i)
assert (D.center()).order() == 2
# the center of the dihedral group D_n is of order 1 for odd n>2
for i in (3, 5, 7):
D = DihedralGroup(i)
assert (D.center()).order() == 1
# the center of an abelian group is the group itself
for i in (2, 3, 5):
for j in (1, 5, 7):
for k in (1, 1, 11):
G = AbelianGroup(i, j, k)
assert G.center().is_subgroup(G)
# the center of a nonabelian simple group is trivial
for i in(1, 5, 9):
A = AlternatingGroup(i)
assert (A.center()).order() == 1
# brute-force verifications
D = DihedralGroup(5)
A = AlternatingGroup(3)
C = CyclicGroup(4)
G.is_subgroup(D*A*C)
assert _verify_centralizer(G, G)
def test_DihedralGroup():
G = DihedralGroup(6)
elements = list(G.generate())
assert len(elements) == 12
assert G.is_transitive() is True
assert G.is_abelian is False
assert G.is_solvable is True
assert G.is_nilpotent is False
H = DihedralGroup(1)
assert H.order() == 2
L = DihedralGroup(2)
assert L.order() == 4
assert L.is_abelian is True
assert L.is_nilpotent is True
def test_commutator():
# the commutator of the trivial group and the trivial group is trivial
S = SymmetricGroup(3)
triv = PermutationGroup([Permutation([0, 1, 2])])
assert S.commutator(triv, triv).is_subgroup(triv)
# the commutator of the trivial group and any other group is again trivial
A = AlternatingGroup(3)
assert S.commutator(triv, A).is_subgroup(triv)
# the commutator is commutative
for i in (3, 4, 5):
S = SymmetricGroup(i)
A = AlternatingGroup(i)
D = DihedralGroup(i)
assert S.commutator(A, D).is_subgroup(S.commutator(D, A))
# the commutator of an abelian group is trivial
S = SymmetricGroup(7)
A1 = AbelianGroup(2, 5)
A2 = AbelianGroup(3, 4)
triv = PermutationGroup([Permutation([0, 1, 2, 3, 4, 5, 6])])
assert S.commutator(A1, A1).is_subgroup(triv)
assert S.commutator(A2, A2).is_subgroup(triv)
# examples calculated by hand
S = SymmetricGroup(3)
A = AlternatingGroup(3)
assert S.commutator(A, S).is_subgroup(A)
def test_strip():
D = DihedralGroup(5)
D.schreier_sims()
member = Permutation([4, 0, 1, 2, 3])
not_member1 = Permutation([0, 1, 4, 3, 2])
not_member2 = Permutation([3, 1, 4, 2, 0])
identity = Permutation([0, 1, 2, 3, 4])
res1 = _strip(member, D.base, D.basic_orbits, D.basic_transversals)
res2 = _strip(not_member1, D.base, D.basic_orbits, D.basic_transversals)
res3 = _strip(not_member2, D.base, D.basic_orbits, D.basic_transversals)
assert res1[0] == identity
assert res1[1] == len(D.base) + 1
assert res2[0] == not_member1
assert res2[1] == len(D.base) + 1
assert res3[0] != identity
assert res3[1] == 2
def test_direct_product():
C = CyclicGroup(4)
D = DihedralGroup(4)
G = C*C*C
assert G.order() == 64
assert G.degree == 12
assert len(G.orbits()) == 3
assert G.is_abelian is True
H = D*C
assert H.order() == 32
assert H.is_abelian is False
def test_derived_series():
# the derived series of the trivial group consists only of the trivial group
triv = PermutationGroup([Permutation([0, 1, 2])])
assert triv.derived_series()[0].is_subgroup(triv)
# the derived series for a simple group consists only of the group itself
for i in (5, 6, 7):
A = AlternatingGroup(i)
assert A.derived_series()[0].is_subgroup(A)
# the derived series for S_4 is S_4 > A_4 > K_4 > triv
S = SymmetricGroup(4)
series = S.derived_series()
assert series[1].is_subgroup(AlternatingGroup(4))
assert series[2].is_subgroup(DihedralGroup(2))
assert series[3].is_trivial
def test_schreier_sims_incremental():
identity = Permutation([0, 1, 2, 3, 4])
TrivialGroup = PermutationGroup([identity])
base, strong_gens = TrivialGroup.schreier_sims_incremental(base=[0, 1, 2])
assert _verify_bsgs(TrivialGroup, base, strong_gens) is True
S = SymmetricGroup(5)
base, strong_gens = S.schreier_sims_incremental(base=[0, 1, 2])
assert _verify_bsgs(S, base, strong_gens) is True
D = DihedralGroup(2)
base, strong_gens = D.schreier_sims_incremental(base=[1])
assert _verify_bsgs(D, base, strong_gens) is True
A = AlternatingGroup(7)
gens = A.generators[:]
gen0 = gens[0]
gen1 = gens[1]
gen1 = rmul(gen1, ~gen0)
gen0 = rmul(gen0, gen1)
gen1 = rmul(gen0, gen1)
base, strong_gens = A.schreier_sims_incremental(base=[0, 1], gens=gens)
assert _verify_bsgs(A, base, strong_gens) is True
C = CyclicGroup(11)
gen = C.generators[0]
base, strong_gens = C.schreier_sims_incremental(gens=[gen**3])
assert _verify_bsgs(C, base, strong_gens) is True
def test_centralizer():
# the centralizer of the trivial group is the entire group
S = SymmetricGroup(2)
assert S.centralizer(Permutation(list(range(2)))).is_subgroup(S)
A = AlternatingGroup(5)
assert A.centralizer(Permutation(list(range(5)))).is_subgroup(A)
# a centralizer in the trivial group is the trivial group itself
triv = PermutationGroup([Permutation([0, 1, 2, 3])])
D = DihedralGroup(4)
assert triv.centralizer(D).is_subgroup(triv)
# brute-force verifications for centralizers of groups
for i in (4, 5, 6):
S = SymmetricGroup(i)
A = AlternatingGroup(i)
C = CyclicGroup(i)
D = DihedralGroup(i)
for gp in (S, A, C, D):
for gp2 in (S, A, C, D):
if not gp2.is_subgroup(gp):
assert _verify_centralizer(gp, gp2)
# verify the centralizer for all elements of several groups
S = SymmetricGroup(5)
elements = list(S.generate_dimino())
for element in elements:
assert _verify_centralizer(S, element)
A = AlternatingGroup(5)
elements = list(A.generate_dimino())
for element in elements:
assert _verify_centralizer(A, element)
D = DihedralGroup(7)
elements = list(D.generate_dimino())
for element in elements:
assert _verify_centralizer(D, element)
# verify centralizers of small groups within small groups
small = []
for i in (1, 2, 3):
small.append(SymmetricGroup(i))
small.append(AlternatingGroup(i))
small.append(DihedralGroup(i))
small.append(CyclicGroup(i))
for gp in small:
for gp2 in small:
if gp.degree == gp2.degree:
assert _verify_centralizer(gp, gp2)
def test_remove_gens():
S = SymmetricGroup(10)
base, strong_gens = S.schreier_sims_incremental()
new_gens = _remove_gens(base, strong_gens)
assert _verify_bsgs(S, base, new_gens) is True
A = AlternatingGroup(7)
base, strong_gens = A.schreier_sims_incremental()
new_gens = _remove_gens(base, strong_gens)
assert _verify_bsgs(A, base, new_gens) is True
D = DihedralGroup(2)
base, strong_gens = D.schreier_sims_incremental()
new_gens = _remove_gens(base, strong_gens)
assert _verify_bsgs(D, base, new_gens) is True
D = DihedralGroup(2)
base, strong_gens = D.schreier_sims_incremental()
strong_gens_distr = _distribute_gens_by_base(base, strong_gens)
_, transversals = _orbits_transversals_from_bsgs(base, strong_gens_distr)
new_gens = _remove_gens(base, strong_gens, transversals, strong_gens_distr)
assert _verify_bsgs(D, base, new_gens) is True
