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
def _subgroup_search(i, j, k):
def prop_true(x):
return True
def prop_fix_points(x):
return [x(point) for point in points] == points
def prop_comm_g(x):
return rmul(x, g) == rmul(g, x)
def prop_even(x):
return x.is_even
for i in range(i, j, k):
S = SymmetricGroup(i)
A = AlternatingGroup(i)
C = CyclicGroup(i)
Sym = S.subgroup_search(prop_true)
assert Sym.is_subgroup(S)
Alt = S.subgroup_search(prop_even)
assert Alt.is_subgroup(A)
Sym = S.subgroup_search(prop_true, init_subgroup=C)
assert Sym.is_subgroup(S)
points = [7]
assert S.stabilizer(7).is_subgroup(S.subgroup_search(prop_fix_points))
points = [3, 4]
assert S.stabilizer(3).stabilizer(4).is_subgroup(
S.subgroup_search(prop_fix_points))
points = [3, 5]
fix35 = A.subgroup_search(prop_fix_points)
points = [5]
fix5 = A.subgroup_search(prop_fix_points)
assert A.subgroup_search(prop_fix_points,
init_subgroup=fix35).is_subgroup(fix5)
base, strong_gens = A.schreier_sims_incremental()
g = A.generators[0]
comm_g = \
A.subgroup_search(prop_comm_g, base=base, strong_gens=strong_gens)
assert _verify_bsgs(comm_g, base, comm_g.generators) is True
assert [prop_comm_g(gen) is True for gen in comm_g.generators]
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
