mirror of
https://github.com/kalmarek/GroupRings.jl.git
synced 2024-11-15 13:35:27 +01:00
169 lines
4.5 KiB
Julia
169 lines
4.5 KiB
Julia
using GroupRings
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using Base.Test
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using Nemo
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@testset "GroupRings" begin
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@testset "Constructors: PermutationGroup" begin
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G = PermutationGroup(3)
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@test isa(GroupRing(G), Nemo.Ring)
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@test isa(GroupRing(G), GroupRing)
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RG = GroupRing(G, initialise=false)
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@test isdefined(RG, :pm) == false
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@test isdefined(RG, :basis) == false
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@test isdefined(RG, :basis_dict) == false
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@test isa(complete(RG), GroupRing)
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@test size(RG.pm) == (6,6)
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@test length(RG.basis) == 6
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@test RG.basis_dict == GroupRings.reverse_dict(elements(G))
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@test isa(GroupRing(G, collect(elements(G))), GroupRing)
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S = collect(elements(G))
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pm = create_pm(S)
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@test isa(GroupRing(G, S), GroupRing)
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@test isa(GroupRing(G, S, pm), GroupRing)
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A = GroupRing(G, S)
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B = GroupRing(G, S, pm)
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@test RG == A
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@test RG == B
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end
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@testset "GroupRing constructors FreeGroup" begin
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using Groups
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F = FreeGroup(3)
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S = gens(F)
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append!(S, [inv(s) for s in S])
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S = unique(S)
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basis, sizes = Groups.generate_balls(S, F(), radius=4)
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d = GroupRings.reverse_dict(basis)
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@test_throws KeyError create_pm(basis)
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pm = create_pm(basis, d, sizes[2])
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@test isa(GroupRing(F, basis, pm), GroupRing)
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@test isa(GroupRing(F, basis, d, pm), GroupRing)
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A = GroupRing(F, basis, pm)
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B = GroupRing(F, basis, d, pm)
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@test A == B
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end
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@testset "GroupRingElems constructors/basic manipulation" begin
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G = PermutationGroup(3)
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RG = GroupRing(G, initialise=true)
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a = rand(6)
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@test isa(GroupRingElem(a, RG), GroupRingElem)
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@test isa(RG(a), GroupRingElem)
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for g in elements(G)
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@test isa(RG(g), GroupRingElem)
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end
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@test_throws String GroupRingElem([1,2,3], RG)
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@test isa(RG(G([2,3,1])), GroupRingElem)
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p = G([2,3,1])
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a = RG(p)
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@test length(a) == 1
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@test isa(a.coeffs, SparseVector)
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@test a.coeffs[5] == 1
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@test a[5] == 1
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@test a[p] == 1
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@test string(a) == " + 1*[2, 3, 1]"
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@test RG([0,0,0,0,1,0]) == a
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s = G([1,2,3])
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@test a[s] == 0
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a[s] = 2
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@test a.coeffs[1] == 2
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@test a[1] == 2
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@test a[s] == 2
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@test string(a) == " + 2*[1, 2, 3] + 1*[2, 3, 1]"
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@test length(a) == 2
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end
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@testset "Arithmetic" begin
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G = PermutationGroup(3)
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RG = GroupRing(G)
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a = RG(ones(Int, order(G)))
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@testset "scalar operators" begin
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@test isa(-a, GroupRingElem)
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@test (-a).coeffs == -(a.coeffs)
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@test isa(2*a, GroupRingElem)
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@test eltype(2*a) == typeof(2)
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@test (2*a).coeffs == 2.*(a.coeffs)
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@test isa(2.0*a, GroupRingElem)
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@test eltype(2.0*a) == typeof(2.0)
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@test (2.0*a).coeffs == 2.0.*(a.coeffs)
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@test isa(a/2, GroupRingElem)
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@test eltype(a/2) == typeof(1/2)
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@test (a/2).coeffs == 0.5*(a.coeffs)
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@test isa(convert(Rational{Int}, a), GroupRingElem)
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@test eltype(convert(Rational{Int}, a)) == Rational{Int}
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@test convert(Rational{Int}, a).coeffs ==
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convert(Vector{Rational{Int}}, a.coeffs)
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b = convert(Rational{Int}, a)
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@test isa(b//4, GroupRingElem)
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@test eltype(b//4) == Rational{Int}
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@test isa(b//big(4), GroupElem)
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@test eltype(b//(big(4)//1)) == Rational{BigInt}
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@test isa(a//1, GroupRingElem)
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@test eltype(a//1) == Rational{Int}
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@test_throws MethodError (1.0*a)//1
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end
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@testset "Additive structure" begin
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@test RG(ones(Int, order(G))) == sum(RG(g) for g in elements(G))
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a = RG(ones(Int, order(G)))
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b = sum((-1)^parity(g)*RG(g) for g in elements(G))
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@test 1/2*(a+b).coeffs == [1.0, 0.0, 1.0, 0.0, 1.0, 0.0]
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end
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@testset "Multiplicative structure" begin
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for g in elements(G), h in elements(G)
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a = RG(g)
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b = RG(h)
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@test a*b == RG(g*h)
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@test (a+b)*(a+b) == a*a + a*b + b*a + b*b
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end
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for g in elements(G)
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@test GroupRings.star(RG(g)) == RG(inv(g))
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@test (one(RG)-RG(g))*GroupRings.star(one(RG)-RG(g)) ==
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2*one(RG) - RG(g) - RG(inv(g))
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@test GroupRings.augmentation((one(RG)-RG(g))) == 0
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end
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z = sum((one(RG)-RG(g))*GroupRings.star(one(RG)-RG(g)) for g in elements(G))
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@test GroupRings.augmentation(z) == 0
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@test rationalize(Int, z) == convert(Rational{Int}, z)
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end
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end
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end
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