184 lines
5.2 KiB
Julia
184 lines
5.2 KiB
Julia
using JLD
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using JuMP
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import SCS: SCSSolver
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import Mosek: MosekSolver
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using Groups
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using ProgressMeter
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#=
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Note that the element
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α(i,j,k) = ϱ(i,j)*ϱ(i,k)*inv(ϱ(i,j))*inv(ϱ(i,k)),
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which surely belongs to ball of radius 4 in Aut(F₄) becomes trivial under the representation
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Aut(F₄) → GL₄(ℤ)⋉ℤ⁴ → GL₅(ℂ).
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Moreover, due to work of Potapchik and Rapinchuk [1] every real representation of Aut(Fₙ) into GLₘ(ℂ) (for m ≤ 2n-2) factors through GLₙ(ℤ)⋉ℤⁿ, so will have the same problem.
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We need a different approach: Here we actually compute in Aut(𝔽₄)
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=#
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import Combinatorics.nthperm
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SymmetricGroup(n) = [nthperm(collect(1:n), k) for k in 1:factorial(n)]
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function generating_set_of_AutF(N::Int)
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indexing = [[i,j] for i in 1:N for j in 1:N if i≠j]
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σs = [symmetric_AutSymbol(perm) for perm in SymmetricGroup(N)[2:end]];
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ϱs = [rmul_AutSymbol(i,j) for (i,j) in indexing]
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λs = [lmul_AutSymbol(i,j) for (i,j) in indexing]
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ɛs = [flip_AutSymbol(i) for i in 1:N];
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S = vcat(ϱs,λs)
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S = vcat(S..., σs..., ɛs)
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S = vcat(S..., [inv(g) for g in S])
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return Vector{AutWord}(unique(S))
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end
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function generating_set_of_OutF(N::Int)
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indexing = [[i,j] for i in 1:N for j in 1:N if i≠j]
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ϱs = [rmul_AutSymbol(i,j) for (i,j) in indexing]
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λs = [lmul_AutSymbol(i,j) for (i,j) in indexing]
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ɛs = [flip_AutSymbol(i) for i in 1:N];
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S = ϱs
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push!(S, λs..., ɛs...)
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push!(S,[inv(g) for g in S]...)
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return Vector{AutWord}(unique(S))
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end
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function generating_set_of_Sym(N::Int)
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σs = [symmetric_AutSymbol(perm) for perm in SymmetricGroup(N)[2:end]];
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S = σs
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push!(S, [inv(s) for s in S]...)
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return Vector{AutWord}(unique(S))
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end
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function products(S1::Vector{AutWord}, S2::Vector{AutWord})
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result = Vector{AutWord}()
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seen = Set{Vector{FGWord}}()
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n = length(S1)
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p = Progress(n, 1, "Computing complete products...", 50)
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for (i,x) in enumerate(S1)
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for y in S2
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z::AutWord = x*y
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v::Vector{FGWord} = z(domain)
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if !in(v, seen)
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push!(seen, v)
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push!(result, z)
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end
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end
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next!(p)
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end
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return result
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end
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function products_images(S1::Vector{AutWord}, S2::Vector{AutWord})
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result = Vector{Vector{FGWord}}()
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seen = Set{Vector{FGWord}}()
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n = length(S1)
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p = Progress(n, 1, "Computing images of elts in B₄...", 50)
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for (i,x) in enumerate(S1)
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z = x(domain)
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for y in S2
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v = y(z)
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if !in(v, seen)
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push!(seen, v)
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push!(result, v)
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end
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end
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next!(p)
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end
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return result
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end
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function hashed_product{T}(image::T, B, images_dict::Dict{T, Int})
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n = size(B,1)
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column = zeros(Int,n)
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Threads.@threads for j in 1:n
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w = (B[j])(image)
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k = images_dict[w]
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k ≠ 0 || throw(ArgumentError(
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"($i,$j): $(x^-1)*$y don't seem to be supported on basis!"))
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column[j] = k
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end
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return column
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end
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function create_product_matrix(basis::Vector{AutWord}, images)
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n = length(basis)
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product_matrix = zeros(Int, (n, n));
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print("Creating hashtable of images...")
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@time images_dict = Dict{Vector{FGWord}, Int}(x => i
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for (i,x) in enumerate(images))
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p = Progress(n, 1, "Computing product matrix in basis...", 50)
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for i in 1:n
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z = (inv(basis[i]))(domain)
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product_matrix[i,:] = hashed_product(z, basis, images_dict)
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next!(p)
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end
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return product_matrix
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end
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function ΔandSDPconstraints(identity::AutWord, S::Vector{AutWord})
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println("Generating Balls of increasing radius...")
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@time B₁ = vcat([identity], S)
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@time B₂ = products(B₁,B₁);
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@show length(B₂)
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if length(B₂) != length(B₁)
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@time B₃ = products(B₁, B₂)
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@show length(B₃)
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if length(B₃) != length(B₂)
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@time B₄_images = products_images(B₁, B₃)
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else
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B₄_images = unique([f(domain) for f in B₃])
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end
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else
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B₃ = B₂
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B₄ = B₂
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B₄_images = unique([f(domain) for f in B₃])
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end
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@show length(B₄_images)
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# @assert length(B₄_images) == 3425657
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println("Creating product matrix...")
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@time pm = create_product_matrix(B₂, B₄_images)
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println("Creating sdp_constratints...")
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@time sdp_constraints = constraints_from_pm(pm)
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L_coeff = splaplacian_coeff(S, B₂, length(B₄_images))
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Δ = GroupAlgebraElement(L_coeff, Array{Int,2}(pm))
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return Δ, sdp_constraints
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end
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@everywhere push!(LOAD_PATH, "./")
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using GroupAlgebras
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include("property(T).jl")
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const symbols = [FGSymbol("x₁",1), FGSymbol("x₂",1), FGSymbol("x₃",1), FGSymbol("x₄",1), FGSymbol("x₅",1), FGSymbol("x₆",1)]
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const TOL=1e-8
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const N = 4
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const domain = Vector{FGWord}(symbols[1:N])
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const ID = one(AutWord)
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# const name = "SYM$N"
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# const upper_bound=factorial(N)-TOL^(1/5)
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# S() = generating_set_of_Sym(N)
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# name = "AutF$N"
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# S() = generating_set_of_AutF(N)
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name = "OutF$N"
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S() = generating_set_of_OutF(N)
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const upper_bound=0.05
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BLAS.set_num_threads(4)
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@time check_property_T(name, ID, S; verbose=true, tol=TOL, upper_bound=upper_bound)
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