include("Projections.jl") ############################################################################### # # Iterator protocol for Nemo.FinField # ############################################################################### mutable struct FFEltsIter{T<:Generic.FinField} all::Int field::T function FFEltsIter{T}(F::T) where {T} return new(Int(characteristic(F)^degree(F)), F) end end FFEltsIter(F::T) where {T<:Nemo.FinField} = FFEltsIter{T}(F) import Base: start, next, done, eltype, length Base.start(A::FFEltsIter) = (zero(A.field), 0) Base.next(A::FFEltsIter, state) = next_ffelem(state...) Base.done(A::FFEltsIter, state) = state[2] >= A.all Base.eltype(::Type{FFEltsIter}) = elem_type(A.field) Base.length(A::FFEltsIter) = A.all function next_ffelem(f::Nemo.FinFieldElem, c::Int) if c == 0 return (f, (f, 1)) elseif c == 1 f = one(parent(f)) return (f, (f, 2)) else f = gen(parent(f))*f return (f, (f, c+1)) end end import Nemo.elements elements(F::Nemo.FinField) = FFEltsIter(F) ############################################################################### # # Orbit stuff # ############################################################################### function orbit_decomposition(G::Nemo.Group, E::Vector, rdict=GroupRings.reverse_dict(E)) elts = collect(elements(G)) tovisit = trues(E); orbits = Vector{Vector{Int}}() for i in 1:endof(E) if tovisit[i] orbit = zeros(Int, length(elts)) a = E[i] Threads.@threads for i in 1:length(elts) orbit[i] = rdict[elts[i](a)] end tovisit[orbit] = false push!(orbits, unique(orbit)) end end return orbits end function orbit_spvector(vect::AbstractVector, orbits) orb_vector = spzeros(length(orbits)) for (i,o) in enumerate(orbits) k = vect[collect(o)] val = k[1] @assert all(k .== val) orb_vector[i] = val end return orb_vector end function orbit_constraint(constraints::Vector{Vector{Tuple{Int,Int}}}, n) result = spzeros(n,n) for cnstr in constraints for p in cnstr result[p[2], p[1]] += 1.0/length(constraints) end end return result end ############################################################################### # # Matrix-, Permutation- and C*-representations # ############################################################################### function matrix_repr(p::perm) N = parent(p).n return sparse(1:N, p.d, [1.0 for _ in 1:N]) end function matrix_reps{T<:GroupElem}(preps::Dict{T,perm}) kk = collect(keys(preps)) mreps = Vector{SparseMatrixCSC{Float64, Int}}(length(kk)) Threads.@threads for i in 1:length(kk) mreps[i] = matrix_repr(preps[kk[i]]) end return Dict(kk[i] => mreps[i] for i in 1:length(kk)) end function perm_repr(g::GroupElem, E::Vector, E_dict) p = Vector{Int}(length(E)) for (i,elt) in enumerate(E) p[i] = E_dict[g(elt)] end return p end function perm_reps(G::Group, E::Vector, E_rdict=GroupRings.reverse_dict(E)) elts = collect(elements(G)) l = length(elts) preps = Vector{Generic.perm}(l) permG = Nemo.PermutationGroup(length(E)) Threads.@threads for i in 1:l preps[i] = permG(PropertyT.perm_repr(elts[i], E, E_rdict)) end return Dict(elts[i]=>preps[i] for i in 1:l) end function perm_reps(S::Vector, autS::Group, radius::Int) E, _ = Groups.generate_balls(S, radius=radius) return perm_reps(autS, E) end function reconstruct_sol{T<:GroupElem, S<:perm}(preps::Dict{T, S}, Us::Vector, Ps::Vector, dims::Vector) l = length(Us) transfP = [dims[π].*Us[π]*Ps[π]*Us[π]' for π in 1:l] tmp = [zeros(Float64, size(first(transfP))) for _ in 1:l] perms = collect(keys(preps)) @inbounds Threads.@threads for π in 1:l for p in perms BLAS.axpy!(1.0, view(transfP[π], preps[p].d, preps[p].d), tmp[π]) end end recP = 1/length(perms) .* sum(tmp) recP[abs.(recP) .< eps(eltype(recP))] = zero(eltype(recP)) return recP end function Cstar_repr(x::GroupRingElem{T}, mreps::Dict) where {T} return sum(x[i].*mreps[parent(x).basis[i]] for i in findn(x.coeffs)) end function orthSVD{T}(M::AbstractMatrix{T}) M = full(M) fact = svdfact(M) M_rank = sum(fact[:S] .> maximum(size(M))*eps(T)) return fact[:U][:,1:M_rank] end function compute_orbit_data{T<:GroupElem}(logger, name::String, G::Nemo.Group, S::Vector{T}, autS::Nemo.Group; radius=2) isdir(name) || mkdir(name) info(logger, "Generating ball of radius $(2*radius)") # TODO: Fix that by multiple dispatch? Id = (isa(G, Nemo.Ring) ? one(G) : G()) @logtime logger E_2R, sizes = Groups.generate_balls(S, Id, radius=2*radius); info(logger, "Balls of sizes $sizes.") info(logger, "Reverse dict") @logtime logger E_rdict = GroupRings.reverse_dict(E_2R) info(logger, "Product matrix") @logtime logger pm = GroupRings.create_pm(E_2R, E_rdict, sizes[radius], twisted=true) RG = GroupRing(G, E_2R, E_rdict, pm) Δ = PropertyT.splaplacian(RG, S) @assert GroupRings.augmentation(Δ) == 0 save(joinpath(name, "delta.jld"), "Δ", Δ.coeffs) save(joinpath(name, "pm.jld"), "pm", pm) info(logger, "Decomposing E into orbits of $(autS)") @logtime logger orbs = orbit_decomposition(autS, E_2R, E_rdict) @assert sum(length(o) for o in orbs) == length(E_2R) info(logger, "E consists of $(length(orbs)) orbits!") save(joinpath(name, "orbits.jld"), "orbits", orbs) info(logger, "Action matrices") @logtime logger reps = perm_reps(autS, E_2R[1:sizes[radius]], E_rdict) save_preps(joinpath(name, "preps.jld"), reps) reps = matrix_reps(reps) info(logger, "Projections") @logtime logger autS_mps = rankOne_projections(autS); @logtime logger π_E_projections = [Cstar_repr(p, reps) for p in autS_mps] info(logger, "Uπs...") @logtime logger Uπs = orthSVD.(π_E_projections) multiplicities = size.(Uπs,2) info(logger, "multiplicities = $multiplicities") dimensions = [Int(p[autS()]*Int(order(autS))) for p in autS_mps]; info(logger, "dimensions = $dimensions") @assert dot(multiplicities, dimensions) == sizes[radius] save(joinpath(name, "U_pis.jld"), "Uπs", Uπs, "dims", dimensions) return 0 end