PropertyT.jl/SL(3,Z).jl

using JuMP
import SCS: SCSSolver
import Mosek: MosekSolver

workers_processes = addprocs()

@everywhere push!(LOAD_PATH, "./")
using GroupAlgebras
@everywhere include("property(T).jl")

function E(i::Int, j::Int, N::Int=3)
    @assert i≠j
    k = eye(N)
    k[i,j] = 1
    return k
end

function SL_3ZZ_generating_set()
    S = [E(1,2), E(1,3), E(2,3)];
    S = vcat(S, [x' for x in S]);
    S = vcat(S, [inv(x) for x in S]);
    return S
end

const ID = eye(3)

const S₁ = SL_3ZZ_generating_set()


const TOL=10.0^-7
# const VERBOSE=true
#solver = SCSSolver(eps=TOL, max_iters=ITERATIONS, verbose=VERBOSE);
# solver = MosekSolver(MSK_DPAR_INTPNT_CO_TOL_REL_GAP=TOL,
# #                      MSK_DPAR_INTPNT_CO_TOL_PFEAS=1e-15,
# #                      MSK_DPAR_INTPNT_CO_TOL_DFEAS=1e-15,
# #                      MSK_IPAR_PRESOLVE_USE=0,
#                   QUIET=!VERBOSE)

# κ, A = solve_for_property_T(S₁, solver, verbose=VERBOSE)


const product_matrix = readdlm("SL3Z.product_matrix", Int)
const L = readdlm("SL3Z.delta.coefficients")[:, 1]
const Δ = GroupAlgebraElement(L, product_matrix)

const A = readdlm("SL3Z.SDPmatrixA.Mosek")
const κ = readdlm("SL3Z.kappa.Mosek")[1]

@assert isapprox(eigvals(A), abs(eigvals(A)), atol=TOL)
@assert A == Symmetric(A)

const A_sqrt = real(sqrtm(A))

const SOS_fp_diff, SOS_fp_L₁_distance = check_solution(κ, A_sqrt, Δ)

@show SOS_fp_L₁_distance
@show GroupAlgebras.ɛ(SOS_fp_diff)

const κ_rational = rationalize(BigInt, κ, tol=TOL)
const A_sqrt_rational = rationalize(BigInt, A_sqrt, tol=TOL)
const Δ_rational = rationalize(BigInt, Δ, tol=TOL)

const SOS_rational_diff, SOS_rat_L₁_distance = check_solution(κ_rational, A_sqrt_rational, Δ_rational)

@assert isa(SOS_rat_L₁_distance, Rational{BigInt})
@show float(SOS_rat_L₁_distance)
@show float(GroupAlgebras.ɛ(SOS_rational_diff))

const A_sqrt_augmented = correct_to_augmentation_ideal(A_sqrt_rational)

const SOS_rational_aug_diff, SOS_aug_rat_L₁_distance = check_solution(κ_rational, A_sqrt_augmented, Δ_rational)

@assert isa(SOS_aug_rat_L₁_distance, Rational{BigInt})
@assert GroupAlgebras.ɛ(SOS_rational_aug_diff) == 0//1

@show float(SOS_aug_rat_L₁_distance)
@show float(κ_rational - 2^3*SOS_aug_rat_L₁_distance)

rmprocs(workers_processes)
SL(3,Z) specific code 2017-01-09 01:03:46 +01:00			`using JuMP`
			`import SCS: SCSSolver`
			`import Mosek: MosekSolver`

Parallel compute_SOS 2017-01-14 15:24:16 +01:00			`workers_processes = addprocs()`
SL(3,Z) specific code 2017-01-09 01:03:46 +01:00
Parallel compute_SOS 2017-01-14 15:24:16 +01:00			`@everywhere push!(LOAD_PATH, "./")`
SL(3,Z) specific code 2017-01-09 01:03:46 +01:00			`using GroupAlgebras`
Parallel compute_SOS 2017-01-14 15:24:16 +01:00			`@everywhere include("property(T).jl")`
SL(3,Z) specific code 2017-01-09 01:03:46 +01:00
			`function E(i::Int, j::Int, N::Int=3)`
			`@assert i≠j`
			`k = eye(N)`
			`k[i,j] = 1`
			`return k`
			`end`

			`function SL_3ZZ_generating_set()`
			`S = [E(1,2), E(1,3), E(2,3)];`
			`S = vcat(S, [x' for x in S]);`
			`S = vcat(S, [inv(x) for x in S]);`
			`return S`
			`end`

			`const ID = eye(3)`

			`const S₁ = SL_3ZZ_generating_set()`


			`const TOL=10.0^-7`
comment solving, results are cached 2017-01-13 18:41:21 +01:00			`# const VERBOSE=true`
			`#solver = SCSSolver(eps=TOL, max_iters=ITERATIONS, verbose=VERBOSE);`
			`# solver = MosekSolver(MSK_DPAR_INTPNT_CO_TOL_REL_GAP=TOL,`
			`# # MSK_DPAR_INTPNT_CO_TOL_PFEAS=1e-15,`
			`# # MSK_DPAR_INTPNT_CO_TOL_DFEAS=1e-15,`
			`# # MSK_IPAR_PRESOLVE_USE=0,`
			`# QUIET=!VERBOSE)`
SL(3,Z) specific code 2017-01-09 01:03:46 +01:00
			`# κ, A = solve_for_property_T(S₁, solver, verbose=VERBOSE)`
comment solving, results are cached 2017-01-13 18:41:21 +01:00
SL(3,Z) specific code 2017-01-09 01:03:46 +01:00
Parallel compute_SOS 2017-01-14 15:24:16 +01:00			`const product_matrix = readdlm("SL3Z.product_matrix", Int)`
			`const L = readdlm("SL3Z.delta.coefficients")[:, 1]`
			`const Δ = GroupAlgebraElement(L, product_matrix)`
SL(3,Z) specific code 2017-01-09 01:03:46 +01:00
Parallel compute_SOS 2017-01-14 15:24:16 +01:00			`const A = readdlm("SL3Z.SDPmatrixA.Mosek")`
			`const κ = readdlm("SL3Z.kappa.Mosek")[1]`
SL(3,Z) specific code 2017-01-09 01:03:46 +01:00
			`@assert isapprox(eigvals(A), abs(eigvals(A)), atol=TOL)`
			`@assert A == Symmetric(A)`

			`const A_sqrt = real(sqrtm(A))`

Parallel compute_SOS 2017-01-14 15:24:16 +01:00			`const SOS_fp_diff, SOS_fp_L₁_distance = check_solution(κ, A_sqrt, Δ)`
Use the norm function; shuffle returns of check_solution 2017-01-13 18:07:41 +01:00
			`@show SOS_fp_L₁_distance`
			`@show GroupAlgebras.ɛ(SOS_fp_diff)`
SL(3,Z) specific code 2017-01-09 01:03:46 +01:00
Parallel compute_SOS 2017-01-14 15:24:16 +01:00			`const κ_rational = rationalize(BigInt, κ, tol=TOL)`
			`const A_sqrt_rational = rationalize(BigInt, A_sqrt, tol=TOL)`
			`const Δ_rational = rationalize(BigInt, Δ, tol=TOL)`
SL(3,Z) specific code 2017-01-09 01:03:46 +01:00
Parallel compute_SOS 2017-01-14 15:24:16 +01:00			`const SOS_rational_diff, SOS_rat_L₁_distance = check_solution(κ_rational, A_sqrt_rational, Δ_rational)`
Use the norm function; shuffle returns of check_solution 2017-01-13 18:07:41 +01:00
			`@assert isa(SOS_rat_L₁_distance, Rational{BigInt})`
			`@show float(SOS_rat_L₁_distance)`
			`@show float(GroupAlgebras.ɛ(SOS_rational_diff))`
comment solving, results are cached 2017-01-13 18:41:21 +01:00
Parallel compute_SOS 2017-01-14 15:24:16 +01:00			`const A_sqrt_augmented = correct_to_augmentation_ideal(A_sqrt_rational)`

			`const SOS_rational_aug_diff, SOS_aug_rat_L₁_distance = check_solution(κ_rational, A_sqrt_augmented, Δ_rational)`

			`@assert isa(SOS_aug_rat_L₁_distance, Rational{BigInt})`
			`@assert GroupAlgebras.ɛ(SOS_rational_aug_diff) == 0//1`

			`@show float(SOS_aug_rat_L₁_distance)`
			`@show float(κ_rational - 2^3*SOS_aug_rat_L₁_distance)`
comment solving, results are cached 2017-01-13 18:41:21 +01:00
Parallel compute_SOS 2017-01-14 15:24:16 +01:00			`rmprocs(workers_processes)`