include("Engine.jl") using SparseArrays using Random # initialize the partial gram matrix for a sphere inscribed in a regular # tetrahedron J = Int64[] K = Int64[] values = BigFloat[] for j in 1:9 for k in 1:9 filled = false if j == 9 if k <= 5 && k != 2 push!(values, 0) filled = true end elseif k == 9 if j <= 5 && j != 2 push!(values, 0) filled = true end elseif j == k push!(values, 1) filled = true elseif j == 1 || k == 1 push!(values, 0) filled = true elseif j == 2 || k == 2 push!(values, -1) filled = true end if filled push!(J, j) push!(K, k) end end end append!(J, [6, 4, 6, 5, 7, 5, 7, 3, 8, 3, 8, 4]) append!(K, [4, 6, 5, 6, 5, 7, 3, 7, 3, 8, 4, 8]) append!(values, fill(-1, 12)) #= make construction rigid append!(J, [3, 4, 4, 5]) append!(K, [4, 3, 5, 4]) append!(values, fill(-0.5, 4)) =# gram = sparse(J, K, values) # set initial guess Random.seed!(58271) guess = hcat( Engine.plane(BigFloat[0, 0, 1], BigFloat(0)), Engine.sphere(BigFloat[0, 0, 0], BigFloat(1//2)) + 0.1*Engine.rand_on_shell([BigFloat(-1)]), Engine.plane(-BigFloat[1, 0, 0], BigFloat(-1)) + 0.1*Engine.rand_on_shell([BigFloat(-1)]), Engine.plane(-BigFloat[cos(2pi/3), sin(2pi/3), 0], BigFloat(-1)) + 0.1*Engine.rand_on_shell([BigFloat(-1)]), Engine.plane(-BigFloat[cos(-2pi/3), sin(-2pi/3), 0], BigFloat(-1)) + 0.1*Engine.rand_on_shell([BigFloat(-1)]), Engine.sphere(BigFloat[-1, 0, 0], BigFloat(1//5)) + 0.1*Engine.rand_on_shell([BigFloat(-1)]), Engine.sphere(BigFloat[cos(-pi/3), sin(-pi/3), 0], BigFloat(1//5)) + 0.1*Engine.rand_on_shell([BigFloat(-1)]), Engine.sphere(BigFloat[cos(pi/3), sin(pi/3), 0], BigFloat(1//5)) + 0.1*Engine.rand_on_shell([BigFloat(-1)]), BigFloat[0, 0, 0, 0, 1] ) frozen = [CartesianIndex(j, 9) for j in 1:5] # complete the gram matrix using Newton's method with backtracking L, success, history = Engine.realize_gram(gram, guess, frozen) completed_gram = L'*Engine.Q*L println("Completed Gram matrix:\n") display(completed_gram) if success println("\nTarget accuracy achieved!") else println("\nFailed to reach target accuracy") end println("Steps: ", size(history.scaled_loss, 1)) println("Loss: ", history.scaled_loss[end], "\n")