dyna3/engine-proto/gram-test/circles-in-triangle.jl

include("Engine.jl")

using SparseArrays

# 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 == k
      push!(values, j < 9 ? 1 : 0)
      filled = true
    elseif (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 == 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)
## Random.seed!(58271) # stuck; step size collapses on step 48
## Random.seed!(58272) # good convergence
## Random.seed!(58273) # stuck; step size collapses on step 18
## Random.seed!(58274) # stuck
## Random.seed!(58275) #
## guess = Engine.rand_on_shell(fill(BigFloat(-1), 8))

# set initial guess
guess = hcat(
  Engine.plane(BigFloat[0, 0, 1], BigFloat(0)),
  Engine.sphere(BigFloat[0, 0, 0], BigFloat(1//2)),
  Engine.plane(BigFloat[1, 0, 0], BigFloat(1)),
  Engine.plane(BigFloat[cos(2pi/3), sin(2pi/3), 0], BigFloat(1)),
  Engine.plane(BigFloat[cos(-2pi/3), sin(-2pi/3), 0], BigFloat(1)),
  Engine.sphere(BigFloat[-1, 0, 0], BigFloat(1//5)),
  Engine.sphere(BigFloat[cos(-pi/3), sin(-pi/3), 0], BigFloat(1//5)),
  Engine.sphere(BigFloat[cos(pi/3), sin(pi/3), 0], BigFloat(1//5)),
  BigFloat[0, 0, 0, 1, 1]
)
#=
guess = hcat(
  Engine.plane(BigFloat[0, 0, 1], BigFloat(0)),
  Engine.sphere(BigFloat[0, 0, 0], BigFloat(0.9)),
  Engine.plane(BigFloat[1, 0, 0], BigFloat(1)),
  Engine.plane(BigFloat[cos(2pi/3), sin(2pi/3), 0], BigFloat(1)),
  Engine.plane(BigFloat[cos(-2pi/3), sin(-2pi/3), 0], BigFloat(1)),
  Engine.sphere(4//3*BigFloat[-1, 0, 0], BigFloat(1//3)),
  Engine.sphere(4//3*BigFloat[cos(-pi/3), sin(-pi/3), 0], BigFloat(1//3)),
  Engine.sphere(4//3*BigFloat[cos(pi/3), sin(pi/3), 0], BigFloat(1//3)),
  BigFloat[0, 0, 0, 1, 1]
)
=#

# complete the gram matrix using gradient descent followed by Newton's method
#=
L, history = Engine.realize_gram_gradient(gram, guess, scaled_tol = 0.01)
L_pol, history_pol = Engine.realize_gram_newton(gram, L, rate = 0.3, scaled_tol = 1e-9)
L_pol2, history_pol2 = Engine.realize_gram_newton(gram, L_pol)
=#
L, success, history = Engine.realize_gram(Float64.(gram), Float64.(guess))
completed_gram = L'*Engine.Q*L
println("Completed Gram matrix:\n")
display(completed_gram)
#=
println(
  "\nSteps: ",
  size(history.scaled_loss, 1),
  " + ", size(history_pol.scaled_loss, 1),
  " + ", size(history_pol2.scaled_loss, 1)
)
println("Loss: ", history_pol2.scaled_loss[end], "\n")
=#
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")
Test gradient descent for circles in triangle 2024-07-08 19:56:28 +00:00			`include("Engine.jl")`

			`using SparseArrays`

			`# initialize the partial gram matrix for a sphere inscribed in a regular`
			`# tetrahedron`
			`J = Int64[]`
			`K = Int64[]`
			`values = BigFloat[]`
Require triangle sides to be planar 2024-07-09 21:10:23 +00:00			`for j in 1:9`
			`for k in 1:9`
Test gradient descent for circles in triangle 2024-07-08 19:56:28 +00:00			`filled = false`
			`if j == k`
Require triangle sides to be planar 2024-07-09 21:10:23 +00:00			`push!(values, j < 9 ? 1 : 0)`
Test gradient descent for circles in triangle 2024-07-08 19:56:28 +00:00			`filled = true`
Require triangle sides to be planar 2024-07-09 21:10:23 +00:00			`elseif (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`
Test gradient descent for circles in triangle 2024-07-08 19:56:28 +00:00			`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))`
Start "circles in triangle" from a very close guess 2024-07-08 21:21:10 +00:00			`#= make construction rigid`
			`append!(J, [3, 4, 4, 5])`
			`append!(K, [4, 3, 5, 4])`
			`append!(values, fill(-0.5, 4))`
			`=#`
Test gradient descent for circles in triangle 2024-07-08 19:56:28 +00:00			`gram = sparse(J, K, values)`

			`# set initial guess (random)`
			`## Random.seed!(58271) # stuck; step size collapses on step 48`
			`## Random.seed!(58272) # good convergence`
			`## Random.seed!(58273) # stuck; step size collapses on step 18`
			`## Random.seed!(58274) # stuck`
			`## Random.seed!(58275) #`
			`## guess = Engine.rand_on_shell(fill(BigFloat(-1), 8))`

			`# set initial guess`
			`guess = hcat(`
			`Engine.plane(BigFloat[0, 0, 1], BigFloat(0)),`
			`Engine.sphere(BigFloat[0, 0, 0], BigFloat(1//2)),`
			`Engine.plane(BigFloat[1, 0, 0], BigFloat(1)),`
			`Engine.plane(BigFloat[cos(2pi/3), sin(2pi/3), 0], BigFloat(1)),`
			`Engine.plane(BigFloat[cos(-2pi/3), sin(-2pi/3), 0], BigFloat(1)),`
			`Engine.sphere(BigFloat[-1, 0, 0], BigFloat(1//5)),`
			`Engine.sphere(BigFloat[cos(-pi/3), sin(-pi/3), 0], BigFloat(1//5)),`
Require triangle sides to be planar 2024-07-09 21:10:23 +00:00			`Engine.sphere(BigFloat[cos(pi/3), sin(pi/3), 0], BigFloat(1//5)),`
			`BigFloat[0, 0, 0, 1, 1]`
Test gradient descent for circles in triangle 2024-07-08 19:56:28 +00:00			`)`
Use Newton's method for polishing 2024-07-11 20:43:52 +00:00			`#=`
Start "circles in triangle" from a very close guess 2024-07-08 21:21:10 +00:00			`guess = hcat(`
			`Engine.plane(BigFloat[0, 0, 1], BigFloat(0)),`
			`Engine.sphere(BigFloat[0, 0, 0], BigFloat(0.9)),`
			`Engine.plane(BigFloat[1, 0, 0], BigFloat(1)),`
			`Engine.plane(BigFloat[cos(2pi/3), sin(2pi/3), 0], BigFloat(1)),`
			`Engine.plane(BigFloat[cos(-2pi/3), sin(-2pi/3), 0], BigFloat(1)),`
			`Engine.sphere(4//3*BigFloat[-1, 0, 0], BigFloat(1//3)),`
			`Engine.sphere(4//3*BigFloat[cos(-pi/3), sin(-pi/3), 0], BigFloat(1//3)),`
Require triangle sides to be planar 2024-07-09 21:10:23 +00:00			`Engine.sphere(4//3*BigFloat[cos(pi/3), sin(pi/3), 0], BigFloat(1//3)),`
			`BigFloat[0, 0, 0, 1, 1]`
Start "circles in triangle" from a very close guess 2024-07-08 21:21:10 +00:00			`)`
Use Newton's method for polishing 2024-07-11 20:43:52 +00:00			`=#`
Test gradient descent for circles in triangle 2024-07-08 19:56:28 +00:00
Use Newton's method for polishing 2024-07-11 20:43:52 +00:00			`# complete the gram matrix using gradient descent followed by Newton's method`
Sketch backtracking Newton's method This code is a mess, but I'm committing it to record a working state before I start trying to clean up. 2024-07-15 18:32:04 +00:00			`#=`
Use Newton's method for polishing 2024-07-11 20:43:52 +00:00			`L, history = Engine.realize_gram_gradient(gram, guess, scaled_tol = 0.01)`
			`L_pol, history_pol = Engine.realize_gram_newton(gram, L, rate = 0.3, scaled_tol = 1e-9)`
			`L_pol2, history_pol2 = Engine.realize_gram_newton(gram, L_pol)`
Sketch backtracking Newton's method This code is a mess, but I'm committing it to record a working state before I start trying to clean up. 2024-07-15 18:32:04 +00:00			`=#`
Clean up backtracking gradient descent code Drop experimental singularity handling strategies. Reduce the default tolerance to within 64-bit floating point precision. Report success. 2024-07-15 20:15:15 +00:00			`L, success, history = Engine.realize_gram(Float64.(gram), Float64.(guess))`
Test gradient descent for circles in triangle 2024-07-08 19:56:28 +00:00			`completed_gram = L'Engine.QL`
			`println("Completed Gram matrix:\n")`
			`display(completed_gram)`
Sketch backtracking Newton's method This code is a mess, but I'm committing it to record a working state before I start trying to clean up. 2024-07-15 18:32:04 +00:00			`#=`
Use Newton's method for polishing 2024-07-11 20:43:52 +00:00			`println(`
			`"\nSteps: ",`
			`size(history.scaled_loss, 1),`
			`" + ", size(history_pol.scaled_loss, 1),`
			`" + ", size(history_pol2.scaled_loss, 1)`
			`)`
Sketch backtracking Newton's method This code is a mess, but I'm committing it to record a working state before I start trying to clean up. 2024-07-15 18:32:04 +00:00			`println("Loss: ", history_pol2.scaled_loss[end], "\n")`
			`=#`
Clean up backtracking gradient descent code Drop experimental singularity handling strategies. Reduce the default tolerance to within 64-bit floating point precision. Report success. 2024-07-15 20:15:15 +00:00			`if success`
			`println("\nTarget accuracy achieved!")`
			`else`
			`println("\nFailed to reach target accuracy")`
			`end`
			`println("Steps: ", size(history.scaled_loss, 1))`
Sketch backtracking Newton's method This code is a mess, but I'm committing it to record a working state before I start trying to clean up. 2024-07-15 18:32:04 +00:00			`println("Loss: ", history.scaled_loss[end], "\n")`