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	import keras
	import numpy
	import gradio
	import pandas
	import glob
	import os
	import shutil
	import stat
	import math
	import platform
	import scipy.spatial
	import plotly.graph_objects as go
	import random
	from huggingface_hub import from_pretrained_keras

	def load_data():

	from datasets import load_dataset

	data = load_dataset("cmudrc/wave-energy", data_files="data.csv", split='train').to_pandas()

	# Open all the files we downloaded at the beginning and take out hte good bits
	curves = data.iloc[:, [i for i in range(1, 3*64+1)]]
	geometry = data.iloc[:, [i for i in range(1 + 364, 1 + 364 + 32**3)]]
	S = 5
	N = 1000
	D = 3
	F = 64
	G = 32

	flattened_curves = curves.values / 1000000
	curvey_curves = [c.reshape([3, 64]) for c in flattened_curves]

	flattened_geometry = geometry.values
	round_geometry = [g.reshape([32, 32, 32]) for g in flattened_geometry]

	# Return good bits to user
	return curvey_curves, round_geometry, S, N, D, F, G, flattened_curves, flattened_geometry

	# Disable eager execution because its bad
	from tensorflow.python.framework.ops import disable_eager_execution
	disable_eager_execution()

	class Mesh:
	def __init__(self):
	# Define blank values
	self.np = 0
	self.nf = 0
	self.X = []
	self.Y = []
	self.Z = []
	self.P = []

	def combine_meshes(self, ob1, ob2):
	# Check for largest mesh
	if ob1.nf < ob2.nf:
	coin_test = ob1.make_coin()
	coin_target = ob2.make_coin()
	else:
	coin_test = ob2.make_coin()
	coin_target = ob1.make_coin()
	# Check for duplicate panels
	deletion_list = []
	for iF in range(numpy.size(coin_test[1, 1, :])):
	panel_test = coin_test[:, :, iF]
	for iFF in range(numpy.size(coin_target[1, 1, :])):
	panel_target = coin_target[:, :, iFF]
	if numpy.sum(panel_test == panel_target) == 12:
	coin_target = numpy.delete(coin_target, iFF, 2)
	deletion_list.append(iF)
	coin_test = numpy.delete(coin_test, deletion_list, 2)

	# Concatenate unique meshes
	coin = numpy.concatenate((coin_test, coin_target), axis=2)
	self.np = numpy.size(coin[1, 1, :]) * 4
	self.nf = numpy.size(coin[1, 1, :])
	self.X = numpy.zeros(numpy.size(coin[1, 1, :]) * 4)
	self.Y = numpy.zeros(numpy.size(coin[1, 1, :]) * 4)
	self.Z = numpy.zeros(numpy.size(coin[1, 1, :]) * 4)
	self.P = numpy.zeros((numpy.size(coin[1, 1, :]), 4), dtype=int)

	iP = 0
	for iF in range(numpy.size(coin[1, 1, :])):
	for iC in range(4):
	self.X[iP] = coin[0, iC, iF]
	self.Y[iP] = coin[1, iC, iF]
	self.Z[iP] = coin[2, iC, iF]
	iP += 1
	self.P[iF, 0] = 1 + iF * 4
	self.P[iF, 1] = 2 + iF * 4
	self.P[iF, 2] = 3 + iF * 4
	self.P[iF, 3] = 4 + iF * 4

	def make_coin(self):
	coin = numpy.zeros((3, 4, self.nf))
	for iF in range(self.nf):
	for iC in range(4):
	coin[0, iC, iF] = self.X[self.P[iF, iC] - 1]
	coin[1, iC, iF] = self.Y[self.P[iF, iC] - 1]
	coin[2, iC, iF] = self.Z[self.P[iF, iC] - 1]
	return coin

	def delete_horizontal_panels(self):
	coin = self.make_coin()
	apex = numpy.min(self.Z)
	zLoc = numpy.zeros(4)
	deletion_list = []

	# Check every panel for horizontality and higher position than lowest point
	for iP in range(self.nf):
	for iC in range(4):
	zLoc[iC] = coin[2, iC, iP]
	if numpy.abs(numpy.mean(zLoc) - zLoc[0]) < 0.001 and numpy.mean(zLoc) > apex:
	deletion_list.append(iP)

	# Delete selected panels
	coin = numpy.delete(coin, deletion_list, 2)

	# Remake mesh
	self.np = numpy.size(coin[1, 1, :]) * 4
	self.nf = numpy.size(coin[1, 1, :])
	self.X = numpy.zeros(numpy.size(coin[1, 1, :]) * 4)
	self.Y = numpy.zeros(numpy.size(coin[1, 1, :]) * 4)
	self.Z = numpy.zeros(numpy.size(coin[1, 1, :]) * 4)
	self.P = numpy.zeros((numpy.size(coin[1, 1, :]), 4), dtype=int)

	iP = 0
	for iF in range(numpy.size(coin[1, 1, :])):
	for iC in range(4):
	self.X[iP] = coin[0, iC, iF]
	self.Y[iP] = coin[1, iC, iF]
	self.Z[iP] = coin[2, iC, iF]
	iP += 1
	self.P[iF, 0] = 1 + (iF) * 4
	self.P[iF, 1] = 2 + (iF) * 4
	self.P[iF, 2] = 3 + (iF) * 4
	self.P[iF, 3] = 4 + (iF) * 4




	def writeMesh(msh, filename):
	with open(filename, 'w') as f:
	f.write('{:d}\n'.format(msh.np))
	f.write('{:d}\n'.format(msh.nf))
	for iP in range(msh.np):
	f.write(' {:.7f} {:.7f} {:.7f}\n'.format(msh.X[iP], msh.Y[iP], msh.Z[iP]))
	for iF in range(msh.nf):
	f.write(' {:d} {:d} {:d} {:d}\n'.format(msh.P[iF, 0], msh.P[iF, 1], msh.P[iF, 2], msh.P[iF, 3]))
	return None



	class box:
	def __init__(self, length, width, height, cCor):
	self.length = length
	self.width = width
	self.height = height
	self.xC = cCor[0]
	self.yC = cCor[1]
	self.zC = cCor[2]
	self.name = 'box'
	self.panelize()
	self.translate(self.xC, self.yC, self.zC)

	def panelize(self):
	self.nf = 6
	self.np = 8
	self.X = numpy.array(
	[-self.length / 2.0, self.length / 2.0, -self.length / 2.0, self.length / 2.0, -self.length / 2.0,
	self.length / 2.0, -self.length / 2.0, self.length / 2.0])
	self.Y = numpy.array([self.width / 2.0, self.width / 2.0, self.width / 2.0, self.width / 2.0, -self.width / 2.0,
	-self.width / 2.0, -self.width / 2.0, -self.width / 2.0])
	self.Z = numpy.array(
	[-self.height / 2.0, -self.height / 2.0, self.height / 2.0, self.height / 2.0, -self.height / 2.0,
	-self.height / 2.0, self.height / 2.0, self.height / 2.0])
	self.P = numpy.zeros([6, 4], dtype=int)
	self.P[0, :] = numpy.array([3, 4, 2, 1])
	self.P[1, :] = numpy.array([4, 8, 6, 2])
	self.P[2, :] = numpy.array([8, 7, 5, 6])
	self.P[3, :] = numpy.array([7, 3, 1, 5])
	self.P[4, :] = numpy.array([2, 6, 5, 1])
	self.P[5, :] = numpy.array([8, 4, 3, 7])
	# Define triangles for plotting
	self.trii = numpy.zeros([2 * self.nf, 3], dtype=int)
	iT = 0
	for iTr in range(self.nf):
	self.trii[iT, :] = [self.P[iTr, 0] - 1, self.P[iTr, 1] - 1, self.P[iTr, 2] - 1]
	self.trii[iT + 1, :] = [self.P[iTr, 0] - 1, self.P[iTr, 2] - 1, self.P[iTr, 3] - 1]
	iT += 2

	def translate(self, xT, yT, zT):
	self.X += xT
	self.Y += yT
	self.Z += zT

	def rotate(self, a1, a2, theta):
	R = numpy.zeros([3, 3])
	# Normal vector through origin
	u = a2[0] - a1[0]
	v = a2[1] - a1[1]
	w = a2[2] - a1[2]
	u = u / numpy.sqrt(u 2 + v 2 + w ** 2)
	v = v / numpy.sqrt(u 2 + v 2 + w ** 2)
	w = w / numpy.sqrt(u 2 + v 2 + w ** 2)
	# Translate mesh so that rotation axis starts from the origin
	self.X -= a1[0]
	self.Y -= a1[1]
	self.Z -= a1[2]

	# Rotation matrix
	R[0, 0] = u ** 2 + numpy.cos(theta) * (1 - u ** 2)
	R[0, 1] = u * v * (1 - numpy.cos(theta)) - w * numpy.sin(theta)
	R[0, 2] = u * w * (1 - numpy.cos(theta)) + v * numpy.sin(theta)
	R[1, 0] = u * v * (1 - numpy.cos(theta)) + w * numpy.sin(theta)
	R[1, 1] = v ** 2 + numpy.cos(theta) * (1 - v ** 2)
	R[1, 2] = v * w * (1 - numpy.cos(theta)) - u * numpy.sin(theta)
	R[2, 0] = w * u * (1 - numpy.cos(theta)) - v * numpy.sin(theta)
	R[2, 1] = w * v * (1 - numpy.cos(theta)) + u * numpy.sin(theta)
	R[2, 2] = w ** 2 + numpy.cos(theta) * (1 - w ** 2)

	for iP in range(self.np):
	p1 = numpy.array([self.X[iP], self.Y[iP], self.Z[iP]])
	p2 = numpy.dot(R, p1)
	self.X[iP] = p2[0]
	self.Y[iP] = p2[1]
	self.Z[iP] = p2[2]

	# Translate back to original position

	self.X += a1[0]
	self.Y += a1[1]
	self.Z += a1[2]

	def makeCoin(self):
	coin = numpy.zeros((3, 4, self.nf))
	for iF in range(self.nf):
	for iC in range(4):
	coin[0, iC, iF] = self.X[self.P[iF, iC] - 1]
	coin[1, iC, iF] = self.Y[self.P[iF, iC] - 1]
	coin[2, iC, iF] = self.Z[self.P[iF, iC] - 1]
	return coin




	class cone:
	def __init__(self, diameter, height, cCor):
	self.diameter = diameter
	self.height = height
	self.xC = cCor[0]
	self.yC = cCor[1]
	self.zC = cCor[2]
	self.name = 'cone'
	self.panelize()
	self.translate(self.xC, self.yC, self.zC)

	def panelize(self):
	Ntheta = 18
	Nz = 3
	theta = [xx * 2 * numpy.pi / (Ntheta - 1) for xx in range(Ntheta)]
	self.nf = 0
	self.np = 0
	r = [0, self.diameter / 2.0, 0]
	z = [0, 0, -self.height]
	self.X = []
	self.Y = []
	self.Z = []
	self.P = numpy.zeros([(len(r) - 1) * (Ntheta - 1), 4], dtype=int)
	n = len(r)

	for iT in range(Ntheta):
	for iN in range(n):
	self.X.append(r[iN] * numpy.cos(theta[iT]))
	self.Y.append(r[iN] * numpy.sin(theta[iT]))
	self.Z.append(z[iN])
	self.np += 1

	iP = 0
	for iN in range(1, n):
	for iT in range(1, Ntheta):
	self.P[iP, 0] = iN + n * (iT - 1)
	self.P[iP, 1] = iN + 1 + n * (iT - 1)
	self.P[iP, 2] = iN + 1 + n * iT
	self.P[iP, 3] = iN + n * iT
	self.nf += 1
	iP += 1

	self.X = numpy.array(self.X)
	self.Y = numpy.array(self.Y)
	self.Z = numpy.array(self.Z)
	# Define triangles for plotting
	self.trii = numpy.zeros([2 * self.nf, 3], dtype=int)
	iT = 0
	for iTr in range(self.nf):
	self.trii[iT, :] = [self.P[iTr, 0] - 1, self.P[iTr, 1] - 1, self.P[iTr, 2] - 1]
	self.trii[iT + 1, :] = [self.P[iTr, 0] - 1, self.P[iTr, 2] - 1, self.P[iTr, 3] - 1]
	iT += 2

	def translate(self, xT, yT, zT):
	self.X += xT
	self.Y += yT
	self.Z += zT

	def rotate(self, a1, a2, theta):
	R = numpy.zeros([3, 3])
	# Normal vector through origin
	u = a2[0] - a1[0]
	v = a2[1] - a1[1]
	w = a2[2] - a1[2]
	u = u / numpy.sqrt(u 2 + v 2 + w ** 2)
	v = v / numpy.sqrt(u 2 + v 2 + w ** 2)
	w = w / numpy.sqrt(u 2 + v 2 + w ** 2)
	# Translate mesh so that rotation axis starts from the origin
	self.X -= a1[0]
	self.Y -= a1[1]
	self.Z -= a1[2]

	# Rotation matrix
	R[0, 0] = u ** 2 + numpy.cos(theta) * (1 - u ** 2)
	R[0, 1] = u * v * (1 - numpy.cos(theta)) - w * numpy.sin(theta)
	R[0, 2] = u * w * (1 - numpy.cos(theta)) + v * numpy.sin(theta)
	R[1, 0] = u * v * (1 - numpy.cos(theta)) + w * numpy.sin(theta)
	R[1, 1] = v ** 2 + numpy.cos(theta) * (1 - v ** 2)
	R[1, 2] = v * w * (1 - numpy.cos(theta)) - u * numpy.sin(theta)
	R[2, 0] = w * u * (1 - numpy.cos(theta)) - v * numpy.sin(theta)
	R[2, 1] = w * v * (1 - numpy.cos(theta)) + u * numpy.sin(theta)
	R[2, 2] = w ** 2 + numpy.cos(theta) * (1 - w ** 2)

	for iP in range(self.np):
	p1 = numpy.array([self.X[iP], self.Y[iP], self.Z[iP]])
	p2 = numpy.dot(R, p1)
	self.X[iP] = p2[0]
	self.Y[iP] = p2[1]
	self.Z[iP] = p2[2]

	# Translate back to original position

	self.X += a1[0]
	self.Y += a1[1]
	self.Z += a1[2]

	def makeCoin(self):
	coin = numpy.zeros((3, 4, self.nf))
	for iF in range(self.nf):
	for iC in range(4):
	coin[0, iC, iF] = self.X[self.P[iF, iC] - 1]
	coin[1, iC, iF] = self.Y[self.P[iF, iC] - 1]
	coin[2, iC, iF] = self.Z[self.P[iF, iC] - 1]
	return coin



	class cylinder:
	def __init__(self, diameter, height, cCor):
	self.diameter = diameter
	self.height = height
	self.xC = cCor[0]
	self.yC = cCor[1]
	self.zC = cCor[2]
	self.name = 'cylinder'
	self.panelize()
	self.translate(self.xC, self.yC, self.zC)

	def panelize(self):
	Ntheta = 18
	Nz = 3
	theta = [xx * 2 * numpy.pi / (Ntheta - 1) for xx in range(Ntheta)]
	self.nf = 0
	self.np = 0
	r = [0, self.diameter / 2.0, self.diameter / 2.0, 0]
	z = [0, 0, -self.height, -self.height]
	self.X = []
	self.Y = []
	self.Z = []
	self.P = numpy.zeros([(len(r) - 1) * (Ntheta - 1), 4], dtype=int)
	n = len(r)

	for iT in range(Ntheta):
	for iN in range(n):
	self.X.append(r[iN] * numpy.cos(theta[iT]))
	self.Y.append(r[iN] * numpy.sin(theta[iT]))
	self.Z.append(z[iN])
	self.np += 1

	iP = 0
	for iN in range(1, n):
	for iT in range(1, Ntheta):
	self.P[iP, 0] = iN + n * (iT - 1)
	self.P[iP, 1] = iN + 1 + n * (iT - 1)
	self.P[iP, 2] = iN + 1 + n * iT
	self.P[iP, 3] = iN + n * iT
	self.nf += 1
	iP += 1

	self.X = numpy.array(self.X)
	self.Y = numpy.array(self.Y)
	self.Z = numpy.array(self.Z)
	# Define triangles for plotting
	self.trii = numpy.zeros([2 * self.nf, 3], dtype=int)
	iT = 0
	for iTr in range(self.nf):
	self.trii[iT, :] = [self.P[iTr, 0] - 1, self.P[iTr, 1] - 1, self.P[iTr, 2] - 1]
	self.trii[iT + 1, :] = [self.P[iTr, 0] - 1, self.P[iTr, 2] - 1, self.P[iTr, 3] - 1]
	iT += 2

	def translate(self, xT, yT, zT):
	self.X += xT
	self.Y += yT
	self.Z += zT

	def rotate(self, a1, a2, theta):
	R = numpy.zeros([3, 3])
	# Normal vector through origin
	u = a2[0] - a1[0]
	v = a2[1] - a1[1]
	w = a2[2] - a1[2]
	u = u / numpy.sqrt(u 2 + v 2 + w ** 2)
	v = v / numpy.sqrt(u 2 + v 2 + w ** 2)
	w = w / numpy.sqrt(u 2 + v 2 + w ** 2)
	# Translate mesh so that rotation axis starts from the origin
	self.X -= a1[0]
	self.Y -= a1[1]
	self.Z -= a1[2]

	# Rotation matrix
	R[0, 0] = u ** 2 + numpy.cos(theta) * (1 - u ** 2)
	R[0, 1] = u * v * (1 - numpy.cos(theta)) - w * numpy.sin(theta)
	R[0, 2] = u * w * (1 - numpy.cos(theta)) + v * numpy.sin(theta)
	R[1, 0] = u * v * (1 - numpy.cos(theta)) + w * numpy.sin(theta)
	R[1, 1] = v ** 2 + numpy.cos(theta) * (1 - v ** 2)
	R[1, 2] = v * w * (1 - numpy.cos(theta)) - u * numpy.sin(theta)
	R[2, 0] = w * u * (1 - numpy.cos(theta)) - v * numpy.sin(theta)
	R[2, 1] = w * v * (1 - numpy.cos(theta)) + u * numpy.sin(theta)
	R[2, 2] = w ** 2 + numpy.cos(theta) * (1 - w ** 2)

	for iP in range(self.np):
	p1 = numpy.array([self.X[iP], self.Y[iP], self.Z[iP]])
	p2 = numpy.dot(R, p1)
	self.X[iP] = p2[0]
	self.Y[iP] = p2[1]
	self.Z[iP] = p2[2]

	# Translate back to original position

	self.X += a1[0]
	self.Y += a1[1]
	self.Z += a1[2]

	def makeCoin(self):
	coin = numpy.zeros((3, 4, self.nf))
	for iF in range(self.nf):
	for iC in range(4):
	coin[0, iC, iF] = self.X[self.P[iF, iC] - 1]
	coin[1, iC, iF] = self.Y[self.P[iF, iC] - 1]
	coin[2, iC, iF] = self.Z[self.P[iF, iC] - 1]
	return coin




	class hemicylinder:
	def __init__(self, diameter, height, cCor):
	self.diameter = diameter
	self.height = height
	self.xC = cCor[0]
	self.yC = cCor[1]
	self.zC = cCor[2]
	self.name = 'hemicylinder'
	self.panelize()
	self.translate(self.xC, self.yC, self.zC)

	def panelize(self):
	Ntheta = 18
	Nz = 3
	theta = [xx * numpy.pi / (Ntheta - 1) - numpy.pi / 2.0 for xx in range(Ntheta)]
	self.nf = 0
	self.np = 0
	r = [0, self.diameter / 2.0, self.diameter / 2.0, 0]
	z = [self.height / 2.0, self.height / 2.0, -self.height / 2.0, -self.height / 2.0]
	self.X = []
	self.Y = []
	self.Z = []
	self.P = numpy.zeros([(len(r) - 1) * (Ntheta - 1), 4], dtype=int)
	n = len(r)

	for iT in range(Ntheta):
	for iN in range(n):
	self.Z.append(-r[iN] * numpy.cos(theta[iT]))
	self.X.append(r[iN] * numpy.sin(theta[iT]))
	self.Y.append(z[iN])
	self.np += 1

	iP = 0
	for iN in range(1, n):
	for iT in range(1, Ntheta):
	self.P[iP, 3] = iN + n * (iT - 1)
	self.P[iP, 2] = iN + 1 + n * (iT - 1)
	self.P[iP, 1] = iN + 1 + n * iT
	self.P[iP, 0] = iN + n * iT
	self.nf += 1
	iP += 1

	self.X = numpy.array(self.X)
	self.Y = numpy.array(self.Y)
	self.Z = numpy.array(self.Z)
	# Define triangles for plotting
	self.trii = numpy.zeros([2 * self.nf, 3], dtype=int)
	iT = 0
	for iTr in range(self.nf):
	self.trii[iT, :] = [self.P[iTr, 0] - 1, self.P[iTr, 1] - 1, self.P[iTr, 2] - 1]
	self.trii[iT + 1, :] = [self.P[iTr, 0] - 1, self.P[iTr, 2] - 1, self.P[iTr, 3] - 1]
	iT += 2

	def translate(self, xT, yT, zT):
	self.X += xT
	self.Y += yT
	self.Z += zT

	def rotate(self, a1, a2, theta):
	R = numpy.zeros([3, 3])
	# Normal vector through origin
	u = a2[0] - a1[0]
	v = a2[1] - a1[1]
	w = a2[2] - a1[2]
	u = u / numpy.sqrt(u 2 + v 2 + w ** 2)
	v = v / numpy.sqrt(u 2 + v 2 + w ** 2)
	w = w / numpy.sqrt(u 2 + v 2 + w ** 2)
	# Translate mesh so that rotation axis starts from the origin
	self.X -= a1[0]
	self.Y -= a1[1]
	self.Z -= a1[2]

	# Rotation matrix
	R[0, 0] = u ** 2 + numpy.cos(theta) * (1 - u ** 2)
	R[0, 1] = u * v * (1 - numpy.cos(theta)) - w * numpy.sin(theta)
	R[0, 2] = u * w * (1 - numpy.cos(theta)) + v * numpy.sin(theta)
	R[1, 0] = u * v * (1 - numpy.cos(theta)) + w * numpy.sin(theta)
	R[1, 1] = v ** 2 + numpy.cos(theta) * (1 - v ** 2)
	R[1, 2] = v * w * (1 - numpy.cos(theta)) - u * numpy.sin(theta)
	R[2, 0] = w * u * (1 - numpy.cos(theta)) - v * numpy.sin(theta)
	R[2, 1] = w * v * (1 - numpy.cos(theta)) + u * numpy.sin(theta)
	R[2, 2] = w ** 2 + numpy.cos(theta) * (1 - w ** 2)

	for iP in range(self.np):
	p1 = numpy.array([self.X[iP], self.Y[iP], self.Z[iP]])
	p2 = numpy.dot(R, p1)
	self.X[iP] = p2[0]
	self.Y[iP] = p2[1]
	self.Z[iP] = p2[2]

	# Translate back to original position

	self.X += a1[0]
	self.Y += a1[1]
	self.Z += a1[2]

	def makeCoin(self):
	coin = numpy.zeros((3, 4, self.nf))
	for iF in range(self.nf):
	for iC in range(4):
	coin[0, iC, iF] = self.X[self.P[iF, iC] - 1]
	coin[1, iC, iF] = self.Y[self.P[iF, iC] - 1]
	coin[2, iC, iF] = self.Z[self.P[iF, iC] - 1]
	return coin


	class sphere:
	def __init__(self, diameter, cCor):
	self.diameter = diameter
	self.xC = cCor[0]
	self.yC = cCor[1]
	self.zC = cCor[2]
	self.name = 'sphere'
	self.panelize()
	self.translate(self.xC, self.yC, self.zC)

	def panelize(self):
	Ntheta = 18
	Nthetad2 = int(Ntheta / 2)
	Nz = 3
	theta = [xx * 2 * numpy.pi / (Ntheta - 1) for xx in range(Ntheta)]
	phi = [xx * numpy.pi / (Ntheta / 2 - 1) for xx in range(Nthetad2)]
	self.nf = 0
	self.np = 0
	r = self.diameter / 2.0
	self.X = []
	self.Y = []
	self.Z = []
	self.P = numpy.zeros([(Ntheta - 1) * (Nthetad2 - 1), 4], dtype=int)

	for iT in range(Nthetad2):
	for iTT in range(Ntheta):
	self.X.append(r * numpy.cos(theta[iTT]) * numpy.sin(phi[iT]))
	self.Y.append(r * numpy.sin(theta[iTT]) * numpy.sin(phi[iT]))
	self.Z.append(r * numpy.cos(phi[iT]))
	self.np += 1

	iP = 0
	for iN in range(1, Ntheta):
	for iT in range(1, Nthetad2):
	self.P[iP, 3] = iN + Ntheta * (iT - 1)
	self.P[iP, 2] = iN + 1 + Ntheta * (iT - 1)
	self.P[iP, 1] = iN + 1 + Ntheta * iT
	self.P[iP, 0] = iN + Ntheta * iT
	self.nf += 1
	iP += 1
	self.X = numpy.array(self.X)
	self.Y = numpy.array(self.Y)
	self.Z = numpy.array(self.Z)
	# Define triangles for plotting
	self.trii = numpy.zeros([2 * self.nf, 3], dtype=int)
	iT = 0
	for iTr in range(self.nf):
	self.trii[iT, :] = [self.P[iTr, 0] - 1, self.P[iTr, 1] - 1, self.P[iTr, 2] - 1]
	self.trii[iT + 1, :] = [self.P[iTr, 0] - 1, self.P[iTr, 2] - 1, self.P[iTr, 3] - 1]
	iT += 2

	def translate(self, xT, yT, zT):
	self.X += xT
	self.Y += yT
	self.Z += zT

	def rotate(self, a1, a2, theta):
	R = numpy.zeros([3, 3])
	# Normal vector through origin
	u = a2[0] - a1[0]
	v = a2[1] - a1[1]
	w = a2[2] - a1[2]
	u = u / numpy.sqrt(u 2 + v 2 + w ** 2)
	v = v / numpy.sqrt(u 2 + v 2 + w ** 2)
	w = w / numpy.sqrt(u 2 + v 2 + w ** 2)
	# Translate mesh so that rotation axis starts from the origin
	self.X -= a1[0]
	self.Y -= a1[1]
	self.Z -= a1[2]

	# Rotation matrix
	R[0, 0] = u ** 2 + numpy.cos(theta) * (1 - u ** 2)
	R[0, 1] = u * v * (1 - numpy.cos(theta)) - w * numpy.sin(theta)
	R[0, 2] = u * w * (1 - numpy.cos(theta)) + v * numpy.sin(theta)
	R[1, 0] = u * v * (1 - numpy.cos(theta)) + w * numpy.sin(theta)
	R[1, 1] = v ** 2 + numpy.cos(theta) * (1 - v ** 2)
	R[1, 2] = v * w * (1 - numpy.cos(theta)) - u * numpy.sin(theta)
	R[2, 0] = w * u * (1 - numpy.cos(theta)) - v * numpy.sin(theta)
	R[2, 1] = w * v * (1 - numpy.cos(theta)) + u * numpy.sin(theta)
	R[2, 2] = w ** 2 + numpy.cos(theta) * (1 - w ** 2)

	for iP in range(self.np):
	p1 = numpy.array([self.X[iP], self.Y[iP], self.Z[iP]])
	p2 = numpy.dot(R, p1)
	self.X[iP] = p2[0]
	self.Y[iP] = p2[1]
	self.Z[iP] = p2[2]

	# Translate back to original position

	self.X += a1[0]
	self.Y += a1[1]
	self.Z += a1[2]

	def makeCoin(self):
	coin = numpy.zeros((3, 4, self.nf))
	for iF in range(self.nf):
	for iC in range(4):
	coin[0, iC, iF] = self.X[self.P[iF, iC] - 1]
	coin[1, iC, iF] = self.Y[self.P[iF, iC] - 1]
	coin[2, iC, iF] = self.Z[self.P[iF, iC] - 1]
	return coin





	class hemisphere:
	def __init__(self, diameter, cCor):
	self.diameter = diameter
	self.xC = cCor[0]
	self.yC = cCor[1]
	self.zC = cCor[2]
	self.name = 'hemisphere'
	self.panelize()
	self.translate(self.xC, self.yC, self.zC)

	def panelize(self):
	Ntheta = 18
	theta = [xx * 2 * numpy.pi / (Ntheta - 1) for xx in range(Ntheta)]
	phi = [xx * numpy.pi / 2.0 / (Ntheta / 2 - 1) for xx in range(Ntheta / 2)]
	self.nf = 0
	self.np = 0
	r = self.diameter / 2.0
	self.X = []
	self.Y = []
	self.Z = []
	self.P = numpy.zeros([(Ntheta - 1) * (Ntheta / 2 - 1), 4], dtype=int)

	for iT in range(Ntheta / 2):
	for iTT in range(Ntheta):
	self.X.append(r * numpy.cos(theta[iTT]) * numpy.sin(phi[iT]))
	self.Y.append(r * numpy.sin(theta[iTT]) * numpy.sin(phi[iT]))
	self.Z.append(-r * numpy.cos(phi[iT]))
	self.np += 1

	iP = 0
	for iN in range(1, Ntheta):
	for iT in range(1, Ntheta / 2):
	self.P[iP, 0] = iN + Ntheta * (iT - 1)
	self.P[iP, 1] = iN + 1 + Ntheta * (iT - 1)
	self.P[iP, 2] = iN + 1 + Ntheta * iT
	self.P[iP, 3] = iN + Ntheta * iT
	self.nf += 1
	iP += 1

	self.X = numpy.array(self.X)
	self.Y = numpy.array(self.Y)
	self.Z = numpy.array(self.Z)
	# Define triangles for plotting
	self.trii = numpy.zeros([2 * self.nf, 3], dtype=int)
	iT = 0
	for iTr in range(self.nf):
	self.trii[iT, :] = [self.P[iTr, 0] - 1, self.P[iTr, 1] - 1, self.P[iTr, 2] - 1]
	self.trii[iT + 1, :] = [self.P[iTr, 0] - 1, self.P[iTr, 2] - 1, self.P[iTr, 3] - 1]
	iT += 2

	def translate(self, xT, yT, zT):
	self.X += xT
	self.Y += yT
	self.Z += zT

	def rotate(self, a1, a2, theta):
	R = numpy.zeros([3, 3])
	# Normal vector through origin
	u = a2[0] - a1[0]
	v = a2[1] - a1[1]
	w = a2[2] - a1[2]
	u = u / numpy.sqrt(u 2 + v 2 + w ** 2)
	v = v / numpy.sqrt(u 2 + v 2 + w ** 2)
	w = w / numpy.sqrt(u 2 + v 2 + w ** 2)
	# Translate mesh so that rotation axis starts from the origin
	self.X -= a1[0]
	self.Y -= a1[1]
	self.Z -= a1[2]

	# Rotation matrix
	R[0, 0] = u ** 2 + numpy.cos(theta) * (1 - u ** 2)
	R[0, 1] = u * v * (1 - numpy.cos(theta)) - w * numpy.sin(theta)
	R[0, 2] = u * w * (1 - numpy.cos(theta)) + v * numpy.sin(theta)
	R[1, 0] = u * v * (1 - numpy.cos(theta)) + w * numpy.sin(theta)
	R[1, 1] = v ** 2 + numpy.cos(theta) * (1 - v ** 2)
	R[1, 2] = v * w * (1 - numpy.cos(theta)) - u * numpy.sin(theta)
	R[2, 0] = w * u * (1 - numpy.cos(theta)) - v * numpy.sin(theta)
	R[2, 1] = w * v * (1 - numpy.cos(theta)) + u * numpy.sin(theta)
	R[2, 2] = w ** 2 + numpy.cos(theta) * (1 - w ** 2)

	for iP in range(self.np):
	p1 = numpy.array([self.X[iP], self.Y[iP], self.Z[iP]])
	p2 = numpy.dot(R, p1)
	self.X[iP] = p2[0]
	self.Y[iP] = p2[1]
	self.Z[iP] = p2[2]

	# Translate back to original position

	self.X += a1[0]
	self.Y += a1[1]
	self.Z += a1[2]

	def makeCoin(self):
	coin = numpy.zeros((3, 4, self.nf))
	for iF in range(self.nf):
	for iC in range(4):
	coin[0, iC, iF] = self.X[self.P[iF, iC] - 1]
	coin[1, iC, iF] = self.Y[self.P[iF, iC] - 1]
	coin[2, iC, iF] = self.Z[self.P[iF, iC] - 1]
	return coin




	class pyramid:
	def __init__(self, length, width, height, cCor):
	self.length = length
	self.width = width
	self.height = height
	self.xC = cCor[0]
	self.yC = cCor[1]
	self.zC = cCor[2]
	self.name = 'pyramid'
	self.panelize()
	self.translate(self.xC, self.yC, self.zC)

	def panelize(self):
	self.nf = 6
	self.np = 8
	self.X = numpy.array(
	[0.0, 0.0, -self.length / 2.0, self.length / 2.0, 0.0, 0.0, -self.length / 2.0, self.length / 2.0])
	self.Y = numpy.array(
	[0.0, 0.0, self.width / 2.0, self.width / 2.0, 0.0, 0.0, -self.width / 2.0, -self.width / 2.0])
	self.Z = numpy.array([-self.height, -self.height, 0.0, 0.0, -self.height, -self.height, 0.0, 0.0])
	self.P = numpy.zeros([6, 4], dtype=int)
	self.P[0, :] = numpy.array([3, 4, 2, 1])
	self.P[1, :] = numpy.array([4, 8, 6, 2])
	self.P[2, :] = numpy.array([8, 7, 5, 6])
	self.P[3, :] = numpy.array([7, 3, 1, 5])
	self.P[4, :] = numpy.array([5, 6, 5, 1])
	self.P[5, :] = numpy.array([8, 4, 3, 7])
	# Define triangles for plotting
	self.trii = numpy.zeros([2 * self.nf, 3], dtype=int)
	iT = 0
	for iTr in range(self.nf):
	self.trii[iT, :] = [self.P[iTr, 0] - 1, self.P[iTr, 1] - 1, self.P[iTr, 2] - 1]
	self.trii[iT + 1, :] = [self.P[iTr, 0] - 1, self.P[iTr, 2] - 1, self.P[iTr, 3] - 1]
	iT += 2

	def translate(self, xT, yT, zT):
	self.X += xT
	self.Y += yT
	self.Z += zT

	def rotate(self, a1, a2, theta):
	R = numpy.zeros([3, 3])
	# Normal vector through origin
	u = a2[0] - a1[0]
	v = a2[1] - a1[1]
	w = a2[2] - a1[2]
	u = u / numpy.sqrt(u 2 + v 2 + w ** 2)
	v = v / numpy.sqrt(u 2 + v 2 + w ** 2)
	w = w / numpy.sqrt(u 2 + v 2 + w ** 2)
	# Translate mesh so that rotation axis starts from the origin
	self.X -= a1[0]
	self.Y -= a1[1]
	self.Z -= a1[2]

	# Rotation matrix
	R[0, 0] = u ** 2 + numpy.cos(theta) * (1 - u ** 2)
	R[0, 1] = u * v * (1 - numpy.cos(theta)) - w * numpy.sin(theta)
	R[0, 2] = u * w * (1 - numpy.cos(theta)) + v * numpy.sin(theta)
	R[1, 0] = u * v * (1 - numpy.cos(theta)) + w * numpy.sin(theta)
	R[1, 1] = v ** 2 + numpy.cos(theta) * (1 - v ** 2)
	R[1, 2] = v * w * (1 - numpy.cos(theta)) - u * numpy.sin(theta)
	R[2, 0] = w * u * (1 - numpy.cos(theta)) - v * numpy.sin(theta)
	R[2, 1] = w * v * (1 - numpy.cos(theta)) + u * numpy.sin(theta)
	R[2, 2] = w ** 2 + numpy.cos(theta) * (1 - w ** 2)

	for iP in range(self.np):
	p1 = numpy.array([self.X[iP], self.Y[iP], self.Z[iP]])
	p2 = numpy.dot(R, p1)
	self.X[iP] = p2[0]
	self.Y[iP] = p2[1]
	self.Z[iP] = p2[2]

	# Translate back to original position

	self.X += a1[0]
	self.Y += a1[1]
	self.Z += a1[2]

	def makeCoin(self):
	coin = numpy.zeros((3, 4, self.nf))
	for iF in range(self.nf):
	for iC in range(4):
	coin[0, iC, iF] = self.X[self.P[iF, iC] - 1]
	coin[1, iC, iF] = self.Y[self.P[iF, iC] - 1]
	coin[2, iC, iF] = self.Z[self.P[iF, iC] - 1]
	return coin





	class wedge:
	def __init__(self, length, width, height, cCor):
	self.length = length
	self.width = width
	self.height = height
	self.xC = cCor[0]
	self.yC = cCor[1]
	self.zC = cCor[2]
	self.name = 'wedge'
	self.panelize()
	self.translate(self.xC, self.yC, self.zC)

	def panelize(self):
	self.nf = 6
	self.np = 8
	self.X = numpy.array(
	[0.0, 0.0, -self.length / 2.0, self.length / 2.0, 0.0, 0.0, -self.length / 2.0, self.length / 2.0])
	self.Y = numpy.array([self.width / 2.0, self.width / 2.0, self.width / 2.0, self.width / 2.0, -self.width / 2.0,
	-self.width / 2.0, -self.width / 2.0, -self.width / 2.0])
	self.Z = numpy.array([-self.height, -self.height, 0.0, 0.0, -self.height, -self.height, 0.0, 0.0])
	self.P = numpy.zeros([6, 4], dtype=int)
	self.P[0, :] = numpy.array([3, 4, 2, 1])
	self.P[1, :] = numpy.array([4, 8, 6, 2])
	self.P[2, :] = numpy.array([8, 7, 5, 6])
	self.P[3, :] = numpy.array([7, 3, 1, 5])
	self.P[4, :] = numpy.array([2, 6, 5, 1])
	self.P[5, :] = numpy.array([8, 4, 3, 7])
	# Define triangles for plotting
	self.trii = numpy.zeros([2 * self.nf, 3], dtype=int)
	iT = 0
	for iTr in range(self.nf):
	self.trii[iT, :] = [self.P[iTr, 0] - 1, self.P[iTr, 1] - 1, self.P[iTr, 2] - 1]
	self.trii[iT + 1, :] = [self.P[iTr, 0] - 1, self.P[iTr, 2] - 1, self.P[iTr, 3] - 1]
	iT += 2

	def translate(self, xT, yT, zT):
	self.X += xT
	self.Y += yT
	self.Z += zT

	def rotate(self, a1, a2, theta):
	R = numpy.zeros([3, 3])
	# Normal vector through origin
	u = a2[0] - a1[0]
	v = a2[1] - a1[1]
	w = a2[2] - a1[2]
	u = u / numpy.sqrt(u 2 + v 2 + w ** 2)
	v = v / numpy.sqrt(u 2 + v 2 + w ** 2)
	w = w / numpy.sqrt(u 2 + v 2 + w ** 2)
	# Translate mesh so that rotation axis starts from the origin
	self.X -= a1[0]
	self.Y -= a1[1]
	self.Z -= a1[2]

	# Rotation matrix
	R[0, 0] = u ** 2 + numpy.cos(theta) * (1 - u ** 2)
	R[0, 1] = u * v * (1 - numpy.cos(theta)) - w * numpy.sin(theta)
	R[0, 2] = u * w * (1 - numpy.cos(theta)) + v * numpy.sin(theta)
	R[1, 0] = u * v * (1 - numpy.cos(theta)) + w * numpy.sin(theta)
	R[1, 1] = v ** 2 + numpy.cos(theta) * (1 - v ** 2)
	R[1, 2] = v * w * (1 - numpy.cos(theta)) - u * numpy.sin(theta)
	R[2, 0] = w * u * (1 - numpy.cos(theta)) - v * numpy.sin(theta)
	R[2, 1] = w * v * (1 - numpy.cos(theta)) + u * numpy.sin(theta)
	R[2, 2] = w ** 2 + numpy.cos(theta) * (1 - w ** 2)

	for iP in range(self.np):
	p1 = numpy.array([self.X[iP], self.Y[iP], self.Z[iP]])
	p2 = numpy.dot(R, p1)
	self.X[iP] = p2[0]
	self.Y[iP] = p2[1]
	self.Z[iP] = p2[2]

	# Translate back to original position

	self.X += a1[0]
	self.Y += a1[1]
	self.Z += a1[2]

	def makeCoin(self):
	coin = numpy.zeros((3, 4, self.nf))
	for iF in range(self.nf):
	for iC in range(4):
	coin[0, iC, iF] = self.X[self.P[iF, iC] - 1]
	coin[1, iC, iF] = self.Y[self.P[iF, iC] - 1]
	coin[2, iC, iF] = self.Z[self.P[iF, iC] - 1]
	return coin





	class torus:
	def __init__(self, diamOut, diamIn, cCor):
	self.diamOut = diamOut
	self.diamIn = diamIn
	self.xC = cCor[0]
	self.yC = cCor[1]
	self.zC = cCor[2]
	self.name = 'torus'
	self.panelize()
	self.translate(self.xC, self.yC, self.zC)

	def panelize(self):
	Ntheta = 18
	Nphi = 18
	theta = [xx * 2 * numpy.pi / (Ntheta - 1) for xx in range(Ntheta)]
	phi = [xx * 2 * numpy.pi / (Nphi - 1) for xx in range(Nphi)]
	self.nf = 0
	self.np = 0
	self.X = []
	self.Y = []
	self.Z = []
	R = self.diamOut / 2.0
	r = self.diamIn / 2.0

	for iT in range(Ntheta):
	for iP in range(Nphi):
	self.X.append((R + r * numpy.cos(theta[iT])) * numpy.cos(phi[iP]))
	self.Y.append((R + r * numpy.cos(theta[iT])) * numpy.sin(phi[iP]))
	self.Z.append(r * numpy.sin(theta[iT]))
	self.np += 1

	self.nf = (Ntheta - 1) * (Nphi - 1)
	self.P = numpy.zeros([self.nf, 4], dtype=int)
	iPan = 0
	for iT in range(Ntheta - 1):
	for iP in range(Nphi - 1):
	self.P[iPan, 0] = iP + iT * Nphi + 1
	self.P[iPan, 1] = iP + 1 + iT * Nphi + 1
	self.P[iPan, 2] = iP + 1 + Ntheta + iT * Nphi + 1
	self.P[iPan, 3] = iP + Ntheta + iT * Nphi + 1
	iPan += 1

	self.X = numpy.array(self.X)
	self.Y = numpy.array(self.Y)
	self.Z = numpy.array(self.Z)
	# Define triangles for plotting
	self.trii = numpy.zeros([2 * self.nf, 3], dtype=int)
	iT = 0
	for iTr in range(self.nf):
	self.trii[iT, :] = [self.P[iTr, 0] - 1, self.P[iTr, 1] - 1, self.P[iTr, 2] - 1]
	self.trii[iT + 1, :] = [self.P[iTr, 0] - 1, self.P[iTr, 2] - 1, self.P[iTr, 3] - 1]
	iT += 2

	def translate(self, xT, yT, zT):
	self.X += xT
	self.Y += yT
	self.Z += zT

	def rotate(self, a1, a2, theta):
	R = numpy.zeros([3, 3])
	# Normal vector through origin
	u = a2[0] - a1[0]
	v = a2[1] - a1[1]
	w = a2[2] - a1[2]
	u = u / numpy.sqrt(u 2 + v 2 + w ** 2)
	v = v / numpy.sqrt(u 2 + v 2 + w ** 2)
	w = w / numpy.sqrt(u 2 + v 2 + w ** 2)
	# Translate mesh so that rotation axis starts from the origin
	self.X -= a1[0]
	self.Y -= a1[1]
	self.Z -= a1[2]

	# Rotation matrix
	R[0, 0] = u ** 2 + numpy.cos(theta) * (1 - u ** 2)
	R[0, 1] = u * v * (1 - numpy.cos(theta)) - w * numpy.sin(theta)
	R[0, 2] = u * w * (1 - numpy.cos(theta)) + v * numpy.sin(theta)
	R[1, 0] = u * v * (1 - numpy.cos(theta)) + w * numpy.sin(theta)
	R[1, 1] = v ** 2 + numpy.cos(theta) * (1 - v ** 2)
	R[1, 2] = v * w * (1 - numpy.cos(theta)) - u * numpy.sin(theta)
	R[2, 0] = w * u * (1 - numpy.cos(theta)) - v * numpy.sin(theta)
	R[2, 1] = w * v * (1 - numpy.cos(theta)) + u * numpy.sin(theta)
	R[2, 2] = w ** 2 + numpy.cos(theta) * (1 - w ** 2)

	for iP in range(self.np):
	p1 = numpy.array([self.X[iP], self.Y[iP], self.Z[iP]])
	p2 = numpy.dot(R, p1)
	self.X[iP] = p2[0]
	self.Y[iP] = p2[1]
	self.Z[iP] = p2[2]

	# Translate back to original position

	self.X += a1[0]
	self.Y += a1[1]
	self.Z += a1[2]

	def makeCoin(self):
	coin = numpy.zeros((3, 4, self.nf))
	for iF in range(self.nf):
	for iC in range(4):
	coin[0, iC, iF] = self.X[self.P[iF, iC] - 1]
	coin[1, iC, iF] = self.Y[self.P[iF, iC] - 1]
	coin[2, iC, iF] = self.Z[self.P[iF, iC] - 1]
	return coin

	def make_voxels_without_figure(shape, length, height, width, diameter):
	pos = [0, 0, 0]
	if shape == "box":
	mesh = box(length, width, height, pos)
	elif shape == "cone":
	mesh = cone(diameter, height, pos)
	elif shape == "cylinder":
	mesh = cylinder(diameter, height, pos)
	elif shape == "sphere":
	mesh = sphere(diameter, pos)
	elif shape == "wedge":
	mesh = wedge(length, width, height, pos)

	hull_points = numpy.array([mesh.X.tolist(), mesh.Y.tolist(), mesh.Z.tolist()]).T

	# Set up test points
	G = 32
	ex = 5 - 5 / G
	x, y, z = numpy.meshgrid(numpy.linspace(-ex, ex, G),
	numpy.linspace(-ex, ex, G),
	numpy.linspace(-(9.5 - 5 / G), 0.5 - 5 / G, G))
	test_points = numpy.vstack((x.ravel(), y.ravel(), z.ravel())).T

	hull = scipy.spatial.Delaunay(hull_points)
	within = hull.find_simplex(test_points) >= 0

	return within*1.0


	def make_voxels(shape, length, height, width, diameter):
	return plotly_fig(make_voxels_without_figure(shape, length, height, width, diameter))

	# This function loads a fuckton of data
	# def load_data():
	# # Open all the files we downloaded at the beginning and take out hte good bits
	# curves = numpy.load('data_curves.npz')['curves']
	# geometry = numpy.load('data_geometry.npz')['geometry']
	# constants = numpy.load('constants.npz')
	# S = constants['S']
	# N = constants['N']
	# D = constants['D']
	# F = constants['F']
	# G = constants['G']

	# # Some of the good bits need additional processining
	# new_curves = numpy.zeros((SN, D F))
	# for i, curveset in enumerate(curves):
	# new_curves[i, :] = curveset.T.flatten() / 1000000

	# new_geometry = numpy.zeros((SN, G G * G))
	# for i, geometryset in enumerate(geometry):
	# new_geometry[i, :] = geometryset.T.flatten()

	# # Return good bits to user
	# return curves, geometry, S, N, D, F, G, new_curves, new_geometry

	curves, geometry, S, N, D, F, G, new_curves, new_geometry = load_data()

	class Network(object):

	def __init__(self, type):
	# Instantiate variables
	# self.curves = curves
	# self.new_curves = new_curves
	# self.geometry = geometry
	# self.new_geometry = new_geometry
	# self.S = S
	# self.N = N
	# self.D = D
	# self.F = F
	# self.G = G

	# Load network
	# with open(structure, 'r') as file:
	# self.network = keras.models.model_from_json(file.read())
	# self.network.load_weights(weights)
	self.network = from_pretrained_keras("cmudrc/wave-energy-analysis") if type == "forward" else from_pretrained_keras("cmudrc/wave-energy-synthesis")

	def analysis(self, idx=None):
	print(idx)

	if idx is None:
	idx = numpy.random.randint(1, S * N)
	else:
	idx = int(idx)

	# Get the input
	data_input = new_geometry[idx:(idx+1), :]
	other_data_input = data_input.reshape((G, G, G), order='F')

	# Get the outputs
	print(data_input.shape)
	predicted_output = self.network.predict(data_input)
	true_output = new_curves[idx].reshape((3, F))
	predicted_output = predicted_output.reshape((3, F))

	f = numpy.linspace(0.05, 2.0, 64)
	fd = pandas.DataFrame(f).rename(columns={0: "Frequency"})
	df_pred = pandas.DataFrame(predicted_output.transpose()).rename(columns={0: "Surge", 1: "Heave", 2: "Pitch"})
	df_true = pandas.DataFrame(true_output.transpose()).rename(columns={0: "Surge", 1: "Heave", 2: "Pitch"})

	# return idx, other_data_input, true_output, predicted_output
	return pandas.concat([fd, df_pred], axis=1), pandas.concat([fd, df_true], axis=1)


	def analysis_from_geometry(self, geometry):
	# Get the outputs
	predicted_output = self.network.predict(numpy.array([geometry.flatten().tolist()]))
	predicted_output = predicted_output.reshape((3, F))

	f = numpy.linspace(0.05, 2.0, 64)
	fd = pandas.DataFrame(f).rename(columns={0: "Frequency"})
	df_pred = pandas.DataFrame(predicted_output.transpose()).rename(columns={0: "Surge", 1: "Heave", 2: "Pitch"})
	good_frame = pandas.concat([fd, df_pred], axis=1)

	return good_frame, good_frame

	def synthesis(self, idx=None):
	print(idx)

	if idx is None:
	idx = numpy.random.randint(1, S * N)
	else:
	idx = int(idx)

	# Get the input
	data_input = new_curves[idx:(idx+1), :]
	other_data_input = data_input.reshape((3, F))

	# Get the outputs
	predicted_output = self.network.predict(data_input)
	true_output = new_geometry[idx].reshape((G, G, G), order='F')
	predicted_output = predicted_output.reshape((G, G, G), order='F')

	# return idx, other_data_input, true_output, predicted_output
	return predicted_output, true_output


	def synthesis_from_spectrum(self, other_data_input):
	# Get the input
	data_input = other_data_input.reshape((1, 3*F))

	# Get the outputs
	predicted_output = self.network.predict(data_input)
	predicted_output = predicted_output.reshape((G, G, G), order='F')

	# return idx, other_data_input, true_output, predicted_output
	return predicted_output

	def get_geometry(self, idx=None):

	if idx is None:
	idx = numpy.random.randint(1, S * N)
	else:
	idx = int(idx)

	idx = int(idx)

	# Get the input
	data_input = new_geometry[idx:(idx+1), :]
	other_data_input = data_input.reshape((G, G, G), order='F')

	# return idx, other_data_input, true_output, predicted_output
	return other_data_input


	def get_performance(self, idx=None):

	if idx is None:
	idx = numpy.random.randint(1, S *N)
	else:
	idx = int(idx)

	idx = int(idx)

	# Get the input
	data_input = new_curves[idx:(idx+1), :]
	other_data_input = data_input.reshape((3, F))

	f = numpy.linspace(0.05, 2.0, 64)
	fd = pandas.DataFrame(f).rename(columns={0: "Frequency"})
	df_pred = pandas.DataFrame(other_data_input.transpose()).rename(columns={0: "Surge", 1: "Heave", 2: "Pitch"})
	table = pandas.concat([fd, df_pred], axis=1)

	return table


	def plotly_fig(values):
	X, Y, Z = numpy.mgrid[0:1:32j, 0:1:32j, 0:1:32j]
	fig = go.Figure(data=go.Volume(
	x=X.flatten(),
	y=Y.flatten(),
	z=Z.flatten(),
	value=values.flatten(),
	isomin=0.0,
	isomax=1.0,
	opacity=0.1, # needs to be small to see through all surfaces
	surface_count=21, # needs to be a large number for good volume rendering
	colorscale='haline'
	))
	return fig


	value_net = Network("forward")

	def performance(index):
	return value_net.get_performance(index)

	def geometry(index):
	values = value_net.get_geometry(index)
	return plotly_fig(values)

	def simple_analysis(index, choice, shape, length, width, height, diameter):
	forward_net = Network("forward")
	# forward_net = Network("16forward_structure.json", "16forward_weights.h5")
	if choice == "Construct Shape from Parameters":
	return forward_net.analysis_from_geometry(make_voxels_without_figure(shape, length, height, width, diameter))
	elif choice == "Pick Shape from Dataset":
	return forward_net.analysis(index)


	def simple_synthesis(index):
	inverse_net = Network("inverse")
	# inverse_net = Network("16inverse_structure.json", "16inverse_weights.h5")
	pred, true = inverse_net.synthesis(index)
	return plotly_fig(pred), plotly_fig(true)

	def synthesis_from_spectrum(df):
	inverse_net = Network("inverse")
	# inverse_net = Network("16inverse_structure.json", "16inverse_weights.h5")
	pred = inverse_net.synthesis_from_spectrum(df.to_numpy()[:, 1:])
	return plotly_fig(pred)



	def change_textbox(choice, length, height, width, diameter):
	fig = make_voxels(choice, length, height, width, diameter)
	if choice == "cylinder":
	return [gradio.Slider.update(visible=True), gradio.Slider.update(visible=False), gradio.Slider.update(visible=True), gradio.Slider.update(visible=False), gradio.Plot.update(fig)]
	elif choice == "sphere":
	return [gradio.Slider.update(visible=False), gradio.Slider.update(visible=False), gradio.Slider.update(visible=True), gradio.Slider.update(visible=False), gradio.Plot.update(fig)]
	elif choice == "box":
	return [gradio.Slider.update(visible=True), gradio.Slider.update(visible=True), gradio.Slider.update(visible=False), gradio.Slider.update(visible=True), gradio.Plot.update(fig)]
	elif choice == "wedge":
	return [gradio.Slider.update(visible=True), gradio.Slider.update(visible=True), gradio.Slider.update(visible=False), gradio.Slider.update(visible=True), gradio.Plot.update(fig)]
	elif choice == "cone":
	return [gradio.Slider.update(visible=True), gradio.Slider.update(visible=False), gradio.Slider.update(visible=True), gradio.Slider.update(visible=False), gradio.Plot.update(fig)]



	def randomize_analysis(choice):
	if choice == "Construct Shape from Parameters":
	length = random.uniform(3.0, 10.0)
	height = random.uniform(3.0, 10.0)
	width = random.uniform(3.0, 10.0)
	diameter = random.uniform(3.0, 10.0)
	choice2 = random.choice(["box", "cone", "sphere", "wedge", "cone"])
	if choice2 == "box" or choice2 == "wedge":
	return [gradio.Radio.update(choice2), gradio.Slider.update(length), gradio.Slider.update(height), gradio.Slider.update(width), gradio.Slider.update(), gradio.Number.update(), gradio.Plot.update(make_voxels(choice2, length, height, width, diameter))]
	elif choice2 == "cone" or choice2 == "cylinder":
	return [gradio.Radio.update(choice2), gradio.Slider.update(), gradio.Slider.update(height), gradio.Slider.update(), gradio.Slider.update(diameter), gradio.Number.update(), gradio.Plot.update(make_voxels(choice2, length, height, width, diameter))]
	elif choice2 == "sphere":
	return [gradio.Radio.update(choice2), gradio.Slider.update(), gradio.Slider.update(), gradio.Slider.update(), gradio.Slider.update(diameter), gradio.Number.update(), gradio.Plot.update(make_voxels(choice2, length, height, width, diameter))]
	elif choice == "Pick Shape from Dataset":
	num = random.randint(1, 4999)
	return [gradio.Radio.update(), gradio.Slider.update(), gradio.Slider.update(), gradio.Slider.update(), gradio.Slider.update(), gradio.Number.update(num), gradio.Plot.update(geometry(num))]



	def geometry_change(choice, choice2, num, length, width, height, diameter):
	if choice == "Construct Shape from Parameters":
	[slider1, slider2, slider3, slider4, plot] = change_textbox(choice2, length, height, width, diameter)
	return [gradio.Radio.update(visible=True), slider1, slider2, slider3, slider4, gradio.Number.update(visible=False), gradio.Timeseries.update(visible=False), gradio.Plot.update(make_voxels(choice2, length, height, width, diameter))]
	elif choice == "Pick Shape from Dataset":
	return [gradio.Radio.update(visible=False), gradio.Slider.update(visible=False), gradio.Slider.update(visible=False), gradio.Slider.update(visible=False), gradio.Slider.update(visible=False), gradio.Number.update(visible=True), gradio.Timeseries.update(visible=True), gradio.Plot.update(geometry(num))]

	with gradio.Blocks() as demo:
	with gradio.Accordion("✨ Read about the underlying ML model here! ✨", open=False):
	with gradio.Row():
	with gradio.Column():
	gradio.Markdown("# Toward the Rapid Design of Engineered Systems Through Deep Neural Networks")
	gradio.HTML("Christopher McComb, Carnegie Mellon University")
	gradio.Markdown("__Abstract__: The design of a system commits a significant portion of the final cost of that system. Many computational approaches have been developed to assist designers in the analysis (e.g., computational fluid dynamics) and synthesis (e.g., topology optimization) of engineered systems. However, many of these approaches are computationally intensive, taking significant time to complete an analysis and even longer to iteratively synthesize a solution. The current work proposes a methodology for rapidly evaluating and synthesizing engineered systems through the use of deep neural networks. The proposed methodology is applied to the analysis and synthesis of offshore structures such as oil platforms. These structures are constructed in a marine environment and are typically designed to achieve specific dynamics in response to a known spectrum of ocean waves. Results show that deep learning can be used to accurately and rapidly synthesize and analyze offshore structure.")
	with gradio.Column():
	download = gradio.HTML("<a href=\"https://huggingface.co/spaces/cmudrc/wecnet/resolve/main/McComb2019_Chapter_TowardTheRapidDesignOfEngineer.pdf\" style=\"width: 60%; display: block; margin: auto;\"><img src=\"https://huggingface.co/spaces/cmudrc/wecnet/resolve/main/coverpage.png\"></a>")

	gradio.Markdown("When designing offshore structure, like [wave energy converters](https://www.nrel.gov/news/program/2021/how-wave-energy-could-go-big-by-getting-smaller.html), it's important to know what forces will be placed on the structure as waves come at different speeds. Likewise, if we have some idea of how we want the structure to respond to different waves, we can use that to guide the design of the shape of the structure. We call the first process _Analysis_, and the second process _Synthesis_. This demo has ML models that do both, very quickly.")

	with gradio.Tab("Analysis"):

	with gradio.Row():
	with gradio.Column():
	whence_commeth_geometry = gradio.Radio(
	["Construct Shape from Parameters", "Pick Shape from Dataset"], label="How would you like to generate the shape of the offshore structure for analysis?", value="Construct Shape from Parameters"
	)
	radio = gradio.Radio(
	["box", "cone", "cylinder", "sphere", "wedge"], label="What kind of shape would you like to generate?", value="sphere"
	)
	height = gradio.Slider(label="Height", interactive=True, minimum=3.0, maximum=10.0, value=6.5, visible=False)
	width = gradio.Slider(label="Width", interactive=True, minimum=3.0, maximum=10.0, value=6.5, visible=False)
	diameter = gradio.Slider(label="Diameter", interactive=True, minimum=3.0, maximum=10.0, value=6.5, visible=True)
	length = gradio.Slider(label="Length", interactive=True, minimum=3.0, maximum=10.0, value=6.5, visible=False)


	num = gradio.Number(42, label="Type the index of the spectrum you would like to use or randomly select it.", visible=False)

	btn1 = gradio.Button("Randomize")
	with gradio.Column():
	geo = gradio.Plot(make_voxels("sphere", 6.5, 6.5, 6.5, 6.5), label="Geometry")


	with gradio.Row():
	btn2 = gradio.Button("Estimate Spectrum")

	with gradio.Row():
	with gradio.Column():
	pred = gradio.Timeseries(x="Frequency", y=['Surge', 'Heave', 'Pitch'], label="Predicted")

	with gradio.Column():
	true = gradio.Timeseries(x="Frequency", y=['Surge', 'Heave', 'Pitch'], label="True", visible=False)

	radio.change(fn=change_textbox, inputs=[radio, length, height, width, diameter], outputs=[height, width, diameter, length, geo])
	height.change(fn=make_voxels, inputs = [radio, length, height, width, diameter], outputs=[geo])
	width.change(fn=make_voxels, inputs = [radio, length, height, width, diameter], outputs=[geo])
	diameter.change(fn=make_voxels, inputs = [radio, length, height, width, diameter], outputs=[geo])
	length.change(fn=make_voxels, inputs = [radio, length, height, width, diameter], outputs=[geo])
	whence_commeth_geometry.change(fn=geometry_change, inputs=[whence_commeth_geometry, radio, num, length, width, height, diameter], outputs=[radio, height, width, diameter, length, num, true, geo])
	num.change(fn=geometry, inputs=[num], outputs=[geo])

	btn1.click(fn=randomize_analysis, inputs=[whence_commeth_geometry], outputs=[radio, length, height, width, diameter, num, geo])
	btn2.click(fn=simple_analysis, inputs=[num, whence_commeth_geometry, radio, length, width, height, diameter], outputs=[pred, true])
	with gradio.Tab("Synthesis"):
	with gradio.Row():
	with gradio.Column():
	whence_commeth_performance = gradio.Radio(
	["Construct Spectrum from Table", "Pick Spectrum from Dataset"], label="How would you like to generate the desired response spectrum to synthesize from?", value="Construct Spectrum from Table"
	)
	num = gradio.Number(42, label="Type the index of the shape you would like to use or randomly select it.")
	btn1 = gradio.Button("Randomize")
	with gradio.Column():
	perf = gradio.Timeseries(lambda: performance(42), x="Frequency", y=['Surge', 'Heave', 'Pitch'], label="Performance")

	with gradio.Row():
	btn2 = gradio.Button("Synthesize Geometry")

	with gradio.Row():
	with gradio.Column():
	pred = gradio.Plot(label="Predicted")

	with gradio.Column():
	true = gradio.Plot(label="True")


	btn1.click(fn=lambda: random.randint(1, 4999), inputs=[], outputs=num)
	num.change(fn=performance, inputs=[num], outputs=[perf])
	btn2.click(fn=simple_synthesis, inputs=[num], outputs=[pred, true])

	demo.launch()