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data_utils.py
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data_utils.py
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# Copyright 2020 Deepmind Technologies Limited.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""Mesh data utilities."""
import matplotlib.pyplot as plt
from mpl_toolkits import mplot3d # pylint: disable=unused-import
from mpl_toolkits.mplot3d.art3d import Poly3DCollection
import networkx as nx
import numpy as np
import six
from six.moves import range
import tensorflow.compat.v1 as tf
import tensorflow_probability as tfp
tfd = tfp.distributions
def random_shift(vertices, shift_factor=0.25):
"""Apply random shift to vertices."""
max_shift_pos = tf.cast(255 - tf.reduce_max(vertices, axis=0), tf.float32)
max_shift_pos = tf.maximum(max_shift_pos, 1e-9)
max_shift_neg = tf.cast(tf.reduce_min(vertices, axis=0), tf.float32)
max_shift_neg = tf.maximum(max_shift_neg, 1e-9)
shift = tfd.TruncatedNormal(
tf.zeros([1, 3]), shift_factor*255, -max_shift_neg,
max_shift_pos).sample()
shift = tf.cast(shift, tf.int32)
vertices += shift
return vertices
def make_vertex_model_dataset(ds, apply_random_shift=False):
"""Prepare dataset for vertex model training."""
def _vertex_model_map_fn(example):
vertices = example['vertices']
# Randomly shift vertices
if apply_random_shift:
vertices = random_shift(vertices)
# Re-order vertex coordinates as (z, y, x).
vertices_permuted = tf.stack(
[vertices[:, 2], vertices[:, 1], vertices[:, 0]], axis=-1)
# Flatten quantized vertices, reindex starting from 1, and pad with a
# zero stopping token.
vertices_flat = tf.reshape(vertices_permuted, [-1])
example['vertices_flat'] = tf.pad(vertices_flat + 1, [[0, 1]])
# Create mask to indicate valid tokens after padding and batching.
example['vertices_flat_mask'] = tf.ones_like(
example['vertices_flat'], dtype=tf.float32)
return example
return ds.map(_vertex_model_map_fn)
def make_face_model_dataset(
ds, apply_random_shift=False, shuffle_vertices=True, quantization_bits=8):
"""Prepare dataset for face model training."""
def _face_model_map_fn(example):
vertices = example['vertices']
# Randomly shift vertices
if apply_random_shift:
vertices = random_shift(vertices)
example['num_vertices'] = tf.shape(vertices)[0]
# Optionally shuffle vertices and re-order faces to match
if shuffle_vertices:
permutation = tf.random_shuffle(tf.range(example['num_vertices']))
vertices = tf.gather(vertices, permutation)
face_permutation = tf.concat(
[tf.constant([0, 1], dtype=tf.int32), tf.argsort(permutation) + 2],
axis=0)
example['faces'] = tf.cast(
tf.gather(face_permutation, example['faces']), tf.int64)
def _dequantize_verts(verts, n_bits):
min_range = -0.5
max_range = 0.5
range_quantize = 2**n_bits - 1
verts = tf.cast(verts, tf.float32)
verts = verts * (max_range - min_range) / range_quantize + min_range
return verts
# Vertices are quantized. So convert to floats for input to face model
example['vertices'] = _dequantize_verts(vertices, quantization_bits)
example['vertices_mask'] = tf.ones_like(
example['vertices'][..., 0], dtype=tf.float32)
example['faces_mask'] = tf.ones_like(example['faces'], dtype=tf.float32)
return example
return ds.map(_face_model_map_fn)
def read_obj_file(obj_file):
"""Read vertices and faces from already opened file."""
vertex_list = []
flat_vertices_list = []
flat_vertices_indices = {}
flat_triangles = []
for line in obj_file:
tokens = line.split()
if not tokens:
continue
line_type = tokens[0]
# We skip lines not starting with v or f.
if line_type == 'v':
vertex_list.append([float(x) for x in tokens[1:]])
elif line_type == 'f':
triangle = []
for i in range(len(tokens) - 1):
vertex_name = tokens[i + 1]
if vertex_name in flat_vertices_indices:
triangle.append(flat_vertices_indices[vertex_name])
continue
flat_vertex = []
for index in six.ensure_str(vertex_name).split('/'):
if not index:
continue
# obj triangle indices are 1 indexed, so subtract 1 here.
flat_vertex += vertex_list[int(index) - 1]
flat_vertex_index = len(flat_vertices_list)
flat_vertices_list.append(flat_vertex)
flat_vertices_indices[vertex_name] = flat_vertex_index
triangle.append(flat_vertex_index)
flat_triangles.append(triangle)
return np.array(flat_vertices_list, dtype=np.float32), flat_triangles
def read_obj(obj_path):
"""Open .obj file from the path provided and read vertices and faces."""
with open(obj_path) as obj_file:
return read_obj_file(obj_file)
def write_obj(vertices, faces, file_path, transpose=True, scale=1.):
"""Write vertices and faces to obj."""
if transpose:
vertices = vertices[:, [1, 2, 0]]
vertices *= scale
if faces is not None:
if min(min(faces)) == 0:
f_add = 1
else:
f_add = 0
with open(file_path, 'w') as f:
for v in vertices:
f.write('v {} {} {}\n'.format(v[0], v[1], v[2]))
for face in faces:
line = 'f'
for i in face:
line += ' {}'.format(i + f_add)
line += '\n'
f.write(line)
def quantize_verts(verts, n_bits=8):
"""Convert vertices in [-1., 1.] to discrete values in [0, n_bits**2 - 1]."""
min_range = -0.5
max_range = 0.5
range_quantize = 2**n_bits - 1
verts_quantize = (verts - min_range) * range_quantize / (
max_range - min_range)
return verts_quantize.astype('int32')
def dequantize_verts(verts, n_bits=8, add_noise=False):
"""Convert quantized vertices to floats."""
min_range = -0.5
max_range = 0.5
range_quantize = 2**n_bits - 1
verts = verts.astype('float32')
verts = verts * (max_range - min_range) / range_quantize + min_range
if add_noise:
verts += np.random.uniform(size=verts.shape) * (1 / range_quantize)
return verts
def face_to_cycles(face):
"""Find cycles in face."""
g = nx.Graph()
for v in range(len(face) - 1):
g.add_edge(face[v], face[v + 1])
g.add_edge(face[-1], face[0])
return list(nx.cycle_basis(g))
def flatten_faces(faces):
"""Converts from list of faces to flat face array with stopping indices."""
if not faces:
return np.array([0])
else:
l = [f + [-1] for f in faces[:-1]]
l += [faces[-1] + [-2]]
return np.array([item for sublist in l for item in sublist]) + 2 # pylint: disable=g-complex-comprehension
def unflatten_faces(flat_faces):
"""Converts from flat face sequence to a list of separate faces."""
def group(seq):
g = []
for el in seq:
if el == 0 or el == -1:
yield g
g = []
else:
g.append(el - 1)
yield g
outputs = list(group(flat_faces - 1))[:-1]
# Remove empty faces
return [o for o in outputs if len(o) > 2]
def center_vertices(vertices):
"""Translate the vertices so that bounding box is centered at zero."""
vert_min = vertices.min(axis=0)
vert_max = vertices.max(axis=0)
vert_center = 0.5 * (vert_min + vert_max)
return vertices - vert_center
def normalize_vertices_scale(vertices):
"""Scale the vertices so that the long diagonal of the bounding box is one."""
vert_min = vertices.min(axis=0)
vert_max = vertices.max(axis=0)
extents = vert_max - vert_min
scale = np.sqrt(np.sum(extents**2))
return vertices / scale
def quantize_process_mesh(vertices, faces, tris=None, quantization_bits=8):
"""Quantize vertices, remove resulting duplicates and reindex faces."""
vertices = quantize_verts(vertices, quantization_bits)
vertices, inv = np.unique(vertices, axis=0, return_inverse=True)
# Sort vertices by z then y then x.
sort_inds = np.lexsort(vertices.T)
vertices = vertices[sort_inds]
# Re-index faces and tris to re-ordered vertices.
faces = [np.argsort(sort_inds)[inv[f]] for f in faces]
if tris is not None:
tris = np.array([np.argsort(sort_inds)[inv[t]] for t in tris])
# Merging duplicate vertices and re-indexing the faces causes some faces to
# contain loops (e.g [2, 3, 5, 2, 4]). Split these faces into distinct
# sub-faces.
sub_faces = []
for f in faces:
cliques = face_to_cycles(f)
for c in cliques:
c_length = len(c)
# Only append faces with more than two verts.
if c_length > 2:
d = np.argmin(c)
# Cyclically permute faces just that first index is the smallest.
sub_faces.append([c[(d + i) % c_length] for i in range(c_length)])
faces = sub_faces
if tris is not None:
tris = np.array([v for v in tris if len(set(v)) == len(v)])
# Sort faces by lowest vertex indices. If two faces have the same lowest
# index then sort by next lowest and so on.
faces.sort(key=lambda f: tuple(sorted(f)))
if tris is not None:
tris = tris.tolist()
tris.sort(key=lambda f: tuple(sorted(f)))
tris = np.array(tris)
# After removing degenerate faces some vertices are now unreferenced.
# Remove these.
num_verts = vertices.shape[0]
vert_connected = np.equal(
np.arange(num_verts)[:, None], np.hstack(faces)[None]).any(axis=-1)
vertices = vertices[vert_connected]
# Re-index faces and tris to re-ordered vertices.
vert_indices = (
np.arange(num_verts) - np.cumsum(1 - vert_connected.astype('int')))
faces = [vert_indices[f].tolist() for f in faces]
if tris is not None:
tris = np.array([vert_indices[t].tolist() for t in tris])
return vertices, faces, tris
def process_mesh(vertices, faces, quantization_bits=8):
"""Process mesh vertices and faces."""
# Transpose so that z-axis is vertical.
vertices = vertices[:, [2, 0, 1]]
# Translate the vertices so that bounding box is centered at zero.
vertices = center_vertices(vertices)
# Scale the vertices so that the long diagonal of the bounding box is equal
# to one.
vertices = normalize_vertices_scale(vertices)
# Quantize and sort vertices, remove resulting duplicates, sort and reindex
# faces.
vertices, faces, _ = quantize_process_mesh(
vertices, faces, quantization_bits=quantization_bits)
# Flatten faces and add 'new face' = 1 and 'stop' = 0 tokens.
faces = flatten_faces(faces)
# Discard degenerate meshes without faces.
return {
'vertices': vertices,
'faces': faces,
}
def load_process_mesh(mesh_obj_path, quantization_bits=8):
"""Load obj file and process."""
# Load mesh
vertices, faces = read_obj(mesh_obj_path)
return process_mesh(vertices, faces, quantization_bits)
def plot_meshes(mesh_list,
ax_lims=0.3,
fig_size=4,
el=30,
rot_start=120,
vert_size=10,
vert_alpha=0.75,
n_cols=4):
"""Plots mesh data using matplotlib."""
n_plot = len(mesh_list)
n_cols = np.minimum(n_plot, n_cols)
n_rows = np.ceil(n_plot / n_cols).astype('int')
fig = plt.figure(figsize=(fig_size * n_cols, fig_size * n_rows))
for p_inc, mesh in enumerate(mesh_list):
for key in [
'vertices', 'faces', 'vertices_conditional', 'pointcloud', 'class_name'
]:
if key not in list(mesh.keys()):
mesh[key] = None
ax = fig.add_subplot(n_rows, n_cols, p_inc + 1, projection='3d')
if mesh['faces'] is not None:
if mesh['vertices_conditional'] is not None:
face_verts = np.concatenate(
[mesh['vertices_conditional'], mesh['vertices']], axis=0)
else:
face_verts = mesh['vertices']
collection = []
for f in mesh['faces']:
collection.append(face_verts[f])
plt_mesh = Poly3DCollection(collection)
plt_mesh.set_edgecolor((0., 0., 0., 0.3))
plt_mesh.set_facecolor((1, 0, 0, 0.2))
ax.add_collection3d(plt_mesh)
if mesh['vertices'] is not None:
ax.scatter3D(
mesh['vertices'][:, 0],
mesh['vertices'][:, 1],
mesh['vertices'][:, 2],
lw=0.,
s=vert_size,
c='g',
alpha=vert_alpha)
if mesh['vertices_conditional'] is not None:
ax.scatter3D(
mesh['vertices_conditional'][:, 0],
mesh['vertices_conditional'][:, 1],
mesh['vertices_conditional'][:, 2],
lw=0.,
s=vert_size,
c='b',
alpha=vert_alpha)
if mesh['pointcloud'] is not None:
ax.scatter3D(
mesh['pointcloud'][:, 0],
mesh['pointcloud'][:, 1],
mesh['pointcloud'][:, 2],
lw=0.,
s=2.5 * vert_size,
c='b',
alpha=1.)
ax.set_xlim(-ax_lims, ax_lims)
ax.set_ylim(-ax_lims, ax_lims)
ax.set_zlim(-ax_lims, ax_lims)
ax.view_init(el, rot_start)
display_string = ''
if mesh['faces'] is not None:
display_string += 'Num. faces: {}\n'.format(len(collection))
if mesh['vertices'] is not None:
num_verts = mesh['vertices'].shape[0]
if mesh['vertices_conditional'] is not None:
num_verts += mesh['vertices_conditional'].shape[0]
display_string += 'Num. verts: {}\n'.format(num_verts)
if mesh['class_name'] is not None:
display_string += 'Synset: {}'.format(mesh['class_name'])
if mesh['pointcloud'] is not None:
display_string += 'Num. pointcloud: {}\n'.format(
mesh['pointcloud'].shape[0])
ax.text2D(0.05, 0.8, display_string, transform=ax.transAxes)
plt.subplots_adjust(
left=0., right=1., bottom=0., top=1., wspace=0.025, hspace=0.025)
plt.show()