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reconstruct.py
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reconstruct.py
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#!/usr/bin/env python3
# Copyright 2004-present Facebook. All Rights Reserved.
import argparse
import json
import logging
import os
import random
import time
import torch
import deep_sdf
import deep_sdf.workspace as ws
def reconstruct(
decoder,
num_iterations,
latent_size,
test_sdf,
stat,
clamp_dist,
num_samples=30000,
lr=5e-4,
l2reg=False,
):
def adjust_learning_rate(
initial_lr, optimizer, num_iterations, decreased_by, adjust_lr_every
):
lr = initial_lr * ((1 / decreased_by) ** (num_iterations // adjust_lr_every))
for param_group in optimizer.param_groups:
param_group["lr"] = lr
decreased_by = 10
adjust_lr_every = int(num_iterations / 2)
if type(stat) == type(0.1):
latent = torch.ones(1, latent_size).normal_(mean=0, std=stat).cuda()
else:
latent = torch.normal(stat[0].detach(), stat[1].detach()).cuda()
latent.requires_grad = True
optimizer = torch.optim.Adam([latent], lr=lr)
loss_num = 0
loss_l1 = torch.nn.L1Loss()
for e in range(num_iterations):
decoder.eval()
sdf_data = deep_sdf.data.unpack_sdf_samples_from_ram(
test_sdf, num_samples
).cuda()
xyz = sdf_data[:, 0:3]
sdf_gt = sdf_data[:, 3].unsqueeze(1)
sdf_gt = torch.clamp(sdf_gt, -clamp_dist, clamp_dist)
adjust_learning_rate(lr, optimizer, e, decreased_by, adjust_lr_every)
optimizer.zero_grad()
latent_inputs = latent.expand(num_samples, -1)
inputs = torch.cat([latent_inputs, xyz], 1).cuda()
pred_sdf = decoder(inputs)
# TODO: why is this needed?
if e == 0:
pred_sdf = decoder(inputs)
pred_sdf = torch.clamp(pred_sdf, -clamp_dist, clamp_dist)
loss = loss_l1(pred_sdf, sdf_gt)
if l2reg:
loss += 1e-4 * torch.mean(latent.pow(2))
loss.backward()
optimizer.step()
if e % 50 == 0:
logging.debug(loss.cpu().data.numpy())
logging.debug(e)
logging.debug(latent.norm())
loss_num = loss.cpu().data.numpy()
return loss_num, latent
if __name__ == "__main__":
arg_parser = argparse.ArgumentParser(
description="Use a trained DeepSDF decoder to reconstruct a shape given SDF "
+ "samples."
)
arg_parser.add_argument(
"--experiment",
"-e",
dest="experiment_directory",
required=True,
help="The experiment directory which includes specifications and saved model "
+ "files to use for reconstruction",
)
arg_parser.add_argument(
"--checkpoint",
"-c",
dest="checkpoint",
default="latest",
help="The checkpoint weights to use. This can be a number indicated an epoch "
+ "or 'latest' for the latest weights (this is the default)",
)
arg_parser.add_argument(
"--data",
"-d",
dest="data_source",
required=True,
help="The data source directory.",
)
arg_parser.add_argument(
"--split",
"-s",
dest="split_filename",
required=True,
help="The split to reconstruct.",
)
arg_parser.add_argument(
"--iters",
dest="iterations",
default=800,
help="The number of iterations of latent code optimization to perform.",
)
arg_parser.add_argument(
"--skip",
dest="skip",
action="store_true",
help="Skip meshes which have already been reconstructed.",
)
deep_sdf.add_common_args(arg_parser)
args = arg_parser.parse_args()
deep_sdf.configure_logging(args)
def empirical_stat(latent_vecs, indices):
lat_mat = torch.zeros(0).cuda()
for ind in indices:
lat_mat = torch.cat([lat_mat, latent_vecs[ind]], 0)
mean = torch.mean(lat_mat, 0)
var = torch.var(lat_mat, 0)
return mean, var
specs_filename = os.path.join(args.experiment_directory, "specs.json")
if not os.path.isfile(specs_filename):
raise Exception(
'The experiment directory does not include specifications file "specs.json"'
)
specs = json.load(open(specs_filename))
arch = __import__("networks." + specs["NetworkArch"], fromlist=["Decoder"])
latent_size = specs["CodeLength"]
decoder = arch.Decoder(latent_size, **specs["NetworkSpecs"])
decoder = torch.nn.DataParallel(decoder)
saved_model_state = torch.load(
os.path.join(
args.experiment_directory, ws.model_params_subdir, args.checkpoint + ".pth"
)
)
saved_model_epoch = saved_model_state["epoch"]
decoder.load_state_dict(saved_model_state["model_state_dict"])
decoder = decoder.module.cuda()
with open(args.split_filename, "r") as f:
split = json.load(f)
npz_filenames = deep_sdf.data.get_instance_filenames(args.data_source, split)
random.shuffle(npz_filenames)
logging.debug(decoder)
err_sum = 0.0
repeat = 1
save_latvec_only = False
rerun = 0
reconstruction_dir = os.path.join(
args.experiment_directory, ws.reconstructions_subdir, str(saved_model_epoch)
)
if not os.path.isdir(reconstruction_dir):
os.makedirs(reconstruction_dir)
reconstruction_meshes_dir = os.path.join(
reconstruction_dir, ws.reconstruction_meshes_subdir
)
if not os.path.isdir(reconstruction_meshes_dir):
os.makedirs(reconstruction_meshes_dir)
reconstruction_codes_dir = os.path.join(
reconstruction_dir, ws.reconstruction_codes_subdir
)
if not os.path.isdir(reconstruction_codes_dir):
os.makedirs(reconstruction_codes_dir)
for ii, npz in enumerate(npz_filenames):
if "npz" not in npz:
continue
full_filename = os.path.join(args.data_source, ws.sdf_samples_subdir, npz)
logging.debug("loading {}".format(npz))
data_sdf = deep_sdf.data.read_sdf_samples_into_ram(full_filename)
for k in range(repeat):
if rerun > 1:
mesh_filename = os.path.join(
reconstruction_meshes_dir, npz[:-4] + "-" + str(k + rerun)
)
latent_filename = os.path.join(
reconstruction_codes_dir, npz[:-4] + "-" + str(k + rerun) + ".pth"
)
else:
mesh_filename = os.path.join(reconstruction_meshes_dir, npz[:-4])
latent_filename = os.path.join(
reconstruction_codes_dir, npz[:-4] + ".pth"
)
if (
args.skip
and os.path.isfile(mesh_filename + ".ply")
and os.path.isfile(latent_filename)
):
continue
logging.info("reconstructing {}".format(npz))
data_sdf[0] = data_sdf[0][torch.randperm(data_sdf[0].shape[0])]
data_sdf[1] = data_sdf[1][torch.randperm(data_sdf[1].shape[0])]
start = time.time()
err, latent = reconstruct(
decoder,
int(args.iterations),
latent_size,
data_sdf,
0.01, # [emp_mean,emp_var],
0.1,
num_samples=8000,
lr=5e-3,
l2reg=True,
)
logging.debug("reconstruct time: {}".format(time.time() - start))
err_sum += err
logging.debug("current_error avg: {}".format((err_sum / (ii + 1))))
logging.debug(ii)
logging.debug("latent: {}".format(latent.detach().cpu().numpy()))
decoder.eval()
if not os.path.exists(os.path.dirname(mesh_filename)):
os.makedirs(os.path.dirname(mesh_filename))
if not save_latvec_only:
start = time.time()
with torch.no_grad():
deep_sdf.mesh.create_mesh(
decoder, latent, mesh_filename, N=256, max_batch=int(2 ** 18)
)
logging.debug("total time: {}".format(time.time() - start))
if not os.path.exists(os.path.dirname(latent_filename)):
os.makedirs(os.path.dirname(latent_filename))
torch.save(latent.unsqueeze(0), latent_filename)