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train.py
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train.py
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#
# Copyright (C) 2023, Inria
# GRAPHDECO research group, https://team.inria.fr/graphdeco
# All rights reserved.
#
# This software is free for non-commercial, research and evaluation use
# under the terms of the LICENSE.md file.
#
# For inquiries contact george.drettakis@inria.fr
#
import numpy as np
import random
import os
import torch
from random import randint
from utils.loss_utils import l1_loss, ssim, lpips_loss, TV_loss
from gaussian_renderer import render, network_gui
import sys
from scene import Scene, GaussianModel
from utils.general_utils import safe_state
import uuid
from tqdm import tqdm
from utils.image_utils import psnr
from argparse import ArgumentParser, Namespace
from arguments import ModelParams, PipelineParams, OptimizationParams, ModelHiddenParams
from torch.utils.data import DataLoader
from utils.timer import Timer
from torchmetrics.functional.regression import pearson_corrcoef
import lpips
from utils.scene_utils import render_training_image
from time import time
to8b = lambda x : (255*np.clip(x.cpu().numpy(),0,1)).astype(np.uint8)
try:
from torch.utils.tensorboard import SummaryWriter
TENSORBOARD_FOUND = True
except ImportError:
TENSORBOARD_FOUND = False
def scene_reconstruction(dataset, opt, hyper, pipe, testing_iterations, saving_iterations,
checkpoint_iterations, checkpoint, debug_from,
gaussians, scene, stage, tb_writer, train_iter, timer):
first_iter = 0
gaussians.training_setup(opt)
if checkpoint:
(model_params, first_iter) = torch.load(checkpoint)
gaussians.restore(model_params, opt)
bg_color = [1, 1, 1] if dataset.white_background else [0, 0, 0]
background = torch.tensor(bg_color, dtype=torch.float32, device="cuda")
iter_start = torch.cuda.Event(enable_timing = True)
iter_end = torch.cuda.Event(enable_timing = True)
viewpoint_stack = None
ema_loss_for_log = 0.0
ema_psnr_for_log = 0.0
final_iter = train_iter
progress_bar = tqdm(range(first_iter, final_iter), desc="Training progress")
first_iter += 1
lpips_model = lpips.LPIPS(net="vgg").cuda()
video_cams = scene.getVideoCameras()
if not viewpoint_stack:
viewpoint_stack = scene.getTrainCameras()
for iteration in range(first_iter, final_iter+1):
if network_gui.conn == None:
network_gui.try_connect()
while network_gui.conn != None:
try:
net_image_bytes = None
custom_cam, do_training, pipe.convert_SHs_python, pipe.compute_cov3D_python, keep_alive, scaling_modifer, ts = network_gui.receive()
if custom_cam != None:
net_image = render(custom_cam, gaussians, pipe, background, scaling_modifer, stage="stage")["render"]
net_image_bytes = memoryview((torch.clamp(net_image, min=0, max=1.0) * 255).byte().permute(1, 2, 0).contiguous().cpu().numpy())
network_gui.send(net_image_bytes, dataset.source_path)
if do_training and ((iteration < int(opt.iterations)) or not keep_alive):
break
except Exception as e:
network_gui.conn = None
iter_start.record()
gaussians.update_learning_rate(iteration)
# Every 1000 its we increase the levels of SH up to a maximum degree
if iteration % 500 == 0:
gaussians.oneupSHdegree()
if stage == 'coarse':
idx = 0
else:
idx = randint(0, len(viewpoint_stack)-1)
viewpoint_cams = [viewpoint_stack[idx]]
# Render
if (iteration - 1) == debug_from:
pipe.debug = True
images = []
depths = []
gt_images = []
gt_depths = []
masks = []
radii_list = []
visibility_filter_list = []
viewspace_point_tensor_list = []
for viewpoint_cam in viewpoint_cams:
render_pkg = render(viewpoint_cam, gaussians, pipe, background, stage=stage)
image, depth, viewspace_point_tensor, visibility_filter, radii = \
render_pkg["render"], render_pkg["depth"], render_pkg["viewspace_points"], render_pkg["visibility_filter"], render_pkg["radii"]
gt_image = viewpoint_cam.original_image.cuda().float()
gt_depth = viewpoint_cam.original_depth.cuda().float()
mask = viewpoint_cam.mask.cuda()
images.append(image.unsqueeze(0))
depths.append(depth.unsqueeze(0))
gt_images.append(gt_image.unsqueeze(0))
gt_depths.append(gt_depth.unsqueeze(0))
masks.append(mask.unsqueeze(0))
radii_list.append(radii.unsqueeze(0))
visibility_filter_list.append(visibility_filter.unsqueeze(0))
viewspace_point_tensor_list.append(viewspace_point_tensor)
radii = torch.cat(radii_list,0).max(dim=0).values
visibility_filter = torch.cat(visibility_filter_list).any(dim=0)
rendered_images = torch.cat(images,0)
rendered_depths = torch.cat(depths, 0)
gt_images = torch.cat(gt_images,0)
gt_depths = torch.cat(gt_depths, 0)
masks = torch.cat(masks, 0)
Ll1 = l1_loss(rendered_images, gt_images, masks)
if (gt_depths!=0).sum() < 10:
depth_loss = torch.tensor(0.).cuda()
elif scene.mode == 'binocular':
rendered_depths[rendered_depths!=0] = 1 / rendered_depths[rendered_depths!=0]
gt_depths[gt_depths!=0] = 1 / gt_depths[gt_depths!=0]
depth_loss = l1_loss(rendered_depths, gt_depths, masks)
elif scene.mode == 'monocular':
rendered_depths_reshape = rendered_depths.reshape(-1, 1)
gt_depths_reshape = gt_depths.reshape(-1, 1)
mask_tmp = mask.reshape(-1)
rendered_depths_reshape, gt_depths_reshape = rendered_depths_reshape[mask_tmp!=0, :], gt_depths_reshape[mask_tmp!=0, :]
depth_loss = 0.001 * (1 - pearson_corrcoef(gt_depths_reshape, rendered_depths_reshape))
else:
raise ValueError(f"{scene.mode} is not implemented.")
depth_tvloss = TV_loss(rendered_depths)
img_tvloss = TV_loss(rendered_images)
tv_loss = 0.03 * (img_tvloss + depth_tvloss)
loss = Ll1 + depth_loss + tv_loss
psnr_ = psnr(rendered_images, gt_images, masks).mean().double()
if stage == "fine" and hyper.time_smoothness_weight != 0:
tv_loss = gaussians.compute_regulation(2e-2, 2e-2, 2e-2)
loss += tv_loss
if opt.lambda_dssim != 0:
ssim_loss = ssim(rendered_images,gt_images)
loss += opt.lambda_dssim * (1.0-ssim_loss)
if opt.lambda_lpips !=0:
lpipsloss = lpips_loss(rendered_images,gt_images,lpips_model)
loss += opt.lambda_lpips * lpipsloss
loss.backward()
viewspace_point_tensor_grad = torch.zeros_like(viewspace_point_tensor)
for idx in range(0, len(viewspace_point_tensor_list)):
viewspace_point_tensor_grad = viewspace_point_tensor_grad + viewspace_point_tensor_list[idx].grad
iter_end.record()
with torch.no_grad():
# Progress bar
ema_loss_for_log = 0.4 * loss.item() + 0.6 * ema_loss_for_log
ema_psnr_for_log = 0.4 * psnr_ + 0.6 * ema_psnr_for_log
total_point = gaussians._xyz.shape[0]
if iteration % 10 == 0:
progress_bar.set_postfix({"Loss": f"{ema_loss_for_log:.{7}f}",
"psnr": f"{psnr_:.{2}f}",
"point":f"{total_point}"})
progress_bar.update(10)
if iteration == train_iter:
progress_bar.close()
# Log and save
timer.pause()
training_report(tb_writer, iteration, Ll1, loss, l1_loss, iter_start.elapsed_time(iter_end), testing_iterations, scene, render, [pipe, background], stage)
if (iteration in saving_iterations):
print("\n[ITER {}] Saving Gaussians".format(iteration))
scene.save(iteration, stage)
if dataset.render_process:
if (iteration < 1000 and iteration % 10 == 1) \
or (iteration < 3000 and iteration % 50 == 1) \
or (iteration < 10000 and iteration % 100 == 1) \
or (iteration < 60000 and iteration % 100 ==1):
render_training_image(scene, gaussians, video_cams, render, pipe, background, stage, iteration-1,timer.get_elapsed_time())
timer.start()
# Densification
if iteration < opt.densify_until_iter :
# Keep track of max radii in image-space for pruning
gaussians.max_radii2D[visibility_filter] = torch.max(gaussians.max_radii2D[visibility_filter], radii[visibility_filter])
gaussians.add_densification_stats(viewspace_point_tensor_grad, visibility_filter)
if stage == "coarse":
opacity_threshold = opt.opacity_threshold_coarse
densify_threshold = opt.densify_grad_threshold_coarse
else:
opacity_threshold = opt.opacity_threshold_fine_init - iteration*(opt.opacity_threshold_fine_init - opt.opacity_threshold_fine_after)/(opt.densify_until_iter)
densify_threshold = opt.densify_grad_threshold_fine_init - iteration*(opt.densify_grad_threshold_fine_init - opt.densify_grad_threshold_after)/(opt.densify_until_iter )
if iteration > opt.densify_from_iter and iteration % opt.densification_interval == 0 :
size_threshold = 20 if iteration > opt.opacity_reset_interval else None
gaussians.densify(densify_threshold, opacity_threshold, scene.cameras_extent, size_threshold)
if iteration > opt.pruning_from_iter and iteration % opt.pruning_interval == 0:
size_threshold = 40 if iteration > opt.opacity_reset_interval else None
gaussians.prune(densify_threshold, opacity_threshold, scene.cameras_extent, size_threshold)
if iteration % opt.opacity_reset_interval == 0 or (dataset.white_background and iteration == opt.densify_from_iter):
print("reset opacity")
gaussians.reset_opacity()
# Optimizer step
if iteration < train_iter:
gaussians.optimizer.step()
gaussians.optimizer.zero_grad(set_to_none = True)
if (iteration in checkpoint_iterations):
print("\n[ITER {}] Saving Checkpoint".format(iteration))
torch.save((gaussians.capture(), iteration), scene.model_path + "/chkpnt" + str(iteration) + ".pth")
def training(dataset, hyper, opt, pipe, testing_iterations, saving_iterations, checkpoint_iterations, checkpoint, debug_from, expname, extra_mark):
tb_writer = prepare_output_and_logger(expname)
gaussians = GaussianModel(dataset.sh_degree, hyper)
dataset.model_path = args.model_path
timer = Timer()
scene = Scene(dataset, gaussians, load_coarse=args.no_fine)
timer.start()
scene_reconstruction(dataset, opt, hyper, pipe, testing_iterations, saving_iterations,
checkpoint_iterations, checkpoint, debug_from,
gaussians, scene, "coarse", tb_writer, opt.coarse_iterations,timer)
if not args.no_fine:
scene_reconstruction(dataset, opt, hyper, pipe, testing_iterations, saving_iterations,
checkpoint_iterations, checkpoint, debug_from,
gaussians, scene, "fine", tb_writer, opt.iterations,timer)
def prepare_output_and_logger(expname):
if not args.model_path:
unique_str = expname
args.model_path = os.path.join("./output/", unique_str)
print("Output folder: {}".format(args.model_path))
os.makedirs(args.model_path, exist_ok = True)
with open(os.path.join(args.model_path, "cfg_args"), 'w') as cfg_log_f:
cfg_log_f.write(str(Namespace(**vars(args))))
tb_writer = None
if TENSORBOARD_FOUND:
tb_writer = SummaryWriter(args.model_path)
else:
print("Tensorboard not available: not logging progress")
return tb_writer
def training_report(tb_writer, iteration, Ll1, loss, l1_loss, elapsed, testing_iterations, scene : Scene, renderFunc, renderArgs, stage):
if tb_writer:
tb_writer.add_scalar(f'{stage}/train_loss_patches/l1_loss', Ll1.item(), iteration)
tb_writer.add_scalar(f'{stage}/train_loss_patchestotal_loss', loss.item(), iteration)
tb_writer.add_scalar(f'{stage}/iter_time', elapsed, iteration)
# Report test and samples of training set
'''
if iteration in testing_iterations:
torch.cuda.empty_cache()
validation_configs = ({'name': 'test', 'cameras' : [scene.getTestCameras()[idx % len(scene.getTestCameras())] for idx in range(10, 5000, 299)]},
{'name': 'train', 'cameras' : [scene.getTrainCameras()[idx % len(scene.getTrainCameras())] for idx in range(10, 5000, 299)]})
for config in validation_configs:
if config['cameras'] and len(config['cameras']) > 0:
l1_test = 0.0
psnr_test = 0.0
for idx, viewpoint in enumerate(config['cameras']):
image = torch.clamp(renderFunc(viewpoint, scene.gaussians,stage=stage, *renderArgs)["render"], 0.0, 1.0)
gt_image = torch.clamp(viewpoint.original_image.to("cuda"), 0.0, 1.0)
mask = viewpoint.mask.to("cuda")
image, gt_image, mask = image.unsqueeze(0), gt_image.unsqueeze(0), mask.unsqueeze(0)
if tb_writer and (idx < 5):
tb_writer.add_images(stage + "/"+config['name'] + "_view_{}/render".format(viewpoint.image_name), image[None], global_step=iteration)
if iteration == testing_iterations[0]:
tb_writer.add_images(stage + "/"+config['name'] + "_view_{}/ground_truth".format(viewpoint.image_name), gt_image[None], global_step=iteration)
l1_test += l1_loss(image, gt_image, mask).mean().double()
psnr_test += psnr(image, gt_image, mask).mean().double()
psnr_test /= len(config['cameras'])
l1_test /= len(config['cameras'])
print("\n[ITER {}] Evaluating {}: L1 {} PSNR {}".format(iteration, config['name'], l1_test, psnr_test))
if tb_writer:
tb_writer.add_scalar(stage + "/"+config['name'] + '/loss_viewpoint - l1_loss', l1_test, iteration)
tb_writer.add_scalar(stage+"/"+config['name'] + '/loss_viewpoint - psnr', psnr_test, iteration)
if tb_writer:
tb_writer.add_histogram(f"{stage}/scene/opacity_histogram", scene.gaussians.get_opacity, iteration)
tb_writer.add_scalar(f'{stage}/total_points', scene.gaussians.get_xyz.shape[0], iteration)
tb_writer.add_scalar(f'{stage}/deformation_rate', scene.gaussians._deformation_table.sum()/scene.gaussians.get_xyz.shape[0], iteration)
tb_writer.add_histogram(f"{stage}/scene/motion_histogram", scene.gaussians._deformation_accum.mean(dim=-1)/100, iteration,max_bins=500)
torch.cuda.empty_cache()
'''
def setup_seed(seed):
torch.manual_seed(seed)
torch.cuda.manual_seed_all(seed)
np.random.seed(seed)
random.seed(seed)
torch.backends.cudnn.deterministic = True
if __name__ == "__main__":
# Set up command line argument parser
# torch.set_default_tensor_type('torch.FloatTensor')
torch.cuda.empty_cache()
parser = ArgumentParser(description="Training script parameters")
setup_seed(6666)
lp = ModelParams(parser)
op = OptimizationParams(parser)
pp = PipelineParams(parser)
hp = ModelHiddenParams(parser)
parser.add_argument('--ip', type=str, default="127.0.0.1")
parser.add_argument('--port', type=int, default=6009)
parser.add_argument('--debug_from', type=int, default=-1)
parser.add_argument('--detect_anomaly', action='store_true', default=False)
parser.add_argument("--test_iterations", nargs="+", type=int, default=[i*500 for i in range(0,120)])
parser.add_argument("--save_iterations", nargs="+", type=int, default=[2000, 3000,4000, 5000, 6000, 9000, 10000, 14000, 20000, 30_000,45000,60000])
parser.add_argument("--checkpoint_iterations", nargs="+", type=int, default=[])
parser.add_argument("--quiet", action="store_true")
parser.add_argument("--start_checkpoint", type=str, default = None)
parser.add_argument("--expname", type=str, default = "")
parser.add_argument("--configs", type=str, default = "")
args = parser.parse_args(sys.argv[1:])
args.save_iterations.append(args.iterations)
if args.configs:
import mmcv
from utils.params_utils import merge_hparams
config = mmcv.Config.fromfile(args.configs)
args = merge_hparams(args, config)
print("Optimizing " + args.model_path)
# Initialize system state (RNG)
safe_state(args.quiet)
# Start GUI server, configure and run training
network_gui.init(args.ip, args.port)
torch.autograd.set_detect_anomaly(args.detect_anomaly)
training(lp.extract(args), hp.extract(args), op.extract(args), pp.extract(args), args.test_iterations, \
args.save_iterations, args.checkpoint_iterations, args.start_checkpoint, args.debug_from, args.expname, args.extra_mark)
# All done
print("\nTraining complete.")