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GaussianAnything-AIGC3D / nsr /cvD /nvsD.py

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	import functools
	import json
	import os
	from pathlib import Path
	from pdb import set_trace as st
	import torchvision
	import blobfile as bf
	import imageio
	import numpy as np
	import torch as th
	import torch.distributed as dist
	import torchvision
	from PIL import Image
	from torch.nn.parallel.distributed import DistributedDataParallel as DDP
	from tqdm import tqdm

	from guided_diffusion.fp16_util import MixedPrecisionTrainer
	from guided_diffusion import dist_util, logger
	from guided_diffusion.train_util import (calc_average_loss,
	log_rec3d_loss_dict,
	find_resume_checkpoint)

	from torch.optim import AdamW

	from ..train_util import TrainLoopBasic, TrainLoop3DRec
	import vision_aided_loss
	from dnnlib.util import calculate_adaptive_weight


	def get_blob_logdir():
	# You can change this to be a separate path to save checkpoints to
	# a blobstore or some external drive.
	return logger.get_dir()


	from ..train_util_cvD import TrainLoop3DcvD


	class TrainLoop3DcvD_nvsD(TrainLoop3DcvD):

	def __init__(self,
	*,
	# model,
	rec_model,
	loss_class,
	data,
	eval_data,
	batch_size,
	microbatch,
	lr,
	ema_rate,
	log_interval,
	eval_interval,
	save_interval,
	resume_checkpoint,
	use_fp16=False,
	fp16_scale_growth=0.001,
	weight_decay=0,
	lr_anneal_steps=0,
	iterations=10001,
	load_submodule_name='',
	ignore_resume_opt=False,
	use_amp=False,
	**kwargs):
	super().__init__(rec_model=rec_model,
	loss_class=loss_class,
	data=data,
	eval_data=eval_data,
	batch_size=batch_size,
	microbatch=microbatch,
	lr=lr,
	ema_rate=ema_rate,
	log_interval=log_interval,
	eval_interval=eval_interval,
	save_interval=save_interval,
	resume_checkpoint=resume_checkpoint,
	use_fp16=use_fp16,
	fp16_scale_growth=fp16_scale_growth,
	weight_decay=weight_decay,
	lr_anneal_steps=lr_anneal_steps,
	iterations=iterations,
	load_submodule_name=load_submodule_name,
	ignore_resume_opt=ignore_resume_opt,
	use_amp=use_amp,
	**kwargs)

	def run_step(self, batch, step='g_step'):
	# self.forward_backward(batch)

	if step == 'g_step_rec':
	self.forward_G_rec(batch)
	took_step_g_rec = self.mp_trainer_rec.optimize(self.opt)

	if took_step_g_rec:
	self._update_ema() # g_ema

	elif step == 'g_step_nvs':
	self.forward_G_nvs(batch)
	took_step_g_nvs = self.mp_trainer_rec.optimize(self.opt)

	if took_step_g_nvs:
	self._update_ema() # g_ema

	elif step == 'd_step':
	self.forward_D(batch)
	_ = self.mp_trainer_cvD.optimize(self.opt_cvD)

	self._anneal_lr()
	self.log_step()

	def run_loop(self):
	while (not self.lr_anneal_steps
	or self.step + self.resume_step < self.lr_anneal_steps):

	# let all processes sync up before starting with a new epoch of training
	dist_util.synchronize()

	batch = next(self.data)
	self.run_step(batch, 'g_step_rec') # pure VAE reconstruction

	batch = next(self.data)
	self.run_step(batch, 'g_step_nvs')

	batch = next(self.data)
	self.run_step(batch, 'd_step')

	if self.step % self.log_interval == 0 and dist_util.get_rank(
	) == 0:
	out = logger.dumpkvs()
	# * log to tensorboard
	for k, v in out.items():
	self.writer.add_scalar(f'Loss/{k}', v,
	self.step + self.resume_step)

	if self.step % self.eval_interval == 0 and self.step != 0:
	if dist_util.get_rank() == 0:
	self.eval_loop()
	# self.eval_novelview_loop()
	# let all processes sync up before starting with a new epoch of training
	dist_util.synchronize()

	if self.step % self.save_interval == 0:
	self.save()
	self.save(self.mp_trainer_cvD, 'cvD')
	dist_util.synchronize()
	# Run for a finite amount of time in integration tests.
	if os.environ.get("DIFFUSION_TRAINING_TEST",
	"") and self.step > 0:
	return

	self.step += 1

	if self.step > self.iterations:
	print('reached maximum iterations, exiting')

	# Save the last checkpoint if it wasn't already saved.
	if (self.step - 1) % self.save_interval != 0:
	self.save()
	self.save(self.mp_trainer_cvD, 'cvD')

	exit()

	# Save the last checkpoint if it wasn't already saved.
	if (self.step - 1) % self.save_interval != 0:
	self.save()
	self.save(self.mp_trainer_cvD, 'cvD')

	def forward_D(self, batch): # update D
	self.rec_model.requires_grad_(False)

	self.mp_trainer_cvD.zero_grad()
	self.ddp_nvs_cvD.requires_grad_(True)

	batch_size = batch['img'].shape[0]

	# * sample a new batch for D training
	for i in range(0, batch_size, self.microbatch):
	micro = {
	k: v[i:i + self.microbatch].to(dist_util.dev()).contiguous()
	for k, v in batch.items()
	}

	with th.autocast(device_type='cuda',
	dtype=th.float16,
	enabled=self.mp_trainer_cvD.use_amp):

	novel_view_c = th.cat([
	micro['c'][1:], micro['c'][:1]
	])
	latent = self.rec_model(img=micro['img_to_encoder'],
	behaviour='enc_dec_wo_triplane')

	cano_pred = self.rec_model(latent=latent,
	c=micro['c'],
	behaviour='triplane_dec')

	nvs_pred = self.rec_model(latent=latent,
	c=novel_view_c,
	behaviour='triplane_dec')

	if 'image_sr' in nvs_pred:
	d_loss_nvs = self.run_D_Diter(
	real=th.cat([
	th.nn.functional.interpolate(
	cano_pred['image_raw'],
	size=cano_pred['image_sr'].shape[2:],
	mode='bilinear',
	align_corners=False,
	antialias=True),
	cano_pred['image_sr'],
	], dim=1),
	fake=th.cat([
	th.nn.functional.interpolate(
	nvs_pred['image_raw'],
	size=nvs_pred['image_sr'].shape[2:],
	mode='bilinear',
	align_corners=False,
	antialias=True),
	nvs_pred['image_sr'],
	], dim=1),
	D=self.ddp_nvs_cvD) # TODO, add SR for FFHQ

	else:
	d_loss_nvs = self.run_D_Diter(
	real=cano_pred['image_raw'],
	fake=nvs_pred['image_raw'],
	D=self.ddp_nvs_cvD) # TODO, add SR for FFHQ

	log_rec3d_loss_dict(
	{'vision_aided_loss/D_nvs': d_loss_nvs})
	self.mp_trainer_cvD.backward(d_loss_nvs)

	def forward_G_rec(self, batch): # update G

	self.mp_trainer_rec.zero_grad()
	self.rec_model.requires_grad_(True)
	self.ddp_nvs_cvD.requires_grad_(False)

	batch_size = batch['img'].shape[0]

	for i in range(0, batch_size, self.microbatch):
	micro = {
	k: v[i:i + self.microbatch].to(dist_util.dev()).contiguous()
	for k, v in batch.items()
	}

	last_batch = (i + self.microbatch) >= batch_size

	with th.autocast(device_type='cuda',
	dtype=th.float16,
	enabled=self.mp_trainer_rec.use_amp):

	pred = self.rec_model(
	img=micro['img_to_encoder'], c=micro['c']
	) # render novel view for first half of the batch for D loss

	target_for_rec = micro
	pred_for_rec = pred

	if last_batch or not self.use_ddp:
	loss, loss_dict = self.loss_class(pred_for_rec,
	target_for_rec,
	test_mode=False)
	else:
	with self.rec_model.no_sync(): # type: ignore
	loss, loss_dict = self.loss_class(pred_for_rec,
	target_for_rec,
	test_mode=False)

	log_rec3d_loss_dict(loss_dict)

	self.mp_trainer_rec.backward(loss)

	# ! move to other places, add tensorboard

	if dist_util.get_rank() == 0 and self.step % 500 == 0:
	with th.no_grad():
	# gt_vis = th.cat([batch['img'], batch['depth']], dim=-1)

	gt_depth = micro['depth']
	if gt_depth.ndim == 3:
	gt_depth = gt_depth.unsqueeze(1)
	gt_depth = (gt_depth - gt_depth.min()) / (gt_depth.max() -
	gt_depth.min())
	# if True:
	pred_depth = pred['image_depth']
	pred_depth = (pred_depth - pred_depth.min()) / (
	pred_depth.max() - pred_depth.min())
	pred_img = pred['image_raw']
	gt_img = micro['img']

	if 'image_sr' in pred:
	if pred['image_sr'].shape[-1] == 512:
	pred_img = th.cat(
	[self.pool_512(pred_img), pred['image_sr']],
	dim=-1)
	gt_img = th.cat(
	[self.pool_512(micro['img']), micro['img_sr']],
	dim=-1)
	pred_depth = self.pool_512(pred_depth)
	gt_depth = self.pool_512(gt_depth)

	elif pred['image_sr'].shape[-1] == 256:
	pred_img = th.cat(
	[self.pool_256(pred_img), pred['image_sr']],
	dim=-1)
	gt_img = th.cat(
	[self.pool_256(micro['img']), micro['img_sr']],
	dim=-1)
	pred_depth = self.pool_256(pred_depth)
	gt_depth = self.pool_256(gt_depth)

	else:
	pred_img = th.cat(
	[self.pool_128(pred_img), pred['image_sr']],
	dim=-1)
	gt_img = th.cat(
	[self.pool_128(micro['img']), micro['img_sr']],
	dim=-1)
	gt_depth = self.pool_128(gt_depth)
	pred_depth = self.pool_128(pred_depth)

	gt_vis = th.cat(
	[gt_img, gt_depth.repeat_interleave(3, dim=1)],
	dim=-1) # TODO, fail to load depth. range [0, 1]

	pred_vis = th.cat(
	[pred_img,
	pred_depth.repeat_interleave(3, dim=1)],
	dim=-1) # B, 3, H, W

	vis = th.cat([gt_vis, pred_vis], dim=-2)[0].permute(
	1, 2, 0).cpu() # ! pred in range[-1, 1]
	# vis_grid = torchvision.utils.make_grid(vis) # HWC
	vis = vis.numpy() * 127.5 + 127.5
	vis = vis.clip(0, 255).astype(np.uint8)
	Image.fromarray(vis).save(
	f'{logger.get_dir()}/{self.step+self.resume_step}_rec.jpg'
	)
	print(
	'log vis to: ',
	f'{logger.get_dir()}/{self.step+self.resume_step}_rec.jpg'
	)

	def forward_G_nvs(self, batch): # update G

	self.mp_trainer_rec.zero_grad()
	self.rec_model.requires_grad_(True)
	self.ddp_nvs_cvD.requires_grad_(False) # only use novel view D

	batch_size = batch['img'].shape[0]

	for i in range(0, batch_size, self.microbatch):
	micro = {
	k: v[i:i + self.microbatch].to(dist_util.dev()).contiguous()
	for k, v in batch.items()
	}

	with th.autocast(device_type='cuda',
	dtype=th.float16,
	enabled=self.mp_trainer_rec.use_amp):

	nvs_pred = self.rec_model(
	img=micro['img_to_encoder'],
	c=th.cat([
	micro['c'][1:],
	micro['c'][:1],
	])) # ! render novel views only for D loss

	# add cvD supervision

	if 'image_sr' in nvs_pred:
	# concat sr and raw results
	vision_aided_loss = self.ddp_nvs_cvD(
	th.cat([
	th.nn.functional.interpolate(
	nvs_pred['image_raw'],
	size=nvs_pred['image_sr'].shape[2:],
	mode='bilinear',
	align_corners=False,
	antialias=True),
	nvs_pred['image_sr'],
	], dim=1),
	for_G=True).mean()
	else:
	vision_aided_loss = self.ddp_nvs_cvD(
	nvs_pred['image_raw'],
	for_G=True).mean() # [B, 1] shape

	loss = vision_aided_loss * self.loss_class.opt.nvs_cvD_lambda

	log_rec3d_loss_dict({
	'vision_aided_loss/G_nvs': loss
	})

	self.mp_trainer_rec.backward(loss)

	# ! move to other places, add tensorboard

	if dist_util.get_rank() == 0 and self.step % 500 == 0:
	with th.no_grad():
	gt_depth = micro['depth']
	if gt_depth.ndim == 3:
	gt_depth = gt_depth.unsqueeze(1)
	gt_depth = (gt_depth - gt_depth.min()) / (gt_depth.max() -
	gt_depth.min())
	# if True:
	pred_depth = nvs_pred['image_depth']
	pred_depth = (pred_depth - pred_depth.min()) / (
	pred_depth.max() - pred_depth.min())
	pred_img = nvs_pred['image_raw']
	gt_img = micro['img']

	if 'image_sr' in nvs_pred:

	if nvs_pred['image_sr'].shape[-1] == 512:
	pred_img = th.cat([
	self.pool_512(pred_img), nvs_pred['image_sr']
	],
	dim=-1)
	gt_img = th.cat(
	[self.pool_512(micro['img']), micro['img_sr']],
	dim=-1)
	pred_depth = self.pool_512(pred_depth)
	gt_depth = self.pool_512(gt_depth)

	elif nvs_pred['image_sr'].shape[-1] == 256:
	pred_img = th.cat([
	self.pool_256(pred_img), nvs_pred['image_sr']
	],
	dim=-1)
	gt_img = th.cat(
	[self.pool_256(micro['img']), micro['img_sr']],
	dim=-1)
	pred_depth = self.pool_256(pred_depth)
	gt_depth = self.pool_256(gt_depth)

	else:
	pred_img = th.cat([
	self.pool_128(pred_img), nvs_pred['image_sr']
	],
	dim=-1)
	gt_img = th.cat(
	[self.pool_128(micro['img']), micro['img_sr']],
	dim=-1)
	gt_depth = self.pool_128(gt_depth)
	pred_depth = self.pool_128(pred_depth)

	gt_vis = th.cat(
	[gt_img, gt_depth.repeat_interleave(3, dim=1)],
	dim=-1) # TODO, fail to load depth. range [0, 1]

	pred_vis = th.cat(
	[pred_img,
	pred_depth.repeat_interleave(3, dim=1)],
	dim=-1) # B, 3, H, W

	vis = th.cat([gt_vis, pred_vis], dim=-2)

	vis = torchvision.utils.make_grid(
	vis,
	normalize=True,
	scale_each=True,
	value_range=(-1, 1)).cpu().permute(1, 2, 0) # H W 3
	vis = vis.numpy() * 255
	vis = vis.clip(0, 255).astype(np.uint8)

	Image.fromarray(vis).save(
	f'{logger.get_dir()}/{self.step+self.resume_step}_nvs.jpg'
	)
	print(
	'log vis to: ',
	f'{logger.get_dir()}/{self.step+self.resume_step}_nvs.jpg'
	)

	def save(self, mp_trainer=None, model_name='rec'):
	if mp_trainer is None:
	mp_trainer = self.mp_trainer_rec

	def save_checkpoint(rate, params):
	state_dict = mp_trainer.master_params_to_state_dict(params)
	if dist_util.get_rank() == 0:
	logger.log(f"saving model {model_name} {rate}...")
	if not rate:
	filename = f"model_{model_name}{(self.step+self.resume_step):07d}.pt"
	else:
	filename = f"ema_{model_name}_{rate}_{(self.step+self.resume_step):07d}.pt"
	with bf.BlobFile(bf.join(get_blob_logdir(), filename),
	"wb") as f:
	th.save(state_dict, f)

	save_checkpoint(0, mp_trainer.master_params)
	for rate, params in zip(self.ema_rate, self.ema_params):
	save_checkpoint(rate, params)

	dist.barrier()

	def _load_and_sync_parameters(self, model=None, model_name='rec'):
	resume_checkpoint, self.resume_step = find_resume_checkpoint(
	self.resume_checkpoint, model_name) or self.resume_checkpoint

	if model is None:
	model = self.rec_model # default model in the parent class

	print(resume_checkpoint)

	if resume_checkpoint and Path(resume_checkpoint).exists():
	if dist_util.get_rank() == 0:

	logger.log(
	f"loading model from checkpoint: {resume_checkpoint}...")
	map_location = {
	'cuda:%d' % 0: 'cuda:%d' % dist_util.get_rank()
	} # configure map_location properly

	print(f'mark {model_name} loading ', flush=True)
	resume_state_dict = dist_util.load_state_dict(
	resume_checkpoint, map_location=map_location)
	print(f'mark {model_name} loading finished', flush=True)

	model_state_dict = model.state_dict()

	for k, v in resume_state_dict.items():
	if k in model_state_dict.keys() and v.size(
	) == model_state_dict[k].size():
	model_state_dict[k] = v
	elif 'IN' in k:
	print('ignore ', k)
	else:
	print('!!!! ignore key: ', k, ": ", v.size(),
	'shape in model: ', model_state_dict[k].size())

	model.load_state_dict(model_state_dict, strict=True)
	del model_state_dict

	if dist_util.get_world_size() > 1:
	dist_util.sync_params(model.parameters())
	print(f'synced {model_name} params')