from typing import * import os import copy import functools import numpy as np import torch import torch.nn.functional as F from torch.utils.data import DataLoader import utils3d from easydict import EasyDict as edict from ..basic import BasicTrainer from ...modules import sparse as sp from ...renderers import MeshRenderer from ...representations import Mesh from ...utils.data_utils import recursive_to_device, cycle, BalancedResumableSampler from ...utils.loss_utils import l1_loss, ssim, lpips class ShapeVaeTrainer(BasicTrainer): """ Trainer for Shape VAE Args: models (dict[str, nn.Module]): Models to train. dataset (torch.utils.data.Dataset): Dataset. output_dir (str): Output directory. load_dir (str): Load directory. step (int): Step to load. batch_size (int): Batch size. batch_size_per_gpu (int): Batch size per GPU. If specified, batch_size will be ignored. batch_split (int): Split batch with gradient accumulation. max_steps (int): Max steps. optimizer (dict): Optimizer config. lr_scheduler (dict): Learning rate scheduler config. elastic (dict): Elastic memory management config. grad_clip (float or dict): Gradient clip config. ema_rate (float or list): Exponential moving average rates. fp16_mode (str): FP16 mode. - None: No FP16. - 'inflat_all': Hold a inflated fp32 master param for all params. - 'amp': Automatic mixed precision. fp16_scale_growth (float): Scale growth for FP16 gradient backpropagation. finetune_ckpt (dict): Finetune checkpoint. log_param_stats (bool): Log parameter stats. i_print (int): Print interval. i_log (int): Log interval. i_sample (int): Sample interval. i_save (int): Save interval. i_ddpcheck (int): DDP check interval. lambda_subdiv (float): Subdivision loss weight. lambda_intersected (float): Intersected loss weight. lambda_vertice (float): Vertice loss weight. lambda_kl (float): KL loss weight. lambda_ssim (float): SSIM loss weight. lambda_lpips (float): LPIPS loss weight. """ def __init__( self, *args, lambda_subdiv: float = 0.1, lambda_intersected: float = 0.1, lambda_vertice: float = 1e-2, lambda_mask: float = 1, lambda_depth: float = 10, lambda_normal: float = 1, lambda_kl: float = 1e-6, lambda_ssim: float = 0.2, lambda_lpips: float = 0.2, render_resolution: float = 1024, camera_randomization_config: dict = { 'radius_range': [2, 100], }, **kwargs ): super().__init__(*args, **kwargs) self.lambda_subdiv = lambda_subdiv self.lambda_intersected = lambda_intersected self.lambda_mask = lambda_mask self.lambda_vertice = lambda_vertice self.lambda_depth = lambda_depth self.lambda_normal = lambda_normal self.lambda_kl = lambda_kl self.lambda_ssim = lambda_ssim self.lambda_lpips = lambda_lpips self.camera_randomization_config = camera_randomization_config self.renderer = MeshRenderer({'near': 1, 'far': 3, 'resolution': render_resolution}, device=self.device) def prepare_dataloader(self, **kwargs): """ Prepare dataloader. """ self.data_sampler = BalancedResumableSampler( self.dataset, shuffle=True, batch_size=self.batch_size_per_gpu, ) self.dataloader = DataLoader( self.dataset, batch_size=self.batch_size_per_gpu, num_workers=int(np.ceil(os.cpu_count() / torch.cuda.device_count())), pin_memory=True, drop_last=True, persistent_workers=True, collate_fn=functools.partial(self.dataset.collate_fn, split_size=self.batch_split), sampler=self.data_sampler, ) self.data_iterator = cycle(self.dataloader) def _randomize_camera(self, num_samples: int): # sample radius and fov r_min, r_max = self.camera_randomization_config['radius_range'] k_min = 1 / r_max**2 k_max = 1 / r_min**2 ks = torch.rand(num_samples, device=self.device) * (k_max - k_min) + k_min radius = 1 / torch.sqrt(ks) fov = 2 * torch.arcsin(0.5 / radius) origin = radius.unsqueeze(-1) * F.normalize(torch.randn(num_samples, 3, device=self.device), dim=-1) # build camera extrinsics = utils3d.torch.extrinsics_look_at(origin, torch.zeros_like(origin), torch.tensor([0, 0, 1], dtype=torch.float32, device=self.device)) intrinsics = utils3d.torch.intrinsics_from_fov_xy(fov, fov) near = [np.random.uniform(r - 1, r) for r in radius.tolist()] return { 'extrinsics': extrinsics, 'intrinsics': intrinsics, 'near': near, } def _render_batch(self, reps: List[Mesh], extrinsics: torch.Tensor, intrinsics: torch.Tensor, near: List, return_types=['mask', 'normal', 'depth']) -> Dict[str, torch.Tensor]: """ Render a batch of representations. Args: reps: The dictionary of lists of representations. extrinsics: The [N x 4 x 4] tensor of extrinsics. intrinsics: The [N x 3 x 3] tensor of intrinsics. return_types: vary in ['mask', 'normal', 'depth', 'normal_map', 'color'] Returns: a dict with mask : [N x 1 x H x W] tensor of rendered masks normal : [N x 3 x H x W] tensor of rendered normals depth : [N x 1 x H x W] tensor of rendered depths """ ret = {k : [] for k in return_types} for i, rep in enumerate(reps): self.renderer.rendering_options['near'] = near[i] self.renderer.rendering_options['far'] = near[i] + 2 out_dict = self.renderer.render(rep, extrinsics[i], intrinsics[i], return_types=return_types) for k in out_dict: ret[k].append(out_dict[k][None] if k in ['mask', 'depth'] else out_dict[k]) for k in ret: ret[k] = torch.stack(ret[k]) return ret def training_losses( self, vertices: sp.SparseTensor, intersected: sp.SparseTensor, mesh: List[Mesh], ) -> Tuple[Dict, Dict]: """ Compute training losses. Args: vertices (SparseTensor): vertices of each active voxel intersected (SparseTensor): intersected flag of each active voxel mesh (List[Mesh]): the list of meshes to render Returns: a dict with the key "loss" containing a scalar tensor. may also contain other keys for different terms. """ z, mean, logvar = self.training_models['encoder'](vertices, intersected, sample_posterior=True, return_raw=True) recon, pred_vertice, pred_intersected, subs_gt, subs = self.training_models['decoder'](z, intersected) terms = edict(loss = 0.0) # direct regression if self.lambda_intersected > 0: terms["direct/intersected"] = F.binary_cross_entropy_with_logits(pred_intersected.feats.flatten(), intersected.feats.flatten().float()) terms["loss"] = terms["loss"] + self.lambda_intersected * terms["direct/intersected"] if self.lambda_vertice > 0: terms["direct/vertice"] = F.mse_loss(pred_vertice.feats, vertices.feats) terms["loss"] = terms["loss"] + self.lambda_vertice * terms["direct/vertice"] # subdivision prediction loss for i, (sub_gt, sub) in enumerate(zip(subs_gt, subs)): terms[f"bce_sub{i}"] = F.binary_cross_entropy_with_logits(sub.feats, sub_gt.float()) terms["loss"] = terms["loss"] + self.lambda_subdiv * terms[f"bce_sub{i}"] # rendering loss cameras = self._randomize_camera(len(mesh)) gt_renders = self._render_batch(mesh, **cameras, return_types=['mask', 'normal', 'depth']) pred_renders = self._render_batch(recon, **cameras, return_types=['mask', 'normal', 'depth']) terms['render/mask'] = l1_loss(pred_renders['mask'], gt_renders['mask']) terms['render/depth'] = l1_loss(pred_renders['depth'], gt_renders['depth']) terms['render/normal/l1'] = l1_loss(pred_renders['normal'], gt_renders['normal']) terms['render/normal/ssim'] = 1 - ssim(pred_renders['normal'], gt_renders['normal']) terms['render/normal/lpips'] = lpips(pred_renders['normal'], gt_renders['normal']) terms['loss'] = terms['loss'] + \ self.lambda_mask * terms['render/mask'] + \ self.lambda_depth * terms['render/depth'] + \ self.lambda_normal * (terms['render/normal/l1'] + self.lambda_ssim * terms['render/normal/ssim'] + self.lambda_lpips * terms['render/normal/lpips']) # KL regularization terms["kl"] = 0.5 * torch.mean(mean.pow(2) + logvar.exp() - logvar - 1) terms["loss"] = terms["loss"] + self.lambda_kl * terms["kl"] return terms, {} @torch.no_grad() def run_snapshot( self, num_samples: int, batch_size: int, verbose: bool = False, ) -> Dict: dataloader = DataLoader( copy.deepcopy(self.dataset), batch_size=batch_size, shuffle=True, num_workers=1, collate_fn=self.dataset.collate_fn if hasattr(self.dataset, 'collate_fn') else None, ) # inference gts = [] recons = [] recons2 = [] self.models['encoder'].eval() for i in range(0, num_samples, batch_size): batch = min(batch_size, num_samples - i) data = next(iter(dataloader)) args = {k: v[:batch] for k, v in data.items()} args = recursive_to_device(args, self.device) z = self.models['encoder'](args['vertices'], args['intersected']) self.models['decoder'].train() y = self.models['decoder'](z, args['intersected'])[0] z.clear_spatial_cache() self.models['decoder'].eval() y2 = self.models['decoder'](z) gts.extend(args['mesh']) recons.extend(y) recons2.extend(y2) self.models['encoder'].train() self.models['decoder'].train() cameras = self._randomize_camera(num_samples) gt_renders = self._render_batch(gts, **cameras, return_types=['normal']) recons_renders = self._render_batch(recons, **cameras, return_types=['normal']) recons2_renders = self._render_batch(recons2, **cameras, return_types=['normal']) sample_dict = { 'gt': {'value': gt_renders['normal'], 'type': 'image'}, 'rec': {'value': recons_renders['normal'], 'type': 'image'}, 'rec2': {'value': recons2_renders['normal'], 'type': 'image'}, } return sample_dict