| |
|
|
| from typing import Any, List |
| import torch |
| from torch import nn |
| from torch.nn import functional as F |
|
|
| from detectron2.config import CfgNode |
| from detectron2.structures import Instances |
|
|
| from densepose.data.meshes.catalog import MeshCatalog |
| from densepose.modeling.cse.utils import normalize_embeddings, squared_euclidean_distance_matrix |
|
|
| from .embed_utils import PackedCseAnnotations |
| from .mask import extract_data_for_mask_loss_from_matches |
|
|
|
|
| def _create_pixel_dist_matrix(grid_size: int) -> torch.Tensor: |
| rows = torch.arange(grid_size) |
| cols = torch.arange(grid_size) |
| |
| |
| |
| pix_coords = ( |
| torch.stack(torch.meshgrid(rows, cols), -1).reshape((grid_size * grid_size, 2)).float() |
| ) |
| return squared_euclidean_distance_matrix(pix_coords, pix_coords) |
|
|
|
|
| def _sample_fg_pixels_randperm(fg_mask: torch.Tensor, sample_size: int) -> torch.Tensor: |
| fg_mask_flattened = fg_mask.reshape((-1,)) |
| num_pixels = int(fg_mask_flattened.sum().item()) |
| fg_pixel_indices = fg_mask_flattened.nonzero(as_tuple=True)[0] |
| if (sample_size <= 0) or (num_pixels <= sample_size): |
| return fg_pixel_indices |
| sample_indices = torch.randperm(num_pixels, device=fg_mask.device)[:sample_size] |
| return fg_pixel_indices[sample_indices] |
|
|
|
|
| def _sample_fg_pixels_multinomial(fg_mask: torch.Tensor, sample_size: int) -> torch.Tensor: |
| fg_mask_flattened = fg_mask.reshape((-1,)) |
| num_pixels = int(fg_mask_flattened.sum().item()) |
| if (sample_size <= 0) or (num_pixels <= sample_size): |
| return fg_mask_flattened.nonzero(as_tuple=True)[0] |
| return fg_mask_flattened.float().multinomial(sample_size, replacement=False) |
|
|
|
|
| class PixToShapeCycleLoss(nn.Module): |
| """ |
| Cycle loss for pixel-vertex correspondence |
| """ |
|
|
| def __init__(self, cfg: CfgNode): |
| super().__init__() |
| self.shape_names = list(cfg.MODEL.ROI_DENSEPOSE_HEAD.CSE.EMBEDDERS.keys()) |
| self.embed_size = cfg.MODEL.ROI_DENSEPOSE_HEAD.CSE.EMBED_SIZE |
| self.norm_p = cfg.MODEL.ROI_DENSEPOSE_HEAD.CSE.PIX_TO_SHAPE_CYCLE_LOSS.NORM_P |
| self.use_all_meshes_not_gt_only = ( |
| cfg.MODEL.ROI_DENSEPOSE_HEAD.CSE.PIX_TO_SHAPE_CYCLE_LOSS.USE_ALL_MESHES_NOT_GT_ONLY |
| ) |
| self.num_pixels_to_sample = ( |
| cfg.MODEL.ROI_DENSEPOSE_HEAD.CSE.PIX_TO_SHAPE_CYCLE_LOSS.NUM_PIXELS_TO_SAMPLE |
| ) |
| self.pix_sigma = cfg.MODEL.ROI_DENSEPOSE_HEAD.CSE.PIX_TO_SHAPE_CYCLE_LOSS.PIXEL_SIGMA |
| self.temperature_pix_to_vertex = ( |
| cfg.MODEL.ROI_DENSEPOSE_HEAD.CSE.PIX_TO_SHAPE_CYCLE_LOSS.TEMPERATURE_PIXEL_TO_VERTEX |
| ) |
| self.temperature_vertex_to_pix = ( |
| cfg.MODEL.ROI_DENSEPOSE_HEAD.CSE.PIX_TO_SHAPE_CYCLE_LOSS.TEMPERATURE_VERTEX_TO_PIXEL |
| ) |
| self.pixel_dists = _create_pixel_dist_matrix(cfg.MODEL.ROI_DENSEPOSE_HEAD.HEATMAP_SIZE) |
|
|
| def forward( |
| self, |
| proposals_with_gt: List[Instances], |
| densepose_predictor_outputs: Any, |
| packed_annotations: PackedCseAnnotations, |
| embedder: nn.Module, |
| ): |
| """ |
| Args: |
| proposals_with_gt (list of Instances): detections with associated |
| ground truth data; each item corresponds to instances detected |
| on 1 image; the number of items corresponds to the number of |
| images in a batch |
| densepose_predictor_outputs: an object of a dataclass that contains predictor |
| outputs with estimated values; assumed to have the following attributes: |
| * embedding - embedding estimates, tensor of shape [N, D, S, S], where |
| N = number of instances (= sum N_i, where N_i is the number of |
| instances on image i) |
| D = embedding space dimensionality (MODEL.ROI_DENSEPOSE_HEAD.CSE.EMBED_SIZE) |
| S = output size (width and height) |
| packed_annotations (PackedCseAnnotations): contains various data useful |
| for loss computation, each data is packed into a single tensor |
| embedder (nn.Module): module that computes vertex embeddings for different meshes |
| """ |
| pix_embeds = densepose_predictor_outputs.embedding |
| if self.pixel_dists.device != pix_embeds.device: |
| |
| self.pixel_dists = self.pixel_dists.to(device=pix_embeds.device) |
| with torch.no_grad(): |
| mask_loss_data = extract_data_for_mask_loss_from_matches( |
| proposals_with_gt, densepose_predictor_outputs.coarse_segm |
| ) |
| |
| masks_gt = mask_loss_data.masks_gt.long() |
| assert len(pix_embeds) == len(masks_gt), ( |
| f"Number of instances with embeddings {len(pix_embeds)} != " |
| f"number of instances with GT masks {len(masks_gt)}" |
| ) |
| losses = [] |
| mesh_names = ( |
| self.shape_names |
| if self.use_all_meshes_not_gt_only |
| else [ |
| MeshCatalog.get_mesh_name(mesh_id.item()) |
| for mesh_id in packed_annotations.vertex_mesh_ids_gt.unique() |
| ] |
| ) |
| for pixel_embeddings, mask_gt in zip(pix_embeds, masks_gt): |
| |
| |
| for mesh_name in mesh_names: |
| mesh_vertex_embeddings = embedder(mesh_name) |
| |
| pixel_indices_flattened = _sample_fg_pixels_randperm( |
| mask_gt, self.num_pixels_to_sample |
| ) |
| |
| pixel_dists = self.pixel_dists.to(pixel_embeddings.device)[ |
| torch.meshgrid(pixel_indices_flattened, pixel_indices_flattened) |
| ] |
| |
| pixel_embeddings_sampled = normalize_embeddings( |
| pixel_embeddings.reshape((self.embed_size, -1))[:, pixel_indices_flattened].T |
| ) |
| |
| sim_matrix = pixel_embeddings_sampled.mm(mesh_vertex_embeddings.T) |
| c_pix_vertex = F.softmax(sim_matrix / self.temperature_pix_to_vertex, dim=1) |
| c_vertex_pix = F.softmax(sim_matrix.T / self.temperature_vertex_to_pix, dim=1) |
| c_cycle = c_pix_vertex.mm(c_vertex_pix) |
| loss_cycle = torch.norm(pixel_dists * c_cycle, p=self.norm_p) |
| losses.append(loss_cycle) |
|
|
| if len(losses) == 0: |
| return pix_embeds.sum() * 0 |
| return torch.stack(losses, dim=0).mean() |
|
|
| def fake_value(self, densepose_predictor_outputs: Any, embedder: nn.Module): |
| losses = [embedder(mesh_name).sum() * 0 for mesh_name in embedder.mesh_names] |
| losses.append(densepose_predictor_outputs.embedding.sum() * 0) |
| return torch.mean(torch.stack(losses)) |
|
|
