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| import torch |
| import torch.nn.functional as F |
|
|
| from .models.core.model_utils import smart_cat, get_points_on_a_grid |
| from .models.build_cotracker import build_cotracker |
|
|
|
|
| class CoTrackerPredictor(torch.nn.Module): |
| def __init__( |
| self, |
| checkpoint="./checkpoints/scaled_offline.pth", |
| offline=True, |
| v2=False, |
| window_len=60, |
| ): |
| super().__init__() |
| self.v2 = v2 |
| self.support_grid_size = 6 |
| model = build_cotracker( |
| checkpoint, |
| v2=v2, |
| offline=offline, |
| window_len=window_len, |
| ) |
| self.interp_shape = model.model_resolution |
| self.model = model |
| self.model.eval() |
|
|
| @torch.no_grad() |
| def forward( |
| self, |
| video, |
| |
| |
| |
| |
| |
| |
| queries: torch.Tensor = None, |
| segm_mask: torch.Tensor = None, |
| grid_size: int = 0, |
| grid_query_frame: int = 0, |
| backward_tracking: bool = False, |
| ): |
| if queries is None and grid_size == 0: |
| tracks, visibilities = self._compute_dense_tracks( |
| video, |
| grid_query_frame=grid_query_frame, |
| backward_tracking=backward_tracking, |
| ) |
| else: |
| tracks, visibilities = self._compute_sparse_tracks( |
| video, |
| queries, |
| segm_mask, |
| grid_size, |
| add_support_grid=(grid_size == 0 or segm_mask is not None), |
| grid_query_frame=grid_query_frame, |
| backward_tracking=backward_tracking, |
| ) |
|
|
| return tracks, visibilities |
|
|
| def _compute_dense_tracks( |
| self, video, grid_query_frame, grid_size=80, backward_tracking=False |
| ): |
| *_, H, W = video.shape |
| grid_step = W // grid_size |
| grid_width = W // grid_step |
| grid_height = H // grid_step |
| tracks = visibilities = None |
| grid_pts = torch.zeros((video.shape[0], grid_width * grid_height, 3)).to(video.device) |
| grid_pts[:, :, 0] = grid_query_frame |
| for offset in range(grid_step * grid_step): |
| print(f"step {offset} / {grid_step * grid_step}") |
| ox = offset % grid_step |
| oy = offset // grid_step |
| grid_pts[:, :, 1] = ( |
| torch.arange(grid_width).repeat(grid_height) * grid_step + ox |
| ) |
| grid_pts[:, :, 2] = ( |
| torch.arange(grid_height).repeat_interleave(grid_width) * grid_step + oy |
| ) |
| tracks_step, visibilities_step = self._compute_sparse_tracks( |
| video=video, |
| queries=grid_pts, |
| backward_tracking=backward_tracking, |
| ) |
| tracks = smart_cat(tracks, tracks_step, dim=2) |
| visibilities = smart_cat(visibilities, visibilities_step, dim=2) |
|
|
| return tracks, visibilities |
|
|
| def _compute_sparse_tracks( |
| self, |
| video, |
| queries, |
| segm_mask=None, |
| grid_size=0, |
| add_support_grid=False, |
| grid_query_frame=0, |
| backward_tracking=False, |
| ): |
| B, T, C, H, W = video.shape |
|
|
| video = video.reshape(B * T, C, H, W) |
| video = F.interpolate( |
| video, tuple(self.interp_shape), mode="bilinear", align_corners=True |
| ) |
| video = video.reshape(B, T, 3, self.interp_shape[0], self.interp_shape[1]) |
|
|
| if queries is not None: |
| B, N, D = queries.shape |
| assert D == 3 |
| queries = queries.clone() |
| queries[:, :, 1:] *= queries.new_tensor( |
| [ |
| (self.interp_shape[1] - 1) / (W - 1), |
| (self.interp_shape[0] - 1) / (H - 1), |
| ] |
| ) |
| elif grid_size > 0: |
| grid_pts = get_points_on_a_grid( |
| grid_size, self.interp_shape, device=video.device |
| ) |
| if segm_mask is not None: |
| segm_mask = F.interpolate( |
| segm_mask, tuple(self.interp_shape), mode="nearest" |
| ) |
| point_mask = segm_mask[0, 0][ |
| (grid_pts[0, :, 1]).round().long().cpu(), |
| (grid_pts[0, :, 0]).round().long().cpu(), |
| ].bool() |
| grid_pts = grid_pts[:, point_mask] |
|
|
| queries = torch.cat( |
| [torch.ones_like(grid_pts[:, :, :1]) * grid_query_frame, grid_pts], |
| dim=2, |
| ).repeat(B, 1, 1) |
|
|
| if add_support_grid: |
| grid_pts = get_points_on_a_grid( |
| self.support_grid_size, self.interp_shape, device=video.device |
| ) |
| grid_pts = torch.cat( |
| [torch.zeros_like(grid_pts[:, :, :1]), grid_pts], dim=2 |
| ) |
| grid_pts = grid_pts.repeat(B, 1, 1) |
| queries = torch.cat([queries, grid_pts], dim=1) |
|
|
| tracks, visibilities, *_ = self.model.forward( |
| video=video, queries=queries, iters=6 |
| ) |
|
|
| if backward_tracking: |
| tracks, visibilities = self._compute_backward_tracks( |
| video, queries, tracks, visibilities |
| ) |
| if add_support_grid: |
| queries[:, -self.support_grid_size**2 :, 0] = T - 1 |
| if add_support_grid: |
| tracks = tracks[:, :, : -self.support_grid_size**2] |
| visibilities = visibilities[:, :, : -self.support_grid_size**2] |
| thr = 0.9 |
| visibilities = visibilities > thr |
|
|
| |
| |
|
|
| |
| for i in range(len(queries)): |
| queries_t = queries[i, : tracks.size(2), 0].to(torch.int64) |
| arange = torch.arange(0, len(queries_t)) |
|
|
| |
| tracks[i, queries_t, arange] = queries[i, : tracks.size(2), 1:] |
|
|
| |
| visibilities[i, queries_t, arange] = True |
|
|
| tracks *= tracks.new_tensor( |
| [(W - 1) / (self.interp_shape[1] - 1), (H - 1) / (self.interp_shape[0] - 1)] |
| ) |
| return tracks, visibilities |
|
|
| def _compute_backward_tracks(self, video, queries, tracks, visibilities): |
| inv_video = video.flip(1).clone() |
| inv_queries = queries.clone() |
| inv_queries[:, :, 0] = inv_video.shape[1] - inv_queries[:, :, 0] - 1 |
|
|
| inv_tracks, inv_visibilities, *_ = self.model( |
| video=inv_video, queries=inv_queries, iters=6 |
| ) |
|
|
| inv_tracks = inv_tracks.flip(1) |
| inv_visibilities = inv_visibilities.flip(1) |
| arange = torch.arange(video.shape[1], device=queries.device)[None, :, None] |
|
|
| mask = (arange < queries[:, None, :, 0]).unsqueeze(-1).repeat(1, 1, 1, 2) |
|
|
| tracks[mask] = inv_tracks[mask] |
| visibilities[mask[:, :, :, 0]] = inv_visibilities[mask[:, :, :, 0]] |
| return tracks, visibilities |
|
|
|
|
| class CoTrackerOnlinePredictor(torch.nn.Module): |
| def __init__( |
| self, |
| checkpoint="./checkpoints/scaled_online.pth", |
| offline=False, |
| v2=False, |
| window_len=16, |
| ): |
| super().__init__() |
| self.v2 = v2 |
| self.support_grid_size = 6 |
| model = build_cotracker(checkpoint, v2=v2, offline=False, window_len=window_len) |
| self.interp_shape = model.model_resolution |
| self.step = model.window_len // 2 |
| self.model = model |
| self.model.eval() |
|
|
| @torch.no_grad() |
| def forward( |
| self, |
| video_chunk, |
| is_first_step: bool = False, |
| queries: torch.Tensor = None, |
| grid_size: int = 5, |
| grid_query_frame: int = 0, |
| add_support_grid=False, |
| ): |
| B, T, C, H, W = video_chunk.shape |
| |
| |
| if is_first_step: |
| self.model.init_video_online_processing() |
| if queries is not None: |
| B, N, D = queries.shape |
| self.N = N |
| assert D == 3 |
| queries = queries.clone() |
| queries[:, :, 1:] *= queries.new_tensor( |
| [ |
| (self.interp_shape[1] - 1) / (W - 1), |
| (self.interp_shape[0] - 1) / (H - 1), |
| ] |
| ) |
| if add_support_grid: |
| grid_pts = get_points_on_a_grid( |
| self.support_grid_size, self.interp_shape, device=video_chunk.device |
| ) |
| grid_pts = torch.cat( |
| [torch.zeros_like(grid_pts[:, :, :1]), grid_pts], dim=2 |
| ) |
| queries = torch.cat([queries, grid_pts], dim=1) |
| elif grid_size > 0: |
| grid_pts = get_points_on_a_grid( |
| grid_size, self.interp_shape, device=video_chunk.device |
| ) |
| self.N = grid_size**2 |
| queries = torch.cat( |
| [torch.ones_like(grid_pts[:, :, :1]) * grid_query_frame, grid_pts], |
| dim=2, |
| ) |
| |
| self.queries = queries |
| return (None, None) |
|
|
| video_chunk = video_chunk.reshape(B * T, C, H, W) |
| video_chunk = F.interpolate( |
| video_chunk, tuple(self.interp_shape), mode="bilinear", align_corners=True |
| ) |
| video_chunk = video_chunk.reshape( |
| B, T, 3, self.interp_shape[0], self.interp_shape[1] |
| ) |
| if self.v2: |
| tracks, visibilities, __ = self.model( |
| video=video_chunk, queries=self.queries, iters=6, is_online=True |
| ) |
| else: |
| tracks, visibilities, confidence, __ = self.model( |
| video=video_chunk, queries=self.queries, iters=6, is_online=True |
| ) |
| if add_support_grid: |
| tracks = tracks[:,:,:self.N] |
| visibilities = visibilities[:,:,:self.N] |
| if not self.v2: |
| confidence = confidence[:,:,:self.N] |
| |
| if not self.v2: |
| visibilities = visibilities * confidence |
| thr = 0.6 |
| return ( |
| tracks |
| * tracks.new_tensor( |
| [ |
| (W - 1) / (self.interp_shape[1] - 1), |
| (H - 1) / (self.interp_shape[0] - 1), |
| ] |
| ), |
| visibilities > thr, |
| ) |
|
|
