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310 lines
13 KiB
310 lines
13 KiB
import math
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from copy import deepcopy
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from itertools import product
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from typing import Any, Dict, Generator, ItemsView, List, Tuple
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import numpy as np
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import torch
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class MaskData:
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"""
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A structure for storing masks and their related data in batched format.
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Implements basic filtering and concatenation.
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"""
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def __init__(self, **kwargs) -> None:
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"""Initialize a MaskData object, ensuring all values are supported types."""
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for v in kwargs.values():
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assert isinstance(
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v, (list, np.ndarray, torch.Tensor)), 'MaskData only supports list, numpy arrays, and torch tensors.'
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self._stats = dict(**kwargs)
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def __setitem__(self, key: str, item: Any) -> None:
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"""Set an item in the MaskData object, ensuring it is a supported type."""
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assert isinstance(
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item, (list, np.ndarray, torch.Tensor)), 'MaskData only supports list, numpy arrays, and torch tensors.'
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self._stats[key] = item
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def __delitem__(self, key: str) -> None:
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"""Delete an item from the MaskData object."""
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del self._stats[key]
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def __getitem__(self, key: str) -> Any:
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"""Get an item from the MaskData object."""
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return self._stats[key]
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def items(self) -> ItemsView[str, Any]:
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"""Return an ItemsView of the MaskData object."""
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return self._stats.items()
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def filter(self, keep: torch.Tensor) -> None:
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"""Filter the MaskData object based on the given boolean tensor."""
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for k, v in self._stats.items():
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if v is None:
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self._stats[k] = None
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elif isinstance(v, torch.Tensor):
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self._stats[k] = v[torch.as_tensor(keep, device=v.device)]
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elif isinstance(v, np.ndarray):
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self._stats[k] = v[keep.detach().cpu().numpy()]
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elif isinstance(v, list) and keep.dtype == torch.bool:
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self._stats[k] = [a for i, a in enumerate(v) if keep[i]]
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elif isinstance(v, list):
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self._stats[k] = [v[i] for i in keep]
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else:
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raise TypeError(f'MaskData key {k} has an unsupported type {type(v)}.')
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def cat(self, new_stats: 'MaskData') -> None:
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"""Concatenate a new MaskData object to the current one."""
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for k, v in new_stats.items():
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if k not in self._stats or self._stats[k] is None:
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self._stats[k] = deepcopy(v)
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elif isinstance(v, torch.Tensor):
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self._stats[k] = torch.cat([self._stats[k], v], dim=0)
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elif isinstance(v, np.ndarray):
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self._stats[k] = np.concatenate([self._stats[k], v], axis=0)
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elif isinstance(v, list):
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self._stats[k] = self._stats[k] + deepcopy(v)
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else:
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raise TypeError(f'MaskData key {k} has an unsupported type {type(v)}.')
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def to_numpy(self) -> None:
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"""Convert all torch tensors in the MaskData object to numpy arrays."""
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for k, v in self._stats.items():
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if isinstance(v, torch.Tensor):
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self._stats[k] = v.detach().cpu().numpy()
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def is_box_near_crop_edge(boxes: torch.Tensor,
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crop_box: List[int],
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orig_box: List[int],
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atol: float = 20.0) -> torch.Tensor:
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"""Return a boolean tensor indicating if boxes are near the crop edge."""
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crop_box_torch = torch.as_tensor(crop_box, dtype=torch.float, device=boxes.device)
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orig_box_torch = torch.as_tensor(orig_box, dtype=torch.float, device=boxes.device)
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boxes = uncrop_boxes_xyxy(boxes, crop_box).float()
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near_crop_edge = torch.isclose(boxes, crop_box_torch[None, :], atol=atol, rtol=0)
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near_image_edge = torch.isclose(boxes, orig_box_torch[None, :], atol=atol, rtol=0)
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near_crop_edge = torch.logical_and(near_crop_edge, ~near_image_edge)
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return torch.any(near_crop_edge, dim=1)
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def box_xyxy_to_xywh(box_xyxy: torch.Tensor) -> torch.Tensor:
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"""Convert bounding boxes from XYXY format to XYWH format."""
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box_xywh = deepcopy(box_xyxy)
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box_xywh[2] = box_xywh[2] - box_xywh[0]
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box_xywh[3] = box_xywh[3] - box_xywh[1]
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return box_xywh
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def batch_iterator(batch_size: int, *args) -> Generator[List[Any], None, None]:
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"""Yield batches of data from the input arguments."""
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assert args and all(len(a) == len(args[0]) for a in args), 'Batched iteration must have same-size inputs.'
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n_batches = len(args[0]) // batch_size + int(len(args[0]) % batch_size != 0)
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for b in range(n_batches):
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yield [arg[b * batch_size:(b + 1) * batch_size] for arg in args]
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def mask_to_rle_pytorch(tensor: torch.Tensor) -> List[Dict[str, Any]]:
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"""Encode masks as uncompressed RLEs in the format expected by pycocotools."""
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# Put in fortran order and flatten h,w
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b, h, w = tensor.shape
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tensor = tensor.permute(0, 2, 1).flatten(1)
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# Compute change indices
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diff = tensor[:, 1:] ^ tensor[:, :-1]
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change_indices = diff.nonzero()
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# Encode run length
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out = []
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for i in range(b):
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cur_idxs = change_indices[change_indices[:, 0] == i, 1]
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cur_idxs = torch.cat([
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torch.tensor([0], dtype=cur_idxs.dtype, device=cur_idxs.device),
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cur_idxs + 1,
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torch.tensor([h * w], dtype=cur_idxs.dtype, device=cur_idxs.device), ])
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btw_idxs = cur_idxs[1:] - cur_idxs[:-1]
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counts = [] if tensor[i, 0] == 0 else [0]
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counts.extend(btw_idxs.detach().cpu().tolist())
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out.append({'size': [h, w], 'counts': counts})
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return out
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def rle_to_mask(rle: Dict[str, Any]) -> np.ndarray:
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"""Compute a binary mask from an uncompressed RLE."""
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h, w = rle['size']
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mask = np.empty(h * w, dtype=bool)
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idx = 0
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parity = False
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for count in rle['counts']:
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mask[idx:idx + count] = parity
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idx += count
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parity ^= True
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mask = mask.reshape(w, h)
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return mask.transpose() # Put in C order
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def area_from_rle(rle: Dict[str, Any]) -> int:
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"""Calculate the area of a mask from its uncompressed RLE."""
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return sum(rle['counts'][1::2])
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def calculate_stability_score(masks: torch.Tensor, mask_threshold: float, threshold_offset: float) -> torch.Tensor:
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"""
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Computes the stability score for a batch of masks. The stability
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score is the IoU between the binary masks obtained by thresholding
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the predicted mask logits at high and low values.
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"""
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# One mask is always contained inside the other.
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# Save memory by preventing unnecessary cast to torch.int64
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intersections = ((masks > (mask_threshold + threshold_offset)).sum(-1, dtype=torch.int16).sum(-1,
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dtype=torch.int32))
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unions = ((masks > (mask_threshold - threshold_offset)).sum(-1, dtype=torch.int16).sum(-1, dtype=torch.int32))
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return intersections / unions
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def build_point_grid(n_per_side: int) -> np.ndarray:
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"""Generate a 2D grid of evenly spaced points in the range [0,1]x[0,1]."""
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offset = 1 / (2 * n_per_side)
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points_one_side = np.linspace(offset, 1 - offset, n_per_side)
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points_x = np.tile(points_one_side[None, :], (n_per_side, 1))
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points_y = np.tile(points_one_side[:, None], (1, n_per_side))
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return np.stack([points_x, points_y], axis=-1).reshape(-1, 2)
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def build_all_layer_point_grids(n_per_side: int, n_layers: int, scale_per_layer: int) -> List[np.ndarray]:
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"""Generate point grids for all crop layers."""
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return [build_point_grid(int(n_per_side / (scale_per_layer ** i))) for i in range(n_layers + 1)]
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def generate_crop_boxes(im_size: Tuple[int, ...], n_layers: int,
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overlap_ratio: float) -> Tuple[List[List[int]], List[int]]:
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"""Generates a list of crop boxes of different sizes. Each layer has (2**i)**2 boxes for the ith layer."""
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crop_boxes, layer_idxs = [], []
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im_h, im_w = im_size
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short_side = min(im_h, im_w)
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# Original image
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crop_boxes.append([0, 0, im_w, im_h])
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layer_idxs.append(0)
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def crop_len(orig_len, n_crops, overlap):
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"""Crops bounding boxes to the size of the input image."""
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return int(math.ceil((overlap * (n_crops - 1) + orig_len) / n_crops))
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for i_layer in range(n_layers):
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n_crops_per_side = 2 ** (i_layer + 1)
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overlap = int(overlap_ratio * short_side * (2 / n_crops_per_side))
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crop_w = crop_len(im_w, n_crops_per_side, overlap)
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crop_h = crop_len(im_h, n_crops_per_side, overlap)
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crop_box_x0 = [int((crop_w - overlap) * i) for i in range(n_crops_per_side)]
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crop_box_y0 = [int((crop_h - overlap) * i) for i in range(n_crops_per_side)]
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# Crops in XYWH format
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for x0, y0 in product(crop_box_x0, crop_box_y0):
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box = [x0, y0, min(x0 + crop_w, im_w), min(y0 + crop_h, im_h)]
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crop_boxes.append(box)
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layer_idxs.append(i_layer + 1)
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return crop_boxes, layer_idxs
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def uncrop_boxes_xyxy(boxes: torch.Tensor, crop_box: List[int]) -> torch.Tensor:
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"""Uncrop bounding boxes by adding the crop box offset."""
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x0, y0, _, _ = crop_box
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offset = torch.tensor([[x0, y0, x0, y0]], device=boxes.device)
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# Check if boxes has a channel dimension
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if len(boxes.shape) == 3:
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offset = offset.unsqueeze(1)
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return boxes + offset
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def uncrop_points(points: torch.Tensor, crop_box: List[int]) -> torch.Tensor:
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"""Uncrop points by adding the crop box offset."""
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x0, y0, _, _ = crop_box
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offset = torch.tensor([[x0, y0]], device=points.device)
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# Check if points has a channel dimension
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if len(points.shape) == 3:
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offset = offset.unsqueeze(1)
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return points + offset
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def uncrop_masks(masks: torch.Tensor, crop_box: List[int], orig_h: int, orig_w: int) -> torch.Tensor:
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"""Uncrop masks by padding them to the original image size."""
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x0, y0, x1, y1 = crop_box
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if x0 == 0 and y0 == 0 and x1 == orig_w and y1 == orig_h:
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return masks
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# Coordinate transform masks
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pad_x, pad_y = orig_w - (x1 - x0), orig_h - (y1 - y0)
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pad = (x0, pad_x - x0, y0, pad_y - y0)
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return torch.nn.functional.pad(masks, pad, value=0)
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def remove_small_regions(mask: np.ndarray, area_thresh: float, mode: str) -> Tuple[np.ndarray, bool]:
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"""Remove small disconnected regions or holes in a mask, returning the mask and a modification indicator."""
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import cv2 # type: ignore
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assert mode in {'holes', 'islands'}
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correct_holes = mode == 'holes'
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working_mask = (correct_holes ^ mask).astype(np.uint8)
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n_labels, regions, stats, _ = cv2.connectedComponentsWithStats(working_mask, 8)
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sizes = stats[:, -1][1:] # Row 0 is background label
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small_regions = [i + 1 for i, s in enumerate(sizes) if s < area_thresh]
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if not small_regions:
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return mask, False
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fill_labels = [0] + small_regions
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if not correct_holes:
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# If every region is below threshold, keep largest
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fill_labels = [i for i in range(n_labels) if i not in fill_labels] or [int(np.argmax(sizes)) + 1]
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mask = np.isin(regions, fill_labels)
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return mask, True
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def coco_encode_rle(uncompressed_rle: Dict[str, Any]) -> Dict[str, Any]:
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"""Encode uncompressed RLE (run-length encoding) to COCO RLE format."""
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from pycocotools import mask as mask_utils # type: ignore
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h, w = uncompressed_rle['size']
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rle = mask_utils.frPyObjects(uncompressed_rle, h, w)
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rle['counts'] = rle['counts'].decode('utf-8') # Necessary to serialize with json
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return rle
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def batched_mask_to_box(masks: torch.Tensor) -> torch.Tensor:
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"""
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Calculates boxes in XYXY format around masks. Return [0,0,0,0] for
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an empty mask. For input shape C1xC2x...xHxW, the output shape is C1xC2x...x4.
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"""
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# torch.max below raises an error on empty inputs, just skip in this case
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if torch.numel(masks) == 0:
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return torch.zeros(*masks.shape[:-2], 4, device=masks.device)
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# Normalize shape to CxHxW
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shape = masks.shape
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h, w = shape[-2:]
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masks = masks.flatten(0, -3) if len(shape) > 2 else masks.unsqueeze(0)
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# Get top and bottom edges
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in_height, _ = torch.max(masks, dim=-1)
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in_height_coords = in_height * torch.arange(h, device=in_height.device)[None, :]
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bottom_edges, _ = torch.max(in_height_coords, dim=-1)
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in_height_coords = in_height_coords + h * (~in_height)
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top_edges, _ = torch.min(in_height_coords, dim=-1)
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# Get left and right edges
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in_width, _ = torch.max(masks, dim=-2)
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in_width_coords = in_width * torch.arange(w, device=in_width.device)[None, :]
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right_edges, _ = torch.max(in_width_coords, dim=-1)
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in_width_coords = in_width_coords + w * (~in_width)
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left_edges, _ = torch.min(in_width_coords, dim=-1)
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# If the mask is empty the right edge will be to the left of the left edge.
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# Replace these boxes with [0, 0, 0, 0]
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empty_filter = (right_edges < left_edges) | (bottom_edges < top_edges)
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out = torch.stack([left_edges, top_edges, right_edges, bottom_edges], dim=-1)
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out = out * (~empty_filter).unsqueeze(-1)
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# Return to original shape
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return out.reshape(*shape[:-2], 4) if len(shape) > 2 else out[0]
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