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import numpy as np |
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import torch |
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from torchvision.ops.boxes import batched_nms, box_area |
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from typing import Any, Dict, List, Optional, Tuple |
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from .modeling import Sam |
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from .predictor import SamPredictor |
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from .utils.amg import ( |
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MaskData, |
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area_from_rle, |
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batch_iterator, |
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batched_mask_to_box, |
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box_xyxy_to_xywh, |
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build_all_layer_point_grids, |
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calculate_stability_score, |
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coco_encode_rle, |
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generate_crop_boxes, |
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is_box_near_crop_edge, |
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mask_to_rle_pytorch, |
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remove_small_regions, |
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rle_to_mask, |
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uncrop_boxes_xyxy, |
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uncrop_masks, |
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uncrop_points, |
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) |
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class SamAutomaticMaskGenerator: |
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def __init__( |
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self, |
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model: Sam, |
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points_per_side: Optional[int] = 32, |
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points_per_batch: int = 64, |
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pred_iou_thresh: float = 0.88, |
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stability_score_thresh: float = 0.95, |
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stability_score_offset: float = 1.0, |
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box_nms_thresh: float = 0.7, |
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crop_n_layers: int = 0, |
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crop_nms_thresh: float = 0.7, |
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crop_overlap_ratio: float = 512 / 1500, |
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crop_n_points_downscale_factor: int = 1, |
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point_grids: Optional[List[np.ndarray]] = None, |
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min_mask_region_area: int = 0, |
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output_mode: str = "binary_mask", |
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) -> None: |
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""" |
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Using a SAM model, generates masks for the entire image. |
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Generates a grid of point prompts over the image, then filters |
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low quality and duplicate masks. The default settings are chosen |
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for SAM with a ViT-H backbone. |
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Arguments: |
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model (Sam): The SAM model to use for mask prediction. |
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points_per_side (int or None): The number of points to be sampled |
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along one side of the image. The total number of points is |
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points_per_side**2. If None, 'point_grids' must provide explicit |
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point sampling. |
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points_per_batch (int): Sets the number of points run simultaneously |
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by the model. Higher numbers may be faster but use more GPU memory. |
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pred_iou_thresh (float): A filtering threshold in [0,1], using the |
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model's predicted mask quality. |
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stability_score_thresh (float): A filtering threshold in [0,1], using |
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the stability of the mask under changes to the cutoff used to binarize |
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the model's mask predictions. |
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stability_score_offset (float): The amount to shift the cutoff when |
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calculated the stability score. |
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box_nms_thresh (float): The box IoU cutoff used by non-maximal |
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suppression to filter duplicate masks. |
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crop_n_layers (int): If >0, mask prediction will be run again on |
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crops of the image. Sets the number of layers to run, where each |
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layer has 2**i_layer number of image crops. |
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crop_nms_thresh (float): The box IoU cutoff used by non-maximal |
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suppression to filter duplicate masks between different crops. |
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crop_overlap_ratio (float): Sets the degree to which crops overlap. |
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In the first crop layer, crops will overlap by this fraction of |
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the image length. Later layers with more crops scale down this overlap. |
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crop_n_points_downscale_factor (int): The number of points-per-side |
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sampled in layer n is scaled down by crop_n_points_downscale_factor**n. |
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point_grids (list(np.ndarray) or None): A list over explicit grids |
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of points used for sampling, normalized to [0,1]. The nth grid in the |
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list is used in the nth crop layer. Exclusive with points_per_side. |
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min_mask_region_area (int): If >0, postprocessing will be applied |
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to remove disconnected regions and holes in masks with area smaller |
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than min_mask_region_area. Requires opencv. |
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output_mode (str): The form masks are returned in. Can be 'binary_mask', |
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'uncompressed_rle', or 'coco_rle'. 'coco_rle' requires pycocotools. |
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For large resolutions, 'binary_mask' may consume large amounts of |
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memory. |
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""" |
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assert (points_per_side is None) != ( |
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point_grids is None |
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), "Exactly one of points_per_side or point_grid must be provided." |
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if points_per_side is not None: |
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self.point_grids = build_all_layer_point_grids( |
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points_per_side, |
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crop_n_layers, |
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crop_n_points_downscale_factor, |
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) |
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elif point_grids is not None: |
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self.point_grids = point_grids |
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else: |
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raise ValueError("Can't have both points_per_side and point_grid be None.") |
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assert output_mode in [ |
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"binary_mask", |
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"uncompressed_rle", |
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"coco_rle", |
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], f"Unknown output_mode {output_mode}." |
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if output_mode == "coco_rle": |
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from pycocotools import mask as mask_utils |
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if min_mask_region_area > 0: |
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import cv2 |
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self.predictor = SamPredictor(model) |
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self.points_per_batch = points_per_batch |
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self.pred_iou_thresh = pred_iou_thresh |
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self.stability_score_thresh = stability_score_thresh |
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self.stability_score_offset = stability_score_offset |
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self.box_nms_thresh = box_nms_thresh |
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self.crop_n_layers = crop_n_layers |
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self.crop_nms_thresh = crop_nms_thresh |
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self.crop_overlap_ratio = crop_overlap_ratio |
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self.crop_n_points_downscale_factor = crop_n_points_downscale_factor |
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self.min_mask_region_area = min_mask_region_area |
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self.output_mode = output_mode |
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@torch.no_grad() |
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def generate(self, image: np.ndarray, multimask_output: bool = True) -> List[Dict[str, Any]]: |
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""" |
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Generates masks for the given image. |
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Arguments: |
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image (np.ndarray): The image to generate masks for, in HWC uint8 format. |
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Returns: |
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list(dict(str, any)): A list over records for masks. Each record is |
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a dict containing the following keys: |
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segmentation (dict(str, any) or np.ndarray): The mask. If |
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output_mode='binary_mask', is an array of shape HW. Otherwise, |
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is a dictionary containing the RLE. |
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bbox (list(float)): The box around the mask, in XYWH format. |
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area (int): The area in pixels of the mask. |
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predicted_iou (float): The model's own prediction of the mask's |
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quality. This is filtered by the pred_iou_thresh parameter. |
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point_coords (list(list(float))): The point coordinates input |
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to the model to generate this mask. |
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stability_score (float): A measure of the mask's quality. This |
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is filtered on using the stability_score_thresh parameter. |
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crop_box (list(float)): The crop of the image used to generate |
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the mask, given in XYWH format. |
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""" |
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mask_data = self._generate_masks(image, multimask_output) |
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if self.min_mask_region_area > 0: |
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mask_data = self.postprocess_small_regions( |
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mask_data, |
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self.min_mask_region_area, |
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max(self.box_nms_thresh, self.crop_nms_thresh), |
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) |
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if self.output_mode == "coco_rle": |
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mask_data["segmentations"] = [coco_encode_rle(rle) for rle in mask_data["rles"]] |
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elif self.output_mode == "binary_mask": |
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mask_data["segmentations"] = [rle_to_mask(rle) for rle in mask_data["rles"]] |
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else: |
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mask_data["segmentations"] = mask_data["rles"] |
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curr_anns = [] |
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for idx in range(len(mask_data["segmentations"])): |
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ann = { |
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"segmentation": mask_data["segmentations"][idx], |
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"area": area_from_rle(mask_data["rles"][idx]), |
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"bbox": box_xyxy_to_xywh(mask_data["boxes"][idx]).tolist(), |
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"predicted_iou": mask_data["iou_preds"][idx].item(), |
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"point_coords": [mask_data["points"][idx].tolist()], |
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"stability_score": mask_data["stability_score"][idx].item(), |
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"crop_box": box_xyxy_to_xywh(mask_data["crop_boxes"][idx]).tolist(), |
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} |
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curr_anns.append(ann) |
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return curr_anns |
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def _generate_masks(self, image: np.ndarray, multimask_output: bool = True) -> MaskData: |
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orig_size = image.shape[:2] |
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crop_boxes, layer_idxs = generate_crop_boxes( |
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orig_size, self.crop_n_layers, self.crop_overlap_ratio |
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) |
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data = MaskData() |
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for crop_box, layer_idx in zip(crop_boxes, layer_idxs): |
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crop_data = self._process_crop(image, crop_box, layer_idx, orig_size, multimask_output) |
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data.cat(crop_data) |
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if len(crop_boxes) > 1: |
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scores = 1 / box_area(data["crop_boxes"]) |
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scores = scores.to(data["boxes"].device) |
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keep_by_nms = batched_nms( |
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data["boxes"].float(), |
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scores, |
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torch.zeros_like(data["boxes"][:, 0]), |
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iou_threshold=self.crop_nms_thresh, |
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) |
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data.filter(keep_by_nms) |
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data.to_numpy() |
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return data |
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def _process_crop( |
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self, |
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image: np.ndarray, |
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crop_box: List[int], |
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crop_layer_idx: int, |
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orig_size: Tuple[int, ...], |
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multimask_output: bool = True, |
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) -> MaskData: |
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x0, y0, x1, y1 = crop_box |
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cropped_im = image[y0:y1, x0:x1, :] |
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cropped_im_size = cropped_im.shape[:2] |
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self.predictor.set_image(cropped_im) |
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points_scale = np.array(cropped_im_size)[None, ::-1] |
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points_for_image = self.point_grids[crop_layer_idx] * points_scale |
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data = MaskData() |
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for (points,) in batch_iterator(self.points_per_batch, points_for_image): |
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batch_data = self._process_batch(points, cropped_im_size, crop_box, orig_size, multimask_output) |
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data.cat(batch_data) |
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del batch_data |
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self.predictor.reset_image() |
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keep_by_nms = batched_nms( |
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data["boxes"].float(), |
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data["iou_preds"], |
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torch.zeros_like(data["boxes"][:, 0]), |
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iou_threshold=self.box_nms_thresh, |
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) |
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data.filter(keep_by_nms) |
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data["boxes"] = uncrop_boxes_xyxy(data["boxes"], crop_box) |
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data["points"] = uncrop_points(data["points"], crop_box) |
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data["crop_boxes"] = torch.tensor([crop_box for _ in range(len(data["rles"]))]) |
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return data |
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def _process_batch( |
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self, |
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points: np.ndarray, |
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im_size: Tuple[int, ...], |
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crop_box: List[int], |
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orig_size: Tuple[int, ...], |
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multimask_output: bool = True, |
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) -> MaskData: |
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orig_h, orig_w = orig_size |
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transformed_points = self.predictor.transform.apply_coords(points, im_size) |
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in_points = torch.as_tensor(transformed_points, device=self.predictor.device) |
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in_labels = torch.ones(in_points.shape[0], dtype=torch.int, device=in_points.device) |
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masks, iou_preds, _ = self.predictor.predict_torch( |
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in_points[:, None, :], |
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in_labels[:, None], |
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multimask_output=multimask_output, |
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return_logits=True, |
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) |
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data = MaskData( |
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masks=masks.flatten(0, 1), |
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iou_preds=iou_preds.flatten(0, 1), |
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points=torch.as_tensor(points.repeat(masks.shape[1], axis=0)), |
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) |
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del masks |
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if self.pred_iou_thresh > 0.0: |
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keep_mask = data["iou_preds"] > self.pred_iou_thresh |
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data.filter(keep_mask) |
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data["stability_score"] = calculate_stability_score( |
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data["masks"], self.predictor.model.mask_threshold, self.stability_score_offset |
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) |
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if self.stability_score_thresh > 0.0: |
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keep_mask = data["stability_score"] >= self.stability_score_thresh |
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data.filter(keep_mask) |
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data["masks"] = data["masks"] > self.predictor.model.mask_threshold |
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data["boxes"] = batched_mask_to_box(data["masks"]) |
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keep_mask = ~is_box_near_crop_edge(data["boxes"], crop_box, [0, 0, orig_w, orig_h]) |
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if not torch.all(keep_mask): |
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data.filter(keep_mask) |
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data["masks"] = uncrop_masks(data["masks"], crop_box, orig_h, orig_w) |
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data["rles"] = mask_to_rle_pytorch(data["masks"]) |
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del data["masks"] |
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return data |
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@staticmethod |
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def postprocess_small_regions( |
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mask_data: MaskData, min_area: int, nms_thresh: float |
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) -> MaskData: |
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""" |
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Removes small disconnected regions and holes in masks, then reruns |
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box NMS to remove any new duplicates. |
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Edits mask_data in place. |
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Requires open-cv as a dependency. |
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""" |
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if len(mask_data["rles"]) == 0: |
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return mask_data |
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new_masks = [] |
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scores = [] |
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for rle in mask_data["rles"]: |
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mask = rle_to_mask(rle) |
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mask, changed = remove_small_regions(mask, min_area, mode="holes") |
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unchanged = not changed |
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mask, changed = remove_small_regions(mask, min_area, mode="islands") |
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unchanged = unchanged and not changed |
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new_masks.append(torch.as_tensor(mask).unsqueeze(0)) |
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scores.append(float(unchanged)) |
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masks = torch.cat(new_masks, dim=0) |
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boxes = batched_mask_to_box(masks) |
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keep_by_nms = batched_nms( |
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boxes.float(), |
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torch.as_tensor(scores), |
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torch.zeros_like(boxes[:, 0]), |
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iou_threshold=nms_thresh, |
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) |
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for i_mask in keep_by_nms: |
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if scores[i_mask] == 0.0: |
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mask_torch = masks[i_mask].unsqueeze(0) |
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mask_data["rles"][i_mask] = mask_to_rle_pytorch(mask_torch)[0] |
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mask_data["boxes"][i_mask] = boxes[i_mask] |
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mask_data.filter(keep_by_nms) |
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return mask_data |
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