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import math |
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from typing import List, Optional |
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import torch |
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from torch import nn |
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from torchvision.ops import RoIPool |
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from annotator.oneformer.detectron2.layers import ROIAlign, ROIAlignRotated, cat, nonzero_tuple, shapes_to_tensor |
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from annotator.oneformer.detectron2.structures import Boxes |
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from annotator.oneformer.detectron2.utils.tracing import assert_fx_safe, is_fx_tracing |
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""" |
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To export ROIPooler to torchscript, in this file, variables that should be annotated with |
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`Union[List[Boxes], List[RotatedBoxes]]` are only annotated with `List[Boxes]`. |
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TODO: Correct these annotations when torchscript support `Union`. |
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https://github.com/pytorch/pytorch/issues/41412 |
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""" |
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__all__ = ["ROIPooler"] |
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def assign_boxes_to_levels( |
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box_lists: List[Boxes], |
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min_level: int, |
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max_level: int, |
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canonical_box_size: int, |
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canonical_level: int, |
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): |
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""" |
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Map each box in `box_lists` to a feature map level index and return the assignment |
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vector. |
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Args: |
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box_lists (list[Boxes] | list[RotatedBoxes]): A list of N Boxes or N RotatedBoxes, |
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where N is the number of images in the batch. |
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min_level (int): Smallest feature map level index. The input is considered index 0, |
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the output of stage 1 is index 1, and so. |
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max_level (int): Largest feature map level index. |
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canonical_box_size (int): A canonical box size in pixels (sqrt(box area)). |
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canonical_level (int): The feature map level index on which a canonically-sized box |
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should be placed. |
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Returns: |
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A tensor of length M, where M is the total number of boxes aggregated over all |
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N batch images. The memory layout corresponds to the concatenation of boxes |
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from all images. Each element is the feature map index, as an offset from |
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`self.min_level`, for the corresponding box (so value i means the box is at |
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`self.min_level + i`). |
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""" |
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box_sizes = torch.sqrt(cat([boxes.area() for boxes in box_lists])) |
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level_assignments = torch.floor( |
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canonical_level + torch.log2(box_sizes / canonical_box_size + 1e-8) |
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) |
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level_assignments = torch.clamp(level_assignments, min=min_level, max=max_level) |
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return level_assignments.to(torch.int64) - min_level |
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@torch.jit.script_if_tracing |
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def _convert_boxes_to_pooler_format(boxes: torch.Tensor, sizes: torch.Tensor) -> torch.Tensor: |
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sizes = sizes.to(device=boxes.device) |
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indices = torch.repeat_interleave( |
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torch.arange(len(sizes), dtype=boxes.dtype, device=boxes.device), sizes |
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) |
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return cat([indices[:, None], boxes], dim=1) |
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def convert_boxes_to_pooler_format(box_lists: List[Boxes]): |
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""" |
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Convert all boxes in `box_lists` to the low-level format used by ROI pooling ops |
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(see description under Returns). |
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Args: |
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box_lists (list[Boxes] | list[RotatedBoxes]): |
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A list of N Boxes or N RotatedBoxes, where N is the number of images in the batch. |
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Returns: |
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When input is list[Boxes]: |
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A tensor of shape (M, 5), where M is the total number of boxes aggregated over all |
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N batch images. |
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The 5 columns are (batch index, x0, y0, x1, y1), where batch index |
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is the index in [0, N) identifying which batch image the box with corners at |
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(x0, y0, x1, y1) comes from. |
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When input is list[RotatedBoxes]: |
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A tensor of shape (M, 6), where M is the total number of boxes aggregated over all |
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N batch images. |
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The 6 columns are (batch index, x_ctr, y_ctr, width, height, angle_degrees), |
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where batch index is the index in [0, N) identifying which batch image the |
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rotated box (x_ctr, y_ctr, width, height, angle_degrees) comes from. |
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""" |
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boxes = torch.cat([x.tensor for x in box_lists], dim=0) |
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sizes = shapes_to_tensor([x.__len__() for x in box_lists]) |
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return _convert_boxes_to_pooler_format(boxes, sizes) |
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@torch.jit.script_if_tracing |
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def _create_zeros( |
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batch_target: Optional[torch.Tensor], |
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channels: int, |
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height: int, |
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width: int, |
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like_tensor: torch.Tensor, |
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) -> torch.Tensor: |
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batches = batch_target.shape[0] if batch_target is not None else 0 |
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sizes = (batches, channels, height, width) |
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return torch.zeros(sizes, dtype=like_tensor.dtype, device=like_tensor.device) |
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class ROIPooler(nn.Module): |
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""" |
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Region of interest feature map pooler that supports pooling from one or more |
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feature maps. |
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""" |
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def __init__( |
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self, |
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output_size, |
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scales, |
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sampling_ratio, |
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pooler_type, |
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canonical_box_size=224, |
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canonical_level=4, |
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): |
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""" |
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Args: |
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output_size (int, tuple[int] or list[int]): output size of the pooled region, |
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e.g., 14 x 14. If tuple or list is given, the length must be 2. |
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scales (list[float]): The scale for each low-level pooling op relative to |
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the input image. For a feature map with stride s relative to the input |
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image, scale is defined as 1/s. The stride must be power of 2. |
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When there are multiple scales, they must form a pyramid, i.e. they must be |
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a monotically decreasing geometric sequence with a factor of 1/2. |
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sampling_ratio (int): The `sampling_ratio` parameter for the ROIAlign op. |
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pooler_type (string): Name of the type of pooling operation that should be applied. |
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For instance, "ROIPool" or "ROIAlignV2". |
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canonical_box_size (int): A canonical box size in pixels (sqrt(box area)). The default |
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is heuristically defined as 224 pixels in the FPN paper (based on ImageNet |
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pre-training). |
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canonical_level (int): The feature map level index from which a canonically-sized box |
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should be placed. The default is defined as level 4 (stride=16) in the FPN paper, |
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i.e., a box of size 224x224 will be placed on the feature with stride=16. |
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The box placement for all boxes will be determined from their sizes w.r.t |
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canonical_box_size. For example, a box whose area is 4x that of a canonical box |
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should be used to pool features from feature level ``canonical_level+1``. |
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Note that the actual input feature maps given to this module may not have |
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sufficiently many levels for the input boxes. If the boxes are too large or too |
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small for the input feature maps, the closest level will be used. |
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""" |
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super().__init__() |
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if isinstance(output_size, int): |
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output_size = (output_size, output_size) |
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assert len(output_size) == 2 |
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assert isinstance(output_size[0], int) and isinstance(output_size[1], int) |
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self.output_size = output_size |
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if pooler_type == "ROIAlign": |
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self.level_poolers = nn.ModuleList( |
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ROIAlign( |
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output_size, spatial_scale=scale, sampling_ratio=sampling_ratio, aligned=False |
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) |
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for scale in scales |
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) |
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elif pooler_type == "ROIAlignV2": |
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self.level_poolers = nn.ModuleList( |
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ROIAlign( |
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output_size, spatial_scale=scale, sampling_ratio=sampling_ratio, aligned=True |
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) |
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for scale in scales |
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) |
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elif pooler_type == "ROIPool": |
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self.level_poolers = nn.ModuleList( |
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RoIPool(output_size, spatial_scale=scale) for scale in scales |
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) |
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elif pooler_type == "ROIAlignRotated": |
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self.level_poolers = nn.ModuleList( |
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ROIAlignRotated(output_size, spatial_scale=scale, sampling_ratio=sampling_ratio) |
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for scale in scales |
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) |
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else: |
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raise ValueError("Unknown pooler type: {}".format(pooler_type)) |
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min_level = -(math.log2(scales[0])) |
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max_level = -(math.log2(scales[-1])) |
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assert math.isclose(min_level, int(min_level)) and math.isclose( |
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max_level, int(max_level) |
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), "Featuremap stride is not power of 2!" |
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self.min_level = int(min_level) |
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self.max_level = int(max_level) |
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assert ( |
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len(scales) == self.max_level - self.min_level + 1 |
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), "[ROIPooler] Sizes of input featuremaps do not form a pyramid!" |
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assert 0 <= self.min_level and self.min_level <= self.max_level |
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self.canonical_level = canonical_level |
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assert canonical_box_size > 0 |
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self.canonical_box_size = canonical_box_size |
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def forward(self, x: List[torch.Tensor], box_lists: List[Boxes]): |
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""" |
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Args: |
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x (list[Tensor]): A list of feature maps of NCHW shape, with scales matching those |
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used to construct this module. |
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box_lists (list[Boxes] | list[RotatedBoxes]): |
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A list of N Boxes or N RotatedBoxes, where N is the number of images in the batch. |
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The box coordinates are defined on the original image and |
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will be scaled by the `scales` argument of :class:`ROIPooler`. |
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Returns: |
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Tensor: |
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A tensor of shape (M, C, output_size, output_size) where M is the total number of |
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boxes aggregated over all N batch images and C is the number of channels in `x`. |
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""" |
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num_level_assignments = len(self.level_poolers) |
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if not is_fx_tracing(): |
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torch._assert( |
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isinstance(x, list) and isinstance(box_lists, list), |
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"Arguments to pooler must be lists", |
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) |
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assert_fx_safe( |
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len(x) == num_level_assignments, |
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"unequal value, num_level_assignments={}, but x is list of {} Tensors".format( |
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num_level_assignments, len(x) |
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), |
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) |
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assert_fx_safe( |
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len(box_lists) == x[0].size(0), |
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"unequal value, x[0] batch dim 0 is {}, but box_list has length {}".format( |
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x[0].size(0), len(box_lists) |
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), |
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) |
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if len(box_lists) == 0: |
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return _create_zeros(None, x[0].shape[1], *self.output_size, x[0]) |
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pooler_fmt_boxes = convert_boxes_to_pooler_format(box_lists) |
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if num_level_assignments == 1: |
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return self.level_poolers[0](x[0], pooler_fmt_boxes) |
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level_assignments = assign_boxes_to_levels( |
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box_lists, self.min_level, self.max_level, self.canonical_box_size, self.canonical_level |
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) |
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num_channels = x[0].shape[1] |
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output_size = self.output_size[0] |
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output = _create_zeros(pooler_fmt_boxes, num_channels, output_size, output_size, x[0]) |
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for level, pooler in enumerate(self.level_poolers): |
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inds = nonzero_tuple(level_assignments == level)[0] |
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pooler_fmt_boxes_level = pooler_fmt_boxes[inds] |
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output.index_put_((inds,), pooler(x[level], pooler_fmt_boxes_level)) |
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return output |
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