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import math |
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from typing import List, Tuple |
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import torch |
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from annotator.oneformer.detectron2.layers.rotated_boxes import pairwise_iou_rotated |
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from .boxes import Boxes |
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class RotatedBoxes(Boxes): |
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""" |
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This structure stores a list of rotated boxes as a Nx5 torch.Tensor. |
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It supports some common methods about boxes |
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(`area`, `clip`, `nonempty`, etc), |
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and also behaves like a Tensor |
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(support indexing, `to(device)`, `.device`, and iteration over all boxes) |
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""" |
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def __init__(self, tensor: torch.Tensor): |
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""" |
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Args: |
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tensor (Tensor[float]): a Nx5 matrix. Each row is |
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(x_center, y_center, width, height, angle), |
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in which angle is represented in degrees. |
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While there's no strict range restriction for it, |
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the recommended principal range is between [-180, 180) degrees. |
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Assume we have a horizontal box B = (x_center, y_center, width, height), |
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where width is along the x-axis and height is along the y-axis. |
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The rotated box B_rot (x_center, y_center, width, height, angle) |
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can be seen as: |
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1. When angle == 0: |
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B_rot == B |
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2. When angle > 0: |
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B_rot is obtained by rotating B w.r.t its center by :math:`|angle|` degrees CCW; |
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3. When angle < 0: |
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B_rot is obtained by rotating B w.r.t its center by :math:`|angle|` degrees CW. |
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Mathematically, since the right-handed coordinate system for image space |
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is (y, x), where y is top->down and x is left->right, the 4 vertices of the |
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rotated rectangle :math:`(yr_i, xr_i)` (i = 1, 2, 3, 4) can be obtained from |
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the vertices of the horizontal rectangle :math:`(y_i, x_i)` (i = 1, 2, 3, 4) |
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in the following way (:math:`\\theta = angle*\\pi/180` is the angle in radians, |
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:math:`(y_c, x_c)` is the center of the rectangle): |
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.. math:: |
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yr_i = \\cos(\\theta) (y_i - y_c) - \\sin(\\theta) (x_i - x_c) + y_c, |
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xr_i = \\sin(\\theta) (y_i - y_c) + \\cos(\\theta) (x_i - x_c) + x_c, |
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which is the standard rigid-body rotation transformation. |
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Intuitively, the angle is |
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(1) the rotation angle from y-axis in image space |
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to the height vector (top->down in the box's local coordinate system) |
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of the box in CCW, and |
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(2) the rotation angle from x-axis in image space |
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to the width vector (left->right in the box's local coordinate system) |
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of the box in CCW. |
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More intuitively, consider the following horizontal box ABCD represented |
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in (x1, y1, x2, y2): (3, 2, 7, 4), |
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covering the [3, 7] x [2, 4] region of the continuous coordinate system |
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which looks like this: |
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.. code:: none |
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O--------> x |
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| |
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| A---B |
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| | | |
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| D---C |
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| |
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v y |
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Note that each capital letter represents one 0-dimensional geometric point |
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instead of a 'square pixel' here. |
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In the example above, using (x, y) to represent a point we have: |
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.. math:: |
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O = (0, 0), A = (3, 2), B = (7, 2), C = (7, 4), D = (3, 4) |
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We name vector AB = vector DC as the width vector in box's local coordinate system, and |
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vector AD = vector BC as the height vector in box's local coordinate system. Initially, |
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when angle = 0 degree, they're aligned with the positive directions of x-axis and y-axis |
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in the image space, respectively. |
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For better illustration, we denote the center of the box as E, |
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.. code:: none |
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O--------> x |
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| |
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| A---B |
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| | E | |
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| D---C |
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| |
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v y |
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where the center E = ((3+7)/2, (2+4)/2) = (5, 3). |
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Also, |
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.. math:: |
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width = |AB| = |CD| = 7 - 3 = 4, |
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height = |AD| = |BC| = 4 - 2 = 2. |
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Therefore, the corresponding representation for the same shape in rotated box in |
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(x_center, y_center, width, height, angle) format is: |
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(5, 3, 4, 2, 0), |
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Now, let's consider (5, 3, 4, 2, 90), which is rotated by 90 degrees |
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CCW (counter-clockwise) by definition. It looks like this: |
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.. code:: none |
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O--------> x |
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| B-C |
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| | | |
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| |E| |
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| | | |
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| A-D |
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v y |
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The center E is still located at the same point (5, 3), while the vertices |
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ABCD are rotated by 90 degrees CCW with regard to E: |
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A = (4, 5), B = (4, 1), C = (6, 1), D = (6, 5) |
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Here, 90 degrees can be seen as the CCW angle to rotate from y-axis to |
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vector AD or vector BC (the top->down height vector in box's local coordinate system), |
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or the CCW angle to rotate from x-axis to vector AB or vector DC (the left->right |
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width vector in box's local coordinate system). |
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.. math:: |
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width = |AB| = |CD| = 5 - 1 = 4, |
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height = |AD| = |BC| = 6 - 4 = 2. |
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Next, how about (5, 3, 4, 2, -90), which is rotated by 90 degrees CW (clockwise) |
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by definition? It looks like this: |
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.. code:: none |
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O--------> x |
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| D-A |
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| | | |
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| |E| |
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| | | |
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| C-B |
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v y |
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The center E is still located at the same point (5, 3), while the vertices |
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ABCD are rotated by 90 degrees CW with regard to E: |
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A = (6, 1), B = (6, 5), C = (4, 5), D = (4, 1) |
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.. math:: |
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width = |AB| = |CD| = 5 - 1 = 4, |
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height = |AD| = |BC| = 6 - 4 = 2. |
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This covers exactly the same region as (5, 3, 4, 2, 90) does, and their IoU |
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will be 1. However, these two will generate different RoI Pooling results and |
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should not be treated as an identical box. |
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On the other hand, it's easy to see that (X, Y, W, H, A) is identical to |
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(X, Y, W, H, A+360N), for any integer N. For example (5, 3, 4, 2, 270) would be |
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identical to (5, 3, 4, 2, -90), because rotating the shape 270 degrees CCW is |
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equivalent to rotating the same shape 90 degrees CW. |
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We could rotate further to get (5, 3, 4, 2, 180), or (5, 3, 4, 2, -180): |
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.. code:: none |
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O--------> x |
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| |
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| C---D |
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| | E | |
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| B---A |
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| |
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v y |
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.. math:: |
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A = (7, 4), B = (3, 4), C = (3, 2), D = (7, 2), |
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width = |AB| = |CD| = 7 - 3 = 4, |
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height = |AD| = |BC| = 4 - 2 = 2. |
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Finally, this is a very inaccurate (heavily quantized) illustration of |
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how (5, 3, 4, 2, 60) looks like in case anyone wonders: |
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.. code:: none |
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O--------> x |
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| B\ |
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| / C |
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| /E / |
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| A / |
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| `D |
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v y |
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It's still a rectangle with center of (5, 3), width of 4 and height of 2, |
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but its angle (and thus orientation) is somewhere between |
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(5, 3, 4, 2, 0) and (5, 3, 4, 2, 90). |
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""" |
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device = tensor.device if isinstance(tensor, torch.Tensor) else torch.device("cpu") |
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tensor = torch.as_tensor(tensor, dtype=torch.float32, device=device) |
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if tensor.numel() == 0: |
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tensor = tensor.reshape((0, 5)).to(dtype=torch.float32, device=device) |
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assert tensor.dim() == 2 and tensor.size(-1) == 5, tensor.size() |
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self.tensor = tensor |
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def clone(self) -> "RotatedBoxes": |
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""" |
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Clone the RotatedBoxes. |
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Returns: |
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RotatedBoxes |
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""" |
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return RotatedBoxes(self.tensor.clone()) |
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def to(self, device: torch.device): |
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return RotatedBoxes(self.tensor.to(device=device)) |
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def area(self) -> torch.Tensor: |
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""" |
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Computes the area of all the boxes. |
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Returns: |
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torch.Tensor: a vector with areas of each box. |
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""" |
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box = self.tensor |
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area = box[:, 2] * box[:, 3] |
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return area |
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def normalize_angles(self) -> None: |
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""" |
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Restrict angles to the range of [-180, 180) degrees |
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""" |
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angle_tensor = (self.tensor[:, 4] + 180.0) % 360.0 - 180.0 |
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self.tensor = torch.cat((self.tensor[:, :4], angle_tensor[:, None]), dim=1) |
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def clip(self, box_size: Tuple[int, int], clip_angle_threshold: float = 1.0) -> None: |
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""" |
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Clip (in place) the boxes by limiting x coordinates to the range [0, width] |
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and y coordinates to the range [0, height]. |
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For RRPN: |
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Only clip boxes that are almost horizontal with a tolerance of |
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clip_angle_threshold to maintain backward compatibility. |
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Rotated boxes beyond this threshold are not clipped for two reasons: |
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1. There are potentially multiple ways to clip a rotated box to make it |
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fit within the image. |
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2. It's tricky to make the entire rectangular box fit within the image |
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and still be able to not leave out pixels of interest. |
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Therefore we rely on ops like RoIAlignRotated to safely handle this. |
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Args: |
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box_size (height, width): The clipping box's size. |
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clip_angle_threshold: |
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Iff. abs(normalized(angle)) <= clip_angle_threshold (in degrees), |
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we do the clipping as horizontal boxes. |
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""" |
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h, w = box_size |
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self.normalize_angles() |
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idx = torch.where(torch.abs(self.tensor[:, 4]) <= clip_angle_threshold)[0] |
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x1 = self.tensor[idx, 0] - self.tensor[idx, 2] / 2.0 |
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y1 = self.tensor[idx, 1] - self.tensor[idx, 3] / 2.0 |
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x2 = self.tensor[idx, 0] + self.tensor[idx, 2] / 2.0 |
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y2 = self.tensor[idx, 1] + self.tensor[idx, 3] / 2.0 |
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x1.clamp_(min=0, max=w) |
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y1.clamp_(min=0, max=h) |
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x2.clamp_(min=0, max=w) |
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y2.clamp_(min=0, max=h) |
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self.tensor[idx, 0] = (x1 + x2) / 2.0 |
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self.tensor[idx, 1] = (y1 + y2) / 2.0 |
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self.tensor[idx, 2] = torch.min(self.tensor[idx, 2], x2 - x1) |
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self.tensor[idx, 3] = torch.min(self.tensor[idx, 3], y2 - y1) |
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def nonempty(self, threshold: float = 0.0) -> torch.Tensor: |
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""" |
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Find boxes that are non-empty. |
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A box is considered empty, if either of its side is no larger than threshold. |
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Returns: |
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Tensor: a binary vector which represents |
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whether each box is empty (False) or non-empty (True). |
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""" |
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box = self.tensor |
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widths = box[:, 2] |
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heights = box[:, 3] |
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keep = (widths > threshold) & (heights > threshold) |
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return keep |
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def __getitem__(self, item) -> "RotatedBoxes": |
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""" |
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Returns: |
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RotatedBoxes: Create a new :class:`RotatedBoxes` by indexing. |
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The following usage are allowed: |
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1. `new_boxes = boxes[3]`: return a `RotatedBoxes` which contains only one box. |
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2. `new_boxes = boxes[2:10]`: return a slice of boxes. |
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3. `new_boxes = boxes[vector]`, where vector is a torch.ByteTensor |
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with `length = len(boxes)`. Nonzero elements in the vector will be selected. |
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Note that the returned RotatedBoxes might share storage with this RotatedBoxes, |
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subject to Pytorch's indexing semantics. |
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""" |
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if isinstance(item, int): |
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return RotatedBoxes(self.tensor[item].view(1, -1)) |
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b = self.tensor[item] |
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assert b.dim() == 2, "Indexing on RotatedBoxes with {} failed to return a matrix!".format( |
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item |
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) |
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return RotatedBoxes(b) |
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def __len__(self) -> int: |
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return self.tensor.shape[0] |
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def __repr__(self) -> str: |
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return "RotatedBoxes(" + str(self.tensor) + ")" |
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def inside_box(self, box_size: Tuple[int, int], boundary_threshold: int = 0) -> torch.Tensor: |
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""" |
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Args: |
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box_size (height, width): Size of the reference box covering |
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[0, width] x [0, height] |
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boundary_threshold (int): Boxes that extend beyond the reference box |
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boundary by more than boundary_threshold are considered "outside". |
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For RRPN, it might not be necessary to call this function since it's common |
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for rotated box to extend to outside of the image boundaries |
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(the clip function only clips the near-horizontal boxes) |
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Returns: |
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a binary vector, indicating whether each box is inside the reference box. |
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""" |
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height, width = box_size |
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cnt_x = self.tensor[..., 0] |
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cnt_y = self.tensor[..., 1] |
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half_w = self.tensor[..., 2] / 2.0 |
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half_h = self.tensor[..., 3] / 2.0 |
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a = self.tensor[..., 4] |
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c = torch.abs(torch.cos(a * math.pi / 180.0)) |
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s = torch.abs(torch.sin(a * math.pi / 180.0)) |
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max_rect_dx = c * half_w + s * half_h |
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max_rect_dy = c * half_h + s * half_w |
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inds_inside = ( |
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(cnt_x - max_rect_dx >= -boundary_threshold) |
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& (cnt_y - max_rect_dy >= -boundary_threshold) |
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& (cnt_x + max_rect_dx < width + boundary_threshold) |
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& (cnt_y + max_rect_dy < height + boundary_threshold) |
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) |
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return inds_inside |
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def get_centers(self) -> torch.Tensor: |
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""" |
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Returns: |
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The box centers in a Nx2 array of (x, y). |
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""" |
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return self.tensor[:, :2] |
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def scale(self, scale_x: float, scale_y: float) -> None: |
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""" |
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Scale the rotated box with horizontal and vertical scaling factors |
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Note: when scale_factor_x != scale_factor_y, |
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the rotated box does not preserve the rectangular shape when the angle |
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is not a multiple of 90 degrees under resize transformation. |
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Instead, the shape is a parallelogram (that has skew) |
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Here we make an approximation by fitting a rotated rectangle to the parallelogram. |
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""" |
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self.tensor[:, 0] *= scale_x |
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self.tensor[:, 1] *= scale_y |
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theta = self.tensor[:, 4] * math.pi / 180.0 |
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c = torch.cos(theta) |
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s = torch.sin(theta) |
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self.tensor[:, 2] *= torch.sqrt((scale_x * c) ** 2 + (scale_y * s) ** 2) |
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self.tensor[:, 3] *= torch.sqrt((scale_x * s) ** 2 + (scale_y * c) ** 2) |
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self.tensor[:, 4] = torch.atan2(scale_x * s, scale_y * c) * 180 / math.pi |
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@classmethod |
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def cat(cls, boxes_list: List["RotatedBoxes"]) -> "RotatedBoxes": |
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""" |
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Concatenates a list of RotatedBoxes into a single RotatedBoxes |
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Arguments: |
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boxes_list (list[RotatedBoxes]) |
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Returns: |
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RotatedBoxes: the concatenated RotatedBoxes |
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""" |
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assert isinstance(boxes_list, (list, tuple)) |
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if len(boxes_list) == 0: |
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return cls(torch.empty(0)) |
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assert all([isinstance(box, RotatedBoxes) for box in boxes_list]) |
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cat_boxes = cls(torch.cat([b.tensor for b in boxes_list], dim=0)) |
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return cat_boxes |
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@property |
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def device(self) -> torch.device: |
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return self.tensor.device |
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@torch.jit.unused |
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def __iter__(self): |
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""" |
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Yield a box as a Tensor of shape (5,) at a time. |
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""" |
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yield from self.tensor |
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def pairwise_iou(boxes1: RotatedBoxes, boxes2: RotatedBoxes) -> None: |
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""" |
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Given two lists of rotated boxes of size N and M, |
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compute the IoU (intersection over union) |
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between **all** N x M pairs of boxes. |
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The box order must be (x_center, y_center, width, height, angle). |
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Args: |
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boxes1, boxes2 (RotatedBoxes): |
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two `RotatedBoxes`. Contains N & M rotated boxes, respectively. |
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Returns: |
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Tensor: IoU, sized [N,M]. |
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""" |
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return pairwise_iou_rotated(boxes1.tensor, boxes2.tensor) |
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