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Version:
2.2.0rc0 ▾
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# Copyright (c) OpenMMLab. All rights reserved.
from typing import Any, Optional, Tuple, Union
import torch
import torch.nn as nn
from mmengine.utils import deprecated_api_warning
from torch.autograd import Function
from torch.nn.modules.utils import _pair
from ..utils import ext_loader
ext_module = ext_loader.load_ext(
'_ext', ['roi_align_rotated_forward', 'roi_align_rotated_backward'])
class RoIAlignRotatedFunction(Function):
@staticmethod
def symbolic(g, input, rois, output_size, spatial_scale, sampling_ratio,
aligned, clockwise):
if isinstance(output_size, int):
out_h = output_size
out_w = output_size
elif isinstance(output_size, tuple):
assert len(output_size) == 2
assert isinstance(output_size[0], int)
assert isinstance(output_size[1], int)
out_h, out_w = output_size
else:
raise TypeError(
'"output_size" must be an integer or tuple of integers')
return g.op(
'mmcv::MMCVRoIAlignRotated',
input,
rois,
output_height_i=out_h,
output_width_i=out_h,
spatial_scale_f=spatial_scale,
sampling_ratio_i=sampling_ratio,
aligned_i=aligned,
clockwise_i=clockwise)
@staticmethod
def forward(ctx: Any,
input: torch.Tensor,
rois: torch.Tensor,
output_size: Union[int, tuple],
spatial_scale: float,
sampling_ratio: int = 0,
aligned: bool = True,
clockwise: bool = False) -> torch.Tensor:
ctx.output_size = _pair(output_size)
ctx.spatial_scale = spatial_scale
ctx.sampling_ratio = sampling_ratio
ctx.aligned = aligned
ctx.clockwise = clockwise
ctx.save_for_backward(rois)
ctx.feature_size = input.size()
batch_size, num_channels, data_height, data_width = input.size()
num_rois = rois.size(0)
output = input.new_zeros(num_rois, num_channels, ctx.output_size[0],
ctx.output_size[1])
ext_module.roi_align_rotated_forward(
input,
rois,
output,
pooled_height=ctx.output_size[0],
pooled_width=ctx.output_size[1],
spatial_scale=ctx.spatial_scale,
sampling_ratio=ctx.sampling_ratio,
aligned=ctx.aligned,
clockwise=ctx.clockwise)
return output
@staticmethod
def backward(
ctx: Any, grad_output: torch.Tensor
) -> Tuple[Optional[torch.Tensor], Optional[torch.Tensor], None, None,
None, None, None]:
feature_size = ctx.feature_size
rois = ctx.saved_tensors[0]
assert feature_size is not None
batch_size, num_channels, data_height, data_width = feature_size
out_w = grad_output.size(3)
out_h = grad_output.size(2)
grad_input = grad_rois = None
if ctx.needs_input_grad[0]:
grad_input = rois.new_zeros(batch_size, num_channels, data_height,
data_width)
ext_module.roi_align_rotated_backward(
grad_output.contiguous(),
rois,
grad_input,
pooled_height=out_h,
pooled_width=out_w,
spatial_scale=ctx.spatial_scale,
sampling_ratio=ctx.sampling_ratio,
aligned=ctx.aligned,
clockwise=ctx.clockwise)
return grad_input, grad_rois, None, None, None, None, None
roi_align_rotated = RoIAlignRotatedFunction.apply
class RoIAlignRotated(nn.Module):
"""RoI align pooling layer for rotated proposals.
It accepts a feature map of shape (N, C, H, W) and rois with shape
(n, 6) with each roi decoded as (batch_index, center_x, center_y,
w, h, angle). The angle is in radian.
Args:
output_size (tuple): h, w
spatial_scale (float): scale the input boxes by this number
sampling_ratio(int): number of inputs samples to take for each
output sample. 0 to take samples densely for current models.
aligned (bool): if False, use the legacy implementation in
MMDetection. If True, align the results more perfectly.
Default: True.
clockwise (bool): If True, the angle in each proposal follows a
clockwise fashion in image space, otherwise, the angle is
counterclockwise. Default: False.
Note:
The implementation of RoIAlign when aligned=True is modified from
https://github.com/facebookresearch/detectron2/
The meaning of aligned=True:
Given a continuous coordinate c, its two neighboring pixel
indices (in our pixel model) are computed by floor(c - 0.5) and
ceil(c - 0.5). For example, c=1.3 has pixel neighbors with discrete
indices [0] and [1] (which are sampled from the underlying signal
at continuous coordinates 0.5 and 1.5). But the original roi_align
(aligned=False) does not subtract the 0.5 when computing
neighboring pixel indices and therefore it uses pixels with a
slightly incorrect alignment (relative to our pixel model) when
performing bilinear interpolation.
With `aligned=True`,
we first appropriately scale the ROI and then shift it by -0.5
prior to calling roi_align. This produces the correct neighbors;
The difference does not make a difference to the model's
performance if ROIAlign is used together with conv layers.
"""
@deprecated_api_warning(
{
'out_size': 'output_size',
'sample_num': 'sampling_ratio'
},
cls_name='RoIAlignRotated')
def __init__(self,
output_size: Union[int, tuple],
spatial_scale: float,
sampling_ratio: int = 0,
aligned: bool = True,
clockwise: bool = False):
super().__init__()
self.output_size = _pair(output_size)
self.spatial_scale = float(spatial_scale)
self.sampling_ratio = int(sampling_ratio)
self.aligned = aligned
self.clockwise = clockwise
def forward(self, input: torch.Tensor, rois: torch.Tensor) -> torch.Tensor:
return RoIAlignRotatedFunction.apply(input, rois, self.output_size,
self.spatial_scale,
self.sampling_ratio, self.aligned,
self.clockwise)
def __repr__(self):
s = self.__class__.__name__
s += f'(output_size={self.output_size}, '
s += f'spatial_scale={self.spatial_scale}, '
s += f'sampling_ratio={self.sampling_ratio}, '
s += f'aligned={self.aligned}, '
s += f'clockwise={self.clockwise})'
return s