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import torch | |
from torch import nn | |
import torch.nn.functional as F | |
# coordinates system | |
# ------------------------------> [ x: range=-1.0~1.0; w: range=0~W ] | |
# | ----------------------------- | |
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# | | image | | |
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# v | |
# [ y: range=-1.0~1.0; h: range=0~H ] | |
def simple_nms(scores, nms_radius: int): | |
"""Fast Non-maximum suppression to remove nearby points""" | |
assert nms_radius >= 0 | |
def max_pool(x): | |
return torch.nn.functional.max_pool2d( | |
x, kernel_size=nms_radius * 2 + 1, stride=1, padding=nms_radius | |
) | |
zeros = torch.zeros_like(scores) | |
max_mask = scores == max_pool(scores) | |
for _ in range(2): | |
supp_mask = max_pool(max_mask.float()) > 0 | |
supp_scores = torch.where(supp_mask, zeros, scores) | |
new_max_mask = supp_scores == max_pool(supp_scores) | |
max_mask = max_mask | (new_max_mask & (~supp_mask)) | |
return torch.where(max_mask, scores, zeros) | |
def sample_descriptor(descriptor_map, kpts, bilinear_interp=False): | |
""" | |
:param descriptor_map: BxCxHxW | |
:param kpts: list, len=B, each is Nx2 (keypoints) [h,w] | |
:param bilinear_interp: bool, whether to use bilinear interpolation | |
:return: descriptors: list, len=B, each is NxD | |
""" | |
batch_size, channel, height, width = descriptor_map.shape | |
descriptors = [] | |
for index in range(batch_size): | |
kptsi = kpts[index] # Nx2,(x,y) | |
if bilinear_interp: | |
descriptors_ = torch.nn.functional.grid_sample( | |
descriptor_map[index].unsqueeze(0), | |
kptsi.view(1, 1, -1, 2), | |
mode="bilinear", | |
align_corners=True, | |
)[ | |
0, :, 0, : | |
] # CxN | |
else: | |
kptsi = (kptsi + 1) / 2 * kptsi.new_tensor([[width - 1, height - 1]]) | |
kptsi = kptsi.long() | |
descriptors_ = descriptor_map[index, :, kptsi[:, 1], kptsi[:, 0]] # CxN | |
descriptors_ = torch.nn.functional.normalize(descriptors_, p=2, dim=0) | |
descriptors.append(descriptors_.t()) | |
return descriptors | |
class DKD(nn.Module): | |
def __init__(self, radius=2, top_k=0, scores_th=0.2, n_limit=20000): | |
""" | |
Args: | |
radius: soft detection radius, kernel size is (2 * radius + 1) | |
top_k: top_k > 0: return top k keypoints | |
scores_th: top_k <= 0 threshold mode: scores_th > 0: return keypoints with scores>scores_th | |
else: return keypoints with scores > scores.mean() | |
n_limit: max number of keypoint in threshold mode | |
""" | |
super().__init__() | |
self.radius = radius | |
self.top_k = top_k | |
self.scores_th = scores_th | |
self.n_limit = n_limit | |
self.kernel_size = 2 * self.radius + 1 | |
self.temperature = 0.1 # tuned temperature | |
self.unfold = nn.Unfold(kernel_size=self.kernel_size, padding=self.radius) | |
# local xy grid | |
x = torch.linspace(-self.radius, self.radius, self.kernel_size) | |
# (kernel_size*kernel_size) x 2 : (w,h) | |
self.hw_grid = torch.stack(torch.meshgrid([x, x])).view(2, -1).t()[:, [1, 0]] | |
def detect_keypoints(self, scores_map, sub_pixel=True): | |
b, c, h, w = scores_map.shape | |
scores_nograd = scores_map.detach() | |
# nms_scores = simple_nms(scores_nograd, self.radius) | |
nms_scores = simple_nms(scores_nograd, 2) | |
# remove border | |
nms_scores[:, :, : self.radius + 1, :] = 0 | |
nms_scores[:, :, :, : self.radius + 1] = 0 | |
nms_scores[:, :, h - self.radius :, :] = 0 | |
nms_scores[:, :, :, w - self.radius :] = 0 | |
# detect keypoints without grad | |
if self.top_k > 0: | |
topk = torch.topk(nms_scores.view(b, -1), self.top_k) | |
indices_keypoints = topk.indices # B x top_k | |
else: | |
if self.scores_th > 0: | |
masks = nms_scores > self.scores_th | |
if masks.sum() == 0: | |
th = scores_nograd.reshape(b, -1).mean(dim=1) # th = self.scores_th | |
masks = nms_scores > th.reshape(b, 1, 1, 1) | |
else: | |
th = scores_nograd.reshape(b, -1).mean(dim=1) # th = self.scores_th | |
masks = nms_scores > th.reshape(b, 1, 1, 1) | |
masks = masks.reshape(b, -1) | |
indices_keypoints = [] # list, B x (any size) | |
scores_view = scores_nograd.reshape(b, -1) | |
for mask, scores in zip(masks, scores_view): | |
indices = mask.nonzero(as_tuple=False)[:, 0] | |
if len(indices) > self.n_limit: | |
kpts_sc = scores[indices] | |
sort_idx = kpts_sc.sort(descending=True)[1] | |
sel_idx = sort_idx[: self.n_limit] | |
indices = indices[sel_idx] | |
indices_keypoints.append(indices) | |
keypoints = [] | |
scoredispersitys = [] | |
kptscores = [] | |
if sub_pixel: | |
# detect soft keypoints with grad backpropagation | |
patches = self.unfold(scores_map) # B x (kernel**2) x (H*W) | |
self.hw_grid = self.hw_grid.to(patches) # to device | |
for b_idx in range(b): | |
patch = patches[b_idx].t() # (H*W) x (kernel**2) | |
indices_kpt = indices_keypoints[ | |
b_idx | |
] # one dimension vector, say its size is M | |
patch_scores = patch[indices_kpt] # M x (kernel**2) | |
# max is detached to prevent undesired backprop loops in the graph | |
max_v = patch_scores.max(dim=1).values.detach()[:, None] | |
x_exp = ( | |
(patch_scores - max_v) / self.temperature | |
).exp() # M * (kernel**2), in [0, 1] | |
# \frac{ \sum{(i,j) \times \exp(x/T)} }{ \sum{\exp(x/T)} } | |
xy_residual = ( | |
x_exp @ self.hw_grid / x_exp.sum(dim=1)[:, None] | |
) # Soft-argmax, Mx2 | |
hw_grid_dist2 = ( | |
torch.norm( | |
(self.hw_grid[None, :, :] - xy_residual[:, None, :]) | |
/ self.radius, | |
dim=-1, | |
) | |
** 2 | |
) | |
scoredispersity = (x_exp * hw_grid_dist2).sum(dim=1) / x_exp.sum(dim=1) | |
# compute result keypoints | |
keypoints_xy_nms = torch.stack( | |
[indices_kpt % w, indices_kpt // w], dim=1 | |
) # Mx2 | |
keypoints_xy = keypoints_xy_nms + xy_residual | |
keypoints_xy = ( | |
keypoints_xy / keypoints_xy.new_tensor([w - 1, h - 1]) * 2 - 1 | |
) # (w,h) -> (-1~1,-1~1) | |
kptscore = torch.nn.functional.grid_sample( | |
scores_map[b_idx].unsqueeze(0), | |
keypoints_xy.view(1, 1, -1, 2), | |
mode="bilinear", | |
align_corners=True, | |
)[ | |
0, 0, 0, : | |
] # CxN | |
keypoints.append(keypoints_xy) | |
scoredispersitys.append(scoredispersity) | |
kptscores.append(kptscore) | |
else: | |
for b_idx in range(b): | |
indices_kpt = indices_keypoints[ | |
b_idx | |
] # one dimension vector, say its size is M | |
keypoints_xy_nms = torch.stack( | |
[indices_kpt % w, indices_kpt // w], dim=1 | |
) # Mx2 | |
keypoints_xy = ( | |
keypoints_xy_nms / keypoints_xy_nms.new_tensor([w - 1, h - 1]) * 2 | |
- 1 | |
) # (w,h) -> (-1~1,-1~1) | |
kptscore = torch.nn.functional.grid_sample( | |
scores_map[b_idx].unsqueeze(0), | |
keypoints_xy.view(1, 1, -1, 2), | |
mode="bilinear", | |
align_corners=True, | |
)[ | |
0, 0, 0, : | |
] # CxN | |
keypoints.append(keypoints_xy) | |
scoredispersitys.append(None) | |
kptscores.append(kptscore) | |
return keypoints, scoredispersitys, kptscores | |
def forward(self, scores_map, descriptor_map, sub_pixel=False): | |
""" | |
:param scores_map: Bx1xHxW | |
:param descriptor_map: BxCxHxW | |
:param sub_pixel: whether to use sub-pixel keypoint detection | |
:return: kpts: list[Nx2,...]; kptscores: list[N,....] normalised position: -1.0 ~ 1.0 | |
""" | |
keypoints, scoredispersitys, kptscores = self.detect_keypoints( | |
scores_map, sub_pixel | |
) | |
descriptors = sample_descriptor(descriptor_map, keypoints, sub_pixel) | |
# keypoints: B M 2 | |
# descriptors: B M D | |
# scoredispersitys: | |
return keypoints, descriptors, kptscores, scoredispersitys | |