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import numpy as np | |
import torch | |
import torchvision | |
from itertools import product as product | |
from math import ceil | |
class PriorBox(object): | |
def __init__(self, cfg, image_size=None, phase='train'): | |
super(PriorBox, self).__init__() | |
self.min_sizes = cfg['min_sizes'] | |
self.steps = cfg['steps'] | |
self.clip = cfg['clip'] | |
self.image_size = image_size | |
self.feature_maps = [[ceil(self.image_size[0] / step), ceil(self.image_size[1] / step)] for step in self.steps] | |
self.name = 's' | |
def forward(self): | |
anchors = [] | |
for k, f in enumerate(self.feature_maps): | |
min_sizes = self.min_sizes[k] | |
for i, j in product(range(f[0]), range(f[1])): | |
for min_size in min_sizes: | |
s_kx = min_size / self.image_size[1] | |
s_ky = min_size / self.image_size[0] | |
dense_cx = [x * self.steps[k] / self.image_size[1] for x in [j + 0.5]] | |
dense_cy = [y * self.steps[k] / self.image_size[0] for y in [i + 0.5]] | |
for cy, cx in product(dense_cy, dense_cx): | |
anchors += [cx, cy, s_kx, s_ky] | |
# back to torch land | |
output = torch.Tensor(anchors).view(-1, 4) | |
if self.clip: | |
output.clamp_(max=1, min=0) | |
return output | |
def py_cpu_nms(dets, thresh): | |
"""Pure Python NMS baseline.""" | |
keep = torchvision.ops.nms( | |
boxes=torch.Tensor(dets[:, :4]), | |
scores=torch.Tensor(dets[:, 4]), | |
iou_threshold=thresh, | |
) | |
return list(keep) | |
def point_form(boxes): | |
""" Convert prior_boxes to (xmin, ymin, xmax, ymax) | |
representation for comparison to point form ground truth data. | |
Args: | |
boxes: (tensor) center-size default boxes from priorbox layers. | |
Return: | |
boxes: (tensor) Converted xmin, ymin, xmax, ymax form of boxes. | |
""" | |
return torch.cat( | |
( | |
boxes[:, :2] - boxes[:, 2:] / 2, # xmin, ymin | |
boxes[:, :2] + boxes[:, 2:] / 2), | |
1) # xmax, ymax | |
def center_size(boxes): | |
""" Convert prior_boxes to (cx, cy, w, h) | |
representation for comparison to center-size form ground truth data. | |
Args: | |
boxes: (tensor) point_form boxes | |
Return: | |
boxes: (tensor) Converted xmin, ymin, xmax, ymax form of boxes. | |
""" | |
return torch.cat( | |
(boxes[:, 2:] + boxes[:, :2]) / 2, # cx, cy | |
boxes[:, 2:] - boxes[:, :2], | |
1) # w, h | |
def intersect(box_a, box_b): | |
""" We resize both tensors to [A,B,2] without new malloc: | |
[A,2] -> [A,1,2] -> [A,B,2] | |
[B,2] -> [1,B,2] -> [A,B,2] | |
Then we compute the area of intersect between box_a and box_b. | |
Args: | |
box_a: (tensor) bounding boxes, Shape: [A,4]. | |
box_b: (tensor) bounding boxes, Shape: [B,4]. | |
Return: | |
(tensor) intersection area, Shape: [A,B]. | |
""" | |
A = box_a.size(0) | |
B = box_b.size(0) | |
max_xy = torch.min(box_a[:, 2:].unsqueeze(1).expand(A, B, 2), box_b[:, 2:].unsqueeze(0).expand(A, B, 2)) | |
min_xy = torch.max(box_a[:, :2].unsqueeze(1).expand(A, B, 2), box_b[:, :2].unsqueeze(0).expand(A, B, 2)) | |
inter = torch.clamp((max_xy - min_xy), min=0) | |
return inter[:, :, 0] * inter[:, :, 1] | |
def jaccard(box_a, box_b): | |
"""Compute the jaccard overlap of two sets of boxes. The jaccard overlap | |
is simply the intersection over union of two boxes. Here we operate on | |
ground truth boxes and default boxes. | |
E.g.: | |
A ∩ B / A ∪ B = A ∩ B / (area(A) + area(B) - A ∩ B) | |
Args: | |
box_a: (tensor) Ground truth bounding boxes, Shape: [num_objects,4] | |
box_b: (tensor) Prior boxes from priorbox layers, Shape: [num_priors,4] | |
Return: | |
jaccard overlap: (tensor) Shape: [box_a.size(0), box_b.size(0)] | |
""" | |
inter = intersect(box_a, box_b) | |
area_a = ((box_a[:, 2] - box_a[:, 0]) * (box_a[:, 3] - box_a[:, 1])).unsqueeze(1).expand_as(inter) # [A,B] | |
area_b = ((box_b[:, 2] - box_b[:, 0]) * (box_b[:, 3] - box_b[:, 1])).unsqueeze(0).expand_as(inter) # [A,B] | |
union = area_a + area_b - inter | |
return inter / union # [A,B] | |
def matrix_iou(a, b): | |
""" | |
return iou of a and b, numpy version for data augenmentation | |
""" | |
lt = np.maximum(a[:, np.newaxis, :2], b[:, :2]) | |
rb = np.minimum(a[:, np.newaxis, 2:], b[:, 2:]) | |
area_i = np.prod(rb - lt, axis=2) * (lt < rb).all(axis=2) | |
area_a = np.prod(a[:, 2:] - a[:, :2], axis=1) | |
area_b = np.prod(b[:, 2:] - b[:, :2], axis=1) | |
return area_i / (area_a[:, np.newaxis] + area_b - area_i) | |
def matrix_iof(a, b): | |
""" | |
return iof of a and b, numpy version for data augenmentation | |
""" | |
lt = np.maximum(a[:, np.newaxis, :2], b[:, :2]) | |
rb = np.minimum(a[:, np.newaxis, 2:], b[:, 2:]) | |
area_i = np.prod(rb - lt, axis=2) * (lt < rb).all(axis=2) | |
area_a = np.prod(a[:, 2:] - a[:, :2], axis=1) | |
return area_i / np.maximum(area_a[:, np.newaxis], 1) | |
def match(threshold, truths, priors, variances, labels, landms, loc_t, conf_t, landm_t, idx): | |
"""Match each prior box with the ground truth box of the highest jaccard | |
overlap, encode the bounding boxes, then return the matched indices | |
corresponding to both confidence and location preds. | |
Args: | |
threshold: (float) The overlap threshold used when matching boxes. | |
truths: (tensor) Ground truth boxes, Shape: [num_obj, 4]. | |
priors: (tensor) Prior boxes from priorbox layers, Shape: [n_priors,4]. | |
variances: (tensor) Variances corresponding to each prior coord, | |
Shape: [num_priors, 4]. | |
labels: (tensor) All the class labels for the image, Shape: [num_obj]. | |
landms: (tensor) Ground truth landms, Shape [num_obj, 10]. | |
loc_t: (tensor) Tensor to be filled w/ encoded location targets. | |
conf_t: (tensor) Tensor to be filled w/ matched indices for conf preds. | |
landm_t: (tensor) Tensor to be filled w/ encoded landm targets. | |
idx: (int) current batch index | |
Return: | |
The matched indices corresponding to 1)location 2)confidence | |
3)landm preds. | |
""" | |
# jaccard index | |
overlaps = jaccard(truths, point_form(priors)) | |
# (Bipartite Matching) | |
# [1,num_objects] best prior for each ground truth | |
best_prior_overlap, best_prior_idx = overlaps.max(1, keepdim=True) | |
# ignore hard gt | |
valid_gt_idx = best_prior_overlap[:, 0] >= 0.2 | |
best_prior_idx_filter = best_prior_idx[valid_gt_idx, :] | |
if best_prior_idx_filter.shape[0] <= 0: | |
loc_t[idx] = 0 | |
conf_t[idx] = 0 | |
return | |
# [1,num_priors] best ground truth for each prior | |
best_truth_overlap, best_truth_idx = overlaps.max(0, keepdim=True) | |
best_truth_idx.squeeze_(0) | |
best_truth_overlap.squeeze_(0) | |
best_prior_idx.squeeze_(1) | |
best_prior_idx_filter.squeeze_(1) | |
best_prior_overlap.squeeze_(1) | |
best_truth_overlap.index_fill_(0, best_prior_idx_filter, 2) # ensure best prior | |
# TODO refactor: index best_prior_idx with long tensor | |
# ensure every gt matches with its prior of max overlap | |
for j in range(best_prior_idx.size(0)): # 判别此anchor是预测哪一个boxes | |
best_truth_idx[best_prior_idx[j]] = j | |
matches = truths[best_truth_idx] # Shape: [num_priors,4] 此处为每一个anchor对应的bbox取出来 | |
conf = labels[best_truth_idx] # Shape: [num_priors] 此处为每一个anchor对应的label取出来 | |
conf[best_truth_overlap < threshold] = 0 # label as background overlap<0.35的全部作为负样本 | |
loc = encode(matches, priors, variances) | |
matches_landm = landms[best_truth_idx] | |
landm = encode_landm(matches_landm, priors, variances) | |
loc_t[idx] = loc # [num_priors,4] encoded offsets to learn | |
conf_t[idx] = conf # [num_priors] top class label for each prior | |
landm_t[idx] = landm | |
def encode(matched, priors, variances): | |
"""Encode the variances from the priorbox layers into the ground truth boxes | |
we have matched (based on jaccard overlap) with the prior boxes. | |
Args: | |
matched: (tensor) Coords of ground truth for each prior in point-form | |
Shape: [num_priors, 4]. | |
priors: (tensor) Prior boxes in center-offset form | |
Shape: [num_priors,4]. | |
variances: (list[float]) Variances of priorboxes | |
Return: | |
encoded boxes (tensor), Shape: [num_priors, 4] | |
""" | |
# dist b/t match center and prior's center | |
g_cxcy = (matched[:, :2] + matched[:, 2:]) / 2 - priors[:, :2] | |
# encode variance | |
g_cxcy /= (variances[0] * priors[:, 2:]) | |
# match wh / prior wh | |
g_wh = (matched[:, 2:] - matched[:, :2]) / priors[:, 2:] | |
g_wh = torch.log(g_wh) / variances[1] | |
# return target for smooth_l1_loss | |
return torch.cat([g_cxcy, g_wh], 1) # [num_priors,4] | |
def encode_landm(matched, priors, variances): | |
"""Encode the variances from the priorbox layers into the ground truth boxes | |
we have matched (based on jaccard overlap) with the prior boxes. | |
Args: | |
matched: (tensor) Coords of ground truth for each prior in point-form | |
Shape: [num_priors, 10]. | |
priors: (tensor) Prior boxes in center-offset form | |
Shape: [num_priors,4]. | |
variances: (list[float]) Variances of priorboxes | |
Return: | |
encoded landm (tensor), Shape: [num_priors, 10] | |
""" | |
# dist b/t match center and prior's center | |
matched = torch.reshape(matched, (matched.size(0), 5, 2)) | |
priors_cx = priors[:, 0].unsqueeze(1).expand(matched.size(0), 5).unsqueeze(2) | |
priors_cy = priors[:, 1].unsqueeze(1).expand(matched.size(0), 5).unsqueeze(2) | |
priors_w = priors[:, 2].unsqueeze(1).expand(matched.size(0), 5).unsqueeze(2) | |
priors_h = priors[:, 3].unsqueeze(1).expand(matched.size(0), 5).unsqueeze(2) | |
priors = torch.cat([priors_cx, priors_cy, priors_w, priors_h], dim=2) | |
g_cxcy = matched[:, :, :2] - priors[:, :, :2] | |
# encode variance | |
g_cxcy /= (variances[0] * priors[:, :, 2:]) | |
# g_cxcy /= priors[:, :, 2:] | |
g_cxcy = g_cxcy.reshape(g_cxcy.size(0), -1) | |
# return target for smooth_l1_loss | |
return g_cxcy | |
# Adapted from https://github.com/Hakuyume/chainer-ssd | |
def decode(loc, priors, variances): | |
"""Decode locations from predictions using priors to undo | |
the encoding we did for offset regression at train time. | |
Args: | |
loc (tensor): location predictions for loc layers, | |
Shape: [num_priors,4] | |
priors (tensor): Prior boxes in center-offset form. | |
Shape: [num_priors,4]. | |
variances: (list[float]) Variances of priorboxes | |
Return: | |
decoded bounding box predictions | |
""" | |
boxes = torch.cat((priors[:, :2] + loc[:, :2] * variances[0] * priors[:, 2:], | |
priors[:, 2:] * torch.exp(loc[:, 2:] * variances[1])), 1) | |
boxes[:, :2] -= boxes[:, 2:] / 2 | |
boxes[:, 2:] += boxes[:, :2] | |
return boxes | |
def decode_landm(pre, priors, variances): | |
"""Decode landm from predictions using priors to undo | |
the encoding we did for offset regression at train time. | |
Args: | |
pre (tensor): landm predictions for loc layers, | |
Shape: [num_priors,10] | |
priors (tensor): Prior boxes in center-offset form. | |
Shape: [num_priors,4]. | |
variances: (list[float]) Variances of priorboxes | |
Return: | |
decoded landm predictions | |
""" | |
tmp = ( | |
priors[:, :2] + pre[:, :2] * variances[0] * priors[:, 2:], | |
priors[:, :2] + pre[:, 2:4] * variances[0] * priors[:, 2:], | |
priors[:, :2] + pre[:, 4:6] * variances[0] * priors[:, 2:], | |
priors[:, :2] + pre[:, 6:8] * variances[0] * priors[:, 2:], | |
priors[:, :2] + pre[:, 8:10] * variances[0] * priors[:, 2:], | |
) | |
landms = torch.cat(tmp, dim=1) | |
return landms | |
def batched_decode(b_loc, priors, variances): | |
"""Decode locations from predictions using priors to undo | |
the encoding we did for offset regression at train time. | |
Args: | |
b_loc (tensor): location predictions for loc layers, | |
Shape: [num_batches,num_priors,4] | |
priors (tensor): Prior boxes in center-offset form. | |
Shape: [1,num_priors,4]. | |
variances: (list[float]) Variances of priorboxes | |
Return: | |
decoded bounding box predictions | |
""" | |
boxes = ( | |
priors[:, :, :2] + b_loc[:, :, :2] * variances[0] * priors[:, :, 2:], | |
priors[:, :, 2:] * torch.exp(b_loc[:, :, 2:] * variances[1]), | |
) | |
boxes = torch.cat(boxes, dim=2) | |
boxes[:, :, :2] -= boxes[:, :, 2:] / 2 | |
boxes[:, :, 2:] += boxes[:, :, :2] | |
return boxes | |
def batched_decode_landm(pre, priors, variances): | |
"""Decode landm from predictions using priors to undo | |
the encoding we did for offset regression at train time. | |
Args: | |
pre (tensor): landm predictions for loc layers, | |
Shape: [num_batches,num_priors,10] | |
priors (tensor): Prior boxes in center-offset form. | |
Shape: [1,num_priors,4]. | |
variances: (list[float]) Variances of priorboxes | |
Return: | |
decoded landm predictions | |
""" | |
landms = ( | |
priors[:, :, :2] + pre[:, :, :2] * variances[0] * priors[:, :, 2:], | |
priors[:, :, :2] + pre[:, :, 2:4] * variances[0] * priors[:, :, 2:], | |
priors[:, :, :2] + pre[:, :, 4:6] * variances[0] * priors[:, :, 2:], | |
priors[:, :, :2] + pre[:, :, 6:8] * variances[0] * priors[:, :, 2:], | |
priors[:, :, :2] + pre[:, :, 8:10] * variances[0] * priors[:, :, 2:], | |
) | |
landms = torch.cat(landms, dim=2) | |
return landms | |
def log_sum_exp(x): | |
"""Utility function for computing log_sum_exp while determining | |
This will be used to determine unaveraged confidence loss across | |
all examples in a batch. | |
Args: | |
x (Variable(tensor)): conf_preds from conf layers | |
""" | |
x_max = x.data.max() | |
return torch.log(torch.sum(torch.exp(x - x_max), 1, keepdim=True)) + x_max | |
# Original author: Francisco Massa: | |
# https://github.com/fmassa/object-detection.torch | |
# Ported to PyTorch by Max deGroot (02/01/2017) | |
def nms(boxes, scores, overlap=0.5, top_k=200): | |
"""Apply non-maximum suppression at test time to avoid detecting too many | |
overlapping bounding boxes for a given object. | |
Args: | |
boxes: (tensor) The location preds for the img, Shape: [num_priors,4]. | |
scores: (tensor) The class predscores for the img, Shape:[num_priors]. | |
overlap: (float) The overlap thresh for suppressing unnecessary boxes. | |
top_k: (int) The Maximum number of box preds to consider. | |
Return: | |
The indices of the kept boxes with respect to num_priors. | |
""" | |
keep = torch.Tensor(scores.size(0)).fill_(0).long() | |
if boxes.numel() == 0: | |
return keep | |
x1 = boxes[:, 0] | |
y1 = boxes[:, 1] | |
x2 = boxes[:, 2] | |
y2 = boxes[:, 3] | |
area = torch.mul(x2 - x1, y2 - y1) | |
v, idx = scores.sort(0) # sort in ascending order | |
# I = I[v >= 0.01] | |
idx = idx[-top_k:] # indices of the top-k largest vals | |
xx1 = boxes.new() | |
yy1 = boxes.new() | |
xx2 = boxes.new() | |
yy2 = boxes.new() | |
w = boxes.new() | |
h = boxes.new() | |
# keep = torch.Tensor() | |
count = 0 | |
while idx.numel() > 0: | |
i = idx[-1] # index of current largest val | |
# keep.append(i) | |
keep[count] = i | |
count += 1 | |
if idx.size(0) == 1: | |
break | |
idx = idx[:-1] # remove kept element from view | |
# load bboxes of next highest vals | |
torch.index_select(x1, 0, idx, out=xx1) | |
torch.index_select(y1, 0, idx, out=yy1) | |
torch.index_select(x2, 0, idx, out=xx2) | |
torch.index_select(y2, 0, idx, out=yy2) | |
# store element-wise max with next highest score | |
xx1 = torch.clamp(xx1, min=x1[i]) | |
yy1 = torch.clamp(yy1, min=y1[i]) | |
xx2 = torch.clamp(xx2, max=x2[i]) | |
yy2 = torch.clamp(yy2, max=y2[i]) | |
w.resize_as_(xx2) | |
h.resize_as_(yy2) | |
w = xx2 - xx1 | |
h = yy2 - yy1 | |
# check sizes of xx1 and xx2.. after each iteration | |
w = torch.clamp(w, min=0.0) | |
h = torch.clamp(h, min=0.0) | |
inter = w * h | |
# IoU = i / (area(a) + area(b) - i) | |
rem_areas = torch.index_select(area, 0, idx) # load remaining areas) | |
union = (rem_areas - inter) + area[i] | |
IoU = inter / union # store result in iou | |
# keep only elements with an IoU <= overlap | |
idx = idx[IoU.le(overlap)] | |
return keep, count | |