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post_process.py
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post_process.py
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# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import numpy as np
import paddle
import paddle.nn as nn
import paddle.nn.functional as F
from ppdet.core.workspace import register
from ppdet.modeling.bbox_utils import nonempty_bbox
from .transformers import bbox_cxcywh_to_xyxy
try:
from collections.abc import Sequence
except Exception:
from collections import Sequence
__all__ = [
'BBoxPostProcess', 'MaskPostProcess', 'JDEBBoxPostProcess',
'CenterNetPostProcess', 'DETRPostProcess', 'SparsePostProcess',
'DETRBBoxSemiPostProcess'
]
@register
class BBoxPostProcess(object):
__shared__ = ['num_classes', 'export_onnx', 'export_eb']
__inject__ = ['decode', 'nms']
def __init__(self,
num_classes=80,
decode=None,
nms=None,
export_onnx=False,
export_eb=False):
super(BBoxPostProcess, self).__init__()
self.num_classes = num_classes
self.decode = decode
self.nms = nms
self.export_onnx = export_onnx
self.export_eb = export_eb
def __call__(self, head_out, rois, im_shape, scale_factor):
"""
Decode the bbox and do NMS if needed.
Args:
head_out (tuple): bbox_pred and cls_prob of bbox_head output.
rois (tuple): roi and rois_num of rpn_head output.
im_shape (Tensor): The shape of the input image.
scale_factor (Tensor): The scale factor of the input image.
export_onnx (bool): whether export model to onnx
Returns:
bbox_pred (Tensor): The output prediction with shape [N, 6], including
labels, scores and bboxes. The size of bboxes are corresponding
to the input image, the bboxes may be used in other branch.
bbox_num (Tensor): The number of prediction boxes of each batch with
shape [1], and is N.
"""
if self.nms is not None:
bboxes, score = self.decode(head_out, rois, im_shape, scale_factor)
bbox_pred, bbox_num, before_nms_indexes = self.nms(bboxes, score,
self.num_classes)
else:
bbox_pred, bbox_num = self.decode(head_out, rois, im_shape,
scale_factor)
if self.export_onnx:
# add fake box after postprocess when exporting onnx
fake_bboxes = paddle.to_tensor(
np.array(
[[0., 0.0, 0.0, 0.0, 1.0, 1.0]], dtype='float32'))
bbox_pred = paddle.concat([bbox_pred, fake_bboxes])
bbox_num = bbox_num + 1
if self.nms is not None:
return bbox_pred, bbox_num, before_nms_indexes
else:
return bbox_pred, bbox_num
def get_pred(self, bboxes, bbox_num, im_shape, scale_factor):
"""
Rescale, clip and filter the bbox from the output of NMS to
get final prediction.
Notes:
Currently only support bs = 1.
Args:
bboxes (Tensor): The output bboxes with shape [N, 6] after decode
and NMS, including labels, scores and bboxes.
bbox_num (Tensor): The number of prediction boxes of each batch with
shape [1], and is N.
im_shape (Tensor): The shape of the input image.
scale_factor (Tensor): The scale factor of the input image.
Returns:
pred_result (Tensor): The final prediction results with shape [N, 6]
including labels, scores and bboxes.
"""
if self.export_eb:
# enable rcnn models for edgeboard hw to skip the following postprocess.
return bboxes, bboxes, bbox_num
if not self.export_onnx:
bboxes_list = []
bbox_num_list = []
id_start = 0
fake_bboxes = paddle.to_tensor(
np.array(
[[0., 0.0, 0.0, 0.0, 1.0, 1.0]], dtype='float32'))
fake_bbox_num = paddle.to_tensor(np.array([1], dtype='int32'))
# add fake bbox when output is empty for each batch
for i in range(bbox_num.shape[0]):
if bbox_num[i] == 0:
bboxes_i = fake_bboxes
bbox_num_i = fake_bbox_num
else:
bboxes_i = bboxes[id_start:id_start + bbox_num[i], :]
bbox_num_i = bbox_num[i:i + 1]
# id_start: 0-dim, bbox_num: 1-dim. Use bbox_num[i] instead of bbox_num[i:i+1] in pir.
id_start += bbox_num[i]
bboxes_list.append(bboxes_i)
bbox_num_list.append(bbox_num_i)
bboxes = paddle.concat(bboxes_list)
bbox_num = paddle.concat(bbox_num_list)
origin_shape = paddle.floor(im_shape / scale_factor + 0.5)
if not self.export_onnx:
origin_shape_list = []
scale_factor_list = []
# scale_factor: scale_y, scale_x
for i in range(bbox_num.shape[0]):
expand_shape = paddle.expand(origin_shape[i:i + 1, :],
[bbox_num[i:i + 1], 2])
scale_y, scale_x = scale_factor[i, 0], scale_factor[i, 1]
# TODO(PIR): something wrong with slice op, remove unsqueeze in the future.
scale_y = paddle.unsqueeze(scale_y, 0)
scale_x = paddle.unsqueeze(scale_x, 0)
scale = paddle.concat([scale_x, scale_y, scale_x, scale_y])
expand_scale = paddle.expand(scale, [bbox_num[i:i + 1], 4])
origin_shape_list.append(expand_shape)
scale_factor_list.append(expand_scale)
self.origin_shape_list = paddle.concat(origin_shape_list)
scale_factor_list = paddle.concat(scale_factor_list)
else:
# simplify the computation for bs=1 when exporting onnx
scale_y, scale_x = scale_factor[0][0], scale_factor[0][1]
scale = paddle.concat(
[scale_x, scale_y, scale_x, scale_y]).unsqueeze(0)
self.origin_shape_list = paddle.expand(origin_shape,
[bbox_num[0:1], 2])
scale_factor_list = paddle.expand(scale, [bbox_num[0:1], 4])
# bboxes: [N, 6], label, score, bbox
pred_label = bboxes[:, 0:1]
pred_score = bboxes[:, 1:2]
pred_bbox = bboxes[:, 2:]
# rescale bbox to original image
scaled_bbox = pred_bbox / scale_factor_list
origin_h = self.origin_shape_list[:, 0]
origin_w = self.origin_shape_list[:, 1]
zeros = paddle.zeros_like(origin_h)
# clip bbox to [0, original_size]
x1 = paddle.maximum(paddle.minimum(scaled_bbox[:, 0], origin_w), zeros)
y1 = paddle.maximum(paddle.minimum(scaled_bbox[:, 1], origin_h), zeros)
x2 = paddle.maximum(paddle.minimum(scaled_bbox[:, 2], origin_w), zeros)
y2 = paddle.maximum(paddle.minimum(scaled_bbox[:, 3], origin_h), zeros)
pred_bbox = paddle.stack([x1, y1, x2, y2], axis=-1)
# filter empty bbox
keep_mask = nonempty_bbox(pred_bbox, return_mask=True)
keep_mask = paddle.unsqueeze(keep_mask, [1])
pred_label = paddle.where(keep_mask, pred_label,
paddle.ones_like(pred_label) * -1)
pred_result = paddle.concat([pred_label, pred_score, pred_bbox], axis=1)
return bboxes, pred_result, bbox_num
def get_origin_shape(self, ):
return self.origin_shape_list
@register
class MaskPostProcess(object):
__shared__ = ['export_onnx', 'assign_on_cpu']
"""
refer to:
https://github.com/facebookresearch/detectron2/layers/mask_ops.py
Get Mask output according to the output from model
"""
def __init__(self,
binary_thresh=0.5,
export_onnx=False,
assign_on_cpu=False):
super(MaskPostProcess, self).__init__()
self.binary_thresh = binary_thresh
self.export_onnx = export_onnx
self.assign_on_cpu = assign_on_cpu
def __call__(self, mask_out, bboxes, bbox_num, origin_shape):
"""
Decode the mask_out and paste the mask to the origin image.
Args:
mask_out (Tensor): mask_head output with shape [N, 28, 28].
bbox_pred (Tensor): The output bboxes with shape [N, 6] after decode
and NMS, including labels, scores and bboxes.
bbox_num (Tensor): The number of prediction boxes of each batch with
shape [1], and is N.
origin_shape (Tensor): The origin shape of the input image, the tensor
shape is [N, 2], and each row is [h, w].
Returns:
pred_result (Tensor): The final prediction mask results with shape
[N, h, w] in binary mask style.
"""
num_mask = mask_out.shape[0]
origin_shape = paddle.cast(origin_shape, 'int32')
device = paddle.device.get_device()
if self.export_onnx:
h, w = origin_shape[0][0], origin_shape[0][1]
mask_onnx = paste_mask(mask_out[:, None, :, :], bboxes[:, 2:], h, w,
self.assign_on_cpu)
mask_onnx = mask_onnx >= self.binary_thresh
pred_result = paddle.cast(mask_onnx, 'int32')
else:
max_h = paddle.max(origin_shape[:, 0])
max_w = paddle.max(origin_shape[:, 1])
pred_result = paddle.zeros(
[num_mask, max_h, max_w], dtype='int32') - 1
id_start = 0
for i in range(bbox_num.shape[0]):
bboxes_i = bboxes[id_start:id_start + bbox_num[i], :]
mask_out_i = mask_out[id_start:id_start + bbox_num[i], :, :]
im_h = origin_shape[i, 0]
im_w = origin_shape[i, 1]
pred_mask = paste_mask(mask_out_i[:, None, :, :],
bboxes_i[:, 2:], im_h, im_w,
self.assign_on_cpu)
pred_mask = paddle.cast(pred_mask >= self.binary_thresh,
'int32')
pred_result[id_start:id_start + bbox_num[i], :im_h, :
im_w] = pred_mask
id_start += bbox_num[i]
if self.assign_on_cpu:
paddle.set_device(device)
return pred_result
@register
class JDEBBoxPostProcess(nn.Layer):
__shared__ = ['num_classes']
__inject__ = ['decode', 'nms']
def __init__(self, num_classes=1, decode=None, nms=None, return_idx=True):
super(JDEBBoxPostProcess, self).__init__()
self.num_classes = num_classes
self.decode = decode
self.nms = nms
self.return_idx = return_idx
self.fake_bbox_pred = paddle.to_tensor(
np.array(
[[-1, 0.0, 0.0, 0.0, 0.0, 0.0]], dtype='float32'))
self.fake_bbox_num = paddle.to_tensor(np.array([1], dtype='int32'))
self.fake_nms_keep_idx = paddle.to_tensor(
np.array(
[[0]], dtype='int32'))
self.fake_yolo_boxes_out = paddle.to_tensor(
np.array(
[[[0.0, 0.0, 0.0, 0.0]]], dtype='float32'))
self.fake_yolo_scores_out = paddle.to_tensor(
np.array(
[[[0.0]]], dtype='float32'))
self.fake_boxes_idx = paddle.to_tensor(np.array([[0]], dtype='int64'))
def forward(self, head_out, anchors):
"""
Decode the bbox and do NMS for JDE model.
Args:
head_out (list): Bbox_pred and cls_prob of bbox_head output.
anchors (list): Anchors of JDE model.
Returns:
boxes_idx (Tensor): The index of kept bboxes after decode 'JDEBox'.
bbox_pred (Tensor): The output is the prediction with shape [N, 6]
including labels, scores and bboxes.
bbox_num (Tensor): The number of prediction of each batch with shape [N].
nms_keep_idx (Tensor): The index of kept bboxes after NMS.
"""
boxes_idx, yolo_boxes_scores = self.decode(head_out, anchors)
if len(boxes_idx) == 0:
boxes_idx = self.fake_boxes_idx
yolo_boxes_out = self.fake_yolo_boxes_out
yolo_scores_out = self.fake_yolo_scores_out
else:
yolo_boxes = paddle.gather_nd(yolo_boxes_scores, boxes_idx)
# TODO: only support bs=1 now
yolo_boxes_out = paddle.reshape(
yolo_boxes[:, :4], shape=[1, len(boxes_idx), 4])
yolo_scores_out = paddle.reshape(
yolo_boxes[:, 4:5], shape=[1, 1, len(boxes_idx)])
boxes_idx = boxes_idx[:, 1:]
if self.return_idx:
bbox_pred, bbox_num, nms_keep_idx = self.nms(
yolo_boxes_out, yolo_scores_out, self.num_classes)
if bbox_pred.shape[0] == 0:
bbox_pred = self.fake_bbox_pred
bbox_num = self.fake_bbox_num
nms_keep_idx = self.fake_nms_keep_idx
return boxes_idx, bbox_pred, bbox_num, nms_keep_idx
else:
bbox_pred, bbox_num, _ = self.nms(yolo_boxes_out, yolo_scores_out,
self.num_classes)
if bbox_pred.shape[0] == 0:
bbox_pred = self.fake_bbox_pred
bbox_num = self.fake_bbox_num
return _, bbox_pred, bbox_num, _
@register
class CenterNetPostProcess(object):
"""
Postprocess the model outputs to get final prediction:
1. Do NMS for heatmap to get top `max_per_img` bboxes.
2. Decode bboxes using center offset and box size.
3. Rescale decoded bboxes reference to the origin image shape.
Args:
max_per_img(int): the maximum number of predicted objects in a image,
500 by default.
down_ratio(int): the down ratio from images to heatmap, 4 by default.
regress_ltrb (bool): whether to regress left/top/right/bottom or
width/height for a box, true by default.
"""
__shared__ = ['down_ratio']
def __init__(self, max_per_img=500, down_ratio=4, regress_ltrb=True):
super(CenterNetPostProcess, self).__init__()
self.max_per_img = max_per_img
self.down_ratio = down_ratio
self.regress_ltrb = regress_ltrb
# _simple_nms() _topk() are same as TTFBox in ppdet/modeling/layers.py
def _simple_nms(self, heat, kernel=3):
""" Use maxpool to filter the max score, get local peaks. """
pad = (kernel - 1) // 2
hmax = F.max_pool2d(heat, kernel, stride=1, padding=pad)
keep = paddle.cast(hmax == heat, 'float32')
return heat * keep
def _topk(self, scores):
""" Select top k scores and decode to get xy coordinates. """
k = self.max_per_img
shape_fm = paddle.shape(scores)
shape_fm.stop_gradient = True
cat, height, width = shape_fm[1], shape_fm[2], shape_fm[3]
# batch size is 1
scores_r = paddle.reshape(scores, [cat, -1])
topk_scores, topk_inds = paddle.topk(scores_r, k)
topk_ys = topk_inds // width
topk_xs = topk_inds % width
topk_score_r = paddle.reshape(topk_scores, [-1])
topk_score, topk_ind = paddle.topk(topk_score_r, k)
k_t = paddle.full(topk_ind.shape, k, dtype='int64')
topk_clses = paddle.cast(paddle.floor_divide(topk_ind, k_t), 'float32')
topk_inds = paddle.reshape(topk_inds, [-1])
topk_ys = paddle.reshape(topk_ys, [-1, 1])
topk_xs = paddle.reshape(topk_xs, [-1, 1])
topk_inds = paddle.gather(topk_inds, topk_ind)
topk_ys = paddle.gather(topk_ys, topk_ind)
topk_xs = paddle.gather(topk_xs, topk_ind)
return topk_score, topk_inds, topk_clses, topk_ys, topk_xs
def __call__(self, hm, wh, reg, im_shape, scale_factor):
# 1.get clses and scores, note that hm had been done sigmoid
heat = self._simple_nms(hm)
scores, inds, topk_clses, ys, xs = self._topk(heat)
clses = topk_clses.unsqueeze(1)
scores = scores.unsqueeze(1)
# 2.get bboxes, note only support batch_size=1 now
reg_t = paddle.transpose(reg, [0, 2, 3, 1])
reg = paddle.reshape(reg_t, [-1, reg_t.shape[-1]])
reg = paddle.gather(reg, inds)
xs = paddle.cast(xs, 'float32')
ys = paddle.cast(ys, 'float32')
xs = xs + reg[:, 0:1]
ys = ys + reg[:, 1:2]
wh_t = paddle.transpose(wh, [0, 2, 3, 1])
wh = paddle.reshape(wh_t, [-1, wh_t.shape[-1]])
wh = paddle.gather(wh, inds)
if self.regress_ltrb:
x1 = xs - wh[:, 0:1]
y1 = ys - wh[:, 1:2]
x2 = xs + wh[:, 2:3]
y2 = ys + wh[:, 3:4]
else:
x1 = xs - wh[:, 0:1] / 2
y1 = ys - wh[:, 1:2] / 2
x2 = xs + wh[:, 0:1] / 2
y2 = ys + wh[:, 1:2] / 2
n, c, feat_h, feat_w = paddle.shape(hm)
padw = (feat_w * self.down_ratio - im_shape[0, 1]) / 2
padh = (feat_h * self.down_ratio - im_shape[0, 0]) / 2
x1 = x1 * self.down_ratio
y1 = y1 * self.down_ratio
x2 = x2 * self.down_ratio
y2 = y2 * self.down_ratio
x1 = x1 - padw
y1 = y1 - padh
x2 = x2 - padw
y2 = y2 - padh
bboxes = paddle.concat([x1, y1, x2, y2], axis=1)
scale_y = scale_factor[:, 0:1]
scale_x = scale_factor[:, 1:2]
scale_expand = paddle.concat(
[scale_x, scale_y, scale_x, scale_y], axis=1)
boxes_shape = bboxes.shape[:]
scale_expand = paddle.expand(scale_expand, shape=boxes_shape)
bboxes = paddle.divide(bboxes, scale_expand)
results = paddle.concat([clses, scores, bboxes], axis=1)
return results, paddle.shape(results)[0:1], inds, topk_clses, ys, xs
@register
class DETRPostProcess(object):
__shared__ = ['num_classes', 'use_focal_loss', 'with_mask']
__inject__ = []
def __init__(self,
num_classes=80,
num_top_queries=100,
dual_queries=False,
dual_groups=0,
use_focal_loss=False,
with_mask=False,
mask_stride=4,
mask_threshold=0.5,
use_avg_mask_score=False,
bbox_decode_type='origin'):
super(DETRPostProcess, self).__init__()
assert bbox_decode_type in ['origin', 'pad']
self.num_classes = num_classes
self.num_top_queries = num_top_queries
self.dual_queries = dual_queries
self.dual_groups = dual_groups
self.use_focal_loss = use_focal_loss
self.with_mask = with_mask
self.mask_stride = mask_stride
self.mask_threshold = mask_threshold
self.use_avg_mask_score = use_avg_mask_score
self.bbox_decode_type = bbox_decode_type
def _mask_postprocess(self, mask_pred, score_pred):
mask_score = F.sigmoid(mask_pred)
mask_pred = (mask_score > self.mask_threshold).astype(mask_score.dtype)
if self.use_avg_mask_score:
avg_mask_score = (mask_pred * mask_score).sum([-2, -1]) / (
mask_pred.sum([-2, -1]) + 1e-6)
score_pred *= avg_mask_score
return mask_pred.flatten(0, 1).astype('int32'), score_pred
def __call__(self, head_out, im_shape, scale_factor, pad_shape):
"""
Decode the bbox and mask.
Args:
head_out (tuple): bbox_pred, cls_logit and masks of bbox_head output.
im_shape (Tensor): The shape of the input image without padding.
scale_factor (Tensor): The scale factor of the input image.
pad_shape (Tensor): The shape of the input image with padding.
Returns:
bbox_pred (Tensor): The output prediction with shape [N, 6], including
labels, scores and bboxes. The size of bboxes are corresponding
to the input image, the bboxes may be used in other branch.
bbox_num (Tensor): The number of prediction boxes of each batch with
shape [bs], and is N.
"""
bboxes, logits, masks = head_out
if self.dual_queries:
num_queries = logits.shape[1]
logits, bboxes = logits[:, :int(num_queries // (self.dual_groups + 1)), :], \
bboxes[:, :int(num_queries // (self.dual_groups + 1)), :]
bbox_pred = bbox_cxcywh_to_xyxy(bboxes)
# calculate the original shape of the image
origin_shape = paddle.floor(im_shape / scale_factor + 0.5)
img_h, img_w = paddle.split(origin_shape, 2, axis=-1)
if self.bbox_decode_type == 'pad':
# calculate the shape of the image with padding
out_shape = pad_shape / im_shape * origin_shape
out_shape = out_shape.flip(1).tile([1, 2]).unsqueeze(1)
elif self.bbox_decode_type == 'origin':
out_shape = origin_shape.flip(1).tile([1, 2]).unsqueeze(1)
else:
raise Exception(
f'Wrong `bbox_decode_type`: {self.bbox_decode_type}.')
bbox_pred *= out_shape
scores = F.sigmoid(logits) if self.use_focal_loss else F.softmax(
logits)[:, :, :-1]
if not self.use_focal_loss:
scores, labels = scores.max(-1), scores.argmax(-1)
if scores.shape[1] > self.num_top_queries:
scores, index = paddle.topk(
scores, self.num_top_queries, axis=-1)
batch_ind = paddle.arange(
end=scores.shape[0]).unsqueeze(-1).tile(
[1, self.num_top_queries])
index = paddle.stack([batch_ind, index], axis=-1)
labels = paddle.gather_nd(labels, index)
bbox_pred = paddle.gather_nd(bbox_pred, index)
else:
scores, index = paddle.topk(
scores.flatten(1), self.num_top_queries, axis=-1)
labels = index % self.num_classes
index = index // self.num_classes
batch_ind = paddle.arange(end=scores.shape[0]).unsqueeze(-1).tile(
[1, self.num_top_queries])
index = paddle.stack([batch_ind, index], axis=-1)
bbox_pred = paddle.gather_nd(bbox_pred, index)
mask_pred = None
if self.with_mask:
assert masks is not None
assert masks.shape[0] == 1
masks = paddle.gather_nd(masks, index)
if self.bbox_decode_type == 'pad':
masks = F.interpolate(
masks,
scale_factor=self.mask_stride,
mode="bilinear",
align_corners=False)
# TODO: Support prediction with bs>1.
# remove padding for input image
h, w = im_shape.astype('int32')[0]
masks = masks[..., :h, :w]
# get pred_mask in the original resolution.
img_h = img_h[0].astype('int32')
img_w = img_w[0].astype('int32')
masks = F.interpolate(
masks,
size=[img_h, img_w],
mode="bilinear",
align_corners=False)
mask_pred, scores = self._mask_postprocess(masks, scores)
bbox_pred = paddle.concat(
[
labels.unsqueeze(-1).astype('float32'), scores.unsqueeze(-1),
bbox_pred
],
axis=-1)
bbox_num = paddle.to_tensor(
self.num_top_queries, dtype='int32').tile([bbox_pred.shape[0]])
bbox_pred = bbox_pred.reshape([-1, 6])
return bbox_pred, bbox_num, mask_pred
@register
class SparsePostProcess(object):
__shared__ = ['num_classes', 'assign_on_cpu']
def __init__(self,
num_proposals,
num_classes=80,
binary_thresh=0.5,
assign_on_cpu=False):
super(SparsePostProcess, self).__init__()
self.num_classes = num_classes
self.num_proposals = num_proposals
self.binary_thresh = binary_thresh
self.assign_on_cpu = assign_on_cpu
def __call__(self, scores, bboxes, scale_factor, ori_shape, masks=None):
assert len(scores) == len(bboxes) == \
len(ori_shape) == len(scale_factor)
device = paddle.device.get_device()
batch_size = len(ori_shape)
scores = F.sigmoid(scores)
has_mask = masks is not None
if has_mask:
masks = F.sigmoid(masks)
masks = masks.reshape([batch_size, -1, *masks.shape[1:]])
bbox_pred = []
mask_pred = [] if has_mask else None
bbox_num = paddle.zeros([batch_size], dtype='int32')
for i in range(batch_size):
score = scores[i]
bbox = bboxes[i]
score, indices = score.flatten(0, 1).topk(
self.num_proposals, sorted=False)
label = indices % self.num_classes
if has_mask:
mask = masks[i]
mask = mask.flatten(0, 1)[indices]
H, W = ori_shape[i][0], ori_shape[i][1]
bbox = bbox[paddle.cast(indices / self.num_classes, indices.dtype)]
bbox /= scale_factor[i]
bbox[:, 0::2] = paddle.clip(bbox[:, 0::2], 0, W)
bbox[:, 1::2] = paddle.clip(bbox[:, 1::2], 0, H)
keep = ((bbox[:, 2] - bbox[:, 0]).numpy() > 1.) & \
((bbox[:, 3] - bbox[:, 1]).numpy() > 1.)
if keep.sum() == 0:
bbox = paddle.zeros([1, 6], dtype='float32')
if has_mask:
mask = paddle.zeros([1, H, W], dtype='uint8')
else:
label = paddle.to_tensor(label.numpy()[keep]).astype(
'float32').unsqueeze(-1)
score = paddle.to_tensor(score.numpy()[keep]).astype(
'float32').unsqueeze(-1)
bbox = paddle.to_tensor(bbox.numpy()[keep]).astype('float32')
if has_mask:
mask = paddle.to_tensor(mask.numpy()[keep]).astype(
'float32').unsqueeze(1)
mask = paste_mask(mask, bbox, H, W, self.assign_on_cpu)
mask = paddle.cast(mask >= self.binary_thresh, 'uint8')
bbox = paddle.concat([label, score, bbox], axis=-1)
bbox_num[i] = bbox.shape[0]
bbox_pred.append(bbox)
if has_mask:
mask_pred.append(mask)
bbox_pred = paddle.concat(bbox_pred)
mask_pred = paddle.concat(mask_pred) if has_mask else None
if self.assign_on_cpu:
paddle.set_device(device)
if has_mask:
return bbox_pred, bbox_num, mask_pred
else:
return bbox_pred, bbox_num
def paste_mask(masks, boxes, im_h, im_w, assign_on_cpu=False):
"""
Paste the mask prediction to the original image.
"""
x0_int, y0_int = 0, 0
x1_int, y1_int = im_w, im_h
x0, y0, x1, y1 = paddle.split(boxes, 4, axis=1)
N = masks.shape[0]
img_y = paddle.arange(y0_int, y1_int) + 0.5
img_x = paddle.arange(x0_int, x1_int) + 0.5
img_y = (img_y - y0) / (y1 - y0) * 2 - 1
img_x = (img_x - x0) / (x1 - x0) * 2 - 1
# img_x, img_y have shapes (N, w), (N, h)
if assign_on_cpu:
paddle.set_device('cpu')
gx = img_x[:, None, :].expand(
[N, img_y.shape[1], img_x.shape[1]])
gy = img_y[:, :, None].expand(
[N, img_y.shape[1], img_x.shape[1]])
grid = paddle.stack([gx, gy], axis=3)
img_masks = F.grid_sample(masks, grid, align_corners=False)
return img_masks[:, 0]
def multiclass_nms(bboxs, num_classes, match_threshold=0.6, match_metric='iou'):
final_boxes = []
for c in range(num_classes):
idxs = bboxs[:, 0] == c
if np.count_nonzero(idxs) == 0: continue
r = nms(bboxs[idxs, 1:], match_threshold, match_metric)
final_boxes.append(np.concatenate([np.full((r.shape[0], 1), c), r], 1))
return final_boxes
def nms(dets, match_threshold=0.6, match_metric='iou'):
""" Apply NMS to avoid detecting too many overlapping bounding boxes.
Args:
dets: shape [N, 5], [score, x1, y1, x2, y2]
match_metric: 'iou' or 'ios'
match_threshold: overlap thresh for match metric.
"""
if dets.shape[0] == 0:
return dets[[], :]
scores = dets[:, 0]
x1 = dets[:, 1]
y1 = dets[:, 2]
x2 = dets[:, 3]
y2 = dets[:, 4]
areas = (x2 - x1 + 1) * (y2 - y1 + 1)
order = scores.argsort()[::-1]
keep = []
while order.size > 0:
i = order[0]
keep.append(i)
xx1 = np.maximum(x1[i], x1[order[1:]])
yy1 = np.maximum(y1[i], y1[order[1:]])
xx2 = np.minimum(x2[i], x2[order[1:]])
yy2 = np.minimum(y2[i], y2[order[1:]])
w = np.maximum(0.0, xx2 - xx1 + 1)
h = np.maximum(0.0, yy2 - yy1 + 1)
inter = w * h
if match_metric == 'iou':
union = areas[i] + areas[order[1:]] - inter
match_value = inter / union
elif match_metric == 'ios':
smaller = np.minimum(areas[i], areas[order[1:]])
match_value = inter / smaller
else:
raise ValueError()
inds = np.where(match_value < match_threshold)[0]
order = order[inds + 1]
dets = dets[keep, :]
return dets
@register
class DETRBBoxSemiPostProcess(object):
__shared__ = ['num_classes', 'use_focal_loss']
__inject__ = []
def __init__(self,
num_classes=80,
num_top_queries=100,
use_focal_loss=False):
super(DETRBBoxSemiPostProcess, self).__init__()
self.num_classes = num_classes
self.num_top_queries = num_top_queries
self.use_focal_loss = use_focal_loss
def __call__(self, head_out):
"""
Decode the bbox.
Args:
head_out (tuple): bbox_pred, cls_logit and masks of bbox_head output.
im_shape (Tensor): The shape of the input image.
scale_factor (Tensor): The scale factor of the input image.
Returns:
bbox_pred (Tensor): The output prediction with shape [N, 6], including
labels, scores and bboxes. The size of bboxes are corresponding
to the input image, the bboxes may be used in other branch.
bbox_num (Tensor): The number of prediction boxes of each batch with
shape [bs], and is N.
"""
bboxes, logits, masks = head_out
bbox_pred = bboxes
scores = F.softmax(logits, axis=2)
import copy
soft_scores = copy.deepcopy(scores)
scores, index = paddle.topk(scores.max(-1), 300, axis=-1)
batch_ind = paddle.arange(end=scores.shape[0]).unsqueeze(-1).tile(
[1, 300])
index = paddle.stack([batch_ind, index], axis=-1)
labels = paddle.gather_nd(soft_scores.argmax(-1), index).astype('int32')
score_class = paddle.gather_nd(soft_scores, index)
bbox_pred = paddle.gather_nd(bbox_pred, index)
bbox_pred = paddle.concat(
[
labels.unsqueeze(-1).astype('float32'), score_class,
scores.unsqueeze(-1), bbox_pred
],
axis=-1)
bbox_num = paddle.to_tensor(
bbox_pred.shape[1], dtype='int32').tile([bbox_pred.shape[0]])
bbox_pred = bbox_pred.reshape([-1, bbox_pred.shape[-1]])
return bbox_pred, bbox_num