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test_utils.py
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test_utils.py
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from utils import get_filtered_lidar, project_velo2rgb, draw_rgb_projections
from config import config as cfg
from data.kitti import KittiDataset
import torch.utils.data as data
from nms.pth_nms import pth_nms
import torch.nn.functional as F
import numpy as np
import torch.backends.cudnn
import cv2
import matplotlib.pyplot as plt
torch.backends.cudnn.benchmark=True
torch.backends.cudnn.enabled=True
def delta_to_boxes3d(deltas, anchors):
# Input:
# deltas: (N, w, l, 14)
# feature_map_shape: (w, l)
# anchors: (w, l, 2, 7)
# Ouput:
# boxes3d: (N, w*l*2, 7)
N = deltas.shape[0]
deltas = deltas.view(N, -1, 7)
anchors = torch.FloatTensor(anchors)
boxes3d = torch.zeros_like(deltas)
if deltas.is_cuda:
anchors = anchors.cuda()
boxes3d = boxes3d.cuda()
anchors_reshaped = anchors.view(-1, 7)
anchors_d = torch.sqrt(anchors_reshaped[:, 4]**2 + anchors_reshaped[:, 5]**2)
anchors_d = anchors_d.repeat(N, 2, 1).transpose(1,2)
anchors_reshaped = anchors_reshaped.repeat(N, 1, 1)
boxes3d[..., [0, 1]] = torch.mul(deltas[..., [0, 1]], anchors_d) + anchors_reshaped[..., [0, 1]]
boxes3d[..., [2]] = torch.mul(deltas[..., [2]], anchors_reshaped[...,[3]]) + anchors_reshaped[..., [2]]
boxes3d[..., [3, 4, 5]] = torch.exp(
deltas[..., [3, 4, 5]]) * anchors_reshaped[..., [3, 4, 5]]
boxes3d[..., 6] = deltas[..., 6] + anchors_reshaped[..., 6]
return boxes3d
def detection_collate(batch):
lidars = []
images = []
calibs = []
targets = []
pos_equal_ones=[]
ids = []
for i, sample in enumerate(batch):
lidars.append(sample[0])
images.append(sample[1])
calibs.append(sample[2])
targets.append(sample[3])
pos_equal_ones.append(sample[4])
ids.append(sample[5])
return lidars,images,calibs,\
torch.cuda.FloatTensor(np.array(targets)), \
torch.cuda.FloatTensor(np.array(pos_equal_ones)),\
ids
def box3d_center_to_corner_batch(boxes_center):
# (N, 7) -> (N, 8, 3)
N = boxes_center.shape[0]
ret = torch.zeros((N, 8, 3))
if boxes_center.is_cuda:
ret = ret.cuda()
for i in range(N):
box = boxes_center[i]
translation = box[0:3]
size = box[3:6]
rotation = [0, 0, box[-1]]
h, w, l = size[0], size[1], size[2]
trackletBox = torch.FloatTensor([ # in velodyne coordinates around zero point and without orientation yet
[-l / 2, -l / 2, l / 2, l / 2, -l / 2, -l / 2, l / 2, l / 2], \
[w / 2, -w / 2, -w / 2, w / 2, w / 2, -w / 2, -w / 2, w / 2], \
[0, 0, 0, 0, h, h, h, h]])
if boxes_center.is_cuda:
trackletBox = trackletBox.cuda()
# re-create 3D bounding box in velodyne coordinate system
yaw = rotation[2]
rotMat = torch.FloatTensor([
[np.cos(yaw), -np.sin(yaw), 0.0],
[np.sin(yaw), np.cos(yaw), 0.0],
[0.0, 0.0, 1.0]])
if boxes_center.is_cuda:
rotMat = rotMat.cuda()
cornerPosInVelo = torch.mm(rotMat, trackletBox) + translation.repeat(8, 1).t()
box3d = cornerPosInVelo.transpose(0,1)
ret[i] = box3d
return ret
def box3d_corner_to_top_batch(boxes3d, use_min_rect=True):
# [N,8,3] -> [N,4,2] -> [N,8]
box3d_top=[]
num =len(boxes3d)
for n in range(num):
b = boxes3d[n]
x0 = b[0,0]
y0 = b[0,1]
x1 = b[1,0]
y1 = b[1,1]
x2 = b[2,0]
y2 = b[2,1]
x3 = b[3,0]
y3 = b[3,1]
box3d_top.append([x0,y0,x1,y1,x2,y2,x3,y3])
if use_min_rect:
box8pts = torch.FloatTensor(np.array(box3d_top))
if boxes3d.is_cuda:
box8pts = box8pts.cuda()
min_rects = torch.zeros((box8pts.shape[0], 4))
if boxes3d.is_cuda:
min_rects = min_rects.cuda()
# calculate minimum rectangle
min_rects[:, 0] = torch.min(box8pts[:, [0, 2, 4, 6]], dim=1)[0]
min_rects[:, 1] = torch.min(box8pts[:, [1, 3, 5, 7]], dim=1)[0]
min_rects[:, 2] = torch.max(box8pts[:, [0, 2, 4, 6]], dim=1)[0]
min_rects[:, 3] = torch.max(box8pts[:, [1, 3, 5, 7]], dim=1)[0]
return min_rects
return box3d_top
def draw_boxes(reg, prob, images, calibs, ids, tag):
prob = prob.view(cfg.N, -1)
batch_boxes3d = delta_to_boxes3d(reg, cfg.anchors)
mask = torch.gt(prob, cfg.score_threshold)
mask_reg = mask.unsqueeze(2).repeat(1, 1, 7)
for batch_id in range(cfg.N):
boxes3d = torch.masked_select(batch_boxes3d[batch_id], mask_reg[batch_id]).view(-1, 7)
scores = torch.masked_select(prob[batch_id], mask[batch_id])
image = images[batch_id]
calib = calibs[batch_id]
id = ids[batch_id]
if len(boxes3d) != 0:
boxes3d_corner = box3d_center_to_corner_batch(boxes3d)
boxes2d = box3d_corner_to_top_batch(boxes3d_corner)
boxes2d_score = torch.cat((boxes2d, scores.unsqueeze(1)), dim=1)
# NMS
keep = pth_nms(boxes2d_score, cfg.nms_threshold)
boxes3d_corner_keep = boxes3d_corner[keep]
print("No. %d objects detected" % len(boxes3d_corner_keep))
rgb_2D = project_velo2rgb(boxes3d_corner_keep, calib)
img_with_box = draw_rgb_projections(image, rgb_2D, color=(0, 0, 255), thickness=1)
cv2.imwrite('results/%s_%s.png' % (id,tag), img_with_box)
else:
cv2.imwrite('results/%s_%s.png' % (id,tag), image)
print("No objects detected")