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test_partseg.py
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"""
Author: Congyue Deng
Contact: [email protected]
Date: April 2021
"""
import argparse
import os
from data_utils.ShapeNetDataLoader import PartNormalDataset
import torch
import logging
import sys
import importlib
from tqdm import tqdm
import numpy as np
from pytorch3d.transforms import RotateAxisAngle, Rotate, random_rotations
BASE_DIR = os.path.dirname(os.path.abspath(__file__))
ROOT_DIR = BASE_DIR
sys.path.append(os.path.join(ROOT_DIR, 'models'))
seg_classes = {'Earphone': [16, 17, 18], 'Motorbike': [30, 31, 32, 33, 34, 35], 'Rocket': [41, 42, 43], 'Car': [8, 9, 10, 11], 'Laptop': [28, 29], 'Cap': [6, 7], 'Skateboard': [44, 45, 46], 'Mug': [36, 37], 'Guitar': [19, 20, 21], 'Bag': [4, 5], 'Lamp': [24, 25, 26, 27], 'Table': [47, 48, 49], 'Airplane': [0, 1, 2, 3], 'Pistol': [38, 39, 40], 'Chair': [12, 13, 14, 15], 'Knife': [22, 23]}
seg_label_to_cat = {} # {0:Airplane, 1:Airplane, ...49:Table}
for cat in seg_classes.keys():
for label in seg_classes[cat]:
seg_label_to_cat[label] = cat
def to_categorical(y, num_classes):
""" 1-hot encodes a tensor """
new_y = torch.eye(num_classes)[y.cpu().data.numpy(),]
if (y.is_cuda):
return new_y.cuda()
return new_y
def parse_args():
'''PARAMETERS'''
parser = argparse.ArgumentParser('PointNet')
parser.add_argument('--batch_size', type=int, default=16, help='Batch size in testing [default: 24]')
parser.add_argument('--model', default='vn_dgcnn_partseg', help='Model name [default: None]',
choices = ['pointnet_cls', 'vn_pointnet_cls', 'dgcnn_cls', 'vn_dgcnn_cls'])
parser.add_argument('--gpu', type=str, default='0', help='Specify gpu device [default: 0]')
parser.add_argument('--num_point', type=int, default=2048, help='Point Number [default: 2048]')
parser.add_argument('--log_dir', type=str, default='vn_dgcnn/aligned', help='Experiment root [default: vn_dgcnn/aligned]')
parser.add_argument('--normal', action='store_true', default=False, help='Whether to use normal information [default: False]')
parser.add_argument('--num_votes', type=int, default=3, help='Aggregate segmentation scores with voting [default: 3]')
parser.add_argument('--rot', type=str, default='aligned', help='Rotation augmentation to input data [default: aligned]',
choices=['aligned', 'z', 'so3'])
parser.add_argument('--pooling', type=str, default='mean', help='VN networks only: pooling method [default: mean]',
choices=['mean', 'max'])
parser.add_argument('--n_knn', default=40, type=int, help='Number of nearest neighbors to use, not applicable to PointNet [default: 20]')
return parser.parse_args()
def main(args):
def log_string(str):
logger.info(str)
print(str)
'''HYPER PARAMETER'''
os.environ["CUDA_VISIBLE_DEVICES"] = args.gpu
experiment_dir = 'log/partseg/' + args.log_dir
'''LOG'''
args = parse_args()
logger = logging.getLogger("Model")
logger.setLevel(logging.INFO)
formatter = logging.Formatter('%(asctime)s - %(name)s - %(levelname)s - %(message)s')
file_handler = logging.FileHandler('%s/eval.txt' % experiment_dir)
file_handler.setLevel(logging.INFO)
file_handler.setFormatter(formatter)
logger.addHandler(file_handler)
log_string('PARAMETER ...')
log_string(args)
root = 'data/shapenetcore_partanno_segmentation_benchmark_v0_normal/'
TEST_DATASET = PartNormalDataset(root = root, npoints=args.num_point, split='test', normal_channel=args.normal)
testDataLoader = torch.utils.data.DataLoader(TEST_DATASET, batch_size=args.batch_size,shuffle=False, num_workers=4)
log_string("The number of test data is: %d" % len(TEST_DATASET))
num_classes = 16
num_part = 50
'''MODEL LOADING'''
MODEL = importlib.import_module(args.model)
classifier = MODEL.get_model(args, num_part, normal_channel=args.normal).cuda()
checkpoint = torch.load(str(experiment_dir) + '/checkpoints/best_model.pth')
classifier.load_state_dict(checkpoint['model_state_dict'])
with torch.no_grad():
test_metrics = {}
total_correct = 0
total_seen = 0
total_seen_class = [0 for _ in range(num_part)]
total_correct_class = [0 for _ in range(num_part)]
shape_ious = {cat: [] for cat in seg_classes.keys()}
seg_label_to_cat = {} # {0:Airplane, 1:Airplane, ...49:Table}
for cat in seg_classes.keys():
for label in seg_classes[cat]:
seg_label_to_cat[label] = cat
for batch_id, (points, label, target) in tqdm(enumerate(testDataLoader), total=len(testDataLoader), smoothing=0.9):
batchsize, num_point, _ = points.size()
cur_batch_size, NUM_POINT, _ = points.size()
if args.rot == 'z':
trot = RotateAxisAngle(angle=torch.rand(points.shape[0])*360, axis="Z", degrees=True)
elif args.rot == 'so3':
trot = Rotate(R=random_rotations(points.shape[0]))
points = trot.transform_points(points)
points, label, target = points.float().cuda(), label.long().cuda(), target.long().cuda()
points = points.transpose(2, 1)
classifier = classifier.eval()
vote_pool = torch.zeros(target.size()[0], target.size()[1], num_part).cuda()
for _ in range(args.num_votes):
seg_pred, _ = classifier(points, to_categorical(label, num_classes))
vote_pool += seg_pred
seg_pred = vote_pool / args.num_votes
cur_pred_val = seg_pred.cpu().data.numpy()
cur_pred_val_logits = cur_pred_val
cur_pred_val = np.zeros((cur_batch_size, NUM_POINT)).astype(np.int32)
target = target.cpu().data.numpy()
for i in range(cur_batch_size):
cat = seg_label_to_cat[target[i, 0]]
logits = cur_pred_val_logits[i, :, :]
cur_pred_val[i, :] = np.argmax(logits[:, seg_classes[cat]], 1) + seg_classes[cat][0]
correct = np.sum(cur_pred_val == target)
total_correct += correct
total_seen += (cur_batch_size * NUM_POINT)
for l in range(num_part):
total_seen_class[l] += np.sum(target == l)
total_correct_class[l] += (np.sum((cur_pred_val == l) & (target == l)))
for i in range(cur_batch_size):
segp = cur_pred_val[i, :]
segl = target[i, :]
cat = seg_label_to_cat[segl[0]]
part_ious = [0.0 for _ in range(len(seg_classes[cat]))]
for l in seg_classes[cat]:
if (np.sum(segl == l) == 0) and (
np.sum(segp == l) == 0): # part is not present, no prediction as well
part_ious[l - seg_classes[cat][0]] = 1.0
else:
part_ious[l - seg_classes[cat][0]] = np.sum((segl == l) & (segp == l)) / float(
np.sum((segl == l) | (segp == l)))
shape_ious[cat].append(np.mean(part_ious))
all_shape_ious = []
for cat in shape_ious.keys():
for iou in shape_ious[cat]:
all_shape_ious.append(iou)
shape_ious[cat] = np.mean(shape_ious[cat])
mean_shape_ious = np.mean(list(shape_ious.values()))
test_metrics['accuracy'] = total_correct / float(total_seen)
test_metrics['class_avg_accuracy'] = np.mean(
np.array(total_correct_class) / np.array(total_seen_class, dtype=np.float))
for cat in sorted(shape_ious.keys()):
log_string('eval mIoU of %s %f' % (cat + ' ' * (14 - len(cat)), shape_ious[cat]))
test_metrics['class_avg_iou'] = mean_shape_ious
test_metrics['inctance_avg_iou'] = np.mean(all_shape_ious)
log_string('Accuracy is: %.5f'%test_metrics['accuracy'])
log_string('Class avg accuracy is: %.5f'%test_metrics['class_avg_accuracy'])
log_string('Class avg mIOU is: %.5f'%test_metrics['class_avg_iou'])
log_string('Inctance avg mIOU is: %.5f'%test_metrics['inctance_avg_iou'])
if __name__ == '__main__':
args = parse_args()
main(args)