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evaluate_semantics_by_distance.py
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evaluate_semantics_by_distance.py
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#!/usr/bin/env python3
# This file is covered by the LICENSE file in the root of this project.
import argparse
import os
import yaml
import sys
import numpy as np
DISTANCES = [(1e-8, 10.0),
(10.0, 20.0),
(20.0, 30.0),
(30.0, 40.0),
(40.0, 50.0)]
# possible splits
splits = ["train", "valid", "test"]
# possible backends
backends = ["numpy", "torch"]
if __name__ == '__main__':
parser = argparse.ArgumentParser("./evaluate_semantics_by_distance.py")
parser.add_argument(
'--dataset', '-d',
type=str,
required=True,
help='Dataset dir. No Default',
)
parser.add_argument(
'--predictions', '-p',
type=str,
required=None,
help='Prediction dir. Same organization as dataset, but predictions in'
'each sequences "prediction" directory. No Default. If no option is set'
' we look for the labels in the same directory as dataset'
)
parser.add_argument(
'--split', '-s',
type=str,
required=False,
default="valid",
help='Split to evaluate on. One of ' +
str(splits) + '. Defaults to %(default)s',
)
parser.add_argument(
'--backend', '-b',
type=str,
required=False,
default="numpy",
help='Backend for evaluation. One of ' +
str(backends) + ' Defaults to %(default)s',
)
parser.add_argument(
'--datacfg', '-dc',
type=str,
required=False,
default="config/semantic-kitti.yaml",
help='Dataset config file. Defaults to %(default)s',
)
parser.add_argument(
'--limit', '-l',
type=int,
required=False,
default=None,
help='Limit to the first "--limit" points of each scan. Useful for'
' evaluating single scan from agregated pointcloud.'
' Defaults to %(default)s',
)
parser.add_argument(
'--codalab',
dest='codalab',
default=False,
action='store_true',
help='Exports "segmentation_scores_distance.txt" for codalab'
'Defaults to %(default)s',
)
FLAGS, unparsed = parser.parse_known_args()
# fill in real predictions dir
if FLAGS.predictions is None:
FLAGS.predictions = FLAGS.dataset
# print summary of what we will do
print("*" * 80)
print("INTERFACE:")
print("Data: ", FLAGS.dataset)
print("Predictions: ", FLAGS.predictions)
print("Backend: ", FLAGS.backend)
print("Split: ", FLAGS.split)
print("Config: ", FLAGS.datacfg)
print("Limit: ", FLAGS.limit)
print("Codalab: ", FLAGS.codalab)
print("*" * 80)
# assert split
assert(FLAGS.split in splits)
# assert backend
assert(FLAGS.backend in backends)
print("Opening data config file %s" % FLAGS.datacfg)
DATA = yaml.safe_load(open(FLAGS.datacfg, 'r'))
# get number of interest classes, and the label mappings
class_strings = DATA["labels"]
class_remap = DATA["learning_map"]
class_inv_remap = DATA["learning_map_inv"]
class_ignore = DATA["learning_ignore"]
nr_classes = len(class_inv_remap)
# make lookup table for mapping
maxkey = max(class_remap.keys())
# +100 hack making lut bigger just in case there are unknown labels
remap_lut = np.zeros((maxkey + 100), dtype=np.int32)
remap_lut[list(class_remap.keys())] = list(class_remap.values())
# print(remap_lut)
# create evaluator
ignore = []
for cl, ign in class_ignore.items():
if ign:
x_cl = int(cl)
ignore.append(x_cl)
print("Ignoring xentropy class ", x_cl, " in IoU evaluation")
# create evaluator
evaluators = []
for i in range(len(DISTANCES)):
if FLAGS.backend == "torch":
from auxiliary.torch_ioueval import iouEval
evaluators.append(iouEval(nr_classes, ignore))
evaluators[i].reset()
elif FLAGS.backend == "numpy":
from auxiliary.np_ioueval import iouEval
evaluators.append(iouEval(nr_classes, ignore))
evaluators[i].reset()
else:
print("Backend for evaluator should be one of ", str(backends))
quit()
# get test set
test_sequences = DATA["split"][FLAGS.split]
# get scan paths
scan_names = []
for sequence in test_sequences:
sequence = '{0:02d}'.format(int(sequence))
label_paths = os.path.join(FLAGS.dataset, "sequences",
str(sequence), "velodyne")
# populate the label names
seq_scan_names = [os.path.join(dp, f) for dp, dn, fn in os.walk(
os.path.expanduser(label_paths)) for f in fn if ".bin" in f]
seq_scan_names.sort()
scan_names.extend(seq_scan_names)
# print(scan_names)
# get label paths
label_names = []
for sequence in test_sequences:
sequence = '{0:02d}'.format(int(sequence))
label_paths = os.path.join(FLAGS.dataset, "sequences",
str(sequence), "labels")
# populate the label names
seq_label_names = [os.path.join(dp, f) for dp, dn, fn in os.walk(
os.path.expanduser(label_paths)) for f in fn if ".label" in f]
seq_label_names.sort()
label_names.extend(seq_label_names)
# print(label_names)
# get predictions paths
pred_names = []
for sequence in test_sequences:
sequence = '{0:02d}'.format(int(sequence))
pred_paths = os.path.join(FLAGS.predictions, "sequences",
sequence, "predictions")
# populate the label names
seq_pred_names = [os.path.join(dp, f) for dp, dn, fn in os.walk(
os.path.expanduser(pred_paths)) for f in fn if ".label" in f]
seq_pred_names.sort()
pred_names.extend(seq_pred_names)
# print(pred_names)
# check that I have the same number of files
print("scans", len(scan_names))
print("labels: ", len(label_names))
print("predictions: ", len(pred_names))
assert(len(label_names) == len(pred_names) and
len(scan_names) == len(label_names))
# open each file, get the tensor, and make the iou comparison
for scan_file, label_file, pred_file in zip(scan_names, label_names, pred_names):
print("evaluating scan ", scan_file)
# open scan
scan = np.fromfile(scan_file, dtype=np.float32)
scan = scan.reshape((-1, 4)) # reshape to matrix
if FLAGS.limit is not None:
scan = scan[:FLAGS.limit] # limit to desired length
depth = np.linalg.norm(scan[:, :3], 2, axis=1) # get depth to filter by distance
# open label
label = np.fromfile(label_file, dtype=np.int32)
label = label.reshape((-1)) # reshape to vector
label = label & 0xFFFF # get lower half for semantics
if FLAGS.limit is not None:
label = label[:FLAGS.limit] # limit to desired length
label = remap_lut[label] # remap to xentropy format
# open prediction
pred = np.fromfile(pred_file, dtype=np.int32)
pred = pred.reshape((-1)) # reshape to vector
pred = pred & 0xFFFF # get lower half for semantics
if FLAGS.limit is not None:
pred = pred[:FLAGS.limit] # limit to desired length
pred = remap_lut[pred] # remap to xentropy format
# evaluate for all distances
for idx in range(len(DISTANCES)):
# select by range
lrange = DISTANCES[idx][0]
hrange = DISTANCES[idx][1]
mask = np.logical_and(depth > lrange, depth < hrange)
# mask by distance
# mask_depth = depth[mask]
# print("mask range, ", mask_depth.max(), mask_depth.min())
mask_label = label[mask]
mask_pred = pred[mask]
# add single scan to evaluation
evaluators[idx].addBatch(mask_pred, mask_label)
# print for all ranges
print("*" * 80)
for idx in range(len(DISTANCES)):
# when I am done, print the evaluation
m_accuracy = evaluators[idx].getacc()
m_jaccard, class_jaccard = evaluators[idx].getIoU()
# print for spreadsheet
sys.stdout.write('range {lrange}m to {hrange}m,'.format(lrange=DISTANCES[idx][0],
hrange=DISTANCES[idx][1]))
for i, jacc in enumerate(class_jaccard):
if i not in ignore:
sys.stdout.write('{jacc:.3f}'.format(jacc=jacc.item()))
sys.stdout.write(",")
sys.stdout.write('{jacc:.3f}'.format(jacc=m_jaccard.item()))
sys.stdout.write(",")
sys.stdout.write('{acc:.3f}'.format(acc=m_accuracy.item()))
sys.stdout.write('\n')
sys.stdout.flush()
# if codalab is necessary, then do it
if FLAGS.codalab:
results = {}
for idx in range(len(DISTANCES)):
# make string for distance
d_str = str(DISTANCES[idx][-1])+"m_"
# get values for this distance range
m_accuracy = evaluators[idx].getacc()
m_jaccard, class_jaccard = evaluators[idx].getIoU()
# put in dictionary
results[d_str+"accuracy_mean"] = float(m_accuracy)
results[d_str+"iou_mean"] = float(m_jaccard)
for i, jacc in enumerate(class_jaccard):
if i not in ignore:
results[d_str+"iou_"+class_strings[class_inv_remap[i]]] = float(jacc)
# save to file
with open('segmentation_scores_distance.txt', 'w') as yaml_file:
yaml.dump(results, yaml_file, default_flow_style=False)