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eval.py
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eval.py
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# System libs
import os
import datetime
import argparse
from distutils.version import LooseVersion
# Numerical libs
import numpy as np
import torch
import torch.nn as nn
from scipy.io import loadmat
# Our libs
from dataset import ValDataset
from models import ModelBuilder, SegmentationModule
from utils import AverageMeter, colorEncode, accuracy, intersectionAndUnion
from lib.nn import user_scattered_collate, async_copy_to
from lib.utils import as_numpy, mark_volatile
import lib.utils.data as torchdata
import cv2
def visualize_result(data, preds, args):
colors = loadmat('data/color150.mat')['colors']
(img, seg, info) = data
# segmentation
seg_color = colorEncode(seg, colors)
# prediction
pred_color = colorEncode(preds, colors)
# aggregate images and save
im_vis = np.concatenate((img, seg_color, pred_color),
axis=1).astype(np.uint8)
img_name = info.split('/')[-1]
cv2.imwrite(os.path.join(args.result,
img_name.replace('.jpg', '.png')), im_vis)
def evaluate(segmentation_module, loader, args):
acc_meter = AverageMeter()
intersection_meter = AverageMeter()
union_meter = AverageMeter()
segmentation_module.eval()
for i, batch_data in enumerate(loader):
# process data
batch_data = batch_data[0]
seg_label = as_numpy(batch_data['seg_label'][0])
img_resized_list = batch_data['img_data']
with torch.no_grad():
segSize = (seg_label.shape[0], seg_label.shape[1])
pred = torch.zeros(1, args.num_class, segSize[0], segSize[1])
for img in img_resized_list:
feed_dict = batch_data.copy()
feed_dict['img_data'] = img
del feed_dict['img_ori']
del feed_dict['info']
feed_dict = async_copy_to(feed_dict, args.gpu_id)
# forward pass
pred_tmp = segmentation_module(feed_dict, segSize=segSize)
pred = pred + pred_tmp.cpu() / len(args.imgSize)
_, preds = torch.max(pred.data.cpu(), dim=1)
preds = as_numpy(preds.squeeze(0))
# calculate accuracy
acc, pix = accuracy(preds, seg_label)
intersection, union = intersectionAndUnion(preds, seg_label, args.num_class)
acc_meter.update(acc, pix)
intersection_meter.update(intersection)
union_meter.update(union)
print('[{}] iter {}, accuracy: {}'
.format(datetime.datetime.now().strftime("%Y-%m-%d %H:%M:%S"),
i, acc))
# visualization
if args.visualize:
visualize_result(
(batch_data['img_ori'], seg_label, batch_data['info']),
preds, args)
iou = intersection_meter.sum / (union_meter.sum + 1e-10)
for i, _iou in enumerate(iou):
print('class [{}], IoU: {}'.format(i, _iou))
print('[Eval Summary]:')
print('Mean IoU: {:.4}, Accuracy: {:.2f}%'
.format(iou.mean(), acc_meter.average()*100))
def main(args):
torch.cuda.set_device(args.gpu_id)
# Network Builders
builder = ModelBuilder()
net_encoder = builder.build_encoder(
arch=args.arch_encoder,
fc_dim=args.fc_dim,
weights=args.weights_encoder)
net_decoder = builder.build_decoder(
arch=args.arch_decoder,
fc_dim=args.fc_dim,
num_class=args.num_class,
weights=args.weights_decoder,
use_softmax=True)
crit = nn.NLLLoss(ignore_index=-1)
segmentation_module = SegmentationModule(net_encoder, net_decoder, crit)
# Dataset and Loader
dataset_val = ValDataset(
args.list_val, args, max_sample=args.num_val)
loader_val = torchdata.DataLoader(
dataset_val,
batch_size=args.batch_size,
shuffle=False,
collate_fn=user_scattered_collate,
num_workers=5,
drop_last=True)
segmentation_module.cuda()
# Main loop
evaluate(segmentation_module, loader_val, args)
print('Evaluation Done!')
if __name__ == '__main__':
assert LooseVersion(torch.__version__) >= LooseVersion('0.4.0'), \
'PyTorch>=0.4.0 is required'
parser = argparse.ArgumentParser()
# Model related arguments
parser.add_argument('--id', required=True,
help="a name for identifying the model to load")
parser.add_argument('--suffix', default='_epoch_20.pth',
help="which snapshot to load")
parser.add_argument('--arch_encoder', default='resnet50_dilated8',
help="architecture of net_encoder")
parser.add_argument('--arch_decoder', default='ppm_bilinear_deepsup',
help="architecture of net_decoder")
parser.add_argument('--fc_dim', default=2048, type=int,
help='number of features between encoder and decoder')
# Path related arguments
parser.add_argument('--list_val',
default='./data/validation.odgt')
parser.add_argument('--root_dataset',
default='./data/')
# Data related arguments
parser.add_argument('--num_val', default=-1, type=int,
help='number of images to evalutate')
parser.add_argument('--num_class', default=150, type=int,
help='number of classes')
parser.add_argument('--batch_size', default=1, type=int,
help='batchsize. current only supports 1')
parser.add_argument('--imgSize', default=[450], nargs='+', type=int,
help='list of input image sizes.'
'for multiscale testing, e.g. 300 400 500 600')
parser.add_argument('--imgMaxSize', default=1000, type=int,
help='maximum input image size of long edge')
parser.add_argument('--padding_constant', default=8, type=int,
help='maxmimum downsampling rate of the network')
# Misc arguments
parser.add_argument('--ckpt', default='./ckpt',
help='folder to output checkpoints')
parser.add_argument('--visualize', action='store_true',
help='output visualization?')
parser.add_argument('--result', default='./result',
help='folder to output visualization results')
parser.add_argument('--gpu_id', default=0, type=int,
help='gpu_id for evaluation')
args = parser.parse_args()
print(args)
# absolute paths of model weights
args.weights_encoder = os.path.join(args.ckpt, args.id,
'encoder' + args.suffix)
args.weights_decoder = os.path.join(args.ckpt, args.id,
'decoder' + args.suffix)
assert os.path.exists(args.weights_encoder) and \
os.path.exists(args.weights_encoder), 'checkpoint does not exitst!'
args.result = os.path.join(args.result, args.id)
if not os.path.isdir(args.result):
os.makedirs(args.result)
main(args)