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inference.py
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inference.py
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import argparse
import scipy
import os
import numpy as np
import json
import torch
import torch.nn as nn
import torch.nn.functional as F
from torchvision import transforms
from scipy import ndimage
from tqdm import tqdm
from math import ceil
from glob import glob
from PIL import Image
import dataloaders
import models
from utils.helpers import colorize_mask
def pad_image(img, target_size):
rows_to_pad = max(target_size[0] - img.shape[2], 0)
cols_to_pad = max(target_size[1] - img.shape[3], 0)
padded_img = F.pad(img, (0, cols_to_pad, 0, rows_to_pad), "constant", 0)
return padded_img
def sliding_predict(model, image, num_classes, flip=True):
image_size = image.shape
tile_size = (int(image_size[2]//2.5), int(image_size[3]//2.5))
overlap = 1/3
stride = ceil(tile_size[0] * (1 - overlap))
num_rows = int(ceil((image_size[2] - tile_size[0]) / stride) + 1)
num_cols = int(ceil((image_size[3] - tile_size[1]) / stride) + 1)
total_predictions = np.zeros((num_classes, image_size[2], image_size[3]))
count_predictions = np.zeros((image_size[2], image_size[3]))
tile_counter = 0
for row in range(num_rows):
for col in range(num_cols):
x_min, y_min = int(col * stride), int(row * stride)
x_max = min(x_min + tile_size[1], image_size[3])
y_max = min(y_min + tile_size[0], image_size[2])
img = image[:, :, y_min:y_max, x_min:x_max]
padded_img = pad_image(img, tile_size)
tile_counter += 1
padded_prediction = model(padded_img)
if flip:
fliped_img = padded_img.flip(-1)
fliped_predictions = model(padded_img.flip(-1))
padded_prediction = 0.5 * (fliped_predictions.flip(-1) + padded_prediction)
predictions = padded_prediction[:, :, :img.shape[2], :img.shape[3]]
count_predictions[y_min:y_max, x_min:x_max] += 1
total_predictions[:, y_min:y_max, x_min:x_max] += predictions.data.cpu().numpy().squeeze(0)
total_predictions /= count_predictions
return total_predictions
def multi_scale_predict(model, image, scales, num_classes, device, flip=False):
input_size = (image.size(2), image.size(3))
upsample = nn.Upsample(size=input_size, mode='bilinear', align_corners=True)
total_predictions = np.zeros((num_classes, image.size(2), image.size(3)))
image = image.data.data.cpu().numpy()
for scale in scales:
scaled_img = ndimage.zoom(image, (1.0, 1.0, float(scale), float(scale)), order=1, prefilter=False)
scaled_img = torch.from_numpy(scaled_img).to(device)
scaled_prediction = upsample(model(scaled_img).cpu())
if flip:
fliped_img = scaled_img.flip(-1).to(device)
fliped_predictions = upsample(model(fliped_img).cpu())
scaled_prediction = 0.5 * (fliped_predictions.flip(-1) + scaled_prediction)
total_predictions += scaled_prediction.data.cpu().numpy().squeeze(0)
total_predictions /= len(scales)
return total_predictions
def save_images(image, mask, output_path, image_file, palette):
# Saves the image, the model output and the results after the post processing
w, h = image.size
image_file = os.path.basename(image_file).split('.')[0]
colorized_mask = colorize_mask(mask, palette)
colorized_mask.save(os.path.join(output_path, image_file+'.png'))
# output_im = Image.new('RGB', (w*2, h))
# output_im.paste(image, (0,0))
# output_im.paste(colorized_mask, (w,0))
# output_im.save(os.path.join(output_path, image_file+'_colorized.png'))
# mask_img = Image.fromarray(mask, 'L')
# mask_img.save(os.path.join(output_path, image_file+'.png'))
def main():
args = parse_arguments()
config = json.load(open(args.config))
# Dataset used for training the model
dataset_type = config['train_loader']['type']
assert dataset_type in ['VOC', 'COCO', 'CityScapes', 'ADE20K']
if dataset_type == 'CityScapes':
scales = [0.75, 1.0, 1.25, 1.5, 1.75, 2.0, 2.25]
else:
scales = [0.75, 1.0, 1.25, 1.5, 1.75, 2.0]
loader = getattr(dataloaders, config['train_loader']['type'])(**config['train_loader']['args'])
to_tensor = transforms.ToTensor()
normalize = transforms.Normalize(loader.MEAN, loader.STD)
num_classes = loader.dataset.num_classes
palette = loader.dataset.palette
# Model
model = getattr(models, config['arch']['type'])(num_classes, **config['arch']['args'])
availble_gpus = list(range(torch.cuda.device_count()))
device = torch.device('cuda:0' if len(availble_gpus) > 0 else 'cpu')
checkpoint = torch.load(args.model, map_location=device)
if isinstance(checkpoint, dict) and 'state_dict' in checkpoint.keys():
checkpoint = checkpoint['state_dict']
if 'module' in list(checkpoint.keys())[0] and not isinstance(model, torch.nn.DataParallel):
model = torch.nn.DataParallel(model)
model.load_state_dict(checkpoint)
model.to(device)
model.eval()
if not os.path.exists('outputs'):
os.makedirs('outputs')
image_files = sorted(glob(os.path.join(args.images, f'*.{args.extension}')))
with torch.no_grad():
tbar = tqdm(image_files, ncols=100)
for img_file in tbar:
image = Image.open(img_file).convert('RGB')
input = normalize(to_tensor(image)).unsqueeze(0)
if args.mode == 'multiscale':
prediction = multi_scale_predict(model, input, scales, num_classes, device)
elif args.mode == 'sliding':
prediction = sliding_predict(model, input, num_classes)
else:
prediction = model(input.to(device))
prediction = prediction.squeeze(0).cpu().numpy()
prediction = F.softmax(torch.from_numpy(prediction), dim=0).argmax(0).cpu().numpy()
save_images(image, prediction, args.output, img_file, palette)
def parse_arguments():
parser = argparse.ArgumentParser(description='Inference')
parser.add_argument('-c', '--config', default='VOC',type=str,
help='The config used to train the model')
parser.add_argument('-mo', '--mode', default='multiscale', type=str,
help='Mode used for prediction: either [multiscale, sliding]')
parser.add_argument('-m', '--model', default='model_weights.pth', type=str,
help='Path to the .pth model checkpoint to be used in the prediction')
parser.add_argument('-i', '--images', default=None, type=str,
help='Path to the images to be segmented')
parser.add_argument('-o', '--output', default='outputs', type=str,
help='Output Path')
parser.add_argument('-e', '--extension', default='jpg', type=str,
help='The extension of the images to be segmented')
args = parser.parse_args()
return args
if __name__ == '__main__':
main()