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dataset.py
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dataset.py
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import os
from PIL import Image
import cv2
import torch
from torch.utils import data
from torchvision import transforms
from torchvision.transforms import functional as F
import numbers
import numpy as np
import random
#re_size = (256, 256)
#cr_size = (224, 224)
class ImageDataTrain(data.Dataset):
def __init__(self):
self.sal_root = '/home/liuj/dataset/DUTS/DUTS-TR'
self.sal_source = '/home/liuj/dataset/DUTS/DUTS-TR/train_pair_edge.lst'
with open(self.sal_source, 'r') as f:
self.sal_list = [x.strip() for x in f.readlines()]
self.sal_num = len(self.sal_list)
def __getitem__(self, item):
sal_image = load_image(os.path.join(self.sal_root, self.sal_list[item%self.sal_num].split()[0]))
sal_label = load_sal_label(os.path.join(self.sal_root, self.sal_list[item%self.sal_num].split()[1]))
sal_edge = load_edge_label(os.path.join(self.sal_root, self.sal_list[item%self.sal_num].split()[2]))
sal_image, sal_label, sal_edge = cv_random_flip(sal_image, sal_label, sal_edge)
sal_image = torch.Tensor(sal_image)
sal_label = torch.Tensor(sal_label)
sal_edge = torch.Tensor(sal_edge)
sample = {'sal_image': sal_image, 'sal_label': sal_label, 'sal_edge': sal_edge}
return sample
def __len__(self):
# return max(max(self.edge_num, self.sal_num), self.skel_num)
return self.sal_num
class ImageDataTest(data.Dataset):
def __init__(self, test_mode=1, sal_mode='e'):
if test_mode == 0:
# self.image_root = '/home/liuj/dataset/saliency_test/ECSSD/Imgs/'
# self.image_source = '/home/liuj/dataset/saliency_test/ECSSD/test.lst'
self.image_root = '/home/liuj/dataset/HED-BSDS_PASCAL/HED-BSDS/test/'
self.image_source = '/home/liuj/dataset/HED-BSDS_PASCAL/HED-BSDS/test.lst'
elif test_mode == 1:
if sal_mode == 'e':
self.image_root = '/home/liuj/dataset/saliency_test/ECSSD/Imgs/'
self.image_source = '/home/liuj/dataset/saliency_test/ECSSD/test.lst'
self.test_fold = '/media/ubuntu/disk/Result/saliency/ECSSD/'
elif sal_mode == 'p':
self.image_root = '/home/liuj/dataset/saliency_test/PASCALS/Imgs/'
self.image_source = '/home/liuj/dataset/saliency_test/PASCALS/test.lst'
self.test_fold = '/media/ubuntu/disk/Result/saliency/PASCALS/'
elif sal_mode == 'd':
self.image_root = '/home/liuj/dataset/saliency_test/DUTOMRON/Imgs/'
self.image_source = '/home/liuj/dataset/saliency_test/DUTOMRON/test.lst'
self.test_fold = '/media/ubuntu/disk/Result/saliency/DUTOMRON/'
elif sal_mode == 'h':
self.image_root = '/home/liuj/dataset/saliency_test/HKU-IS/Imgs/'
self.image_source = '/home/liuj/dataset/saliency_test/HKU-IS/test.lst'
self.test_fold = '/media/ubuntu/disk/Result/saliency/HKU-IS/'
elif sal_mode == 's':
self.image_root = '/home/liuj/dataset/saliency_test/SOD/Imgs/'
self.image_source = '/home/liuj/dataset/saliency_test/SOD/test.lst'
self.test_fold = '/media/ubuntu/disk/Result/saliency/SOD/'
elif sal_mode == 'm':
self.image_root = '/home/liuj/dataset/saliency_test/MSRA/Imgs/'
self.image_source = '/home/liuj/dataset/saliency_test/MSRA/test.lst'
elif sal_mode == 'o':
self.image_root = '/home/liuj/dataset/saliency_test/SOC/TestSet/Imgs/'
self.image_source = '/home/liuj/dataset/saliency_test/SOC/TestSet/test.lst'
self.test_fold = '/media/ubuntu/disk/Result/saliency/SOC/'
elif sal_mode == 't':
self.image_root = '/home/liuj/dataset/DUTS/DUTS-TE/DUTS-TE-Image/'
self.image_source = '/home/liuj/dataset/DUTS/DUTS-TE/test.lst'
self.test_fold = '/media/ubuntu/disk/Result/saliency/DUTS/'
elif test_mode == 2:
self.image_root = '/home/liuj/dataset/SK-LARGE/images/test/'
self.image_source = '/home/liuj/dataset/SK-LARGE/test.lst'
with open(self.image_source, 'r') as f:
self.image_list = [x.strip() for x in f.readlines()]
self.image_num = len(self.image_list)
def __getitem__(self, item):
image, im_size = load_image_test(os.path.join(self.image_root, self.image_list[item]))
image = torch.Tensor(image)
return {'image': image, 'name': self.image_list[item%self.image_num], 'size': im_size}
def save_folder(self):
return self.test_fold
def __len__(self):
# return max(max(self.edge_num, self.skel_num), self.sal_num)
return self.image_num
# get the dataloader (Note: without data augmentation, except saliency with random flip)
def get_loader(batch_size, mode='train', num_thread=1, test_mode=0, sal_mode='e'):
shuffle = False
if mode == 'train':
shuffle = True
dataset = ImageDataTrain()
else:
dataset = ImageDataTest(test_mode=test_mode, sal_mode=sal_mode)
data_loader = data.DataLoader(dataset=dataset, batch_size=batch_size, shuffle=shuffle, num_workers=num_thread)
return data_loader, dataset
def load_image(pah):
if not os.path.exists(pah):
print('File Not Exists')
im = cv2.imread(pah)
in_ = np.array(im, dtype=np.float32)
# in_ = cv2.resize(in_, im_sz, interpolation=cv2.INTER_CUBIC)
# in_ = in_[:,:,::-1] # only if use PIL to load image
in_ -= np.array((104.00699, 116.66877, 122.67892))
in_ = in_.transpose((2,0,1))
return in_
def load_image_test(pah):
if not os.path.exists(pah):
print('File Not Exists')
im = cv2.imread(pah)
in_ = np.array(im, dtype=np.float32)
im_size = tuple(in_.shape[:2])
# in_ = cv2.resize(in_, (cr_size[1], cr_size[0]), interpolation=cv2.INTER_LINEAR)
# in_ = in_[:,:,::-1] # only if use PIL to load image
in_ -= np.array((104.00699, 116.66877, 122.67892))
in_ = in_.transpose((2,0,1))
return in_, im_size
def load_edge_label(pah):
"""
pixels > 0.5 -> 1
Load label image as 1 x height x width integer array of label indices.
The leading singleton dimension is required by the loss.
"""
if not os.path.exists(pah):
print('File Not Exists')
im = Image.open(pah)
label = np.array(im, dtype=np.float32)
if len(label.shape) == 3:
label = label[:,:,0]
# label = cv2.resize(label, im_sz, interpolation=cv2.INTER_NEAREST)
label = label / 255.
label[np.where(label > 0.5)] = 1.
label = label[np.newaxis, ...]
return label
def load_skel_label(pah):
"""
pixels > 0 -> 1
Load label image as 1 x height x width integer array of label indices.
The leading singleton dimension is required by the loss.
"""
if not os.path.exists(pah):
print('File Not Exists')
im = Image.open(pah)
label = np.array(im, dtype=np.float32)
if len(label.shape) == 3:
label = label[:,:,0]
# label = cv2.resize(label, im_sz, interpolation=cv2.INTER_NEAREST)
label = label / 255.
label[np.where(label > 0.)] = 1.
label = label[np.newaxis, ...]
return label
def load_sal_label(pah):
"""
Load label image as 1 x height x width integer array of label indices.
The leading singleton dimension is required by the loss.
"""
if not os.path.exists(pah):
print('File Not Exists')
im = Image.open(pah)
label = np.array(im, dtype=np.float32)
if len(label.shape) == 3:
label = label[:,:,0]
# label = cv2.resize(label, im_sz, interpolation=cv2.INTER_NEAREST)
label = label / 255.
label = label[np.newaxis, ...]
return label
def load_sem_label(pah):
"""
Load label image as 1 x height x width integer array of label indices.
The leading singleton dimension is required by the loss.
"""
if not os.path.exists(pah):
print('File Not Exists')
im = Image.open(pah)
label = np.array(im, dtype=np.float32)
if len(label.shape) == 3:
label = label[:,:,0]
# label = cv2.resize(label, im_sz, interpolation=cv2.INTER_NEAREST)
# label = label / 255.
label = label[np.newaxis, ...]
return label
def edge_thres_transform(x, thres):
# y0 = torch.zeros(x.size())
y1 = torch.ones(x.size())
x = torch.where(x >= thres, y1, x)
return x
def skel_thres_transform(x, thres):
y0 = torch.zeros(x.size())
y1 = torch.ones(x.size())
x = torch.where(x > thres, y1, y0)
return x
def cv_random_flip(img, label, edge):
flip_flag = random.randint(0, 1)
if flip_flag == 1:
img = img[:,:,::-1].copy()
label = label[:,:,::-1].copy()
edge = edge[:,:,::-1].copy()
return img, label, edge
def cv_random_crop_flip(img, label, resize_size, crop_size, random_flip=True):
def get_params(img_size, output_size):
h, w = img_size
th, tw = output_size
if w == tw and h == th:
return 0, 0, h, w
i = random.randint(0, h - th)
j = random.randint(0, w - tw)
return i, j, th, tw
if random_flip:
flip_flag = random.randint(0, 1)
img = img.transpose((1,2,0)) # H, W, C
label = label[0,:,:] # H, W
img = cv2.resize(img, (resize_size[1], resize_size[0]), interpolation=cv2.INTER_LINEAR)
label = cv2.resize(label, (resize_size[1], resize_size[0]), interpolation=cv2.INTER_NEAREST)
i, j, h, w = get_params(resize_size, crop_size)
img = img[i:i+h, j:j+w, :].transpose((2,0,1)) # C, H, W
label = label[i:i+h, j:j+w][np.newaxis, ...] # 1, H, W
if flip_flag == 1:
img = img[:,:,::-1].copy()
label = label[:,:,::-1].copy()
return img, label
def random_crop(img, label, size, padding=None, pad_if_needed=True, fill_img=(123, 116, 103), fill_label=0, padding_mode='constant'):
def get_params(img, output_size):
w, h = img.size
th, tw = output_size
if w == tw and h == th:
return 0, 0, h, w
i = random.randint(0, h - th)
j = random.randint(0, w - tw)
return i, j, th, tw
if isinstance(size, numbers.Number):
size = (int(size), int(size))
if padding is not None:
img = F.pad(img, padding, fill_img, padding_mode)
label = F.pad(label, padding, fill_label, padding_mode)
# pad the width if needed
if pad_if_needed and img.size[0] < size[1]:
img = F.pad(img, (int((1 + size[1] - img.size[0]) / 2), 0), fill_img, padding_mode)
label = F.pad(label, (int((1 + size[1] - label.size[0]) / 2), 0), fill_label, padding_mode)
# pad the height if needed
if pad_if_needed and img.size[1] < size[0]:
img = F.pad(img, (0, int((1 + size[0] - img.size[1]) / 2)), fill_img, padding_mode)
label = F.pad(label, (0, int((1 + size[0] - label.size[1]) / 2)), fill_label, padding_mode)
i, j, h, w = get_params(img, size)
return [F.crop(img, i, j, h, w), F.crop(label, i, j, h, w)]