selfdeblur_levin_reproduce.py

# coding: utf-8


from __future__ import print_function
import matplotlib.pyplot as plt
import argparse
import os
import numpy as np
import cv2
import torch
import torch.optim
import glob
from skimage.io import imread
from skimage.io import imsave
import warnings
from tqdm import tqdm
from torch.optim.lr_scheduler import MultiStepLR
from utils.common_utils import *
from SSIM import SSIM

parser = argparse.ArgumentParser()
parser.add_argument("--preprocess", type=bool, default=False, help='run prepare_data or not')
parser.add_argument('--num_iter', type=int, default=2, help='number of epochs of training')
parser.add_argument('--img_size', type=int, default=[256, 256], help='size of each image dimension')
parser.add_argument('--kernel_size', type=int, default=[21, 21], help='size of blur kernel [height, width]')
parser.add_argument('--data_path', type=str, default="imgs/levin/", help='path to blurry image')
parser.add_argument('--save_path', type=str, default="results/levin_reproduce/", help='path to save results')
parser.add_argument('--save_frequency', type=int, default=1, help='frequency to save results')
opt = parser.parse_args()
#print(opt)

#os.environ['CUDA_VISIBLE_DEVICES'] = '1'

torch.backends.cudnn.enabled = True
torch.backends.cudnn.benchmark =True
dtype = torch.cuda.FloatTensor

warnings.filterwarnings("ignore")


files_source = glob.glob(os.path.join(opt.data_path, '*.png'))
files_source.sort()
save_path = opt.save_path
os.makedirs(save_path, exist_ok=True)

# start #image
for f in files_source:
    INPUT = 'noise'
    pad = 'reflection'
    LR = 0.0001
    num_iter = opt.num_iter
    reg_noise_std = 0.001

    path_to_image = f
    imgname = os.path.basename(f)
    imgname = os.path.splitext(imgname)[0]

    if imgname.find('kernel1') != -1:
        opt.kernel_size = [17, 17]
    if imgname.find('kernel2') != -1:
        opt.kernel_size = [15, 15]
    if imgname.find('kernel3') != -1:
        opt.kernel_size = [13, 13]
    if imgname.find('kernel4') != -1:
        opt.kernel_size = [27, 27]
    if imgname.find('kernel5') != -1:
        opt.kernel_size = [11, 11]
    if imgname.find('kernel6') != -1:
        opt.kernel_size = [19, 19]
    if imgname.find('kernel7') != -1:
        opt.kernel_size = [21, 21]
    if imgname.find('kernel8') != -1:
        opt.kernel_size = [21, 21]

    _, imgs = get_image(path_to_image, -1) # load image and convert to np.
    y = np_to_torch(imgs).type(dtype)

    img_size = imgs.shape
    print(imgname)
    # ######################################################################
    padh, padw = opt.kernel_size[0]-1, opt.kernel_size[1]-1
    opt.img_size[0], opt.img_size[1] = img_size[1]+padh, img_size[2]+padw

    '''
    x_net:
    '''
    input_depth = 8

    net_input = get_noise(input_depth, INPUT, (opt.img_size[0], opt.img_size[1])).type(dtype)

    net = torch.load(os.path.join(opt.save_path, "%s_xnet.pth" % imgname))
    net = net.type(dtype)

    n_k = 200
    net_input_kernel = get_noise(n_k, INPUT, (1, 1)).type(dtype)
    net_input_kernel.squeeze_()

    net_kernel = torch.load(os.path.join(opt.save_path, "%s_knet.pth" % imgname))
    net_kernel = net_kernel.type(dtype)

    # Losses
    mse = torch.nn.MSELoss().type(dtype)
    L1 = torch.nn.L1Loss(reduction='sum').type(dtype)
    ssim = SSIM().type(dtype)

    # optimizer
    optimizer = torch.optim.Adam([{'params':net.parameters()},{'params':net_kernel.parameters(),'lr':0e-4}], lr=LR)
    scheduler = MultiStepLR(optimizer, milestones=[700, 800, 900], gamma=0.5)  # learning rates

    # initilization inputs
    net_input_saved = net_input.detach().clone()
    net_input_kernel_saved = net_input_kernel.detach().clone()

    ### start SelfDeblur
    for step in tqdm(range(num_iter)):

        # input regularization
        net_input = net_input_saved + reg_noise_std*torch.zeros(net_input_saved.shape).type_as(net_input_saved.data).normal_()
        # net_input_kernel = net_input_kernel_saved + reg_noise_std*torch.zeros(net_input_kernel_saved.shape).type_as(net_input_kernel_saved.data).normal_()

        # change the learning rate
        scheduler.step(step)
        optimizer.zero_grad()

        # get the network output
        out_x = net(net_input)
        out_k = net_kernel(net_input_kernel)
    
        out_k_m = out_k.view(-1,1,opt.kernel_size[0],opt.kernel_size[1])
        # print(out_k_m)
        out_y = nn.functional.conv2d(out_x, out_k_m, padding=0, bias=None)

        if step < 0:
            total_loss = mse(out_y, y)
        else:
            total_loss = 1 - ssim(out_y, y)  # + tv_loss(out_x) #+ tv_loss2(out_k_m)
        total_loss.backward()
        optimizer.step()

        if (step+1) % opt.save_frequency == 0:
            #print('Iteration %05d' %(step+1))

            save_path = os.path.join(opt.save_path, '%s_x.png'%imgname)
            out_x_np = torch_to_np(out_x)
            out_x_np = out_x_np.squeeze()
            out_x_np = out_x_np[padh//2:padh//2+img_size[1], padw//2:padw//2+img_size[2]]
            #out_x_np = np.uint8(out_x_np*255)
            #cv2.imwrite(save_path, out_x_np)
            imsave(save_path, out_x_np)

            save_path = os.path.join(opt.save_path, '%s_k.png'%imgname)
            out_k_np = torch_to_np(out_k_m)
            out_k_np = out_k_np.squeeze()
            out_k_np /= np.max(out_k_np)
            imsave(save_path, out_k_np)

            #torch.save(net, os.path.join(opt.save_path, "%s_xnet.pth" % imgname))
            #torch.save(net_kernel, os.path.join(opt.save_path, "%s_knet.pth" % imgname))