test_AMP_Net_BM.py

# This file is used to test
import torch
import os
from torch.nn import Module
from torch import nn
from scipy import io
import numpy as np
import glob
from utils import *
from skimage.io import imsave


class Denoiser(Module):
    def __init__(self):
        super().__init__()
        self.D = nn.Sequential(nn.Conv2d(1, 32, 3, padding=1),

                               nn.ReLU(),
                               nn.Conv2d(32, 32, 3, padding=1),

                               nn.ReLU(),
                               nn.Conv2d(32, 32, 3, padding=1),

                               nn.ReLU(),
                               nn.Conv2d(32, 1, 3, padding=1,bias=False))

    def forward(self, inputs):
        inputs = torch.unsqueeze(torch.reshape(torch.transpose(inputs,0,1),[-1,33,33]),dim=1)
        output = self.D(inputs)
        # output=inputs-output
        output = torch.transpose(torch.reshape(torch.squeeze(output),[-1,33*33]),0,1)
        return output

class Deblocker(Module):
    def __init__(self):
        super().__init__()
        self.D = nn.Sequential(nn.Conv2d(1, 32, 3, padding=1),

                               nn.ReLU(),
                               nn.Conv2d(32, 32, 3, padding=1),

                               nn.ReLU(),
                               nn.Conv2d(32, 32, 3, padding=1),

                               nn.ReLU(),
                               nn.Conv2d(32, 1, 3, padding=1,bias=False))

    def forward(self, inputs):
        inputs = torch.unsqueeze(inputs,dim=1)
        output = self.D(inputs)
        output = torch.squeeze(output,dim=1)
        return output

class AMP_net_Deblock(Module):
    def __init__(self,layer_num, A):
        super().__init__()
        self.layer_num = layer_num
        self.denoisers = []
        self.deblocks = []
        self.steps = []
        self.register_parameter("A",nn.Parameter(torch.from_numpy(A).float(),requires_grad=True))
        self.register_parameter("Q", nn.Parameter(torch.from_numpy(np.transpose(A)).float(), requires_grad=True))
        for n in range(layer_num):
            self.denoisers.append(Denoiser())
            self.deblocks.append(Deblocker())
            self.register_parameter("step_" + str(n + 1), nn.Parameter(torch.tensor(1.0)))
            self.steps.append(eval("self.step_" + str(n + 1)))
        for n,denoiser in enumerate(self.denoisers):
            self.add_module("denoiser_"+str(n+1),denoiser)
        for n,deblock in enumerate(self.deblocks):
            self.add_module("deblock_"+str(n+1),deblock)

    def forward(self, inputs, output_layers):
        H = int(inputs.shape[2]/33)
        L = int(inputs.shape[3]/33)
        S = inputs.shape[0]

        y = self.sampling(inputs)
        X = torch.matmul(self.Q,y)
        for n in range(output_layers):
            step = self.steps[n]
            denoiser = self.denoisers[n]
            deblocker = self.deblocks[n]

            z = self.block1(X, y,step)
            noise = denoiser(X)
            X = z - torch.matmul(
                (step * torch.matmul(torch.transpose(self.A,0,1), self.A)) - torch.eye(33 * 33).float().cuda(), noise)

            X = self.together(X,S,H,L)

            X = X - deblocker(X)
            X = torch.cat(torch.split(X, split_size_or_sections=33, dim=1), dim=0)
            X = torch.cat(torch.split(X, split_size_or_sections=33, dim=2), dim=0)
            X = torch.transpose(torch.reshape(X, [-1, 33 * 33]), 0, 1)

        X = self.together(X, S, H, L)
        return torch.unsqueeze(X, dim=1)


    def sampling(self,inputs):
        inputs = torch.squeeze(inputs,dim=1)
        inputs = torch.cat(torch.split(inputs, split_size_or_sections=33, dim=1), dim=0)
        inputs = torch.cat(torch.split(inputs, split_size_or_sections=33, dim=2), dim=0)
        inputs = torch.transpose(torch.reshape(inputs, [-1, 33*33]),0,1)
        outputs = torch.matmul(self.A, inputs)
        return outputs

    def block1(self,X,y,step):
        outputs = torch.matmul(torch.transpose(self.A,0,1),y-torch.matmul(self.A,X))
        outputs = step * outputs + X
        return outputs

    def together(self,inputs,S,H,L):
        inputs = torch.reshape(torch.transpose(inputs,0,1),[-1,33,33])
        inputs = torch.cat(torch.split(inputs, split_size_or_sections=H*S, dim=0), dim=2)
        inputs = torch.cat(torch.split(inputs, split_size_or_sections=S, dim=0), dim=1)
        return inputs


def load_sampling_matrix(CS_ratio):
    path = "dataset/sampling_matrix"
    data = io.loadmat(os.path.join(path, str(CS_ratio) + '.mat'))['sampling_matrix']
    return data


def get_val_result(model, num, CS_ratio, sub_save_path, is_cuda=True):

    with torch.no_grad():
        test_set_path = "dataset/Set11"
        # test_set_path = "dataset/bsds500/test"
        test_set_path = glob.glob(test_set_path + '/*.tif')
        ImgNum = len(test_set_path)  
        PSNR_All = np.zeros([1, ImgNum], dtype=np.float32)
        SSIM_All = np.zeros([1, ImgNum], dtype=np.float32)

        for img_no in range(ImgNum):

            imgName = test_set_path[img_no] 
            # print(img_no)
            [Iorg, row, col, Ipad, row_new, col_new] = imread_CS_py(imgName)
            Icol = img2col_py(Ipad, 33) / 255.0  
            Ipad /= 255.0
            if is_cuda:
                inputs = Variable(torch.from_numpy(Ipad.astype('float32')).cuda())
            else:
                inputs = Variable(torch.from_numpy(Ipad.astype('float32')))

            inputs = torch.unsqueeze(inputs, dim=0)
            inputs = torch.unsqueeze(inputs, dim=0)
            outputs= model(inputs, num)
            output = torch.squeeze(outputs)
            if is_cuda:
                output = output.cpu().data.numpy()
            else:
                output = output.data.numpy()
            images_recovered = output[0:row, 0:col]
            images_recovered = images_recovered * 255
            aaa = images_recovered.astype(int)
            bbb = aaa < 0
            aaa[bbb] = 0
            bbb = aaa > 255
            aaa[bbb] = 255
            rec_PSNR = psnr(aaa, Iorg)  
            PSNR_All[0, img_no] = rec_PSNR
            rec_SSIM = compute_ssim(aaa, Iorg)  
            SSIM_All[0, img_no] = rec_SSIM
			imgname_for_save = (imgName.split('/')[-1]).split('.')[0]
			imsave(os.path.join(save_path,imgname_for_save+'_'+str(rec_PSNR)+'_'+str(rec_SSIM)+'.jpg'),aaa)

        return np.mean(PSNR_All), np.mean(SSIM_All)


if __name__ == "__main__":
    model_name = "AMP_net_K_BM"
    CS_ratios = [50,40,30,25,10,4,1]
    Phases = [9]
	save_path = "./results/generated_images"
	
    for phase in Phases:
        for CS_ratio in CS_ratios:
            if not os.path.exists(save_path):
				os.mkdir(save_path)
			sub_save_path = os.path.join(results_saving_path, str(CS_ratio))
			if not os.path.exists(sub_save_path):
				os.mkdir(sub_save_path)
			sub_save_path = os.path.join(results_saving_path, str(phase))
			if not os.path.exists(sub_save_path):
				os.mkdir(sub_save_path)
            path = os.path.join("results",model_name,str(CS_ratio),str(phase),"best_model.pkl")

            A = load_sampling_matrix(CS_ratio)
            H = torch.from_numpy(np.matmul(np.transpose(A), A) - np.eye(33 * 33)).float()
            Q = np.transpose(A)
            model = AMP_net_Deblock(phase,A)
            model.cuda()
            model.load_state_dict(torch.load(path))
            print("Start")
            one_psnr, one_ssim = get_val_result(model, phase,CS_ratio, sub_save_path, is_cuda=True)  # test AMP_net

            print(one_psnr, "dB", one_ssim)