predict.py

import torch
from torch.autograd import Variable as V
import cv2
import os
import numpy as np
from time import time
from network import ResUNet
# from network import DLinkNet34
# from network import HTDLinkNet34
# from network import MHTDLinkNet34


BATCHSIZE_PER_CARD = 4


class TTAFrame:
    def __init__(self, net):
        self.net = net().cuda()
        self.net = torch.nn.DataParallel(self.net, device_ids=range(torch.cuda.device_count()))
        
    def test_one_img_from_path(self, path, evalmode = True):
        if evalmode:
            self.net.eval()
        batchsize = torch.cuda.device_count() * BATCHSIZE_PER_CARD
        if batchsize >= 8:
            return self.test_one_img_from_path_1(path)
        elif batchsize >= 4:
            return self.test_one_img_from_path_2(path)
        elif batchsize >= 2:
            return self.test_one_img_from_path_4(path)

    def test_one_img_from_path_8(self, path):
        img = cv2.imread(path)#.transpose(2,0,1)[None]
        img90 = np.array(np.rot90(img))
        img1 = np.concatenate([img[None],img90[None]])
        img2 = np.array(img1)[:,::-1]
        img3 = np.array(img1)[:,:,::-1]
        img4 = np.array(img2)[:,:,::-1]
        
        img1 = img1.transpose(0,3,1,2)
        img2 = img2.transpose(0,3,1,2)
        img3 = img3.transpose(0,3,1,2)
        img4 = img4.transpose(0,3,1,2)
        
        img1 = V(torch.Tensor(np.array(img1, np.float32)/255.0 * 3.2 -1.6).cuda())
        img2 = V(torch.Tensor(np.array(img2, np.float32)/255.0 * 3.2 -1.6).cuda())
        img3 = V(torch.Tensor(np.array(img3, np.float32)/255.0 * 3.2 -1.6).cuda())
        img4 = V(torch.Tensor(np.array(img4, np.float32)/255.0 * 3.2 -1.6).cuda())
        
        maska = self.net.forward(img1).squeeze().cpu().data.numpy()
        maskb = self.net.forward(img2).squeeze().cpu().data.numpy()
        maskc = self.net.forward(img3).squeeze().cpu().data.numpy()
        maskd = self.net.forward(img4).squeeze().cpu().data.numpy()
        
        mask1 = maska + maskb[:,::-1] + maskc[:,:,::-1] + maskd[:,::-1,::-1]
        mask2 = mask1[0] + np.rot90(mask1[1])[::-1,::-1]
        
        return mask2

    def test_one_img_from_path_4(self, path):
        img = cv2.imread(path)#.transpose(2,0,1)[None]
        img90 = np.array(np.rot90(img))
        img1 = np.concatenate([img[None],img90[None]])
        img2 = np.array(img1)[:,::-1]
        img3 = np.array(img1)[:,:,::-1]
        img4 = np.array(img2)[:,:,::-1]
        
        img1 = img1.transpose(0,3,1,2)
        img2 = img2.transpose(0,3,1,2)
        img3 = img3.transpose(0,3,1,2)
        img4 = img4.transpose(0,3,1,2)
        
        img1 = V(torch.Tensor(np.array(img1, np.float32)/255.0 * 3.2 -1.6).cuda())
        img2 = V(torch.Tensor(np.array(img2, np.float32)/255.0 * 3.2 -1.6).cuda())
        img3 = V(torch.Tensor(np.array(img3, np.float32)/255.0 * 3.2 -1.6).cuda())
        img4 = V(torch.Tensor(np.array(img4, np.float32)/255.0 * 3.2 -1.6).cuda())
        
        maska = self.net.forward(img1).squeeze().cpu().data.numpy()
        maskb = self.net.forward(img2).squeeze().cpu().data.numpy()
        maskc = self.net.forward(img3).squeeze().cpu().data.numpy()
        maskd = self.net.forward(img4).squeeze().cpu().data.numpy()
        
        mask1 = maska + maskb[:,::-1] + maskc[:,:,::-1] + maskd[:,::-1,::-1]
        mask2 = mask1[0] + np.rot90(mask1[1])[::-1,::-1]
        
        return mask2
    
    def test_one_img_from_path_2(self, path):
        img = cv2.imread(path)#.transpose(2,0,1)[None]
        img90 = np.array(np.rot90(img))
        img1 = np.concatenate([img[None],img90[None]])
        img2 = np.array(img1)[:,::-1]
        img3 = np.concatenate([img1,img2])
        img4 = np.array(img3)[:,:,::-1]
        img5 = img3.transpose(0,3,1,2)
        img5 = np.array(img5, np.float32)/255.0 * 3.2 -1.6
        img5 = V(torch.Tensor(img5).contiguous().cuda())
        img6 = img4.transpose(0,3,1,2)
        img6 = np.array(img6, np.float32)/255.0 * 3.2 -1.6
        img6 = V(torch.Tensor(img6).contiguous().cuda())
        
        maska = self.net.forward(img5).squeeze().cpu().data.numpy()#.squeeze(1)
        maskb = self.net.forward(img6).squeeze().cpu().data.numpy()
        
        mask1 = maska + maskb[:,:,::-1]
        mask2 = mask1[:2] + mask1[2:,::-1]
        mask3 = mask2[0] + np.rot90(mask2[1])[::-1,::-1]
        
        return mask3
    
    def test_one_img_from_path_1(self, path):
        img = cv2.imread(path)#.transpose(2,0,1)[None]
        
        img90 = np.array(np.rot90(img))
        img1 = np.concatenate([img[None],img90[None]])
        img2 = np.array(img1)[:,::-1]
        img3 = np.concatenate([img1,img2])
        img4 = np.array(img3)[:,:,::-1]
        img5 = np.concatenate([img3,img4]).transpose(0,3,1,2)
        img5 = np.array(img5, np.float32)/255.0 * 3.2 -1.6
        img5 = V(torch.Tensor(img5).cuda())
        
        mask = self.net.forward(img5).squeeze().cpu().data.numpy()#.squeeze(1)
        mask1 = mask[:4] + mask[4:,:,::-1]
        mask2 = mask1[:2] + mask1[2:,::-1]
        mask3 = mask2[0] + np.rot90(mask2[1])[::-1,::-1]
        
        return mask3

    def load(self, path):
        self.net.load_state_dict(torch.load(path))


source = '../datasets/deepglobe/val_crops/images/'
val = os.listdir(source)
solver = TTAFrame(ResUNet)
solver.load('../weights/essentialfeatures/resunet/best.th')
tic = time()
target = '../results/essentialfeatures/resunet/'
# os.mkdir(target)
for i, name in enumerate(val):
    if i % 10 == 0:
        print(i/10, '    ', '%.2f' % (time()-tic))
    mask = solver.test_one_img_from_path(source+name)
    mask[mask > 4.0] = 255
    mask[mask <= 4.0] = 0
    mask = np.concatenate([mask[:,:,None],mask[:,:,None],mask[:,:,None]],axis=2)
    # cv2.imwrite(target+name[:-7]+'mask.png',mask.astype(np.uint8))
    cv2.imwrite(target + name, mask.astype(np.uint8))