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pred_CD.py
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pred_CD.py
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import os
import math
import time
import argparse
import numpy as np
import torch.autograd
from skimage import io
from torch.nn import functional as F
from torchvision.transforms import functional as transF
from torch.utils.data import DataLoader
from collections import OrderedDict
################## Load Model and Data ##################
from models.SAM_CD import SAM_CD as Net
NET_NAME = 'SAM_CD'
from datasets import Levir_CD as Data
DATA_NAME = 'Levir_CD'
#from datasets.WHU_CD import WHU_CD as Data
#DATA_NAME = 'WHU_CD'
################## Load Model and Data ##################
class PredOptions():
def __init__(self):
"""Reset the class; indicates the class hasn't been initailized"""
self.initialized = False
def initialize(self, parser):
working_path = os.path.dirname(os.path.abspath(__file__))
parser.add_argument('--crop_size', required=False, default=(1024, 1024), help='cropping size')
parser.add_argument('--TTA', required=False, default=True, help='Test time augmentation')
parser.add_argument('--test_dir', required=False, default=os.path.join(Data.root, 'test'), help='directory to test images')
parser.add_argument('--pred_dir', required=False, default=os.path.join(working_path, 'eval', DATA_NAME, NET_NAME), help='directory to output masks')
parser.add_argument('--chkpt_path', required=False, default=os.path.join(working_path, 'checkpoints', DATA_NAME, 'xxx.pth') )
parser.add_argument('--dev_id', required=False, default=0, help='Device id')
self.initialized = True
return parser
def gather_options(self):
if not self.initialized: # check if it has been initialized
parser = argparse.ArgumentParser(formatter_class=argparse.ArgumentDefaultsHelpFormatter)
parser = self.initialize(parser)
self.parser = parser
return parser.parse_args()
def parse(self):
self.opt = self.gather_options()
return self.opt
def create_crops(imgA, imgB, size):
imgA_crops = []
imgB_crops = []
h = imgA.shape[0]
w = imgA.shape[1]
c_h = size[0]
c_w = size[1]
if h < c_h or w < c_w:
print("Cannot crop area {} from image with size ({}, {})".format(str(size), h, w))
return 1
h_rate = h/c_h
w_rate = w/c_w
rows = math.ceil(h_rate)
cols = math.ceil(w_rate)
stride_h = int((c_h*rows-h)/(rows-1))
stride_w = int((c_w*cols-w)/(cols-1))
for j in range(rows):
for i in range(cols):
s_h = int(j*c_h - j*stride_h)
if(j==(rows-1)): s_h = h - c_h
e_h = s_h + c_h
s_w = int(i*c_w - i*stride_w)
if(i==(cols-1)): s_w = w - c_w
e_w = s_w + c_w
imgA_crops.append(imgA[s_h:e_h, s_w:e_w, :])
imgB_crops.append(imgB[s_h:e_h, s_w:e_w, :])
print('Sliding crop finished. %d images created.' %len(imgA_crops))
return imgA_crops, imgB_crops
def stitch_pred(patch_list, size_stitch):
H, W = size_stitch
h, w = patch_list[0].shape
stitch_rows = math.ceil(H/h)
stitch_cols = math.ceil(W/w)
assert stitch_rows*stitch_cols == len(patch_list), "Stitching patch number mismatch."
h_overlap = int((h*stitch_rows-H)/(stitch_rows-1))
w_overlap = int((w*stitch_cols-W)/(stitch_cols-1))
for r in range(stitch_rows):
crop_t = math.ceil(h_overlap/2)
crop_b = h_overlap-crop_t
crop_l = math.ceil(w_overlap/2)
crop_r = w_overlap-crop_l
if r == 0: crop_t=0
if r == stitch_rows-1:
crop_b=0
crop_t = stitched_img.shape[0]-H
stitched_r = patch_list[r*stitch_cols][crop_t:h-crop_b, 0:w-crop_r]
for c in range(1,stitch_cols):
if c == stitch_cols-1:
crop_r = 0
crop_l = stitched_r.shape[1]-W
patch_croped = patch_list[r*stitch_cols+c][crop_t:h-crop_b, crop_l:w-crop_r]
stitched_r = np.concatenate((stitched_r, patch_croped), axis=1)
if r==0: stitched_img = stitched_r
else: stitched_img = np.concatenate((stitched_img, stitched_r), axis=0)
#sH, sW = stitched_img.shape
#if sH>H or sW>W: stitched_img = stitched_img[:H, :W]
print('Pred Stitched (%d, %d)'%(stitched_img.shape[0], stitched_img.shape[1]))
return stitched_img
def compare_models(model_1, model_2):
models_differ = 0
for key_item_1, key_item_2 in zip(model_1.state_dict().items(), model_2.state_dict().items()):
if torch.equal(key_item_1[1], key_item_2[1]):
pass
else:
models_differ += 1
if (key_item_1[0] == key_item_2[0]):
print('Mismtach found at', key_item_1[0])
else:
raise Exception
if models_differ == 0:
print('Models match perfectly! :)')
def main():
begin_time = time.time()
opt = PredOptions().parse()
net = Net()
state_dict = torch.load(opt.chkpt_path, map_location="cpu")
new_state_dict = OrderedDict()
for k, v in state_dict.items():
# name = k[7:] # remove `module.`
if 'module.' in k:
new_state_dict[k[7:]] = v
else:
new_state_dict = state_dict
net.load_state_dict(new_state_dict)
net.to(torch.device('cuda', int(opt.dev_id))).eval()
predict(net, opt)
time_use = time.time() - begin_time
print('Total time: %.2fs'%time_use)
def predict(net, opt):
if not os.path.exists(opt.pred_dir): os.makedirs(opt.pred_dir)
imgA_dir = os.path.join(opt.test_dir, 'A')
imgB_dir = os.path.join(opt.test_dir, 'B')
data_list = os.listdir(imgA_dir)
valid_list = []
for it in data_list:
if (it[-4:]=='.png'): valid_list.append(it)
for it in valid_list:
imgA_path = os.path.join(imgA_dir, it)
imgB_path = os.path.join(imgB_dir, it)
imgA = io.imread(imgA_path)
imgB = io.imread(imgB_path)
imgA = Data.normalize_image(imgA)
imgB = Data.normalize_image(imgB)
with torch.no_grad():
if imgA.shape[0]>opt.crop_size[0] or imgA.shape[1]>opt.crop_size[1]:
imgA_crops, imgB_crops = create_crops(imgA, imgB, opt.crop_size)
crop_num = len(imgA_crops)
print(it+' (%d, %d, %d) cropped into %d patches.'%(imgA.shape[0], imgA.shape[1], imgA.shape[2], crop_num))
preds = []
for idx in range(crop_num):
cropA = imgA_crops[idx]
cropB = imgB_crops[idx]
tensorA = transF.to_tensor(cropA).unsqueeze(0).to(torch.device('cuda', int(opt.dev_id))).float()
tensorB = transF.to_tensor(cropB).unsqueeze(0).to(torch.device('cuda', int(opt.dev_id))).float()
output, _, _ = net(tensorA, tensorB)
output = F.sigmoid(output)
if opt.TTA:
tensorA_v = torch.flip(tensorA, [2])
tensorB_v = torch.flip(tensorB, [2])
output_v, _, _ = net(tensorA_v, tensorB_v)
output_v = torch.flip(output_v, [2])
output += F.sigmoid(output_v)
tensorA_h = torch.flip(tensorA, [3])
tensorB_h = torch.flip(tensorB, [3])
output_h, _, _ = net(tensorA_h, tensorB_h)
output_h = torch.flip(output_h, [3])
output += F.sigmoid(output_h)
tensorA_hv = torch.flip(tensorA, [2,3])
tensorB_hv = torch.flip(tensorB, [2,3])
output_hv, _, _ = net(tensorA_hv, tensorB_hv)
output_hv = torch.flip(output_hv, [2,3])
output += F.sigmoid(output_hv)
output = output/4.0
pred = output.cpu().detach().numpy().squeeze()>0.5
preds.append(pred)
print('%d preds calculated...'%len(preds))
pred = stitch_pred(preds, size_stitch=imgA.shape[:-1])
else:
tensorA = transF.to_tensor(imgA).unsqueeze(0).to(torch.device('cuda', int(opt.dev_id))).float()
tensorB = transF.to_tensor(imgB).unsqueeze(0).to(torch.device('cuda', int(opt.dev_id))).float()
output, _, _ = net(tensorA, tensorB)
output = F.sigmoid(output)
if opt.TTA:
tensorA_v = torch.flip(tensorA, [2])
tensorB_v = torch.flip(tensorB, [2])
output_v, _, _ = net(tensorA_v, tensorB_v)
output_v = torch.flip(output_v, [2])
output += F.sigmoid(output_v)
tensorA_h = torch.flip(tensorA, [3])
tensorB_h = torch.flip(tensorB, [3])
output_h, _, _ = net(tensorA_h, tensorB_h)
output_h = torch.flip(output_h, [3])
output += F.sigmoid(output_h)
tensorA_hv = torch.flip(tensorA, [2,3])
tensorB_hv = torch.flip(tensorB, [2,3])
output_hv, _, _ = net(tensorA_hv, tensorB_hv)
output_hv = torch.flip(output_hv, [2,3])
output += F.sigmoid(output_hv)
output = output/4.0
pred = output.cpu().detach().numpy().squeeze()>0.5
pred_path = os.path.join(opt.pred_dir, it)
io.imsave(pred_path, pred)
if __name__ == '__main__':
main()