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main.py
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main.py
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# -*- coding: utf-8 -*-
"""
Created on Wed Feb 17 22:05:16 2021
@author: angelou
"""
import os
import cv2
import numpy as np
from tqdm import tqdm
import matplotlib.pyplot as plt
from keras import initializers
from keras.layers import SpatialDropout2D,Input, Conv2D, MaxPooling2D, Conv2DTranspose, concatenate,AveragePooling2D, UpSampling2D, BatchNormalization, Activation, add,Dropout,Permute,ZeroPadding2D,Add, Reshape
from keras.models import Model, model_from_json
from keras.optimizers import Adam
from keras.layers.advanced_activations import ELU, LeakyReLU, ReLU, PReLU
from keras.utils.vis_utils import plot_model
from keras import backend as K
from sklearn.model_selection import train_test_split
from sklearn.metrics import classification_report
from keras import applications, optimizers, callbacks
import matplotlib
import keras
import tensorflow as tf
from keras.layers import *
from model import DCUNet
# prepare training and testing set
X = []
Y = []
for i in range(612):
path = 'D:\\CVC-ClinicDB\\Original\\'+ str(i+1)+'.tif'
img = cv2.imread(path,1)
resized_img = cv2.resize(img,(256, 192), interpolation = cv2.INTER_CUBIC)
X.append(resized_img)
for i in range(612):
path2 = 'D:\\CVC-ClinicDB\\Ground Truth\\' + str(i+1)+'.tif'
msk = cv2.imread(path2,0)
resized_msk = cv2.resize(msk,(256, 192), interpolation = cv2.INTER_CUBIC)
Y.append(resized_msk)
X = np.array(X)
Y = np.array(Y)
X_train, X_test, Y_train, Y_test = train_test_split(X, Y, test_size=0.2, random_state=5)
Y_train = Y_train.reshape((Y_train.shape[0],Y_train.shape[1],Y_train.shape[2],1))
Y_test = Y_test.reshape((Y_test.shape[0],Y_test.shape[1],Y_test.shape[2],1))
X_train = X_train / 255
X_test = X_test / 255
Y_train = Y_train / 255
Y_test = Y_test / 255
Y_train = np.round(Y_train,0)
Y_test = np.round(Y_test,0)
print(X_train.shape)
print(Y_train.shape)
print(X_test.shape)
print(Y_test.shape)
# different loss functions
def dice_coef(y_true, y_pred):
smooth = 1.0 #0.0
y_true_f = K.flatten(y_true)
y_pred_f = K.flatten(y_pred)
intersection = K.sum(y_true_f * y_pred_f)
return (2. * intersection + smooth) / (K.sum(y_true_f) + K.sum(y_pred_f) + smooth)
def jacard(y_true, y_pred):
y_true_f = K.flatten(y_true)
y_pred_f = K.flatten(y_pred)
intersection = K.sum ( y_true_f * y_pred_f)
union = K.sum ( y_true_f + y_pred_f - y_true_f * y_pred_f)
return intersection/union
def dice_coef_loss(y_true,y_pred):
return 1 - dice_coef(y_true,y_pred)
def iou_loss(y_true,y_pred):
return 1 - jacard(y_true, y_pred)
def tversky(y_true, y_pred):
y_true_pos = K.flatten(y_true)
y_pred_pos = K.flatten(y_pred)
true_pos = K.sum(y_true_pos * y_pred_pos)
false_neg = K.sum(y_true_pos * (1-y_pred_pos))
false_pos = K.sum((1-y_true_pos)*y_pred_pos)
alpha = 0.75
smooth = 1
return (true_pos + smooth)/(true_pos + alpha*false_neg + (1-alpha)*false_pos + smooth)
def tversky_loss(y_true, y_pred):
return 1 - tversky(y_true,y_pred)
def focal_tversky(y_true,y_pred):
pt_1 = tversky(y_true, y_pred)
gamma = 0.75
return K.pow((1-pt_1), gamma)
# training
def saveModel(model):
model_json = model.to_json()
try:
os.makedirs('models')
except:
pass
fp = open('models/modelP.json','w')
fp.write(model_json)
model.save('models/modelW.h5')
def evaluateModel(model, X_test, Y_test, batchSize):
try:
os.makedirs('results')
except:
pass
yp = model.predict(x=X_test, batch_size=batchSize, verbose=1)
yp = np.round(yp,0)
for i in range(10):
plt.figure(figsize=(20,10))
plt.subplot(1,3,1)
plt.imshow(X_test[i])
plt.title('Input')
plt.subplot(1,3,2)
plt.imshow(Y_test[i].reshape(Y_test[i].shape[0],Y_test[i].shape[1]))
plt.title('Ground Truth')
plt.subplot(1,3,3)
plt.imshow(yp[i].reshape(yp[i].shape[0],yp[i].shape[1]))
plt.title('Prediction')
intersection = yp[i].ravel() * Y_test[i].ravel()
union = yp[i].ravel() + Y_test[i].ravel() - intersection
jacard = (np.sum(intersection)/np.sum(union))
plt.suptitle('Jacard Index'+ str(np.sum(intersection)) +'/'+ str(np.sum(union)) +'='+str(jacard))
plt.savefig('results/'+str(i)+'.png',format='png')
plt.close()
jacard = 0
dice = 0
for i in range(len(Y_test)):
yp_2 = yp[i].ravel()
y2 = Y_test[i].ravel()
intersection = yp_2 * y2
union = yp_2 + y2 - intersection
jacard += (np.sum(intersection)/np.sum(union))
dice += (2. * np.sum(intersection) ) / (np.sum(yp_2) + np.sum(y2))
jacard /= len(Y_test)
dice /= len(Y_test)
print('Jacard Index : '+str(jacard))
print('Dice Coefficient : '+str(dice))
fp = open('models/log.txt','a')
fp.write(str(jacard)+'\n')
fp.close()
fp = open('models/best.txt','r')
best = fp.read()
fp.close()
if(jacard>float(best)):
print('***********************************************')
print('Jacard Index improved from '+str(best)+' to '+str(jacard))
print('***********************************************')
fp = open('models/best.txt','w')
fp.write(str(jacard))
fp.close()
saveModel(model)
def trainStep(model, X_train, Y_train, X_test, Y_test, epochs, batchSize):
for epoch in range(epochs):
print('Epoch : {}'.format(epoch+1))
model.fit(x=X_train, y=Y_train, batch_size=batchSize, epochs=1, verbose=1)
evaluateModel(model,X_test, Y_test,batchSize)
return model
model = DCUNet(height=192, width=256, channels=3)
model.compile(optimizer='adam', loss=focal_tversky, metrics=[dice_coef, jacard, 'accuracy'])
#binary_crossentropy
model.summary()
saveModel(model)
fp = open('models/log.txt','w')
fp.close()
fp = open('models/best.txt','w')
fp.write('-1.0')
fp.close()
trainStep(model, X_train, Y_train, X_test, Y_test, epochs=150, batchSize=4)