I'd assume that most frameworks like keras/tensorflow/... automatically use all CPU cores but in practice it seems they are not. I just could find few sources which can lead us to use whole capacity of CPU during Deep learning process. I found an article which is written about usage of

```
from multiprocessing import Pool
import psutil
import ray
```

in another hand, based on this answer for using a keras model in multiple processes there is no track of above-mentioned libraries. Is there the more elegant way to take advantage of **Multiprocessing** for Keras since it's very popular for implementation.

For instance , how can modify following simple RNN implementation to achieve at least 50% capacity of CPU during learning process?

Should I use 2nd model as multitasking like LSTM which I comment bellow? I mean can we simultaneously manage to run multi-models by using more capacity of CPU?

```
import numpy as np
import pandas as pd
import matplotlib.pyplot as plt
from keras.layers.normalization import BatchNormalization
from sklearn.preprocessing import MinMaxScaler
from sklearn.metrics import mean_squared_error
from sklearn.metrics import accuracy_score
from sklearn.model_selection import train_test_split
from keras.layers import Dense
from keras.layers import Dropout
from keras.layers import LSTM,SimpleRNN
from keras.models import Sequential
from keras.optimizers import Adam, RMSprop
df = pd.read_csv("D:\Train.csv", header=None)
index = [i for i in list(range(1440)) if i%3==2]
Y_train= df[index]
df = df.values
#making history by using look-back to prediction next
def create_dataset(dataset,data_train,look_back=1):
dataX,dataY = [],[]
print("Len:",len(dataset)-look_back-1)
for i in range(len(dataset)-look_back-1):
a = dataset[i:(i+look_back), :]
dataX.append(a)
dataY.append(data_train[i + look_back, :])
return np.array(dataX), np.array(dataY)
Y_train=np.array(Y_train)
df=np.array(df)
look_back = 10
trainX,trainY = create_dataset(df,Y_train, look_back=look_back)
#Split data into train & test
trainX, testX, trainY, testY = train_test_split(trainX,trainY, test_size=0.2 , shuffle=False)
#Shape of train and test data
trainX, testX, trainY, testY = train_test_split(trainX,trainY, test_size=0.2 , shuffle=False)
print("train size: {}".format(trainX.shape))
print("train Label size: {}".format(trainY.shape))
print("test size: {}".format(testX.shape))
print("test Label size: {}".format(testY.shape))
#train size: (23, 10, 1440)
#train Label size: (23, 960)
#test size: (6, 10, 1440)
#test Label size: (6, 960)
model_RNN = Sequential()
model_RNN.add(SimpleRNN(units=1440, input_shape=(trainX.shape[1], trainX.shape[2])))
model_RNN.add(Dense(960))
model_RNN.add(BatchNormalization())
model_RNN.add(Activation('tanh'))
# Compile model
model_RNN.compile(loss='mean_squared_error', optimizer='adam')
callbacks = [
EarlyStopping(patience=10, verbose=1),
ReduceLROnPlateau(factor=0.1, patience=3, min_lr=0.00001, verbose=1)]
# Fit the model
hist_RNN=model_RNN.fit(trainX, trainY, epochs =50, batch_size =20,validation_data=(testX,testY),verbose=1, callbacks=callbacks)
#predict
Y_train=np.array(trainY)
Y_test=np.array(testX)
Y_RNN_Train_pred=model_RNN.predict(trainX)
Y_RNN_Test_pred=model_RNN.predict(testX)
train_MSE=mean_squared_error(trainY, Y_RNN_Train_pred)
test_MSE=mean_squared_error(testY, Y_RNN_Test_pred)
# create and fit the Simple LSTM model as 2nd model for multi-tasking
#model_LSTM = Sequential()
#model_LSTM.add(LSTM(units = 1440, input_shape=(trainX.shape[1], trainX.shape[2])))
#model_LSTM.add(Dense(units = 960))
#model_LSTM.add(BatchNormalization())
#model_LSTM.add(Activation('tanh'))
#model_LSTM.compile(loss='mean_squared_error', optimizer='adam')
#hist_LSTM=model_LSTM.fit(trainX, trainY, epochs =50, batch_size =20,validation_data=(testX,testY),verbose=1, callbacks=callbacks)
#Y_train=np.array(trainY)
#Y_test=np.array(testX)
#Y_LSTM_Train_pred=model_LSTM.predict(trainX)
#Y_LSTM_Test_pred=model_LSTM.predict(testX)
#train_MSE=mean_squared_error(trainY, Y_LSTM_Train_pred)
#test_MSE=mean_squared_error(testY, Y_LSTM_Test_pred)
#plot losses for RNN + LSTM
f, ax = plt.subplots(figsize=(20, 15))
plt.subplot(1, 2, 1)
ax=plt.plot(hist_RNN.history['loss'] ,label='Train loss')
ax=plt.plot(hist_RNN.history['val_loss'],label='Test/Validation/Prediction loss')
plt.xlabel('Training steps (Epochs = 50)')
plt.ylabel('Loss (MSE) for Sx-Sy & Sxy')
plt.title(' RNN Loss on Train and Test data')
plt.legend()
plt.subplot(1, 2, 2)
ax=plt.plot(hist_LSTM.history['loss'] ,label='Train loss')
ax=plt.plot(hist_LSTM.history['val_loss'],label='Test/Validation/Prediction loss')
plt.xlabel('Training steps (Epochs = 50)')
plt.ylabel('Loss (MSE) for Sx-Sy & Sxy')
plt.title('LSTM Loss on Train and Test data')
plt.legend()
plt.subplots_adjust(top=0.80, bottom=0.38, left=0.12, right=0.90, hspace=0.37, wspace=0.28)
#plt.savefig('All_Losses_history_.png')
plt.show()
```

**Note** I don't access to **CUDA** just I access powerful server without VGA. My aim is to take advantage of multiprocessing and multithreading for use maximum capacity of CPU instead of 30% it means just one core while I have Quad-core!
Any advice would be greatly appreciated. I have uploaded a formatted csv dataset.

**Update:** my HW configuration is following:

- CPU: AMD A8-7650K Radeon R7 10 Compute Cores 4C+6G 3.30 GHz
- RAM: 16GB
- OS: Win 7
- Python ver 3.6.6
- Tensorflow ver 1.8.0
- Keras ver 2.2.4

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