This article will demonstrate how to build a Text Generator by building a Gated Recurrent Unit Network. The conceptual procedure of training the network is to first feed the network a mapping of each character present in the text on which the network is training to a unique number. Each character is then hot-encoded into a vector which is the required format for the network.
The data for the described procedure is a collection of short and famous poems by famous poets and is in a .txt format. It can be downloaded from here.
Step 1: Importing the required libraries
from __future__ import absolute_import, division,
print_function, unicode_literals
import numpy as np
import tensorflow as tf
from keras.models import Sequential
from keras.layers import Dense, Activation
from keras.layers import LSTM
from keras.optimizers import RMSprop
from keras.callbacks import LambdaCallback
from keras.callbacks import ModelCheckpoint
from keras.callbacks import ReduceLROnPlateau
import random
import sys
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Step 2: Loading the data into a string
# Changing the working location to the location of the text file cd C:\Users\Dev\Desktop\Kaggle\Poems # Reading the text file into a string with open ( 'poems.txt' , 'r' ) as file :
text = file .read()
# A preview of the text file print (text)
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Step 3: Creating a mapping from each unique character in the text to a unique number
# Storing all the unique characters present in the text vocabulary = sorted ( list ( set (text)))
# Creating dictionaries to map each character to an index char_to_indices = dict ((c, i) for i, c in enumerate (vocabulary))
indices_to_char = dict ((i, c) for i, c in enumerate (vocabulary))
print (vocabulary)
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Step 4: Pre-processing the data
# Dividing the text into subsequences of length max_length # So that at each time step the next max_length characters # are fed into the network max_length = 100
steps = 5
sentences = []
next_chars = []
for i in range ( 0 , len (text) - max_length, steps):
sentences.append(text[i: i + max_length])
next_chars.append(text[i + max_length])
# Hot encoding each character into a boolean vector # Initializing a matrix of boolean vectors with each column representing # the hot encoded representation of the character X = np.zeros(( len (sentences), max_length, len (vocabulary)), dtype = np. bool )
y = np.zeros(( len (sentences), len (vocabulary)), dtype = np. bool )
# Placing the value 1 at the appropriate position for each vector # to complete the hot-encoding process for i, sentence in enumerate (sentences):
for t, char in enumerate (sentence):
X[i, t, char_to_indices[char]] = 1
y[i, char_to_indices[next_chars[i]]] = 1
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Step 5: Building the GRU network
# Initializing the LSTM network model = Sequential()
# Defining the cell type model.add(GRU( 128 , input_shape = (max_length, len (vocabulary))))
# Defining the densely connected Neural Network layer model.add(Dense( len (vocabulary)))
# Defining the activation function for the cell model.add(Activation( 'softmax' ))
# Defining the optimizing function optimizer = RMSprop(lr = 0.01 )
# Configuring the model for training model. compile (loss = 'categorical_crossentropy' , optimizer = optimizer)
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Step 6: Defining some helper functions which will be used during the training of the network
Note that the first two functions given below have been referred from the documentation of the official text generation example from the Keras team.
a) Helper function to sample the next character:
# Helper function to sample an index from a probability array def sample_index(preds, temperature = 1.0 ):
# temperature determines the freedom the function has when generating text # Converting the predictions vector into a numpy array
preds = np.asarray(preds).astype( 'float64' )
# Normalizing the predictions array
preds = np.log(preds) / temperature
exp_preds = np.exp(preds)
preds = exp_preds / np. sum (exp_preds)
# The main sampling step. Creates an array of probabilities signifying
# the probability of each character to be the next character in the
# generated text
probas = np.random.multinomial( 1 , preds, 1 )
# Returning the character with maximum probability to be the next character
# in the generated text
return np.argmax(probas)
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b) Helper function to generate text after each epoch
# Helper function to generate text after the end of each epoch def on_epoch_end(epoch, logs):
print ()
print ( '----- Generating text after Epoch: % d' % epoch)
# Choosing a random starting index for the text generation
start_index = random.randint( 0 , len (text) - max_length - 1 )
# Sampling for different values of diversity
for diversity in [ 0.2 , 0.5 , 1.0 , 1.2 ]:
print ( '----- diversity:' , diversity)
generated = ''
# Seed sentence
sentence = text[start_index: start_index + max_length]
generated + = sentence
print ( '----- Generating with seed: "' + sentence + '"' )
sys.stdout.write(generated)
for i in range ( 400 ):
# Initializing the predictions vector
x_pred = np.zeros(( 1 , max_length, len (vocabulary)))
for t, char in enumerate (sentence):
x_pred[ 0 , t, char_to_indices[char]] = 1.
# Making the predictions for the next character
preds = model.predict(x_pred, verbose = 0 )[ 0 ]
# Getting the index of the most probable next character
next_index = sample_index(preds, diversity)
# Getting the most probable next character using the mapping built
next_char = indices_to_char[next_index]
# Building the generated text
generated + = next_char
sentence = sentence[ 1 :] + next_char
sys.stdout.write(next_char)
sys.stdout.flush()
print ()
# Defining a custom callback function to # describe the internal states of the network print_callback = LambdaCallback(on_epoch_end = on_epoch_end)
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c) Helper function to save the model after each epoch in which loss decreases
# Defining a helper function to save the model after each epoch # in which the loss decreases filepath = "weights.hdf5"
checkpoint = ModelCheckpoint(filepath, monitor = 'loss' ,
verbose = 1 , save_best_only = True ,
mode = 'min' )
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d) Helper function to reduce the learning rate each time the learning plateaus
# Defining a helper function to reduce the learning rate each time # the learning plateaus reduce_alpha = ReduceLROnPlateau(monitor = 'loss' , factor = 0.2 ,
patience = 1 , min_lr = 0.001 )
callbacks = [print_callback, checkpoint, reduce_alpha]
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Step 7: Training the GRU model
# Training the GRU model model.fit(X, y, batch_size = 128 , epochs = 30 , callbacks = callbacks)
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Step 8: Generating new and random text
def generate_text(length, diversity):
# Get random starting text
start_index = random.randint( 0 , len (text) - max_length - 1 )
# Defining the generated text
generated = ''
sentence = text[start_index: start_index + max_length]
generated + = sentence
# Generating new text of given length
for i in range (length):
# Initializing the prediction vector
x_pred = np.zeros(( 1 , max_length, len (vocabulary)))
for t, char in enumerate (sentence):
x_pred[ 0 , t, char_to_indices[char]] = 1.
# Making the predictions
preds = model.predict(x_pred, verbose = 0 )[ 0 ]
# Getting the index of the next most probable index
next_index = sample_index(preds, diversity)
# Getting the most probable next character using the mapping built
next_char = indices_to_char[next_index]
# Generating new text
generated + = next_char
sentence = sentence[ 1 :] + next_char
return generated
print (generate_text( 500 , 0.2 ))
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Note: Although the output does not make much sense now, the output can be significantly improved by training the model for more epochs.