tv-script-generation/dlnd_tv_script_generation.py at master · Page6/tv-script-generation

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# coding: utf-8
# # TV Script Generation
# In this project, you'll generate your own [Simpsons](https://en.wikipedia.org/wiki/The_Simpsons) TV scripts using RNNs.  You'll be using part of the [Simpsons dataset](https://www.kaggle.com/wcukierski/the-simpsons-by-the-data) of scripts from 27 seasons.  The Neural Network you'll build will generate a new TV script for a scene at [Moe's Tavern](https://simpsonswiki.com/wiki/Moe's_Tavern).
# ## Get the Data
# The data is already provided for you.  You'll be using a subset of the original dataset.  It consists of only the scenes in Moe's Tavern.  This doesn't include other versions of the tavern, like "Moe's Cavern", "Flaming Moe's", "Uncle Moe's Family Feed-Bag", etc..
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import helper
data_dir = './data/simpsons/moes_tavern_lines.txt'
text = helper.load_data(data_dir)
# Ignore notice, since we don't use it for analysing the data
text = text[81:]
# ## Explore the Data
# Play around with `view_sentence_range` to view different parts of the data.
view_sentence_range = (0, 10)
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import numpy as np
print('Dataset Stats')
print('Roughly the number of unique words: {}'.format(len({word: None for word in text.split()})))
scenes = text.split('\n\n')
print('Number of scenes: {}'.format(len(scenes)))
sentence_count_scene = [scene.count('\n') for scene in scenes]
print('Average number of sentences in each scene: {}'.format(np.average(sentence_count_scene)))
sentences = [sentence for scene in scenes for sentence in scene.split('\n')]
print('Number of lines: {}'.format(len(sentences)))
word_count_sentence = [len(sentence.split()) for sentence in sentences]
print('Average number of words in each line: {}'.format(np.average(word_count_sentence)))
print('The sentences {} to {}:'.format(*view_sentence_range))
print('\n'.join(text.split('\n')[view_sentence_range[0]:view_sentence_range[1]]))
# ## Implement Preprocessing Functions
# The first thing to do to any dataset is preprocessing.  Implement the following preprocessing functions below:
# - Lookup Table
# - Tokenize Punctuation
# ### Lookup Table
# To create a word embedding, you first need to transform the words to ids.  In this function, create two dictionaries:
# - Dictionary to go from the words to an id, we'll call `vocab_to_int`
# - Dictionary to go from the id to word, we'll call `int_to_vocab`
# Return these dictionaries in the following tuple `(vocab_to_int, int_to_vocab)`
import numpy as np
import problem_unittests as tests
def create_lookup_tables(text):
    Create lookup tables for vocabulary
    :param text: The text of tv scripts split into words
    :return: A tuple of dicts (vocab_to_int, int_to_vocab)
    # TODO: Implement Function
    vocab = sorted(set(text))
    vocab_to_int = {word: i for i, word in enumerate(vocab)}
    int_to_vocab = dict(enumerate(vocab))
    return vocab_to_int, int_to_vocab
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tests.test_create_lookup_tables(create_lookup_tables)
# ### Tokenize Punctuation
# We'll be splitting the script into a word array using spaces as delimiters.  However, punctuations like periods and exclamation marks make it hard for the neural network to distinguish between the word "bye" and "bye!".
# Implement the function `token_lookup` to return a dict that will be used to tokenize symbols like "!" into "||Exclamation_Mark||".  Create a dictionary for the following symbols where the symbol is the key and value is the token:
# - Period ( . )
# - Comma ( , )
# - Quotation Mark ( " )
# - Semicolon ( ; )
# - Exclamation mark ( ! )
# - Question mark ( ? )
# - Left Parentheses ( ( )
# - Right Parentheses ( ) )
# - Dash ( -- )
# - Return ( \n )
# This dictionary will be used to token the symbols and add the delimiter (space) around it.  This separates the symbols as it's own word, making it easier for the neural network to predict on the next word. Make sure you don't use a token that could be confused as a word. Instead of using the token "dash", try using something like "||dash||".
def token_lookup():
    Generate a dict to turn punctuation into a token.
    :return: Tokenize dictionary where the key is the punctuation and the value is the token
    # TODO: Implement Function
    token = {".":"||Period||",
             ",":"||Comma||",
             '"':"||Quotation_Mark||",
             ";":"||Semicolon||",
             "!":"||Exclamation_mark||",
             "?":"||Question_mark||",
             "(":"||Left_Parentheses||",
             ")":"||Right_Parentheses||",
             "--":"||Dash||",
             "\n":"||Return||"}
    return token
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tests.test_tokenize(token_lookup)
# ## Preprocess all the data and save it
# Running the code cell below will preprocess all the data and save it to file.
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# Preprocess Training, Validation, and Testing Data
helper.preprocess_and_save_data(data_dir, token_lookup, create_lookup_tables)
# # Check Point
# This is your first checkpoint. If you ever decide to come back to this notebook or have to restart the notebook, you can start from here. The preprocessed data has been saved to disk.
os.environ["CUDA_VISIBLE_DEVICES"] = "0,1,2,3"
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import helper
import numpy as np
import problem_unittests as tests
int_text, vocab_to_int, int_to_vocab, token_dict = helper.load_preprocess()
# ## Build the Neural Network
# You'll build the components necessary to build a RNN by implementing the following functions below:
# - get_inputs
# - get_init_cell
# - get_embed
# - build_rnn
# - build_nn
# - get_batches
# ### Check the Version of TensorFlow and Access to GPU
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from distutils.version import LooseVersion
import warnings
import tensorflow as tf
# Check TensorFlow Version
assert LooseVersion(tf.__version__) >= LooseVersion('1.0'), 'Please use TensorFlow version 1.0 or newer'
print('TensorFlow Version: {}'.format(tf.__version__))
# Check for a GPU
if not tf.test.gpu_device_name():
    warnings.warn('No GPU found. Please use a GPU to train your neural network.')
    print('Default GPU Device: {}'.format(tf.test.gpu_device_name()))
# ### Input
# Implement the `get_inputs()` function to create TF Placeholders for the Neural Network.  It should create the following placeholders:
# - Input text placeholder named "input" using the [TF Placeholder](https://www.tensorflow.org/api_docs/python/tf/placeholder) `name` parameter.
# - Targets placeholder
# - Learning Rate placeholder
# Return the placeholders in the following tuple `(Input, Targets, LearningRate)`
def get_inputs():
    Create TF Placeholders for input, targets, and learning rate.
    :return: Tuple (input, targets, learning rate)
    # TODO: Implement Function
    inputs = tf.placeholder(tf.int32,[None,None],name='input')
    targets = tf.placeholder(tf.int32,[None,None],name='targets')
    learning_rate = tf.placeholder(tf.float32,name='learning_rate')
    return inputs, targets, learning_rate
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tests.test_get_inputs(get_inputs)
# ### Build RNN Cell and Initialize
# Stack one or more [`BasicLSTMCells`](https://www.tensorflow.org/api_docs/python/tf/contrib/rnn/BasicLSTMCell) in a [`MultiRNNCell`](https://www.tensorflow.org/api_docs/python/tf/contrib/rnn/MultiRNNCell).
# - The Rnn size should be set using `rnn_size`
# - Initalize Cell State using the MultiRNNCell's [`zero_state()`](https://www.tensorflow.org/api_docs/python/tf/contrib/rnn/MultiRNNCell#zero_state) function
#     - Apply the name "initial_state" to the initial state using [`tf.identity()`](https://www.tensorflow.org/api_docs/python/tf/identity)
# Return the cell and initial state in the following tuple `(Cell, InitialState)`
def get_init_cell(batch_size, rnn_size):
    Create an RNN Cell and initialize it.
    :param batch_size: Size of batches
    :param rnn_size: Size of RNNs
    :return: Tuple (cell, initialize state)
    # TODO: Implement Function
    lstm = tf.contrib.rnn.BasicLSTMCell(rnn_size)
    drop = tf.contrib.rnn.DropoutWrapper(lstm)
    cell = tf.contrib.rnn.MultiRNNCell([drop])
    initial_state = cell.zero_state(batch_size,tf.float32)
    initial_state = tf.identity(initial_state,name="initial_state")
    return cell, initial_state
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tests.test_get_init_cell(get_init_cell)
# ### Word Embedding
# Apply embedding to `input_data` using TensorFlow.  Return the embedded sequence.
def get_embed(input_data, vocab_size, embed_dim):
    Create embedding for <input_data>.
    :param input_data: TF placeholder for text input.
    :param vocab_size: Number of words in vocabulary.
    :param embed_dim: Number of embedding dimensions
    :return: Embedded input.
    # TODO: Implement Function
    embedding = tf.Variable(tf.random_uniform((vocab_size,embed_dim),-1,1))
    embed = tf.nn.embedding_lookup(embedding,input_data)
    return embed
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tests.test_get_embed(get_embed)
# ### Build RNN
# You created a RNN Cell in the `get_init_cell()` function.  Time to use the cell to create a RNN.
# - Build the RNN using the [`tf.nn.dynamic_rnn()`](https://www.tensorflow.org/api_docs/python/tf/nn/dynamic_rnn)
#  - Apply the name "final_state" to the final state using [`tf.identity()`](https://www.tensorflow.org/api_docs/python/tf/identity)
# Return the outputs and final_state state in the following tuple `(Outputs, FinalState)` 
def build_rnn(cell, inputs):
    Create a RNN using a RNN Cell
    :param cell: RNN Cell
    :param inputs: Input text data
    :return: Tuple (Outputs, Final State)
    # TODO: Implement Function
    outputs,final_state = tf.nn.dynamic_rnn(cell,inputs,dtype=tf.float32)
    final_state = tf.identity(final_state,name='final_state')
    return outputs, final_state
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tests.test_build_rnn(build_rnn)
# ### Build the Neural Network
# Apply the functions you implemented above to:
# - Apply embedding to `input_data` using your `get_embed(input_data, vocab_size, embed_dim)` function.
# - Build RNN using `cell` and your `build_rnn(cell, inputs)` function.
# - Apply a fully connected layer with a linear activation and `vocab_size` as the number of outputs.
# Return the logits and final state in the following tuple (Logits, FinalState) 
def build_nn(cell, rnn_size, input_data, vocab_size, embed_dim):
    Build part of the neural network
    :param cell: RNN cell
    :param rnn_size: Size of rnns
    :param input_data: Input data
    :param vocab_size: Vocabulary size
    :param embed_dim: Number of embedding dimensions
    :return: Tuple (Logits, FinalState)
    # TODO: Implement Function
    embed = get_embed(input_data,vocab_size,embed_dim)
    outputs,final_state = build_rnn(cell,embed)
    logits = tf.contrib.layers.fully_connected(outputs,vocab_size,activation_fn=None)
    return logits, final_state
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tests.test_build_nn(build_nn)
# ### Batches
# Implement `get_batches` to create batches of input and targets using `int_text`.  The batches should be a Numpy array with the shape `(number of batches, 2, batch size, sequence length)`. Each batch contains two elements:
# - The first element is a single batch of **input** with the shape `[batch size, sequence length]`
# - The second element is a single batch of **targets** with the shape `[batch size, sequence length]`
# If you can't fill the last batch with enough data, drop the last batch.
# For exmple, `get_batches([1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20], 3, 2)` would return a Numpy array of the following:
#   # First Batch
#     # Batch of Input
#     [[ 1  2], [ 7  8], [13 14]]
#     # Batch of targets
#     [[ 2  3], [ 8  9], [14 15]]
#   # Second Batch
#     # Batch of Input
#     [[ 3  4], [ 9 10], [15 16]]
#     # Batch of targets
#     [[ 4  5], [10 11], [16 17]]
#   # Third Batch
#     # Batch of Input
#     [[ 5  6], [11 12], [17 18]]
#     # Batch of targets
#     [[ 6  7], [12 13], [18  1]]
# Notice that the last target value in the last batch is the first input value of the first batch. In this case, `1`. This is a common technique used when creating sequence batches, although it is rather unintuitive.
def get_batches(int_text, batch_size, seq_length):
    Return batches of input and target
    :param int_text: Text with the words replaced by their ids
    :param batch_size: The size of batch
    :param seq_length: The length of sequence
    :return: Batches as a Numpy array
    # TODO: Implement Function
    per_batch = batch_size * seq_length
    n_batches = len(int_text) // per_batch
    batches_inputs = np.array(int_text[:n_batches * per_batch])
    batches_targets = np.array(int_text[1:n_batches * per_batch+1])
    batches_targets[-1] = batches_inputs[0]
    batches_inputs = np.split(batches_inputs.reshape(batch_size,-1),n_batches,1)
    batches_targets = np.split(batches_targets.reshape(batch_size,-1),n_batches,1)
    batches = np.array(list(zip(batches_inputs,batches_targets)))
    return batches
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tests.test_get_batches(get_batches)
# ## Neural Network Training
# ### Hyperparameters
# Tune the following parameters:
# - Set `num_epochs` to the number of epochs.
# - Set `batch_size` to the batch size.
# - Set `rnn_size` to the size of the RNNs.
# - Set `embed_dim` to the size of the embedding.
# - Set `seq_length` to the length of sequence.
# - Set `learning_rate` to the learning rate.
# - Set `show_every_n_batches` to the number of batches the neural network should print progress.
# Number of Epochs
num_epochs = 50
# Batch Size
batch_size = 256
rnn_size = 256
# Embedding Dimension Size
embed_dim = 256
# Sequence Length
seq_length = 20
# Learning Rate
learning_rate = 0.01
# Show stats for every n number of batches
show_every_n_batches = 20
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save_dir = './save'
# ### Build the Graph
# Build the graph using the neural network you implemented.
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from tensorflow.contrib import seq2seq
train_graph = tf.Graph()
with train_graph.as_default():
    vocab_size = len(int_to_vocab)
    input_text, targets, lr = get_inputs()
    input_data_shape = tf.shape(input_text)
    cell, initial_state = get_init_cell(input_data_shape[0], rnn_size)
    logits, final_state = build_nn(cell, rnn_size, input_text, vocab_size, embed_dim)
    # Probabilities for generating words
    probs = tf.nn.softmax(logits, name='probs')
    # Loss function
    cost = seq2seq.sequence_loss(
        logits,
        targets,
        tf.ones([input_data_shape[0], input_data_shape[1]]))
    # Optimizer
    optimizer = tf.train.AdamOptimizer(lr)
    # Gradient Clipping
    gradients = optimizer.compute_gradients(cost)
    capped_gradients = [(tf.clip_by_value(grad, -1., 1.), var) for grad, var in gradients if grad is not None]
    train_op = optimizer.apply_gradients(capped_gradients)
# Train the neural network on the preprocessed data.  If you have a hard time getting a good loss, check the [forums](https://discussions.udacity.com/) to see if anyone is having the same problem.
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batches = get_batches(int_text, batch_size, seq_length)
with tf.Session(graph=train_graph) as sess:
    sess.run(tf.global_variables_initializer())
    for epoch_i in range(num_epochs):
        state = sess.run(initial_state, {input_text: batches[0][0]})
        for batch_i, (x, y) in enumerate(batches):
            feed = {
                input_text: x,
                targets: y,
                initial_state: state,
                lr: learning_rate}
            train_loss, state, _ = sess.run([cost, final_state, train_op], feed)
            # Show every <show_every_n_batches> batches
            if (epoch_i * len(batches) + batch_i) % show_every_n_batches == 0:
                print('Epoch {:>3} Batch {:>4}/{}   train_loss = {:.3f}'.format(
                    epoch_i,
                    batch_i,
                    len(batches),
                    train_loss))
    # Save Model
    saver = tf.train.Saver()
    saver.save(sess, save_dir)
    print('Model Trained and Saved')
# ## Save Parameters
# Save `seq_length` and `save_dir` for generating a new TV script.
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# Save parameters for checkpoint
helper.save_params((seq_length, save_dir))
# # Checkpoint
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import tensorflow as tf
import numpy as np
import helper
import problem_unittests as tests
_, vocab_to_int, int_to_vocab, token_dict = helper.load_preprocess()
seq_length, load_dir = helper.load_params()
# ## Implement Generate Functions
# ### Get Tensors
# Get tensors from `loaded_graph` using the function [`get_tensor_by_name()`](https://www.tensorflow.org/api_docs/python/tf/Graph#get_tensor_by_name).  Get the tensors using the following names:
# - "input:0"
# - "initial_state:0"
# - "final_state:0"
# - "probs:0"
# Return the tensors in the following tuple `(InputTensor, InitialStateTensor, FinalStateTensor, ProbsTensor)` 
def get_tensors(loaded_graph):
    Get input, initial state, final state, and probabilities tensor from <loaded_graph>
    :param loaded_graph: TensorFlow graph loaded from file
    :return: Tuple (InputTensor, InitialStateTensor, FinalStateTensor, ProbsTensor)
    # TODO: Implement Function
    input_tensor = loaded_graph.get_tensor_by_name(name='input:0')
    initial_state_tensor = loaded_graph.get_tensor_by_name(name='initial_state:0')
    final_state_tensor = loaded_graph.get_tensor_by_name(name='final_state:0')
    probs_tesor = loaded_graph.get_tensor_by_name(name='probs:0')
    return input_tensor, initial_state_tensor, final_state_tensor, probs_tesor
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tests.test_get_tensors(get_tensors)
# ### Choose Word
# Implement the `pick_word()` function to select the next word using `probabilities`.
def pick_word(probabilities, int_to_vocab):
    Pick the next word in the generated text
    :param probabilities: Probabilites of the next word
    :param int_to_vocab: Dictionary of word ids as the keys and words as the values
    :return: String of the predicted word
    # TODO: Implement Function
    next_word = np.random.choice(list(int_to_vocab.values()),1,p=probabilities)
    return next_word[0]
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tests.test_pick_word(pick_word)
# ## Generate TV Script
# This will generate the TV script for you.  Set `gen_length` to the length of TV script you want to generate.
gen_length = 200
# homer_simpson, moe_szyslak, or Barney_Gumble
prime_word = 'moe_szyslak'
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loaded_graph = tf.Graph()
with tf.Session(graph=loaded_graph) as sess:
    # Load saved model
    loader = tf.train.import_meta_graph(load_dir + '.meta')
    loader.restore(sess, load_dir)
    # Get Tensors from loaded model
    input_text, initial_state, final_state, probs = get_tensors(loaded_graph)
    # Sentences generation setup
    gen_sentences = [prime_word + ':']
    prev_state = sess.run(initial_state, {input_text: np.array([[1]])})
    # Generate sentences
    for n in range(gen_length):
        # Dynamic Input
        dyn_input = [[vocab_to_int[word] for word in gen_sentences[-seq_length:]]]
        dyn_seq_length = len(dyn_input[0])
        # Get Prediction
        probabilities, prev_state = sess.run(
            [probs, final_state],
            {input_text: dyn_input, initial_state: prev_state})
        pred_word = pick_word(probabilities[0][dyn_seq_length-1], int_to_vocab)
        gen_sentences.append(pred_word)
    # Remove tokens
    tv_script = ' '.join(gen_sentences)
    for key, token in token_dict.items():
        ending = ' ' if key in ['\n', '(', '"'] else ''
        tv_script = tv_script.replace(' ' + token.lower(), key)
    tv_script = tv_script.replace('\n ', '\n')
    tv_script = tv_script.replace('( ', '(')
    print(tv_script)
# # The TV Script is Nonsensical
# It's ok if the TV script doesn't make any sense.  We trained on less than a megabyte of text.  In order to get good results, you'll have to use a smaller vocabulary or get more data.  Luckly there's more data!  As we mentioned in the begging of this project, this is a subset of [another dataset](https://www.kaggle.com/wcukierski/the-simpsons-by-the-data).  We didn't have you train on all the data, because that would take too long.  However, you are free to train your neural network on all the data.  After you complete the project, of course.
# # Submitting This Project
# When submitting this project, make sure to run all the cells before saving the notebook. Save the notebook file as "dlnd_tv_script_generation.ipynb" and save it as a HTML file under "File" -> "Download as". Include the "helper.py" and "problem_unittests.py" files in your submission.
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