This example shows how to do text classification starting from raw text (as
a set of text files on disk). We demonstrate the workflow on the IMDB sentiment
classification dataset (unprocessed version). We use the TextVectorization
layer for
word splitting & indexing.
import os os.environ["KERAS_BACKEND"] = "tensorflow" import keras import tensorflow as tf import numpy as np from keras import layers
Let's download the data and inspect its structure.
curl -O https://ai.stanford.edu/~amaas/data/sentiment/aclImdb_v1.tar.gz tar -xf aclImdb_v1.tar.gz
The aclImdb
folder contains a train
and test
subfolder:
ls aclImdb
ls aclImdb/test
ls aclImdb/train
The aclImdb/train/pos
and aclImdb/train/neg
folders contain text files, each of
which represents one review (either positive or negative):
cat aclImdb/train/pos/6248_7.txt
We are only interested in the pos
and neg
subfolders, so let's delete the other subfolder that has text files in it:
rm -r aclImdb/train/unsup
You can use the utility keras.utils.text_dataset_from_directory
to
generate a labeled tf.data.Dataset
object from a set of text files on disk filed
into class-specific folders.
Let's use it to generate the training, validation, and test datasets. The validation
and training datasets are generated from two subsets of the train
directory, with 20%
of samples going to the validation dataset and 80% going to the training dataset.
Having a validation dataset in addition to the test dataset is useful for tuning hyperparameters, such as the model architecture, for which the test dataset should not be used.
Before putting the model out into the real world however, it should be retrained using all available training data (without creating a validation dataset), so its performance is maximized.
When using the validation_split
& subset
arguments, make sure to either specify a
random seed, or to pass shuffle=False
, so that the validation & training splits you
get have no overlap.
batch_size = 32 raw_train_ds = keras.utils.text_dataset_from_directory( "aclImdb/train", batch_size=batch_size, validation_split=0.2, subset="training", seed=1337, ) raw_val_ds = keras.utils.text_dataset_from_directory( "aclImdb/train", batch_size=batch_size, validation_split=0.2, subset="validation", seed=1337, ) raw_test_ds = keras.utils.text_dataset_from_directory( "aclImdb/test", batch_size=batch_size ) print(f"Number of batches in raw_train_ds: {raw_train_ds.cardinality()}") print(f"Number of batches in raw_val_ds: {raw_val_ds.cardinality()}") print(f"Number of batches in raw_test_ds: {raw_test_ds.cardinality()}")
Let's preview a few samples:
# It's important to take a look at your raw data to ensure your normalization # and tokenization will work as expected. We can do that by taking a few # examples from the training set and looking at them. # This is one of the places where eager execution shines: # we can just evaluate these tensors using .numpy() # instead of needing to evaluate them in a Session/Graph context. for text_batch, label_batch in raw_train_ds.take(1): for i in range(5): print(text_batch.numpy()[i]) print(label_batch.numpy()[i])
In particular, we remove <br />
tags.
import string import re # Having looked at our data above, we see that the raw text contains HTML break # tags of the form '<br />'. These tags will not be removed by the default # standardizer (which doesn't strip HTML). Because of this, we will need to # create a custom standardization function. def custom_standardization(input_data): lowercase = tf.strings.lower(input_data) stripped_html = tf.strings.regex_replace(lowercase, "<br />", " ") return tf.strings.regex_replace( stripped_html, f"[{re.escape(string.punctuation)}]", "" ) # Model constants. max_features = 20000 embedding_dim = 128 sequence_length = 500 # Now that we have our custom standardization, we can instantiate our text # vectorization layer. We are using this layer to normalize, split, and map # strings to integers, so we set our 'output_mode' to 'int'. # Note that we're using the default split function, # and the custom standardization defined above. # We also set an explicit maximum sequence length, since the CNNs later in our # model won't support ragged sequences. vectorize_layer = keras.layers.TextVectorization( standardize=custom_standardization, max_tokens=max_features, output_mode="int", output_sequence_length=sequence_length, ) # Now that the vectorize_layer has been created, call `adapt` on a text-only # dataset to create the vocabulary. You don't have to batch, but for very large # datasets this means you're not keeping spare copies of the dataset in memory. # Let's make a text-only dataset (no labels): text_ds = raw_train_ds.map(lambda x, y: x) # Let's call `adapt`: vectorize_layer.adapt(text_ds)
There are 2 ways we can use our text vectorization layer:
Option 1: Make it part of the model, so as to obtain a model that processes raw strings, like this:
text_input = keras.Input(shape=(1,), dtype=tf.string, name='text') x = vectorize_layer(text_input) x = layers.Embedding(max_features + 1, embedding_dim)(x) ...
Option 2: Apply it to the text dataset to obtain a dataset of word indices, then feed it into a model that expects integer sequences as inputs.
An important difference between the two is that option 2 enables you to do asynchronous CPU processing and buffering of your data when training on GPU. So if you're training the model on GPU, you probably want to go with this option to get the best performance. This is what we will do below.
If we were to export our model to production, we'd ship a model that accepts raw strings as input, like in the code snippet for option 1 above. This can be done after training. We do this in the last section.
def vectorize_text(text, label): text = tf.expand_dims(text, -1) return vectorize_layer(text), label # Vectorize the data. train_ds = raw_train_ds.map(vectorize_text) val_ds = raw_val_ds.map(vectorize_text) test_ds = raw_test_ds.map(vectorize_text) # Do async prefetching / buffering of the data for best performance on GPU. train_ds = train_ds.cache().prefetch(buffer_size=10) val_ds = val_ds.cache().prefetch(buffer_size=10) test_ds = test_ds.cache().prefetch(buffer_size=10)
We choose a simple 1D convnet starting with an Embedding
layer.
# A integer input for vocab indices. inputs = keras.Input(shape=(None,), dtype="int64") # Next, we add a layer to map those vocab indices into a space of dimensionality # 'embedding_dim'. x = layers.Embedding(max_features, embedding_dim)(inputs) x = layers.Dropout(0.5)(x) # Conv1D + global max pooling x = layers.Conv1D(128, 7, padding="valid", activation="relu", strides=3)(x) x = layers.Conv1D(128, 7, padding="valid", activation="relu", strides=3)(x) x = layers.GlobalMaxPooling1D()(x) # We add a vanilla hidden layer: x = layers.Dense(128, activation="relu")(x) x = layers.Dropout(0.5)(x) # We project onto a single unit output layer, and squash it with a sigmoid: predictions = layers.Dense(1, activation="sigmoid", name="predictions")(x) model = keras.Model(inputs, predictions) # Compile the model with binary crossentropy loss and an adam optimizer. model.compile(loss="binary_crossentropy", optimizer="adam", metrics=["accuracy"])
epochs = 3 # Fit the model using the train and test datasets. model.fit(train_ds, validation_data=val_ds, epochs=epochs)
model.evaluate(test_ds)
If you want to obtain a model capable of processing raw strings, you can simply create a new model (using the weights we just trained):
# A string input inputs = keras.Input(shape=(1,), dtype="string") # Turn strings into vocab indices indices = vectorize_layer(inputs) # Turn vocab indices into predictions outputs = model(indices) # Our end to end model end_to_end_model = keras.Model(inputs, outputs) end_to_end_model.compile( loss="binary_crossentropy", optimizer="adam", metrics=["accuracy"] ) # Test it with `raw_test_ds`, which yields raw strings end_to_end_model.evaluate(raw_test_ds)
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