mirror of
https://github.com/hexastack/hexabot
synced 2024-12-28 23:02:03 +00:00
171 lines
6.1 KiB
Python
171 lines
6.1 KiB
Python
import tensorflow as tf
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from sys import platform
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if platform == "darwin":
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from keras.optimizers.legacy import Adam
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else:
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from keras.optimizers import Adam
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from keras import layers, Sequential, regularizers
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import numpy as np
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from typing import Any, Dict, Tuple
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from data_loaders.tflcdl import TFLCDL
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import boilerplate as tfbp
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def mapify(keys: list, values: list) -> dict:
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return dict(zip(keys, values))
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def format_float(values: np.ndarray, precision: int = 5, padding: int = 5) -> list:
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return [np.format_float_positional(v, precision=precision, pad_right=padding,
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min_digits=padding) for v in values]
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# TFLC (Term Frequency based Language Classifier)
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@tfbp.default_export
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class TFLC(tfbp.Model):
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default_hparams: Dict[str, Any] = {
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"layer_sizes": [32, 2],
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"num_epochs": 70,
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"kernel_regularizer": 1e-4,
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"bias_regularizer": 1e-4,
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"dropout_proba": .2,
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"learning_rate": 1e-3
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}
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data_loader: TFLCDL
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def __init__(self, *args, **kwargs):
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super().__init__(*args, **kwargs)
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# Init data loader
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self.data_loader = TFLCDL(save_dir=self._save_dir, **kwargs)
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# Init layers
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self.forward = Sequential()
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# Dropout layer to avoid overfitting
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self.forward.add(layers.Dropout(self.hparams.dropout_proba))
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# Hidden feed forward layers
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for hidden_size in self.hparams.layer_sizes[:-1]:
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self.forward.add(layers.Dense(hidden_size, activation=tf.nn.sigmoid,
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kernel_regularizer=regularizers.L2(
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self.hparams.kernel_regularizer),
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bias_regularizer=regularizers.L2(self.hparams.bias_regularizer)))
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# Output layer
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self.forward.add(layers.Dense(self.hparams.layer_sizes[-1], activation=tf.nn.softmax,
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kernel_regularizer=regularizers.L2(
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self.hparams.kernel_regularizer),
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bias_regularizer=regularizers.L2(self.hparams.bias_regularizer)))
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self.loss = tf.losses.categorical_crossentropy
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self.optimizer = Adam(self.hparams.learning_rate)
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def call(self, x: tf.Tensor):
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return self.forward(x)
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@tfbp.runnable
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def fit(self):
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# getting our training data
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X_train, y_train, languages = self.data_loader()
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self.compile(self.optimizer, self.loss)
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# fitting the model to the data
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super().fit(
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x=X_train,
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y=y_train,
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# validation_split=0.1,
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epochs=self.hparams.num_epochs,
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shuffle=True)
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self.extra_params["languages"] = languages
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# Save the model
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self.save()
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@tfbp.runnable
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def evaluate(self):
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languages = list(self.extra_params['languages'])
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# loading the test set
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X_test, y_test = self.data_loader()
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y_pred = super().predict(X_test)
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self.calculate_metrics(y_test, y_pred, languages)
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def preprocess_text(self, text):
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# The predict file contains a single JSON object whose only key is text.
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stripped_text = self.strip_numbers(text)
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encoded_text = np.array(self.tfidf.transform(
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[stripped_text]).toarray()) # type: ignore
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return np.array([stripped_text]), encoded_text
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@tfbp.runnable
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def predict(self):
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languages = list(self.extra_params['languages'])
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input_provided = input("Provide text: ")
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text, encoded_text = self.preprocess_text(input_provided)
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# converting a one hot output to language index
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probas = super().predict(encoded_text)
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predictions = np.argmax(probas, axis=1)
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results = []
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for idx, prediction in enumerate(predictions):
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print('The sentence "{}" is in {}.'.format(
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text[idx], languages[prediction].upper()))
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results.append({'text': text[idx], 'language': prediction})
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return results
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def get_prediction(self, text: str):
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languages = self.extra_params["languages"]
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encoded_text = self.data_loader.encode_text(text)
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probas = super().predict(encoded_text)
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predictions = np.argmax(probas, axis=1)
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prediction_id = predictions[0]
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return {
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'entity': "language",
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'value': languages[prediction_id],
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'confidence': float(probas[0][prediction_id])
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}
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def calculate_metrics(self, y_true: np.ndarray, y_pred: np.ndarray, languages: list,
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formatting: int = 5) -> Tuple[np.float64, dict, dict, dict]:
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argm = np.argmax(y_pred, axis=1)
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actual_pred = [i == argm[j] for j in range(
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y_pred.shape[0]) for i in range(y_pred.shape[1])]
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actual_pred = np.array(actual_pred).reshape(-1, y_true.shape[1])
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# we use these to compute the metrics
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true_positives = (np.logical_and(
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actual_pred == y_true, y_true)).sum(axis=0)
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actual_positives = y_true.sum(axis=0)
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positive_preds = actual_pred.sum(axis=0)
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# our chosen metrics are recall, precision, accuracy and F1 score
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recall = (true_positives/actual_positives).T
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precision = (true_positives/positive_preds).T
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f1_score = (2*recall*precision/(recall+precision)).T
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# converting our other metrics into a map (dict)
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recall = mapify(languages, format_float(recall, padding=formatting))
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precision = mapify(languages, format_float(
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precision, padding=formatting))
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f1_score = mapify(languages, format_float(
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f1_score, padding=formatting))
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# from one hot vectors to the language index
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y_pred = np.array(np.argmax(y_pred, axis=1))
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y_true = np.argmax(y_true, axis=1)
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accuracy = (y_pred == y_true).mean()
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print("accuracy: {}".format(
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np.format_float_positional(accuracy, formatting)))
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print("recall:\n{}".format(recall))
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print("precision:\n{}".format(precision))
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print("F1 score:\n{}".format(f1_score))
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return (accuracy, recall, precision, f1_score)
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