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import tensorflow as tf |
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from tensorflow.keras import layers, activations, initializers |
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import numpy as np |
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class MiniSunConfig: |
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def __init__(self, vocab_size=30522, max_position_embeddings=1024, hidden_size=512, |
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num_attention_heads=8, intermediate_size=2048, num_hidden_layers=8, |
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dropout_rate=0.1, weight_decay=0.01, learning_rate=1e-4, total_steps=2500, |
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warmup_ratio=0.5, restart_period=500): |
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self.vocab_size = vocab_size |
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self.max_position_embeddings = max_position_embeddings |
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self.hidden_size = hidden_size |
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self.num_attention_heads = num_attention_heads |
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self.intermediate_size = intermediate_size |
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self.num_hidden_layers = num_hidden_layers |
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self.dropout_rate = dropout_rate |
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self.weight_decay = weight_decay |
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self.learning_rate = learning_rate |
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self.total_steps = total_steps |
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self.warmup_ratio = warmup_ratio |
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self.restart_period = restart_period |
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@tf.keras.utils.register_keras_serializable() |
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class MiniSunModel(tf.keras.Model): |
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def __init__(self, config): |
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super(MiniSunModel, self).__init__() |
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self.config = config |
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self.token_embedding = layers.Embedding(config.vocab_size, config.hidden_size) |
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self.position_embedding = layers.Embedding(config.max_position_embeddings, config.hidden_size) |
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self.decoder_blocks = [] |
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self.layer_norm = layers.LayerNormalization(epsilon=1e-6) |
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self.lm_head = layers.Dense(config.vocab_size, kernel_initializer=initializers.he_normal()) |
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def build(self, input_shape): |
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self.decoder_blocks = [self._build_decoder_block() for _ in range(self.config.num_hidden_layers)] |
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super(MiniSunModel, self).build(input_shape) |
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def _build_decoder_block(self): |
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return [ |
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layers.MultiHeadAttention(num_heads=self.config.num_attention_heads, key_dim=self.config.hidden_size, |
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kernel_initializer=initializers.he_normal()), |
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layers.LayerNormalization(epsilon=1e-6), |
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layers.Dense(self.config.intermediate_size, activation=activations.elu, |
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kernel_initializer=initializers.he_normal()), |
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layers.Dense(self.config.hidden_size, kernel_initializer=initializers.he_normal()), |
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layers.Dropout(self.config.dropout_rate) |
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] |
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def call(self, inputs, attention_mask=None, training=False): |
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input_ids = inputs['input_ids'] |
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position_ids = tf.range(start=0, limit=tf.shape(input_ids)[-1], delta=1) |
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embeddings = self.token_embedding(input_ids) + self.position_embedding(position_ids) |
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if attention_mask is not None: |
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attention_mask = tf.cast(attention_mask[:, tf.newaxis, tf.newaxis, :], dtype=tf.float32) |
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hidden_states = embeddings |
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for mha, norm, ffn1, ffn2, dropout in self.decoder_blocks: |
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attn_output = mha(hidden_states, hidden_states, attention_mask=attention_mask, training=training) |
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attn_output = dropout(attn_output, training=training) |
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hidden_states = norm(attn_output + hidden_states) |
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ffn_output = ffn1(hidden_states) |
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ffn_output = ffn2(ffn_output) |
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ffn_output = dropout(ffn_output, training=training) |
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hidden_states = norm(ffn_output + hidden_states) |
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hidden_states = self.layer_norm(hidden_states) |
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logits = self.lm_head(hidden_states) |
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softmax_output = tf.nn.softmax(logits, axis=-1) |
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return logits, softmax_output |
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def get_config(self): |
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return { |
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'config': self.config.__dict__ |
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} |
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@classmethod |
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def from_config(cls, config): |
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return cls(MiniSunConfig(**config['config'])) |
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def compute_loss(self, labels, logits): |
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"""Computes the loss between labels and logits.""" |
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if labels is None or logits is None: |
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raise ValueError("Labels and logits cannot be None.") |
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return tf.keras.losses.sparse_categorical_crossentropy(labels, logits, from_logits=True) |
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def train_step(self, data): |
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inputs, labels = data |
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input_ids = inputs['input_ids'] |
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attention_mask = inputs['attention_mask'] |
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with tf.GradientTape() as tape: |
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logits, _ = self(inputs, training=True) |
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loss = self.compute_loss(labels, logits) |
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gradients = tape.gradient(loss, self.trainable_variables) |
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self.optimizer.apply_gradients(zip(gradients, self.trainable_variables)) |
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logits_for_metrics = tf.argmax(logits, axis=-1) |
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logits_for_metrics = tf.reshape(logits_for_metrics, [-1]) |
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labels_for_metrics = tf.reshape(labels, [-1]) |
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for metric in self.metrics: |
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metric.update_state(labels_for_metrics, logits_for_metrics) |
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return {m.name: m.result() for m in self.metrics} |
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def create_model(config): |
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model = MiniSunModel(config) |
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optimizer = tf.keras.optimizers.AdamW(learning_rate=config.learning_rate, weight_decay=config.weight_decay) |
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strategy = tf.distribute.get_strategy() |
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with strategy.scope(): |
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model.compile(optimizer=optimizer, |
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loss=tf.keras.losses.SparseCategoricalCrossentropy(from_logits=True), |
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metrics=['accuracy']) |
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return model |
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def cosine_annealing_with_warmup(step, config): |
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"""Learning rate schedule with warm-up and cosine annealing.""" |
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warmup_steps = int(config.total_steps * config.warmup_ratio) |
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if step < warmup_steps: |
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return config.learning_rate * (step / warmup_steps) |
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else: |
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cos_step = step - warmup_steps |
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total_cos_steps = config.total_steps - warmup_steps |
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return 0.5 * config.learning_rate * (1 + tf.cos(tf.constant(np.pi) * cos_step / total_cos_steps)) |
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def cosine_annealing_with_restarts(step, config): |
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"""Learning rate schedule with warm-up and cosine annealing with restarts.""" |
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warmup_steps = int(config.total_steps * config.warmup_ratio) |
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current_cycle = step // config.restart_period |
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effective_step = step % config.restart_period |
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if effective_step < warmup_steps: |
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return config.learning_rate * (effective_step / warmup_steps) |
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else: |
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cos_step = effective_step - warmup_steps |
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total_cos_steps = config.restart_period - warmup_steps |
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return 0.5 * config.learning_rate * (1 + tf.cos(tf.constant(np.pi) * cos_step / total_cos_steps)) |
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config = MiniSunConfig() |
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model = create_model(config) |
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lr_scheduler = tf.keras.callbacks.LearningRateScheduler(lambda step: cosine_annealing_with_warmup(step, config)) |
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lr_scheduler_with_restarts = tf.keras.callbacks.LearningRateScheduler(lambda step: cosine_annealing_with_restarts(step, config)) |