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!pip install sentencepiece |
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import sentencepiece as spm |
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import os, json, numpy as np, tensorflow as tf |
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import requests |
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print('1') |
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tf.get_logger().setLevel("ERROR") |
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SEED = 42 |
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tf.random.set_seed(SEED) |
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np.random.seed(SEED) |
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try: |
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resolver = tf.distribute.cluster_resolver.TPUClusterResolver(tpu="local") |
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tf.tpu.experimental.initialize_tpu_system(resolver) |
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strategy = tf.distribute.TPUStrategy(resolver) |
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print("β
TPU μ΄κΈ°ν μλ£:", resolver.cluster_spec().as_dict()) |
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on_tpu = True |
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except Exception as e: |
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print("β οΈ TPU λ―Έμ¬μ©, GPU/CPUλ‘ μ§ν:", e) |
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strategy = tf.distribute.get_strategy() |
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on_tpu = False |
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from tensorflow.keras import mixed_precision |
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import tensorflow as tf |
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from tensorflow.keras import layers, activations, initializers |
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policy = mixed_precision.Policy("mixed_bfloat16" if on_tpu else "float32") |
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mixed_precision.set_global_policy(policy) |
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print("β
Mixed precision:", policy) |
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def download_file(url, save_path): |
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r = requests.get(url, stream=True) |
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r.raise_for_status() |
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with open(save_path, "wb") as f: |
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for chunk in r.iter_content(8192): |
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f.write(chunk) |
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print(f"β
{save_path} μ μ₯λ¨") |
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DATA_PATH = "converted.jsonl" |
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TOKENIZER_PATH = "ko_unigram.model" |
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if not os.path.exists(DATA_PATH): |
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download_file( |
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"https://huggingface.co/datasets/Yuchan5386/SFT/resolve/main/data_shuffled_1.jsonl?download=true", |
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DATA_PATH |
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) |
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if not os.path.exists(TOKENIZER_PATH): |
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download_file( |
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"https://huggingface.co/Yuchan5386/inlam-70m-instruct/resolve/main/unigram.model?download=true", |
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TOKENIZER_PATH |
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) |
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sp = spm.SentencePieceProcessor(TOKENIZER_PATH) |
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pad_id = sp.piece_to_id("<pad>") if sp.piece_to_id("<pad>") != -1 else 0 |
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start_id = sp.piece_to_id("<start>") |
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sep_id = sp.piece_to_id("<sep>") |
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end_id = sp.piece_to_id("<end>") |
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unk_id = sp.piece_to_id("<unk>") |
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vocab_size = sp.get_piece_size() |
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print(f"β
Vocabulary size: {vocab_size}") |
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max_len = 1024 |
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batch_size = 128 |
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def text_to_ids(text): |
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return sp.encode(text, out_type=int) |
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def ids_to_text(ids): |
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return sp.decode(ids) |
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def jsonl_stream(file_path): |
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with open(file_path, "r", encoding="utf-8") as f: |
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for line in f: |
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data = json.loads(line) |
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conversations = data.get("conversations", []) |
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for i in range(0, len(conversations) - 1, 2): |
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human_msg = conversations[i] |
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gpt_msg = conversations[i + 1] |
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if human_msg.get("from") != "human" or gpt_msg.get("from") != "gpt": |
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continue |
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prompt = human_msg.get("value", "").strip() |
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response = gpt_msg.get("value", "").strip() |
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full = f"<start> {prompt} <sep> {response} <end>" |
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if "<sep>" not in full: |
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continue |
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sep_index = full.index("<sep>") |
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input_text = full[:sep_index + len("<sep>")].strip() |
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target_text = full[sep_index + len("<sep>"):].strip() |
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input_ids = text_to_ids(input_text) |
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target_ids = text_to_ids(target_text + " <end>") |
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available_len = max_len - len(input_ids) |
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if available_len <= 0: |
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input_ids = input_ids[-max_len:] |
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target_ids = [] |
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target_mask = [0] * len(input_ids) |
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else: |
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target_ids = target_ids[:available_len] |
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target_mask = [0] * len(input_ids) + [1] * len(target_ids) |
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full_input = input_ids + target_ids |
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pad_len = max_len - len(full_input) |
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full_input += [pad_id] * pad_len |
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target_mask += [0] * pad_len |
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target_seq = full_input[1:] + [end_id] |
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target_seq = target_seq[:max_len] |
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masked_target = [ |
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t if m == 1 else pad_id |
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for t, m in zip(target_seq, target_mask) |
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] |
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yield ( |
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tf.convert_to_tensor(full_input, dtype=tf.int32), |
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tf.convert_to_tensor(masked_target, dtype=tf.int32) |
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) |
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dataset = tf.data.Dataset.from_generator( |
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lambda: jsonl_stream(DATA_PATH), |
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output_signature=( |
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tf.TensorSpec(shape=(max_len,), dtype=tf.int32), |
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tf.TensorSpec(shape=(max_len,), dtype=tf.int32), |
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), |
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) |
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dataset = dataset.shuffle(1000, seed=SEED).batch(batch_size, drop_remainder=True).prefetch(tf.data.AUTOTUNE) |
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with strategy.scope(): |
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dist_dataset = strategy.experimental_distribute_dataset(dataset) |
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class RotaryPositionalEmbedding(tf.keras.layers.Layer): |
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def __init__(self, dim): |
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super().__init__() |
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inv_freq = 1.0 / (10000 ** (np.arange(0, dim, 2) / dim)) |
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self.inv_freq = tf.constant(inv_freq, dtype=tf.float32) |
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def call(self, x): |
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b, h, s, d = tf.unstack(tf.shape(x)) |
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t = tf.range(s, dtype=tf.float32) |
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freqs = tf.einsum('i,j->ij', t, self.inv_freq) |
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dtype = x.dtype |
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emb_sin = tf.cast(tf.sin(freqs), dtype) |
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emb_cos = tf.cast(tf.cos(freqs), dtype) |
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emb_cos = tf.reshape(emb_cos, [1,1,s,-1]) |
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emb_sin = tf.reshape(emb_sin, [1,1,s,-1]) |
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x1, x2 = x[..., ::2], x[..., 1::2] |
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x_rot = tf.stack([x1*emb_cos - x2*emb_sin, x1*emb_sin + x2*emb_cos], axis=-1) |
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x_rot = tf.reshape(x_rot, tf.shape(x)) |
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return x_rot |
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class SwiGLU(tf.keras.layers.Layer): |
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def __init__(self, d_model, d_ff): |
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super().__init__() |
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self.proj = tf.keras.layers.Dense(d_ff) |
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self.out = tf.keras.layers.Dense(d_model) |
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def call(self, x): |
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x_proj = self.proj(x) |
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x_val, x_gate = tf.split(x_proj, 2, axis=-1) |
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return self.out(x_val * tf.nn.silu(x_gate)) |
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class FlashAttentionMHA(layers.Layer): |
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def __init__(self, d_model, num_heads=8, dropout_rate=0.1): |
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super().__init__() |
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self.d_model = d_model |
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self.num_heads = num_heads |
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self.dh = d_model // num_heads |
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self.q_proj = layers.Dense(d_model, use_bias=False) |
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self.k_proj = layers.Dense(d_model, use_bias=False) |
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self.v_proj = layers.Dense(d_model, use_bias=False) |
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self.out_proj = layers.Dense(d_model, use_bias=False) |
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self.dropout = layers.Dropout(dropout_rate) |
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self.rope = RotaryPositionalEmbedding(self.dh) |
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@tf.function(jit_compile=True) |
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def call(self, x, training=False, causal=False): |
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B, N, D = tf.shape(x)[0], tf.shape(x)[1], x.shape[2] |
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Q = tf.reshape(self.q_proj(x), [B, N, self.num_heads, self.dh]) |
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K = tf.reshape(self.k_proj(x), [B, N, self.num_heads, self.dh]) |
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V = tf.reshape(self.v_proj(x), [B, N, self.num_heads, self.dh]) |
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Q = tf.transpose(Q, [0,2,1,3]) |
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K = tf.transpose(K, [0,2,1,3]) |
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V = tf.transpose(V, [0,2,1,3]) |
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Q = self.rope(Q) |
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K = self.rope(K) |
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scale = tf.cast(self.dh ** -0.5, x.dtype) |
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Q = Q * scale |
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attn_scores = tf.matmul(Q, K, transpose_b=True) |
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if causal: |
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mask = tf.linalg.band_part(tf.ones((N,N), dtype=x.dtype), -1, 0) |
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attn_scores = attn_scores * mask - 1e9 * (1 - mask) |
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attn_weights = tf.nn.softmax(attn_scores, axis=-1) |
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attn_weights = self.dropout(attn_weights, training=training) |
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out = tf.matmul(attn_weights, V) |
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out = tf.transpose(out, [0,2,1,3]) |
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out = tf.reshape(out, [B, N, D]) |
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out = self.out_proj(out) |
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return out |
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class GPTBlock(tf.keras.layers.Layer): |
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def __init__(self, d_model, d_ff, num_heads=12, dropout_rate=0.1, adapter_dim=64): |
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super().__init__() |
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self.ln1 = tf.keras.layers.LayerNormalization(epsilon=1e-5) |
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self.mha = FlashAttentionMHA(d_model, num_heads, dropout_rate=dropout_rate) |
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self.dropout1 = tf.keras.layers.Dropout(dropout_rate) |
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self.adapter_down = tf.keras.layers.Dense(adapter_dim, activation='gelu') |
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self.adapter_up = tf.keras.layers.Dense(d_model) |
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self.ln2 = tf.keras.layers.LayerNormalization(epsilon=1e-5) |
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self.ffn = SwiGLU(d_model, d_ff) |
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self.dropout2 = tf.keras.layers.Dropout(dropout_rate) |
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def call(self, x, training=False): |
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x_norm = self.ln1(x) |
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attn_out = self.mha(x_norm, training=training, causal=True) |
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attn_out = self.dropout1(attn_out, training=training) |
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adapter_out = self.adapter_up(self.adapter_down(attn_out)) |
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attn_out = attn_out + adapter_out |
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x = x + attn_out |
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ffn_out = self.ffn(self.ln2(x)) |
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x = x + self.dropout2(ffn_out, training=training) |
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return x |
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class InLaM(tf.keras.Model): |
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def __init__(self, vocab_size, seq_len, d_model, d_ff, n_layers, num_heads=12, dropout_rate=0.1): |
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super().__init__() |
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self.vocab_size = vocab_size |
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self.d_model = d_model |
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self.token_embedding = tf.keras.layers.Embedding(vocab_size, d_model, dtype="bfloat16") |
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self.blocks = [GPTBlock(d_model, d_ff, num_heads, dropout_rate) for _ in range(n_layers)] |
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self.ln_f = tf.keras.layers.LayerNormalization(epsilon=1e-5, dtype="bfloat16") |
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def call(self, x, training=False): |
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x = self.token_embedding(x) |
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for block in self.blocks: |
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x = block(x, training=training) |
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x = self.ln_f(x) |
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embed_weights = self.token_embedding.weights[0] |
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logits = tf.matmul(x, embed_weights, transpose_b=True) |
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return tf.cast(logits, tf.float32) |
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def smoothed_loss_keras(y_true, y_pred, eps=0.1): |
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y_true = tf.cast(y_true, tf.int32) |
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mask = tf.cast(tf.not_equal(y_true, pad_id), tf.float32) |
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vocab = tf.shape(y_pred)[-1] |
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y_true_oh = tf.one_hot(y_true, depth=vocab, dtype=tf.float32) |
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y_true_ls = (1.0 - eps) * y_true_oh + eps / tf.cast(vocab, tf.float32) |
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log_probs = tf.nn.log_softmax(y_pred, axis=-1) |
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per_tok = -tf.reduce_sum(y_true_ls * log_probs, axis=-1) |
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per_tok = per_tok * mask |
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return tf.reduce_sum(per_tok) / (tf.reduce_sum(mask) + 1e-8) |
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def masked_accuracy(y_true, y_pred): |
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y_true = tf.cast(y_true, tf.int32) |
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mask = tf.cast(tf.not_equal(y_true, pad_id), tf.float32) |
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pred_id = tf.argmax(y_pred, axis=-1, output_type=tf.int32) |
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acc = tf.cast(tf.equal(y_true, pred_id), tf.float32) * mask |
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return tf.reduce_sum(acc) / (tf.reduce_sum(mask) + 1e-8) |
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def masked_perplexity(y_true, y_pred, eps=0.1): |
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y_true = tf.cast(y_true, tf.int32) |
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mask = tf.cast(tf.not_equal(y_true, pad_id), tf.float32) |
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vocab = tf.shape(y_pred)[-1] |
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y_true_oh = tf.one_hot(y_true, depth=vocab, dtype=tf.float32) |
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y_true_ls = (1.0 - eps) * y_true_oh + eps / tf.cast(vocab, tf.float32) |
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log_probs = tf.nn.log_softmax(y_pred, axis=-1) |
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per_tok = -tf.reduce_sum(y_true_ls * log_probs, axis=-1) |
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per_tok = per_tok * mask |
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mean_loss = tf.reduce_sum(per_tok) / (tf.reduce_sum(mask) + 1e-8) |
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return tf.exp(mean_loss) |
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with strategy.scope(): |
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model = InLaM(vocab_size=vocab_size, seq_len=max_len, d_model=768, d_ff=768*4, n_layers=12) |
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dummy_input = tf.zeros((batch_size, max_len), dtype=tf.int32) |
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_ = model(dummy_input, training=False) |
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model.summary() |
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optimizer = tf.keras.optimizers.Adam(1e-4, beta_1=0.9, beta_2=0.95, epsilon=1e-8, clipnorm=1.0) |
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model.compile(optimizer=optimizer, loss=smoothed_loss_keras, metrics=[masked_accuracy, masked_perplexity]) |
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history = model.fit(dist_dataset, epochs=1, verbose=1) |
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model.save_weights("tf_model.weights.h5") |
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print("β
λͺ¨λΈ κ°μ€μΉ μ μ₯ μλ£!") |
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def generate_text_topp(model, prompt, max_len=115, max_gen=98, p=0.9, temperature=0.68, min_len=20): |
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model_input = text_to_ids(f"<start> {prompt} <sep>") |
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model_input = model_input[:max_len] |
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generated = list(model_input) |
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for step in range(max_gen): |
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input_seq = generated[-max_len:] if len(generated) > max_len else generated |
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input_padded = np.pad(input_seq, (0, max_len - len(input_seq)), constant_values=pad_id) |
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input_tensor = tf.convert_to_tensor([input_padded], dtype=tf.int32) |
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logits = model(input_tensor, training=False).numpy()[0, len(input_seq)-1] |
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logits[end_id] -= 5.0 |
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logits[pad_id] -= 10.0 |
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probs = tf.nn.softmax(logits / temperature).numpy() |
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sorted_idx = np.argsort(probs)[::-1] |
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sorted_probs = probs[sorted_idx] |
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cumulative = np.cumsum(sorted_probs) |
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cutoff = np.searchsorted(cumulative, p) |
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top_idx = sorted_idx[:cutoff + 1] |
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top_probs = sorted_probs[:cutoff + 1] / sorted_probs[:cutoff + 1].sum() |
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next_token = int(np.random.choice(top_idx, p=top_probs)) |
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if next_token == end_id and len(generated) >= min_len: |
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break |
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generated.append(next_token) |
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return ids_to_text(generated) |
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prompt = "μλ
νμΈμ! νκ΅ λ°΄λμ λν΄ κΆκΈν κ²μ΄ μμ΄μ!" |
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sample_text = generate_text_topp(model, prompt, p=0.9) |
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print("\n===== μμ± κ²°κ³Ό =====\n") |
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print(sample_text) |
