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# TPU-compatible training script (์์ ๋ณธ)
import os, requests, math
import numpy as np
import tensorflow as tf
from tensorflow.keras import layers, Model
import sentencepiece as spm
# =========================
# ์ค์ (ํ์ํ๋ฉด ๋ณ๊ฒฝ)
# =========================
TOKENIZER_PATH = "bpe.model"
DATA_PATH = "shuffled_corpus.txt"
MAX_LEN = 384
EMBED_DIM = 512
LATENT_DIM = 512
BATCH_SIZE = 768 # global batch size (Keras/TPU๊ฐ replica-wise๋ก ๋๋ ์ ์ฒ๋ฆฌ)
EPOCHS = 1
SHUFFLE_BUFFER = 200000
LEARNING_RATE = 1e-4
TEMPERATURE = 0.05
DROPOUT_AUG = 0.1
EMBED_DROPOUT = 0.1
SEED = 42
print('1')
tf.get_logger().setLevel("ERROR")
tf.random.set_seed(SEED)
np.random.seed(SEED)
# =========================
# TPU ์ด๊ธฐํ / ๋ถ์ฐ์ ๋ต ์ ํ
# =========================
on_tpu = False
try:
resolver = tf.distribute.cluster_resolver.TPUClusterResolver(tpu="local")
tf.tpu.experimental.initialize_tpu_system(resolver)
strategy = tf.distribute.TPUStrategy(resolver)
print("โ
TPU ์ด๊ธฐํ ์๋ฃ:", resolver.cluster_spec().as_dict())
on_tpu = True
except Exception as e:
print("โ ๏ธ TPU ๋ฏธ์ฌ์ฉ, GPU/CPU๋ก ์งํ:", e)
strategy = tf.distribute.get_strategy()
# Mixed precision
from tensorflow.keras import mixed_precision
policy = mixed_precision.Policy("mixed_bfloat16" if on_tpu else "float32")
mixed_precision.set_global_policy(policy)
print("โ
Mixed precision:", policy)
# =========================
# ํ์ผ ๋ค์ด๋ก๋ (ํ์์)
# =========================
def download_file(url, save_path):
if os.path.exists(save_path):
print(f"exists: {save_path}")
return
print(f"Downloading {save_path} ...")
r = requests.get(url, stream=True)
r.raise_for_status()
with open(save_path, "wb") as f:
for chunk in r.iter_content(8192*2):
if not chunk:
break
f.write(chunk)
print(f"โ
{save_path} saved")
# (ํ์ํ๋ฉด ์ฃผ์ ํด์ /์ฌ์ฉ)
download_file(
"https://huggingface.co/datasets/OpenLab-NLP/ko-corpus/resolve/main/bpe.model?download=true",
TOKENIZER_PATH
)
download_file(
"https://huggingface.co/datasets/OpenLab-NLP/ko-corpus/resolve/main/shuffled_corpus%20(1).txt?download=true",
DATA_PATH
)
# =========================
# Tokenizer ๋ก๋
# =========================
sp = spm.SentencePieceProcessor()
sp.load(TOKENIZER_PATH)
pad_id = sp.piece_to_id("<pad>")
if pad_id == -1:
pad_id = 0
vocab_size = sp.get_piece_size()
print("vocab_size:", vocab_size, "pad_id:", pad_id)
# =========================
# ์ธ์ฝ๋ฉ/๋ฐ์ดํฐ ํ์ดํ๋ผ์ธ
# =========================
def encode_sentence_py(s: str):
ids = sp.encode(s, out_type=int)[:MAX_LEN]
if len(ids) < MAX_LEN:
ids = ids + [pad_id] * (MAX_LEN - len(ids))
else:
ids = ids[:MAX_LEN]
return np.array(ids, dtype=np.int32)
def tf_encode(line):
def _encode_py(s_tensor):
s = s_tensor.numpy().decode("utf-8")
return encode_sentence_py(s)
ids = tf.py_function(func=_encode_py, inp=[line], Tout=tf.int32)
ids.set_shape([MAX_LEN])
return ids
def token_dropout(tokens, drop_prob=DROPOUT_AUG):
rnd = tf.random.uniform(tf.shape(tokens), 0, 1)
keep_mask = rnd > drop_prob
return tf.where(keep_mask, tokens, tf.cast(pad_id, tf.int32))
def make_views(tokens):
v1 = token_dropout(tokens)
v2 = token_dropout(tokens)
return v1, v2
# ํ
์คํธํ์ผ ๊ธฐ๋ฐ ๋ฐ์ดํฐ์
ds = tf.data.TextLineDataset(DATA_PATH)
ds = ds.map(lambda x: tf.strings.strip(x), num_parallel_calls=tf.data.AUTOTUNE)
ds = ds.filter(lambda x: tf.not_equal(x, ""))
ds = ds.map(tf_encode, num_parallel_calls=tf.data.AUTOTUNE)
ds = ds.shuffle(SHUFFLE_BUFFER, seed=SEED)
ds = ds.repeat()
ds = ds.map(lambda t: make_views(t), num_parallel_calls=tf.data.AUTOTUNE)
ds = ds.batch(BATCH_SIZE, drop_remainder=True)
# model.fit expects (inputs, labels), labels๋ ์ฌ์ฉํ์ง ์์(๋๋ฏธ)
ds = ds.map(lambda v1, v2: ((v1, v2), tf.zeros([BATCH_SIZE], dtype=tf.float32)), num_parallel_calls=tf.data.AUTOTUNE)
ds = ds.prefetch(tf.data.AUTOTUNE)
# =========================
# ๋ชจ๋ธ ๊ตฌ์ฑ (์๋ ๋ง๋ SentenceEncoder ์ฌ์ฉ)
# =========================
class DynamicConv(layers.Layer):
def __init__(self, d_model, k=7):
super().__init__()
assert k % 2 == 1
self.k = k
self.dense = layers.Dense(d_model, activation='silu')
self.proj = layers.Dense(d_model)
self.generator = layers.Dense(k, dtype='float32')
def call(self, x):
x_in = x
x = tf.cast(x, tf.float32)
B = tf.shape(x)[0]
L = tf.shape(x)[1]
D = tf.shape(x)[2]
kernels = self.generator(self.dense(x))
kernels = tf.nn.softmax(kernels, axis=-1)
pad = (self.k - 1) // 2
x_pad = tf.pad(x, [[0,0],[pad,pad],[0,0]])
x_pad_4d = tf.expand_dims(x_pad, axis=1)
patches = tf.image.extract_patches(
images=x_pad_4d,
sizes=[1,1,self.k,1],
strides=[1,1,1,1],
rates=[1,1,1,1],
padding='VALID'
)
patches = tf.reshape(patches, [B, L, self.k, D])
kernels_exp = tf.expand_dims(kernels, axis=-1)
out = tf.reduce_sum(patches * kernels_exp, axis=2)
out = self.proj(out)
# ๐ฅ ์๋ dtype์ผ๋ก ๋๋ ค์ค
return tf.cast(out, x_in.dtype)
class EncoderBlock(tf.keras.layers.Layer):
def __init__(self, embed_dim=EMBED_DIM, ff_dim=1152, seq_len=MAX_LEN, num_conv_layers=2):
super().__init__()
self.embed_dim = embed_dim
self.seq_len = seq_len
# MLP / FFN
self.fc1 = layers.Dense(ff_dim)
self.fc2 = layers.Dense(embed_dim)
self.blocks = [DynamicConv(d_model=embed_dim, k=7) for _ in range(num_conv_layers)]
# LayerNorm
self.ln = layers.LayerNormalization(epsilon=1e-5) # ์
๋ ฅ ์ ๊ทํ
self.ln1 = layers.LayerNormalization(epsilon=1e-5) # Conv residual
self.ln2 = layers.LayerNormalization(epsilon=1e-5) # FFN residual
def call(self, x, mask=None):
# ์
๋ ฅ ์ ๊ทํ
x_norm = self.ln(x)
# DynamicConv ์ฌ๋ฌ ์ธต ํต๊ณผ
out = x_norm
for block in self.blocks: out = block(out)
# Conv residual ์ฐ๊ฒฐ
x = x_norm + self.ln1(out)
# FFN / GLU
v = out
h = self.fc1(v)
g, v_split = tf.split(h, 2, axis=-1)
h = tf.nn.silu(g) * v_split
h = self.fc2(h)
# FFN residual ์ฐ๊ฒฐ
x = x + self.ln2(h)
return x
class L2NormLayer(layers.Layer):
def __init__(self, axis=1, epsilon=1e-10, **kwargs):
super().__init__(**kwargs)
self.axis = axis
self.epsilon = epsilon
def call(self, inputs):
return tf.math.l2_normalize(inputs, axis=self.axis, epsilon=self.epsilon)
class SentenceEncoder(Model):
def __init__(self, vocab_size, embed_dim=EMBED_DIM, latent_dim=LATENT_DIM, max_len=MAX_LEN, pad_id=pad_id, dropout_rate=EMBED_DROPOUT):
super().__init__()
self.pad_id = pad_id
self.embed = layers.Embedding(vocab_size, embed_dim)
self.pos_embed = layers.Embedding(input_dim=max_len, output_dim=embed_dim)
self.dropout = layers.Dropout(dropout_rate)
self.blocks = [EncoderBlock() for _ in range(2)]
self.attn_pool = layers.Dense(1)
self.ln_f = layers.LayerNormalization(epsilon=1e-5, dtype=tf.float32)
self.latent = layers.Dense(latent_dim, activation=None)
self.l2norm = L2NormLayer(axis=1)
def call(self, x, training=None):
positions = tf.range(tf.shape(x)[1])[tf.newaxis, :]
x_embed = self.embed(x) + self.pos_embed(positions)
x_embed = self.dropout(x_embed, training=training)
mask = tf.cast(tf.not_equal(x, self.pad_id), tf.float32)
h = x_embed
for block in self.blocks:
h = block(h, training=training)
h = self.ln_f(h)
# ๐ฅ scores๋ฅผ float32 ๊ฐ์
scores = self.attn_pool(h)
scores = tf.cast(scores, tf.float32)
scores = tf.where(mask[..., tf.newaxis] == 0, tf.constant(-1e9, tf.float32), scores)
scores = tf.nn.softmax(scores, axis=1)
pooled = tf.reduce_sum(h * scores, axis=1)
latent = self.latent(pooled)
latent = self.l2norm(latent)
# ๐ฅ ์ถ๋ ฅ๋ง float32
return tf.cast(latent, tf.float32)
# contrastive wrapper: ๋ ๋ทฐ๋ฅผ ์ธ์ฝ๋ฉํ๊ณ (2B, D) concat ๋ฐํ
def build_contrastive_model(vocab_size):
encoder = SentenceEncoder(vocab_size=vocab_size)
input1 = layers.Input(shape=(MAX_LEN,), dtype=tf.int32, name="view1")
input2 = layers.Input(shape=(MAX_LEN,), dtype=tf.int32, name="view2")
z1 = encoder(input1)
z2 = encoder(input2)
out = layers.Concatenate(axis=0)([z1, z2]) # (2B, D)
return Model(inputs=[input1, input2], outputs=out), encoder
def nt_xent_loss(y_true, y_pred):
# y_pred: (2N, D) normalized
z = y_pred
z = tf.cast(z, tf.float32)
sim = tf.matmul(z, z, transpose_b=True) # (2N, 2N)
sim = sim / TEMPERATURE
# large negative on diagonal to avoid trivial argmax
diag = tf.eye(tf.shape(sim)[0])
sim = sim - diag * 1e9
N2 = tf.shape(sim)[0]
N = N2 // 2
# positive index for i: if i < N => i+N, else i-N
labels_pos = tf.concat([tf.range(N, N2), tf.range(0, N)], axis=0)
loss = tf.nn.sparse_softmax_cross_entropy_with_logits(labels=labels_pos, logits=sim)
return tf.reduce_mean(loss)
# =========================
# ๋ชจ๋ธ ์์ฑ / ์ปดํ์ผ (strategy.scope ์์์)
# =========================
with strategy.scope():
model, encoder = build_contrastive_model(vocab_size)
optimizer = tf.keras.optimizers.Adam(learning_rate=LEARNING_RATE)
model.compile(optimizer=optimizer, loss=nt_xent_loss)
model.summary()
# =========================
# steps_per_epoch ๊ณ์ฐ (ํ์ผ ๋ผ์ธ ์ ๊ธฐ๋ฐ)
# =========================
try:
with open(DATA_PATH, "r", encoding="utf-8") as f:
num_lines = sum(1 for _ in f)
except Exception as e:
print("Warning: ๋ฐ์ดํฐ ํ์ผ ๋ผ์ธ ์ ๊ณ์ฐ ์คํจ:", e)
num_lines = None
if num_lines:
steps_per_epoch = max(1, num_lines // BATCH_SIZE)
else:
# fallback (์๊ฒ ์ก์)
steps_per_epoch = 1000
print("steps_per_epoch:", steps_per_epoch)
# =========================
# ํ์ต ์คํ
# =========================
history = model.fit(ds, epochs=EPOCHS, steps_per_epoch=steps_per_epoch, verbose=1)
# encoder ๊ฐ์ค์น ์ ์ฅ
encoder.save_weights("encoder_fit.weights.h5")
print("Training finished and weights saved.")
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