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ncf_keras_main.py
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ncf_keras_main.py
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# Copyright 2018 The TensorFlow Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# ==============================================================================
"""NCF framework to train and evaluate the NeuMF model.
The NeuMF model assembles both MF and MLP models under the NCF framework. Check
`neumf_model.py` for more details about the models.
"""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import json
import os
# pylint: disable=g-bad-import-order
from absl import app
from absl import flags
from absl import logging
import tensorflow as tf
# pylint: enable=g-bad-import-order
from official.recommendation import constants as rconst
from official.recommendation import movielens
from official.recommendation import ncf_common
from official.recommendation import ncf_input_pipeline
from official.recommendation import neumf_model
from official.utils.logs import logger
from official.utils.logs import mlperf_helper
from official.utils.misc import distribution_utils
from official.utils.misc import keras_utils
from official.utils.misc import model_helpers
from official.utils.flags import core as flags_core
FLAGS = flags.FLAGS
def metric_fn(logits, dup_mask, params):
dup_mask = tf.cast(dup_mask, tf.float32)
logits = tf.slice(logits, [0, 1], [-1, -1])
in_top_k, _, metric_weights, _ = neumf_model.compute_top_k_and_ndcg(
logits,
dup_mask,
params["match_mlperf"])
metric_weights = tf.cast(metric_weights, tf.float32)
return in_top_k, metric_weights
class MetricLayer(tf.keras.layers.Layer):
"""Custom layer of metrics for NCF model."""
def __init__(self, params):
super(MetricLayer, self).__init__()
self.params = params
def call(self, inputs, training=False):
logits, dup_mask = inputs
if training:
hr_sum = 0.0
hr_count = 0.0
else:
metric, metric_weights = metric_fn(logits, dup_mask, self.params)
hr_sum = tf.reduce_sum(metric * metric_weights)
hr_count = tf.reduce_sum(metric_weights)
self.add_metric(hr_sum, name="hr_sum", aggregation="mean")
self.add_metric(hr_count, name="hr_count", aggregation="mean")
return logits
class LossLayer(tf.keras.layers.Layer):
"""Pass-through loss layer for NCF model."""
def __init__(self, loss_normalization_factor):
super(LossLayer, self).__init__()
self.loss_normalization_factor = loss_normalization_factor
self.loss = tf.keras.losses.SparseCategoricalCrossentropy(
from_logits=True, reduction="sum")
def call(self, inputs):
logits, labels, valid_pt_mask_input = inputs
loss = self.loss(
y_true=labels, y_pred=logits, sample_weight=valid_pt_mask_input)
loss = loss * (1.0 / self.loss_normalization_factor)
self.add_loss(loss)
return logits
class IncrementEpochCallback(tf.keras.callbacks.Callback):
"""A callback to increase the requested epoch for the data producer.
The reason why we need this is because we can only buffer a limited amount of
data. So we keep a moving window to represent the buffer. This is to move the
one of the window's boundaries for each epoch.
"""
def __init__(self, producer):
self._producer = producer
def on_epoch_begin(self, epoch, logs=None):
self._producer.increment_request_epoch()
class CustomEarlyStopping(tf.keras.callbacks.Callback):
"""Stop training has reached a desired hit rate."""
def __init__(self, monitor, desired_value):
super(CustomEarlyStopping, self).__init__()
self.monitor = monitor
self.desired = desired_value
self.stopped_epoch = 0
def on_epoch_end(self, epoch, logs=None):
current = self.get_monitor_value(logs)
if current and current >= self.desired:
self.stopped_epoch = epoch
self.model.stop_training = True
def on_train_end(self, logs=None):
if self.stopped_epoch > 0:
print("Epoch %05d: early stopping" % (self.stopped_epoch + 1))
def get_monitor_value(self, logs):
logs = logs or {}
monitor_value = logs.get(self.monitor)
if monitor_value is None:
logging.warning("Early stopping conditioned on metric `%s` "
"which is not available. Available metrics are: %s",
self.monitor, ",".join(list(logs.keys())))
return monitor_value
def _get_keras_model(params):
"""Constructs and returns the model."""
batch_size = params["batch_size"]
user_input = tf.keras.layers.Input(
shape=(1,), name=movielens.USER_COLUMN, dtype=tf.int32)
item_input = tf.keras.layers.Input(
shape=(1,), name=movielens.ITEM_COLUMN, dtype=tf.int32)
valid_pt_mask_input = tf.keras.layers.Input(
shape=(1,), name=rconst.VALID_POINT_MASK, dtype=tf.bool)
dup_mask_input = tf.keras.layers.Input(
shape=(1,), name=rconst.DUPLICATE_MASK, dtype=tf.int32)
label_input = tf.keras.layers.Input(
shape=(1,), name=rconst.TRAIN_LABEL_KEY, dtype=tf.bool)
base_model = neumf_model.construct_model(user_input, item_input, params)
logits = base_model.output
zeros = tf.keras.layers.Lambda(
lambda x: x * 0)(logits)
softmax_logits = tf.keras.layers.concatenate(
[zeros, logits],
axis=-1)
# Custom training loop calculates loss and metric as a part of
# training/evaluation step function.
if not params["keras_use_ctl"]:
softmax_logits = MetricLayer(params)([softmax_logits, dup_mask_input])
# TODO(b/134744680): Use model.add_loss() instead once the API is well
# supported.
softmax_logits = LossLayer(batch_size)(
[softmax_logits, label_input, valid_pt_mask_input])
keras_model = tf.keras.Model(
inputs={
movielens.USER_COLUMN: user_input,
movielens.ITEM_COLUMN: item_input,
rconst.VALID_POINT_MASK: valid_pt_mask_input,
rconst.DUPLICATE_MASK: dup_mask_input,
rconst.TRAIN_LABEL_KEY: label_input},
outputs=softmax_logits)
keras_model.summary()
return keras_model
def run_ncf(_):
"""Run NCF training and eval with Keras."""
keras_utils.set_session_config(enable_xla=FLAGS.enable_xla)
if FLAGS.seed is not None:
print("Setting tf seed")
tf.random.set_seed(FLAGS.seed)
params = ncf_common.parse_flags(FLAGS)
model_helpers.apply_clean(flags.FLAGS)
strategy = distribution_utils.get_distribution_strategy(
distribution_strategy=FLAGS.distribution_strategy,
num_gpus=FLAGS.num_gpus,
tpu_address=FLAGS.tpu)
params["distribute_strategy"] = strategy
if not keras_utils.is_v2_0() and strategy is not None:
logging.error("NCF Keras only works with distribution strategy in TF 2.0")
return
if (params["keras_use_ctl"] and (
not keras_utils.is_v2_0() or strategy is None)):
logging.error(
"Custom training loop only works with tensorflow 2.0 and dist strat.")
return
if params["use_tpu"] and not params["keras_use_ctl"]:
logging.error("Custom training loop must be used when using TPUStrategy.")
return
batch_size = params["batch_size"]
time_callback = keras_utils.TimeHistory(batch_size, FLAGS.log_steps)
callbacks = [time_callback]
producer, input_meta_data = None, None
generate_input_online = params["train_dataset_path"] is None
if generate_input_online:
# Start data producing thread.
num_users, num_items, _, _, producer = ncf_common.get_inputs(params)
producer.start()
per_epoch_callback = IncrementEpochCallback(producer)
callbacks.append(per_epoch_callback)
else:
assert params["eval_dataset_path"] and params["input_meta_data_path"]
with tf.io.gfile.GFile(params["input_meta_data_path"], "rb") as reader:
input_meta_data = json.loads(reader.read().decode("utf-8"))
num_users = input_meta_data["num_users"]
num_items = input_meta_data["num_items"]
params["num_users"], params["num_items"] = num_users, num_items
if FLAGS.early_stopping:
early_stopping_callback = CustomEarlyStopping(
"val_HR_METRIC", desired_value=FLAGS.hr_threshold)
callbacks.append(early_stopping_callback)
(train_input_dataset, eval_input_dataset,
num_train_steps, num_eval_steps) = \
(ncf_input_pipeline.create_ncf_input_data(
params, producer, input_meta_data, strategy))
steps_per_epoch = None if generate_input_online else num_train_steps
with distribution_utils.get_strategy_scope(strategy):
keras_model = _get_keras_model(params)
optimizer = tf.keras.optimizers.Adam(
learning_rate=params["learning_rate"],
beta_1=params["beta1"],
beta_2=params["beta2"],
epsilon=params["epsilon"])
if FLAGS.dtype == "fp16":
optimizer = \
tf.compat.v1.train.experimental.enable_mixed_precision_graph_rewrite(
optimizer,
loss_scale=flags_core.get_loss_scale(FLAGS,
default_for_fp16="dynamic"))
if params["keras_use_ctl"]:
train_loss, eval_results = run_ncf_custom_training(
params,
strategy,
keras_model,
optimizer,
callbacks,
train_input_dataset,
eval_input_dataset,
num_train_steps,
num_eval_steps,
generate_input_online=generate_input_online)
else:
# TODO(b/138957587): Remove when force_v2_in_keras_compile is on longer
# a valid arg for this model. Also remove as a valid flag.
if FLAGS.force_v2_in_keras_compile is not None:
keras_model.compile(
optimizer=optimizer,
run_eagerly=FLAGS.run_eagerly,
experimental_run_tf_function=FLAGS.force_v2_in_keras_compile)
else:
keras_model.compile(
optimizer=optimizer, run_eagerly=FLAGS.run_eagerly)
history = keras_model.fit(
train_input_dataset,
epochs=FLAGS.train_epochs,
steps_per_epoch=steps_per_epoch,
callbacks=callbacks,
validation_data=eval_input_dataset,
validation_steps=num_eval_steps,
verbose=2)
logging.info("Training done. Start evaluating")
eval_loss_and_metrics = keras_model.evaluate(
eval_input_dataset, steps=num_eval_steps, verbose=2)
logging.info("Keras evaluation is done.")
# Keras evaluate() API returns scalar loss and metric values from
# evaluation as a list. Here, the returned list would contain
# [evaluation loss, hr sum, hr count].
eval_hit_rate = eval_loss_and_metrics[1] / eval_loss_and_metrics[2]
# Format evaluation result into [eval loss, eval hit accuracy].
eval_results = [eval_loss_and_metrics[0], eval_hit_rate]
if history and history.history:
train_history = history.history
train_loss = train_history["loss"][-1]
stats = build_stats(train_loss, eval_results, time_callback)
return stats
def run_ncf_custom_training(params,
strategy,
keras_model,
optimizer,
callbacks,
train_input_dataset,
eval_input_dataset,
num_train_steps,
num_eval_steps,
generate_input_online=True):
"""Runs custom training loop.
Args:
params: Dictionary containing training parameters.
strategy: Distribution strategy to be used for distributed training.
keras_model: Model used for training.
optimizer: Optimizer used for training.
callbacks: Callbacks to be invoked between batches/epochs.
train_input_dataset: tf.data.Dataset used for training.
eval_input_dataset: tf.data.Dataset used for evaluation.
num_train_steps: Total number of steps to run for training.
num_eval_steps: Total number of steps to run for evaluation.
generate_input_online: Whether input data was generated by data producer.
When data is generated by data producer, then train dataset must be
re-initialized after every epoch.
Returns:
A tuple of train loss and a list of training and evaluation results.
"""
loss_object = tf.keras.losses.SparseCategoricalCrossentropy(
reduction="sum", from_logits=True)
train_input_iterator = iter(
strategy.experimental_distribute_dataset(train_input_dataset))
def train_step(train_iterator):
"""Called once per step to train the model."""
def step_fn(features):
"""Computes loss and applied gradient per replica."""
with tf.GradientTape() as tape:
softmax_logits = keras_model(features)
labels = features[rconst.TRAIN_LABEL_KEY]
loss = loss_object(
labels,
softmax_logits,
sample_weight=features[rconst.VALID_POINT_MASK])
loss *= (1.0 / params["batch_size"])
if FLAGS.dtype == "fp16":
loss = optimizer.get_scaled_loss(loss)
grads = tape.gradient(loss, keras_model.trainable_variables)
if FLAGS.dtype == "fp16":
grads = optimizer.get_unscaled_gradients(grads)
# Converting gradients to dense form helps in perf on GPU for NCF
grads = neumf_model.sparse_to_dense_grads(
list(zip(grads, keras_model.trainable_variables)))
optimizer.apply_gradients(grads)
return loss
per_replica_losses = strategy.experimental_run_v2(
step_fn, args=(next(train_iterator),))
mean_loss = strategy.reduce(
tf.distribute.ReduceOp.SUM, per_replica_losses, axis=None)
return mean_loss
def eval_step(eval_iterator):
"""Called once per eval step to compute eval metrics."""
def step_fn(features):
"""Computes eval metrics per replica."""
softmax_logits = keras_model(features)
in_top_k, metric_weights = metric_fn(softmax_logits,
features[rconst.DUPLICATE_MASK],
params)
hr_sum = tf.reduce_sum(in_top_k * metric_weights)
hr_count = tf.reduce_sum(metric_weights)
return hr_sum, hr_count
per_replica_hr_sum, per_replica_hr_count = (
strategy.experimental_run_v2(
step_fn, args=(next(eval_iterator),)))
hr_sum = strategy.reduce(
tf.distribute.ReduceOp.SUM, per_replica_hr_sum, axis=None)
hr_count = strategy.reduce(
tf.distribute.ReduceOp.SUM, per_replica_hr_count, axis=None)
return hr_sum, hr_count
if not FLAGS.run_eagerly:
train_step = tf.function(train_step)
eval_step = tf.function(eval_step)
for callback in callbacks:
callback.on_train_begin()
train_loss = 0
for epoch in range(FLAGS.train_epochs):
for cb in callbacks:
cb.on_epoch_begin(epoch)
# As NCF dataset is sampled with randomness, not repeating
# data elements in each epoch has significant impact on
# convergence. As so, offline-generated TF record files
# contains all epoch worth of data. Thus we do not need
# to initialize dataset when reading from tf record files.
if generate_input_online:
train_input_iterator = iter(
strategy.experimental_distribute_dataset(train_input_dataset))
train_loss = 0
for step in range(num_train_steps):
current_step = step + epoch * num_train_steps
for c in callbacks:
c.on_batch_begin(current_step)
train_loss += train_step(train_input_iterator)
for c in callbacks:
c.on_batch_end(current_step)
train_loss /= num_train_steps
logging.info("Done training epoch %s, epoch loss=%s.", epoch + 1,
train_loss)
eval_input_iterator = iter(
strategy.experimental_distribute_dataset(eval_input_dataset))
hr_sum = 0
hr_count = 0
for _ in range(num_eval_steps):
step_hr_sum, step_hr_count = eval_step(eval_input_iterator)
hr_sum += step_hr_sum
hr_count += step_hr_count
logging.info("Done eval epoch %s, hr=%s.", epoch + 1, hr_sum / hr_count)
if (FLAGS.early_stopping and
float(hr_sum / hr_count) > params["hr_threshold"]):
break
for c in callbacks:
c.on_train_end()
return train_loss, [None, hr_sum / hr_count]
def build_stats(loss, eval_result, time_callback):
"""Normalizes and returns dictionary of stats.
Args:
loss: The final loss at training time.
eval_result: Output of the eval step. Assumes first value is eval_loss and
second value is accuracy_top_1.
time_callback: Time tracking callback likely used during keras.fit.
Returns:
Dictionary of normalized results.
"""
stats = {}
if loss:
stats["loss"] = loss
if eval_result:
stats["eval_loss"] = eval_result[0]
stats["eval_hit_rate"] = eval_result[1]
if time_callback:
timestamp_log = time_callback.timestamp_log
stats["step_timestamp_log"] = timestamp_log
stats["train_finish_time"] = time_callback.train_finish_time
if len(timestamp_log) > 1:
stats["avg_exp_per_second"] = (
time_callback.batch_size * time_callback.log_steps *
(len(time_callback.timestamp_log)-1) /
(timestamp_log[-1].timestamp - timestamp_log[0].timestamp))
return stats
def main(_):
with logger.benchmark_context(FLAGS), \
mlperf_helper.LOGGER(FLAGS.output_ml_perf_compliance_logging):
mlperf_helper.set_ncf_root(os.path.split(os.path.abspath(__file__))[0])
run_ncf(FLAGS)
if __name__ == "__main__":
ncf_common.define_ncf_flags()
app.run(main)