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W tym przewodniku pokazano, jak przeprowadzić migrację przepływów pracy dla jednego pracownika z wieloma procesorami graficznymi z TensorFlow 1 do TensorFlow 2.
Aby przeprowadzić szkolenie synchroniczne na wielu procesorach graficznych na jednym komputerze:
- W TensorFlow 1 używasz interfejsów API
tf.estimator.Estimator
ztf.distribute.MirroredStrategy
. - W TensorFlow 2 możesz użyć Keras Model.fit lub niestandardowej pętli treningowej z
tf.distribute.MirroredStrategy
. Dowiedz się więcej z przewodnika Rozproszone szkolenie z TensorFlow .
Ustawiać
Zacznij od importów i prostego zestawu danych do celów demonstracyjnych:
import tensorflow as tf
import tensorflow.compat.v1 as tf1
features = [[1., 1.5], [2., 2.5], [3., 3.5]]
labels = [[0.3], [0.5], [0.7]]
eval_features = [[4., 4.5], [5., 5.5], [6., 6.5]]
eval_labels = [[0.8], [0.9], [1.]]
TensorFlow 1: Szkolenie rozproszone dla pojedynczego pracownika z tf.estimator.Estimator
Ten przykład ilustruje kanoniczny przepływ pracy TensorFlow 1 dotyczący szkolenia jednego pracownika na wielu procesorach graficznych. Musisz ustawić strategię dystrybucji ( tf.distribute.MirroredStrategy
) za pomocą parametru config
tf.estimator.Estimator
:
def _input_fn():
return tf1.data.Dataset.from_tensor_slices((features, labels)).batch(1)
def _eval_input_fn():
return tf1.data.Dataset.from_tensor_slices(
(eval_features, eval_labels)).batch(1)
def _model_fn(features, labels, mode):
logits = tf1.layers.Dense(1)(features)
loss = tf1.losses.mean_squared_error(labels=labels, predictions=logits)
optimizer = tf1.train.AdagradOptimizer(0.05)
train_op = optimizer.minimize(loss, global_step=tf1.train.get_global_step())
return tf1.estimator.EstimatorSpec(mode, loss=loss, train_op=train_op)
strategy = tf1.distribute.MirroredStrategy()
config = tf1.estimator.RunConfig(
train_distribute=strategy, eval_distribute=strategy)
estimator = tf1.estimator.Estimator(model_fn=_model_fn, config=config)
train_spec = tf1.estimator.TrainSpec(input_fn=_input_fn)
eval_spec = tf1.estimator.EvalSpec(input_fn=_eval_input_fn)
tf1.estimator.train_and_evaluate(estimator, train_spec, eval_spec)
INFO:tensorflow:Using MirroredStrategy with devices ('/job:localhost/replica:0/task:0/device:GPU:0',) INFO:tensorflow:Initializing RunConfig with distribution strategies. INFO:tensorflow:Not using Distribute Coordinator. WARNING:tensorflow:Using temporary folder as model directory: /tmp/tmp5g_f_ufk INFO:tensorflow:Using config: {'_model_dir': '/tmp/tmp5g_f_ufk', '_tf_random_seed': None, '_save_summary_steps': 100, '_save_checkpoints_steps': None, '_save_checkpoints_secs': 600, '_session_config': allow_soft_placement: true graph_options { rewrite_options { meta_optimizer_iterations: ONE } } , '_keep_checkpoint_max': 5, '_keep_checkpoint_every_n_hours': 10000, '_log_step_count_steps': 100, '_train_distribute': <tensorflow.python.distribute.mirrored_strategy.MirroredStrategyV1 object at 0x7f6853562450>, '_device_fn': None, '_protocol': None, '_eval_distribute': <tensorflow.python.distribute.mirrored_strategy.MirroredStrategyV1 object at 0x7f6853562450>, '_experimental_distribute': None, '_experimental_max_worker_delay_secs': None, '_session_creation_timeout_secs': 7200, '_checkpoint_save_graph_def': True, '_service': None, '_cluster_spec': ClusterSpec({}), '_task_type': 'worker', '_task_id': 0, '_global_id_in_cluster': 0, '_master': '', '_evaluation_master': '', '_is_chief': True, '_num_ps_replicas': 0, '_num_worker_replicas': 1, '_distribute_coordinator_mode': None} INFO:tensorflow:Not using Distribute Coordinator. INFO:tensorflow:Running training and evaluation locally (non-distributed). INFO:tensorflow:Start train and evaluate loop. The evaluate will happen after every checkpoint. Checkpoint frequency is determined based on RunConfig arguments: save_checkpoints_steps None or save_checkpoints_secs 600. /tmpfs/src/tf_docs_env/lib/python3.7/site-packages/tensorflow/python/data/ops/dataset_ops.py:374: UserWarning: To make it possible to preserve tf.data options across serialization boundaries, their implementation has moved to be part of the TensorFlow graph. As a consequence, the options value is in general no longer known at graph construction time. Invoking this method in graph mode retains the legacy behavior of the original implementation, but note that the returned value might not reflect the actual value of the options. warnings.warn("To make it possible to preserve tf.data options across " INFO:tensorflow:Calling model_fn. WARNING:tensorflow:From /tmpfs/src/tf_docs_env/lib/python3.7/site-packages/tensorflow/python/training/adagrad.py:77: calling Constant.__init__ (from tensorflow.python.ops.init_ops) with dtype is deprecated and will be removed in a future version. Instructions for updating: Call initializer instance with the dtype argument instead of passing it to the constructor INFO:tensorflow:Done calling model_fn. INFO:tensorflow:Create CheckpointSaverHook. WARNING:tensorflow:From /tmpfs/src/tf_docs_env/lib/python3.7/site-packages/tensorflow_estimator/python/estimator/util.py:95: DistributedIteratorV1.initialize (from tensorflow.python.distribute.input_lib) is deprecated and will be removed in a future version. Instructions for updating: Use the iterator's `initializer` property instead. INFO:tensorflow:Graph was finalized. INFO:tensorflow:Running local_init_op. INFO:tensorflow:Done running local_init_op. INFO:tensorflow:Calling checkpoint listeners before saving checkpoint 0... INFO:tensorflow:Saving checkpoints for 0 into /tmp/tmp5g_f_ufk/model.ckpt. INFO:tensorflow:Calling checkpoint listeners after saving checkpoint 0... 2021-09-22 20:15:43.228503: W tensorflow/core/grappler/utils/graph_view.cc:836] No registered 'MultiDeviceIteratorFromStringHandle' OpKernel for GPU devices compatible with node { {node MultiDeviceIteratorFromStringHandle} } . Registered: device='CPU' 2021-09-22 20:15:43.229960: W tensorflow/core/grappler/utils/graph_view.cc:836] No registered 'MultiDeviceIteratorGetNextFromShard' OpKernel for GPU devices compatible with node { {node MultiDeviceIteratorGetNextFromShard} } . Registered: device='CPU' INFO:tensorflow:loss = 0.14477473, step = 0 INFO:tensorflow:Calling checkpoint listeners before saving checkpoint 3... INFO:tensorflow:Saving checkpoints for 3 into /tmp/tmp5g_f_ufk/model.ckpt. INFO:tensorflow:Calling checkpoint listeners after saving checkpoint 3... INFO:tensorflow:Calling model_fn. INFO:tensorflow:Done calling model_fn. INFO:tensorflow:Reduce to /replica:0/task:0/device:CPU:0 then broadcast to ('/replica:0/task:0/device:CPU:0',). INFO:tensorflow:Reduce to /replica:0/task:0/device:CPU:0 then broadcast to ('/replica:0/task:0/device:CPU:0',). INFO:tensorflow:Reduce to /replica:0/task:0/device:CPU:0 then broadcast to ('/replica:0/task:0/device:CPU:0',). INFO:tensorflow:Reduce to /replica:0/task:0/device:CPU:0 then broadcast to ('/replica:0/task:0/device:CPU:0',). INFO:tensorflow:Starting evaluation at 2021-09-22T20:15:43 INFO:tensorflow:Graph was finalized. INFO:tensorflow:Restoring parameters from /tmp/tmp5g_f_ufk/model.ckpt-3 INFO:tensorflow:Running local_init_op. INFO:tensorflow:Done running local_init_op. INFO:tensorflow:Inference Time : 0.17626s INFO:tensorflow:Finished evaluation at 2021-09-22-20:15:44 INFO:tensorflow:Saving dict for global step 3: global_step = 3, loss = 1.1251448 INFO:tensorflow:Saving 'checkpoint_path' summary for global step 3: /tmp/tmp5g_f_ufk/model.ckpt-3 INFO:tensorflow:Loss for final step: 0.45722964. 2021-09-22 20:15:44.095116: W tensorflow/core/grappler/utils/graph_view.cc:836] No registered 'MultiDeviceIteratorFromStringHandle' OpKernel for GPU devices compatible with node { {node MultiDeviceIteratorFromStringHandle} } . Registered: device='CPU' 2021-09-22 20:15:44.096454: W tensorflow/core/grappler/utils/graph_view.cc:836] No registered 'MultiDeviceIteratorGetNextFromShard' OpKernel for GPU devices compatible with node { {node MultiDeviceIteratorGetNextFromShard} } . Registered: device='CPU' ({'loss': 1.1251448, 'global_step': 3}, [])
TensorFlow 2: Szkolenie jednoosobowe z Keras
Podczas migracji do TensorFlow 2 możesz użyć interfejsów API Keras z tf.distribute.MirroredStrategy
.
Jeśli używasz interfejsów API tf.keras
do budowania modelu i Keras Model.fit
do szkolenia, główną różnicą jest tworzenie instancji modelu Keras, optymalizatora i metryk w kontekście Strategy.scope
, zamiast definiowania config
dla tf.estimator.Estimator
.
Jeśli potrzebujesz użyć niestandardowej pętli treningowej, zapoznaj się z przewodnikiem Korzystanie z tf.distribute.Strategy z niestandardowymi pętlami treningowymi .
dataset = tf.data.Dataset.from_tensor_slices((features, labels)).batch(1)
eval_dataset = tf.data.Dataset.from_tensor_slices(
(eval_features, eval_labels)).batch(1)
strategy = tf.distribute.MirroredStrategy()
with strategy.scope():
model = tf.keras.models.Sequential([tf.keras.layers.Dense(1)])
optimizer = tf.keras.optimizers.Adagrad(learning_rate=0.05)
model.compile(optimizer=optimizer, loss='mse')
model.fit(dataset)
model.evaluate(eval_dataset, return_dict=True)
INFO:tensorflow:Using MirroredStrategy with devices ('/job:localhost/replica:0/task:0/device:GPU:0',) INFO:tensorflow:Reduce to /job:localhost/replica:0/task:0/device:CPU:0 then broadcast to ('/job:localhost/replica:0/task:0/device:CPU:0',). INFO:tensorflow:Reduce to /job:localhost/replica:0/task:0/device:CPU:0 then broadcast to ('/job:localhost/replica:0/task:0/device:CPU:0',). INFO:tensorflow:Reduce to /job:localhost/replica:0/task:0/device:CPU:0 then broadcast to ('/job:localhost/replica:0/task:0/device:CPU:0',). INFO:tensorflow:Reduce to /job:localhost/replica:0/task:0/device:CPU:0 then broadcast to ('/job:localhost/replica:0/task:0/device:CPU:0',). 2021-09-22 20:15:44.265351: W tensorflow/core/grappler/optimizers/data/auto_shard.cc:695] AUTO sharding policy will apply DATA sharding policy as it failed to apply FILE sharding policy because of the following reason: Found an unshardable source dataset: name: "TensorSliceDataset/_2" op: "TensorSliceDataset" input: "Placeholder/_0" input: "Placeholder/_1" attr { key: "Toutput_types" value { list { type: DT_FLOAT type: DT_FLOAT } } } attr { key: "output_shapes" value { list { shape { dim { size: 2 } } shape { dim { size: 1 } } } } } INFO:tensorflow:Reduce to /job:localhost/replica:0/task:0/device:CPU:0 then broadcast to ('/job:localhost/replica:0/task:0/device:CPU:0',). INFO:tensorflow:Reduce to /job:localhost/replica:0/task:0/device:CPU:0 then broadcast to ('/job:localhost/replica:0/task:0/device:CPU:0',). 3/3 [==============================] - 2s 3ms/step - loss: 0.2363 2021-09-22 20:15:46.836745: W tensorflow/core/grappler/optimizers/data/auto_shard.cc:695] AUTO sharding policy will apply DATA sharding policy as it failed to apply FILE sharding policy because of the following reason: Found an unshardable source dataset: name: "TensorSliceDataset/_2" op: "TensorSliceDataset" input: "Placeholder/_0" input: "Placeholder/_1" attr { key: "Toutput_types" value { list { type: DT_FLOAT type: DT_FLOAT } } } attr { key: "output_shapes" value { list { shape { dim { size: 2 } } shape { dim { size: 1 } } } } } 3/3 [==============================] - 1s 3ms/step - loss: 0.0079 {'loss': 0.007883546873927116}
Następne kroki
Aby dowiedzieć się więcej o rozproszonym szkoleniu z tf.distribute.MirroredStrategy
w TensorFlow 2, zapoznaj się z następującą dokumentacją:
- Szkolenie rozproszone na jednej maszynie z samouczkiem Keras
- Szkolenie rozproszone na jednej maszynie z samouczkiem niestandardowej pętli szkoleniowej
- Szkolenie rozproszone z przewodnikiem TensorFlow
- Przewodnik Korzystanie z wielu procesorów graficznych
- Przewodnik dotyczący optymalizacji wydajności na pojedynczym hoście obsługującym wiele procesorów graficznych (za pomocą narzędzia TensorFlow Profiler)