tf.compat.v1.train.SyncReplicasOptimizer

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Class to synchronize, aggregate gradients and pass them to the optimizer.

Inherits From: Optimizer

This class is deprecated. For synchronous training, please use Distribution Strategies.

In a typical asynchronous training environment, it's common to have some stale gradients. For example, with a N-replica asynchronous training, gradients will be applied to the variables N times independently. Depending on each replica's training speed, some gradients might be calculated from copies of the variable from several steps back (N-1 steps on average). This optimizer avoids stale gradients by collecting gradients from all replicas, averaging them, then applying them to the variables in one shot, after which replicas can fetch the new variables and continue.

The following accumulators/queue are created:

  • N gradient accumulators, one per variable to train. Gradients are pushed to them and the chief worker will wait until enough gradients are collected and then average them before applying to variables. The accumulator will drop all stale gradients (more details in the accumulator op).
  • 1 token queue where the optimizer pushes the new global_step value after all variables are updated.

The following local variable is created:

  • sync_rep_local_step, one per replica. Compared against the global_step in each accumulator to check for staleness of the gradients.

The optimizer adds nodes to the graph to collect gradients and pause the trainers until variables are updated. For the Parameter Server job:

  1. An accumulator is created for each variable, and each replica pushes the gradients into the accumulators instead of directly applying them to the variables.
  2. Each accumulator averages once enough gradients (replicas_to_aggregate) have been accumulated.
  3. Apply the averaged gradients to the variables.
  4. Only after all variables have been updated, increment the global step.
  5. Only after step 4, pushes global_step in the token_queue, once for each worker replica. The workers can now fetch the global step, use it to update its local_step variable and start the next batch. Please note that some workers can consume multiple minibatches, while some may not consume even one. This is because each worker fetches minibatches as long as a token exists. If one worker is stuck for some reason and does not consume a token, another worker can use it.

For the replicas:

  1. Start a step: fetch variables and compute gradients.
  2. Once the gradients have been computed, push them into gradient accumulators. Each accumulator will check the staleness and drop the stale.
  3. After pushing all the gradients, dequeue an updated value of global_step from the token queue and record that step to its local_step variable. Note that this is effectively a barrier.
  4. Start the next batch.

Usage

# Create any optimizer to update the variables, say a simple SGD:
opt = GradientDescentOptimizer(learning_rate=0.1)

# Wrap the optimizer with sync_replicas_optimizer with 50 replicas: at each
# step the optimizer collects 50 gradients before applying to variables.
# Note that if you want to have 2 backup replicas, you can change
# total_num_replicas=52 and make sure this number matches how many physical
# replicas you started in your job.
opt = tf.compat.v1.train.SyncReplicasOptimizer(opt, replicas_to_aggregate=50,
                               total_num_replicas=50)

# Some models have startup_delays to help stabilize the model but when using
# sync_replicas training, set it to 0.

# Now you can call `minimize()` or `compute_gradients()` and
# `apply_gradients()` normally
training_op = opt.minimize(total_loss, global_step=self.global_step)


# You can create the hook which handles initialization and queues.
sync_replicas_hook = opt.make_session_run_hook(is_chief)

In the training program, every worker will run the train_op as if not synchronized.

with training.MonitoredTrainingSession(
    master=workers[worker_id].target, is_chief=is_chief,
    hooks=[sync_replicas_hook]) as mon_sess:
  while not mon_sess.should_stop():
    mon_sess.run(training_op)

To use SyncReplicasOptimizer with an Estimator, you need to send sync_replicas_hook while calling the fit.

my_estimator = DNNClassifier(..., optimizer=opt)
my_estimator.fit(..., hooks=[sync_replicas_hook])

opt The actual optimizer that will be used to compute and apply the gradients. Must be one of the Optimizer classes.
replicas_to_aggregate number of replicas to aggregate for each variable update.
total_num_replicas Total number of tasks/workers/replicas, could be different from replicas_to_aggregate. If total_num_replicas > replicas_to_aggregate: it is backup_replicas + replicas_to_aggregate. If total_num_replicas < replicas_to_aggregate: Replicas compute multiple batches per update to variables.
variable_averages Optional ExponentialMovingAverage object, used to maintain moving averages for the variables passed in variables_to_average.
variables_to_average a list of variables that need to be averaged. Only needed if variable_averages is passed in.
use_locking If True use locks for update operation.
name string. Optional name of the returned operation.

Methods

apply_gradients

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Apply gradients to variables.

This contains most of the synchronization implementation and also wraps the apply_gradients() from the real optimizer.

Args
grads_and_vars List of (gradient, variable) pairs as returned by compute_gradients().
global_step Optional Variable to increment by one after the variables have been updated.
name Optional name for the returned operation. Default to the name passed to the Optimizer constructor.

Returns
train_op The op to dequeue a token so the replicas can exit this batch and start the next one. This is executed by each replica.

Raises
ValueError If the grads_and_vars is empty.
ValueError If global step is not provided, the staleness cannot be checked.

compute_gradients

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Compute gradients of "loss" for the variables in "var_list".

This simply wraps the compute_gradients() from the real optimizer. The gradients will be aggregated in the apply_gradients() so that user can modify the gradients like clipping with per replica global norm if needed. The global norm with aggregated gradients can be bad as one replica's huge gradients can hurt the gradients from other replicas.

Args
*args Arguments for compute_gradients().
**kwargs Keyword arguments for compute_gradients().

Returns
A list of (gradient, variable) pairs.

get_chief_queue_runner

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Returns the QueueRunner for the chief to execute.

This includes the operations to synchronize replicas: aggregate gradients, apply to variables, increment global step, insert tokens to token queue.

Note that this can only be called after calling apply_gradients() which actually generates this queuerunner.

Returns
A QueueRunner for chief to execute.

Raises
ValueError If this is called before apply_gradients().

get_init_tokens_op

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Returns the op to fill the sync_token_queue with the tokens.

This is supposed to be executed in the beginning of the chief/sync thread so that even if the total_num_replicas is less than replicas_to_aggregate, the model can still proceed as the replicas can compute multiple steps per variable update. Make sure: num_tokens >= replicas_to_aggregate - total_num_replicas.

Args
num_tokens Number of tokens to add to the queue.

Returns
An op for the chief/sync replica to fill the token queue.

Raises
ValueError If this is called before apply_gradients().
ValueError If num_tokens are smaller than replicas_to_aggregate - total_num_replicas.

get_name

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get_slot

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Return a slot named "name" created for "var" by the Optimizer.

This simply wraps the get_slot() from the actual optimizer.

Args
*args Arguments for get_slot().
**kwargs Keyword arguments for get_slot().

Returns
The Variable for the slot if it was created, None otherwise.

get_slot_names

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Return a list of the names of slots created by the Optimizer.

This simply wraps the get_slot_names() from the actual optimizer.

Args
*args Arguments for get_slot().
**kwargs Keyword arguments for get_slot().

Returns
A list of strings.

make_session_run_hook

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Creates a hook to handle SyncReplicasHook ops such as initialization.

minimize

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Add operations to minimize loss by updating var_list.

This method simply combines calls compute_gradients() and apply_gradients(). If you want to process the gradient before applying them call compute_gradients() and apply_gradients() explicitly instead of using this function.

Args
loss A Tensor containing the value to minimize.
global_step Optional Variable to increment by one after the variables have been updated.
var_list Optional list or tuple of Variable objects to update to minimize loss. Defaults to the list of variables collected in the graph under the key GraphKeys.TRAINABLE_VARIABLES.
gate_gradients How to gate the computation of gradients. Can be GATE_NONE, GATE_OP, or GATE_GRAPH.
aggregation_method Specifies the method used to combine gradient terms. Valid values are defined in the class AggregationMethod.
colocate_gradients_with_ops If True, try colocating gradients with the corresponding op.
name Optional name for the returned operation.
grad_loss Optional. A Tensor holding the gradient computed for loss.

Returns
An Operation that updates the variables in var_list. If global_step was not None, that operation also increments global_step.

Raises
ValueError If some of the variables are not Variable objects.

Eager Compatibility

When eager execution is enabled, loss should be a Python function that takes no arguments and computes the value to be minimized. Minimization (and gradient computation) is done with respect to the elements of var_list if not None, else with respect to any trainable variables created during the execution of the loss function. gate_gradients, aggregation_method, colocate_gradients_with_ops and grad_loss are ignored when eager execution is enabled.

variables

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Fetches a list of optimizer variables in the default graph.

This wraps variables() from the actual optimizer. It does not include the SyncReplicasOptimizer's local step.

Returns
A list of variables.

Class Variables

  • GATE_GRAPH = 2
  • GATE_NONE = 0
  • GATE_OP = 1