Exemplo n.º 1
0
    def testVariablesPS(self):
        deploy_config = model_deploy.DeploymentConfig(num_ps_tasks=2)

        with tf.device(deploy_config.variables_device()):
            a = tf.Variable(0)
            b = tf.Variable(0)
            c = tf.no_op()
            d = framework.variable(
                'a', [], caching_device=deploy_config.caching_device())

        self.assertDeviceEqual(a.device, '/job:ps/task:0/device:CPU:0')
        self.assertDeviceEqual(a.device, a.value().device)
        self.assertDeviceEqual(b.device, '/job:ps/task:1/device:CPU:0')
        self.assertDeviceEqual(b.device, b.value().device)
        self.assertDeviceEqual(c.device, '')
        self.assertDeviceEqual(d.device, '/job:ps/task:0/device:CPU:0')
        self.assertDeviceEqual(d.value().device, '')
Exemplo n.º 2
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    def testPS(self):
        deploy_config = model_deploy.DeploymentConfig(num_clones=1,
                                                      num_ps_tasks=1)

        self.assertDeviceEqual(deploy_config.clone_device(0),
                               '/job:worker/device:GPU:0')
        self.assertEqual(deploy_config.clone_scope(0), '')
        self.assertDeviceEqual(deploy_config.optimizer_device(),
                               '/job:worker/device:CPU:0')
        self.assertDeviceEqual(deploy_config.inputs_device(),
                               '/job:worker/device:CPU:0')
        with tf.device(deploy_config.variables_device()):
            a = tf.Variable(0)
            b = tf.Variable(0)
            c = tf.no_op()
            d = framework.variable(
                'a', [], caching_device=deploy_config.caching_device())
        self.assertDeviceEqual(a.device, '/job:ps/task:0/device:CPU:0')
        self.assertDeviceEqual(a.device, a.value().device)
        self.assertDeviceEqual(b.device, '/job:ps/task:0/device:CPU:0')
        self.assertDeviceEqual(b.device, b.value().device)
        self.assertDeviceEqual(c.device, '')
        self.assertDeviceEqual(d.device, '/job:ps/task:0/device:CPU:0')
        self.assertDeviceEqual(d.value().device, '')
Exemplo n.º 3
0
def batch_norm(inputs,
               decay=0.999,
               center=True,
               scale=False,
               epsilon=0.001,
               moving_vars='moving_vars',
               activation_fn=None,
               is_training=True,
               data_format='NHWC',
               reuse=None,
               num_shards=None,
               distributed_group_size=1,
               scope=None):
  """Adds a Batch Normalization layer from http://arxiv.org/abs/1502.03167.

    "Batch Normalization: Accelerating Deep Network Training by Reducing
    Internal Covariate Shift"

    Sergey Ioffe, Christian Szegedy

  Can be used as a normalizer function for conv2d and fully_connected.

  Note: When is_training is True the moving_mean and moving_variance need to be
  updated, by default the update_ops are placed in `tf.GraphKeys.UPDATE_OPS` so
  they need to be added as a dependency to the `train_op`, example:

    update_ops = tf.get_collection(tf.GraphKeys.UPDATE_OPS)
    if update_ops:
      updates = tf.group(*update_ops)
      total_loss = control_flow_ops.with_dependencies([updates], total_loss)

  One can set updates_collections=None to force the updates in place, but that
  can have speed penalty, especially in distributed settings.

  Args:
    inputs: A tensor with 2 or more dimensions, where the first dimension has
      `batch_size`. The normalization is over all but the last dimension if
      `data_format` is `NHWC` and the second dimension if `data_format` is
      `NCHW`.
    decay: Decay for the moving average. Reasonable values for `decay` are close
      to 1.0, typically in the multiple-nines range: 0.999, 0.99, 0.9, etc.
      Lower `decay` value (recommend trying `decay`=0.9) if model experiences
      reasonably good training performance but poor validation and/or test
      performance.
    center: If True, add offset of `beta` to normalized tensor.  If False,
      `beta` is ignored.
    scale: If True, multiply by `gamma`. If False, `gamma` is
      not used. When the next layer is linear (also e.g. `nn.relu`), this can be
      disabled since the scaling can be done by the next layer.
    epsilon: Small float added to variance to avoid dividing by zero.
    moving_vars: Name of collection created for moving variables.
    activation_fn: Activation function, default set to None to skip it and
      maintain a linear activation.
    is_training: Whether or not the layer is in training mode. In training mode
      it would accumulate the statistics of the moments into `moving_mean` and
      `moving_variance` using an exponential moving average with the given
      `decay`. When it is not in training mode then it would use the values of
      the `moving_mean` and the `moving_variance`.
    data_format: input data format. NHWC or NCHW
    reuse: Whether or not the layer and its variables should be reused. To be
      able to reuse the layer scope must be given.
    num_shards: Number of shards that participate in the global
      reduction. Default is set to None, that will skip the cross replica sum in
      and normalize across local examples only.
    distributed_group_size: Number of replicas to normalize across in the
      distributed batch normalization.
    scope: Optional scope for `variable_scope`.

  Returns:
    A `Tensor` representing the output of the operation.

  Raises:
    ValueError: If the rank of `inputs` is undefined.
    ValueError: If the rank of `inputs` is neither 2 or 4.
    ValueError: If rank or `C` dimension of `inputs` is undefined.
  """
  trainable = True

  with tf.variable_scope(scope, 'BatchNorm', [inputs], reuse=reuse):
    inputs = tf.convert_to_tensor(inputs)
    original_shape = inputs.get_shape()
    original_rank = original_shape.ndims
    if original_rank is None:
      raise ValueError('Inputs %s has undefined rank' % inputs.name)
    elif original_rank not in [2, 4]:
      raise ValueError('Inputs %s has unsupported rank.'
                       ' Expected 2 or 4 but got %d' % (inputs.name,
                                                        original_rank))
    if original_rank == 2:
      channels = inputs.get_shape()[-1].value
      if channels is None:
        raise ValueError('`C` dimension must be known but is None')
      new_shape = [-1, 1, 1, channels]
      if data_format == 'NCHW':
        new_shape = [-1, channels, 1, 1]
      inputs = tf.reshape(inputs, new_shape)
    inputs_shape = inputs.get_shape()
    if data_format == 'NHWC':
      params_shape = inputs_shape[-1:]
    else:
      params_shape = inputs_shape[1:2]
    if not params_shape.is_fully_defined():
      raise ValueError('Inputs %s has undefined `C` dimension %s.' %
                       (inputs.name, params_shape))

    # Allocate parameters for the beta and gamma of the normalization.
    trainable_beta = trainable and center
    collections = [tf.GraphKeys.MODEL_VARIABLES, tf.GraphKeys.GLOBAL_VARIABLES]
    beta = contrib_framework.variable(
        'beta',
        params_shape,
        collections=collections,
        initializer=tf.zeros_initializer(),
        trainable=trainable_beta)
    trainable_gamma = trainable and scale
    gamma = contrib_framework.variable(
        'gamma',
        params_shape,
        collections=collections,
        initializer=tf.ones_initializer(),
        trainable=trainable_gamma)

    # Create moving_mean and moving_variance variables and add them to the
    # appropiate collections.
    moving_collections = [moving_vars,
                          tf.GraphKeys.MOVING_AVERAGE_VARIABLES,
                          tf.GraphKeys.MODEL_VARIABLES,
                          tf.GraphKeys.GLOBAL_VARIABLES]
    # Disable partition setting for moving_mean and moving_variance
    # as assign_moving_average op below doesn't support partitioned variable.
    scope = tf.get_variable_scope()
    partitioner = scope.partitioner
    scope.set_partitioner(None)
    moving_mean = contrib_framework.variable(
        'moving_mean',
        params_shape,
        initializer=tf.zeros_initializer(),
        trainable=False,
        collections=moving_collections)
    moving_variance = contrib_framework.variable(
        'moving_variance',
        params_shape,
        initializer=tf.ones_initializer(),
        trainable=False,
        collections=moving_collections)
    # Restore scope's partitioner setting.
    scope.set_partitioner(partitioner)

    # Add cross replica sum to do subset mean and variance calculation
    # First compute mean and variance
    if is_training:
      if distributed_group_size > 1:
        # Execute a distributed batch normalization
        if data_format == 'NCHW':
          axis = 1
        else:
          axis = 3
        input_shape = inputs.get_shape()
        inputs_dtype = inputs.dtype
        inputs = tf.cast(inputs, tf.float32)
        ndims = len(input_shape)
        reduction_axes = [i for i in range(ndims) if i != axis]
        counts, mean_ss, variance_ss, _ = tf.nn.sufficient_statistics(
            inputs, reduction_axes, keep_dims=False)
        mean_ss = cross_replica_average(mean_ss, num_shards,
                                        distributed_group_size)
        variance_ss = cross_replica_average(variance_ss, num_shards,
                                            distributed_group_size)
        mean, variance = tf.nn.normalize_moments(
            counts, mean_ss, variance_ss, shift=None)
        outputs = tf.nn.batch_normalization(inputs, mean, variance, beta, gamma,
                                            epsilon)
        outputs = tf.cast(outputs, inputs_dtype)
      else:
        outputs, mean, variance = tf.nn.fused_batch_norm(
            inputs, gamma, beta, epsilon=epsilon, data_format=data_format)
    else:
      outputs, mean, variance = tf.nn.fused_batch_norm(
          inputs,
          gamma,
          beta,
          mean=moving_mean,
          variance=moving_variance,
          epsilon=epsilon,
          is_training=False,
          data_format=data_format)

    if is_training:
      update_moving_mean = moving_averages.assign_moving_average(
          moving_mean,
          tf.cast(mean, moving_mean.dtype),
          decay,
          zero_debias=False)
      update_moving_variance = moving_averages.assign_moving_average(
          moving_variance,
          tf.cast(variance, moving_variance.dtype),
          decay,
          zero_debias=False)
      tf.add_to_collection('update_ops', update_moving_mean)
      tf.add_to_collection('update_ops', update_moving_variance)

    outputs.set_shape(inputs_shape)
    if original_shape.ndims == 2:
      outputs = tf.reshape(outputs, original_shape)
    if activation_fn is not None:
      outputs = activation_fn(outputs)
    return outputs