class AdversarialEnvironmentScalar(tf_metric.TFStepMetric):
"""Metric to compute average of simple scalars like number of obstacles."""
def __init__(self,
name,
prefix='Metrics',
dtype=tf.float32,
batch_size=1,
buffer_size=10):
super(AdversarialEnvironmentScalar, self).__init__(name=name,
prefix=prefix)
self._buffer = TFDeque(buffer_size, dtype)
self._dtype = dtype
@common.function(autograph=True)
def call(self, new_scalar_vals):
for v in new_scalar_vals:
self._buffer.add(v)
return new_scalar_vals
def result(self):
return self._buffer.mean()
@common.function
def reset(self):
self._buffer.clear()
class ActionProbabilityMetric(TFStepMetric):
"""
A metric that records the average action probabilities over a given period.
Implementation similar to tf_agent.metrics.tf_metrics.AverageReturnMetric
"""
def __init__(self,
policy: tf_policy.TFPolicy,
action_indices: Tuple[int, ...],
name: str = 'ActionProbability',
prefix: str = 'Metrics',
dtype: Type = tf.float32,
batch_size: int = 1,
buffer_size: int = 10):
"""
:param policy: Policy of the agent used for reevaluation to attain action probabilities at
each time step.
:param action_indices: A tuple of indices of the action probability vector to track. This is
a tuple to allow for the case where the action is a tuple of tensors.
:param name: Name of the metric (as it will appear in tensorboard).
:param prefix: Prefix to apply as part of the naming convention.
:param dtype: Data type of the metric.
:param batch_size: Batch size of the RL environment.
:param buffer_size: The capacity of the buffer which will rewrite itself when full but is
emptied at every logging point.
"""
super().__init__(name=name, prefix=prefix)
self._action_indices = action_indices
self._dtype = dtype
self._probability_accumulator = common.create_variable(
initial_value=0, dtype=dtype, shape=(batch_size,), name='Accumulator'
)
self._policy = policy
self._buffer = TFDeque(buffer_size, dtype)
self._count_accumulator = common.create_variable(
initial_value=0, dtype=dtype, shape=(batch_size,), name='CountAccumulator'
)
@common.function(autograph=True)
def call(self, trajectory: Trajectory) -> Trajectory:
time_step = TimeStep(trajectory.step_type, trajectory.reward, trajectory.discount,
trajectory.observation)
action_dist = self._policy.distribution(time_step).action
# If the action distribution is in fact a tuple of distributions (one for each resource set)
# then we need to index into them to attain the underlying distribution which can then be
# used to attain probabilities. This is only the case where there are multiple resource
# sets.
for i in self._action_indices[:-1]:
action_dist = action_dist[i]
action_probs = action_dist.probs_parameter()
# Zero out batch indices where a new episode is starting.
self._probability_accumulator.assign(
tf.where(trajectory.is_first(), tf.zeros_like(self._probability_accumulator),
self._probability_accumulator))
self._count_accumulator.assign(
tf.where(trajectory.is_first(), tf.zeros_like(self._count_accumulator),
self._count_accumulator))
# Update accumulators with probability and count increments.
self._probability_accumulator.assign_add(action_probs[..., 0, self._action_indices[-1]])
self._count_accumulator.assign_add(tf.ones_like(self._count_accumulator))
# Add final cumulants to buffer at the end of episodes.
last_episode_indices = tf.squeeze(tf.where(trajectory.is_last()), axis=-1)
for idx in last_episode_indices:
self._buffer.add(self._probability_accumulator[idx] / self._count_accumulator[idx])
return trajectory
def result(self) -> tf.Tensor:
"""Return the metric value."""
return self._buffer.mean()
@common.function
def reset(self) -> None:
"""Clear the buffer and reset the accumulators."""
self._buffer.clear()
self._probability_accumulator.assign(tf.zeros_like(self._probability_accumulator))
self._count_accumulator.assign(tf.zeros_like(self._count_accumulator))
@property
def action_indices(self) -> Tuple[int, ...]:
return self._action_indices
class AverageReturnMetric(tf_metric.TFStepMetric):
"""Metric for the average collective return and individual agent returns."""
def __init__(self,
n_agents,
name='MultiagentAverageReturn',
prefix='Metrics',
dtype=tf.float32,
batch_size=1,
buffer_size=10):
super(AverageReturnMetric, self).__init__(name=name, prefix=prefix)
self.n_agents = n_agents
self._dtype = dtype
# Accumulator and buffer for the average return of all agents
self._collective_return_accumulator = common.create_variable(
initial_value=0,
dtype=dtype,
shape=(batch_size, ),
name='Accumulator')
self._collective_buffer = TFDeque(buffer_size, dtype)
# Accumulators for each agent's independent reward
self._agent_return_accumulators = []
for a in range(n_agents):
self._agent_return_accumulators.append(
common.create_variable(initial_value=0,
dtype=dtype,
shape=(batch_size, ),
name='Accumulator' + str(a)))
# Buffers for each agent's independent reward
self._agent_buffers = []
for a in range(n_agents):
self._agent_buffers.append(TFDeque(buffer_size, dtype))
@common.function(autograph=True)
def call(self, trajectory):
# Zero out batch indices where a new episode is starting.
self._collective_return_accumulator.assign(
zero_out_new_episodes(trajectory,
self._collective_return_accumulator))
for a in range(self.n_agents):
self._agent_return_accumulators[a].assign(
zero_out_new_episodes(trajectory,
self._agent_return_accumulators[a]))
# Note that trajectory.reward has shape (batch, n_agents)
# Update accumulator with sum of received rewards.
self._collective_return_accumulator.assign_add(
tf.reduce_mean(trajectory.reward, axis=1))
# Pull out data for each agent and assign
for a in range(self.n_agents):
self._agent_return_accumulators[a].assign_add(trajectory.reward[:,
a])
# Add final returns to buffer.
last_episode_indices = tf.squeeze(tf.where(trajectory.is_last()),
axis=-1)
for indx in last_episode_indices:
self._collective_buffer.add(
self._collective_return_accumulator[indx])
# Agent buffers that use the global done
for a in range(self.n_agents):
self._agent_buffers[a].add(
self._agent_return_accumulators[a][indx])
return trajectory
def result(self):
return self._collective_buffer.mean()
def result_for_agent(self, agent_id):
return self._agent_buffers[agent_id].mean()
@common.function
def reset(self):
self._collective_buffer.clear()
self._collective_return_accumulator.assign(
tf.zeros_like(self._collective_return_accumulator))
for a in range(self.n_agents):
self._agent_buffers[a].clear()
self._agent_return_accumulators[a].assign(
tf.zeros_like(self._agent_return_accumulators[a]))
def tf_summaries(self, train_step=None, step_metrics=()):
"""Generates summaries for all agents & collective summary against steps.
Args:
train_step: (Optional) Step counter for training iterations. If None, no
metric is generated against the global step.
step_metrics: (Optional) Iterable of step metrics to generate summaries
against.
Returns:
A list of summaries.
"""
summaries = super(AverageReturnMetric,
self).tf_summaries(train_step=train_step,
step_metrics=step_metrics)
for a in range(self.n_agents):
summaries.extend(
self.single_agent_summary(a, train_step, step_metrics))
return summaries
def single_agent_summary(self, agent_id, train_step=None, step_metrics=()):
summaries = []
prefix = self._prefix
name = self.name + '_agent' + str(agent_id)
tag = common.join_scope(prefix, name)
result = self.result_for_agent(agent_id)
if train_step is not None:
summaries.append(
tf.compat.v2.summary.scalar(name=tag,
data=result,
step=train_step))
if prefix:
prefix += '_'
for step_metric in step_metrics:
# Skip plotting the metrics against itself.
if self.name == step_metric.name:
continue
step_tag = '{}vs_{}/{}'.format(prefix, step_metric.name, name)
# Summaries expect the step value to be an int64.
step = tf.cast(step_metric.result(), tf.int64)
summaries.append(
tf.compat.v2.summary.scalar(name=step_tag,
data=result,
step=step))
return summaries
class EpisodicConditionalActivityTracker1D(TFStepMetric):
def __init__(self,
filter_condition: Callable,
activity_condition: Callable,
name: str,
prefix: str = "Metrics",
dtype: type = tf.int32,
batch_size: int = 1,
buffer_size: int = 10):
"""
Custom TensorFlow metric which tracks activity in states which satisfy a certain condition.
Used for example to see the behaviour of an agent when the buffers reach a certain level.
:param filter_condition: The condition which determines which time steps to use for
calculation. This defines the denominator.
:param activity_condition: The condition which determines when the tracked activity occurs.
This defined the numerator.
:param name: Name of the metric as will be shown in TensorBoard.
:param prefix: The name of the logging group to which this metric belongs.
:param dtype: The data type of the metric and the components used for its calculation.
Data type must be compatible with tf.reduce_sum (i.e. float or int).
:param batch_size: The batch size of the environment.
:param buffer_size: The length of the buffer used to store historical values of the metric.
"""
# Initialise according to the parent class then add the inputs as attributes.
super(EpisodicConditionalActivityTracker1D, self).__init__(name=name, prefix=prefix)
self.filter_condition = filter_condition
self.activity_condition = activity_condition
self._dtype = dtype
self._batch_size = batch_size
# Build variables and storage to be used for storing and calculating the metrics.
self._activity_buffer = TFDeque(buffer_size, dtype)
self._qualifying_timesteps_buffer = TFDeque(buffer_size, dtype)
# The activity accumulator becomes the numerator of the calculated rate/proportion.
self._activity_accumulator = common.create_variable(
initial_value=0, dtype=dtype, shape=(batch_size,), name='ActivityAccumulator')
# The number of valid time steps becomes the denominator of the calculated rate/proportion.
self._num_valid_timesteps = common.create_variable(
initial_value=0, dtype=dtype, shape=(batch_size,), name='EpLenAccumulator')
@common.function(autograph=True)
def call(self, trajectory: Trajectory) -> Trajectory:
"""
Process the experience passed in to update the metric value (or the components required to
calculate the final value).
:param trajectory: Experience from the agent rolling out in the environment.
:return: The unchanged input trajectory (as per the standard use of TensorFlow Metrics).
"""
start_of_episode_indices = tf.squeeze(tf.where(trajectory.is_first()), axis=-1)
mask = tf.ones(shape=(self._batch_size,), dtype=self._dtype)
for idx in start_of_episode_indices:
mask -= tf.eye(self._batch_size)[idx]
# Reset the accumulators at the end of each episode.
self._num_valid_timesteps.assign(self._num_valid_timesteps * mask)
self._activity_accumulator.assign(self._activity_accumulator * mask)
# Find the number of time steps satisfying the filter condition.
# The reshape is to ensure compatibility with the variable below in the case of no batch
# dimension.
valid_timesteps = tf.reshape(
tf.reduce_sum(
tf.cast(self.filter_condition(trajectory), self._dtype),
axis=-1),
self._num_valid_timesteps.shape)
# Track the number of time steps which meet the qualifying condition.
self._num_valid_timesteps.assign_add(valid_timesteps, name="increment_valid_timesteps")
# Update accumulator with activity counts where both the filtering and activity condition
# are satisfied. Again the reshape is to ensure compatibility with the accumulator
# variable in the case where there is no batch dimension.
bool_values = tf.logical_and(self.filter_condition(trajectory),
self.activity_condition(trajectory))
to_add = tf.reshape(
tf.reduce_sum(tf.cast(bool_values, self._dtype), axis=-1),
self._activity_accumulator.shape)
self._activity_accumulator.assign_add(to_add)
# Add values to buffer at the end of the episode by first finding where the trajectories end
# and then using the resulting indices to update the correct buffer locations.
# At the same time build up a mask of values to use for resetting the accumulators.
end_of_episode_indices = tf.squeeze(tf.where(trajectory.step_type == 2), axis=-1)
for idx in end_of_episode_indices:
self._activity_buffer.add(self._activity_accumulator[idx])
self._qualifying_timesteps_buffer.add(self._num_valid_timesteps[idx])
# Return the original trajectory data as is standard for TFStepMetrics.
return trajectory
def result(self) -> tf.Tensor:
"""
Calculate the value of the metric from stored components.
:return: The calculated metric value.
"""
return tf.reduce_mean(self._activity_buffer.data / self._qualifying_timesteps_buffer.data)
@common.function
def reset(self) -> None:
"""Reset the metric calculation components."""
pass
self._activity_buffer.clear()
self._qualifying_timesteps_buffer.clear()
self._activity_accumulator.assign(tf.zeros_like(self._activity_accumulator))
self._num_valid_timesteps.assign(tf.zeros_like(self._num_valid_timesteps))