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from collections import defaultdict | |
from collections.abc import MutableMapping | |
import enum | |
import itertools | |
from typing import BinaryIO, DefaultDict, List, Tuple, Union, Optional | |
import numpy as np | |
import h5py | |
from mlagents_envs.exception import UnityException | |
# Elements in the buffer can be np.ndarray, or in the case of teammate obs, actions, rewards, | |
# a List of np.ndarray. This is done so that we don't have duplicated np.ndarrays, only references. | |
BufferEntry = Union[np.ndarray, List[np.ndarray]] | |
class BufferException(UnityException): | |
""" | |
Related to errors with the Buffer. | |
""" | |
pass | |
class BufferKey(enum.Enum): | |
ACTION_MASK = "action_mask" | |
CONTINUOUS_ACTION = "continuous_action" | |
NEXT_CONT_ACTION = "next_continuous_action" | |
CONTINUOUS_LOG_PROBS = "continuous_log_probs" | |
DISCRETE_ACTION = "discrete_action" | |
NEXT_DISC_ACTION = "next_discrete_action" | |
DISCRETE_LOG_PROBS = "discrete_log_probs" | |
DONE = "done" | |
ENVIRONMENT_REWARDS = "environment_rewards" | |
MASKS = "masks" | |
MEMORY = "memory" | |
CRITIC_MEMORY = "critic_memory" | |
BASELINE_MEMORY = "poca_baseline_memory" | |
PREV_ACTION = "prev_action" | |
ADVANTAGES = "advantages" | |
DISCOUNTED_RETURNS = "discounted_returns" | |
GROUP_DONES = "group_dones" | |
GROUPMATE_REWARDS = "groupmate_reward" | |
GROUP_REWARD = "group_reward" | |
GROUP_CONTINUOUS_ACTION = "group_continuous_action" | |
GROUP_DISCRETE_ACTION = "group_discrete_aaction" | |
GROUP_NEXT_CONT_ACTION = "group_next_cont_action" | |
GROUP_NEXT_DISC_ACTION = "group_next_disc_action" | |
class ObservationKeyPrefix(enum.Enum): | |
OBSERVATION = "obs" | |
NEXT_OBSERVATION = "next_obs" | |
GROUP_OBSERVATION = "group_obs" | |
NEXT_GROUP_OBSERVATION = "next_group_obs" | |
class RewardSignalKeyPrefix(enum.Enum): | |
# Reward signals | |
REWARDS = "rewards" | |
VALUE_ESTIMATES = "value_estimates" | |
RETURNS = "returns" | |
ADVANTAGE = "advantage" | |
BASELINES = "baselines" | |
AgentBufferKey = Union[ | |
BufferKey, Tuple[ObservationKeyPrefix, int], Tuple[RewardSignalKeyPrefix, str] | |
] | |
class RewardSignalUtil: | |
def rewards_key(name: str) -> AgentBufferKey: | |
return RewardSignalKeyPrefix.REWARDS, name | |
def value_estimates_key(name: str) -> AgentBufferKey: | |
return RewardSignalKeyPrefix.RETURNS, name | |
def returns_key(name: str) -> AgentBufferKey: | |
return RewardSignalKeyPrefix.RETURNS, name | |
def advantage_key(name: str) -> AgentBufferKey: | |
return RewardSignalKeyPrefix.ADVANTAGE, name | |
def baseline_estimates_key(name: str) -> AgentBufferKey: | |
return RewardSignalKeyPrefix.BASELINES, name | |
class AgentBufferField(list): | |
""" | |
AgentBufferField is a list of numpy arrays, or List[np.ndarray] for group entries. | |
When an agent collects a field, you can add it to its AgentBufferField with the append method. | |
""" | |
def __init__(self, *args, **kwargs): | |
self.padding_value = 0 | |
super().__init__(*args, **kwargs) | |
def __str__(self) -> str: | |
return f"AgentBufferField: {super().__str__()}" | |
def __getitem__(self, index): | |
return_data = super().__getitem__(index) | |
if isinstance(return_data, list): | |
return AgentBufferField(return_data) | |
else: | |
return return_data | |
def contains_lists(self) -> bool: | |
""" | |
Checks whether this AgentBufferField contains List[np.ndarray]. | |
""" | |
return len(self) > 0 and isinstance(self[0], list) | |
def append(self, element: BufferEntry, padding_value: float = 0.0) -> None: | |
""" | |
Adds an element to this list. Also lets you change the padding | |
type, so that it can be set on append (e.g. action_masks should | |
be padded with 1.) | |
:param element: The element to append to the list. | |
:param padding_value: The value used to pad when get_batch is called. | |
""" | |
super().append(element) | |
self.padding_value = padding_value | |
def set(self, data: List[BufferEntry]) -> None: | |
""" | |
Sets the list of BufferEntry to the input data | |
:param data: The BufferEntry list to be set. | |
""" | |
self[:] = data | |
def get_batch( | |
self, | |
batch_size: int = None, | |
training_length: Optional[int] = 1, | |
sequential: bool = True, | |
) -> List[BufferEntry]: | |
""" | |
Retrieve the last batch_size elements of length training_length | |
from the list of np.array | |
:param batch_size: The number of elements to retrieve. If None: | |
All elements will be retrieved. | |
:param training_length: The length of the sequence to be retrieved. If | |
None: only takes one element. | |
:param sequential: If true and training_length is not None: the elements | |
will not repeat in the sequence. [a,b,c,d,e] with training_length = 2 and | |
sequential=True gives [[0,a],[b,c],[d,e]]. If sequential=False gives | |
[[a,b],[b,c],[c,d],[d,e]] | |
""" | |
if training_length is None: | |
training_length = 1 | |
if sequential: | |
# The sequences will not have overlapping elements (this involves padding) | |
leftover = len(self) % training_length | |
# leftover is the number of elements in the first sequence (this sequence might need 0 padding) | |
if batch_size is None: | |
# retrieve the maximum number of elements | |
batch_size = len(self) // training_length + 1 * (leftover != 0) | |
# The maximum number of sequences taken from a list of length len(self) without overlapping | |
# with padding is equal to batch_size | |
if batch_size > (len(self) // training_length + 1 * (leftover != 0)): | |
raise BufferException( | |
"The batch size and training length requested for get_batch where" | |
" too large given the current number of data points." | |
) | |
if batch_size * training_length > len(self): | |
if self.contains_lists: | |
padding = [] | |
else: | |
# We want to duplicate the last value in the array, multiplied by the padding_value. | |
padding = np.array(self[-1], dtype=np.float32) * self.padding_value | |
return self[:] + [padding] * (training_length - leftover) | |
else: | |
return self[len(self) - batch_size * training_length :] | |
else: | |
# The sequences will have overlapping elements | |
if batch_size is None: | |
# retrieve the maximum number of elements | |
batch_size = len(self) - training_length + 1 | |
# The number of sequences of length training_length taken from a list of len(self) elements | |
# with overlapping is equal to batch_size | |
if (len(self) - training_length + 1) < batch_size: | |
raise BufferException( | |
"The batch size and training length requested for get_batch where" | |
" too large given the current number of data points." | |
) | |
tmp_list: List[np.ndarray] = [] | |
for end in range(len(self) - batch_size + 1, len(self) + 1): | |
tmp_list += self[end - training_length : end] | |
return tmp_list | |
def reset_field(self) -> None: | |
""" | |
Resets the AgentBufferField | |
""" | |
self[:] = [] | |
def padded_to_batch( | |
self, pad_value: np.float = 0, dtype: np.dtype = np.float32 | |
) -> Union[np.ndarray, List[np.ndarray]]: | |
""" | |
Converts this AgentBufferField (which is a List[BufferEntry]) into a numpy array | |
with first dimension equal to the length of this AgentBufferField. If this AgentBufferField | |
contains a List[List[BufferEntry]] (i.e., in the case of group observations), return a List | |
containing numpy arrays or tensors, of length equal to the maximum length of an entry. Missing | |
For entries with less than that length, the array will be padded with pad_value. | |
:param pad_value: Value to pad List AgentBufferFields, when there are less than the maximum | |
number of agents present. | |
:param dtype: Dtype of output numpy array. | |
:return: Numpy array or List of numpy arrays representing this AgentBufferField, where the first | |
dimension is equal to the length of the AgentBufferField. | |
""" | |
if len(self) > 0 and not isinstance(self[0], list): | |
return np.asanyarray(self, dtype=dtype) | |
shape = None | |
for _entry in self: | |
# _entry could be an empty list if there are no group agents in this | |
# step. Find the first non-empty list and use that shape. | |
if _entry: | |
shape = _entry[0].shape | |
break | |
# If there were no groupmate agents in the entire batch, return an empty List. | |
if shape is None: | |
return [] | |
# Convert to numpy array while padding with 0's | |
new_list = list( | |
map( | |
lambda x: np.asanyarray(x, dtype=dtype), | |
itertools.zip_longest(*self, fillvalue=np.full(shape, pad_value)), | |
) | |
) | |
return new_list | |
def to_ndarray(self): | |
""" | |
Returns the AgentBufferField which is a list of numpy ndarrays (or List[np.ndarray]) as an ndarray. | |
""" | |
return np.array(self) | |
class AgentBuffer(MutableMapping): | |
""" | |
AgentBuffer contains a dictionary of AgentBufferFields. Each agent has his own AgentBuffer. | |
The keys correspond to the name of the field. Example: state, action | |
""" | |
# Whether or not to validate the types of keys at runtime | |
# This should be off for training, but enabled for testing | |
CHECK_KEY_TYPES_AT_RUNTIME = False | |
def __init__(self): | |
self.last_brain_info = None | |
self.last_take_action_outputs = None | |
self._fields: DefaultDict[AgentBufferKey, AgentBufferField] = defaultdict( | |
AgentBufferField | |
) | |
def __str__(self): | |
return ", ".join([f"'{k}' : {str(self[k])}" for k in self._fields.keys()]) | |
def reset_agent(self) -> None: | |
""" | |
Resets the AgentBuffer | |
""" | |
for f in self._fields.values(): | |
f.reset_field() | |
self.last_brain_info = None | |
self.last_take_action_outputs = None | |
def _check_key(key): | |
if isinstance(key, BufferKey): | |
return | |
if isinstance(key, tuple): | |
key0, key1 = key | |
if isinstance(key0, ObservationKeyPrefix): | |
if isinstance(key1, int): | |
return | |
raise KeyError(f"{key} has type ({type(key0)}, {type(key1)})") | |
if isinstance(key0, RewardSignalKeyPrefix): | |
if isinstance(key1, str): | |
return | |
raise KeyError(f"{key} has type ({type(key0)}, {type(key1)})") | |
raise KeyError(f"{key} is a {type(key)}") | |
def _encode_key(key: AgentBufferKey) -> str: | |
""" | |
Convert the key to a string representation so that it can be used for serialization. | |
""" | |
if isinstance(key, BufferKey): | |
return key.value | |
prefix, suffix = key | |
return f"{prefix.value}:{suffix}" | |
def _decode_key(encoded_key: str) -> AgentBufferKey: | |
""" | |
Convert the string representation back to a key after serialization. | |
""" | |
# Simple case: convert the string directly to a BufferKey | |
try: | |
return BufferKey(encoded_key) | |
except ValueError: | |
pass | |
# Not a simple key, so split into two parts | |
prefix_str, _, suffix_str = encoded_key.partition(":") | |
# See if it's an ObservationKeyPrefix first | |
try: | |
return ObservationKeyPrefix(prefix_str), int(suffix_str) | |
except ValueError: | |
pass | |
# If not, it had better be a RewardSignalKeyPrefix | |
try: | |
return RewardSignalKeyPrefix(prefix_str), suffix_str | |
except ValueError: | |
raise ValueError(f"Unable to convert {encoded_key} to an AgentBufferKey") | |
def __getitem__(self, key: AgentBufferKey) -> AgentBufferField: | |
if self.CHECK_KEY_TYPES_AT_RUNTIME: | |
self._check_key(key) | |
return self._fields[key] | |
def __setitem__(self, key: AgentBufferKey, value: AgentBufferField) -> None: | |
if self.CHECK_KEY_TYPES_AT_RUNTIME: | |
self._check_key(key) | |
self._fields[key] = value | |
def __delitem__(self, key: AgentBufferKey) -> None: | |
if self.CHECK_KEY_TYPES_AT_RUNTIME: | |
self._check_key(key) | |
self._fields.__delitem__(key) | |
def __iter__(self): | |
return self._fields.__iter__() | |
def __len__(self) -> int: | |
return self._fields.__len__() | |
def __contains__(self, key): | |
if self.CHECK_KEY_TYPES_AT_RUNTIME: | |
self._check_key(key) | |
return self._fields.__contains__(key) | |
def check_length(self, key_list: List[AgentBufferKey]) -> bool: | |
""" | |
Some methods will require that some fields have the same length. | |
check_length will return true if the fields in key_list | |
have the same length. | |
:param key_list: The fields which length will be compared | |
""" | |
if self.CHECK_KEY_TYPES_AT_RUNTIME: | |
for k in key_list: | |
self._check_key(k) | |
if len(key_list) < 2: | |
return True | |
length = None | |
for key in key_list: | |
if key not in self._fields: | |
return False | |
if (length is not None) and (length != len(self[key])): | |
return False | |
length = len(self[key]) | |
return True | |
def shuffle( | |
self, sequence_length: int, key_list: List[AgentBufferKey] = None | |
) -> None: | |
""" | |
Shuffles the fields in key_list in a consistent way: The reordering will | |
be the same across fields. | |
:param key_list: The fields that must be shuffled. | |
""" | |
if key_list is None: | |
key_list = list(self._fields.keys()) | |
if not self.check_length(key_list): | |
raise BufferException( | |
"Unable to shuffle if the fields are not of same length" | |
) | |
s = np.arange(len(self[key_list[0]]) // sequence_length) | |
np.random.shuffle(s) | |
for key in key_list: | |
buffer_field = self[key] | |
tmp: List[np.ndarray] = [] | |
for i in s: | |
tmp += buffer_field[i * sequence_length : (i + 1) * sequence_length] | |
buffer_field.set(tmp) | |
def make_mini_batch(self, start: int, end: int) -> "AgentBuffer": | |
""" | |
Creates a mini-batch from buffer. | |
:param start: Starting index of buffer. | |
:param end: Ending index of buffer. | |
:return: Dict of mini batch. | |
""" | |
mini_batch = AgentBuffer() | |
for key, field in self._fields.items(): | |
# slicing AgentBufferField returns a List[Any} | |
mini_batch[key] = field[start:end] # type: ignore | |
return mini_batch | |
def sample_mini_batch( | |
self, batch_size: int, sequence_length: int = 1 | |
) -> "AgentBuffer": | |
""" | |
Creates a mini-batch from a random start and end. | |
:param batch_size: number of elements to withdraw. | |
:param sequence_length: Length of sequences to sample. | |
Number of sequences to sample will be batch_size/sequence_length. | |
""" | |
num_seq_to_sample = batch_size // sequence_length | |
mini_batch = AgentBuffer() | |
buff_len = self.num_experiences | |
num_sequences_in_buffer = buff_len // sequence_length | |
start_idxes = ( | |
np.random.randint(num_sequences_in_buffer, size=num_seq_to_sample) | |
* sequence_length | |
) # Sample random sequence starts | |
for key in self: | |
buffer_field = self[key] | |
mb_list = (buffer_field[i : i + sequence_length] for i in start_idxes) | |
# See comparison of ways to make a list from a list of lists here: | |
# https://stackoverflow.com/questions/952914/how-to-make-a-flat-list-out-of-list-of-lists | |
mini_batch[key].set(list(itertools.chain.from_iterable(mb_list))) | |
return mini_batch | |
def save_to_file(self, file_object: BinaryIO) -> None: | |
""" | |
Saves the AgentBuffer to a file-like object. | |
""" | |
with h5py.File(file_object, "w") as write_file: | |
for key, data in self.items(): | |
write_file.create_dataset( | |
self._encode_key(key), data=data, dtype="f", compression="gzip" | |
) | |
def load_from_file(self, file_object: BinaryIO) -> None: | |
""" | |
Loads the AgentBuffer from a file-like object. | |
""" | |
with h5py.File(file_object, "r") as read_file: | |
for key in list(read_file.keys()): | |
decoded_key = self._decode_key(key) | |
self[decoded_key] = AgentBufferField() | |
# extend() will convert the numpy array's first dimension into list | |
self[decoded_key].extend(read_file[key][()]) | |
def truncate(self, max_length: int, sequence_length: int = 1) -> None: | |
""" | |
Truncates the buffer to a certain length. | |
This can be slow for large buffers. We compensate by cutting further than we need to, so that | |
we're not truncating at each update. Note that we must truncate an integer number of sequence_lengths | |
param: max_length: The length at which to truncate the buffer. | |
""" | |
current_length = self.num_experiences | |
# make max_length an integer number of sequence_lengths | |
max_length -= max_length % sequence_length | |
if current_length > max_length: | |
for _key in self.keys(): | |
self[_key][:] = self[_key][current_length - max_length :] | |
def resequence_and_append( | |
self, | |
target_buffer: "AgentBuffer", | |
key_list: List[AgentBufferKey] = None, | |
batch_size: int = None, | |
training_length: int = None, | |
) -> None: | |
""" | |
Takes in a batch size and training length (sequence length), and appends this AgentBuffer to target_buffer | |
properly padded for LSTM use. Optionally, use key_list to restrict which fields are inserted into the new | |
buffer. | |
:param target_buffer: The buffer which to append the samples to. | |
:param key_list: The fields that must be added. If None: all fields will be appended. | |
:param batch_size: The number of elements that must be appended. If None: All of them will be. | |
:param training_length: The length of the samples that must be appended. If None: only takes one element. | |
""" | |
if key_list is None: | |
key_list = list(self.keys()) | |
if not self.check_length(key_list): | |
raise BufferException( | |
f"The length of the fields {key_list} were not of same length" | |
) | |
for field_key in key_list: | |
target_buffer[field_key].extend( | |
self[field_key].get_batch( | |
batch_size=batch_size, training_length=training_length | |
) | |
) | |
def num_experiences(self) -> int: | |
""" | |
The number of agent experiences in the AgentBuffer, i.e. the length of the buffer. | |
An experience consists of one element across all of the fields of this AgentBuffer. | |
Note that these all have to be the same length, otherwise shuffle and append_to_update_buffer | |
will fail. | |
""" | |
if self.values(): | |
return len(next(iter(self.values()))) | |
else: | |
return 0 | |