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368 行
14 KiB
368 行
14 KiB
from mlagents_envs.base_env import (
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ActionSpec,
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ObservationSpec,
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DimensionProperty,
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BehaviorSpec,
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DecisionSteps,
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TerminalSteps,
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ObservationType,
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)
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from mlagents_envs.exception import UnityObservationException
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from mlagents_envs.timers import hierarchical_timer, timed
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from mlagents_envs.communicator_objects.agent_info_pb2 import AgentInfoProto
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from mlagents_envs.communicator_objects.observation_pb2 import (
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ObservationProto,
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NONE as COMPRESSION_TYPE_NONE,
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)
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from mlagents_envs.communicator_objects.brain_parameters_pb2 import BrainParametersProto
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import numpy as np
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import io
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from typing import cast, List, Tuple, Collection, Optional, Iterable
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from PIL import Image
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PNG_HEADER = b"\x89PNG\r\n\x1a\n"
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def behavior_spec_from_proto(
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brain_param_proto: BrainParametersProto, agent_info: AgentInfoProto
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) -> BehaviorSpec:
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"""
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Converts brain parameter and agent info proto to BehaviorSpec object.
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:param brain_param_proto: protobuf object.
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:param agent_info: protobuf object.
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:return: BehaviorSpec object.
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"""
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observation_specs = []
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for obs in agent_info.observations:
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observation_specs.append(
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ObservationSpec(
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tuple(obs.shape),
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tuple(DimensionProperty(dim) for dim in obs.dimension_properties)
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if len(obs.dimension_properties) > 0
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else (DimensionProperty.UNSPECIFIED,) * len(obs.shape),
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ObservationType(obs.observation_type),
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)
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)
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# proto from communicator < v1.3 does not set action spec, use deprecated fields instead
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if (
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brain_param_proto.action_spec.num_continuous_actions == 0
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and brain_param_proto.action_spec.num_discrete_actions == 0
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):
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if brain_param_proto.vector_action_space_type_deprecated == 1:
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action_spec = ActionSpec(
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brain_param_proto.vector_action_size_deprecated[0], ()
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)
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else:
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action_spec = ActionSpec(
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0, tuple(brain_param_proto.vector_action_size_deprecated)
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)
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else:
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action_spec_proto = brain_param_proto.action_spec
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action_spec = ActionSpec(
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action_spec_proto.num_continuous_actions,
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tuple(branch for branch in action_spec_proto.discrete_branch_sizes),
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)
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return BehaviorSpec(observation_specs, action_spec)
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class OffsetBytesIO:
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"""
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Simple file-like class that wraps a bytes, and allows moving its "start"
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position in the bytes. This is only used for reading concatenated PNGs,
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because Pillow always calls seek(0) at the start of reading.
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"""
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__slots__ = ["fp", "offset"]
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def __init__(self, data: bytes):
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self.fp = io.BytesIO(data)
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self.offset = 0
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def seek(self, offset: int, whence: int = io.SEEK_SET) -> int:
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if whence == io.SEEK_SET:
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res = self.fp.seek(offset + self.offset)
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return res - self.offset
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raise NotImplementedError()
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def tell(self) -> int:
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return self.fp.tell() - self.offset
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def read(self, size: int = -1) -> bytes:
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return self.fp.read(size)
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def original_tell(self) -> int:
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"""
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Returns the offset into the original byte array
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"""
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return self.fp.tell()
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@timed
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def process_pixels(
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image_bytes: bytes, expected_channels: int, mappings: Optional[List[int]] = None
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) -> np.ndarray:
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"""
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Converts byte array observation image into numpy array, re-sizes it,
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and optionally converts it to grey scale
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:param image_bytes: input byte array corresponding to image
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:param expected_channels: Expected output channels
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:return: processed numpy array of observation from environment
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"""
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image_fp = OffsetBytesIO(image_bytes)
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image_arrays = []
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# Read the images back from the bytes (without knowing the sizes).
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while True:
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with hierarchical_timer("image_decompress"):
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image = Image.open(image_fp)
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# Normally Image loads lazily, load() forces it to do loading in the timer scope.
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image.load()
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image_arrays.append(np.array(image, dtype=np.float32) / 255.0)
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# Look for the next header, starting from the current stream location
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try:
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new_offset = image_bytes.index(PNG_HEADER, image_fp.original_tell())
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image_fp.offset = new_offset
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except ValueError:
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# Didn't find the header, so must be at the end.
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break
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if mappings is not None and len(mappings) > 0:
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return _process_images_mapping(image_arrays, mappings)
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else:
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return _process_images_num_channels(image_arrays, expected_channels)
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def _process_images_mapping(image_arrays, mappings):
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"""
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Helper function for processing decompressed images with compressed channel mappings.
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"""
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image_arrays = np.concatenate(image_arrays, axis=2).transpose((2, 0, 1))
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if len(mappings) != len(image_arrays):
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raise UnityObservationException(
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f"Compressed observation and its mapping had different number of channels - "
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f"observation had {len(image_arrays)} channels but its mapping had {len(mappings)} channels"
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)
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if len({m for m in mappings if m > -1}) != max(mappings) + 1:
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raise UnityObservationException(
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f"Invalid Compressed Channel Mapping: the mapping {mappings} does not have the correct format."
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)
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if max(mappings) >= len(image_arrays):
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raise UnityObservationException(
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f"Invalid Compressed Channel Mapping: the mapping has index larger than the total "
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f"number of channels in observation - mapping index {max(mappings)} is"
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f"invalid for input observation with {len(image_arrays)} channels."
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)
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processed_image_arrays: List[np.array] = [[] for _ in range(max(mappings) + 1)]
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for mapping_idx, img in zip(mappings, image_arrays):
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if mapping_idx > -1:
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processed_image_arrays[mapping_idx].append(img)
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for i, img_array in enumerate(processed_image_arrays):
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processed_image_arrays[i] = np.mean(img_array, axis=0)
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img = np.stack(processed_image_arrays, axis=2)
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return img
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def _process_images_num_channels(image_arrays, expected_channels):
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"""
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Helper function for processing decompressed images with number of expected channels.
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This is for old API without mapping provided. Use the first n channel, n=expected_channels.
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"""
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if expected_channels == 1:
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# Convert to grayscale
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img = np.mean(image_arrays[0], axis=2)
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img = np.reshape(img, [img.shape[0], img.shape[1], 1])
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else:
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img = np.concatenate(image_arrays, axis=2)
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# We can drop additional channels since they may need to be added to include
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# numbers of observation channels not divisible by 3.
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actual_channels = list(img.shape)[2]
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if actual_channels > expected_channels:
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img = img[..., 0:expected_channels]
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return img
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@timed
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def observation_to_np_array(
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obs: ObservationProto, expected_shape: Optional[Iterable[int]] = None
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) -> np.ndarray:
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"""
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Converts observation proto into numpy array of the appropriate size.
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:param obs: observation proto to be converted
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:param expected_shape: optional shape information, used for sanity checks.
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:return: processed numpy array of observation from environment
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"""
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if expected_shape is not None:
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if list(obs.shape) != list(expected_shape):
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raise UnityObservationException(
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f"Observation did not have the expected shape - got {obs.shape} but expected {expected_shape}"
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)
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expected_channels = obs.shape[2]
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if obs.compression_type == COMPRESSION_TYPE_NONE:
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img = np.array(obs.float_data.data, dtype=np.float32)
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img = np.reshape(img, obs.shape)
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return img
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else:
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img = process_pixels(
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obs.compressed_data, expected_channels, list(obs.compressed_channel_mapping)
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)
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# Compare decompressed image size to observation shape and make sure they match
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if list(obs.shape) != list(img.shape):
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raise UnityObservationException(
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f"Decompressed observation did not have the expected shape - "
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f"decompressed had {img.shape} but expected {obs.shape}"
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)
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return img
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@timed
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def _process_visual_observation(
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obs_index: int,
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shape: Tuple[int, int, int],
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agent_info_list: Collection[AgentInfoProto],
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) -> np.ndarray:
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if len(agent_info_list) == 0:
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return np.zeros((0, shape[0], shape[1], shape[2]), dtype=np.float32)
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batched_visual = [
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observation_to_np_array(agent_obs.observations[obs_index], shape)
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for agent_obs in agent_info_list
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]
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return np.array(batched_visual, dtype=np.float32)
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def _raise_on_nan_and_inf(data: np.array, source: str) -> np.array:
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# Check for NaNs or Infinite values in the observation or reward data.
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# If there's a NaN in the observations, the np.mean() result will be NaN
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# If there's an Infinite value (either sign) then the result will be Inf
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# See https://stackoverflow.com/questions/6736590/fast-check-for-nan-in-numpy for background
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# Note that a very large values (larger than sqrt(float_max)) will result in an Inf value here
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# Raise a Runtime error in the case that NaNs or Infinite values make it into the data.
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if data.size == 0:
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return data
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d = np.mean(data)
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has_nan = np.isnan(d)
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has_inf = not np.isfinite(d)
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if has_nan:
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raise RuntimeError(f"The {source} provided had NaN values.")
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if has_inf:
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raise RuntimeError(f"The {source} provided had Infinite values.")
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@timed
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def _process_vector_observation(
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obs_index: int, shape: Tuple[int, ...], agent_info_list: Collection[AgentInfoProto]
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) -> np.ndarray:
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if len(agent_info_list) == 0:
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return np.zeros((0,) + shape, dtype=np.float32)
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np_obs = np.array(
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[
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agent_obs.observations[obs_index].float_data.data
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for agent_obs in agent_info_list
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],
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dtype=np.float32,
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).reshape((len(agent_info_list),) + shape)
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_raise_on_nan_and_inf(np_obs, "observations")
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return np_obs
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@timed
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def steps_from_proto(
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agent_info_list: Collection[AgentInfoProto], behavior_spec: BehaviorSpec
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) -> Tuple[DecisionSteps, TerminalSteps]:
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decision_agent_info_list = [
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agent_info for agent_info in agent_info_list if not agent_info.done
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]
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terminal_agent_info_list = [
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agent_info for agent_info in agent_info_list if agent_info.done
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]
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decision_obs_list: List[np.ndarray] = []
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terminal_obs_list: List[np.ndarray] = []
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for obs_index, observation_specs in enumerate(behavior_spec.observation_specs):
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is_visual = len(observation_specs.shape) == 3
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if is_visual:
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obs_shape = cast(Tuple[int, int, int], observation_specs.shape)
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decision_obs_list.append(
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_process_visual_observation(
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obs_index, obs_shape, decision_agent_info_list
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)
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)
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terminal_obs_list.append(
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_process_visual_observation(
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obs_index, obs_shape, terminal_agent_info_list
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)
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)
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else:
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decision_obs_list.append(
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_process_vector_observation(
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obs_index, observation_specs.shape, decision_agent_info_list
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)
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)
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terminal_obs_list.append(
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_process_vector_observation(
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obs_index, observation_specs.shape, terminal_agent_info_list
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)
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)
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decision_rewards = np.array(
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[agent_info.reward for agent_info in decision_agent_info_list], dtype=np.float32
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)
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terminal_rewards = np.array(
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[agent_info.reward for agent_info in terminal_agent_info_list], dtype=np.float32
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)
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_raise_on_nan_and_inf(decision_rewards, "rewards")
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_raise_on_nan_and_inf(terminal_rewards, "rewards")
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max_step = np.array(
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[agent_info.max_step_reached for agent_info in terminal_agent_info_list],
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dtype=np.bool,
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)
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decision_agent_id = np.array(
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[agent_info.id for agent_info in decision_agent_info_list], dtype=np.int32
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)
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terminal_agent_id = np.array(
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[agent_info.id for agent_info in terminal_agent_info_list], dtype=np.int32
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)
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action_mask = None
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if behavior_spec.action_spec.discrete_size > 0:
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if any(
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[agent_info.action_mask is not None]
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for agent_info in decision_agent_info_list
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):
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n_agents = len(decision_agent_info_list)
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a_size = np.sum(behavior_spec.action_spec.discrete_branches)
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mask_matrix = np.ones((n_agents, a_size), dtype=np.bool)
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for agent_index, agent_info in enumerate(decision_agent_info_list):
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if agent_info.action_mask is not None:
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if len(agent_info.action_mask) == a_size:
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mask_matrix[agent_index, :] = [
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False if agent_info.action_mask[k] else True
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for k in range(a_size)
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]
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action_mask = (1 - mask_matrix).astype(np.bool)
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indices = _generate_split_indices(
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behavior_spec.action_spec.discrete_branches
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)
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action_mask = np.split(action_mask, indices, axis=1)
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return (
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DecisionSteps(
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decision_obs_list, decision_rewards, decision_agent_id, action_mask
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),
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TerminalSteps(terminal_obs_list, terminal_rewards, max_step, terminal_agent_id),
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)
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def _generate_split_indices(dims):
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if len(dims) <= 1:
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return ()
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result = (dims[0],)
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for i in range(len(dims) - 2):
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result += (dims[i + 1] + result[i],)
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return result
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