Source code for gymnasium.spaces.discrete

"""Implementation of a space consisting of finitely many elements."""
from __future__ import annotations

from typing import Any, Iterable, Mapping, Sequence

import numpy as np

from gymnasium.spaces.space import MaskNDArray, Space


[docs] class Discrete(Space[np.int64]): r"""A space consisting of finitely many elements. This class represents a finite subset of integers, more specifically a set of the form :math:`\{ a, a+1, \dots, a+n-1 \}`. Example: >>> from gymnasium.spaces import Discrete >>> observation_space = Discrete(2, seed=42) # {0, 1} >>> observation_space.sample() 0 >>> observation_space = Discrete(3, start=-1, seed=42) # {-1, 0, 1} >>> observation_space.sample() -1 """ def __init__( self, n: int | np.integer[Any], seed: int | np.random.Generator | None = None, start: int | np.integer[Any] = 0, ): r"""Constructor of :class:`Discrete` space. This will construct the space :math:`\{\text{start}, ..., \text{start} + n - 1\}`. Args: n (int): The number of elements of this space. seed: Optionally, you can use this argument to seed the RNG that is used to sample from the ``Dict`` space. start (int): The smallest element of this space. """ assert np.issubdtype( type(n), np.integer ), f"Expects `n` to be an integer, actual dtype: {type(n)}" assert n > 0, "n (counts) have to be positive" assert np.issubdtype( type(start), np.integer ), f"Expects `start` to be an integer, actual type: {type(start)}" self.n = np.int64(n) self.start = np.int64(start) super().__init__((), np.int64, seed) @property def is_np_flattenable(self): """Checks whether this space can be flattened to a :class:`spaces.Box`.""" return True
[docs] def sample(self, mask: MaskNDArray | None = None) -> np.int64: """Generates a single random sample from this space. A sample will be chosen uniformly at random with the mask if provided Args: mask: An optional mask for if an action can be selected. Expected `np.ndarray` of shape ``(n,)`` and dtype ``np.int8`` where ``1`` represents valid actions and ``0`` invalid / infeasible actions. If there are no possible actions (i.e. ``np.all(mask == 0)``) then ``space.start`` will be returned. Returns: A sampled integer from the space """ if mask is not None: assert isinstance( mask, np.ndarray ), f"The expected type of the mask is np.ndarray, actual type: {type(mask)}" assert ( mask.dtype == np.int8 ), f"The expected dtype of the mask is np.int8, actual dtype: {mask.dtype}" assert mask.shape == ( self.n, ), f"The expected shape of the mask is {(self.n,)}, actual shape: {mask.shape}" valid_action_mask = mask == 1 assert np.all( np.logical_or(mask == 0, valid_action_mask) ), f"All values of a mask should be 0 or 1, actual values: {mask}" if np.any(valid_action_mask): return self.start + self.np_random.choice( np.where(valid_action_mask)[0] ) else: return self.start return self.start + self.np_random.integers(self.n)
def contains(self, x: Any) -> bool: """Return boolean specifying if x is a valid member of this space.""" if isinstance(x, int): as_int64 = np.int64(x) elif isinstance(x, (np.generic, np.ndarray)) and ( np.issubdtype(x.dtype, np.integer) and x.shape == () ): as_int64 = np.int64(x) else: return False return bool(self.start <= as_int64 < self.start + self.n) def __repr__(self) -> str: """Gives a string representation of this space.""" if self.start != 0: return f"Discrete({self.n}, start={self.start})" return f"Discrete({self.n})" def __eq__(self, other: Any) -> bool: """Check whether ``other`` is equivalent to this instance.""" return ( isinstance(other, Discrete) and self.n == other.n and self.start == other.start ) def __setstate__(self, state: Iterable[tuple[str, Any]] | Mapping[str, Any]): """Used when loading a pickled space. This method has to be implemented explicitly to allow for loading of legacy states. Args: state: The new state """ # Don't mutate the original state state = dict(state) # Allow for loading of legacy states. # See https://github.com/openai/gym/pull/2470 if "start" not in state: state["start"] = np.int64(0) super().__setstate__(state) def to_jsonable(self, sample_n: Sequence[np.int64]) -> list[int]: """Converts a list of samples to a list of ints.""" return [int(x) for x in sample_n] def from_jsonable(self, sample_n: list[int]) -> list[np.int64]: """Converts a list of json samples to a list of np.int64.""" return [np.int64(x) for x in sample_n]