Mini Shell
from __future__ import annotations
import abc
import copy
import dataclasses
import math
import re
import string
import sys
from datetime import date
from datetime import datetime
from datetime import time
from datetime import tzinfo
from enum import Enum
from typing import TYPE_CHECKING
from typing import Any
from typing import Callable
from typing import Collection
from typing import Iterable
from typing import Iterator
from typing import Sequence
from typing import TypeVar
from typing import cast
from typing import overload
from tomlkit._compat import PY38
from tomlkit._compat import decode
from tomlkit._types import _CustomDict
from tomlkit._types import _CustomFloat
from tomlkit._types import _CustomInt
from tomlkit._types import _CustomList
from tomlkit._types import wrap_method
from tomlkit._utils import CONTROL_CHARS
from tomlkit._utils import escape_string
from tomlkit.exceptions import ConvertError
from tomlkit.exceptions import InvalidStringError
if TYPE_CHECKING:
from tomlkit import container
ItemT = TypeVar("ItemT", bound="Item")
Encoder = Callable[[Any], "Item"]
CUSTOM_ENCODERS: list[Encoder] = []
AT = TypeVar("AT", bound="AbstractTable")
@overload
def item(value: bool, _parent: Item | None = ..., _sort_keys: bool = ...) -> Bool: ...
@overload
def item(value: int, _parent: Item | None = ..., _sort_keys: bool = ...) -> Integer: ...
@overload
def item(value: float, _parent: Item | None = ..., _sort_keys: bool = ...) -> Float: ...
@overload
def item(value: str, _parent: Item | None = ..., _sort_keys: bool = ...) -> String: ...
@overload
def item(
value: datetime, _parent: Item | None = ..., _sort_keys: bool = ...
) -> DateTime: ...
@overload
def item(value: date, _parent: Item | None = ..., _sort_keys: bool = ...) -> Date: ...
@overload
def item(value: time, _parent: Item | None = ..., _sort_keys: bool = ...) -> Time: ...
@overload
def item(
value: Sequence[dict], _parent: Item | None = ..., _sort_keys: bool = ...
) -> AoT: ...
@overload
def item(
value: Sequence, _parent: Item | None = ..., _sort_keys: bool = ...
) -> Array: ...
@overload
def item(value: dict, _parent: Array = ..., _sort_keys: bool = ...) -> InlineTable: ...
@overload
def item(value: dict, _parent: Item | None = ..., _sort_keys: bool = ...) -> Table: ...
@overload
def item(value: ItemT, _parent: Item | None = ..., _sort_keys: bool = ...) -> ItemT: ...
def item(value: Any, _parent: Item | None = None, _sort_keys: bool = False) -> Item:
"""Create a TOML item from a Python object.
:Example:
>>> item(42)
42
>>> item([1, 2, 3])
[1, 2, 3]
>>> item({'a': 1, 'b': 2})
a = 1
b = 2
"""
from tomlkit.container import Container
if isinstance(value, Item):
return value
if isinstance(value, bool):
return Bool(value, Trivia())
elif isinstance(value, int):
return Integer(value, Trivia(), str(value))
elif isinstance(value, float):
return Float(value, Trivia(), str(value))
elif isinstance(value, dict):
table_constructor = (
InlineTable if isinstance(_parent, (Array, InlineTable)) else Table
)
val = table_constructor(Container(), Trivia(), False)
for k, v in sorted(
value.items(),
key=lambda i: (isinstance(i[1], dict), i[0]) if _sort_keys else 1,
):
val[k] = item(v, _parent=val, _sort_keys=_sort_keys)
return val
elif isinstance(value, (list, tuple)):
if (
value
and all(isinstance(v, dict) for v in value)
and (_parent is None or isinstance(_parent, Table))
):
a = AoT([])
table_constructor = Table
else:
a = Array([], Trivia())
table_constructor = InlineTable
for v in value:
if isinstance(v, dict):
table = table_constructor(Container(), Trivia(), True)
for k, _v in sorted(
v.items(),
key=lambda i: (isinstance(i[1], dict), i[0] if _sort_keys else 1),
):
i = item(_v, _parent=table, _sort_keys=_sort_keys)
if isinstance(table, InlineTable):
i.trivia.trail = ""
table[k] = i
v = table
a.append(v)
return a
elif isinstance(value, str):
return String.from_raw(value)
elif isinstance(value, datetime):
return DateTime(
value.year,
value.month,
value.day,
value.hour,
value.minute,
value.second,
value.microsecond,
value.tzinfo,
Trivia(),
value.isoformat().replace("+00:00", "Z"),
)
elif isinstance(value, date):
return Date(value.year, value.month, value.day, Trivia(), value.isoformat())
elif isinstance(value, time):
return Time(
value.hour,
value.minute,
value.second,
value.microsecond,
value.tzinfo,
Trivia(),
value.isoformat(),
)
else:
for encoder in CUSTOM_ENCODERS:
try:
rv = encoder(value)
except ConvertError:
pass
else:
if not isinstance(rv, Item):
raise ConvertError(
f"Custom encoder is expected to return an instance of Item, got {type(rv)}"
)
return rv
raise ConvertError(f"Unable to convert an object of {type(value)} to a TOML item")
class StringType(Enum):
# Single Line Basic
SLB = '"'
# Multi Line Basic
MLB = '"""'
# Single Line Literal
SLL = "'"
# Multi Line Literal
MLL = "'''"
@classmethod
def select(cls, literal=False, multiline=False) -> StringType:
return {
(False, False): cls.SLB,
(False, True): cls.MLB,
(True, False): cls.SLL,
(True, True): cls.MLL,
}[(literal, multiline)]
@property
def escaped_sequences(self) -> Collection[str]:
# https://toml.io/en/v1.0.0#string
escaped_in_basic = CONTROL_CHARS | {"\\"}
allowed_in_multiline = {"\n", "\r"}
return {
StringType.SLB: escaped_in_basic | {'"'},
StringType.MLB: (escaped_in_basic | {'"""'}) - allowed_in_multiline,
StringType.SLL: (),
StringType.MLL: (),
}[self]
@property
def invalid_sequences(self) -> Collection[str]:
# https://toml.io/en/v1.0.0#string
forbidden_in_literal = CONTROL_CHARS - {"\t"}
allowed_in_multiline = {"\n", "\r"}
return {
StringType.SLB: (),
StringType.MLB: (),
StringType.SLL: forbidden_in_literal | {"'"},
StringType.MLL: (forbidden_in_literal | {"'''"}) - allowed_in_multiline,
}[self]
@property
def unit(self) -> str:
return self.value[0]
def is_basic(self) -> bool:
return self in {StringType.SLB, StringType.MLB}
def is_literal(self) -> bool:
return self in {StringType.SLL, StringType.MLL}
def is_singleline(self) -> bool:
return self in {StringType.SLB, StringType.SLL}
def is_multiline(self) -> bool:
return self in {StringType.MLB, StringType.MLL}
def toggle(self) -> StringType:
return {
StringType.SLB: StringType.MLB,
StringType.MLB: StringType.SLB,
StringType.SLL: StringType.MLL,
StringType.MLL: StringType.SLL,
}[self]
class BoolType(Enum):
TRUE = "true"
FALSE = "false"
def __bool__(self):
return {BoolType.TRUE: True, BoolType.FALSE: False}[self]
def __iter__(self):
return iter(self.value)
def __len__(self):
return len(self.value)
@dataclasses.dataclass
class Trivia:
"""
Trivia information (aka metadata).
"""
# Whitespace before a value.
indent: str = ""
# Whitespace after a value, but before a comment.
comment_ws: str = ""
# Comment, starting with # character, or empty string if no comment.
comment: str = ""
# Trailing newline.
trail: str = "\n"
def copy(self) -> Trivia:
return dataclasses.replace(self)
class KeyType(Enum):
"""
The type of a Key.
Keys can be bare (unquoted), or quoted using basic ("), or literal (')
quotes following the same escaping rules as single-line StringType.
"""
Bare = ""
Basic = '"'
Literal = "'"
class Key(abc.ABC):
"""Base class for a key"""
sep: str
_original: str
_keys: list[SingleKey]
_dotted: bool
key: str
@abc.abstractmethod
def __hash__(self) -> int:
pass
@abc.abstractmethod
def __eq__(self, __o: object) -> bool:
pass
def is_dotted(self) -> bool:
"""If the key is followed by other keys"""
return self._dotted
def __iter__(self) -> Iterator[SingleKey]:
return iter(self._keys)
def concat(self, other: Key) -> DottedKey:
"""Concatenate keys into a dotted key"""
keys = self._keys + other._keys
return DottedKey(keys, sep=self.sep)
def is_multi(self) -> bool:
"""Check if the key contains multiple keys"""
return len(self._keys) > 1
def as_string(self) -> str:
"""The TOML representation"""
return self._original
def __str__(self) -> str:
return self.as_string()
def __repr__(self) -> str:
return f"<Key {self.as_string()}>"
class SingleKey(Key):
"""A single key"""
def __init__(
self,
k: str,
t: KeyType | None = None,
sep: str | None = None,
original: str | None = None,
) -> None:
if t is None:
if not k or any(
c not in string.ascii_letters + string.digits + "-" + "_" for c in k
):
t = KeyType.Basic
else:
t = KeyType.Bare
self.t = t
if sep is None:
sep = " = "
self.sep = sep
self.key = k
if original is None:
key_str = escape_string(k) if t == KeyType.Basic else k
original = f"{t.value}{key_str}{t.value}"
self._original = original
self._keys = [self]
self._dotted = False
@property
def delimiter(self) -> str:
"""The delimiter: double quote/single quote/none"""
return self.t.value
def is_bare(self) -> bool:
"""Check if the key is bare"""
return self.t == KeyType.Bare
def __hash__(self) -> int:
return hash(self.key)
def __eq__(self, other: Any) -> bool:
if isinstance(other, Key):
return isinstance(other, SingleKey) and self.key == other.key
return self.key == other
class DottedKey(Key):
def __init__(
self,
keys: Iterable[SingleKey],
sep: str | None = None,
original: str | None = None,
) -> None:
self._keys = list(keys)
if original is None:
original = ".".join(k.as_string() for k in self._keys)
self.sep = " = " if sep is None else sep
self._original = original
self._dotted = False
self.key = ".".join(k.key for k in self._keys)
def __hash__(self) -> int:
return hash(tuple(self._keys))
def __eq__(self, __o: object) -> bool:
return isinstance(__o, DottedKey) and self._keys == __o._keys
class Item:
"""
An item within a TOML document.
"""
def __init__(self, trivia: Trivia) -> None:
self._trivia = trivia
@property
def trivia(self) -> Trivia:
"""The trivia element associated with this item"""
return self._trivia
@property
def discriminant(self) -> int:
raise NotImplementedError()
def as_string(self) -> str:
"""The TOML representation"""
raise NotImplementedError()
@property
def value(self) -> Any:
return self
def unwrap(self) -> Any:
"""Returns as pure python object (ppo)"""
raise NotImplementedError()
# Helpers
def comment(self, comment: str) -> Item:
"""Attach a comment to this item"""
if not comment.strip().startswith("#"):
comment = "# " + comment
self._trivia.comment_ws = " "
self._trivia.comment = comment
return self
def indent(self, indent: int) -> Item:
"""Indent this item with given number of spaces"""
if self._trivia.indent.startswith("\n"):
self._trivia.indent = "\n" + " " * indent
else:
self._trivia.indent = " " * indent
return self
def is_boolean(self) -> bool:
return isinstance(self, Bool)
def is_table(self) -> bool:
return isinstance(self, Table)
def is_inline_table(self) -> bool:
return isinstance(self, InlineTable)
def is_aot(self) -> bool:
return isinstance(self, AoT)
def _getstate(self, protocol=3):
return (self._trivia,)
def __reduce__(self):
return self.__reduce_ex__(2)
def __reduce_ex__(self, protocol):
return self.__class__, self._getstate(protocol)
class Whitespace(Item):
"""
A whitespace literal.
"""
def __init__(self, s: str, fixed: bool = False) -> None:
self._s = s
self._fixed = fixed
@property
def s(self) -> str:
return self._s
@property
def value(self) -> str:
"""The wrapped string of the whitespace"""
return self._s
@property
def trivia(self) -> Trivia:
raise RuntimeError("Called trivia on a Whitespace variant.")
@property
def discriminant(self) -> int:
return 0
def is_fixed(self) -> bool:
"""If the whitespace is fixed, it can't be merged or discarded from the output."""
return self._fixed
def as_string(self) -> str:
return self._s
def __repr__(self) -> str:
return f"<{self.__class__.__name__} {self._s!r}>"
def _getstate(self, protocol=3):
return self._s, self._fixed
class Comment(Item):
"""
A comment literal.
"""
@property
def discriminant(self) -> int:
return 1
def as_string(self) -> str:
return (
f"{self._trivia.indent}{decode(self._trivia.comment)}{self._trivia.trail}"
)
def __str__(self) -> str:
return f"{self._trivia.indent}{decode(self._trivia.comment)}"
class Integer(Item, _CustomInt):
"""
An integer literal.
"""
def __new__(cls, value: int, trivia: Trivia, raw: str) -> Integer:
return int.__new__(cls, value)
def __init__(self, value: int, trivia: Trivia, raw: str) -> None:
super().__init__(trivia)
self._original = value
self._raw = raw
self._sign = False
if re.match(r"^[+\-]\d+$", raw):
self._sign = True
def unwrap(self) -> int:
return self._original
__int__ = unwrap
def __hash__(self) -> int:
return hash(self.unwrap())
@property
def discriminant(self) -> int:
return 2
@property
def value(self) -> int:
"""The wrapped integer value"""
return self
def as_string(self) -> str:
return self._raw
def _new(self, result):
raw = str(result)
if self._sign and result >= 0:
raw = f"+{raw}"
return Integer(result, self._trivia, raw)
def _getstate(self, protocol=3):
return int(self), self._trivia, self._raw
# int methods
__abs__ = wrap_method(int.__abs__)
__add__ = wrap_method(int.__add__)
__and__ = wrap_method(int.__and__)
__ceil__ = wrap_method(int.__ceil__)
__eq__ = int.__eq__
__floor__ = wrap_method(int.__floor__)
__floordiv__ = wrap_method(int.__floordiv__)
__invert__ = wrap_method(int.__invert__)
__le__ = int.__le__
__lshift__ = wrap_method(int.__lshift__)
__lt__ = int.__lt__
__mod__ = wrap_method(int.__mod__)
__mul__ = wrap_method(int.__mul__)
__neg__ = wrap_method(int.__neg__)
__or__ = wrap_method(int.__or__)
__pos__ = wrap_method(int.__pos__)
__pow__ = wrap_method(int.__pow__)
__radd__ = wrap_method(int.__radd__)
__rand__ = wrap_method(int.__rand__)
__rfloordiv__ = wrap_method(int.__rfloordiv__)
__rlshift__ = wrap_method(int.__rlshift__)
__rmod__ = wrap_method(int.__rmod__)
__rmul__ = wrap_method(int.__rmul__)
__ror__ = wrap_method(int.__ror__)
__round__ = wrap_method(int.__round__)
__rpow__ = wrap_method(int.__rpow__)
__rrshift__ = wrap_method(int.__rrshift__)
__rshift__ = wrap_method(int.__rshift__)
__rxor__ = wrap_method(int.__rxor__)
__trunc__ = wrap_method(int.__trunc__)
__xor__ = wrap_method(int.__xor__)
def __rtruediv__(self, other):
result = int.__rtruediv__(self, other)
if result is NotImplemented:
return result
return Float._new(self, result)
def __truediv__(self, other):
result = int.__truediv__(self, other)
if result is NotImplemented:
return result
return Float._new(self, result)
class Float(Item, _CustomFloat):
"""
A float literal.
"""
def __new__(cls, value: float, trivia: Trivia, raw: str) -> Float:
return float.__new__(cls, value)
def __init__(self, value: float, trivia: Trivia, raw: str) -> None:
super().__init__(trivia)
self._original = value
self._raw = raw
self._sign = False
if re.match(r"^[+\-].+$", raw):
self._sign = True
def unwrap(self) -> float:
return self._original
__float__ = unwrap
def __hash__(self) -> int:
return hash(self.unwrap())
@property
def discriminant(self) -> int:
return 3
@property
def value(self) -> float:
"""The wrapped float value"""
return self
def as_string(self) -> str:
return self._raw
def _new(self, result):
raw = str(result)
if self._sign and result >= 0:
raw = f"+{raw}"
return Float(result, self._trivia, raw)
def _getstate(self, protocol=3):
return float(self), self._trivia, self._raw
# float methods
__abs__ = wrap_method(float.__abs__)
__add__ = wrap_method(float.__add__)
__eq__ = float.__eq__
__floordiv__ = wrap_method(float.__floordiv__)
__le__ = float.__le__
__lt__ = float.__lt__
__mod__ = wrap_method(float.__mod__)
__mul__ = wrap_method(float.__mul__)
__neg__ = wrap_method(float.__neg__)
__pos__ = wrap_method(float.__pos__)
__pow__ = wrap_method(float.__pow__)
__radd__ = wrap_method(float.__radd__)
__rfloordiv__ = wrap_method(float.__rfloordiv__)
__rmod__ = wrap_method(float.__rmod__)
__rmul__ = wrap_method(float.__rmul__)
__round__ = wrap_method(float.__round__)
__rpow__ = wrap_method(float.__rpow__)
__rtruediv__ = wrap_method(float.__rtruediv__)
__truediv__ = wrap_method(float.__truediv__)
__trunc__ = float.__trunc__
if sys.version_info >= (3, 9):
__ceil__ = float.__ceil__
__floor__ = float.__floor__
else:
__ceil__ = math.ceil
__floor__ = math.floor
class Bool(Item):
"""
A boolean literal.
"""
def __init__(self, t: int, trivia: Trivia) -> None:
super().__init__(trivia)
self._value = bool(t)
def unwrap(self) -> bool:
return bool(self)
@property
def discriminant(self) -> int:
return 4
@property
def value(self) -> bool:
"""The wrapped boolean value"""
return self._value
def as_string(self) -> str:
return str(self._value).lower()
def _getstate(self, protocol=3):
return self._value, self._trivia
def __bool__(self):
return self._value
__nonzero__ = __bool__
def __eq__(self, other):
if not isinstance(other, bool):
return NotImplemented
return other == self._value
def __hash__(self):
return hash(self._value)
def __repr__(self):
return repr(self._value)
class DateTime(Item, datetime):
"""
A datetime literal.
"""
def __new__(
cls,
year: int,
month: int,
day: int,
hour: int,
minute: int,
second: int,
microsecond: int,
tzinfo: tzinfo | None,
*_: Any,
**kwargs: Any,
) -> datetime:
return datetime.__new__(
cls,
year,
month,
day,
hour,
minute,
second,
microsecond,
tzinfo=tzinfo,
**kwargs,
)
def __init__(
self,
year: int,
month: int,
day: int,
hour: int,
minute: int,
second: int,
microsecond: int,
tzinfo: tzinfo | None,
trivia: Trivia | None = None,
raw: str | None = None,
**kwargs: Any,
) -> None:
super().__init__(trivia or Trivia())
self._raw = raw or self.isoformat()
def unwrap(self) -> datetime:
(
year,
month,
day,
hour,
minute,
second,
microsecond,
tzinfo,
_,
_,
) = self._getstate()
return datetime(year, month, day, hour, minute, second, microsecond, tzinfo)
@property
def discriminant(self) -> int:
return 5
@property
def value(self) -> datetime:
return self
def as_string(self) -> str:
return self._raw
def __add__(self, other):
if PY38:
result = datetime(
self.year,
self.month,
self.day,
self.hour,
self.minute,
self.second,
self.microsecond,
self.tzinfo,
).__add__(other)
else:
result = super().__add__(other)
return self._new(result)
def __sub__(self, other):
if PY38:
result = datetime(
self.year,
self.month,
self.day,
self.hour,
self.minute,
self.second,
self.microsecond,
self.tzinfo,
).__sub__(other)
else:
result = super().__sub__(other)
if isinstance(result, datetime):
result = self._new(result)
return result
def replace(self, *args: Any, **kwargs: Any) -> datetime:
return self._new(super().replace(*args, **kwargs))
def astimezone(self, tz: tzinfo) -> datetime:
result = super().astimezone(tz)
if PY38:
return result
return self._new(result)
def _new(self, result) -> DateTime:
raw = result.isoformat()
return DateTime(
result.year,
result.month,
result.day,
result.hour,
result.minute,
result.second,
result.microsecond,
result.tzinfo,
self._trivia,
raw,
)
def _getstate(self, protocol=3):
return (
self.year,
self.month,
self.day,
self.hour,
self.minute,
self.second,
self.microsecond,
self.tzinfo,
self._trivia,
self._raw,
)
class Date(Item, date):
"""
A date literal.
"""
def __new__(cls, year: int, month: int, day: int, *_: Any) -> date:
return date.__new__(cls, year, month, day)
def __init__(
self,
year: int,
month: int,
day: int,
trivia: Trivia | None = None,
raw: str = "",
) -> None:
super().__init__(trivia or Trivia())
self._raw = raw
def unwrap(self) -> date:
(year, month, day, _, _) = self._getstate()
return date(year, month, day)
@property
def discriminant(self) -> int:
return 6
@property
def value(self) -> date:
return self
def as_string(self) -> str:
return self._raw
def __add__(self, other):
if PY38:
result = date(self.year, self.month, self.day).__add__(other)
else:
result = super().__add__(other)
return self._new(result)
def __sub__(self, other):
if PY38:
result = date(self.year, self.month, self.day).__sub__(other)
else:
result = super().__sub__(other)
if isinstance(result, date):
result = self._new(result)
return result
def replace(self, *args: Any, **kwargs: Any) -> date:
return self._new(super().replace(*args, **kwargs))
def _new(self, result):
raw = result.isoformat()
return Date(result.year, result.month, result.day, self._trivia, raw)
def _getstate(self, protocol=3):
return (self.year, self.month, self.day, self._trivia, self._raw)
class Time(Item, time):
"""
A time literal.
"""
def __new__(
cls,
hour: int,
minute: int,
second: int,
microsecond: int,
tzinfo: tzinfo | None,
*_: Any,
) -> time:
return time.__new__(cls, hour, minute, second, microsecond, tzinfo)
def __init__(
self,
hour: int,
minute: int,
second: int,
microsecond: int,
tzinfo: tzinfo | None,
trivia: Trivia | None = None,
raw: str = "",
) -> None:
super().__init__(trivia or Trivia())
self._raw = raw
def unwrap(self) -> time:
(hour, minute, second, microsecond, tzinfo, _, _) = self._getstate()
return time(hour, minute, second, microsecond, tzinfo)
@property
def discriminant(self) -> int:
return 7
@property
def value(self) -> time:
return self
def as_string(self) -> str:
return self._raw
def replace(self, *args: Any, **kwargs: Any) -> time:
return self._new(super().replace(*args, **kwargs))
def _new(self, result):
raw = result.isoformat()
return Time(
result.hour,
result.minute,
result.second,
result.microsecond,
result.tzinfo,
self._trivia,
raw,
)
def _getstate(self, protocol: int = 3) -> tuple:
return (
self.hour,
self.minute,
self.second,
self.microsecond,
self.tzinfo,
self._trivia,
self._raw,
)
class _ArrayItemGroup:
__slots__ = ("value", "indent", "comma", "comment")
def __init__(
self,
value: Item | None = None,
indent: Whitespace | None = None,
comma: Whitespace | None = None,
comment: Comment | None = None,
) -> None:
self.value = value
self.indent = indent
self.comma = comma
self.comment = comment
def __iter__(self) -> Iterator[Item]:
return filter(
lambda x: x is not None, (self.indent, self.value, self.comma, self.comment)
)
def __repr__(self) -> str:
return repr(tuple(self))
def is_whitespace(self) -> bool:
return self.value is None and self.comment is None
def __bool__(self) -> bool:
try:
next(iter(self))
except StopIteration:
return False
return True
class Array(Item, _CustomList):
"""
An array literal
"""
def __init__(
self, value: list[Item], trivia: Trivia, multiline: bool = False
) -> None:
super().__init__(trivia)
list.__init__(
self,
[v for v in value if not isinstance(v, (Whitespace, Comment, Null))],
)
self._index_map: dict[int, int] = {}
self._value = self._group_values(value)
self._multiline = multiline
self._reindex()
def _group_values(self, value: list[Item]) -> list[_ArrayItemGroup]:
"""Group the values into (indent, value, comma, comment) tuples"""
groups = []
this_group = _ArrayItemGroup()
for item in value:
if isinstance(item, Whitespace):
if "," not in item.s:
groups.append(this_group)
this_group = _ArrayItemGroup(indent=item)
else:
if this_group.value is None:
# when comma is met and no value is provided, add a dummy Null
this_group.value = Null()
this_group.comma = item
elif isinstance(item, Comment):
if this_group.value is None:
this_group.value = Null()
this_group.comment = item
elif this_group.value is None:
this_group.value = item
else:
groups.append(this_group)
this_group = _ArrayItemGroup(value=item)
groups.append(this_group)
return [group for group in groups if group]
def unwrap(self) -> list[Any]:
unwrapped = []
for v in self:
if hasattr(v, "unwrap"):
unwrapped.append(v.unwrap())
else:
unwrapped.append(v)
return unwrapped
@property
def discriminant(self) -> int:
return 8
@property
def value(self) -> list:
return self
def _iter_items(self) -> Iterator[Item]:
for v in self._value:
yield from v
def multiline(self, multiline: bool) -> Array:
"""Change the array to display in multiline or not.
:Example:
>>> a = item([1, 2, 3])
>>> print(a.as_string())
[1, 2, 3]
>>> print(a.multiline(True).as_string())
[
1,
2,
3,
]
"""
self._multiline = multiline
return self
def as_string(self) -> str:
if not self._multiline or not self._value:
return f'[{"".join(v.as_string() for v in self._iter_items())}]'
s = "[\n"
s += "".join(
self.trivia.indent
+ " " * 4
+ v.value.as_string()
+ ("," if not isinstance(v.value, Null) else "")
+ (v.comment.as_string() if v.comment is not None else "")
+ "\n"
for v in self._value
if v.value is not None
)
s += self.trivia.indent + "]"
return s
def _reindex(self) -> None:
self._index_map.clear()
index = 0
for i, v in enumerate(self._value):
if v.value is None or isinstance(v.value, Null):
continue
self._index_map[index] = i
index += 1
def add_line(
self,
*items: Any,
indent: str = " ",
comment: str | None = None,
add_comma: bool = True,
newline: bool = True,
) -> None:
"""Add multiple items in a line to control the format precisely.
When add_comma is True, only accept actual values and
", " will be added between values automatically.
:Example:
>>> a = array()
>>> a.add_line(1, 2, 3)
>>> a.add_line(4, 5, 6)
>>> a.add_line(indent="")
>>> print(a.as_string())
[
1, 2, 3,
4, 5, 6,
]
"""
new_values: list[Item] = []
first_indent = f"\n{indent}" if newline else indent
if first_indent:
new_values.append(Whitespace(first_indent))
whitespace = ""
data_values = []
for i, el in enumerate(items):
it = item(el, _parent=self)
if isinstance(it, Comment) or add_comma and isinstance(el, Whitespace):
raise ValueError(f"item type {type(it)} is not allowed in add_line")
if not isinstance(it, Whitespace):
if whitespace:
new_values.append(Whitespace(whitespace))
whitespace = ""
new_values.append(it)
data_values.append(it.value)
if add_comma:
new_values.append(Whitespace(","))
if i != len(items) - 1:
new_values.append(Whitespace(" "))
elif "," not in it.s:
whitespace += it.s
else:
new_values.append(it)
if whitespace:
new_values.append(Whitespace(whitespace))
if comment:
indent = " " if items else ""
new_values.append(
Comment(Trivia(indent=indent, comment=f"# {comment}", trail=""))
)
list.extend(self, data_values)
if len(self._value) > 0:
last_item = self._value[-1]
last_value_item = next(
(
v
for v in self._value[::-1]
if v.value is not None and not isinstance(v.value, Null)
),
None,
)
if last_value_item is not None:
last_value_item.comma = Whitespace(",")
if last_item.is_whitespace():
self._value[-1:-1] = self._group_values(new_values)
else:
self._value.extend(self._group_values(new_values))
else:
self._value.extend(self._group_values(new_values))
self._reindex()
def clear(self) -> None:
"""Clear the array."""
list.clear(self)
self._index_map.clear()
self._value.clear()
def __len__(self) -> int:
return list.__len__(self)
def __getitem__(self, key: int | slice) -> Any:
rv = cast(Item, list.__getitem__(self, key))
if rv.is_boolean():
return bool(rv)
return rv
def __setitem__(self, key: int | slice, value: Any) -> Any:
it = item(value, _parent=self)
list.__setitem__(self, key, it)
if isinstance(key, slice):
raise ValueError("slice assignment is not supported")
if key < 0:
key += len(self)
self._value[self._index_map[key]].value = it
def insert(self, pos: int, value: Any) -> None:
it = item(value, _parent=self)
length = len(self)
if not isinstance(it, (Comment, Whitespace)):
list.insert(self, pos, it)
if pos < 0:
pos += length
if pos < 0:
pos = 0
idx = 0 # insert position of the self._value list
default_indent = " "
if pos < length:
try:
idx = self._index_map[pos]
except KeyError as e:
raise IndexError("list index out of range") from e
else:
idx = len(self._value)
if idx >= 1 and self._value[idx - 1].is_whitespace():
# The last item is a pure whitespace(\n ), insert before it
idx -= 1
if (
self._value[idx].indent is not None
and "\n" in self._value[idx].indent.s
):
default_indent = "\n "
indent: Item | None = None
comma: Item | None = Whitespace(",") if pos < length else None
if idx < len(self._value) and not self._value[idx].is_whitespace():
# Prefer to copy the indentation from the item after
indent = self._value[idx].indent
if idx > 0:
last_item = self._value[idx - 1]
if indent is None:
indent = last_item.indent
if not isinstance(last_item.value, Null) and "\n" in default_indent:
# Copy the comma from the last item if 1) it contains a value and
# 2) the array is multiline
comma = last_item.comma
if last_item.comma is None and not isinstance(last_item.value, Null):
# Add comma to the last item to separate it from the following items.
last_item.comma = Whitespace(",")
if indent is None and (idx > 0 or "\n" in default_indent):
# apply default indent if it isn't the first item or the array is multiline.
indent = Whitespace(default_indent)
new_item = _ArrayItemGroup(value=it, indent=indent, comma=comma)
self._value.insert(idx, new_item)
self._reindex()
def __delitem__(self, key: int | slice):
length = len(self)
list.__delitem__(self, key)
if isinstance(key, slice):
indices_to_remove = list(
range(key.start or 0, key.stop or length, key.step or 1)
)
else:
indices_to_remove = [length + key if key < 0 else key]
for i in sorted(indices_to_remove, reverse=True):
try:
idx = self._index_map[i]
except KeyError as e:
if not isinstance(key, slice):
raise IndexError("list index out of range") from e
else:
del self._value[idx]
if (
idx == 0
and len(self._value) > 0
and self._value[idx].indent
and "\n" not in self._value[idx].indent.s
):
# Remove the indentation of the first item if not newline
self._value[idx].indent = None
if len(self._value) > 0:
v = self._value[-1]
if not v.is_whitespace():
# remove the comma of the last item
v.comma = None
self._reindex()
def _getstate(self, protocol=3):
return list(self._iter_items()), self._trivia, self._multiline
class AbstractTable(Item, _CustomDict):
"""Common behaviour of both :class:`Table` and :class:`InlineTable`"""
def __init__(self, value: container.Container, trivia: Trivia):
Item.__init__(self, trivia)
self._value = value
for k, v in self._value.body:
if k is not None:
dict.__setitem__(self, k.key, v)
def unwrap(self) -> dict[str, Any]:
unwrapped = {}
for k, v in self.items():
if isinstance(k, Key):
k = k.key
if hasattr(v, "unwrap"):
v = v.unwrap()
unwrapped[k] = v
return unwrapped
@property
def value(self) -> container.Container:
return self._value
@overload
def append(self: AT, key: None, value: Comment | Whitespace) -> AT: ...
@overload
def append(self: AT, key: Key | str, value: Any) -> AT: ...
def append(self, key, value):
raise NotImplementedError
@overload
def add(self: AT, key: Comment | Whitespace) -> AT: ...
@overload
def add(self: AT, key: Key | str, value: Any = ...) -> AT: ...
def add(self, key, value=None):
if value is None:
if not isinstance(key, (Comment, Whitespace)):
msg = "Non comment/whitespace items must have an associated key"
raise ValueError(msg)
key, value = None, key
return self.append(key, value)
def remove(self: AT, key: Key | str) -> AT:
self._value.remove(key)
if isinstance(key, Key):
key = key.key
if key is not None:
dict.__delitem__(self, key)
return self
def setdefault(self, key: Key | str, default: Any) -> Any:
super().setdefault(key, default)
return self[key]
def __str__(self):
return str(self.value)
def copy(self: AT) -> AT:
return copy.copy(self)
def __repr__(self) -> str:
return repr(self.value)
def __iter__(self) -> Iterator[str]:
return iter(self._value)
def __len__(self) -> int:
return len(self._value)
def __delitem__(self, key: Key | str) -> None:
self.remove(key)
def __getitem__(self, key: Key | str) -> Item:
return cast(Item, self._value[key])
def __setitem__(self, key: Key | str, value: Any) -> None:
if not isinstance(value, Item):
value = item(value, _parent=self)
is_replace = key in self
self._value[key] = value
if key is not None:
dict.__setitem__(self, key, value)
if is_replace:
return
m = re.match("(?s)^[^ ]*([ ]+).*$", self._trivia.indent)
if not m:
return
indent = m.group(1)
if not isinstance(value, Whitespace):
m = re.match("(?s)^([^ ]*)(.*)$", value.trivia.indent)
if not m:
value.trivia.indent = indent
else:
value.trivia.indent = m.group(1) + indent + m.group(2)
class Table(AbstractTable):
"""
A table literal.
"""
def __init__(
self,
value: container.Container,
trivia: Trivia,
is_aot_element: bool,
is_super_table: bool | None = None,
name: str | None = None,
display_name: str | None = None,
) -> None:
super().__init__(value, trivia)
self.name = name
self.display_name = display_name
self._is_aot_element = is_aot_element
self._is_super_table = is_super_table
@property
def discriminant(self) -> int:
return 9
def __copy__(self) -> Table:
return type(self)(
self._value.copy(),
self._trivia.copy(),
self._is_aot_element,
self._is_super_table,
self.name,
self.display_name,
)
def append(self, key: Key | str | None, _item: Any) -> Table:
"""
Appends a (key, item) to the table.
"""
if not isinstance(_item, Item):
_item = item(_item, _parent=self)
self._value.append(key, _item)
if isinstance(key, Key):
key = next(iter(key)).key
_item = self._value[key]
if key is not None:
dict.__setitem__(self, key, _item)
m = re.match(r"(?s)^[^ ]*([ ]+).*$", self._trivia.indent)
if not m:
return self
indent = m.group(1)
if not isinstance(_item, Whitespace):
m = re.match("(?s)^([^ ]*)(.*)$", _item.trivia.indent)
if not m:
_item.trivia.indent = indent
else:
_item.trivia.indent = m.group(1) + indent + m.group(2)
return self
def raw_append(self, key: Key | str | None, _item: Any) -> Table:
"""Similar to :meth:`append` but does not copy indentation."""
if not isinstance(_item, Item):
_item = item(_item)
self._value.append(key, _item, validate=False)
if isinstance(key, Key):
key = next(iter(key)).key
_item = self._value[key]
if key is not None:
dict.__setitem__(self, key, _item)
return self
def is_aot_element(self) -> bool:
"""True if the table is the direct child of an AOT element."""
return self._is_aot_element
def is_super_table(self) -> bool:
"""A super table is the intermediate parent of a nested table as in [a.b.c].
If true, it won't appear in the TOML representation."""
if self._is_super_table is not None:
return self._is_super_table
if not self:
return False
# If the table has children and all children are tables, then it is a super table.
for k, child in self.items():
if not isinstance(k, Key):
k = SingleKey(k)
index = self.value._map[k]
if isinstance(index, tuple):
return False
real_key = self.value.body[index][0]
if (
not isinstance(child, (Table, AoT))
or real_key is None
or real_key.is_dotted()
):
return False
return True
def as_string(self) -> str:
return self._value.as_string()
# Helpers
def indent(self, indent: int) -> Table:
"""Indent the table with given number of spaces."""
super().indent(indent)
m = re.match("(?s)^[^ ]*([ ]+).*$", self._trivia.indent)
if not m:
indent_str = ""
else:
indent_str = m.group(1)
for _, item in self._value.body:
if not isinstance(item, Whitespace):
item.trivia.indent = indent_str + item.trivia.indent
return self
def invalidate_display_name(self):
"""Call ``invalidate_display_name`` on the contained tables"""
self.display_name = None
for child in self.values():
if hasattr(child, "invalidate_display_name"):
child.invalidate_display_name()
def _getstate(self, protocol: int = 3) -> tuple:
return (
self._value,
self._trivia,
self._is_aot_element,
self._is_super_table,
self.name,
self.display_name,
)
class InlineTable(AbstractTable):
"""
An inline table literal.
"""
def __init__(
self, value: container.Container, trivia: Trivia, new: bool = False
) -> None:
super().__init__(value, trivia)
self._new = new
@property
def discriminant(self) -> int:
return 10
def append(self, key: Key | str | None, _item: Any) -> InlineTable:
"""
Appends a (key, item) to the table.
"""
if not isinstance(_item, Item):
_item = item(_item, _parent=self)
if not isinstance(_item, (Whitespace, Comment)):
if not _item.trivia.indent and len(self._value) > 0 and not self._new:
_item.trivia.indent = " "
if _item.trivia.comment:
_item.trivia.comment = ""
self._value.append(key, _item)
if isinstance(key, Key):
key = key.key
if key is not None:
dict.__setitem__(self, key, _item)
return self
def as_string(self) -> str:
buf = "{"
last_item_idx = next(
(
i
for i in range(len(self._value.body) - 1, -1, -1)
if self._value.body[i][0] is not None
),
None,
)
for i, (k, v) in enumerate(self._value.body):
if k is None:
if i == len(self._value.body) - 1:
if self._new:
buf = buf.rstrip(", ")
else:
buf = buf.rstrip(",")
buf += v.as_string()
continue
v_trivia_trail = v.trivia.trail.replace("\n", "")
buf += (
f"{v.trivia.indent}"
f'{k.as_string() + ("." if k.is_dotted() else "")}'
f"{k.sep}"
f"{v.as_string()}"
f"{v.trivia.comment}"
f"{v_trivia_trail}"
)
if last_item_idx is not None and i < last_item_idx:
buf += ","
if self._new:
buf += " "
buf += "}"
return buf
def __setitem__(self, key: Key | str, value: Any) -> None:
if hasattr(value, "trivia") and value.trivia.comment:
value.trivia.comment = ""
super().__setitem__(key, value)
def __copy__(self) -> InlineTable:
return type(self)(self._value.copy(), self._trivia.copy(), self._new)
def _getstate(self, protocol: int = 3) -> tuple:
return (self._value, self._trivia)
class String(str, Item):
"""
A string literal.
"""
def __new__(cls, t, value, original, trivia):
return super().__new__(cls, value)
def __init__(self, t: StringType, _: str, original: str, trivia: Trivia) -> None:
super().__init__(trivia)
self._t = t
self._original = original
def unwrap(self) -> str:
return str(self)
@property
def discriminant(self) -> int:
return 11
@property
def value(self) -> str:
return self
def as_string(self) -> str:
return f"{self._t.value}{decode(self._original)}{self._t.value}"
def __add__(self: ItemT, other: str) -> ItemT:
if not isinstance(other, str):
return NotImplemented
result = super().__add__(other)
original = self._original + getattr(other, "_original", other)
return self._new(result, original)
def _new(self, result: str, original: str) -> String:
return String(self._t, result, original, self._trivia)
def _getstate(self, protocol=3):
return self._t, str(self), self._original, self._trivia
@classmethod
def from_raw(cls, value: str, type_=StringType.SLB, escape=True) -> String:
value = decode(value)
invalid = type_.invalid_sequences
if any(c in value for c in invalid):
raise InvalidStringError(value, invalid, type_.value)
escaped = type_.escaped_sequences
string_value = escape_string(value, escaped) if escape and escaped else value
return cls(type_, decode(value), string_value, Trivia())
class AoT(Item, _CustomList):
"""
An array of table literal
"""
def __init__(
self, body: list[Table], name: str | None = None, parsed: bool = False
) -> None:
self.name = name
self._body: list[Table] = []
self._parsed = parsed
super().__init__(Trivia(trail=""))
for table in body:
self.append(table)
def unwrap(self) -> list[dict[str, Any]]:
unwrapped = []
for t in self._body:
if hasattr(t, "unwrap"):
unwrapped.append(t.unwrap())
else:
unwrapped.append(t)
return unwrapped
@property
def body(self) -> list[Table]:
return self._body
@property
def discriminant(self) -> int:
return 12
@property
def value(self) -> list[dict[Any, Any]]:
return [v.value for v in self._body]
def __len__(self) -> int:
return len(self._body)
@overload
def __getitem__(self, key: slice) -> list[Table]: ...
@overload
def __getitem__(self, key: int) -> Table: ...
def __getitem__(self, key):
return self._body[key]
def __setitem__(self, key: slice | int, value: Any) -> None:
raise NotImplementedError
def __delitem__(self, key: slice | int) -> None:
del self._body[key]
list.__delitem__(self, key)
def insert(self, index: int, value: dict) -> None:
value = item(value, _parent=self)
if not isinstance(value, Table):
raise ValueError(f"Unsupported insert value type: {type(value)}")
length = len(self)
if index < 0:
index += length
if index < 0:
index = 0
elif index >= length:
index = length
m = re.match("(?s)^[^ ]*([ ]+).*$", self._trivia.indent)
if m:
indent = m.group(1)
m = re.match("(?s)^([^ ]*)(.*)$", value.trivia.indent)
if not m:
value.trivia.indent = indent
else:
value.trivia.indent = m.group(1) + indent + m.group(2)
prev_table = self._body[index - 1] if 0 < index and length else None
next_table = self._body[index + 1] if index < length - 1 else None
if not self._parsed:
if prev_table and "\n" not in value.trivia.indent:
value.trivia.indent = "\n" + value.trivia.indent
if next_table and "\n" not in next_table.trivia.indent:
next_table.trivia.indent = "\n" + next_table.trivia.indent
self._body.insert(index, value)
list.insert(self, index, value)
def invalidate_display_name(self):
"""Call ``invalidate_display_name`` on the contained tables"""
for child in self:
if hasattr(child, "invalidate_display_name"):
child.invalidate_display_name()
def as_string(self) -> str:
b = ""
for table in self._body:
b += table.as_string()
return b
def __repr__(self) -> str:
return f"<AoT {self.value}>"
def _getstate(self, protocol=3):
return self._body, self.name, self._parsed
class Null(Item):
"""
A null item.
"""
def __init__(self) -> None:
super().__init__(Trivia(trail=""))
def unwrap(self) -> None:
return None
@property
def discriminant(self) -> int:
return -1
@property
def value(self) -> None:
return None
def as_string(self) -> str:
return ""
def _getstate(self, protocol=3) -> tuple:
return ()
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