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| Dir : //opt/saltstack/salt/extras-3.10/arrow/parser.py |
"""Provides the :class:`Arrow <arrow.parser.DateTimeParser>` class, a better way to parse datetime strings."""
import re
import sys
from datetime import datetime, timedelta
from datetime import tzinfo as dt_tzinfo
from functools import lru_cache
from typing import (
Any,
ClassVar,
Dict,
Iterable,
List,
Match,
Optional,
Pattern,
SupportsFloat,
SupportsInt,
Tuple,
Union,
cast,
overload,
)
from dateutil import tz
from arrow import locales
from arrow.constants import DEFAULT_LOCALE
from arrow.util import next_weekday, normalize_timestamp
if sys.version_info < (3, 8): # pragma: no cover
from typing_extensions import Literal, TypedDict
else:
from typing import Literal, TypedDict # pragma: no cover
class ParserError(ValueError):
pass
# Allows for ParserErrors to be propagated from _build_datetime()
# when day_of_year errors occur.
# Before this, the ParserErrors were caught by the try/except in
# _parse_multiformat() and the appropriate error message was not
# transmitted to the user.
class ParserMatchError(ParserError):
pass
_WEEKDATE_ELEMENT = Union[str, bytes, SupportsInt, bytearray]
_FORMAT_TYPE = Literal[
"YYYY",
"YY",
"MM",
"M",
"DDDD",
"DDD",
"DD",
"D",
"HH",
"H",
"hh",
"h",
"mm",
"m",
"ss",
"s",
"X",
"x",
"ZZZ",
"ZZ",
"Z",
"S",
"W",
"MMMM",
"MMM",
"Do",
"dddd",
"ddd",
"d",
"a",
"A",
]
class _Parts(TypedDict, total=False):
year: int
month: int
day_of_year: int
day: int
hour: int
minute: int
second: int
microsecond: int
timestamp: float
expanded_timestamp: int
tzinfo: dt_tzinfo
am_pm: Literal["am", "pm"]
day_of_week: int
weekdate: Tuple[_WEEKDATE_ELEMENT, _WEEKDATE_ELEMENT, Optional[_WEEKDATE_ELEMENT]]
class DateTimeParser:
_FORMAT_RE: ClassVar[Pattern[str]] = re.compile(
r"(YYY?Y?|MM?M?M?|Do|DD?D?D?|d?d?d?d|HH?|hh?|mm?|ss?|S+|ZZ?Z?|a|A|x|X|W)"
)
_ESCAPE_RE: ClassVar[Pattern[str]] = re.compile(r"\[[^\[\]]*\]")
_ONE_OR_TWO_DIGIT_RE: ClassVar[Pattern[str]] = re.compile(r"\d{1,2}")
_ONE_OR_TWO_OR_THREE_DIGIT_RE: ClassVar[Pattern[str]] = re.compile(r"\d{1,3}")
_ONE_OR_MORE_DIGIT_RE: ClassVar[Pattern[str]] = re.compile(r"\d+")
_TWO_DIGIT_RE: ClassVar[Pattern[str]] = re.compile(r"\d{2}")
_THREE_DIGIT_RE: ClassVar[Pattern[str]] = re.compile(r"\d{3}")
_FOUR_DIGIT_RE: ClassVar[Pattern[str]] = re.compile(r"\d{4}")
_TZ_Z_RE: ClassVar[Pattern[str]] = re.compile(r"([\+\-])(\d{2})(?:(\d{2}))?|Z")
_TZ_ZZ_RE: ClassVar[Pattern[str]] = re.compile(r"([\+\-])(\d{2})(?:\:(\d{2}))?|Z")
_TZ_NAME_RE: ClassVar[Pattern[str]] = re.compile(r"\w[\w+\-/]+")
# NOTE: timestamps cannot be parsed from natural language strings (by removing the ^...$) because it will
# break cases like "15 Jul 2000" and a format list (see issue #447)
_TIMESTAMP_RE: ClassVar[Pattern[str]] = re.compile(r"^\-?\d+\.?\d+$")
_TIMESTAMP_EXPANDED_RE: ClassVar[Pattern[str]] = re.compile(r"^\-?\d+$")
_TIME_RE: ClassVar[Pattern[str]] = re.compile(
r"^(\d{2})(?:\:?(\d{2}))?(?:\:?(\d{2}))?(?:([\.\,])(\d+))?$"
)
_WEEK_DATE_RE: ClassVar[Pattern[str]] = re.compile(
r"(?P<year>\d{4})[\-]?W(?P<week>\d{2})[\-]?(?P<day>\d)?"
)
_BASE_INPUT_RE_MAP: ClassVar[Dict[_FORMAT_TYPE, Pattern[str]]] = {
"YYYY": _FOUR_DIGIT_RE,
"YY": _TWO_DIGIT_RE,
"MM": _TWO_DIGIT_RE,
"M": _ONE_OR_TWO_DIGIT_RE,
"DDDD": _THREE_DIGIT_RE,
"DDD": _ONE_OR_TWO_OR_THREE_DIGIT_RE,
"DD": _TWO_DIGIT_RE,
"D": _ONE_OR_TWO_DIGIT_RE,
"HH": _TWO_DIGIT_RE,
"H": _ONE_OR_TWO_DIGIT_RE,
"hh": _TWO_DIGIT_RE,
"h": _ONE_OR_TWO_DIGIT_RE,
"mm": _TWO_DIGIT_RE,
"m": _ONE_OR_TWO_DIGIT_RE,
"ss": _TWO_DIGIT_RE,
"s": _ONE_OR_TWO_DIGIT_RE,
"X": _TIMESTAMP_RE,
"x": _TIMESTAMP_EXPANDED_RE,
"ZZZ": _TZ_NAME_RE,
"ZZ": _TZ_ZZ_RE,
"Z": _TZ_Z_RE,
"S": _ONE_OR_MORE_DIGIT_RE,
"W": _WEEK_DATE_RE,
}
SEPARATORS: ClassVar[List[str]] = ["-", "/", "."]
locale: locales.Locale
_input_re_map: Dict[_FORMAT_TYPE, Pattern[str]]
def __init__(self, locale: str = DEFAULT_LOCALE, cache_size: int = 0) -> None:
self.locale = locales.get_locale(locale)
self._input_re_map = self._BASE_INPUT_RE_MAP.copy()
self._input_re_map.update(
{
"MMMM": self._generate_choice_re(
self.locale.month_names[1:], re.IGNORECASE
),
"MMM": self._generate_choice_re(
self.locale.month_abbreviations[1:], re.IGNORECASE
),
"Do": re.compile(self.locale.ordinal_day_re),
"dddd": self._generate_choice_re(
self.locale.day_names[1:], re.IGNORECASE
),
"ddd": self._generate_choice_re(
self.locale.day_abbreviations[1:], re.IGNORECASE
),
"d": re.compile(r"[1-7]"),
"a": self._generate_choice_re(
(self.locale.meridians["am"], self.locale.meridians["pm"])
),
# note: 'A' token accepts both 'am/pm' and 'AM/PM' formats to
# ensure backwards compatibility of this token
"A": self._generate_choice_re(self.locale.meridians.values()),
}
)
if cache_size > 0:
self._generate_pattern_re = lru_cache(maxsize=cache_size)( # type: ignore
self._generate_pattern_re
)
# TODO: since we support more than ISO 8601, we should rename this function
# IDEA: break into multiple functions
def parse_iso(
self, datetime_string: str, normalize_whitespace: bool = False
) -> datetime:
if normalize_whitespace:
datetime_string = re.sub(r"\s+", " ", datetime_string.strip())
has_space_divider = " " in datetime_string
has_t_divider = "T" in datetime_string
num_spaces = datetime_string.count(" ")
if has_space_divider and num_spaces != 1 or has_t_divider and num_spaces > 0:
raise ParserError(
f"Expected an ISO 8601-like string, but was given {datetime_string!r}. "
"Try passing in a format string to resolve this."
)
has_time = has_space_divider or has_t_divider
has_tz = False
# date formats (ISO 8601 and others) to test against
# NOTE: YYYYMM is omitted to avoid confusion with YYMMDD (no longer part of ISO 8601, but is still often used)
formats = [
"YYYY-MM-DD",
"YYYY-M-DD",
"YYYY-M-D",
"YYYY/MM/DD",
"YYYY/M/DD",
"YYYY/M/D",
"YYYY.MM.DD",
"YYYY.M.DD",
"YYYY.M.D",
"YYYYMMDD",
"YYYY-DDDD",
"YYYYDDDD",
"YYYY-MM",
"YYYY/MM",
"YYYY.MM",
"YYYY",
"W",
]
if has_time:
if has_space_divider:
date_string, time_string = datetime_string.split(" ", 1)
else:
date_string, time_string = datetime_string.split("T", 1)
time_parts = re.split(r"[\+\-Z]", time_string, 1, re.IGNORECASE)
time_components: Optional[Match[str]] = self._TIME_RE.match(time_parts[0])
if time_components is None:
raise ParserError(
"Invalid time component provided. "
"Please specify a format or provide a valid time component in the basic or extended ISO 8601 time format."
)
(
hours,
minutes,
seconds,
subseconds_sep,
subseconds,
) = time_components.groups()
has_tz = len(time_parts) == 2
has_minutes = minutes is not None
has_seconds = seconds is not None
has_subseconds = subseconds is not None
is_basic_time_format = ":" not in time_parts[0]
tz_format = "Z"
# use 'ZZ' token instead since tz offset is present in non-basic format
if has_tz and ":" in time_parts[1]:
tz_format = "ZZ"
time_sep = "" if is_basic_time_format else ":"
if has_subseconds:
time_string = "HH{time_sep}mm{time_sep}ss{subseconds_sep}S".format(
time_sep=time_sep, subseconds_sep=subseconds_sep
)
elif has_seconds:
time_string = "HH{time_sep}mm{time_sep}ss".format(time_sep=time_sep)
elif has_minutes:
time_string = f"HH{time_sep}mm"
else:
time_string = "HH"
if has_space_divider:
formats = [f"{f} {time_string}" for f in formats]
else:
formats = [f"{f}T{time_string}" for f in formats]
if has_time and has_tz:
# Add "Z" or "ZZ" to the format strings to indicate to
# _parse_token() that a timezone needs to be parsed
formats = [f"{f}{tz_format}" for f in formats]
return self._parse_multiformat(datetime_string, formats)
def parse(
self,
datetime_string: str,
fmt: Union[List[str], str],
normalize_whitespace: bool = False,
) -> datetime:
if normalize_whitespace:
datetime_string = re.sub(r"\s+", " ", datetime_string)
if isinstance(fmt, list):
return self._parse_multiformat(datetime_string, fmt)
try:
fmt_tokens: List[_FORMAT_TYPE]
fmt_pattern_re: Pattern[str]
fmt_tokens, fmt_pattern_re = self._generate_pattern_re(fmt)
except re.error as e:
raise ParserMatchError(
f"Failed to generate regular expression pattern: {e}."
)
match = fmt_pattern_re.search(datetime_string)
if match is None:
raise ParserMatchError(
f"Failed to match {fmt!r} when parsing {datetime_string!r}."
)
parts: _Parts = {}
for token in fmt_tokens:
value: Union[Tuple[str, str, str], str]
if token == "Do":
value = match.group("value")
elif token == "W":
value = (match.group("year"), match.group("week"), match.group("day"))
else:
value = match.group(token)
if value is None:
raise ParserMatchError(
f"Unable to find a match group for the specified token {token!r}."
)
self._parse_token(token, value, parts) # type: ignore
return self._build_datetime(parts)
def _generate_pattern_re(self, fmt: str) -> Tuple[List[_FORMAT_TYPE], Pattern[str]]:
# fmt is a string of tokens like 'YYYY-MM-DD'
# we construct a new string by replacing each
# token by its pattern:
# 'YYYY-MM-DD' -> '(?P<YYYY>\d{4})-(?P<MM>\d{2})-(?P<DD>\d{2})'
tokens: List[_FORMAT_TYPE] = []
offset = 0
# Escape all special RegEx chars
escaped_fmt = re.escape(fmt)
# Extract the bracketed expressions to be reinserted later.
escaped_fmt = re.sub(self._ESCAPE_RE, "#", escaped_fmt)
# Any number of S is the same as one.
# TODO: allow users to specify the number of digits to parse
escaped_fmt = re.sub(r"S+", "S", escaped_fmt)
escaped_data = re.findall(self._ESCAPE_RE, fmt)
fmt_pattern = escaped_fmt
for m in self._FORMAT_RE.finditer(escaped_fmt):
token: _FORMAT_TYPE = cast(_FORMAT_TYPE, m.group(0))
try:
input_re = self._input_re_map[token]
except KeyError:
raise ParserError(f"Unrecognized token {token!r}.")
input_pattern = f"(?P<{token}>{input_re.pattern})"
tokens.append(token)
# a pattern doesn't have the same length as the token
# it replaces! We keep the difference in the offset variable.
# This works because the string is scanned left-to-right and matches
# are returned in the order found by finditer.
fmt_pattern = (
fmt_pattern[: m.start() + offset]
+ input_pattern
+ fmt_pattern[m.end() + offset :]
)
offset += len(input_pattern) - (m.end() - m.start())
final_fmt_pattern = ""
split_fmt = fmt_pattern.split(r"\#")
# Due to the way Python splits, 'split_fmt' will always be longer
for i in range(len(split_fmt)):
final_fmt_pattern += split_fmt[i]
if i < len(escaped_data):
final_fmt_pattern += escaped_data[i][1:-1]
# Wrap final_fmt_pattern in a custom word boundary to strictly
# match the formatting pattern and filter out date and time formats
# that include junk such as: blah1998-09-12 blah, blah 1998-09-12blah,
# blah1998-09-12blah. The custom word boundary matches every character
# that is not a whitespace character to allow for searching for a date
# and time string in a natural language sentence. Therefore, searching
# for a string of the form YYYY-MM-DD in "blah 1998-09-12 blah" will
# work properly.
# Certain punctuation before or after the target pattern such as
# "1998-09-12," is permitted. For the full list of valid punctuation,
# see the documentation.
starting_word_boundary = (
r"(?<!\S\S)" # Don't have two consecutive non-whitespace characters. This ensures that we allow cases
# like .11.25.2019 but not 1.11.25.2019 (for pattern MM.DD.YYYY)
r"(?<![^\,\.\;\:\?\!\"\'\`\[\]\{\}\(\)<>\s])" # This is the list of punctuation that is ok before the
# pattern (i.e. "It can't not be these characters before the pattern")
r"(\b|^)"
# The \b is to block cases like 1201912 but allow 201912 for pattern YYYYMM. The ^ was necessary to allow a
# negative number through i.e. before epoch numbers
)
ending_word_boundary = (
r"(?=[\,\.\;\:\?\!\"\'\`\[\]\{\}\(\)\<\>]?" # Positive lookahead stating that these punctuation marks
# can appear after the pattern at most 1 time
r"(?!\S))" # Don't allow any non-whitespace character after the punctuation
)
bounded_fmt_pattern = r"{}{}{}".format(
starting_word_boundary, final_fmt_pattern, ending_word_boundary
)
return tokens, re.compile(bounded_fmt_pattern, flags=re.IGNORECASE)
@overload
def _parse_token(
self,
token: Literal[
"YYYY",
"YY",
"MM",
"M",
"DDDD",
"DDD",
"DD",
"D",
"Do",
"HH",
"hh",
"h",
"H",
"mm",
"m",
"ss",
"s",
"x",
],
value: Union[str, bytes, SupportsInt, bytearray],
parts: _Parts,
) -> None:
... # pragma: no cover
@overload
def _parse_token(
self,
token: Literal["X"],
value: Union[str, bytes, SupportsFloat, bytearray],
parts: _Parts,
) -> None:
... # pragma: no cover
@overload
def _parse_token(
self,
token: Literal["MMMM", "MMM", "dddd", "ddd", "S"],
value: Union[str, bytes, bytearray],
parts: _Parts,
) -> None:
... # pragma: no cover
@overload
def _parse_token(
self,
token: Literal["a", "A", "ZZZ", "ZZ", "Z"],
value: Union[str, bytes],
parts: _Parts,
) -> None:
... # pragma: no cover
@overload
def _parse_token(
self,
token: Literal["W"],
value: Tuple[_WEEKDATE_ELEMENT, _WEEKDATE_ELEMENT, Optional[_WEEKDATE_ELEMENT]],
parts: _Parts,
) -> None:
... # pragma: no cover
def _parse_token(
self,
token: Any,
value: Any,
parts: _Parts,
) -> None:
if token == "YYYY":
parts["year"] = int(value)
elif token == "YY":
value = int(value)
parts["year"] = 1900 + value if value > 68 else 2000 + value
elif token in ["MMMM", "MMM"]:
# FIXME: month_number() is nullable
parts["month"] = self.locale.month_number(value.lower()) # type: ignore
elif token in ["MM", "M"]:
parts["month"] = int(value)
elif token in ["DDDD", "DDD"]:
parts["day_of_year"] = int(value)
elif token in ["DD", "D"]:
parts["day"] = int(value)
elif token == "Do":
parts["day"] = int(value)
elif token == "dddd":
# locale day names are 1-indexed
day_of_week = [x.lower() for x in self.locale.day_names].index(
value.lower()
)
parts["day_of_week"] = day_of_week - 1
elif token == "ddd":
# locale day abbreviations are 1-indexed
day_of_week = [x.lower() for x in self.locale.day_abbreviations].index(
value.lower()
)
parts["day_of_week"] = day_of_week - 1
elif token.upper() in ["HH", "H"]:
parts["hour"] = int(value)
elif token in ["mm", "m"]:
parts["minute"] = int(value)
elif token in ["ss", "s"]:
parts["second"] = int(value)
elif token == "S":
# We have the *most significant* digits of an arbitrary-precision integer.
# We want the six most significant digits as an integer, rounded.
# IDEA: add nanosecond support somehow? Need datetime support for it first.
value = value.ljust(7, "0")
# floating-point (IEEE-754) defaults to half-to-even rounding
seventh_digit = int(value[6])
if seventh_digit == 5:
rounding = int(value[5]) % 2
elif seventh_digit > 5:
rounding = 1
else:
rounding = 0
parts["microsecond"] = int(value[:6]) + rounding
elif token == "X":
parts["timestamp"] = float(value)
elif token == "x":
parts["expanded_timestamp"] = int(value)
elif token in ["ZZZ", "ZZ", "Z"]:
parts["tzinfo"] = TzinfoParser.parse(value)
elif token in ["a", "A"]:
if value in (self.locale.meridians["am"], self.locale.meridians["AM"]):
parts["am_pm"] = "am"
if "hour" in parts and not 0 <= parts["hour"] <= 12:
raise ParserMatchError(
f"Hour token value must be between 0 and 12 inclusive for token {token!r}."
)
elif value in (self.locale.meridians["pm"], self.locale.meridians["PM"]):
parts["am_pm"] = "pm"
elif token == "W":
parts["weekdate"] = value
@staticmethod
def _build_datetime(parts: _Parts) -> datetime:
weekdate = parts.get("weekdate")
if weekdate is not None:
year, week = int(weekdate[0]), int(weekdate[1])
if weekdate[2] is not None:
_day = int(weekdate[2])
else:
# day not given, default to 1
_day = 1
date_string = f"{year}-{week}-{_day}"
# tokens for ISO 8601 weekdates
dt = datetime.strptime(date_string, "%G-%V-%u")
parts["year"] = dt.year
parts["month"] = dt.month
parts["day"] = dt.day
timestamp = parts.get("timestamp")
if timestamp is not None:
return datetime.fromtimestamp(timestamp, tz=tz.tzutc())
expanded_timestamp = parts.get("expanded_timestamp")
if expanded_timestamp is not None:
return datetime.fromtimestamp(
normalize_timestamp(expanded_timestamp),
tz=tz.tzutc(),
)
day_of_year = parts.get("day_of_year")
if day_of_year is not None:
_year = parts.get("year")
month = parts.get("month")
if _year is None:
raise ParserError(
"Year component is required with the DDD and DDDD tokens."
)
if month is not None:
raise ParserError(
"Month component is not allowed with the DDD and DDDD tokens."
)
date_string = f"{_year}-{day_of_year}"
try:
dt = datetime.strptime(date_string, "%Y-%j")
except ValueError:
raise ParserError(
f"The provided day of year {day_of_year!r} is invalid."
)
parts["year"] = dt.year
parts["month"] = dt.month
parts["day"] = dt.day
day_of_week: Optional[int] = parts.get("day_of_week")
day = parts.get("day")
# If day is passed, ignore day of week
if day_of_week is not None and day is None:
year = parts.get("year", 1970)
month = parts.get("month", 1)
day = 1
# dddd => first day of week after epoch
# dddd YYYY => first day of week in specified year
# dddd MM YYYY => first day of week in specified year and month
# dddd MM => first day after epoch in specified month
next_weekday_dt = next_weekday(datetime(year, month, day), day_of_week)
parts["year"] = next_weekday_dt.year
parts["month"] = next_weekday_dt.month
parts["day"] = next_weekday_dt.day
am_pm = parts.get("am_pm")
hour = parts.get("hour", 0)
if am_pm == "pm" and hour < 12:
hour += 12
elif am_pm == "am" and hour == 12:
hour = 0
# Support for midnight at the end of day
if hour == 24:
if parts.get("minute", 0) != 0:
raise ParserError("Midnight at the end of day must not contain minutes")
if parts.get("second", 0) != 0:
raise ParserError("Midnight at the end of day must not contain seconds")
if parts.get("microsecond", 0) != 0:
raise ParserError(
"Midnight at the end of day must not contain microseconds"
)
hour = 0
day_increment = 1
else:
day_increment = 0
# account for rounding up to 1000000
microsecond = parts.get("microsecond", 0)
if microsecond == 1000000:
microsecond = 0
second_increment = 1
else:
second_increment = 0
increment = timedelta(days=day_increment, seconds=second_increment)
return (
datetime(
year=parts.get("year", 1),
month=parts.get("month", 1),
day=parts.get("day", 1),
hour=hour,
minute=parts.get("minute", 0),
second=parts.get("second", 0),
microsecond=microsecond,
tzinfo=parts.get("tzinfo"),
)
+ increment
)
def _parse_multiformat(self, string: str, formats: Iterable[str]) -> datetime:
_datetime: Optional[datetime] = None
for fmt in formats:
try:
_datetime = self.parse(string, fmt)
break
except ParserMatchError:
pass
if _datetime is None:
supported_formats = ", ".join(formats)
raise ParserError(
f"Could not match input {string!r} to any of the following formats: {supported_formats}."
)
return _datetime
# generates a capture group of choices separated by an OR operator
@staticmethod
def _generate_choice_re(
choices: Iterable[str], flags: Union[int, re.RegexFlag] = 0
) -> Pattern[str]:
return re.compile(r"({})".format("|".join(choices)), flags=flags)
class TzinfoParser:
_TZINFO_RE: ClassVar[Pattern[str]] = re.compile(
r"^([\+\-])?(\d{2})(?:\:?(\d{2}))?$"
)
@classmethod
def parse(cls, tzinfo_string: str) -> dt_tzinfo:
tzinfo: Optional[dt_tzinfo] = None
if tzinfo_string == "local":
tzinfo = tz.tzlocal()
elif tzinfo_string in ["utc", "UTC", "Z"]:
tzinfo = tz.tzutc()
else:
iso_match = cls._TZINFO_RE.match(tzinfo_string)
if iso_match:
sign: Optional[str]
hours: str
minutes: Union[str, int, None]
sign, hours, minutes = iso_match.groups()
seconds = int(hours) * 3600 + int(minutes or 0) * 60
if sign == "-":
seconds *= -1
tzinfo = tz.tzoffset(None, seconds)
else:
tzinfo = tz.gettz(tzinfo_string)
if tzinfo is None:
raise ParserError(f"Could not parse timezone expression {tzinfo_string!r}.")
return tzinfo