OpenHome/venv/Lib/site-packages/sqlalchemy/processors.py

# sqlalchemy/processors.py
# Copyright (C) 2010-2021 the SQLAlchemy authors and contributors
# <see AUTHORS file>
# Copyright (C) 2010 Gaetan de Menten gdementen@gmail.com
#
# This module is part of SQLAlchemy and is released under
# the MIT License: http://www.opensource.org/licenses/mit-license.php

"""defines generic type conversion functions, as used in bind and result
processors.

They all share one common characteristic: None is passed through unchanged.

"""

import codecs
import datetime
import re

from . import util


def str_to_datetime_processor_factory(regexp, type_):
    rmatch = regexp.match
    # Even on python2.6 datetime.strptime is both slower than this code
    # and it does not support microseconds.
    has_named_groups = bool(regexp.groupindex)

    def process(value):
        if value is None:
            return None
        else:
            try:
                m = rmatch(value)
            except TypeError as err:
                util.raise_(
                    ValueError(
                        "Couldn't parse %s string '%r' "
                        "- value is not a string." % (type_.__name__, value)
                    ),
                    from_=err,
                )
            if m is None:
                raise ValueError(
                    "Couldn't parse %s string: "
                    "'%s'" % (type_.__name__, value)
                )
            if has_named_groups:
                groups = m.groupdict(0)
                return type_(
                    **dict(
                        list(
                            zip(
                                iter(groups.keys()),
                                list(map(int, iter(groups.values()))),
                            )
                        )
                    )
                )
            else:
                return type_(*list(map(int, m.groups(0))))

    return process


def py_fallback():
    def to_unicode_processor_factory(encoding, errors=None):
        decoder = codecs.getdecoder(encoding)

        def process(value):
            if value is None:
                return None
            else:
                # decoder returns a tuple: (value, len). Simply dropping the
                # len part is safe: it is done that way in the normal
                # 'xx'.decode(encoding) code path.
                return decoder(value, errors)[0]

        return process

    def to_conditional_unicode_processor_factory(encoding, errors=None):
        decoder = codecs.getdecoder(encoding)

        def process(value):
            if value is None:
                return None
            elif isinstance(value, util.text_type):
                return value
            else:
                # decoder returns a tuple: (value, len). Simply dropping the
                # len part is safe: it is done that way in the normal
                # 'xx'.decode(encoding) code path.
                return decoder(value, errors)[0]

        return process

    def to_decimal_processor_factory(target_class, scale):
        fstring = "%%.%df" % scale

        def process(value):
            if value is None:
                return None
            else:
                return target_class(fstring % value)

        return process

    def to_float(value):  # noqa
        if value is None:
            return None
        else:
            return float(value)

    def to_str(value):  # noqa
        if value is None:
            return None
        else:
            return str(value)

    def int_to_boolean(value):  # noqa
        if value is None:
            return None
        else:
            return bool(value)

    DATETIME_RE = re.compile(
        r"(\d+)-(\d+)-(\d+) (\d+):(\d+):(\d+)(?:\.(\d+))?"
    )
    TIME_RE = re.compile(r"(\d+):(\d+):(\d+)(?:\.(\d+))?")
    DATE_RE = re.compile(r"(\d+)-(\d+)-(\d+)")

    str_to_datetime = str_to_datetime_processor_factory(  # noqa
        DATETIME_RE, datetime.datetime
    )
    str_to_time = str_to_datetime_processor_factory(  # noqa
        TIME_RE, datetime.time
    )  # noqa
    str_to_date = str_to_datetime_processor_factory(  # noqa
        DATE_RE, datetime.date
    )  # noqa
    return locals()


try:
    from sqlalchemy.cprocessors import DecimalResultProcessor  # noqa
    from sqlalchemy.cprocessors import int_to_boolean  # noqa
    from sqlalchemy.cprocessors import str_to_date  # noqa
    from sqlalchemy.cprocessors import str_to_datetime  # noqa
    from sqlalchemy.cprocessors import str_to_time  # noqa
    from sqlalchemy.cprocessors import to_float  # noqa
    from sqlalchemy.cprocessors import to_str  # noqa
    from sqlalchemy.cprocessors import UnicodeResultProcessor  # noqa

    def to_unicode_processor_factory(encoding, errors=None):
        if errors is not None:
            return UnicodeResultProcessor(encoding, errors).process
        else:
            return UnicodeResultProcessor(encoding).process

    def to_conditional_unicode_processor_factory(encoding, errors=None):
        if errors is not None:
            return UnicodeResultProcessor(encoding, errors).conditional_process
        else:
            return UnicodeResultProcessor(encoding).conditional_process

    def to_decimal_processor_factory(target_class, scale):
        # Note that the scale argument is not taken into account for integer
        # values in the C implementation while it is in the Python one.
        # For example, the Python implementation might return
        # Decimal('5.00000') whereas the C implementation will
        # return Decimal('5'). These are equivalent of course.
        return DecimalResultProcessor(target_class, "%%.%df" % scale).process


except ImportError:
    globals().update(py_fallback())
Initial commit 2021-07-21 21:33:05 +02:00			`# sqlalchemy/processors.py`
			`# Copyright (C) 2010-2021 the SQLAlchemy authors and contributors`
			`# <see AUTHORS file>`
			`# Copyright (C) 2010 Gaetan de Menten gdementen@gmail.com`
			`#`
			`# This module is part of SQLAlchemy and is released under`
			`# the MIT License: http://www.opensource.org/licenses/mit-license.php`

			`"""defines generic type conversion functions, as used in bind and result`
			`processors.`

			`They all share one common characteristic: None is passed through unchanged.`

			`"""`

			`import codecs`
			`import datetime`
			`import re`

			`from . import util`


			`def str_to_datetime_processor_factory(regexp, type_):`
			`rmatch = regexp.match`
			`# Even on python2.6 datetime.strptime is both slower than this code`
			`# and it does not support microseconds.`
			`has_named_groups = bool(regexp.groupindex)`

			`def process(value):`
			`if value is None:`
			`return None`
			`else:`
			`try:`
			`m = rmatch(value)`
			`except TypeError as err:`
			`util.raise_(`
			`ValueError(`
			`"Couldn't parse %s string '%r' "`
			`"- value is not a string." % (type_.__name__, value)`
			`),`
			`from_=err,`
			`)`
			`if m is None:`
			`raise ValueError(`
			`"Couldn't parse %s string: "`
			`"'%s'" % (type_.__name__, value)`
			`)`
			`if has_named_groups:`
			`groups = m.groupdict(0)`
			`return type_(`
			`**dict(`
			`list(`
			`zip(`
			`iter(groups.keys()),`
			`list(map(int, iter(groups.values()))),`
			`)`
			`)`
			`)`
			`)`
			`else:`
			`return type_(*list(map(int, m.groups(0))))`

			`return process`


			`def py_fallback():`
			`def to_unicode_processor_factory(encoding, errors=None):`
			`decoder = codecs.getdecoder(encoding)`

			`def process(value):`
			`if value is None:`
			`return None`
			`else:`
			`# decoder returns a tuple: (value, len). Simply dropping the`
			`# len part is safe: it is done that way in the normal`
			`# 'xx'.decode(encoding) code path.`
			`return decoder(value, errors)[0]`

			`return process`

			`def to_conditional_unicode_processor_factory(encoding, errors=None):`
			`decoder = codecs.getdecoder(encoding)`

			`def process(value):`
			`if value is None:`
			`return None`
			`elif isinstance(value, util.text_type):`
			`return value`
			`else:`
			`# decoder returns a tuple: (value, len). Simply dropping the`
			`# len part is safe: it is done that way in the normal`
			`# 'xx'.decode(encoding) code path.`
			`return decoder(value, errors)[0]`

			`return process`

			`def to_decimal_processor_factory(target_class, scale):`
			`fstring = "%%.%df" % scale`

			`def process(value):`
			`if value is None:`
			`return None`
			`else:`
			`return target_class(fstring % value)`

			`return process`

			`def to_float(value): # noqa`
			`if value is None:`
			`return None`
			`else:`
			`return float(value)`

			`def to_str(value): # noqa`
			`if value is None:`
			`return None`
			`else:`
			`return str(value)`

			`def int_to_boolean(value): # noqa`
			`if value is None:`
			`return None`
			`else:`
			`return bool(value)`

			`DATETIME_RE = re.compile(`
			`r"(\d+)-(\d+)-(\d+) (\d+):(\d+):(\d+)(?:\.(\d+))?"`
			`)`
			`TIME_RE = re.compile(r"(\d+):(\d+):(\d+)(?:\.(\d+))?")`
			`DATE_RE = re.compile(r"(\d+)-(\d+)-(\d+)")`

			`str_to_datetime = str_to_datetime_processor_factory( # noqa`
			`DATETIME_RE, datetime.datetime`
			`)`
			`str_to_time = str_to_datetime_processor_factory( # noqa`
			`TIME_RE, datetime.time`
			`) # noqa`
			`str_to_date = str_to_datetime_processor_factory( # noqa`
			`DATE_RE, datetime.date`
			`) # noqa`
			`return locals()`


			`try:`
			`from sqlalchemy.cprocessors import DecimalResultProcessor # noqa`
			`from sqlalchemy.cprocessors import int_to_boolean # noqa`
			`from sqlalchemy.cprocessors import str_to_date # noqa`
			`from sqlalchemy.cprocessors import str_to_datetime # noqa`
			`from sqlalchemy.cprocessors import str_to_time # noqa`
			`from sqlalchemy.cprocessors import to_float # noqa`
			`from sqlalchemy.cprocessors import to_str # noqa`
			`from sqlalchemy.cprocessors import UnicodeResultProcessor # noqa`

			`def to_unicode_processor_factory(encoding, errors=None):`
			`if errors is not None:`
			`return UnicodeResultProcessor(encoding, errors).process`
			`else:`
			`return UnicodeResultProcessor(encoding).process`

			`def to_conditional_unicode_processor_factory(encoding, errors=None):`
			`if errors is not None:`
			`return UnicodeResultProcessor(encoding, errors).conditional_process`
			`else:`
			`return UnicodeResultProcessor(encoding).conditional_process`

			`def to_decimal_processor_factory(target_class, scale):`
			`# Note that the scale argument is not taken into account for integer`
			`# values in the C implementation while it is in the Python one.`
			`# For example, the Python implementation might return`
			`# Decimal('5.00000') whereas the C implementation will`
			`# return Decimal('5'). These are equivalent of course.`
			`return DecimalResultProcessor(target_class, "%%.%df" % scale).process`


			`except ImportError:`
			`globals().update(py_fallback())`