pw_tokenizer/py/pw_tokenizer/decode.py - pigweed/pigweed - Git at Google

 # Copyright 2020 The Pigweed Authors
 #
 # Licensed under the Apache License, Version 2.0 (the "License"); you may not
 # use this file except in compliance with the License. You may obtain a copy of
 # the License at
 #
 #     https://www.apache.org/licenses/LICENSE-2.0
 #
 # Unless required by applicable law or agreed to in writing, software
 # distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
 # WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
 # License for the specific language governing permissions and limitations under
 # the License.
 """Decodes arguments and formats tokenized messages.

 The decode(format_string, encoded_arguments) function provides a simple way to
 format a string with encoded arguments. The FormatString class may also be used.

 Missing, truncated, or otherwise corrupted arguments are handled and displayed
 in the resulting string with an error message.
 """

 import re
 import struct
 from typing import Iterable, List, NamedTuple, Match, Sequence, Tuple


 def zigzag_decode(value: int) -> int:
     """ZigZag decode function from protobuf's wire_format module."""
     if not value & 0x1:
         return value >> 1
     return (value >> 1) ^ (~0)


 class FormatSpec:
     """Represents a format specifier parsed from a printf-style string."""

     # Regular expression for finding format specifiers.
     FORMAT_SPEC = re.compile(r'%(?:(?P<flags>[+\- #0]*\d*(?:\.\d+)?)'
                              r'(?P<length>hh|h|ll|l|j|z|t|L)?'
                              r'(?P<type>[csdioxXufFeEaAgGnp])|%)')

     # Conversions to make format strings Python compatible.
     _UNSUPPORTED_LENGTH = frozenset(['hh', 'll', 'j', 'z', 't'])
     _REMAP_TYPE = {'a': 'f', 'A': 'F'}

     # Conversion specifiers by type; n is not supported.
     _SIGNED_INT = 'di'
     _UNSIGNED_INT = frozenset('oxXup')
     _FLOATING_POINT = frozenset('fFeEaAgG')

     _PACKED_FLOAT = struct.Struct('<f')

     @classmethod
     def from_string(cls, format_specifier: str):
         """Creates a FormatSpec from a str with a single format specifier."""
         match = cls.FORMAT_SPEC.fullmatch(format_specifier)

         if not match:
             raise ValueError(
                 '{!r} is not a valid single format specifier'.format(
                     format_specifier))

         return cls(match)

     def __init__(self, re_match: Match):
         """Constructs a FormatSpec from an re.Match object for FORMAT_SPEC."""
         self.match = re_match
         self.specifier: str = self.match.group()

         self.flags: str = self.match.group('flags') or ''
         self.length: str = self.match.group('length') or ''

         # If there is no type, the format spec is %%.
         self.type: str = self.match.group('type') or '%'

         # %p prints as 0xFEEDBEEF; other specs may need length/type switched
         if self.type == 'p':
             self.compatible = '0x%08X'
         else:
             self.compatible = ''.join([
                 '%', self.flags,
                 '' if self.length in self._UNSUPPORTED_LENGTH else '',
                 self._REMAP_TYPE.get(self.type, self.type)
             ])

     def decode(self, encoded_arg: bytes) -> 'DecodedArg':
         """Decodes the provided data according to this format specifier."""
         if self.type == '%':  # literal %
             return DecodedArg(self, (),
                               b'')  # Use () as the value for % formatting.

         if self.type == 's':  # string
             return self._decode_string(encoded_arg)

         if self.type == 'c':  # character
             return self._decode_char(encoded_arg)

         if self.type in self._SIGNED_INT:
             return self._decode_signed_integer(encoded_arg)

         if self.type in self._UNSIGNED_INT:
             return self._decode_unsigned_integer(encoded_arg)

         if self.type in self._FLOATING_POINT:
             return self._decode_float(encoded_arg)

         # Unsupported specifier (e.g. %n)
         return DecodedArg(
             self, None, b'', DecodedArg.DECODE_ERROR,
             'Unsupported conversion specifier "{}"'.format(self.type))

     def _decode_signed_integer(self, encoded: bytes) -> 'DecodedArg':
         """Decodes a signed variable-length integer."""
         if not encoded:
             return DecodedArg.missing(self)

         count = 0
         result = 0
         shift = 0

         for byte in encoded:
             count += 1
             result |= (byte & 0x7f) << shift

             if not byte & 0x80:
                 return DecodedArg(self, zigzag_decode(result), encoded[:count])

             shift += 7
             if shift >= 64:
                 break

         return DecodedArg(self, None, encoded[:count], DecodedArg.DECODE_ERROR,
                           'Unterminated variable-length integer')

     def _decode_unsigned_integer(self, encoded: bytes) -> 'DecodedArg':
         arg = self._decode_signed_integer(encoded)

         # Since ZigZag encoding is used, unsigned integers must be masked off to
         # their original bit length.
         if arg.value is not None:
             arg.value &= (1 << self.size_bits()) - 1

         return arg

     def _decode_float(self, encoded: bytes) -> 'DecodedArg':
         if len(encoded) < 4:
             return DecodedArg.missing(self)

         return DecodedArg(self,
                           self._PACKED_FLOAT.unpack_from(encoded)[0],
                           encoded[:4])

     def _decode_string(self, encoded: bytes) -> 'DecodedArg':
         """Reads a unicode string from the encoded data."""
         if not encoded:
             return DecodedArg.missing(self)

         size_and_status = encoded[0]
         status = DecodedArg.OK

         if size_and_status & 0x80:
             status |= DecodedArg.TRUNCATED
             size_and_status &= 0x7f

         raw_data = encoded[0:size_and_status + 1]
         data = raw_data[1:]

         if len(data) < size_and_status:
             status |= DecodedArg.DECODE_ERROR

         try:
             decoded = data.decode()
         except UnicodeDecodeError as err:
             return DecodedArg(self,
                               repr(bytes(data)).lstrip('b'), raw_data,
                               status | DecodedArg.DECODE_ERROR, err)

         return DecodedArg(self, decoded, raw_data, status)

     def _decode_char(self, encoded: bytes) -> 'DecodedArg':
         """Reads an integer from the data, then converts it to a string."""
         arg = self._decode_signed_integer(encoded)

         if arg.ok():
             try:
                 arg.value = chr(arg.value)
             except (OverflowError, ValueError) as err:
                 arg.error = err
                 arg.status |= DecodedArg.DECODE_ERROR

         return arg

     def size_bits(self) -> int:
         """Size of the argument in bits; 0 for strings."""
         if self.type == 's':
             return 0

         # TODO(hepler): 64-bit targets likely have 64-bit l, j, z, and t.
         return 64 if self.length in ['ll', 'j'] else 32

     def __str__(self) -> str:
         return self.specifier


 class DecodedArg:
     """Represents a decoded argument that is ready to be formatted."""

     # Status flags for a decoded argument. These values should match the
     # DecodingStatus enum in pw_tokenizer/internal/decode.h.
     OK = 0  # decoding was successful
     MISSING = 1  # the argument was not present in the data
     TRUNCATED = 2  # the argument was truncated during encoding
     DECODE_ERROR = 4  # an error occurred while decoding the argument
     SKIPPED = 8  # argument was skipped due to a previous error

     @classmethod
     def missing(cls, specifier: FormatSpec):
         return cls(specifier, None, b'', cls.MISSING)

     def __init__(self,
                  specifier: FormatSpec,
                  value,
                  raw_data: bytes,
                  status: int = OK,
                  error=None):
         self.specifier = specifier  # FormatSpec (e.g. to represent "%0.2f")
         self.value = value  # the decoded value, or None if decoding failed
         self.raw_data = bytes(
             raw_data)  # the exact bytes used to decode this arg
         self._status = status
         self.error = error

     def ok(self) -> bool:
         """The argument was decoded without errors."""
         return self.status == self.OK or self.status == self.TRUNCATED

     @property
     def status(self) -> int:
         return self._status

     @status.setter
     def status(self, status: int):
         # The %% specifier is always OK and should always be printed normally.
         self._status = status if self.specifier.type != '%' else self.OK

     def format(self) -> str:
         """Returns formatted version of this argument, with error handling."""
         if self.status == self.TRUNCATED:
             return self.specifier.compatible % (self.value + '[...]')

         if self.ok():
             try:
                 return self.specifier.compatible % self.value
             except (OverflowError, TypeError, ValueError) as err:
                 self.status |= self.DECODE_ERROR
                 self.error = err

         if self.status & self.SKIPPED:
             message = '{} SKIPPED'.format(self.specifier)
         elif self.status == self.MISSING:
             message = '{} MISSING'.format(self.specifier)
         elif self.status & self.DECODE_ERROR:
             message = '{} ERROR'.format(self.specifier)
         else:
             raise AssertionError('Unhandled DecodedArg status {:x}!'.format(
                 self.status))

         if self.value is None or not str(self.value):
             return '<[{}]>'.format(message)

         return '<[{} ({})]>'.format(message, self.value)

     def __str__(self) -> str:
         return self.format()

     def __repr__(self) -> str:
         return 'DecodedArg({!r})'.format(self)


 def parse_format_specifiers(format_string: str) -> Iterable[FormatSpec]:
     for spec in FormatSpec.FORMAT_SPEC.finditer(format_string):
         yield FormatSpec(spec)


 class FormattedString(NamedTuple):
     value: str
     args: Sequence[DecodedArg]
     remaining: bytes


 class FormatString:
     """Represents a printf-style format string."""
     def __init__(self, format_string: str):
         """Parses format specifiers in the format string."""
         self.format_string = format_string
         self.specifiers = tuple(parse_format_specifiers(self.format_string))

         # List of non-specifier string pieces with room for formatted arguments.
         self._segments = self._parse_string_segments()

     def _parse_string_segments(self) -> List:
         """Splits the format string by format specifiers."""
         if not self.specifiers:
             return [self.format_string]

         spec_spans = [spec.match.span() for spec in self.specifiers]

         # Start with the part of the format string up to the first specifier.
         string_pieces = [self.format_string[:spec_spans[0][0]]]

         for ((_, end1), (start2, _)) in zip(spec_spans[:-1], spec_spans[1:]):
             string_pieces.append(self.format_string[end1:start2])

         # Append the format string segment after the last format specifier.
         string_pieces.append(self.format_string[spec_spans[-1][1]:])

         # Make a list with spots for the replacements between the string pieces.
         segments: List = [None] * (len(string_pieces) + len(self.specifiers))
         segments[::2] = string_pieces

         return segments

     def decode(self, encoded: bytes) -> Tuple[Sequence[DecodedArg], bytes]:
         """Decodes arguments according to the format string.

         Args:
           encoded: bytes; the encoded arguments

         Returns:
           tuple with the decoded arguments and any unparsed data
         """
         decoded_args = []

         fatal_error = False
         index = 0

         for spec in self.specifiers:
             arg = spec.decode(encoded[index:])

             if fatal_error:
                 # After an error is encountered, continue to attempt to parse
                 # arguments, but mark them all as SKIPPED. If an error occurs,
                 # it's impossible to know if subsequent arguments are valid.
                 arg.status |= DecodedArg.SKIPPED
             elif not arg.ok():
                 fatal_error = True

             decoded_args.append(arg)
             index += len(arg.raw_data)

         return tuple(decoded_args), encoded[index:]

     def format(self,
                encoded_args: bytes,
                show_errors: bool = False) -> FormattedString:
         """Decodes arguments and formats the string with them.

         Args:
           encoded_args: the arguments to decode and format the string with
           show_errors: if True, an error message is used in place of the %
               conversion specifier when an argument fails to decode

         Returns:
           tuple with the formatted string, decoded arguments, and remaining data
         """
         # Insert formatted arguments in place of each format specifier.
         args, remaining = self.decode(encoded_args)

         if show_errors:
             self._segments[1::2] = (arg.format() for arg in args)
         else:
             self._segments[1::2] = (arg.format()
                                     if arg.ok() else arg.specifier.specifier
                                     for arg in args)

         return FormattedString(''.join(self._segments), args, remaining)


 def decode(format_string: str,
            encoded_arguments: bytes,
            show_errors: bool = False) -> str:
     """Decodes arguments and formats them with the provided format string.

     Args:
       format_string: the printf-style format string
       encoded_arguments: encoded arguments with which to format
           format_string; must exclude the 4-byte string token
       show_errors: if True, an error message is used in place of the %
           conversion specifier when an argument fails to decode

     Returns:
       the printf-style formatted string
     """
     return FormatString(format_string).format(encoded_arguments,
                                               show_errors).value
	# Copyright 2020 The Pigweed Authors
	#
	# Licensed under the Apache License, Version 2.0 (the "License"); you may not
	# use this file except in compliance with the License. You may obtain a copy of
	# the License at
	#
	# https://www.apache.org/licenses/LICENSE-2.0
	#
	# Unless required by applicable law or agreed to in writing, software
	# distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
	# WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
	# License for the specific language governing permissions and limitations under
	# the License.
	"""Decodes arguments and formats tokenized messages.

	The decode(format_string, encoded_arguments) function provides a simple way to
	format a string with encoded arguments. The FormatString class may also be used.

	Missing, truncated, or otherwise corrupted arguments are handled and displayed
	in the resulting string with an error message.
	"""

	import re
	import struct
	from typing import Iterable, List, NamedTuple, Match, Sequence, Tuple


	def zigzag_decode(value: int) -> int:
	"""ZigZag decode function from protobuf's wire_format module."""
	if not value & 0x1:
	return value >> 1
	return (value >> 1) ^ (~0)


	class FormatSpec:
	"""Represents a format specifier parsed from a printf-style string."""

	# Regular expression for finding format specifiers.
	FORMAT_SPEC = re.compile(r'%(?:(?P<flags>[+\- #0]\d(?:\.\d+)?)'
	r'(?P<length>hh\|h\|ll\|l\|j\|z\|t\|L)?'
	r'(?P<type>[csdioxXufFeEaAgGnp])\|%)')

	# Conversions to make format strings Python compatible.
	_UNSUPPORTED_LENGTH = frozenset(['hh', 'll', 'j', 'z', 't'])
	_REMAP_TYPE = {'a': 'f', 'A': 'F'}

	# Conversion specifiers by type; n is not supported.
	_SIGNED_INT = 'di'
	_UNSIGNED_INT = frozenset('oxXup')
	_FLOATING_POINT = frozenset('fFeEaAgG')

	_PACKED_FLOAT = struct.Struct('<f')

	@classmethod
	def from_string(cls, format_specifier: str):
	"""Creates a FormatSpec from a str with a single format specifier."""
	match = cls.FORMAT_SPEC.fullmatch(format_specifier)

	if not match:
	raise ValueError(
	'{!r} is not a valid single format specifier'.format(
	format_specifier))

	return cls(match)

	def __init__(self, re_match: Match):
	"""Constructs a FormatSpec from an re.Match object for FORMAT_SPEC."""
	self.match = re_match
	self.specifier: str = self.match.group()

	self.flags: str = self.match.group('flags') or ''
	self.length: str = self.match.group('length') or ''

	# If there is no type, the format spec is %%.
	self.type: str = self.match.group('type') or '%'

	# %p prints as 0xFEEDBEEF; other specs may need length/type switched
	if self.type == 'p':
	self.compatible = '0x%08X'
	else:
	self.compatible = ''.join([
	'%', self.flags,
	'' if self.length in self._UNSUPPORTED_LENGTH else '',
	self._REMAP_TYPE.get(self.type, self.type)
	])

	def decode(self, encoded_arg: bytes) -> 'DecodedArg':
	"""Decodes the provided data according to this format specifier."""
	if self.type == '%': # literal %
	return DecodedArg(self, (),
	b'') # Use () as the value for % formatting.

	if self.type == 's': # string
	return self._decode_string(encoded_arg)

	if self.type == 'c': # character
	return self._decode_char(encoded_arg)

	if self.type in self._SIGNED_INT:
	return self._decode_signed_integer(encoded_arg)

	if self.type in self._UNSIGNED_INT:
	return self._decode_unsigned_integer(encoded_arg)

	if self.type in self._FLOATING_POINT:
	return self._decode_float(encoded_arg)

	# Unsupported specifier (e.g. %n)
	return DecodedArg(
	self, None, b'', DecodedArg.DECODE_ERROR,
	'Unsupported conversion specifier "{}"'.format(self.type))

	def _decode_signed_integer(self, encoded: bytes) -> 'DecodedArg':
	"""Decodes a signed variable-length integer."""
	if not encoded:
	return DecodedArg.missing(self)

	count = 0
	result = 0
	shift = 0

	for byte in encoded:
	count += 1
	result \|= (byte & 0x7f) << shift

	if not byte & 0x80:
	return DecodedArg(self, zigzag_decode(result), encoded[:count])

	shift += 7
	if shift >= 64:
	break

	return DecodedArg(self, None, encoded[:count], DecodedArg.DECODE_ERROR,
	'Unterminated variable-length integer')

	def _decode_unsigned_integer(self, encoded: bytes) -> 'DecodedArg':
	arg = self._decode_signed_integer(encoded)

	# Since ZigZag encoding is used, unsigned integers must be masked off to
	# their original bit length.
	if arg.value is not None:
	arg.value &= (1 << self.size_bits()) - 1

	return arg

	def _decode_float(self, encoded: bytes) -> 'DecodedArg':
	if len(encoded) < 4:
	return DecodedArg.missing(self)

	return DecodedArg(self,
	self._PACKED_FLOAT.unpack_from(encoded)[0],
	encoded[:4])

	def _decode_string(self, encoded: bytes) -> 'DecodedArg':
	"""Reads a unicode string from the encoded data."""
	if not encoded:
	return DecodedArg.missing(self)

	size_and_status = encoded[0]
	status = DecodedArg.OK

	if size_and_status & 0x80:
	status \|= DecodedArg.TRUNCATED
	size_and_status &= 0x7f

	raw_data = encoded[0:size_and_status + 1]
	data = raw_data[1:]

	if len(data) < size_and_status:
	status \|= DecodedArg.DECODE_ERROR

	try:
	decoded = data.decode()
	except UnicodeDecodeError as err:
	return DecodedArg(self,
	repr(bytes(data)).lstrip('b'), raw_data,
	status \| DecodedArg.DECODE_ERROR, err)

	return DecodedArg(self, decoded, raw_data, status)

	def _decode_char(self, encoded: bytes) -> 'DecodedArg':
	"""Reads an integer from the data, then converts it to a string."""
	arg = self._decode_signed_integer(encoded)

	if arg.ok():
	try:
	arg.value = chr(arg.value)
	except (OverflowError, ValueError) as err:
	arg.error = err
	arg.status \|= DecodedArg.DECODE_ERROR

	return arg

	def size_bits(self) -> int:
	"""Size of the argument in bits; 0 for strings."""
	if self.type == 's':
	return 0

	# TODO(hepler): 64-bit targets likely have 64-bit l, j, z, and t.
	return 64 if self.length in ['ll', 'j'] else 32

	def __str__(self) -> str:
	return self.specifier


	class DecodedArg:
	"""Represents a decoded argument that is ready to be formatted."""

	# Status flags for a decoded argument. These values should match the
	# DecodingStatus enum in pw_tokenizer/internal/decode.h.
	OK = 0 # decoding was successful
	MISSING = 1 # the argument was not present in the data
	TRUNCATED = 2 # the argument was truncated during encoding
	DECODE_ERROR = 4 # an error occurred while decoding the argument
	SKIPPED = 8 # argument was skipped due to a previous error

	@classmethod
	def missing(cls, specifier: FormatSpec):
	return cls(specifier, None, b'', cls.MISSING)

	def __init__(self,
	specifier: FormatSpec,
	value,
	raw_data: bytes,
	status: int = OK,
	error=None):
	self.specifier = specifier # FormatSpec (e.g. to represent "%0.2f")
	self.value = value # the decoded value, or None if decoding failed
	self.raw_data = bytes(
	raw_data) # the exact bytes used to decode this arg
	self._status = status
	self.error = error

	def ok(self) -> bool:
	"""The argument was decoded without errors."""
	return self.status == self.OK or self.status == self.TRUNCATED

	@property
	def status(self) -> int:
	return self._status

	@status.setter
	def status(self, status: int):
	# The %% specifier is always OK and should always be printed normally.
	self._status = status if self.specifier.type != '%' else self.OK

	def format(self) -> str:
	"""Returns formatted version of this argument, with error handling."""
	if self.status == self.TRUNCATED:
	return self.specifier.compatible % (self.value + '[...]')

	if self.ok():
	try:
	return self.specifier.compatible % self.value
	except (OverflowError, TypeError, ValueError) as err:
	self.status \|= self.DECODE_ERROR
	self.error = err

	if self.status & self.SKIPPED:
	message = '{} SKIPPED'.format(self.specifier)
	elif self.status == self.MISSING:
	message = '{} MISSING'.format(self.specifier)
	elif self.status & self.DECODE_ERROR:
	message = '{} ERROR'.format(self.specifier)
	else:
	raise AssertionError('Unhandled DecodedArg status {:x}!'.format(
	self.status))

	if self.value is None or not str(self.value):
	return '<[{}]>'.format(message)

	return '<[{} ({})]>'.format(message, self.value)

	def __str__(self) -> str:
	return self.format()

	def __repr__(self) -> str:
	return 'DecodedArg({!r})'.format(self)


	def parse_format_specifiers(format_string: str) -> Iterable[FormatSpec]:
	for spec in FormatSpec.FORMAT_SPEC.finditer(format_string):
	yield FormatSpec(spec)


	class FormattedString(NamedTuple):
	value: str
	args: Sequence[DecodedArg]
	remaining: bytes


	class FormatString:
	"""Represents a printf-style format string."""
	def __init__(self, format_string: str):
	"""Parses format specifiers in the format string."""
	self.format_string = format_string
	self.specifiers = tuple(parse_format_specifiers(self.format_string))

	# List of non-specifier string pieces with room for formatted arguments.
	self._segments = self._parse_string_segments()

	def _parse_string_segments(self) -> List:
	"""Splits the format string by format specifiers."""
	if not self.specifiers:
	return [self.format_string]

	spec_spans = [spec.match.span() for spec in self.specifiers]

	# Start with the part of the format string up to the first specifier.
	string_pieces = [self.format_string[:spec_spans[0][0]]]

	for ((_, end1), (start2, _)) in zip(spec_spans[:-1], spec_spans[1:]):
	string_pieces.append(self.format_string[end1:start2])

	# Append the format string segment after the last format specifier.
	string_pieces.append(self.format_string[spec_spans[-1][1]:])

	# Make a list with spots for the replacements between the string pieces.
	segments: List = [None] * (len(string_pieces) + len(self.specifiers))
	segments[::2] = string_pieces

	return segments

	def decode(self, encoded: bytes) -> Tuple[Sequence[DecodedArg], bytes]:
	"""Decodes arguments according to the format string.

	Args:
	encoded: bytes; the encoded arguments

	Returns:
	tuple with the decoded arguments and any unparsed data
	"""
	decoded_args = []

	fatal_error = False
	index = 0

	for spec in self.specifiers:
	arg = spec.decode(encoded[index:])

	if fatal_error:
	# After an error is encountered, continue to attempt to parse
	# arguments, but mark them all as SKIPPED. If an error occurs,
	# it's impossible to know if subsequent arguments are valid.
	arg.status \|= DecodedArg.SKIPPED
	elif not arg.ok():
	fatal_error = True

	decoded_args.append(arg)
	index += len(arg.raw_data)

	return tuple(decoded_args), encoded[index:]

	def format(self,
	encoded_args: bytes,
	show_errors: bool = False) -> FormattedString:
	"""Decodes arguments and formats the string with them.

	Args:
	encoded_args: the arguments to decode and format the string with
	show_errors: if True, an error message is used in place of the %
	conversion specifier when an argument fails to decode

	Returns:
	tuple with the formatted string, decoded arguments, and remaining data
	"""
	# Insert formatted arguments in place of each format specifier.
	args, remaining = self.decode(encoded_args)

	if show_errors:
	self._segments[1::2] = (arg.format() for arg in args)
	else:
	self._segments[1::2] = (arg.format()
	if arg.ok() else arg.specifier.specifier
	for arg in args)

	return FormattedString(''.join(self._segments), args, remaining)


	def decode(format_string: str,
	encoded_arguments: bytes,
	show_errors: bool = False) -> str:
	"""Decodes arguments and formats them with the provided format string.

	Args:
	format_string: the printf-style format string
	encoded_arguments: encoded arguments with which to format
	format_string; must exclude the 4-byte string token
	show_errors: if True, an error message is used in place of the %
	conversion specifier when an argument fails to decode

	Returns:
	the printf-style formatted string
	"""
	return FormatString(format_string).format(encoded_arguments,
	show_errors).value