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"""General purpose composite argument parsing and completion.""" from __future__ import annotations import abc import collections.abc as c import contextlib import dataclasses import enum import os import re import typing as t # NOTE: When choosing delimiters, take into account Bash and argcomplete behavior. # # Recommended characters for assignment and/or continuation: `/` `:` `=` # # The recommended assignment_character list is due to how argcomplete handles continuation characters. # see: https://github.com/kislyuk/argcomplete/blob/5a20d6165fbb4d4d58559378919b05964870cc16/argcomplete/__init__.py#L557-L558 PAIR_DELIMITER = ',' ASSIGNMENT_DELIMITER = '=' PATH_DELIMITER = '/' # This class was originally frozen. However, that causes issues when running under Python 3.11. # See: https://github.com/python/cpython/issues/99856 @dataclasses.dataclass class Completion(Exception): """Base class for argument completion results.""" @dataclasses.dataclass class CompletionUnavailable(Completion): """Argument completion unavailable.""" message: str = 'No completions available.' @dataclasses.dataclass class CompletionError(Completion): """Argument completion error.""" message: t.Optional[str] = None @dataclasses.dataclass class CompletionSuccess(Completion): """Successful argument completion result.""" list_mode: bool consumed: str continuation: str matches: list[str] = dataclasses.field(default_factory=list) @property def preserve(self) -> bool: """ True if argcomplete should not mangle completion values, otherwise False. Only used when more than one completion exists to avoid overwriting the word undergoing completion. """ return len(self.matches) > 1 and self.list_mode @property def completions(self) -> list[str]: """List of completion values to return to argcomplete.""" completions = self.matches continuation = '' if self.list_mode else self.continuation if not self.preserve: # include the existing prefix to avoid rewriting the word undergoing completion completions = [f'{self.consumed}{completion}{continuation}' for completion in completions] return completions class ParserMode(enum.Enum): """Mode the parser is operating in.""" PARSE = enum.auto() COMPLETE = enum.auto() LIST = enum.auto() class ParserError(Exception): """Base class for all parsing exceptions.""" @dataclasses.dataclass class ParserBoundary: """Boundary details for parsing composite input.""" delimiters: str required: bool match: t.Optional[str] = None ready: bool = True @dataclasses.dataclass class ParserState: """State of the composite argument parser.""" mode: ParserMode remainder: str = '' consumed: str = '' boundaries: list[ParserBoundary] = dataclasses.field(default_factory=list) namespaces: list[t.Any] = dataclasses.field(default_factory=list) parts: list[str] = dataclasses.field(default_factory=list) @property def incomplete(self) -> bool: """True if parsing is incomplete (unparsed input remains), otherwise False.""" return self.remainder is not None def match(self, value: str, choices: list[str]) -> bool: """Return True if the given value matches the provided choices, taking into account parsing boundaries, otherwise return False.""" if self.current_boundary: delimiters, delimiter = self.current_boundary.delimiters, self.current_boundary.match else: delimiters, delimiter = '', None for choice in choices: if choice.rstrip(delimiters) == choice: # choice is not delimited if value == choice: return True # value matched else: # choice is delimited if f'{value}{delimiter}' == choice: return True # value and delimiter matched return False def read(self) -> str: """Read and return the next input segment, taking into account parsing boundaries.""" delimiters = "".join(boundary.delimiters for boundary in self.boundaries) if delimiters: pattern = '([' + re.escape(delimiters) + '])' regex = re.compile(pattern) parts = regex.split(self.remainder, 1) else: parts = [self.remainder] if len(parts) > 1: value, delimiter, remainder = parts else: value, delimiter, remainder = parts[0], None, None for boundary in reversed(self.boundaries): if delimiter and delimiter in boundary.delimiters: boundary.match = delimiter self.consumed += value + delimiter break boundary.match = None boundary.ready = False if boundary.required: break self.remainder = remainder return value @property def root_namespace(self) -> t.Any: """THe root namespace.""" return self.namespaces[0] @property def current_namespace(self) -> t.Any: """The current namespace.""" return self.namespaces[-1] @property def current_boundary(self) -> t.Optional[ParserBoundary]: """The current parser boundary, if any, otherwise None.""" return self.boundaries[-1] if self.boundaries else None def set_namespace(self, namespace: t.Any) -> None: """Set the current namespace.""" self.namespaces.append(namespace) @contextlib.contextmanager def delimit(self, delimiters: str, required: bool = True) -> c.Iterator[ParserBoundary]: """Context manager for delimiting parsing of input.""" boundary = ParserBoundary(delimiters=delimiters, required=required) self.boundaries.append(boundary) try: yield boundary finally: self.boundaries.pop() if boundary.required and not boundary.match: raise ParserError('required delimiter not found, hit up-level delimiter or end of input instead') @dataclasses.dataclass class DocumentationState: """State of the composite argument parser's generated documentation.""" sections: dict[str, str] = dataclasses.field(default_factory=dict) class Parser(metaclass=abc.ABCMeta): """Base class for all composite argument parsers.""" @abc.abstractmethod def parse(self, state: ParserState) -> t.Any: """Parse the input from the given state and return the result.""" def document(self, state: DocumentationState) -> t.Optional[str]: """Generate and return documentation for this parser.""" raise Exception(f'Undocumented parser: {type(self)}') class MatchConditions(enum.Flag): """Acceptable condition(s) for matching user input to available choices.""" CHOICE = enum.auto() """Match any choice.""" ANY = enum.auto() """Match any non-empty string.""" NOTHING = enum.auto() """Match an empty string which is not followed by a boundary match.""" class DynamicChoicesParser(Parser, metaclass=abc.ABCMeta): """Base class for composite argument parsers which use a list of choices that can be generated during completion.""" def __init__(self, conditions: MatchConditions = MatchConditions.CHOICE) -> None: self.conditions = conditions @abc.abstractmethod def get_choices(self, value: str) -> list[str]: """Return a list of valid choices based on the given input value.""" def no_completion_match(self, value: str) -> CompletionUnavailable: # pylint: disable=unused-argument """Return an instance of CompletionUnavailable when no match was found for the given value.""" return CompletionUnavailable() def no_choices_available(self, value: str) -> ParserError: # pylint: disable=unused-argument """Return an instance of ParserError when parsing fails and no choices are available.""" return ParserError('No choices available.') def parse(self, state: ParserState) -> t.Any: """Parse the input from the given state and return the result.""" value = state.read() choices = self.get_choices(value) if state.mode == ParserMode.PARSE or state.incomplete: if self.conditions & MatchConditions.CHOICE and state.match(value, choices): return value if self.conditions & MatchConditions.ANY and value: return value if self.conditions & MatchConditions.NOTHING and not value and state.current_boundary and not state.current_boundary.match: return value if state.mode == ParserMode.PARSE: if choices: raise ParserError(f'"{value}" not in: {", ".join(choices)}') raise self.no_choices_available(value) raise CompletionUnavailable() matches = [choice for choice in choices if choice.startswith(value)] if not matches: raise self.no_completion_match(value) continuation = state.current_boundary.delimiters if state.current_boundary and state.current_boundary.required else '' raise CompletionSuccess( list_mode=state.mode == ParserMode.LIST, consumed=state.consumed, continuation=continuation, matches=matches, ) class ChoicesParser(DynamicChoicesParser): """Composite argument parser which relies on a static list of choices.""" def __init__(self, choices: list[str], conditions: MatchConditions = MatchConditions.CHOICE) -> None: self.choices = choices super().__init__(conditions=conditions) def get_choices(self, value: str) -> list[str]: """Return a list of valid choices based on the given input value.""" return self.choices def document(self, state: DocumentationState) -> t.Optional[str]: """Generate and return documentation for this parser.""" return '|'.join(self.choices) class EnumValueChoicesParser(ChoicesParser): """Composite argument parser which relies on a static list of choices derived from the values of an enum.""" def __init__(self, enum_type: t.Type[enum.Enum], conditions: MatchConditions = MatchConditions.CHOICE) -> None: self.enum_type = enum_type super().__init__(choices=[str(item.value) for item in enum_type], conditions=conditions) def parse(self, state: ParserState) -> t.Any: """Parse the input from the given state and return the result.""" value = super().parse(state) return self.enum_type(value) class IntegerParser(DynamicChoicesParser): """Composite argument parser for integers.""" PATTERN = re.compile('^[1-9][0-9]*$') def __init__(self, maximum: t.Optional[int] = None) -> None: self.maximum = maximum super().__init__() def get_choices(self, value: str) -> list[str]: """Return a list of valid choices based on the given input value.""" if not value: numbers = list(range(1, 10)) elif self.PATTERN.search(value): int_prefix = int(value) base = int_prefix * 10 numbers = [int_prefix] + [base + i for i in range(0, 10)] else: numbers = [] # NOTE: the minimum is currently fixed at 1 if self.maximum is not None: numbers = [n for n in numbers if n <= self.maximum] return [str(n) for n in numbers] def parse(self, state: ParserState) -> t.Any: """Parse the input from the given state and return the result.""" value = super().parse(state) return int(value) def document(self, state: DocumentationState) -> t.Optional[str]: """Generate and return documentation for this parser.""" return '{integer}' class BooleanParser(ChoicesParser): """Composite argument parser for boolean (yes/no) values.""" def __init__(self) -> None: super().__init__(['yes', 'no']) def parse(self, state: ParserState) -> bool: """Parse the input from the given state and return the result.""" value = super().parse(state) return value == 'yes' class AnyParser(ChoicesParser): """Composite argument parser which accepts any input value.""" def __init__(self, nothing: bool = False, no_match_message: t.Optional[str] = None) -> None: self.no_match_message = no_match_message conditions = MatchConditions.ANY if nothing: conditions |= MatchConditions.NOTHING super().__init__([], conditions=conditions) def no_completion_match(self, value: str) -> CompletionUnavailable: """Return an instance of CompletionUnavailable when no match was found for the given value.""" if self.no_match_message: return CompletionUnavailable(message=self.no_match_message) return super().no_completion_match(value) def no_choices_available(self, value: str) -> ParserError: """Return an instance of ParserError when parsing fails and no choices are available.""" if self.no_match_message: return ParserError(self.no_match_message) return super().no_choices_available(value) class RelativePathNameParser(DynamicChoicesParser): """Composite argument parser for relative path names.""" RELATIVE_NAMES = ['.', '..'] def __init__(self, choices: list[str]) -> None: self.choices = choices super().__init__() def get_choices(self, value: str) -> list[str]: """Return a list of valid choices based on the given input value.""" choices = list(self.choices) if value in self.RELATIVE_NAMES: # complete relative names, but avoid suggesting them unless the current name is relative # unfortunately this will be sorted in reverse of what bash presents ("../ ./" instead of "./ ../") choices.extend(f'{item}{PATH_DELIMITER}' for item in self.RELATIVE_NAMES) return choices class FileParser(Parser): """Composite argument parser for absolute or relative file paths.""" def parse(self, state: ParserState) -> str: """Parse the input from the given state and return the result.""" if state.mode == ParserMode.PARSE: path = AnyParser().parse(state) if not os.path.isfile(path): raise ParserError(f'Not a file: {path}') else: path = '' with state.delimit(PATH_DELIMITER, required=False) as boundary: # type: ParserBoundary while boundary.ready: directory = path or '.' try: with os.scandir(directory) as scan: # type: c.Iterator[os.DirEntry] choices = [f'{item.name}{PATH_DELIMITER}' if item.is_dir() else item.name for item in scan] except OSError: choices = [] if not path: choices.append(PATH_DELIMITER) # allow absolute paths choices.append('../') # suggest relative paths part = RelativePathNameParser(choices).parse(state) path += f'{part}{boundary.match or ""}' return path class AbsolutePathParser(Parser): """Composite argument parser for absolute file paths. Paths are only verified for proper syntax, not for existence.""" def parse(self, state: ParserState) -> t.Any: """Parse the input from the given state and return the result.""" path = '' with state.delimit(PATH_DELIMITER, required=False) as boundary: # type: ParserBoundary while boundary.ready: if path: path += AnyParser(nothing=True).parse(state) else: path += ChoicesParser([PATH_DELIMITER]).parse(state) path += boundary.match or '' return path class NamespaceParser(Parser, metaclass=abc.ABCMeta): """Base class for composite argument parsers that store their results in a namespace.""" def parse(self, state: ParserState) -> t.Any: """Parse the input from the given state and return the result.""" namespace = state.current_namespace current = getattr(namespace, self.dest) if current and self.limit_one: if state.mode == ParserMode.PARSE: raise ParserError('Option cannot be specified more than once.') raise CompletionError('Option cannot be specified more than once.') value = self.get_value(state) if self.use_list: if not current: current = [] setattr(namespace, self.dest, current) current.append(value) else: setattr(namespace, self.dest, value) return value def get_value(self, state: ParserState) -> t.Any: """Parse the input from the given state and return the result, without storing the result in the namespace.""" return super().parse(state) @property def use_list(self) -> bool: """True if the destination is a list, otherwise False.""" return False @property def limit_one(self) -> bool: """True if only one target is allowed, otherwise False.""" return not self.use_list @property @abc.abstractmethod def dest(self) -> str: """The name of the attribute where the value should be stored.""" class NamespaceWrappedParser(NamespaceParser): """Composite argument parser that wraps a non-namespace parser and stores the result in a namespace.""" def __init__(self, dest: str, parser: Parser) -> None: self._dest = dest self.parser = parser def get_value(self, state: ParserState) -> t.Any: """Parse the input from the given state and return the result, without storing the result in the namespace.""" return self.parser.parse(state) @property def dest(self) -> str: """The name of the attribute where the value should be stored.""" return self._dest class KeyValueParser(Parser, metaclass=abc.ABCMeta): """Base class for key/value composite argument parsers.""" @abc.abstractmethod def get_parsers(self, state: ParserState) -> dict[str, Parser]: """Return a dictionary of key names and value parsers.""" def parse(self, state: ParserState) -> t.Any: """Parse the input from the given state and return the result.""" namespace = state.current_namespace parsers = self.get_parsers(state) keys = list(parsers) with state.delimit(PAIR_DELIMITER, required=False) as pair: # type: ParserBoundary while pair.ready: with state.delimit(ASSIGNMENT_DELIMITER): key = ChoicesParser(keys).parse(state) value = parsers[key].parse(state) setattr(namespace, key, value) keys.remove(key) return namespace class PairParser(Parser, metaclass=abc.ABCMeta): """Base class for composite argument parsers consisting of a left and right argument parser, with input separated by a delimiter.""" def parse(self, state: ParserState) -> t.Any: """Parse the input from the given state and return the result.""" namespace = self.create_namespace() state.set_namespace(namespace) with state.delimit(self.delimiter, self.required) as boundary: # type: ParserBoundary choice = self.get_left_parser(state).parse(state) if boundary.match: self.get_right_parser(choice).parse(state) return namespace @property def required(self) -> bool: """True if the delimiter (and thus right parser) is required, otherwise False.""" return False @property def delimiter(self) -> str: """The delimiter to use between the left and right parser.""" return PAIR_DELIMITER @abc.abstractmethod def create_namespace(self) -> t.Any: """Create and return a namespace.""" @abc.abstractmethod def get_left_parser(self, state: ParserState) -> Parser: """Return the parser for the left side.""" @abc.abstractmethod def get_right_parser(self, choice: t.Any) -> Parser: """Return the parser for the right side.""" class TypeParser(Parser, metaclass=abc.ABCMeta): """Base class for composite argument parsers which parse a type name, a colon and then parse results based on the type given by the type name.""" def get_parsers(self, state: ParserState) -> dict[str, Parser]: # pylint: disable=unused-argument """Return a dictionary of type names and type parsers.""" return self.get_stateless_parsers() @abc.abstractmethod def get_stateless_parsers(self) -> dict[str, Parser]: """Return a dictionary of type names and type parsers.""" def parse(self, state: ParserState) -> t.Any: """Parse the input from the given state and return the result.""" parsers = self.get_parsers(state) with state.delimit(':'): key = ChoicesParser(list(parsers)).parse(state) value = parsers[key].parse(state) return value