# -*- coding: utf-8 -*- import codecs import warnings import re from contextlib import contextmanager from parso.normalizer import Normalizer, NormalizerConfig, Issue, Rule from parso.python.tree import search_ancestor from parso.parser import ParserSyntaxError _BLOCK_STMTS = ('if_stmt', 'while_stmt', 'for_stmt', 'try_stmt', 'with_stmt') _STAR_EXPR_PARENTS = ('testlist_star_expr', 'testlist_comp', 'exprlist') # This is the maximal block size given by python. _MAX_BLOCK_SIZE = 20 _MAX_INDENT_COUNT = 100 ALLOWED_FUTURES = ( 'all_feature_names', 'nested_scopes', 'generators', 'division', 'absolute_import', 'with_statement', 'print_function', 'unicode_literals', ) def _iter_stmts(scope): """ Iterates over all statements and splits up simple_stmt. """ for child in scope.children: if child.type == 'simple_stmt': for child2 in child.children: if child2.type == 'newline' or child2 == ';': continue yield child2 else: yield child def _get_comprehension_type(atom): first, second = atom.children[:2] if second.type == 'testlist_comp' and second.children[1].type == 'comp_for': if first == '[': return 'list comprehension' else: return 'generator expression' elif second.type == 'dictorsetmaker' and second.children[-1].type == 'comp_for': if second.children[1] == ':': return 'dict comprehension' else: return 'set comprehension' return None def _is_future_import(import_from): # It looks like a __future__ import that is relative is still a future # import. That feels kind of odd, but whatever. # if import_from.level != 0: # return False from_names = import_from.get_from_names() return [n.value for n in from_names] == ['__future__'] def _remove_parens(atom): """ Returns the inner part of an expression like `(foo)`. Also removes nested parens. """ try: children = atom.children except AttributeError: pass else: if len(children) == 3 and children[0] == '(': return _remove_parens(atom.children[1]) return atom def _iter_params(parent_node): return (n for n in parent_node.children if n.type == 'param') def _is_future_import_first(import_from): """ Checks if the import is the first statement of a file. """ found_docstring = False for stmt in _iter_stmts(import_from.get_root_node()): if stmt.type == 'string' and not found_docstring: continue found_docstring = True if stmt == import_from: return True if stmt.type == 'import_from' and _is_future_import(stmt): continue return False def _iter_definition_exprs_from_lists(exprlist): for child in exprlist.children[::2]: if child.type == 'atom' and child.children[0] in ('(', '['): testlist_comp = child.children[0] if testlist_comp.type == 'testlist_comp': for expr in _iter_definition_exprs_from_lists(testlist_comp): yield expr continue elif child.children[0] == '[': yield testlist_comp continue yield child def _get_expr_stmt_definition_exprs(expr_stmt): exprs = [] for list_ in expr_stmt.children[:-2:2]: if list_.type in ('testlist_star_expr', 'testlist'): exprs += _iter_definition_exprs_from_lists(list_) else: exprs.append(list_) return exprs def _get_for_stmt_definition_exprs(for_stmt): exprlist = for_stmt.children[1] if exprlist.type != 'exprlist': return [exprlist] return list(_iter_definition_exprs_from_lists(exprlist)) class _Context(object): def __init__(self, node, add_syntax_error, parent_context=None): self.node = node self.blocks = [] self.parent_context = parent_context self._used_name_dict = {} self._global_names = [] self._nonlocal_names = [] self._nonlocal_names_in_subscopes = [] self._add_syntax_error = add_syntax_error def is_async_funcdef(self): # Stupidly enough async funcdefs can have two different forms, # depending if a decorator is used or not. return self.is_function() \ and self.node.parent.type in ('async_funcdef', 'async_stmt') def is_function(self): return self.node.type == 'funcdef' def add_name(self, name): parent_type = name.parent.type if parent_type == 'trailer': # We are only interested in first level names. return if parent_type == 'global_stmt': self._global_names.append(name) elif parent_type == 'nonlocal_stmt': self._nonlocal_names.append(name) else: self._used_name_dict.setdefault(name.value, []).append(name) def finalize(self): """ Returns a list of nonlocal names that need to be part of that scope. """ self._analyze_names(self._global_names, 'global') self._analyze_names(self._nonlocal_names, 'nonlocal') # Python2.6 doesn't have dict comprehensions. global_name_strs = dict((n.value, n) for n in self._global_names) for nonlocal_name in self._nonlocal_names: try: global_name = global_name_strs[nonlocal_name.value] except KeyError: continue message = "name '%s' is nonlocal and global" % global_name.value if global_name.start_pos < nonlocal_name.start_pos: error_name = global_name else: error_name = nonlocal_name self._add_syntax_error(error_name, message) nonlocals_not_handled = [] for nonlocal_name in self._nonlocal_names_in_subscopes: search = nonlocal_name.value if search in global_name_strs or self.parent_context is None: message = "no binding for nonlocal '%s' found" % nonlocal_name.value self._add_syntax_error(nonlocal_name, message) elif not self.is_function() or \ nonlocal_name.value not in self._used_name_dict: nonlocals_not_handled.append(nonlocal_name) return self._nonlocal_names + nonlocals_not_handled def _analyze_names(self, globals_or_nonlocals, type_): def raise_(message): self._add_syntax_error(base_name, message % (base_name.value, type_)) params = [] if self.node.type == 'funcdef': params = self.node.get_params() for base_name in globals_or_nonlocals: found_global_or_nonlocal = False # Somehow Python does it the reversed way. for name in reversed(self._used_name_dict.get(base_name.value, [])): if name.start_pos > base_name.start_pos: # All following names don't have to be checked. found_global_or_nonlocal = True parent = name.parent if parent.type == 'param' and parent.name == name: # Skip those here, these definitions belong to the next # scope. continue if name.is_definition(): if parent.type == 'expr_stmt' \ and parent.children[1].type == 'annassign': if found_global_or_nonlocal: # If it's after the global the error seems to be # placed there. base_name = name raise_("annotated name '%s' can't be %s") break else: message = "name '%s' is assigned to before %s declaration" else: message = "name '%s' is used prior to %s declaration" if not found_global_or_nonlocal: raise_(message) # Only add an error for the first occurence. break for param in params: if param.name.value == base_name.value: raise_("name '%s' is parameter and %s"), @contextmanager def add_block(self, node): self.blocks.append(node) yield self.blocks.pop() def add_context(self, node): return _Context(node, self._add_syntax_error, parent_context=self) def close_child_context(self, child_context): self._nonlocal_names_in_subscopes += child_context.finalize() class ErrorFinder(Normalizer): """ Searches for errors in the syntax tree. """ def __init__(self, *args, **kwargs): super(ErrorFinder, self).__init__(*args, **kwargs) self._error_dict = {} self.version = self.grammar.version_info def initialize(self, node): def create_context(node): if node is None: return None parent_context = create_context(node.parent) if node.type in ('classdef', 'funcdef', 'file_input'): return _Context(node, self._add_syntax_error, parent_context) return parent_context self.context = create_context(node) or _Context(node, self._add_syntax_error) self._indentation_count = 0 def visit(self, node): if node.type == 'error_node': with self.visit_node(node): # Don't need to investigate the inners of an error node. We # might find errors in there that should be ignored, because # the error node itself already shows that there's an issue. return '' return super(ErrorFinder, self).visit(node) @contextmanager def visit_node(self, node): self._check_type_rules(node) if node.type in _BLOCK_STMTS: with self.context.add_block(node): if len(self.context.blocks) == _MAX_BLOCK_SIZE: self._add_syntax_error(node, "too many statically nested blocks") yield return elif node.type == 'suite': self._indentation_count += 1 if self._indentation_count == _MAX_INDENT_COUNT: self._add_indentation_error(node.children[1], "too many levels of indentation") yield if node.type == 'suite': self._indentation_count -= 1 elif node.type in ('classdef', 'funcdef'): context = self.context self.context = context.parent_context self.context.close_child_context(context) def visit_leaf(self, leaf): if leaf.type == 'error_leaf': if leaf.token_type in ('INDENT', 'ERROR_DEDENT'): # Indents/Dedents itself never have a prefix. They are just # "pseudo" tokens that get removed by the syntax tree later. # Therefore in case of an error we also have to check for this. spacing = list(leaf.get_next_leaf()._split_prefix())[-1] if leaf.token_type == 'INDENT': message = 'unexpected indent' else: message = 'unindent does not match any outer indentation level' self._add_indentation_error(spacing, message) else: if leaf.value.startswith('\\'): message = 'unexpected character after line continuation character' else: match = re.match('\\w{,2}("{1,3}|\'{1,3})', leaf.value) if match is None: message = 'invalid syntax' else: if len(match.group(1)) == 1: message = 'EOL while scanning string literal' else: message = 'EOF while scanning triple-quoted string literal' self._add_syntax_error(leaf, message) return '' elif leaf.value == ':': parent = leaf.parent if parent.type in ('classdef', 'funcdef'): self.context = self.context.add_context(parent) # The rest is rule based. return super(ErrorFinder, self).visit_leaf(leaf) def _add_indentation_error(self, spacing, message): self.add_issue(spacing, 903, "IndentationError: " + message) def _add_syntax_error(self, node, message): self.add_issue(node, 901, "SyntaxError: " + message) def add_issue(self, node, code, message): # Overwrite the default behavior. # Check if the issues are on the same line. line = node.start_pos[0] args = (code, message, node) self._error_dict.setdefault(line, args) def finalize(self): self.context.finalize() for code, message, node in self._error_dict.values(): self.issues.append(Issue(node, code, message)) class IndentationRule(Rule): code = 903 def _get_message(self, message): message = super(IndentationRule, self)._get_message(message) return "IndentationError: " + message @ErrorFinder.register_rule(type='error_node') class _ExpectIndentedBlock(IndentationRule): message = 'expected an indented block' def get_node(self, node): leaf = node.get_next_leaf() return list(leaf._split_prefix())[-1] def is_issue(self, node): # This is the beginning of a suite that is not indented. return node.children[-1].type == 'newline' class ErrorFinderConfig(NormalizerConfig): normalizer_class = ErrorFinder class SyntaxRule(Rule): code = 901 def _get_message(self, message): message = super(SyntaxRule, self)._get_message(message) return "SyntaxError: " + message @ErrorFinder.register_rule(type='error_node') class _InvalidSyntaxRule(SyntaxRule): message = "invalid syntax" def get_node(self, node): return node.get_next_leaf() def is_issue(self, node): # Error leafs will be added later as an error. return node.get_next_leaf().type != 'error_leaf' @ErrorFinder.register_rule(value='await') class _AwaitOutsideAsync(SyntaxRule): message = "'await' outside async function" def is_issue(self, leaf): return not self._normalizer.context.is_async_funcdef() def get_error_node(self, node): # Return the whole await statement. return node.parent @ErrorFinder.register_rule(value='break') class _BreakOutsideLoop(SyntaxRule): message = "'break' outside loop" def is_issue(self, leaf): in_loop = False for block in self._normalizer.context.blocks: if block.type in ('for_stmt', 'while_stmt'): in_loop = True return not in_loop @ErrorFinder.register_rule(value='continue') class _ContinueChecks(SyntaxRule): message = "'continue' not properly in loop" message_in_finally = "'continue' not supported inside 'finally' clause" def is_issue(self, leaf): in_loop = False for block in self._normalizer.context.blocks: if block.type in ('for_stmt', 'while_stmt'): in_loop = True if block.type == 'try_stmt': last_block = block.children[-3] if last_block == 'finally' and leaf.start_pos > last_block.start_pos: self.add_issue(leaf, message=self.message_in_finally) return False # Error already added if not in_loop: return True @ErrorFinder.register_rule(value='from') class _YieldFromCheck(SyntaxRule): message = "'yield from' inside async function" def get_node(self, leaf): return leaf.parent.parent # This is the actual yield statement. def is_issue(self, leaf): return leaf.parent.type == 'yield_arg' \ and self._normalizer.context.is_async_funcdef() @ErrorFinder.register_rule(type='name') class _NameChecks(SyntaxRule): message = 'cannot assign to __debug__' message_keyword = 'assignment to keyword' message_none = 'cannot assign to None' def is_issue(self, leaf): self._normalizer.context.add_name(leaf) if leaf.value == '__debug__' and leaf.is_definition(): if self._normalizer.version < (3, 0): return True else: self.add_issue(leaf, message=self.message_keyword) if leaf.value == 'None' and self._normalizer.version < (3, 0) \ and leaf.is_definition(): self.add_issue(leaf, message=self.message_none) @ErrorFinder.register_rule(type='string') class _StringChecks(SyntaxRule): message = "bytes can only contain ASCII literal characters." def is_issue(self, leaf): string_prefix = leaf.string_prefix.lower() if 'b' in string_prefix \ and self._normalizer.version >= (3, 0) \ and any(c for c in leaf.value if ord(c) > 127): # b'รค' return True if 'r' not in string_prefix: # Raw strings don't need to be checked if they have proper # escaping. is_bytes = self._normalizer.version < (3, 0) if 'b' in string_prefix: is_bytes = True if 'u' in string_prefix: is_bytes = False payload = leaf._get_payload() if is_bytes: payload = payload.encode('utf-8') func = codecs.escape_decode else: func = codecs.unicode_escape_decode try: with warnings.catch_warnings(): # The warnings from parsing strings are not relevant. warnings.filterwarnings('ignore') func(payload) except UnicodeDecodeError as e: self.add_issue(leaf, message='(unicode error) ' + str(e)) except ValueError as e: self.add_issue(leaf, message='(value error) ' + str(e)) @ErrorFinder.register_rule(value='*') class _StarCheck(SyntaxRule): message = "named arguments must follow bare *" def is_issue(self, leaf): params = leaf.parent if params.type == 'parameters' and params: after = params.children[params.children.index(leaf) + 1:] after = [child for child in after if child not in (',', ')') and not child.star_count] return len(after) == 0 @ErrorFinder.register_rule(value='**') class _StarStarCheck(SyntaxRule): # e.g. {**{} for a in [1]} # TODO this should probably get a better end_pos including # the next sibling of leaf. message = "dict unpacking cannot be used in dict comprehension" def is_issue(self, leaf): if leaf.parent.type == 'dictorsetmaker': comp_for = leaf.get_next_sibling().get_next_sibling() return comp_for is not None and comp_for.type == 'comp_for' @ErrorFinder.register_rule(value='yield') @ErrorFinder.register_rule(value='return') class _ReturnAndYieldChecks(SyntaxRule): message = "'return' with value in async generator" message_async_yield = "'yield' inside async function" def get_node(self, leaf): return leaf.parent def is_issue(self, leaf): if self._normalizer.context.node.type != 'funcdef': self.add_issue(self.get_node(leaf), message="'%s' outside function" % leaf.value) elif self._normalizer.context.is_async_funcdef() \ and any(self._normalizer.context.node.iter_yield_exprs()): if leaf.value == 'return' and leaf.parent.type == 'return_stmt': return True elif leaf.value == 'yield' \ and leaf.get_next_leaf() != 'from' \ and self._normalizer.version == (3, 5): self.add_issue(self.get_node(leaf), message=self.message_async_yield) @ErrorFinder.register_rule(type='strings') class _BytesAndStringMix(SyntaxRule): # e.g. 's' b'' message = "cannot mix bytes and nonbytes literals" def _is_bytes_literal(self, string): if string.type == 'fstring': return False return 'b' in string.string_prefix.lower() def is_issue(self, node): first = node.children[0] # In Python 2 it's allowed to mix bytes and unicode. if self._normalizer.version >= (3, 0): first_is_bytes = self._is_bytes_literal(first) for string in node.children[1:]: if first_is_bytes != self._is_bytes_literal(string): return True @ErrorFinder.register_rule(type='import_as_names') class _TrailingImportComma(SyntaxRule): # e.g. from foo import a, message = "trailing comma not allowed without surrounding parentheses" def is_issue(self, node): if node.children[-1] == ',': return True @ErrorFinder.register_rule(type='import_from') class _ImportStarInFunction(SyntaxRule): message = "import * only allowed at module level" def is_issue(self, node): return node.is_star_import() and self._normalizer.context.parent_context is not None @ErrorFinder.register_rule(type='import_from') class _FutureImportRule(SyntaxRule): message = "from __future__ imports must occur at the beginning of the file" def is_issue(self, node): if _is_future_import(node): if not _is_future_import_first(node): return True for from_name, future_name in node.get_paths(): name = future_name.value allowed_futures = list(ALLOWED_FUTURES) if self._normalizer.version >= (3, 5): allowed_futures.append('generator_stop') if name == 'braces': self.add_issue(node, message = "not a chance") elif name == 'barry_as_FLUFL': m = "Seriously I'm not implementing this :) ~ Dave" self.add_issue(node, message=m) elif name not in ALLOWED_FUTURES: message = "future feature %s is not defined" % name self.add_issue(node, message=message) @ErrorFinder.register_rule(type='star_expr') class _StarExprRule(SyntaxRule): message = "starred assignment target must be in a list or tuple" message_iterable_unpacking = "iterable unpacking cannot be used in comprehension" message_assignment = "can use starred expression only as assignment target" def is_issue(self, node): if node.parent.type not in _STAR_EXPR_PARENTS: return True if node.parent.type == 'testlist_comp': # [*[] for a in [1]] if node.parent.children[1].type == 'comp_for': self.add_issue(node, message=self.message_iterable_unpacking) if self._normalizer.version <= (3, 4): n = search_ancestor(node, 'for_stmt', 'expr_stmt') found_definition = False if n is not None: if n.type == 'expr_stmt': exprs = _get_expr_stmt_definition_exprs(n) else: exprs = _get_for_stmt_definition_exprs(n) if node in exprs: found_definition = True if not found_definition: self.add_issue(node, message=self.message_assignment) @ErrorFinder.register_rule(types=_STAR_EXPR_PARENTS) class _StarExprParentRule(SyntaxRule): def is_issue(self, node): if node.parent.type == 'del_stmt': self.add_issue(node.parent, message="can't use starred expression here") else: def is_definition(node, ancestor): if ancestor is None: return False type_ = ancestor.type if type_ == 'trailer': return False if type_ == 'expr_stmt': return node.start_pos < ancestor.children[-1].start_pos return is_definition(node, ancestor.parent) if is_definition(node, node.parent): args = [c for c in node.children if c != ','] starred = [c for c in args if c.type == 'star_expr'] if len(starred) > 1: message = "two starred expressions in assignment" self.add_issue(starred[1], message=message) elif starred: count = args.index(starred[0]) if count >= 256: message = "too many expressions in star-unpacking assignment" self.add_issue(starred[0], message=message) @ErrorFinder.register_rule(type='annassign') class _AnnotatorRule(SyntaxRule): # True: int # {}: float message = "illegal target for annotation" def get_node(self, node): return node.parent def is_issue(self, node): type_ = None lhs = node.parent.children[0] lhs = _remove_parens(lhs) try: children = lhs.children except AttributeError: pass else: if ',' in children or lhs.type == 'atom' and children[0] == '(': type_ = 'tuple' elif lhs.type == 'atom' and children[0] == '[': type_ = 'list' trailer = children[-1] if type_ is None: if not (lhs.type == 'name' # subscript/attributes are allowed or lhs.type in ('atom_expr', 'power') and trailer.type == 'trailer' and trailer.children[0] != '('): return True else: # x, y: str message = "only single target (not %s) can be annotated" self.add_issue(lhs.parent, message=message % type_) @ErrorFinder.register_rule(type='argument') class _ArgumentRule(SyntaxRule): def is_issue(self, node): first = node.children[0] if node.children[1] == '=' and first.type != 'name': if first.type == 'lambdef': # f(lambda: 1=1) message = "lambda cannot contain assignment" else: # f(+x=1) message = "keyword can't be an expression" self.add_issue(first, message=message) @ErrorFinder.register_rule(type='nonlocal_stmt') class _NonlocalModuleLevelRule(SyntaxRule): message = "nonlocal declaration not allowed at module level" def is_issue(self, node): return self._normalizer.context.parent_context is None @ErrorFinder.register_rule(type='arglist') class _ArglistRule(SyntaxRule): @property def message(self): if self._normalizer.version < (3, 7): return "Generator expression must be parenthesized if not sole argument" else: return "Generator expression must be parenthesized" def is_issue(self, node): first_arg = node.children[0] if first_arg.type == 'argument' \ and first_arg.children[1].type == 'comp_for': # e.g. foo(x for x in [], b) return len(node.children) >= 2 else: arg_set = set() kw_only = False kw_unpacking_only = False is_old_starred = False # In python 3 this would be a bit easier (stars are part of # argument), but we have to understand both. for argument in node.children: if argument == ',': continue if argument in ('*', '**'): # Python < 3.5 has the order engraved in the grammar # file. No need to do anything here. is_old_starred = True continue if is_old_starred: is_old_starred = False continue if argument.type == 'argument': first = argument.children[0] if first in ('*', '**'): if first == '*': if kw_unpacking_only: # foo(**kwargs, *args) message = "iterable argument unpacking follows keyword argument unpacking" self.add_issue(argument, message=message) else: kw_unpacking_only = True else: # Is a keyword argument. kw_only = True if first.type == 'name': if first.value in arg_set: # f(x=1, x=2) self.add_issue(first, message="keyword argument repeated") else: arg_set.add(first.value) else: if kw_unpacking_only: # f(**x, y) message = "positional argument follows keyword argument unpacking" self.add_issue(argument, message=message) elif kw_only: # f(x=2, y) message = "positional argument follows keyword argument" self.add_issue(argument, message=message) @ErrorFinder.register_rule(type='parameters') @ErrorFinder.register_rule(type='lambdef') class _ParameterRule(SyntaxRule): # def f(x=3, y): pass message = "non-default argument follows default argument" def is_issue(self, node): param_names = set() default_only = False for p in _iter_params(node): if p.name.value in param_names: message = "duplicate argument '%s' in function definition" self.add_issue(p.name, message=message % p.name.value) param_names.add(p.name.value) if p.default is None and not p.star_count: if default_only: return True else: default_only = True @ErrorFinder.register_rule(type='try_stmt') class _TryStmtRule(SyntaxRule): message = "default 'except:' must be last" def is_issue(self, try_stmt): default_except = None for except_clause in try_stmt.children[3::3]: if except_clause in ('else', 'finally'): break if except_clause == 'except': default_except = except_clause elif default_except is not None: self.add_issue(default_except, message=self.message) @ErrorFinder.register_rule(type='fstring') class _FStringRule(SyntaxRule): _fstring_grammar = None message_nested = "f-string: expressions nested too deeply" message_conversion = "f-string: invalid conversion character: expected 's', 'r', or 'a'" def _check_format_spec(self, format_spec, depth): self._check_fstring_contents(format_spec.children[1:], depth) def _check_fstring_expr(self, fstring_expr, depth): if depth >= 2: self.add_issue(fstring_expr, message=self.message_nested) conversion = fstring_expr.children[2] if conversion.type == 'fstring_conversion': name = conversion.children[1] if name.value not in ('s', 'r', 'a'): self.add_issue(name, message=self.message_conversion) format_spec = fstring_expr.children[-2] if format_spec.type == 'fstring_format_spec': self._check_format_spec(format_spec, depth + 1) def is_issue(self, fstring): self._check_fstring_contents(fstring.children[1:-1]) def _check_fstring_contents(self, children, depth=0): for fstring_content in children: if fstring_content.type == 'fstring_expr': self._check_fstring_expr(fstring_content, depth) class _CheckAssignmentRule(SyntaxRule): def _check_assignment(self, node, is_deletion=False): error = None type_ = node.type if type_ == 'lambdef': error = 'lambda' elif type_ == 'atom': first, second = node.children[:2] error = _get_comprehension_type(node) if error is None: if second.type == 'dictorsetmaker': error = 'literal' elif first in ('(', '['): if second.type == 'yield_expr': error = 'yield expression' elif second.type == 'testlist_comp': # This is not a comprehension, they were handled # further above. for child in second.children[::2]: self._check_assignment(child, is_deletion) else: # Everything handled, must be useless brackets. self._check_assignment(second, is_deletion) elif type_ == 'keyword': error = 'keyword' elif type_ == 'operator': if node.value == '...': error = 'Ellipsis' elif type_ == 'comparison': error = 'comparison' elif type_ in ('string', 'number', 'strings'): error = 'literal' elif type_ == 'yield_expr': # This one seems to be a slightly different warning in Python. message = 'assignment to yield expression not possible' self.add_issue(node, message=message) elif type_ == 'test': error = 'conditional expression' elif type_ in ('atom_expr', 'power'): if node.children[0] == 'await': error = 'await expression' elif node.children[-2] == '**': error = 'operator' else: # Has a trailer trailer = node.children[-1] assert trailer.type == 'trailer' if trailer.children[0] == '(': error = 'function call' elif type_ in ('testlist_star_expr', 'exprlist', 'testlist'): for child in node.children[::2]: self._check_assignment(child, is_deletion) elif ('expr' in type_ and type_ != 'star_expr' # is a substring or '_test' in type_ or type_ in ('term', 'factor')): error = 'operator' if error is not None: message = "can't %s %s" % ("delete" if is_deletion else "assign to", error) self.add_issue(node, message=message) @ErrorFinder.register_rule(type='comp_for') class _CompForRule(_CheckAssignmentRule): message = "asynchronous comprehension outside of an asynchronous function" def is_issue(self, node): # Some of the nodes here are already used, so no else if expr_list = node.children[1 + int(node.children[0] == 'async')] if expr_list.type != 'expr_list': # Already handled. self._check_assignment(expr_list) return node.children[0] == 'async' \ and not self._normalizer.context.is_async_funcdef() @ErrorFinder.register_rule(type='expr_stmt') class _ExprStmtRule(_CheckAssignmentRule): message = "illegal expression for augmented assignment" def is_issue(self, node): for before_equal in node.children[:-2:2]: self._check_assignment(before_equal) augassign = node.children[1] if augassign != '=' and augassign.type != 'annassign': # Is augassign. return node.children[0].type in ('testlist_star_expr', 'atom', 'testlist') @ErrorFinder.register_rule(type='with_item') class _WithItemRule(_CheckAssignmentRule): def is_issue(self, with_item): self._check_assignment(with_item.children[2]) @ErrorFinder.register_rule(type='del_stmt') class _DelStmtRule(_CheckAssignmentRule): def is_issue(self, del_stmt): child = del_stmt.children[1] if child.type != 'expr_list': # Already handled. self._check_assignment(child, is_deletion=True) @ErrorFinder.register_rule(type='expr_list') class _ExprListRule(_CheckAssignmentRule): def is_issue(self, expr_list): for expr in expr_list.children[::2]: self._check_assignment(expr) @ErrorFinder.register_rule(type='for_stmt') class _ForStmtRule(_CheckAssignmentRule): def is_issue(self, for_stmt): # Some of the nodes here are already used, so no else if expr_list = for_stmt.children[1] if expr_list.type != 'expr_list': # Already handled. self._check_assignment(expr_list)