# Licensed under the Apache License: http://www.apache.org/licenses/LICENSE-2.0 # For details: https://github.com/nedbat/coveragepy/blob/master/NOTICE.txt """Code parsing for coverage.py.""" from __future__ import annotations import ast import collections import os import re import sys import token import tokenize from types import CodeType from typing import ( cast, Any, Callable, Dict, Iterable, List, Optional, Sequence, Set, Tuple, ) from coverage import env from coverage.bytecode import code_objects from coverage.debug import short_stack from coverage.exceptions import NoSource, NotPython from coverage.misc import join_regex, nice_pair from coverage.phystokens import generate_tokens from coverage.types import Protocol, TArc, TLineNo class PythonParser: """Parse code to find executable lines, excluded lines, etc. This information is all based on static analysis: no code execution is involved. """ def __init__( self, text: Optional[str] = None, filename: Optional[str] = None, exclude: Optional[str] = None, ) -> None: """ Source can be provided as `text`, the text itself, or `filename`, from which the text will be read. Excluded lines are those that match `exclude`, a regex string. """ assert text or filename, "PythonParser needs either text or filename" self.filename = filename or "" if text is not None: self.text: str = text else: from coverage.python import get_python_source try: self.text = get_python_source(self.filename) except OSError as err: raise NoSource(f"No source for code: '{self.filename}': {err}") from err self.exclude = exclude # The text lines of the parsed code. self.lines: List[str] = self.text.split("\n") # The normalized line numbers of the statements in the code. Exclusions # are taken into account, and statements are adjusted to their first # lines. self.statements: Set[TLineNo] = set() # The normalized line numbers of the excluded lines in the code, # adjusted to their first lines. self.excluded: Set[TLineNo] = set() # The raw_* attributes are only used in this class, and in # lab/parser.py to show how this class is working. # The line numbers that start statements, as reported by the line # number table in the bytecode. self.raw_statements: Set[TLineNo] = set() # The raw line numbers of excluded lines of code, as marked by pragmas. self.raw_excluded: Set[TLineNo] = set() # The line numbers of class definitions. self.raw_classdefs: Set[TLineNo] = set() # The line numbers of docstring lines. self.raw_docstrings: Set[TLineNo] = set() # Internal detail, used by lab/parser.py. self.show_tokens = False # A dict mapping line numbers to lexical statement starts for # multi-line statements. self._multiline: Dict[TLineNo, TLineNo] = {} # Lazily-created arc data, and missing arc descriptions. self._all_arcs: Optional[Set[TArc]] = None self._missing_arc_fragments: Optional[TArcFragments] = None def lines_matching(self, *regexes: str) -> Set[TLineNo]: """Find the lines matching one of a list of regexes. Returns a set of line numbers, the lines that contain a match for one of the regexes in `regexes`. The entire line needn't match, just a part of it. """ combined = join_regex(regexes) regex_c = re.compile(combined) matches = set() for i, ltext in enumerate(self.lines, start=1): if regex_c.search(ltext): matches.add(i) return matches def _raw_parse(self) -> None: """Parse the source to find the interesting facts about its lines. A handful of attributes are updated. """ # Find lines which match an exclusion pattern. if self.exclude: self.raw_excluded = self.lines_matching(self.exclude) # Tokenize, to find excluded suites, to find docstrings, and to find # multi-line statements. indent = 0 exclude_indent = 0 excluding = False excluding_decorators = False prev_toktype = token.INDENT first_line = None empty = True first_on_line = True nesting = 0 assert self.text is not None tokgen = generate_tokens(self.text) for toktype, ttext, (slineno, _), (elineno, _), ltext in tokgen: if self.show_tokens: # pragma: debugging print("%10s %5s %-20r %r" % ( tokenize.tok_name.get(toktype, toktype), nice_pair((slineno, elineno)), ttext, ltext )) if toktype == token.INDENT: indent += 1 elif toktype == token.DEDENT: indent -= 1 elif toktype == token.NAME: if ttext == "class": # Class definitions look like branches in the bytecode, so # we need to exclude them. The simplest way is to note the # lines with the "class" keyword. self.raw_classdefs.add(slineno) elif toktype == token.OP: if ttext == ":" and nesting == 0: should_exclude = (elineno in self.raw_excluded) or excluding_decorators if not excluding and should_exclude: # Start excluding a suite. We trigger off of the colon # token so that the #pragma comment will be recognized on # the same line as the colon. self.raw_excluded.add(elineno) exclude_indent = indent excluding = True excluding_decorators = False elif ttext == "@" and first_on_line: # A decorator. if elineno in self.raw_excluded: excluding_decorators = True if excluding_decorators: self.raw_excluded.add(elineno) elif ttext in "([{": nesting += 1 elif ttext in ")]}": nesting -= 1 elif toktype == token.STRING and prev_toktype == token.INDENT: # Strings that are first on an indented line are docstrings. # (a trick from trace.py in the stdlib.) This works for # 99.9999% of cases. For the rest (!) see: # http://stackoverflow.com/questions/1769332/x/1769794#1769794 self.raw_docstrings.update(range(slineno, elineno+1)) elif toktype == token.NEWLINE: if first_line is not None and elineno != first_line: # type: ignore[unreachable] # We're at the end of a line, and we've ended on a # different line than the first line of the statement, # so record a multi-line range. for l in range(first_line, elineno+1): # type: ignore[unreachable] self._multiline[l] = first_line first_line = None first_on_line = True if ttext.strip() and toktype != tokenize.COMMENT: # A non-white-space token. empty = False if first_line is None: # The token is not white space, and is the first in a statement. first_line = slineno # Check whether to end an excluded suite. if excluding and indent <= exclude_indent: excluding = False if excluding: self.raw_excluded.add(elineno) first_on_line = False prev_toktype = toktype # Find the starts of the executable statements. if not empty: byte_parser = ByteParser(self.text, filename=self.filename) self.raw_statements.update(byte_parser._find_statements()) # The first line of modules can lie and say 1 always, even if the first # line of code is later. If so, map 1 to the actual first line of the # module. if env.PYBEHAVIOR.module_firstline_1 and self._multiline: self._multiline[1] = min(self.raw_statements) def first_line(self, lineno: TLineNo) -> TLineNo: """Return the first line number of the statement including `lineno`.""" if lineno < 0: lineno = -self._multiline.get(-lineno, -lineno) else: lineno = self._multiline.get(lineno, lineno) return lineno def first_lines(self, linenos: Iterable[TLineNo]) -> Set[TLineNo]: """Map the line numbers in `linenos` to the correct first line of the statement. Returns a set of the first lines. """ return {self.first_line(l) for l in linenos} def translate_lines(self, lines: Iterable[TLineNo]) -> Set[TLineNo]: """Implement `FileReporter.translate_lines`.""" return self.first_lines(lines) def translate_arcs(self, arcs: Iterable[TArc]) -> Set[TArc]: """Implement `FileReporter.translate_arcs`.""" return {(self.first_line(a), self.first_line(b)) for (a, b) in arcs} def parse_source(self) -> None: """Parse source text to find executable lines, excluded lines, etc. Sets the .excluded and .statements attributes, normalized to the first line of multi-line statements. """ try: self._raw_parse() except (tokenize.TokenError, IndentationError) as err: if hasattr(err, "lineno"): lineno = err.lineno # IndentationError else: lineno = err.args[1][0] # TokenError raise NotPython( f"Couldn't parse '{self.filename}' as Python source: " + f"{err.args[0]!r} at line {lineno}" ) from err self.excluded = self.first_lines(self.raw_excluded) ignore = self.excluded | self.raw_docstrings starts = self.raw_statements - ignore self.statements = self.first_lines(starts) - ignore def arcs(self) -> Set[TArc]: """Get information about the arcs available in the code. Returns a set of line number pairs. Line numbers have been normalized to the first line of multi-line statements. """ if self._all_arcs is None: self._analyze_ast() assert self._all_arcs is not None return self._all_arcs def _analyze_ast(self) -> None: """Run the AstArcAnalyzer and save its results. `_all_arcs` is the set of arcs in the code. """ aaa = AstArcAnalyzer(self.text, self.raw_statements, self._multiline) aaa.analyze() self._all_arcs = set() for l1, l2 in aaa.arcs: fl1 = self.first_line(l1) fl2 = self.first_line(l2) if fl1 != fl2: self._all_arcs.add((fl1, fl2)) self._missing_arc_fragments = aaa.missing_arc_fragments def exit_counts(self) -> Dict[TLineNo, int]: """Get a count of exits from that each line. Excluded lines are excluded. """ exit_counts: Dict[TLineNo, int] = collections.defaultdict(int) for l1, l2 in self.arcs(): if l1 < 0: # Don't ever report -1 as a line number continue if l1 in self.excluded: # Don't report excluded lines as line numbers. continue if l2 in self.excluded: # Arcs to excluded lines shouldn't count. continue exit_counts[l1] += 1 # Class definitions have one extra exit, so remove one for each: for l in self.raw_classdefs: # Ensure key is there: class definitions can include excluded lines. if l in exit_counts: exit_counts[l] -= 1 return exit_counts def missing_arc_description( self, start: TLineNo, end: TLineNo, executed_arcs: Optional[Iterable[TArc]] = None, ) -> str: """Provide an English sentence describing a missing arc.""" if self._missing_arc_fragments is None: self._analyze_ast() assert self._missing_arc_fragments is not None actual_start = start if ( executed_arcs and end < 0 and end == -start and (end, start) not in executed_arcs and (end, start) in self._missing_arc_fragments ): # It's a one-line callable, and we never even started it, # and we have a message about not starting it. start, end = end, start fragment_pairs = self._missing_arc_fragments.get((start, end), [(None, None)]) msgs = [] for smsg, emsg in fragment_pairs: if emsg is None: if end < 0: # Hmm, maybe we have a one-line callable, let's check. if (-end, end) in self._missing_arc_fragments: return self.missing_arc_description(-end, end) emsg = "didn't jump to the function exit" else: emsg = "didn't jump to line {lineno}" emsg = emsg.format(lineno=end) msg = f"line {actual_start} {emsg}" if smsg is not None: msg += f", because {smsg.format(lineno=actual_start)}" msgs.append(msg) return " or ".join(msgs) class ByteParser: """Parse bytecode to understand the structure of code.""" def __init__( self, text: str, code: Optional[CodeType] = None, filename: Optional[str] = None, ) -> None: self.text = text if code is not None: self.code = code else: assert filename is not None try: self.code = compile(text, filename, "exec", dont_inherit=True) except SyntaxError as synerr: raise NotPython( "Couldn't parse '%s' as Python source: '%s' at line %d" % ( filename, synerr.msg, synerr.lineno or 0 ) ) from synerr def child_parsers(self) -> Iterable[ByteParser]: """Iterate over all the code objects nested within this one. The iteration includes `self` as its first value. """ return (ByteParser(self.text, code=c) for c in code_objects(self.code)) def _line_numbers(self) -> Iterable[TLineNo]: """Yield the line numbers possible in this code object. Uses co_lnotab described in Python/compile.c to find the line numbers. Produces a sequence: l0, l1, ... """ if hasattr(self.code, "co_lines"): for _, _, line in self.code.co_lines(): if line: yield line else: # Adapted from dis.py in the standard library. byte_increments = self.code.co_lnotab[0::2] line_increments = self.code.co_lnotab[1::2] last_line_num = None line_num = self.code.co_firstlineno byte_num = 0 for byte_incr, line_incr in zip(byte_increments, line_increments): if byte_incr: if line_num != last_line_num: yield line_num last_line_num = line_num byte_num += byte_incr if env.PYBEHAVIOR.negative_lnotab and line_incr >= 0x80: line_incr -= 0x100 line_num += line_incr if line_num != last_line_num: yield line_num def _find_statements(self) -> Iterable[TLineNo]: """Find the statements in `self.code`. Produce a sequence of line numbers that start statements. Recurses into all code objects reachable from `self.code`. """ for bp in self.child_parsers(): # Get all of the lineno information from this code. yield from bp._line_numbers() # # AST analysis # class ArcStart(collections.namedtuple("Arc", "lineno, cause")): """The information needed to start an arc. `lineno` is the line number the arc starts from. `cause` is an English text fragment used as the `startmsg` for AstArcAnalyzer.missing_arc_fragments. It will be used to describe why an arc wasn't executed, so should fit well into a sentence of the form, "Line 17 didn't run because {cause}." The fragment can include "{lineno}" to have `lineno` interpolated into it. """ def __new__(cls, lineno: TLineNo, cause: Optional[str] = None) -> ArcStart: return super().__new__(cls, lineno, cause) class TAddArcFn(Protocol): """The type for AstArcAnalyzer.add_arc().""" def __call__( self, start: TLineNo, end: TLineNo, smsg: Optional[str] = None, emsg: Optional[str] = None, ) -> None: ... TArcFragments = Dict[TArc, List[Tuple[Optional[str], Optional[str]]]] class Block: """ Blocks need to handle various exiting statements in their own ways. All of these methods take a list of exits, and a callable `add_arc` function that they can use to add arcs if needed. They return True if the exits are handled, or False if the search should continue up the block stack. """ # pylint: disable=unused-argument def process_break_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: """Process break exits.""" # Because break can only appear in loops, and most subclasses # implement process_break_exits, this function is never reached. raise AssertionError def process_continue_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: """Process continue exits.""" # Because continue can only appear in loops, and most subclasses # implement process_continue_exits, this function is never reached. raise AssertionError def process_raise_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: """Process raise exits.""" return False def process_return_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: """Process return exits.""" return False class LoopBlock(Block): """A block on the block stack representing a `for` or `while` loop.""" def __init__(self, start: TLineNo) -> None: # The line number where the loop starts. self.start = start # A set of ArcStarts, the arcs from break statements exiting this loop. self.break_exits: Set[ArcStart] = set() def process_break_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: self.break_exits.update(exits) return True def process_continue_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: for xit in exits: add_arc(xit.lineno, self.start, xit.cause) return True class FunctionBlock(Block): """A block on the block stack representing a function definition.""" def __init__(self, start: TLineNo, name: str) -> None: # The line number where the function starts. self.start = start # The name of the function. self.name = name def process_raise_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: for xit in exits: add_arc( xit.lineno, -self.start, xit.cause, f"didn't except from function {self.name!r}", ) return True def process_return_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: for xit in exits: add_arc( xit.lineno, -self.start, xit.cause, f"didn't return from function {self.name!r}", ) return True class TryBlock(Block): """A block on the block stack representing a `try` block.""" def __init__(self, handler_start: Optional[TLineNo], final_start: Optional[TLineNo]) -> None: # The line number of the first "except" handler, if any. self.handler_start = handler_start # The line number of the "finally:" clause, if any. self.final_start = final_start # The ArcStarts for breaks/continues/returns/raises inside the "try:" # that need to route through the "finally:" clause. self.break_from: Set[ArcStart] = set() self.continue_from: Set[ArcStart] = set() self.raise_from: Set[ArcStart] = set() self.return_from: Set[ArcStart] = set() def process_break_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: if self.final_start is not None: self.break_from.update(exits) return True return False def process_continue_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: if self.final_start is not None: self.continue_from.update(exits) return True return False def process_raise_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: if self.handler_start is not None: for xit in exits: add_arc(xit.lineno, self.handler_start, xit.cause) else: assert self.final_start is not None self.raise_from.update(exits) return True def process_return_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: if self.final_start is not None: self.return_from.update(exits) return True return False class WithBlock(Block): """A block on the block stack representing a `with` block.""" def __init__(self, start: TLineNo) -> None: # We only ever use this block if it is needed, so that we don't have to # check this setting in all the methods. assert env.PYBEHAVIOR.exit_through_with # The line number of the with statement. self.start = start # The ArcStarts for breaks/continues/returns/raises inside the "with:" # that need to go through the with-statement while exiting. self.break_from: Set[ArcStart] = set() self.continue_from: Set[ArcStart] = set() self.return_from: Set[ArcStart] = set() def _process_exits( self, exits: Set[ArcStart], add_arc: TAddArcFn, from_set: Optional[Set[ArcStart]] = None, ) -> bool: """Helper to process the four kinds of exits.""" for xit in exits: add_arc(xit.lineno, self.start, xit.cause) if from_set is not None: from_set.update(exits) return True def process_break_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: return self._process_exits(exits, add_arc, self.break_from) def process_continue_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: return self._process_exits(exits, add_arc, self.continue_from) def process_raise_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: return self._process_exits(exits, add_arc) def process_return_exits(self, exits: Set[ArcStart], add_arc: TAddArcFn) -> bool: return self._process_exits(exits, add_arc, self.return_from) class NodeList(ast.AST): """A synthetic fictitious node, containing a sequence of nodes. This is used when collapsing optimized if-statements, to represent the unconditional execution of one of the clauses. """ def __init__(self, body: Sequence[ast.AST]) -> None: self.body = body self.lineno = body[0].lineno # TODO: some add_arcs methods here don't add arcs, they return them. Rename them. # TODO: the cause messages have too many commas. # TODO: Shouldn't the cause messages join with "and" instead of "or"? def _make_expression_code_method(noun: str) -> Callable[[AstArcAnalyzer, ast.AST], None]: """A function to make methods for expression-based callable _code_object__ methods.""" def _code_object__expression_callable(self: AstArcAnalyzer, node: ast.AST) -> None: start = self.line_for_node(node) self.add_arc(-start, start, None, f"didn't run the {noun} on line {start}") self.add_arc(start, -start, None, f"didn't finish the {noun} on line {start}") return _code_object__expression_callable class AstArcAnalyzer: """Analyze source text with an AST to find executable code paths.""" def __init__( self, text: str, statements: Set[TLineNo], multiline: Dict[TLineNo, TLineNo], ) -> None: self.root_node = ast.parse(text) # TODO: I think this is happening in too many places. self.statements = {multiline.get(l, l) for l in statements} self.multiline = multiline # Turn on AST dumps with an environment variable. # $set_env.py: COVERAGE_AST_DUMP - Dump the AST nodes when parsing code. dump_ast = bool(int(os.environ.get("COVERAGE_AST_DUMP", 0))) if dump_ast: # pragma: debugging # Dump the AST so that failing tests have helpful output. print(f"Statements: {self.statements}") print(f"Multiline map: {self.multiline}") ast_dump(self.root_node) self.arcs: Set[TArc] = set() # A map from arc pairs to a list of pairs of sentence fragments: # { (start, end): [(startmsg, endmsg), ...], } # # For an arc from line 17, they should be usable like: # "Line 17 {endmsg}, because {startmsg}" self.missing_arc_fragments: TArcFragments = collections.defaultdict(list) self.block_stack: List[Block] = [] # $set_env.py: COVERAGE_TRACK_ARCS - Trace possible arcs added while parsing code. self.debug = bool(int(os.environ.get("COVERAGE_TRACK_ARCS", 0))) def analyze(self) -> None: """Examine the AST tree from `root_node` to determine possible arcs. This sets the `arcs` attribute to be a set of (from, to) line number pairs. """ for node in ast.walk(self.root_node): node_name = node.__class__.__name__ code_object_handler = getattr(self, "_code_object__" + node_name, None) if code_object_handler is not None: code_object_handler(node) def add_arc( self, start: TLineNo, end: TLineNo, smsg: Optional[str] = None, emsg: Optional[str] = None, ) -> None: """Add an arc, including message fragments to use if it is missing.""" if self.debug: # pragma: debugging print(f"\nAdding possible arc: ({start}, {end}): {smsg!r}, {emsg!r}") print(short_stack(limit=10)) self.arcs.add((start, end)) if smsg is not None or emsg is not None: self.missing_arc_fragments[(start, end)].append((smsg, emsg)) def nearest_blocks(self) -> Iterable[Block]: """Yield the blocks in nearest-to-farthest order.""" return reversed(self.block_stack) def line_for_node(self, node: ast.AST) -> TLineNo: """What is the right line number to use for this node? This dispatches to _line__Node functions where needed. """ node_name = node.__class__.__name__ handler = cast( Optional[Callable[[ast.AST], TLineNo]], getattr(self, "_line__" + node_name, None) ) if handler is not None: return handler(node) else: return node.lineno def _line_decorated(self, node: ast.FunctionDef) -> TLineNo: """Compute first line number for things that can be decorated (classes and functions).""" lineno = node.lineno if env.PYBEHAVIOR.trace_decorated_def or env.PYBEHAVIOR.def_ast_no_decorator: if node.decorator_list: lineno = node.decorator_list[0].lineno return lineno def _line__Assign(self, node: ast.Assign) -> TLineNo: return self.line_for_node(node.value) _line__ClassDef = _line_decorated def _line__Dict(self, node: ast.Dict) -> TLineNo: if node.keys: if node.keys[0] is not None: return node.keys[0].lineno else: # Unpacked dict literals `{**{"a":1}}` have None as the key, # use the value in that case. return node.values[0].lineno else: return node.lineno _line__FunctionDef = _line_decorated _line__AsyncFunctionDef = _line_decorated def _line__List(self, node: ast.List) -> TLineNo: if node.elts: return self.line_for_node(node.elts[0]) else: return node.lineno def _line__Module(self, node: ast.Module) -> TLineNo: if env.PYBEHAVIOR.module_firstline_1: return 1 elif node.body: return self.line_for_node(node.body[0]) else: # Empty modules have no line number, they always start at 1. return 1 # The node types that just flow to the next node with no complications. OK_TO_DEFAULT = { "AnnAssign", "Assign", "Assert", "AugAssign", "Delete", "Expr", "Global", "Import", "ImportFrom", "Nonlocal", "Pass", } def add_arcs(self, node: ast.AST) -> Set[ArcStart]: """Add the arcs for `node`. Return a set of ArcStarts, exits from this node to the next. Because a node represents an entire sub-tree (including its children), the exits from a node can be arbitrarily complex:: if something(1): if other(2): doit(3) else: doit(5) There are two exits from line 1: they start at line 3 and line 5. """ node_name = node.__class__.__name__ handler = cast( Optional[Callable[[ast.AST], Set[ArcStart]]], getattr(self, "_handle__" + node_name, None) ) if handler is not None: return handler(node) else: # No handler: either it's something that's ok to default (a simple # statement), or it's something we overlooked. if env.TESTING: if node_name not in self.OK_TO_DEFAULT: raise RuntimeError(f"*** Unhandled: {node}") # pragma: only failure # Default for simple statements: one exit from this node. return {ArcStart(self.line_for_node(node))} def add_body_arcs( self, body: Sequence[ast.AST], from_start: Optional[ArcStart] = None, prev_starts: Optional[Set[ArcStart]] = None ) -> Set[ArcStart]: """Add arcs for the body of a compound statement. `body` is the body node. `from_start` is a single `ArcStart` that can be the previous line in flow before this body. `prev_starts` is a set of ArcStarts that can be the previous line. Only one of them should be given. Returns a set of ArcStarts, the exits from this body. """ if prev_starts is None: assert from_start is not None prev_starts = {from_start} for body_node in body: lineno = self.line_for_node(body_node) first_line = self.multiline.get(lineno, lineno) if first_line not in self.statements: maybe_body_node = self.find_non_missing_node(body_node) if maybe_body_node is None: continue body_node = maybe_body_node lineno = self.line_for_node(body_node) for prev_start in prev_starts: self.add_arc(prev_start.lineno, lineno, prev_start.cause) prev_starts = self.add_arcs(body_node) return prev_starts def find_non_missing_node(self, node: ast.AST) -> Optional[ast.AST]: """Search `node` looking for a child that has not been optimized away. This might return the node you started with, or it will work recursively to find a child node in self.statements. Returns a node, or None if none of the node remains. """ # This repeats work just done in add_body_arcs, but this duplication # means we can avoid a function call in the 99.9999% case of not # optimizing away statements. lineno = self.line_for_node(node) first_line = self.multiline.get(lineno, lineno) if first_line in self.statements: return node missing_fn = cast( Optional[Callable[[ast.AST], Optional[ast.AST]]], getattr(self, "_missing__" + node.__class__.__name__, None) ) if missing_fn is not None: ret_node = missing_fn(node) else: ret_node = None return ret_node # Missing nodes: _missing__* # # Entire statements can be optimized away by Python. They will appear in # the AST, but not the bytecode. These functions are called (by # find_non_missing_node) to find a node to use instead of the missing # node. They can return None if the node should truly be gone. def _missing__If(self, node: ast.If) -> Optional[ast.AST]: # If the if-node is missing, then one of its children might still be # here, but not both. So return the first of the two that isn't missing. # Use a NodeList to hold the clauses as a single node. non_missing = self.find_non_missing_node(NodeList(node.body)) if non_missing: return non_missing if node.orelse: return self.find_non_missing_node(NodeList(node.orelse)) return None def _missing__NodeList(self, node: NodeList) -> Optional[ast.AST]: # A NodeList might be a mixture of missing and present nodes. Find the # ones that are present. non_missing_children = [] for child in node.body: maybe_child = self.find_non_missing_node(child) if maybe_child is not None: non_missing_children.append(maybe_child) # Return the simplest representation of the present children. if not non_missing_children: return None if len(non_missing_children) == 1: return non_missing_children[0] return NodeList(non_missing_children) def _missing__While(self, node: ast.While) -> Optional[ast.AST]: body_nodes = self.find_non_missing_node(NodeList(node.body)) if not body_nodes: return None # Make a synthetic While-true node. new_while = ast.While() new_while.lineno = body_nodes.lineno new_while.test = ast.Name() new_while.test.lineno = body_nodes.lineno new_while.test.id = "True" assert hasattr(body_nodes, "body") new_while.body = body_nodes.body new_while.orelse = [] return new_while def is_constant_expr(self, node: ast.AST) -> Optional[str]: """Is this a compile-time constant?""" node_name = node.__class__.__name__ if node_name in ["Constant", "NameConstant", "Num"]: return "Num" elif isinstance(node, ast.Name): if node.id in ["True", "False", "None", "__debug__"]: return "Name" return None # In the fullness of time, these might be good tests to write: # while EXPR: # while False: # listcomps hidden deep in other expressions # listcomps hidden in lists: x = [[i for i in range(10)]] # nested function definitions # Exit processing: process_*_exits # # These functions process the four kinds of jump exits: break, continue, # raise, and return. To figure out where an exit goes, we have to look at # the block stack context. For example, a break will jump to the nearest # enclosing loop block, or the nearest enclosing finally block, whichever # is nearer. def process_break_exits(self, exits: Set[ArcStart]) -> None: """Add arcs due to jumps from `exits` being breaks.""" for block in self.nearest_blocks(): # pragma: always breaks if block.process_break_exits(exits, self.add_arc): break def process_continue_exits(self, exits: Set[ArcStart]) -> None: """Add arcs due to jumps from `exits` being continues.""" for block in self.nearest_blocks(): # pragma: always breaks if block.process_continue_exits(exits, self.add_arc): break def process_raise_exits(self, exits: Set[ArcStart]) -> None: """Add arcs due to jumps from `exits` being raises.""" for block in self.nearest_blocks(): if block.process_raise_exits(exits, self.add_arc): break def process_return_exits(self, exits: Set[ArcStart]) -> None: """Add arcs due to jumps from `exits` being returns.""" for block in self.nearest_blocks(): # pragma: always breaks if block.process_return_exits(exits, self.add_arc): break # Handlers: _handle__* # # Each handler deals with a specific AST node type, dispatched from # add_arcs. Handlers return the set of exits from that node, and can # also call self.add_arc to record arcs they find. These functions mirror # the Python semantics of each syntactic construct. See the docstring # for add_arcs to understand the concept of exits from a node. # # Every node type that represents a statement should have a handler, or it # should be listed in OK_TO_DEFAULT. def _handle__Break(self, node: ast.Break) -> Set[ArcStart]: here = self.line_for_node(node) break_start = ArcStart(here, cause="the break on line {lineno} wasn't executed") self.process_break_exits({break_start}) return set() def _handle_decorated(self, node: ast.FunctionDef) -> Set[ArcStart]: """Add arcs for things that can be decorated (classes and functions).""" main_line: TLineNo = node.lineno last: Optional[TLineNo] = node.lineno decs = node.decorator_list if decs: if env.PYBEHAVIOR.trace_decorated_def or env.PYBEHAVIOR.def_ast_no_decorator: last = None for dec_node in decs: dec_start = self.line_for_node(dec_node) if last is not None and dec_start != last: self.add_arc(last, dec_start) last = dec_start assert last is not None if env.PYBEHAVIOR.trace_decorated_def: self.add_arc(last, main_line) last = main_line if env.PYBEHAVIOR.trace_decorator_line_again: for top, bot in zip(decs, decs[1:]): self.add_arc(self.line_for_node(bot), self.line_for_node(top)) self.add_arc(self.line_for_node(decs[0]), main_line) self.add_arc(main_line, self.line_for_node(decs[-1])) # The definition line may have been missed, but we should have it # in `self.statements`. For some constructs, `line_for_node` is # not what we'd think of as the first line in the statement, so map # it to the first one. if node.body: body_start = self.line_for_node(node.body[0]) body_start = self.multiline.get(body_start, body_start) for lineno in range(last+1, body_start): if lineno in self.statements: self.add_arc(last, lineno) last = lineno # The body is handled in collect_arcs. assert last is not None return {ArcStart(last)} _handle__ClassDef = _handle_decorated def _handle__Continue(self, node: ast.Continue) -> Set[ArcStart]: here = self.line_for_node(node) continue_start = ArcStart(here, cause="the continue on line {lineno} wasn't executed") self.process_continue_exits({continue_start}) return set() def _handle__For(self, node: ast.For) -> Set[ArcStart]: start = self.line_for_node(node.iter) self.block_stack.append(LoopBlock(start=start)) from_start = ArcStart(start, cause="the loop on line {lineno} never started") exits = self.add_body_arcs(node.body, from_start=from_start) # Any exit from the body will go back to the top of the loop. for xit in exits: self.add_arc(xit.lineno, start, xit.cause) my_block = self.block_stack.pop() assert isinstance(my_block, LoopBlock) exits = my_block.break_exits from_start = ArcStart(start, cause="the loop on line {lineno} didn't complete") if node.orelse: else_exits = self.add_body_arcs(node.orelse, from_start=from_start) exits |= else_exits else: # No else clause: exit from the for line. exits.add(from_start) return exits _handle__AsyncFor = _handle__For _handle__FunctionDef = _handle_decorated _handle__AsyncFunctionDef = _handle_decorated def _handle__If(self, node: ast.If) -> Set[ArcStart]: start = self.line_for_node(node.test) from_start = ArcStart(start, cause="the condition on line {lineno} was never true") exits = self.add_body_arcs(node.body, from_start=from_start) from_start = ArcStart(start, cause="the condition on line {lineno} was never false") exits |= self.add_body_arcs(node.orelse, from_start=from_start) return exits if sys.version_info >= (3, 10): def _handle__Match(self, node: ast.Match) -> Set[ArcStart]: start = self.line_for_node(node) last_start = start exits = set() had_wildcard = False for case in node.cases: case_start = self.line_for_node(case.pattern) pattern = case.pattern while isinstance(pattern, ast.MatchOr): pattern = pattern.patterns[-1] if isinstance(pattern, ast.MatchAs): had_wildcard = True self.add_arc(last_start, case_start, "the pattern on line {lineno} always matched") from_start = ArcStart( case_start, cause="the pattern on line {lineno} never matched", ) exits |= self.add_body_arcs(case.body, from_start=from_start) last_start = case_start if not had_wildcard: exits.add(from_start) return exits def _handle__NodeList(self, node: NodeList) -> Set[ArcStart]: start = self.line_for_node(node) exits = self.add_body_arcs(node.body, from_start=ArcStart(start)) return exits def _handle__Raise(self, node: ast.Raise) -> Set[ArcStart]: here = self.line_for_node(node) raise_start = ArcStart(here, cause="the raise on line {lineno} wasn't executed") self.process_raise_exits({raise_start}) # `raise` statement jumps away, no exits from here. return set() def _handle__Return(self, node: ast.Return) -> Set[ArcStart]: here = self.line_for_node(node) return_start = ArcStart(here, cause="the return on line {lineno} wasn't executed") self.process_return_exits({return_start}) # `return` statement jumps away, no exits from here. return set() def _handle__Try(self, node: ast.Try) -> Set[ArcStart]: if node.handlers: handler_start = self.line_for_node(node.handlers[0]) else: handler_start = None if node.finalbody: final_start = self.line_for_node(node.finalbody[0]) else: final_start = None # This is true by virtue of Python syntax: have to have either except # or finally, or both. assert handler_start is not None or final_start is not None try_block = TryBlock(handler_start, final_start) self.block_stack.append(try_block) start = self.line_for_node(node) exits = self.add_body_arcs(node.body, from_start=ArcStart(start)) # We're done with the `try` body, so this block no longer handles # exceptions. We keep the block so the `finally` clause can pick up # flows from the handlers and `else` clause. if node.finalbody: try_block.handler_start = None if node.handlers: # If there are `except` clauses, then raises in the try body # will already jump to them. Start this set over for raises in # `except` and `else`. try_block.raise_from = set() else: self.block_stack.pop() handler_exits: Set[ArcStart] = set() if node.handlers: last_handler_start: Optional[TLineNo] = None for handler_node in node.handlers: handler_start = self.line_for_node(handler_node) if last_handler_start is not None: self.add_arc(last_handler_start, handler_start) last_handler_start = handler_start from_cause = "the exception caught by line {lineno} didn't happen" from_start = ArcStart(handler_start, cause=from_cause) handler_exits |= self.add_body_arcs(handler_node.body, from_start=from_start) if node.orelse: exits = self.add_body_arcs(node.orelse, prev_starts=exits) exits |= handler_exits if node.finalbody: self.block_stack.pop() final_from = ( # You can get to the `finally` clause from: exits | # the exits of the body or `else` clause, try_block.break_from | # or a `break`, try_block.continue_from | # or a `continue`, try_block.raise_from | # or a `raise`, try_block.return_from # or a `return`. ) final_exits = self.add_body_arcs(node.finalbody, prev_starts=final_from) if try_block.break_from: if env.PYBEHAVIOR.finally_jumps_back: for break_line in try_block.break_from: lineno = break_line.lineno cause = break_line.cause.format(lineno=lineno) for final_exit in final_exits: self.add_arc(final_exit.lineno, lineno, cause) breaks = try_block.break_from else: breaks = self._combine_finally_starts(try_block.break_from, final_exits) self.process_break_exits(breaks) if try_block.continue_from: if env.PYBEHAVIOR.finally_jumps_back: for continue_line in try_block.continue_from: lineno = continue_line.lineno cause = continue_line.cause.format(lineno=lineno) for final_exit in final_exits: self.add_arc(final_exit.lineno, lineno, cause) continues = try_block.continue_from else: continues = self._combine_finally_starts(try_block.continue_from, final_exits) self.process_continue_exits(continues) if try_block.raise_from: self.process_raise_exits( self._combine_finally_starts(try_block.raise_from, final_exits) ) if try_block.return_from: if env.PYBEHAVIOR.finally_jumps_back: for return_line in try_block.return_from: lineno = return_line.lineno cause = return_line.cause.format(lineno=lineno) for final_exit in final_exits: self.add_arc(final_exit.lineno, lineno, cause) returns = try_block.return_from else: returns = self._combine_finally_starts(try_block.return_from, final_exits) self.process_return_exits(returns) if exits: # The finally clause's exits are only exits for the try block # as a whole if the try block had some exits to begin with. exits = final_exits return exits def _combine_finally_starts(self, starts: Set[ArcStart], exits: Set[ArcStart]) -> Set[ArcStart]: """Helper for building the cause of `finally` branches. "finally" clauses might not execute their exits, and the causes could be due to a failure to execute any of the exits in the try block. So we use the causes from `starts` as the causes for `exits`. """ causes = [] for start in sorted(starts): if start.cause is not None: causes.append(start.cause.format(lineno=start.lineno)) cause = " or ".join(causes) exits = {ArcStart(xit.lineno, cause) for xit in exits} return exits def _handle__While(self, node: ast.While) -> Set[ArcStart]: start = to_top = self.line_for_node(node.test) constant_test = self.is_constant_expr(node.test) top_is_body0 = False if constant_test: top_is_body0 = True if env.PYBEHAVIOR.keep_constant_test: top_is_body0 = False if top_is_body0: to_top = self.line_for_node(node.body[0]) self.block_stack.append(LoopBlock(start=to_top)) from_start = ArcStart(start, cause="the condition on line {lineno} was never true") exits = self.add_body_arcs(node.body, from_start=from_start) for xit in exits: self.add_arc(xit.lineno, to_top, xit.cause) exits = set() my_block = self.block_stack.pop() assert isinstance(my_block, LoopBlock) exits.update(my_block.break_exits) from_start = ArcStart(start, cause="the condition on line {lineno} was never false") if node.orelse: else_exits = self.add_body_arcs(node.orelse, from_start=from_start) exits |= else_exits else: # No `else` clause: you can exit from the start. if not constant_test: exits.add(from_start) return exits def _handle__With(self, node: ast.With) -> Set[ArcStart]: start = self.line_for_node(node) if env.PYBEHAVIOR.exit_through_with: self.block_stack.append(WithBlock(start=start)) exits = self.add_body_arcs(node.body, from_start=ArcStart(start)) if env.PYBEHAVIOR.exit_through_with: with_block = self.block_stack.pop() assert isinstance(with_block, WithBlock) with_exit = {ArcStart(start)} if exits: for xit in exits: self.add_arc(xit.lineno, start) exits = with_exit if with_block.break_from: self.process_break_exits( self._combine_finally_starts(with_block.break_from, with_exit) ) if with_block.continue_from: self.process_continue_exits( self._combine_finally_starts(with_block.continue_from, with_exit) ) if with_block.return_from: self.process_return_exits( self._combine_finally_starts(with_block.return_from, with_exit) ) return exits _handle__AsyncWith = _handle__With # Code object dispatchers: _code_object__* # # These methods are used by analyze() as the start of the analysis. # There is one for each construct with a code object. def _code_object__Module(self, node: ast.Module) -> None: start = self.line_for_node(node) if node.body: exits = self.add_body_arcs(node.body, from_start=ArcStart(-start)) for xit in exits: self.add_arc(xit.lineno, -start, xit.cause, "didn't exit the module") else: # Empty module. self.add_arc(-start, start) self.add_arc(start, -start) def _code_object__FunctionDef(self, node: ast.FunctionDef) -> None: start = self.line_for_node(node) self.block_stack.append(FunctionBlock(start=start, name=node.name)) exits = self.add_body_arcs(node.body, from_start=ArcStart(-start)) self.process_return_exits(exits) self.block_stack.pop() _code_object__AsyncFunctionDef = _code_object__FunctionDef def _code_object__ClassDef(self, node: ast.ClassDef) -> None: start = self.line_for_node(node) self.add_arc(-start, start) exits = self.add_body_arcs(node.body, from_start=ArcStart(start)) for xit in exits: self.add_arc( xit.lineno, -start, xit.cause, f"didn't exit the body of class {node.name!r}", ) _code_object__Lambda = _make_expression_code_method("lambda") _code_object__GeneratorExp = _make_expression_code_method("generator expression") _code_object__DictComp = _make_expression_code_method("dictionary comprehension") _code_object__SetComp = _make_expression_code_method("set comprehension") _code_object__ListComp = _make_expression_code_method("list comprehension") # Code only used when dumping the AST for debugging. SKIP_DUMP_FIELDS = ["ctx"] def _is_simple_value(value: Any) -> bool: """Is `value` simple enough to be displayed on a single line?""" return ( value in [None, [], (), {}, set(), frozenset(), Ellipsis] or isinstance(value, (bytes, int, float, str)) ) def ast_dump( node: ast.AST, depth: int = 0, print: Callable[[str], None] = print, # pylint: disable=redefined-builtin ) -> None: """Dump the AST for `node`. This recursively walks the AST, printing a readable version. """ indent = " " * depth lineno = getattr(node, "lineno", None) if lineno is not None: linemark = f" @ {node.lineno},{node.col_offset}" if hasattr(node, "end_lineno"): assert hasattr(node, "end_col_offset") linemark += ":" if node.end_lineno != node.lineno: linemark += f"{node.end_lineno}," linemark += f"{node.end_col_offset}" else: linemark = "" head = f"{indent}<{node.__class__.__name__}{linemark}" named_fields = [ (name, value) for name, value in ast.iter_fields(node) if name not in SKIP_DUMP_FIELDS ] if not named_fields: print(f"{head}>") elif len(named_fields) == 1 and _is_simple_value(named_fields[0][1]): field_name, value = named_fields[0] print(f"{head} {field_name}: {value!r}>") else: print(head) if 0: print("{}# mro: {}".format( # type: ignore[unreachable] indent, ", ".join(c.__name__ for c in node.__class__.__mro__[1:]), )) next_indent = indent + " " for field_name, value in named_fields: prefix = f"{next_indent}{field_name}:" if _is_simple_value(value): print(f"{prefix} {value!r}") elif isinstance(value, list): print(f"{prefix} [") for n in value: if _is_simple_value(n): print(f"{next_indent} {n!r}") else: ast_dump(n, depth + 8, print=print) print(f"{next_indent}]") else: print(prefix) ast_dump(value, depth + 8, print=print) print(f"{indent}>")