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1 | # Copyright 2006 Google, Inc. All Rights Reserved. |
2 | # Licensed to PSF under a Contributor Agreement. | |
3 | ||
4 | """ | |
5 | Python parse tree definitions. | |
6 | ||
7 | This is a very concrete parse tree; we need to keep every token and | |
8 | even the comments and whitespace between tokens. | |
9 | ||
10 | There's also a pattern matching implementation here. | |
11 | """ | |
12 | ||
13 | # mypy: allow-untyped-defs, allow-incomplete-defs | |
14 | ||
15 | from typing import ( | |
16 | Any, | |
17 | Dict, | |
18 | Iterable, | |
19 | Iterator, | |
20 | List, | |
21 | Optional, | |
22 | Set, | |
23 | Tuple, | |
24 | TypeVar, | |
25 | Union, | |
26 | ) | |
27 | ||
28 | from blib2to3.pgen2.grammar import Grammar | |
29 | ||
30 | __author__ = "Guido van Rossum <guido@python.org>" | |
31 | ||
32 | import sys | |
33 | from io import StringIO | |
34 | ||
35 | HUGE: int = 0x7FFFFFFF # maximum repeat count, default max | |
36 | ||
37 | _type_reprs: Dict[int, Union[str, int]] = {} | |
38 | ||
39 | ||
40 | def type_repr(type_num: int) -> Union[str, int]: | |
41 | global _type_reprs | |
42 | if not _type_reprs: | |
43 | from .pygram import python_symbols | |
44 | ||
45 | # printing tokens is possible but not as useful | |
46 | # from .pgen2 import token // token.__dict__.items(): | |
47 | for name in dir(python_symbols): | |
48 | val = getattr(python_symbols, name) | |
49 | if type(val) == int: | |
50 | _type_reprs[val] = name | |
51 | return _type_reprs.setdefault(type_num, type_num) | |
52 | ||
53 | ||
54 | _P = TypeVar("_P", bound="Base") | |
55 | ||
56 | NL = Union["Node", "Leaf"] | |
57 | Context = Tuple[str, Tuple[int, int]] | |
58 | RawNode = Tuple[int, Optional[str], Optional[Context], Optional[List[NL]]] | |
59 | ||
60 | ||
61 | class Base: | |
62 | """ | |
63 | Abstract base class for Node and Leaf. | |
64 | ||
65 | This provides some default functionality and boilerplate using the | |
66 | template pattern. | |
67 | ||
68 | A node may be a subnode of at most one parent. | |
69 | """ | |
70 | ||
71 | # Default values for instance variables | |
72 | type: int # int: token number (< 256) or symbol number (>= 256) | |
73 | parent: Optional["Node"] = None # Parent node pointer, or None | |
74 | children: List[NL] # List of subnodes | |
75 | was_changed: bool = False | |
76 | was_checked: bool = False | |
77 | ||
78 | def __new__(cls, *args, **kwds): | |
79 | """Constructor that prevents Base from being instantiated.""" | |
80 | assert cls is not Base, "Cannot instantiate Base" | |
81 | return object.__new__(cls) | |
82 | ||
83 | def __eq__(self, other: Any) -> bool: | |
84 | """ | |
85 | Compare two nodes for equality. | |
86 | ||
87 | This calls the method _eq(). | |
88 | """ | |
89 | if self.__class__ is not other.__class__: | |
90 | return NotImplemented | |
91 | return self._eq(other) | |
92 | ||
93 | @property | |
94 | def prefix(self) -> str: | |
95 | raise NotImplementedError | |
96 | ||
97 | def _eq(self: _P, other: _P) -> bool: | |
98 | """ | |
99 | Compare two nodes for equality. | |
100 | ||
101 | This is called by __eq__ and __ne__. It is only called if the two nodes | |
102 | have the same type. This must be implemented by the concrete subclass. | |
103 | Nodes should be considered equal if they have the same structure, | |
104 | ignoring the prefix string and other context information. | |
105 | """ | |
106 | raise NotImplementedError | |
107 | ||
108 | def __deepcopy__(self: _P, memo: Any) -> _P: | |
109 | return self.clone() | |
110 | ||
111 | def clone(self: _P) -> _P: | |
112 | """ | |
113 | Return a cloned (deep) copy of self. | |
114 | ||
115 | This must be implemented by the concrete subclass. | |
116 | """ | |
117 | raise NotImplementedError | |
118 | ||
119 | def post_order(self) -> Iterator[NL]: | |
120 | """ | |
121 | Return a post-order iterator for the tree. | |
122 | ||
123 | This must be implemented by the concrete subclass. | |
124 | """ | |
125 | raise NotImplementedError | |
126 | ||
127 | def pre_order(self) -> Iterator[NL]: | |
128 | """ | |
129 | Return a pre-order iterator for the tree. | |
130 | ||
131 | This must be implemented by the concrete subclass. | |
132 | """ | |
133 | raise NotImplementedError | |
134 | ||
135 | def replace(self, new: Union[NL, List[NL]]) -> None: | |
136 | """Replace this node with a new one in the parent.""" | |
137 | assert self.parent is not None, str(self) | |
138 | assert new is not None | |
139 | if not isinstance(new, list): | |
140 | new = [new] | |
141 | l_children = [] | |
142 | found = False | |
143 | for ch in self.parent.children: | |
144 | if ch is self: | |
145 | assert not found, (self.parent.children, self, new) | |
146 | if new is not None: | |
147 | l_children.extend(new) | |
148 | found = True | |
149 | else: | |
150 | l_children.append(ch) | |
151 | assert found, (self.children, self, new) | |
152 | self.parent.children = l_children | |
153 | self.parent.changed() | |
154 | self.parent.invalidate_sibling_maps() | |
155 | for x in new: | |
156 | x.parent = self.parent | |
157 | self.parent = None | |
158 | ||
159 | def get_lineno(self) -> Optional[int]: | |
160 | """Return the line number which generated the invocant node.""" | |
161 | node = self | |
162 | while not isinstance(node, Leaf): | |
163 | if not node.children: | |
164 | return None | |
165 | node = node.children[0] | |
166 | return node.lineno | |
167 | ||
168 | def changed(self) -> None: | |
169 | if self.was_changed: | |
170 | return | |
171 | if self.parent: | |
172 | self.parent.changed() | |
173 | self.was_changed = True | |
174 | ||
175 | def remove(self) -> Optional[int]: | |
176 | """ | |
177 | Remove the node from the tree. Returns the position of the node in its | |
178 | parent's children before it was removed. | |
179 | """ | |
180 | if self.parent: | |
181 | for i, node in enumerate(self.parent.children): | |
182 | if node is self: | |
183 | del self.parent.children[i] | |
184 | self.parent.changed() | |
185 | self.parent.invalidate_sibling_maps() | |
186 | self.parent = None | |
187 | return i | |
188 | return None | |
189 | ||
190 | @property | |
191 | def next_sibling(self) -> Optional[NL]: | |
192 | """ | |
193 | The node immediately following the invocant in their parent's children | |
194 | list. If the invocant does not have a next sibling, it is None | |
195 | """ | |
196 | if self.parent is None: | |
197 | return None | |
198 | ||
199 | if self.parent.next_sibling_map is None: | |
200 | self.parent.update_sibling_maps() | |
201 | assert self.parent.next_sibling_map is not None | |
202 | return self.parent.next_sibling_map[id(self)] | |
203 | ||
204 | @property | |
205 | def prev_sibling(self) -> Optional[NL]: | |
206 | """ | |
207 | The node immediately preceding the invocant in their parent's children | |
208 | list. If the invocant does not have a previous sibling, it is None. | |
209 | """ | |
210 | if self.parent is None: | |
211 | return None | |
212 | ||
213 | if self.parent.prev_sibling_map is None: | |
214 | self.parent.update_sibling_maps() | |
215 | assert self.parent.prev_sibling_map is not None | |
216 | return self.parent.prev_sibling_map[id(self)] | |
217 | ||
218 | def leaves(self) -> Iterator["Leaf"]: | |
219 | for child in self.children: | |
220 | yield from child.leaves() | |
221 | ||
222 | def depth(self) -> int: | |
223 | if self.parent is None: | |
224 | return 0 | |
225 | return 1 + self.parent.depth() | |
226 | ||
227 | def get_suffix(self) -> str: | |
228 | """ | |
229 | Return the string immediately following the invocant node. This is | |
230 | effectively equivalent to node.next_sibling.prefix | |
231 | """ | |
232 | next_sib = self.next_sibling | |
233 | if next_sib is None: | |
234 | return "" | |
235 | prefix = next_sib.prefix | |
236 | return prefix | |
237 | ||
238 | ||
239 | class Node(Base): | |
240 | """Concrete implementation for interior nodes.""" | |
241 | ||
242 | fixers_applied: Optional[List[Any]] | |
243 | used_names: Optional[Set[str]] | |
244 | ||
245 | def __init__( | |
246 | self, | |
247 | type: int, | |
248 | children: List[NL], | |
249 | context: Optional[Any] = None, | |
250 | prefix: Optional[str] = None, | |
251 | fixers_applied: Optional[List[Any]] = None, | |
252 | ) -> None: | |
253 | """ | |
254 | Initializer. | |
255 | ||
256 | Takes a type constant (a symbol number >= 256), a sequence of | |
257 | child nodes, and an optional context keyword argument. | |
258 | ||
259 | As a side effect, the parent pointers of the children are updated. | |
260 | """ | |
261 | assert type >= 256, type | |
262 | self.type = type | |
263 | self.children = list(children) | |
264 | for ch in self.children: | |
265 | assert ch.parent is None, repr(ch) | |
266 | ch.parent = self | |
267 | self.invalidate_sibling_maps() | |
268 | if prefix is not None: | |
269 | self.prefix = prefix | |
270 | if fixers_applied: | |
271 | self.fixers_applied = fixers_applied[:] | |
272 | else: | |
273 | self.fixers_applied = None | |
274 | ||
275 | def __repr__(self) -> str: | |
276 | """Return a canonical string representation.""" | |
277 | assert self.type is not None | |
278 | return "{}({}, {!r})".format( | |
279 | self.__class__.__name__, | |
280 | type_repr(self.type), | |
281 | self.children, | |
282 | ) | |
283 | ||
284 | def __str__(self) -> str: | |
285 | """ | |
286 | Return a pretty string representation. | |
287 | ||
288 | This reproduces the input source exactly. | |
289 | """ | |
290 | return "".join(map(str, self.children)) | |
291 | ||
292 | def _eq(self, other: Base) -> bool: | |
293 | """Compare two nodes for equality.""" | |
294 | return (self.type, self.children) == (other.type, other.children) | |
295 | ||
296 | def clone(self) -> "Node": | |
297 | assert self.type is not None | |
298 | """Return a cloned (deep) copy of self.""" | |
299 | return Node( | |
300 | self.type, | |
301 | [ch.clone() for ch in self.children], | |
302 | fixers_applied=self.fixers_applied, | |
303 | ) | |
304 | ||
305 | def post_order(self) -> Iterator[NL]: | |
306 | """Return a post-order iterator for the tree.""" | |
307 | for child in self.children: | |
308 | yield from child.post_order() | |
309 | yield self | |
310 | ||
311 | def pre_order(self) -> Iterator[NL]: | |
312 | """Return a pre-order iterator for the tree.""" | |
313 | yield self | |
314 | for child in self.children: | |
315 | yield from child.pre_order() | |
316 | ||
317 | @property | |
318 | def prefix(self) -> str: | |
319 | """ | |
320 | The whitespace and comments preceding this node in the input. | |
321 | """ | |
322 | if not self.children: | |
323 | return "" | |
324 | return self.children[0].prefix | |
325 | ||
326 | @prefix.setter | |
327 | def prefix(self, prefix: str) -> None: | |
328 | if self.children: | |
329 | self.children[0].prefix = prefix | |
330 | ||
331 | def set_child(self, i: int, child: NL) -> None: | |
332 | """ | |
333 | Equivalent to 'node.children[i] = child'. This method also sets the | |
334 | child's parent attribute appropriately. | |
335 | """ | |
336 | child.parent = self | |
337 | self.children[i].parent = None | |
338 | self.children[i] = child | |
339 | self.changed() | |
340 | self.invalidate_sibling_maps() | |
341 | ||
342 | def insert_child(self, i: int, child: NL) -> None: | |
343 | """ | |
344 | Equivalent to 'node.children.insert(i, child)'. This method also sets | |
345 | the child's parent attribute appropriately. | |
346 | """ | |
347 | child.parent = self | |
348 | self.children.insert(i, child) | |
349 | self.changed() | |
350 | self.invalidate_sibling_maps() | |
351 | ||
352 | def append_child(self, child: NL) -> None: | |
353 | """ | |
354 | Equivalent to 'node.children.append(child)'. This method also sets the | |
355 | child's parent attribute appropriately. | |
356 | """ | |
357 | child.parent = self | |
358 | self.children.append(child) | |
359 | self.changed() | |
360 | self.invalidate_sibling_maps() | |
361 | ||
362 | def invalidate_sibling_maps(self) -> None: | |
363 | self.prev_sibling_map: Optional[Dict[int, Optional[NL]]] = None | |
364 | self.next_sibling_map: Optional[Dict[int, Optional[NL]]] = None | |
365 | ||
366 | def update_sibling_maps(self) -> None: | |
367 | _prev: Dict[int, Optional[NL]] = {} | |
368 | _next: Dict[int, Optional[NL]] = {} | |
369 | self.prev_sibling_map = _prev | |
370 | self.next_sibling_map = _next | |
371 | previous: Optional[NL] = None | |
372 | for current in self.children: | |
373 | _prev[id(current)] = previous | |
374 | _next[id(previous)] = current | |
375 | previous = current | |
376 | _next[id(current)] = None | |
377 | ||
378 | ||
379 | class Leaf(Base): | |
380 | """Concrete implementation for leaf nodes.""" | |
381 | ||
382 | # Default values for instance variables | |
383 | value: str | |
384 | fixers_applied: List[Any] | |
385 | bracket_depth: int | |
386 | # Changed later in brackets.py | |
387 | opening_bracket: Optional["Leaf"] = None | |
388 | used_names: Optional[Set[str]] | |
389 | _prefix = "" # Whitespace and comments preceding this token in the input | |
390 | lineno: int = 0 # Line where this token starts in the input | |
391 | column: int = 0 # Column where this token starts in the input | |
392 | # If not None, this Leaf is created by converting a block of fmt off/skip | |
393 | # code, and `fmt_pass_converted_first_leaf` points to the first Leaf in the | |
394 | # converted code. | |
395 | fmt_pass_converted_first_leaf: Optional["Leaf"] = None | |
396 | ||
397 | def __init__( | |
398 | self, | |
399 | type: int, | |
400 | value: str, | |
401 | context: Optional[Context] = None, | |
402 | prefix: Optional[str] = None, | |
403 | fixers_applied: List[Any] = [], | |
404 | opening_bracket: Optional["Leaf"] = None, | |
405 | fmt_pass_converted_first_leaf: Optional["Leaf"] = None, | |
406 | ) -> None: | |
407 | """ | |
408 | Initializer. | |
409 | ||
410 | Takes a type constant (a token number < 256), a string value, and an | |
411 | optional context keyword argument. | |
412 | """ | |
413 | ||
414 | assert 0 <= type < 256, type | |
415 | if context is not None: | |
416 | self._prefix, (self.lineno, self.column) = context | |
417 | self.type = type | |
418 | self.value = value | |
419 | if prefix is not None: | |
420 | self._prefix = prefix | |
421 | self.fixers_applied: Optional[List[Any]] = fixers_applied[:] | |
422 | self.children = [] | |
423 | self.opening_bracket = opening_bracket | |
424 | self.fmt_pass_converted_first_leaf = fmt_pass_converted_first_leaf | |
425 | ||
426 | def __repr__(self) -> str: | |
427 | """Return a canonical string representation.""" | |
428 | from .pgen2.token import tok_name | |
429 | ||
430 | assert self.type is not None | |
431 | return "{}({}, {!r})".format( | |
432 | self.__class__.__name__, | |
433 | tok_name.get(self.type, self.type), | |
434 | self.value, | |
435 | ) | |
436 | ||
437 | def __str__(self) -> str: | |
438 | """ | |
439 | Return a pretty string representation. | |
440 | ||
441 | This reproduces the input source exactly. | |
442 | """ | |
443 | return self._prefix + str(self.value) | |
444 | ||
445 | def _eq(self, other: "Leaf") -> bool: | |
446 | """Compare two nodes for equality.""" | |
447 | return (self.type, self.value) == (other.type, other.value) | |
448 | ||
449 | def clone(self) -> "Leaf": | |
450 | assert self.type is not None | |
451 | """Return a cloned (deep) copy of self.""" | |
452 | return Leaf( | |
453 | self.type, | |
454 | self.value, | |
455 | (self.prefix, (self.lineno, self.column)), | |
456 | fixers_applied=self.fixers_applied, | |
457 | ) | |
458 | ||
459 | def leaves(self) -> Iterator["Leaf"]: | |
460 | yield self | |
461 | ||
462 | def post_order(self) -> Iterator["Leaf"]: | |
463 | """Return a post-order iterator for the tree.""" | |
464 | yield self | |
465 | ||
466 | def pre_order(self) -> Iterator["Leaf"]: | |
467 | """Return a pre-order iterator for the tree.""" | |
468 | yield self | |
469 | ||
470 | @property | |
471 | def prefix(self) -> str: | |
472 | """ | |
473 | The whitespace and comments preceding this token in the input. | |
474 | """ | |
475 | return self._prefix | |
476 | ||
477 | @prefix.setter | |
478 | def prefix(self, prefix: str) -> None: | |
479 | self.changed() | |
480 | self._prefix = prefix | |
481 | ||
482 | ||
483 | def convert(gr: Grammar, raw_node: RawNode) -> NL: | |
484 | """ | |
485 | Convert raw node information to a Node or Leaf instance. | |
486 | ||
487 | This is passed to the parser driver which calls it whenever a reduction of a | |
488 | grammar rule produces a new complete node, so that the tree is build | |
489 | strictly bottom-up. | |
490 | """ | |
491 | type, value, context, children = raw_node | |
492 | if children or type in gr.number2symbol: | |
493 | # If there's exactly one child, return that child instead of | |
494 | # creating a new node. | |
495 | assert children is not None | |
496 | if len(children) == 1: | |
497 | return children[0] | |
498 | return Node(type, children, context=context) | |
499 | else: | |
500 | return Leaf(type, value or "", context=context) | |
501 | ||
502 | ||
503 | _Results = Dict[str, NL] | |
504 | ||
505 | ||
506 | class BasePattern: | |
507 | """ | |
508 | A pattern is a tree matching pattern. | |
509 | ||
510 | It looks for a specific node type (token or symbol), and | |
511 | optionally for a specific content. | |
512 | ||
513 | This is an abstract base class. There are three concrete | |
514 | subclasses: | |
515 | ||
516 | - LeafPattern matches a single leaf node; | |
517 | - NodePattern matches a single node (usually non-leaf); | |
518 | - WildcardPattern matches a sequence of nodes of variable length. | |
519 | """ | |
520 | ||
521 | # Defaults for instance variables | |
522 | type: Optional[int] | |
523 | type = None # Node type (token if < 256, symbol if >= 256) | |
524 | content: Any = None # Optional content matching pattern | |
525 | name: Optional[str] = None # Optional name used to store match in results dict | |
526 | ||
527 | def __new__(cls, *args, **kwds): | |
528 | """Constructor that prevents BasePattern from being instantiated.""" | |
529 | assert cls is not BasePattern, "Cannot instantiate BasePattern" | |
530 | return object.__new__(cls) | |
531 | ||
532 | def __repr__(self) -> str: | |
533 | assert self.type is not None | |
534 | args = [type_repr(self.type), self.content, self.name] | |
535 | while args and args[-1] is None: | |
536 | del args[-1] | |
537 | return "{}({})".format(self.__class__.__name__, ", ".join(map(repr, args))) | |
538 | ||
539 | def _submatch(self, node, results=None) -> bool: | |
540 | raise NotImplementedError | |
541 | ||
542 | def optimize(self) -> "BasePattern": | |
543 | """ | |
544 | A subclass can define this as a hook for optimizations. | |
545 | ||
546 | Returns either self or another node with the same effect. | |
547 | """ | |
548 | return self | |
549 | ||
550 | def match(self, node: NL, results: Optional[_Results] = None) -> bool: | |
551 | """ | |
552 | Does this pattern exactly match a node? | |
553 | ||
554 | Returns True if it matches, False if not. | |
555 | ||
556 | If results is not None, it must be a dict which will be | |
557 | updated with the nodes matching named subpatterns. | |
558 | ||
559 | Default implementation for non-wildcard patterns. | |
560 | """ | |
561 | if self.type is not None and node.type != self.type: | |
562 | return False | |
563 | if self.content is not None: | |
564 | r: Optional[_Results] = None | |
565 | if results is not None: | |
566 | r = {} | |
567 | if not self._submatch(node, r): | |
568 | return False | |
569 | if r: | |
570 | assert results is not None | |
571 | results.update(r) | |
572 | if results is not None and self.name: | |
573 | results[self.name] = node | |
574 | return True | |
575 | ||
576 | def match_seq(self, nodes: List[NL], results: Optional[_Results] = None) -> bool: | |
577 | """ | |
578 | Does this pattern exactly match a sequence of nodes? | |
579 | ||
580 | Default implementation for non-wildcard patterns. | |
581 | """ | |
582 | if len(nodes) != 1: | |
583 | return False | |
584 | return self.match(nodes[0], results) | |
585 | ||
586 | def generate_matches(self, nodes: List[NL]) -> Iterator[Tuple[int, _Results]]: | |
587 | """ | |
588 | Generator yielding all matches for this pattern. | |
589 | ||
590 | Default implementation for non-wildcard patterns. | |
591 | """ | |
592 | r: _Results = {} | |
593 | if nodes and self.match(nodes[0], r): | |
594 | yield 1, r | |
595 | ||
596 | ||
597 | class LeafPattern(BasePattern): | |
598 | def __init__( | |
599 | self, | |
600 | type: Optional[int] = None, | |
601 | content: Optional[str] = None, | |
602 | name: Optional[str] = None, | |
603 | ) -> None: | |
604 | """ | |
605 | Initializer. Takes optional type, content, and name. | |
606 | ||
607 | The type, if given must be a token type (< 256). If not given, | |
608 | this matches any *leaf* node; the content may still be required. | |
609 | ||
610 | The content, if given, must be a string. | |
611 | ||
612 | If a name is given, the matching node is stored in the results | |
613 | dict under that key. | |
614 | """ | |
615 | if type is not None: | |
616 | assert 0 <= type < 256, type | |
617 | if content is not None: | |
618 | assert isinstance(content, str), repr(content) | |
619 | self.type = type | |
620 | self.content = content | |
621 | self.name = name | |
622 | ||
623 | def match(self, node: NL, results=None) -> bool: | |
624 | """Override match() to insist on a leaf node.""" | |
625 | if not isinstance(node, Leaf): | |
626 | return False | |
627 | return BasePattern.match(self, node, results) | |
628 | ||
629 | def _submatch(self, node, results=None): | |
630 | """ | |
631 | Match the pattern's content to the node's children. | |
632 | ||
633 | This assumes the node type matches and self.content is not None. | |
634 | ||
635 | Returns True if it matches, False if not. | |
636 | ||
637 | If results is not None, it must be a dict which will be | |
638 | updated with the nodes matching named subpatterns. | |
639 | ||
640 | When returning False, the results dict may still be updated. | |
641 | """ | |
642 | return self.content == node.value | |
643 | ||
644 | ||
645 | class NodePattern(BasePattern): | |
646 | wildcards: bool = False | |
647 | ||
648 | def __init__( | |
649 | self, | |
650 | type: Optional[int] = None, | |
651 | content: Optional[Iterable[str]] = None, | |
652 | name: Optional[str] = None, | |
653 | ) -> None: | |
654 | """ | |
655 | Initializer. Takes optional type, content, and name. | |
656 | ||
657 | The type, if given, must be a symbol type (>= 256). If the | |
658 | type is None this matches *any* single node (leaf or not), | |
659 | except if content is not None, in which it only matches | |
660 | non-leaf nodes that also match the content pattern. | |
661 | ||
662 | The content, if not None, must be a sequence of Patterns that | |
663 | must match the node's children exactly. If the content is | |
664 | given, the type must not be None. | |
665 | ||
666 | If a name is given, the matching node is stored in the results | |
667 | dict under that key. | |
668 | """ | |
669 | if type is not None: | |
670 | assert type >= 256, type | |
671 | if content is not None: | |
672 | assert not isinstance(content, str), repr(content) | |
673 | newcontent = list(content) | |
674 | for i, item in enumerate(newcontent): | |
675 | assert isinstance(item, BasePattern), (i, item) | |
676 | # I don't even think this code is used anywhere, but it does cause | |
677 | # unreachable errors from mypy. This function's signature does look | |
678 | # odd though *shrug*. | |
679 | if isinstance(item, WildcardPattern): # type: ignore[unreachable] | |
680 | self.wildcards = True # type: ignore[unreachable] | |
681 | self.type = type | |
682 | self.content = newcontent # TODO: this is unbound when content is None | |
683 | self.name = name | |
684 | ||
685 | def _submatch(self, node, results=None) -> bool: | |
686 | """ | |
687 | Match the pattern's content to the node's children. | |
688 | ||
689 | This assumes the node type matches and self.content is not None. | |
690 | ||
691 | Returns True if it matches, False if not. | |
692 | ||
693 | If results is not None, it must be a dict which will be | |
694 | updated with the nodes matching named subpatterns. | |
695 | ||
696 | When returning False, the results dict may still be updated. | |
697 | """ | |
698 | if self.wildcards: | |
699 | for c, r in generate_matches(self.content, node.children): | |
700 | if c == len(node.children): | |
701 | if results is not None: | |
702 | results.update(r) | |
703 | return True | |
704 | return False | |
705 | if len(self.content) != len(node.children): | |
706 | return False | |
707 | for subpattern, child in zip(self.content, node.children): | |
708 | if not subpattern.match(child, results): | |
709 | return False | |
710 | return True | |
711 | ||
712 | ||
713 | class WildcardPattern(BasePattern): | |
714 | """ | |
715 | A wildcard pattern can match zero or more nodes. | |
716 | ||
717 | This has all the flexibility needed to implement patterns like: | |
718 | ||
719 | .* .+ .? .{m,n} | |
720 | (a b c | d e | f) | |
721 | (...)* (...)+ (...)? (...){m,n} | |
722 | ||
723 | except it always uses non-greedy matching. | |
724 | """ | |
725 | ||
726 | min: int | |
727 | max: int | |
728 | ||
729 | def __init__( | |
730 | self, | |
731 | content: Optional[str] = None, | |
732 | min: int = 0, | |
733 | max: int = HUGE, | |
734 | name: Optional[str] = None, | |
735 | ) -> None: | |
736 | """ | |
737 | Initializer. | |
738 | ||
739 | Args: | |
740 | content: optional sequence of subsequences of patterns; | |
741 | if absent, matches one node; | |
742 | if present, each subsequence is an alternative [*] | |
743 | min: optional minimum number of times to match, default 0 | |
744 | max: optional maximum number of times to match, default HUGE | |
745 | name: optional name assigned to this match | |
746 | ||
747 | [*] Thus, if content is [[a, b, c], [d, e], [f, g, h]] this is | |
748 | equivalent to (a b c | d e | f g h); if content is None, | |
749 | this is equivalent to '.' in regular expression terms. | |
750 | The min and max parameters work as follows: | |
751 | min=0, max=maxint: .* | |
752 | min=1, max=maxint: .+ | |
753 | min=0, max=1: .? | |
754 | min=1, max=1: . | |
755 | If content is not None, replace the dot with the parenthesized | |
756 | list of alternatives, e.g. (a b c | d e | f g h)* | |
757 | """ | |
758 | assert 0 <= min <= max <= HUGE, (min, max) | |
759 | if content is not None: | |
760 | f = lambda s: tuple(s) | |
761 | wrapped_content = tuple(map(f, content)) # Protect against alterations | |
762 | # Check sanity of alternatives | |
763 | assert len(wrapped_content), repr( | |
764 | wrapped_content | |
765 | ) # Can't have zero alternatives | |
766 | for alt in wrapped_content: | |
767 | assert len(alt), repr(alt) # Can have empty alternatives | |
768 | self.content = wrapped_content | |
769 | self.min = min | |
770 | self.max = max | |
771 | self.name = name | |
772 | ||
773 | def optimize(self) -> Any: | |
774 | """Optimize certain stacked wildcard patterns.""" | |
775 | subpattern = None | |
776 | if ( | |
777 | self.content is not None | |
778 | and len(self.content) == 1 | |
779 | and len(self.content[0]) == 1 | |
780 | ): | |
781 | subpattern = self.content[0][0] | |
782 | if self.min == 1 and self.max == 1: | |
783 | if self.content is None: | |
784 | return NodePattern(name=self.name) | |
785 | if subpattern is not None and self.name == subpattern.name: | |
786 | return subpattern.optimize() | |
787 | if ( | |
788 | self.min <= 1 | |
789 | and isinstance(subpattern, WildcardPattern) | |
790 | and subpattern.min <= 1 | |
791 | and self.name == subpattern.name | |
792 | ): | |
793 | return WildcardPattern( | |
794 | subpattern.content, | |
795 | self.min * subpattern.min, | |
796 | self.max * subpattern.max, | |
797 | subpattern.name, | |
798 | ) | |
799 | return self | |
800 | ||
801 | def match(self, node, results=None) -> bool: | |
802 | """Does this pattern exactly match a node?""" | |
803 | return self.match_seq([node], results) | |
804 | ||
805 | def match_seq(self, nodes, results=None) -> bool: | |
806 | """Does this pattern exactly match a sequence of nodes?""" | |
807 | for c, r in self.generate_matches(nodes): | |
808 | if c == len(nodes): | |
809 | if results is not None: | |
810 | results.update(r) | |
811 | if self.name: | |
812 | results[self.name] = list(nodes) | |
813 | return True | |
814 | return False | |
815 | ||
816 | def generate_matches(self, nodes) -> Iterator[Tuple[int, _Results]]: | |
817 | """ | |
818 | Generator yielding matches for a sequence of nodes. | |
819 | ||
820 | Args: | |
821 | nodes: sequence of nodes | |
822 | ||
823 | Yields: | |
824 | (count, results) tuples where: | |
825 | count: the match comprises nodes[:count]; | |
826 | results: dict containing named submatches. | |
827 | """ | |
828 | if self.content is None: | |
829 | # Shortcut for special case (see __init__.__doc__) | |
830 | for count in range(self.min, 1 + min(len(nodes), self.max)): | |
831 | r = {} | |
832 | if self.name: | |
833 | r[self.name] = nodes[:count] | |
834 | yield count, r | |
835 | elif self.name == "bare_name": | |
836 | yield self._bare_name_matches(nodes) | |
837 | else: | |
838 | # The reason for this is that hitting the recursion limit usually | |
839 | # results in some ugly messages about how RuntimeErrors are being | |
840 | # ignored. We only have to do this on CPython, though, because other | |
841 | # implementations don't have this nasty bug in the first place. | |
842 | if hasattr(sys, "getrefcount"): | |
843 | save_stderr = sys.stderr | |
844 | sys.stderr = StringIO() | |
845 | try: | |
846 | for count, r in self._recursive_matches(nodes, 0): | |
847 | if self.name: | |
848 | r[self.name] = nodes[:count] | |
849 | yield count, r | |
850 | except RuntimeError: | |
851 | # We fall back to the iterative pattern matching scheme if the recursive | |
852 | # scheme hits the recursion limit. | |
853 | for count, r in self._iterative_matches(nodes): | |
854 | if self.name: | |
855 | r[self.name] = nodes[:count] | |
856 | yield count, r | |
857 | finally: | |
858 | if hasattr(sys, "getrefcount"): | |
859 | sys.stderr = save_stderr | |
860 | ||
861 | def _iterative_matches(self, nodes) -> Iterator[Tuple[int, _Results]]: | |
862 | """Helper to iteratively yield the matches.""" | |
863 | nodelen = len(nodes) | |
864 | if 0 >= self.min: | |
865 | yield 0, {} | |
866 | ||
867 | results = [] | |
868 | # generate matches that use just one alt from self.content | |
869 | for alt in self.content: | |
870 | for c, r in generate_matches(alt, nodes): | |
871 | yield c, r | |
872 | results.append((c, r)) | |
873 | ||
874 | # for each match, iterate down the nodes | |
875 | while results: | |
876 | new_results = [] | |
877 | for c0, r0 in results: | |
878 | # stop if the entire set of nodes has been matched | |
879 | if c0 < nodelen and c0 <= self.max: | |
880 | for alt in self.content: | |
881 | for c1, r1 in generate_matches(alt, nodes[c0:]): | |
882 | if c1 > 0: | |
883 | r = {} | |
884 | r.update(r0) | |
885 | r.update(r1) | |
886 | yield c0 + c1, r | |
887 | new_results.append((c0 + c1, r)) | |
888 | results = new_results | |
889 | ||
890 | def _bare_name_matches(self, nodes) -> Tuple[int, _Results]: | |
891 | """Special optimized matcher for bare_name.""" | |
892 | count = 0 | |
893 | r = {} # type: _Results | |
894 | done = False | |
895 | max = len(nodes) | |
896 | while not done and count < max: | |
897 | done = True | |
898 | for leaf in self.content: | |
899 | if leaf[0].match(nodes[count], r): | |
900 | count += 1 | |
901 | done = False | |
902 | break | |
903 | assert self.name is not None | |
904 | r[self.name] = nodes[:count] | |
905 | return count, r | |
906 | ||
907 | def _recursive_matches(self, nodes, count) -> Iterator[Tuple[int, _Results]]: | |
908 | """Helper to recursively yield the matches.""" | |
909 | assert self.content is not None | |
910 | if count >= self.min: | |
911 | yield 0, {} | |
912 | if count < self.max: | |
913 | for alt in self.content: | |
914 | for c0, r0 in generate_matches(alt, nodes): | |
915 | for c1, r1 in self._recursive_matches(nodes[c0:], count + 1): | |
916 | r = {} | |
917 | r.update(r0) | |
918 | r.update(r1) | |
919 | yield c0 + c1, r | |
920 | ||
921 | ||
922 | class NegatedPattern(BasePattern): | |
923 | def __init__(self, content: Optional[BasePattern] = None) -> None: | |
924 | """ | |
925 | Initializer. | |
926 | ||
927 | The argument is either a pattern or None. If it is None, this | |
928 | only matches an empty sequence (effectively '$' in regex | |
929 | lingo). If it is not None, this matches whenever the argument | |
930 | pattern doesn't have any matches. | |
931 | """ | |
932 | if content is not None: | |
933 | assert isinstance(content, BasePattern), repr(content) | |
934 | self.content = content | |
935 | ||
936 | def match(self, node, results=None) -> bool: | |
937 | # We never match a node in its entirety | |
938 | return False | |
939 | ||
940 | def match_seq(self, nodes, results=None) -> bool: | |
941 | # We only match an empty sequence of nodes in its entirety | |
942 | return len(nodes) == 0 | |
943 | ||
944 | def generate_matches(self, nodes: List[NL]) -> Iterator[Tuple[int, _Results]]: | |
945 | if self.content is None: | |
946 | # Return a match if there is an empty sequence | |
947 | if len(nodes) == 0: | |
948 | yield 0, {} | |
949 | else: | |
950 | # Return a match if the argument pattern has no matches | |
951 | for c, r in self.content.generate_matches(nodes): | |
952 | return | |
953 | yield 0, {} | |
954 | ||
955 | ||
956 | def generate_matches( | |
957 | patterns: List[BasePattern], nodes: List[NL] | |
958 | ) -> Iterator[Tuple[int, _Results]]: | |
959 | """ | |
960 | Generator yielding matches for a sequence of patterns and nodes. | |
961 | ||
962 | Args: | |
963 | patterns: a sequence of patterns | |
964 | nodes: a sequence of nodes | |
965 | ||
966 | Yields: | |
967 | (count, results) tuples where: | |
968 | count: the entire sequence of patterns matches nodes[:count]; | |
969 | results: dict containing named submatches. | |
970 | """ | |
971 | if not patterns: | |
972 | yield 0, {} | |
973 | else: | |
974 | p, rest = patterns[0], patterns[1:] | |
975 | for c0, r0 in p.generate_matches(nodes): | |
976 | if not rest: | |
977 | yield c0, r0 | |
978 | else: | |
979 | for c1, r1 in generate_matches(rest, nodes[c0:]): | |
980 | r = {} | |
981 | r.update(r0) | |
982 | r.update(r1) | |
983 | yield c0 + c1, r |