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1 1 """Completion for IPython.
2 2
3 3 This module started as fork of the rlcompleter module in the Python standard
4 4 library. The original enhancements made to rlcompleter have been sent
5 5 upstream and were accepted as of Python 2.3,
6 6
7 7 This module now support a wide variety of completion mechanism both available
8 8 for normal classic Python code, as well as completer for IPython specific
9 9 Syntax like magics.
10 10
11 11 Latex and Unicode completion
12 12 ============================
13 13
14 14 IPython and compatible frontends not only can complete your code, but can help
15 15 you to input a wide range of characters. In particular we allow you to insert
16 16 a unicode character using the tab completion mechanism.
17 17
18 18 Forward latex/unicode completion
19 19 --------------------------------
20 20
21 21 Forward completion allows you to easily type a unicode character using its latex
22 22 name, or unicode long description. To do so type a backslash follow by the
23 23 relevant name and press tab:
24 24
25 25
26 26 Using latex completion:
27 27
28 28 .. code::
29 29
30 30 \\alpha<tab>
31 31 Ξ±
32 32
33 33 or using unicode completion:
34 34
35 35
36 36 .. code::
37 37
38 38 \\GREEK SMALL LETTER ALPHA<tab>
39 39 Ξ±
40 40
41 41
42 42 Only valid Python identifiers will complete. Combining characters (like arrow or
43 43 dots) are also available, unlike latex they need to be put after the their
44 44 counterpart that is to say, `F\\\\vec<tab>` is correct, not `\\\\vec<tab>F`.
45 45
46 46 Some browsers are known to display combining characters incorrectly.
47 47
48 48 Backward latex completion
49 49 -------------------------
50 50
51 51 It is sometime challenging to know how to type a character, if you are using
52 52 IPython, or any compatible frontend you can prepend backslash to the character
53 53 and press `<tab>` to expand it to its latex form.
54 54
55 55 .. code::
56 56
57 57 \\Ξ±<tab>
58 58 \\alpha
59 59
60 60
61 61 Both forward and backward completions can be deactivated by setting the
62 62 ``Completer.backslash_combining_completions`` option to ``False``.
63 63
64 64
65 65 Experimental
66 66 ============
67 67
68 68 Starting with IPython 6.0, this module can make use of the Jedi library to
69 69 generate completions both using static analysis of the code, and dynamically
70 70 inspecting multiple namespaces. Jedi is an autocompletion and static analysis
71 71 for Python. The APIs attached to this new mechanism is unstable and will
72 72 raise unless use in an :any:`provisionalcompleter` context manager.
73 73
74 74 You will find that the following are experimental:
75 75
76 76 - :any:`provisionalcompleter`
77 77 - :any:`IPCompleter.completions`
78 78 - :any:`Completion`
79 79 - :any:`rectify_completions`
80 80
81 81 .. note::
82 82
83 83 better name for :any:`rectify_completions` ?
84 84
85 85 We welcome any feedback on these new API, and we also encourage you to try this
86 86 module in debug mode (start IPython with ``--Completer.debug=True``) in order
87 87 to have extra logging information if :any:`jedi` is crashing, or if current
88 88 IPython completer pending deprecations are returning results not yet handled
89 89 by :any:`jedi`
90 90
91 91 Using Jedi for tab completion allow snippets like the following to work without
92 92 having to execute any code:
93 93
94 94 >>> myvar = ['hello', 42]
95 95 ... myvar[1].bi<tab>
96 96
97 97 Tab completion will be able to infer that ``myvar[1]`` is a real number without
98 98 executing any code unlike the previously available ``IPCompleter.greedy``
99 99 option.
100 100
101 101 Be sure to update :any:`jedi` to the latest stable version or to try the
102 102 current development version to get better completions.
103 103 """
104 104
105 105
106 106 # Copyright (c) IPython Development Team.
107 107 # Distributed under the terms of the Modified BSD License.
108 108 #
109 109 # Some of this code originated from rlcompleter in the Python standard library
110 110 # Copyright (C) 2001 Python Software Foundation, www.python.org
111 111
112 112
113 113 import builtins as builtin_mod
114 114 import glob
115 115 import inspect
116 116 import itertools
117 117 import keyword
118 118 import os
119 119 import re
120 120 import string
121 121 import sys
122 122 import time
123 123 import unicodedata
124 124 import uuid
125 125 import warnings
126 126 from contextlib import contextmanager
127 127 from importlib import import_module
128 128 from types import SimpleNamespace
129 129 from typing import Iterable, Iterator, List, Tuple, Union, Any, Sequence, Dict, NamedTuple, Pattern, Optional
130 130
131 131 from IPython.core.error import TryNext
132 132 from IPython.core.inputtransformer2 import ESC_MAGIC
133 133 from IPython.core.latex_symbols import latex_symbols, reverse_latex_symbol
134 134 from IPython.core.oinspect import InspectColors
135 135 from IPython.testing.skipdoctest import skip_doctest
136 136 from IPython.utils import generics
137 137 from IPython.utils.dir2 import dir2, get_real_method
138 138 from IPython.utils.path import ensure_dir_exists
139 139 from IPython.utils.process import arg_split
140 140 from traitlets import Bool, Enum, Int, List as ListTrait, Unicode, default, observe
141 141 from traitlets.config.configurable import Configurable
142 142
143 143 import __main__
144 144
145 145 # skip module docstests
146 146 __skip_doctest__ = True
147 147
148 148 try:
149 149 import jedi
150 150 jedi.settings.case_insensitive_completion = False
151 151 import jedi.api.helpers
152 152 import jedi.api.classes
153 153 JEDI_INSTALLED = True
154 154 except ImportError:
155 155 JEDI_INSTALLED = False
156 156 #-----------------------------------------------------------------------------
157 157 # Globals
158 158 #-----------------------------------------------------------------------------
159 159
160 160 # ranges where we have most of the valid unicode names. We could be more finer
161 161 # grained but is it worth it for performance While unicode have character in the
162 162 # range 0, 0x110000, we seem to have name for about 10% of those. (131808 as I
163 163 # write this). With below range we cover them all, with a density of ~67%
164 164 # biggest next gap we consider only adds up about 1% density and there are 600
165 165 # gaps that would need hard coding.
166 166 _UNICODE_RANGES = [(32, 0x3134b), (0xe0001, 0xe01f0)]
167 167
168 168 # Public API
169 169 __all__ = ['Completer','IPCompleter']
170 170
171 171 if sys.platform == 'win32':
172 172 PROTECTABLES = ' '
173 173 else:
174 174 PROTECTABLES = ' ()[]{}?=\\|;:\'#*"^&'
175 175
176 176 # Protect against returning an enormous number of completions which the frontend
177 177 # may have trouble processing.
178 178 MATCHES_LIMIT = 500
179 179
180 _deprecation_readline_sentinel = object()
180
181 class Sentinel:
182 def __repr__(self):
183 return "<deprecated sentinel>"
184
185
186 _deprecation_readline_sentinel = Sentinel()
181 187
182 188
183 189 class ProvisionalCompleterWarning(FutureWarning):
184 190 """
185 191 Exception raise by an experimental feature in this module.
186 192
187 193 Wrap code in :any:`provisionalcompleter` context manager if you
188 194 are certain you want to use an unstable feature.
189 195 """
190 196 pass
191 197
192 198 warnings.filterwarnings('error', category=ProvisionalCompleterWarning)
193 199
194 200
195 201 @skip_doctest
196 202 @contextmanager
197 203 def provisionalcompleter(action='ignore'):
198 204 """
199 205 This context manager has to be used in any place where unstable completer
200 206 behavior and API may be called.
201 207
202 208 >>> with provisionalcompleter():
203 209 ... completer.do_experimental_things() # works
204 210
205 211 >>> completer.do_experimental_things() # raises.
206 212
207 213 .. note::
208 214
209 215 Unstable
210 216
211 217 By using this context manager you agree that the API in use may change
212 218 without warning, and that you won't complain if they do so.
213 219
214 220 You also understand that, if the API is not to your liking, you should report
215 221 a bug to explain your use case upstream.
216 222
217 223 We'll be happy to get your feedback, feature requests, and improvements on
218 224 any of the unstable APIs!
219 225 """
220 226 with warnings.catch_warnings():
221 227 warnings.filterwarnings(action, category=ProvisionalCompleterWarning)
222 228 yield
223 229
224 230
225 231 def has_open_quotes(s):
226 232 """Return whether a string has open quotes.
227 233
228 234 This simply counts whether the number of quote characters of either type in
229 235 the string is odd.
230 236
231 237 Returns
232 238 -------
233 239 If there is an open quote, the quote character is returned. Else, return
234 240 False.
235 241 """
236 242 # We check " first, then ', so complex cases with nested quotes will get
237 243 # the " to take precedence.
238 244 if s.count('"') % 2:
239 245 return '"'
240 246 elif s.count("'") % 2:
241 247 return "'"
242 248 else:
243 249 return False
244 250
245 251
246 252 def protect_filename(s, protectables=PROTECTABLES):
247 253 """Escape a string to protect certain characters."""
248 254 if set(s) & set(protectables):
249 255 if sys.platform == "win32":
250 256 return '"' + s + '"'
251 257 else:
252 258 return "".join(("\\" + c if c in protectables else c) for c in s)
253 259 else:
254 260 return s
255 261
256 262
257 263 def expand_user(path:str) -> Tuple[str, bool, str]:
258 264 """Expand ``~``-style usernames in strings.
259 265
260 266 This is similar to :func:`os.path.expanduser`, but it computes and returns
261 267 extra information that will be useful if the input was being used in
262 268 computing completions, and you wish to return the completions with the
263 269 original '~' instead of its expanded value.
264 270
265 271 Parameters
266 272 ----------
267 273 path : str
268 274 String to be expanded. If no ~ is present, the output is the same as the
269 275 input.
270 276
271 277 Returns
272 278 -------
273 279 newpath : str
274 280 Result of ~ expansion in the input path.
275 281 tilde_expand : bool
276 282 Whether any expansion was performed or not.
277 283 tilde_val : str
278 284 The value that ~ was replaced with.
279 285 """
280 286 # Default values
281 287 tilde_expand = False
282 288 tilde_val = ''
283 289 newpath = path
284 290
285 291 if path.startswith('~'):
286 292 tilde_expand = True
287 293 rest = len(path)-1
288 294 newpath = os.path.expanduser(path)
289 295 if rest:
290 296 tilde_val = newpath[:-rest]
291 297 else:
292 298 tilde_val = newpath
293 299
294 300 return newpath, tilde_expand, tilde_val
295 301
296 302
297 303 def compress_user(path:str, tilde_expand:bool, tilde_val:str) -> str:
298 304 """Does the opposite of expand_user, with its outputs.
299 305 """
300 306 if tilde_expand:
301 307 return path.replace(tilde_val, '~')
302 308 else:
303 309 return path
304 310
305 311
306 312 def completions_sorting_key(word):
307 313 """key for sorting completions
308 314
309 315 This does several things:
310 316
311 317 - Demote any completions starting with underscores to the end
312 318 - Insert any %magic and %%cellmagic completions in the alphabetical order
313 319 by their name
314 320 """
315 321 prio1, prio2 = 0, 0
316 322
317 323 if word.startswith('__'):
318 324 prio1 = 2
319 325 elif word.startswith('_'):
320 326 prio1 = 1
321 327
322 328 if word.endswith('='):
323 329 prio1 = -1
324 330
325 331 if word.startswith('%%'):
326 332 # If there's another % in there, this is something else, so leave it alone
327 333 if not "%" in word[2:]:
328 334 word = word[2:]
329 335 prio2 = 2
330 336 elif word.startswith('%'):
331 337 if not "%" in word[1:]:
332 338 word = word[1:]
333 339 prio2 = 1
334 340
335 341 return prio1, word, prio2
336 342
337 343
338 344 class _FakeJediCompletion:
339 345 """
340 346 This is a workaround to communicate to the UI that Jedi has crashed and to
341 347 report a bug. Will be used only id :any:`IPCompleter.debug` is set to true.
342 348
343 349 Added in IPython 6.0 so should likely be removed for 7.0
344 350
345 351 """
346 352
347 353 def __init__(self, name):
348 354
349 355 self.name = name
350 356 self.complete = name
351 357 self.type = 'crashed'
352 358 self.name_with_symbols = name
353 359 self.signature = ''
354 360 self._origin = 'fake'
355 361
356 362 def __repr__(self):
357 363 return '<Fake completion object jedi has crashed>'
358 364
359 365
360 366 class Completion:
361 367 """
362 368 Completion object used and return by IPython completers.
363 369
364 370 .. warning::
365 371
366 372 Unstable
367 373
368 374 This function is unstable, API may change without warning.
369 375 It will also raise unless use in proper context manager.
370 376
371 377 This act as a middle ground :any:`Completion` object between the
372 378 :any:`jedi.api.classes.Completion` object and the Prompt Toolkit completion
373 379 object. While Jedi need a lot of information about evaluator and how the
374 380 code should be ran/inspected, PromptToolkit (and other frontend) mostly
375 381 need user facing information.
376 382
377 383 - Which range should be replaced replaced by what.
378 384 - Some metadata (like completion type), or meta information to displayed to
379 385 the use user.
380 386
381 387 For debugging purpose we can also store the origin of the completion (``jedi``,
382 388 ``IPython.python_matches``, ``IPython.magics_matches``...).
383 389 """
384 390
385 391 __slots__ = ['start', 'end', 'text', 'type', 'signature', '_origin']
386 392
387 393 def __init__(self, start: int, end: int, text: str, *, type: str=None, _origin='', signature='') -> None:
388 394 warnings.warn("``Completion`` is a provisional API (as of IPython 6.0). "
389 395 "It may change without warnings. "
390 396 "Use in corresponding context manager.",
391 397 category=ProvisionalCompleterWarning, stacklevel=2)
392 398
393 399 self.start = start
394 400 self.end = end
395 401 self.text = text
396 402 self.type = type
397 403 self.signature = signature
398 404 self._origin = _origin
399 405
400 406 def __repr__(self):
401 407 return '<Completion start=%s end=%s text=%r type=%r, signature=%r,>' % \
402 408 (self.start, self.end, self.text, self.type or '?', self.signature or '?')
403 409
404 410 def __eq__(self, other)->Bool:
405 411 """
406 412 Equality and hash do not hash the type (as some completer may not be
407 413 able to infer the type), but are use to (partially) de-duplicate
408 414 completion.
409 415
410 416 Completely de-duplicating completion is a bit tricker that just
411 417 comparing as it depends on surrounding text, which Completions are not
412 418 aware of.
413 419 """
414 420 return self.start == other.start and \
415 421 self.end == other.end and \
416 422 self.text == other.text
417 423
418 424 def __hash__(self):
419 425 return hash((self.start, self.end, self.text))
420 426
421 427
422 428 _IC = Iterable[Completion]
423 429
424 430
425 431 def _deduplicate_completions(text: str, completions: _IC)-> _IC:
426 432 """
427 433 Deduplicate a set of completions.
428 434
429 435 .. warning::
430 436
431 437 Unstable
432 438
433 439 This function is unstable, API may change without warning.
434 440
435 441 Parameters
436 442 ----------
437 443 text : str
438 444 text that should be completed.
439 445 completions : Iterator[Completion]
440 446 iterator over the completions to deduplicate
441 447
442 448 Yields
443 449 ------
444 450 `Completions` objects
445 451 Completions coming from multiple sources, may be different but end up having
446 452 the same effect when applied to ``text``. If this is the case, this will
447 453 consider completions as equal and only emit the first encountered.
448 454 Not folded in `completions()` yet for debugging purpose, and to detect when
449 455 the IPython completer does return things that Jedi does not, but should be
450 456 at some point.
451 457 """
452 458 completions = list(completions)
453 459 if not completions:
454 460 return
455 461
456 462 new_start = min(c.start for c in completions)
457 463 new_end = max(c.end for c in completions)
458 464
459 465 seen = set()
460 466 for c in completions:
461 467 new_text = text[new_start:c.start] + c.text + text[c.end:new_end]
462 468 if new_text not in seen:
463 469 yield c
464 470 seen.add(new_text)
465 471
466 472
467 473 def rectify_completions(text: str, completions: _IC, *, _debug=False)->_IC:
468 474 """
469 475 Rectify a set of completions to all have the same ``start`` and ``end``
470 476
471 477 .. warning::
472 478
473 479 Unstable
474 480
475 481 This function is unstable, API may change without warning.
476 482 It will also raise unless use in proper context manager.
477 483
478 484 Parameters
479 485 ----------
480 486 text : str
481 487 text that should be completed.
482 488 completions : Iterator[Completion]
483 489 iterator over the completions to rectify
484 490
485 491 Notes
486 492 -----
487 493 :any:`jedi.api.classes.Completion` s returned by Jedi may not have the same start and end, though
488 494 the Jupyter Protocol requires them to behave like so. This will readjust
489 495 the completion to have the same ``start`` and ``end`` by padding both
490 496 extremities with surrounding text.
491 497
492 498 During stabilisation should support a ``_debug`` option to log which
493 499 completion are return by the IPython completer and not found in Jedi in
494 500 order to make upstream bug report.
495 501 """
496 502 warnings.warn("`rectify_completions` is a provisional API (as of IPython 6.0). "
497 503 "It may change without warnings. "
498 504 "Use in corresponding context manager.",
499 505 category=ProvisionalCompleterWarning, stacklevel=2)
500 506
501 507 completions = list(completions)
502 508 if not completions:
503 509 return
504 510 starts = (c.start for c in completions)
505 511 ends = (c.end for c in completions)
506 512
507 513 new_start = min(starts)
508 514 new_end = max(ends)
509 515
510 516 seen_jedi = set()
511 517 seen_python_matches = set()
512 518 for c in completions:
513 519 new_text = text[new_start:c.start] + c.text + text[c.end:new_end]
514 520 if c._origin == 'jedi':
515 521 seen_jedi.add(new_text)
516 522 elif c._origin == 'IPCompleter.python_matches':
517 523 seen_python_matches.add(new_text)
518 524 yield Completion(new_start, new_end, new_text, type=c.type, _origin=c._origin, signature=c.signature)
519 525 diff = seen_python_matches.difference(seen_jedi)
520 526 if diff and _debug:
521 527 print('IPython.python matches have extras:', diff)
522 528
523 529
524 530 if sys.platform == 'win32':
525 531 DELIMS = ' \t\n`!@#$^&*()=+[{]}|;\'",<>?'
526 532 else:
527 533 DELIMS = ' \t\n`!@#$^&*()=+[{]}\\|;:\'",<>?'
528 534
529 535 GREEDY_DELIMS = ' =\r\n'
530 536
531 537
532 538 class CompletionSplitter(object):
533 539 """An object to split an input line in a manner similar to readline.
534 540
535 541 By having our own implementation, we can expose readline-like completion in
536 542 a uniform manner to all frontends. This object only needs to be given the
537 543 line of text to be split and the cursor position on said line, and it
538 544 returns the 'word' to be completed on at the cursor after splitting the
539 545 entire line.
540 546
541 547 What characters are used as splitting delimiters can be controlled by
542 548 setting the ``delims`` attribute (this is a property that internally
543 549 automatically builds the necessary regular expression)"""
544 550
545 551 # Private interface
546 552
547 553 # A string of delimiter characters. The default value makes sense for
548 554 # IPython's most typical usage patterns.
549 555 _delims = DELIMS
550 556
551 557 # The expression (a normal string) to be compiled into a regular expression
552 558 # for actual splitting. We store it as an attribute mostly for ease of
553 559 # debugging, since this type of code can be so tricky to debug.
554 560 _delim_expr = None
555 561
556 562 # The regular expression that does the actual splitting
557 563 _delim_re = None
558 564
559 565 def __init__(self, delims=None):
560 566 delims = CompletionSplitter._delims if delims is None else delims
561 567 self.delims = delims
562 568
563 569 @property
564 570 def delims(self):
565 571 """Return the string of delimiter characters."""
566 572 return self._delims
567 573
568 574 @delims.setter
569 575 def delims(self, delims):
570 576 """Set the delimiters for line splitting."""
571 577 expr = '[' + ''.join('\\'+ c for c in delims) + ']'
572 578 self._delim_re = re.compile(expr)
573 579 self._delims = delims
574 580 self._delim_expr = expr
575 581
576 582 def split_line(self, line, cursor_pos=None):
577 583 """Split a line of text with a cursor at the given position.
578 584 """
579 585 l = line if cursor_pos is None else line[:cursor_pos]
580 586 return self._delim_re.split(l)[-1]
581 587
582 588
583 589
584 590 class Completer(Configurable):
585 591
586 592 greedy = Bool(False,
587 593 help="""Activate greedy completion
588 594 PENDING DEPRECTION. this is now mostly taken care of with Jedi.
589 595
590 596 This will enable completion on elements of lists, results of function calls, etc.,
591 597 but can be unsafe because the code is actually evaluated on TAB.
592 598 """
593 599 ).tag(config=True)
594 600
595 601 use_jedi = Bool(default_value=JEDI_INSTALLED,
596 602 help="Experimental: Use Jedi to generate autocompletions. "
597 603 "Default to True if jedi is installed.").tag(config=True)
598 604
599 605 jedi_compute_type_timeout = Int(default_value=400,
600 606 help="""Experimental: restrict time (in milliseconds) during which Jedi can compute types.
601 607 Set to 0 to stop computing types. Non-zero value lower than 100ms may hurt
602 608 performance by preventing jedi to build its cache.
603 609 """).tag(config=True)
604 610
605 611 debug = Bool(default_value=False,
606 612 help='Enable debug for the Completer. Mostly print extra '
607 613 'information for experimental jedi integration.')\
608 614 .tag(config=True)
609 615
610 616 backslash_combining_completions = Bool(True,
611 617 help="Enable unicode completions, e.g. \\alpha<tab> . "
612 618 "Includes completion of latex commands, unicode names, and expanding "
613 619 "unicode characters back to latex commands.").tag(config=True)
614 620
615 621
616 622
617 623 def __init__(self, namespace=None, global_namespace=None, **kwargs):
618 624 """Create a new completer for the command line.
619 625
620 626 Completer(namespace=ns, global_namespace=ns2) -> completer instance.
621 627
622 628 If unspecified, the default namespace where completions are performed
623 629 is __main__ (technically, __main__.__dict__). Namespaces should be
624 630 given as dictionaries.
625 631
626 632 An optional second namespace can be given. This allows the completer
627 633 to handle cases where both the local and global scopes need to be
628 634 distinguished.
629 635 """
630 636
631 637 # Don't bind to namespace quite yet, but flag whether the user wants a
632 638 # specific namespace or to use __main__.__dict__. This will allow us
633 639 # to bind to __main__.__dict__ at completion time, not now.
634 640 if namespace is None:
635 641 self.use_main_ns = True
636 642 else:
637 643 self.use_main_ns = False
638 644 self.namespace = namespace
639 645
640 646 # The global namespace, if given, can be bound directly
641 647 if global_namespace is None:
642 648 self.global_namespace = {}
643 649 else:
644 650 self.global_namespace = global_namespace
645 651
646 652 self.custom_matchers = []
647 653
648 654 super(Completer, self).__init__(**kwargs)
649 655
650 656 def complete(self, text, state):
651 657 """Return the next possible completion for 'text'.
652 658
653 659 This is called successively with state == 0, 1, 2, ... until it
654 660 returns None. The completion should begin with 'text'.
655 661
656 662 """
657 663 if self.use_main_ns:
658 664 self.namespace = __main__.__dict__
659 665
660 666 if state == 0:
661 667 if "." in text:
662 668 self.matches = self.attr_matches(text)
663 669 else:
664 670 self.matches = self.global_matches(text)
665 671 try:
666 672 return self.matches[state]
667 673 except IndexError:
668 674 return None
669 675
670 676 def global_matches(self, text):
671 677 """Compute matches when text is a simple name.
672 678
673 679 Return a list of all keywords, built-in functions and names currently
674 680 defined in self.namespace or self.global_namespace that match.
675 681
676 682 """
677 683 matches = []
678 684 match_append = matches.append
679 685 n = len(text)
680 686 for lst in [keyword.kwlist,
681 687 builtin_mod.__dict__.keys(),
682 688 self.namespace.keys(),
683 689 self.global_namespace.keys()]:
684 690 for word in lst:
685 691 if word[:n] == text and word != "__builtins__":
686 692 match_append(word)
687 693
688 694 snake_case_re = re.compile(r"[^_]+(_[^_]+)+?\Z")
689 695 for lst in [self.namespace.keys(),
690 696 self.global_namespace.keys()]:
691 697 shortened = {"_".join([sub[0] for sub in word.split('_')]) : word
692 698 for word in lst if snake_case_re.match(word)}
693 699 for word in shortened.keys():
694 700 if word[:n] == text and word != "__builtins__":
695 701 match_append(shortened[word])
696 702 return matches
697 703
698 704 def attr_matches(self, text):
699 705 """Compute matches when text contains a dot.
700 706
701 707 Assuming the text is of the form NAME.NAME....[NAME], and is
702 708 evaluatable in self.namespace or self.global_namespace, it will be
703 709 evaluated and its attributes (as revealed by dir()) are used as
704 710 possible completions. (For class instances, class members are
705 711 also considered.)
706 712
707 713 WARNING: this can still invoke arbitrary C code, if an object
708 714 with a __getattr__ hook is evaluated.
709 715
710 716 """
711 717
712 718 # Another option, seems to work great. Catches things like ''.<tab>
713 719 m = re.match(r"(\S+(\.\w+)*)\.(\w*)$", text)
714 720
715 721 if m:
716 722 expr, attr = m.group(1, 3)
717 723 elif self.greedy:
718 724 m2 = re.match(r"(.+)\.(\w*)$", self.line_buffer)
719 725 if not m2:
720 726 return []
721 727 expr, attr = m2.group(1,2)
722 728 else:
723 729 return []
724 730
725 731 try:
726 732 obj = eval(expr, self.namespace)
727 733 except:
728 734 try:
729 735 obj = eval(expr, self.global_namespace)
730 736 except:
731 737 return []
732 738
733 739 if self.limit_to__all__ and hasattr(obj, '__all__'):
734 740 words = get__all__entries(obj)
735 741 else:
736 742 words = dir2(obj)
737 743
738 744 try:
739 745 words = generics.complete_object(obj, words)
740 746 except TryNext:
741 747 pass
742 748 except AssertionError:
743 749 raise
744 750 except Exception:
745 751 # Silence errors from completion function
746 752 #raise # dbg
747 753 pass
748 754 # Build match list to return
749 755 n = len(attr)
750 756 return [u"%s.%s" % (expr, w) for w in words if w[:n] == attr ]
751 757
752 758
753 759 def get__all__entries(obj):
754 760 """returns the strings in the __all__ attribute"""
755 761 try:
756 762 words = getattr(obj, '__all__')
757 763 except:
758 764 return []
759 765
760 766 return [w for w in words if isinstance(w, str)]
761 767
762 768
763 769 def match_dict_keys(keys: List[Union[str, bytes, Tuple[Union[str, bytes]]]], prefix: str, delims: str,
764 770 extra_prefix: Optional[Tuple[str, bytes]]=None) -> Tuple[str, int, List[str]]:
765 771 """Used by dict_key_matches, matching the prefix to a list of keys
766 772
767 773 Parameters
768 774 ----------
769 775 keys
770 776 list of keys in dictionary currently being completed.
771 777 prefix
772 778 Part of the text already typed by the user. E.g. `mydict[b'fo`
773 779 delims
774 780 String of delimiters to consider when finding the current key.
775 781 extra_prefix : optional
776 782 Part of the text already typed in multi-key index cases. E.g. for
777 783 `mydict['foo', "bar", 'b`, this would be `('foo', 'bar')`.
778 784
779 785 Returns
780 786 -------
781 787 A tuple of three elements: ``quote``, ``token_start``, ``matched``, with
782 788 ``quote`` being the quote that need to be used to close current string.
783 789 ``token_start`` the position where the replacement should start occurring,
784 790 ``matches`` a list of replacement/completion
785 791
786 792 """
787 793 prefix_tuple = extra_prefix if extra_prefix else ()
788 794 Nprefix = len(prefix_tuple)
789 795 def filter_prefix_tuple(key):
790 796 # Reject too short keys
791 797 if len(key) <= Nprefix:
792 798 return False
793 799 # Reject keys with non str/bytes in it
794 800 for k in key:
795 801 if not isinstance(k, (str, bytes)):
796 802 return False
797 803 # Reject keys that do not match the prefix
798 804 for k, pt in zip(key, prefix_tuple):
799 805 if k != pt:
800 806 return False
801 807 # All checks passed!
802 808 return True
803 809
804 810 filtered_keys:List[Union[str,bytes]] = []
805 811 def _add_to_filtered_keys(key):
806 812 if isinstance(key, (str, bytes)):
807 813 filtered_keys.append(key)
808 814
809 815 for k in keys:
810 816 if isinstance(k, tuple):
811 817 if filter_prefix_tuple(k):
812 818 _add_to_filtered_keys(k[Nprefix])
813 819 else:
814 820 _add_to_filtered_keys(k)
815 821
816 822 if not prefix:
817 823 return '', 0, [repr(k) for k in filtered_keys]
818 824 quote_match = re.search('["\']', prefix)
819 825 assert quote_match is not None # silence mypy
820 826 quote = quote_match.group()
821 827 try:
822 828 prefix_str = eval(prefix + quote, {})
823 829 except Exception:
824 830 return '', 0, []
825 831
826 832 pattern = '[^' + ''.join('\\' + c for c in delims) + ']*$'
827 833 token_match = re.search(pattern, prefix, re.UNICODE)
828 834 assert token_match is not None # silence mypy
829 835 token_start = token_match.start()
830 836 token_prefix = token_match.group()
831 837
832 838 matched:List[str] = []
833 839 for key in filtered_keys:
834 840 try:
835 841 if not key.startswith(prefix_str):
836 842 continue
837 843 except (AttributeError, TypeError, UnicodeError):
838 844 # Python 3+ TypeError on b'a'.startswith('a') or vice-versa
839 845 continue
840 846
841 847 # reformat remainder of key to begin with prefix
842 848 rem = key[len(prefix_str):]
843 849 # force repr wrapped in '
844 850 rem_repr = repr(rem + '"') if isinstance(rem, str) else repr(rem + b'"')
845 851 rem_repr = rem_repr[1 + rem_repr.index("'"):-2]
846 852 if quote == '"':
847 853 # The entered prefix is quoted with ",
848 854 # but the match is quoted with '.
849 855 # A contained " hence needs escaping for comparison:
850 856 rem_repr = rem_repr.replace('"', '\\"')
851 857
852 858 # then reinsert prefix from start of token
853 859 matched.append('%s%s' % (token_prefix, rem_repr))
854 860 return quote, token_start, matched
855 861
856 862
857 863 def cursor_to_position(text:str, line:int, column:int)->int:
858 864 """
859 865 Convert the (line,column) position of the cursor in text to an offset in a
860 866 string.
861 867
862 868 Parameters
863 869 ----------
864 870 text : str
865 871 The text in which to calculate the cursor offset
866 872 line : int
867 873 Line of the cursor; 0-indexed
868 874 column : int
869 875 Column of the cursor 0-indexed
870 876
871 877 Returns
872 878 -------
873 879 Position of the cursor in ``text``, 0-indexed.
874 880
875 881 See Also
876 882 --------
877 883 position_to_cursor : reciprocal of this function
878 884
879 885 """
880 886 lines = text.split('\n')
881 887 assert line <= len(lines), '{} <= {}'.format(str(line), str(len(lines)))
882 888
883 889 return sum(len(l) + 1 for l in lines[:line]) + column
884 890
885 891 def position_to_cursor(text:str, offset:int)->Tuple[int, int]:
886 892 """
887 893 Convert the position of the cursor in text (0 indexed) to a line
888 894 number(0-indexed) and a column number (0-indexed) pair
889 895
890 896 Position should be a valid position in ``text``.
891 897
892 898 Parameters
893 899 ----------
894 900 text : str
895 901 The text in which to calculate the cursor offset
896 902 offset : int
897 903 Position of the cursor in ``text``, 0-indexed.
898 904
899 905 Returns
900 906 -------
901 907 (line, column) : (int, int)
902 908 Line of the cursor; 0-indexed, column of the cursor 0-indexed
903 909
904 910 See Also
905 911 --------
906 912 cursor_to_position : reciprocal of this function
907 913
908 914 """
909 915
910 916 assert 0 <= offset <= len(text) , "0 <= %s <= %s" % (offset , len(text))
911 917
912 918 before = text[:offset]
913 919 blines = before.split('\n') # ! splitnes trim trailing \n
914 920 line = before.count('\n')
915 921 col = len(blines[-1])
916 922 return line, col
917 923
918 924
919 925 def _safe_isinstance(obj, module, class_name):
920 926 """Checks if obj is an instance of module.class_name if loaded
921 927 """
922 928 return (module in sys.modules and
923 929 isinstance(obj, getattr(import_module(module), class_name)))
924 930
925 931 def back_unicode_name_matches(text:str) -> Tuple[str, Sequence[str]]:
926 932 """Match Unicode characters back to Unicode name
927 933
928 934 This does ``β˜ƒ`` -> ``\\snowman``
929 935
930 936 Note that snowman is not a valid python3 combining character but will be expanded.
931 937 Though it will not recombine back to the snowman character by the completion machinery.
932 938
933 939 This will not either back-complete standard sequences like \\n, \\b ...
934 940
935 941 Returns
936 942 =======
937 943
938 944 Return a tuple with two elements:
939 945
940 946 - The Unicode character that was matched (preceded with a backslash), or
941 947 empty string,
942 948 - a sequence (of 1), name for the match Unicode character, preceded by
943 949 backslash, or empty if no match.
944 950
945 951 """
946 952 if len(text)<2:
947 953 return '', ()
948 954 maybe_slash = text[-2]
949 955 if maybe_slash != '\\':
950 956 return '', ()
951 957
952 958 char = text[-1]
953 959 # no expand on quote for completion in strings.
954 960 # nor backcomplete standard ascii keys
955 961 if char in string.ascii_letters or char in ('"',"'"):
956 962 return '', ()
957 963 try :
958 964 unic = unicodedata.name(char)
959 965 return '\\'+char,('\\'+unic,)
960 966 except KeyError:
961 967 pass
962 968 return '', ()
963 969
964 970 def back_latex_name_matches(text:str) -> Tuple[str, Sequence[str]] :
965 971 """Match latex characters back to unicode name
966 972
967 973 This does ``\\β„΅`` -> ``\\aleph``
968 974
969 975 """
970 976 if len(text)<2:
971 977 return '', ()
972 978 maybe_slash = text[-2]
973 979 if maybe_slash != '\\':
974 980 return '', ()
975 981
976 982
977 983 char = text[-1]
978 984 # no expand on quote for completion in strings.
979 985 # nor backcomplete standard ascii keys
980 986 if char in string.ascii_letters or char in ('"',"'"):
981 987 return '', ()
982 988 try :
983 989 latex = reverse_latex_symbol[char]
984 990 # '\\' replace the \ as well
985 991 return '\\'+char,[latex]
986 992 except KeyError:
987 993 pass
988 994 return '', ()
989 995
990 996
991 997 def _formatparamchildren(parameter) -> str:
992 998 """
993 999 Get parameter name and value from Jedi Private API
994 1000
995 1001 Jedi does not expose a simple way to get `param=value` from its API.
996 1002
997 1003 Parameters
998 1004 ----------
999 1005 parameter
1000 1006 Jedi's function `Param`
1001 1007
1002 1008 Returns
1003 1009 -------
1004 1010 A string like 'a', 'b=1', '*args', '**kwargs'
1005 1011
1006 1012 """
1007 1013 description = parameter.description
1008 1014 if not description.startswith('param '):
1009 1015 raise ValueError('Jedi function parameter description have change format.'
1010 1016 'Expected "param ...", found %r".' % description)
1011 1017 return description[6:]
1012 1018
1013 1019 def _make_signature(completion)-> str:
1014 1020 """
1015 1021 Make the signature from a jedi completion
1016 1022
1017 1023 Parameters
1018 1024 ----------
1019 1025 completion : jedi.Completion
1020 1026 object does not complete a function type
1021 1027
1022 1028 Returns
1023 1029 -------
1024 1030 a string consisting of the function signature, with the parenthesis but
1025 1031 without the function name. example:
1026 1032 `(a, *args, b=1, **kwargs)`
1027 1033
1028 1034 """
1029 1035
1030 1036 # it looks like this might work on jedi 0.17
1031 1037 if hasattr(completion, 'get_signatures'):
1032 1038 signatures = completion.get_signatures()
1033 1039 if not signatures:
1034 1040 return '(?)'
1035 1041
1036 1042 c0 = completion.get_signatures()[0]
1037 1043 return '('+c0.to_string().split('(', maxsplit=1)[1]
1038 1044
1039 1045 return '(%s)'% ', '.join([f for f in (_formatparamchildren(p) for signature in completion.get_signatures()
1040 1046 for p in signature.defined_names()) if f])
1041 1047
1042 1048
1043 1049 class _CompleteResult(NamedTuple):
1044 1050 matched_text : str
1045 1051 matches: Sequence[str]
1046 1052 matches_origin: Sequence[str]
1047 1053 jedi_matches: Any
1048 1054
1049 1055
1050 1056 class IPCompleter(Completer):
1051 1057 """Extension of the completer class with IPython-specific features"""
1052 1058
1053 1059 __dict_key_regexps: Optional[Dict[bool,Pattern]] = None
1054 1060
1055 1061 @observe('greedy')
1056 1062 def _greedy_changed(self, change):
1057 1063 """update the splitter and readline delims when greedy is changed"""
1058 1064 if change['new']:
1059 1065 self.splitter.delims = GREEDY_DELIMS
1060 1066 else:
1061 1067 self.splitter.delims = DELIMS
1062 1068
1063 1069 dict_keys_only = Bool(False,
1064 1070 help="""Whether to show dict key matches only""")
1065 1071
1066 1072 merge_completions = Bool(True,
1067 1073 help="""Whether to merge completion results into a single list
1068 1074
1069 1075 If False, only the completion results from the first non-empty
1070 1076 completer will be returned.
1071 1077 """
1072 1078 ).tag(config=True)
1073 1079 omit__names = Enum((0,1,2), default_value=2,
1074 1080 help="""Instruct the completer to omit private method names
1075 1081
1076 1082 Specifically, when completing on ``object.<tab>``.
1077 1083
1078 1084 When 2 [default]: all names that start with '_' will be excluded.
1079 1085
1080 1086 When 1: all 'magic' names (``__foo__``) will be excluded.
1081 1087
1082 1088 When 0: nothing will be excluded.
1083 1089 """
1084 1090 ).tag(config=True)
1085 1091 limit_to__all__ = Bool(False,
1086 1092 help="""
1087 1093 DEPRECATED as of version 5.0.
1088 1094
1089 1095 Instruct the completer to use __all__ for the completion
1090 1096
1091 1097 Specifically, when completing on ``object.<tab>``.
1092 1098
1093 1099 When True: only those names in obj.__all__ will be included.
1094 1100
1095 1101 When False [default]: the __all__ attribute is ignored
1096 1102 """,
1097 1103 ).tag(config=True)
1098 1104
1099 1105 profile_completions = Bool(
1100 1106 default_value=False,
1101 1107 help="If True, emit profiling data for completion subsystem using cProfile."
1102 1108 ).tag(config=True)
1103 1109
1104 1110 profiler_output_dir = Unicode(
1105 1111 default_value=".completion_profiles",
1106 1112 help="Template for path at which to output profile data for completions."
1107 1113 ).tag(config=True)
1108 1114
1109 1115 @observe('limit_to__all__')
1110 1116 def _limit_to_all_changed(self, change):
1111 1117 warnings.warn('`IPython.core.IPCompleter.limit_to__all__` configuration '
1112 1118 'value has been deprecated since IPython 5.0, will be made to have '
1113 1119 'no effects and then removed in future version of IPython.',
1114 1120 UserWarning)
1115 1121
1116 1122 def __init__(self, shell=None, namespace=None, global_namespace=None,
1117 1123 use_readline=_deprecation_readline_sentinel, config=None, **kwargs):
1118 1124 """IPCompleter() -> completer
1119 1125
1120 1126 Return a completer object.
1121 1127
1122 1128 Parameters
1123 1129 ----------
1124 1130 shell
1125 1131 a pointer to the ipython shell itself. This is needed
1126 1132 because this completer knows about magic functions, and those can
1127 1133 only be accessed via the ipython instance.
1128 1134 namespace : dict, optional
1129 1135 an optional dict where completions are performed.
1130 1136 global_namespace : dict, optional
1131 1137 secondary optional dict for completions, to
1132 1138 handle cases (such as IPython embedded inside functions) where
1133 1139 both Python scopes are visible.
1134 1140 use_readline : bool, optional
1135 1141 DEPRECATED, ignored since IPython 6.0, will have no effects
1136 1142 """
1137 1143
1138 1144 self.magic_escape = ESC_MAGIC
1139 1145 self.splitter = CompletionSplitter()
1140 1146
1141 1147 if use_readline is not _deprecation_readline_sentinel:
1142 1148 warnings.warn('The `use_readline` parameter is deprecated and ignored since IPython 6.0.',
1143 1149 DeprecationWarning, stacklevel=2)
1144 1150
1145 1151 # _greedy_changed() depends on splitter and readline being defined:
1146 1152 Completer.__init__(self, namespace=namespace, global_namespace=global_namespace,
1147 1153 config=config, **kwargs)
1148 1154
1149 1155 # List where completion matches will be stored
1150 1156 self.matches = []
1151 1157 self.shell = shell
1152 1158 # Regexp to split filenames with spaces in them
1153 1159 self.space_name_re = re.compile(r'([^\\] )')
1154 1160 # Hold a local ref. to glob.glob for speed
1155 1161 self.glob = glob.glob
1156 1162
1157 1163 # Determine if we are running on 'dumb' terminals, like (X)Emacs
1158 1164 # buffers, to avoid completion problems.
1159 1165 term = os.environ.get('TERM','xterm')
1160 1166 self.dumb_terminal = term in ['dumb','emacs']
1161 1167
1162 1168 # Special handling of backslashes needed in win32 platforms
1163 1169 if sys.platform == "win32":
1164 1170 self.clean_glob = self._clean_glob_win32
1165 1171 else:
1166 1172 self.clean_glob = self._clean_glob
1167 1173
1168 1174 #regexp to parse docstring for function signature
1169 1175 self.docstring_sig_re = re.compile(r'^[\w|\s.]+\(([^)]*)\).*')
1170 1176 self.docstring_kwd_re = re.compile(r'[\s|\[]*(\w+)(?:\s*=\s*.*)')
1171 1177 #use this if positional argument name is also needed
1172 1178 #= re.compile(r'[\s|\[]*(\w+)(?:\s*=?\s*.*)')
1173 1179
1174 1180 self.magic_arg_matchers = [
1175 1181 self.magic_config_matches,
1176 1182 self.magic_color_matches,
1177 1183 ]
1178 1184
1179 1185 # This is set externally by InteractiveShell
1180 1186 self.custom_completers = None
1181 1187
1182 1188 # This is a list of names of unicode characters that can be completed
1183 1189 # into their corresponding unicode value. The list is large, so we
1184 1190 # laziliy initialize it on first use. Consuming code should access this
1185 1191 # attribute through the `@unicode_names` property.
1186 1192 self._unicode_names = None
1187 1193
1188 1194 @property
1189 1195 def matchers(self) -> List[Any]:
1190 1196 """All active matcher routines for completion"""
1191 1197 if self.dict_keys_only:
1192 1198 return [self.dict_key_matches]
1193 1199
1194 1200 if self.use_jedi:
1195 1201 return [
1196 1202 *self.custom_matchers,
1197 1203 self.dict_key_matches,
1198 1204 self.file_matches,
1199 1205 self.magic_matches,
1200 1206 ]
1201 1207 else:
1202 1208 return [
1203 1209 *self.custom_matchers,
1204 1210 self.dict_key_matches,
1205 1211 self.python_matches,
1206 1212 self.file_matches,
1207 1213 self.magic_matches,
1208 1214 self.python_func_kw_matches,
1209 1215 ]
1210 1216
1211 1217 def all_completions(self, text:str) -> List[str]:
1212 1218 """
1213 1219 Wrapper around the completion methods for the benefit of emacs.
1214 1220 """
1215 1221 prefix = text.rpartition('.')[0]
1216 1222 with provisionalcompleter():
1217 1223 return ['.'.join([prefix, c.text]) if prefix and self.use_jedi else c.text
1218 1224 for c in self.completions(text, len(text))]
1219 1225
1220 1226 return self.complete(text)[1]
1221 1227
1222 1228 def _clean_glob(self, text:str):
1223 1229 return self.glob("%s*" % text)
1224 1230
1225 1231 def _clean_glob_win32(self, text:str):
1226 1232 return [f.replace("\\","/")
1227 1233 for f in self.glob("%s*" % text)]
1228 1234
1229 1235 def file_matches(self, text:str)->List[str]:
1230 1236 """Match filenames, expanding ~USER type strings.
1231 1237
1232 1238 Most of the seemingly convoluted logic in this completer is an
1233 1239 attempt to handle filenames with spaces in them. And yet it's not
1234 1240 quite perfect, because Python's readline doesn't expose all of the
1235 1241 GNU readline details needed for this to be done correctly.
1236 1242
1237 1243 For a filename with a space in it, the printed completions will be
1238 1244 only the parts after what's already been typed (instead of the
1239 1245 full completions, as is normally done). I don't think with the
1240 1246 current (as of Python 2.3) Python readline it's possible to do
1241 1247 better."""
1242 1248
1243 1249 # chars that require escaping with backslash - i.e. chars
1244 1250 # that readline treats incorrectly as delimiters, but we
1245 1251 # don't want to treat as delimiters in filename matching
1246 1252 # when escaped with backslash
1247 1253 if text.startswith('!'):
1248 1254 text = text[1:]
1249 1255 text_prefix = u'!'
1250 1256 else:
1251 1257 text_prefix = u''
1252 1258
1253 1259 text_until_cursor = self.text_until_cursor
1254 1260 # track strings with open quotes
1255 1261 open_quotes = has_open_quotes(text_until_cursor)
1256 1262
1257 1263 if '(' in text_until_cursor or '[' in text_until_cursor:
1258 1264 lsplit = text
1259 1265 else:
1260 1266 try:
1261 1267 # arg_split ~ shlex.split, but with unicode bugs fixed by us
1262 1268 lsplit = arg_split(text_until_cursor)[-1]
1263 1269 except ValueError:
1264 1270 # typically an unmatched ", or backslash without escaped char.
1265 1271 if open_quotes:
1266 1272 lsplit = text_until_cursor.split(open_quotes)[-1]
1267 1273 else:
1268 1274 return []
1269 1275 except IndexError:
1270 1276 # tab pressed on empty line
1271 1277 lsplit = ""
1272 1278
1273 1279 if not open_quotes and lsplit != protect_filename(lsplit):
1274 1280 # if protectables are found, do matching on the whole escaped name
1275 1281 has_protectables = True
1276 1282 text0,text = text,lsplit
1277 1283 else:
1278 1284 has_protectables = False
1279 1285 text = os.path.expanduser(text)
1280 1286
1281 1287 if text == "":
1282 1288 return [text_prefix + protect_filename(f) for f in self.glob("*")]
1283 1289
1284 1290 # Compute the matches from the filesystem
1285 1291 if sys.platform == 'win32':
1286 1292 m0 = self.clean_glob(text)
1287 1293 else:
1288 1294 m0 = self.clean_glob(text.replace('\\', ''))
1289 1295
1290 1296 if has_protectables:
1291 1297 # If we had protectables, we need to revert our changes to the
1292 1298 # beginning of filename so that we don't double-write the part
1293 1299 # of the filename we have so far
1294 1300 len_lsplit = len(lsplit)
1295 1301 matches = [text_prefix + text0 +
1296 1302 protect_filename(f[len_lsplit:]) for f in m0]
1297 1303 else:
1298 1304 if open_quotes:
1299 1305 # if we have a string with an open quote, we don't need to
1300 1306 # protect the names beyond the quote (and we _shouldn't_, as
1301 1307 # it would cause bugs when the filesystem call is made).
1302 1308 matches = m0 if sys.platform == "win32" else\
1303 1309 [protect_filename(f, open_quotes) for f in m0]
1304 1310 else:
1305 1311 matches = [text_prefix +
1306 1312 protect_filename(f) for f in m0]
1307 1313
1308 1314 # Mark directories in input list by appending '/' to their names.
1309 1315 return [x+'/' if os.path.isdir(x) else x for x in matches]
1310 1316
1311 1317 def magic_matches(self, text:str):
1312 1318 """Match magics"""
1313 1319 # Get all shell magics now rather than statically, so magics loaded at
1314 1320 # runtime show up too.
1315 1321 lsm = self.shell.magics_manager.lsmagic()
1316 1322 line_magics = lsm['line']
1317 1323 cell_magics = lsm['cell']
1318 1324 pre = self.magic_escape
1319 1325 pre2 = pre+pre
1320 1326
1321 1327 explicit_magic = text.startswith(pre)
1322 1328
1323 1329 # Completion logic:
1324 1330 # - user gives %%: only do cell magics
1325 1331 # - user gives %: do both line and cell magics
1326 1332 # - no prefix: do both
1327 1333 # In other words, line magics are skipped if the user gives %% explicitly
1328 1334 #
1329 1335 # We also exclude magics that match any currently visible names:
1330 1336 # https://github.com/ipython/ipython/issues/4877, unless the user has
1331 1337 # typed a %:
1332 1338 # https://github.com/ipython/ipython/issues/10754
1333 1339 bare_text = text.lstrip(pre)
1334 1340 global_matches = self.global_matches(bare_text)
1335 1341 if not explicit_magic:
1336 1342 def matches(magic):
1337 1343 """
1338 1344 Filter magics, in particular remove magics that match
1339 1345 a name present in global namespace.
1340 1346 """
1341 1347 return ( magic.startswith(bare_text) and
1342 1348 magic not in global_matches )
1343 1349 else:
1344 1350 def matches(magic):
1345 1351 return magic.startswith(bare_text)
1346 1352
1347 1353 comp = [ pre2+m for m in cell_magics if matches(m)]
1348 1354 if not text.startswith(pre2):
1349 1355 comp += [ pre+m for m in line_magics if matches(m)]
1350 1356
1351 1357 return comp
1352 1358
1353 1359 def magic_config_matches(self, text:str) -> List[str]:
1354 1360 """ Match class names and attributes for %config magic """
1355 1361 texts = text.strip().split()
1356 1362
1357 1363 if len(texts) > 0 and (texts[0] == 'config' or texts[0] == '%config'):
1358 1364 # get all configuration classes
1359 1365 classes = sorted(set([ c for c in self.shell.configurables
1360 1366 if c.__class__.class_traits(config=True)
1361 1367 ]), key=lambda x: x.__class__.__name__)
1362 1368 classnames = [ c.__class__.__name__ for c in classes ]
1363 1369
1364 1370 # return all classnames if config or %config is given
1365 1371 if len(texts) == 1:
1366 1372 return classnames
1367 1373
1368 1374 # match classname
1369 1375 classname_texts = texts[1].split('.')
1370 1376 classname = classname_texts[0]
1371 1377 classname_matches = [ c for c in classnames
1372 1378 if c.startswith(classname) ]
1373 1379
1374 1380 # return matched classes or the matched class with attributes
1375 1381 if texts[1].find('.') < 0:
1376 1382 return classname_matches
1377 1383 elif len(classname_matches) == 1 and \
1378 1384 classname_matches[0] == classname:
1379 1385 cls = classes[classnames.index(classname)].__class__
1380 1386 help = cls.class_get_help()
1381 1387 # strip leading '--' from cl-args:
1382 1388 help = re.sub(re.compile(r'^--', re.MULTILINE), '', help)
1383 1389 return [ attr.split('=')[0]
1384 1390 for attr in help.strip().splitlines()
1385 1391 if attr.startswith(texts[1]) ]
1386 1392 return []
1387 1393
1388 1394 def magic_color_matches(self, text:str) -> List[str] :
1389 1395 """ Match color schemes for %colors magic"""
1390 1396 texts = text.split()
1391 1397 if text.endswith(' '):
1392 1398 # .split() strips off the trailing whitespace. Add '' back
1393 1399 # so that: '%colors ' -> ['%colors', '']
1394 1400 texts.append('')
1395 1401
1396 1402 if len(texts) == 2 and (texts[0] == 'colors' or texts[0] == '%colors'):
1397 1403 prefix = texts[1]
1398 1404 return [ color for color in InspectColors.keys()
1399 1405 if color.startswith(prefix) ]
1400 1406 return []
1401 1407
1402 1408 def _jedi_matches(self, cursor_column:int, cursor_line:int, text:str) -> Iterable[Any]:
1403 1409 """
1404 1410 Return a list of :any:`jedi.api.Completions` object from a ``text`` and
1405 1411 cursor position.
1406 1412
1407 1413 Parameters
1408 1414 ----------
1409 1415 cursor_column : int
1410 1416 column position of the cursor in ``text``, 0-indexed.
1411 1417 cursor_line : int
1412 1418 line position of the cursor in ``text``, 0-indexed
1413 1419 text : str
1414 1420 text to complete
1415 1421
1416 1422 Notes
1417 1423 -----
1418 1424 If ``IPCompleter.debug`` is ``True`` may return a :any:`_FakeJediCompletion`
1419 1425 object containing a string with the Jedi debug information attached.
1420 1426 """
1421 1427 namespaces = [self.namespace]
1422 1428 if self.global_namespace is not None:
1423 1429 namespaces.append(self.global_namespace)
1424 1430
1425 1431 completion_filter = lambda x:x
1426 1432 offset = cursor_to_position(text, cursor_line, cursor_column)
1427 1433 # filter output if we are completing for object members
1428 1434 if offset:
1429 1435 pre = text[offset-1]
1430 1436 if pre == '.':
1431 1437 if self.omit__names == 2:
1432 1438 completion_filter = lambda c:not c.name.startswith('_')
1433 1439 elif self.omit__names == 1:
1434 1440 completion_filter = lambda c:not (c.name.startswith('__') and c.name.endswith('__'))
1435 1441 elif self.omit__names == 0:
1436 1442 completion_filter = lambda x:x
1437 1443 else:
1438 1444 raise ValueError("Don't understand self.omit__names == {}".format(self.omit__names))
1439 1445
1440 1446 interpreter = jedi.Interpreter(text[:offset], namespaces)
1441 1447 try_jedi = True
1442 1448
1443 1449 try:
1444 1450 # find the first token in the current tree -- if it is a ' or " then we are in a string
1445 1451 completing_string = False
1446 1452 try:
1447 1453 first_child = next(c for c in interpreter._get_module().tree_node.children if hasattr(c, 'value'))
1448 1454 except StopIteration:
1449 1455 pass
1450 1456 else:
1451 1457 # note the value may be ', ", or it may also be ''' or """, or
1452 1458 # in some cases, """what/you/typed..., but all of these are
1453 1459 # strings.
1454 1460 completing_string = len(first_child.value) > 0 and first_child.value[0] in {"'", '"'}
1455 1461
1456 1462 # if we are in a string jedi is likely not the right candidate for
1457 1463 # now. Skip it.
1458 1464 try_jedi = not completing_string
1459 1465 except Exception as e:
1460 1466 # many of things can go wrong, we are using private API just don't crash.
1461 1467 if self.debug:
1462 1468 print("Error detecting if completing a non-finished string :", e, '|')
1463 1469
1464 1470 if not try_jedi:
1465 1471 return []
1466 1472 try:
1467 1473 return filter(completion_filter, interpreter.complete(column=cursor_column, line=cursor_line + 1))
1468 1474 except Exception as e:
1469 1475 if self.debug:
1470 1476 return [_FakeJediCompletion('Oops Jedi has crashed, please report a bug with the following:\n"""\n%s\ns"""' % (e))]
1471 1477 else:
1472 1478 return []
1473 1479
1474 1480 def python_matches(self, text:str)->List[str]:
1475 1481 """Match attributes or global python names"""
1476 1482 if "." in text:
1477 1483 try:
1478 1484 matches = self.attr_matches(text)
1479 1485 if text.endswith('.') and self.omit__names:
1480 1486 if self.omit__names == 1:
1481 1487 # true if txt is _not_ a __ name, false otherwise:
1482 1488 no__name = (lambda txt:
1483 1489 re.match(r'.*\.__.*?__',txt) is None)
1484 1490 else:
1485 1491 # true if txt is _not_ a _ name, false otherwise:
1486 1492 no__name = (lambda txt:
1487 1493 re.match(r'\._.*?',txt[txt.rindex('.'):]) is None)
1488 1494 matches = filter(no__name, matches)
1489 1495 except NameError:
1490 1496 # catches <undefined attributes>.<tab>
1491 1497 matches = []
1492 1498 else:
1493 1499 matches = self.global_matches(text)
1494 1500 return matches
1495 1501
1496 1502 def _default_arguments_from_docstring(self, doc):
1497 1503 """Parse the first line of docstring for call signature.
1498 1504
1499 1505 Docstring should be of the form 'min(iterable[, key=func])\n'.
1500 1506 It can also parse cython docstring of the form
1501 1507 'Minuit.migrad(self, int ncall=10000, resume=True, int nsplit=1)'.
1502 1508 """
1503 1509 if doc is None:
1504 1510 return []
1505 1511
1506 1512 #care only the firstline
1507 1513 line = doc.lstrip().splitlines()[0]
1508 1514
1509 1515 #p = re.compile(r'^[\w|\s.]+\(([^)]*)\).*')
1510 1516 #'min(iterable[, key=func])\n' -> 'iterable[, key=func]'
1511 1517 sig = self.docstring_sig_re.search(line)
1512 1518 if sig is None:
1513 1519 return []
1514 1520 # iterable[, key=func]' -> ['iterable[' ,' key=func]']
1515 1521 sig = sig.groups()[0].split(',')
1516 1522 ret = []
1517 1523 for s in sig:
1518 1524 #re.compile(r'[\s|\[]*(\w+)(?:\s*=\s*.*)')
1519 1525 ret += self.docstring_kwd_re.findall(s)
1520 1526 return ret
1521 1527
1522 1528 def _default_arguments(self, obj):
1523 1529 """Return the list of default arguments of obj if it is callable,
1524 1530 or empty list otherwise."""
1525 1531 call_obj = obj
1526 1532 ret = []
1527 1533 if inspect.isbuiltin(obj):
1528 1534 pass
1529 1535 elif not (inspect.isfunction(obj) or inspect.ismethod(obj)):
1530 1536 if inspect.isclass(obj):
1531 1537 #for cython embedsignature=True the constructor docstring
1532 1538 #belongs to the object itself not __init__
1533 1539 ret += self._default_arguments_from_docstring(
1534 1540 getattr(obj, '__doc__', ''))
1535 1541 # for classes, check for __init__,__new__
1536 1542 call_obj = (getattr(obj, '__init__', None) or
1537 1543 getattr(obj, '__new__', None))
1538 1544 # for all others, check if they are __call__able
1539 1545 elif hasattr(obj, '__call__'):
1540 1546 call_obj = obj.__call__
1541 1547 ret += self._default_arguments_from_docstring(
1542 1548 getattr(call_obj, '__doc__', ''))
1543 1549
1544 1550 _keeps = (inspect.Parameter.KEYWORD_ONLY,
1545 1551 inspect.Parameter.POSITIONAL_OR_KEYWORD)
1546 1552
1547 1553 try:
1548 1554 sig = inspect.signature(obj)
1549 1555 ret.extend(k for k, v in sig.parameters.items() if
1550 1556 v.kind in _keeps)
1551 1557 except ValueError:
1552 1558 pass
1553 1559
1554 1560 return list(set(ret))
1555 1561
1556 1562 def python_func_kw_matches(self, text):
1557 1563 """Match named parameters (kwargs) of the last open function"""
1558 1564
1559 1565 if "." in text: # a parameter cannot be dotted
1560 1566 return []
1561 1567 try: regexp = self.__funcParamsRegex
1562 1568 except AttributeError:
1563 1569 regexp = self.__funcParamsRegex = re.compile(r'''
1564 1570 '.*?(?<!\\)' | # single quoted strings or
1565 1571 ".*?(?<!\\)" | # double quoted strings or
1566 1572 \w+ | # identifier
1567 1573 \S # other characters
1568 1574 ''', re.VERBOSE | re.DOTALL)
1569 1575 # 1. find the nearest identifier that comes before an unclosed
1570 1576 # parenthesis before the cursor
1571 1577 # e.g. for "foo (1+bar(x), pa<cursor>,a=1)", the candidate is "foo"
1572 1578 tokens = regexp.findall(self.text_until_cursor)
1573 1579 iterTokens = reversed(tokens); openPar = 0
1574 1580
1575 1581 for token in iterTokens:
1576 1582 if token == ')':
1577 1583 openPar -= 1
1578 1584 elif token == '(':
1579 1585 openPar += 1
1580 1586 if openPar > 0:
1581 1587 # found the last unclosed parenthesis
1582 1588 break
1583 1589 else:
1584 1590 return []
1585 1591 # 2. Concatenate dotted names ("foo.bar" for "foo.bar(x, pa" )
1586 1592 ids = []
1587 1593 isId = re.compile(r'\w+$').match
1588 1594
1589 1595 while True:
1590 1596 try:
1591 1597 ids.append(next(iterTokens))
1592 1598 if not isId(ids[-1]):
1593 1599 ids.pop(); break
1594 1600 if not next(iterTokens) == '.':
1595 1601 break
1596 1602 except StopIteration:
1597 1603 break
1598 1604
1599 1605 # Find all named arguments already assigned to, as to avoid suggesting
1600 1606 # them again
1601 1607 usedNamedArgs = set()
1602 1608 par_level = -1
1603 1609 for token, next_token in zip(tokens, tokens[1:]):
1604 1610 if token == '(':
1605 1611 par_level += 1
1606 1612 elif token == ')':
1607 1613 par_level -= 1
1608 1614
1609 1615 if par_level != 0:
1610 1616 continue
1611 1617
1612 1618 if next_token != '=':
1613 1619 continue
1614 1620
1615 1621 usedNamedArgs.add(token)
1616 1622
1617 1623 argMatches = []
1618 1624 try:
1619 1625 callableObj = '.'.join(ids[::-1])
1620 1626 namedArgs = self._default_arguments(eval(callableObj,
1621 1627 self.namespace))
1622 1628
1623 1629 # Remove used named arguments from the list, no need to show twice
1624 1630 for namedArg in set(namedArgs) - usedNamedArgs:
1625 1631 if namedArg.startswith(text):
1626 1632 argMatches.append("%s=" %namedArg)
1627 1633 except:
1628 1634 pass
1629 1635
1630 1636 return argMatches
1631 1637
1632 1638 @staticmethod
1633 1639 def _get_keys(obj: Any) -> List[Any]:
1634 1640 # Objects can define their own completions by defining an
1635 1641 # _ipy_key_completions_() method.
1636 1642 method = get_real_method(obj, '_ipython_key_completions_')
1637 1643 if method is not None:
1638 1644 return method()
1639 1645
1640 1646 # Special case some common in-memory dict-like types
1641 1647 if isinstance(obj, dict) or\
1642 1648 _safe_isinstance(obj, 'pandas', 'DataFrame'):
1643 1649 try:
1644 1650 return list(obj.keys())
1645 1651 except Exception:
1646 1652 return []
1647 1653 elif _safe_isinstance(obj, 'numpy', 'ndarray') or\
1648 1654 _safe_isinstance(obj, 'numpy', 'void'):
1649 1655 return obj.dtype.names or []
1650 1656 return []
1651 1657
1652 1658 def dict_key_matches(self, text:str) -> List[str]:
1653 1659 "Match string keys in a dictionary, after e.g. 'foo[' "
1654 1660
1655 1661
1656 1662 if self.__dict_key_regexps is not None:
1657 1663 regexps = self.__dict_key_regexps
1658 1664 else:
1659 1665 dict_key_re_fmt = r'''(?x)
1660 1666 ( # match dict-referring expression wrt greedy setting
1661 1667 %s
1662 1668 )
1663 1669 \[ # open bracket
1664 1670 \s* # and optional whitespace
1665 1671 # Capture any number of str-like objects (e.g. "a", "b", 'c')
1666 1672 ((?:[uUbB]? # string prefix (r not handled)
1667 1673 (?:
1668 1674 '(?:[^']|(?<!\\)\\')*'
1669 1675 |
1670 1676 "(?:[^"]|(?<!\\)\\")*"
1671 1677 )
1672 1678 \s*,\s*
1673 1679 )*)
1674 1680 ([uUbB]? # string prefix (r not handled)
1675 1681 (?: # unclosed string
1676 1682 '(?:[^']|(?<!\\)\\')*
1677 1683 |
1678 1684 "(?:[^"]|(?<!\\)\\")*
1679 1685 )
1680 1686 )?
1681 1687 $
1682 1688 '''
1683 1689 regexps = self.__dict_key_regexps = {
1684 1690 False: re.compile(dict_key_re_fmt % r'''
1685 1691 # identifiers separated by .
1686 1692 (?!\d)\w+
1687 1693 (?:\.(?!\d)\w+)*
1688 1694 '''),
1689 1695 True: re.compile(dict_key_re_fmt % '''
1690 1696 .+
1691 1697 ''')
1692 1698 }
1693 1699
1694 1700 match = regexps[self.greedy].search(self.text_until_cursor)
1695 1701
1696 1702 if match is None:
1697 1703 return []
1698 1704
1699 1705 expr, prefix0, prefix = match.groups()
1700 1706 try:
1701 1707 obj = eval(expr, self.namespace)
1702 1708 except Exception:
1703 1709 try:
1704 1710 obj = eval(expr, self.global_namespace)
1705 1711 except Exception:
1706 1712 return []
1707 1713
1708 1714 keys = self._get_keys(obj)
1709 1715 if not keys:
1710 1716 return keys
1711 1717
1712 1718 extra_prefix = eval(prefix0) if prefix0 != '' else None
1713 1719
1714 1720 closing_quote, token_offset, matches = match_dict_keys(keys, prefix, self.splitter.delims, extra_prefix=extra_prefix)
1715 1721 if not matches:
1716 1722 return matches
1717 1723
1718 1724 # get the cursor position of
1719 1725 # - the text being completed
1720 1726 # - the start of the key text
1721 1727 # - the start of the completion
1722 1728 text_start = len(self.text_until_cursor) - len(text)
1723 1729 if prefix:
1724 1730 key_start = match.start(3)
1725 1731 completion_start = key_start + token_offset
1726 1732 else:
1727 1733 key_start = completion_start = match.end()
1728 1734
1729 1735 # grab the leading prefix, to make sure all completions start with `text`
1730 1736 if text_start > key_start:
1731 1737 leading = ''
1732 1738 else:
1733 1739 leading = text[text_start:completion_start]
1734 1740
1735 1741 # the index of the `[` character
1736 1742 bracket_idx = match.end(1)
1737 1743
1738 1744 # append closing quote and bracket as appropriate
1739 1745 # this is *not* appropriate if the opening quote or bracket is outside
1740 1746 # the text given to this method
1741 1747 suf = ''
1742 1748 continuation = self.line_buffer[len(self.text_until_cursor):]
1743 1749 if key_start > text_start and closing_quote:
1744 1750 # quotes were opened inside text, maybe close them
1745 1751 if continuation.startswith(closing_quote):
1746 1752 continuation = continuation[len(closing_quote):]
1747 1753 else:
1748 1754 suf += closing_quote
1749 1755 if bracket_idx > text_start:
1750 1756 # brackets were opened inside text, maybe close them
1751 1757 if not continuation.startswith(']'):
1752 1758 suf += ']'
1753 1759
1754 1760 return [leading + k + suf for k in matches]
1755 1761
1756 1762 @staticmethod
1757 1763 def unicode_name_matches(text:str) -> Tuple[str, List[str]] :
1758 1764 """Match Latex-like syntax for unicode characters base
1759 1765 on the name of the character.
1760 1766
1761 1767 This does ``\\GREEK SMALL LETTER ETA`` -> ``Ξ·``
1762 1768
1763 1769 Works only on valid python 3 identifier, or on combining characters that
1764 1770 will combine to form a valid identifier.
1765 1771 """
1766 1772 slashpos = text.rfind('\\')
1767 1773 if slashpos > -1:
1768 1774 s = text[slashpos+1:]
1769 1775 try :
1770 1776 unic = unicodedata.lookup(s)
1771 1777 # allow combining chars
1772 1778 if ('a'+unic).isidentifier():
1773 1779 return '\\'+s,[unic]
1774 1780 except KeyError:
1775 1781 pass
1776 1782 return '', []
1777 1783
1778 1784
1779 1785 def latex_matches(self, text:str) -> Tuple[str, Sequence[str]]:
1780 1786 """Match Latex syntax for unicode characters.
1781 1787
1782 1788 This does both ``\\alp`` -> ``\\alpha`` and ``\\alpha`` -> ``Ξ±``
1783 1789 """
1784 1790 slashpos = text.rfind('\\')
1785 1791 if slashpos > -1:
1786 1792 s = text[slashpos:]
1787 1793 if s in latex_symbols:
1788 1794 # Try to complete a full latex symbol to unicode
1789 1795 # \\alpha -> Ξ±
1790 1796 return s, [latex_symbols[s]]
1791 1797 else:
1792 1798 # If a user has partially typed a latex symbol, give them
1793 1799 # a full list of options \al -> [\aleph, \alpha]
1794 1800 matches = [k for k in latex_symbols if k.startswith(s)]
1795 1801 if matches:
1796 1802 return s, matches
1797 1803 return '', ()
1798 1804
1799 1805 def dispatch_custom_completer(self, text):
1800 1806 if not self.custom_completers:
1801 1807 return
1802 1808
1803 1809 line = self.line_buffer
1804 1810 if not line.strip():
1805 1811 return None
1806 1812
1807 1813 # Create a little structure to pass all the relevant information about
1808 1814 # the current completion to any custom completer.
1809 1815 event = SimpleNamespace()
1810 1816 event.line = line
1811 1817 event.symbol = text
1812 1818 cmd = line.split(None,1)[0]
1813 1819 event.command = cmd
1814 1820 event.text_until_cursor = self.text_until_cursor
1815 1821
1816 1822 # for foo etc, try also to find completer for %foo
1817 1823 if not cmd.startswith(self.magic_escape):
1818 1824 try_magic = self.custom_completers.s_matches(
1819 1825 self.magic_escape + cmd)
1820 1826 else:
1821 1827 try_magic = []
1822 1828
1823 1829 for c in itertools.chain(self.custom_completers.s_matches(cmd),
1824 1830 try_magic,
1825 1831 self.custom_completers.flat_matches(self.text_until_cursor)):
1826 1832 try:
1827 1833 res = c(event)
1828 1834 if res:
1829 1835 # first, try case sensitive match
1830 1836 withcase = [r for r in res if r.startswith(text)]
1831 1837 if withcase:
1832 1838 return withcase
1833 1839 # if none, then case insensitive ones are ok too
1834 1840 text_low = text.lower()
1835 1841 return [r for r in res if r.lower().startswith(text_low)]
1836 1842 except TryNext:
1837 1843 pass
1838 1844 except KeyboardInterrupt:
1839 1845 """
1840 1846 If custom completer take too long,
1841 1847 let keyboard interrupt abort and return nothing.
1842 1848 """
1843 1849 break
1844 1850
1845 1851 return None
1846 1852
1847 1853 def completions(self, text: str, offset: int)->Iterator[Completion]:
1848 1854 """
1849 1855 Returns an iterator over the possible completions
1850 1856
1851 1857 .. warning::
1852 1858
1853 1859 Unstable
1854 1860
1855 1861 This function is unstable, API may change without warning.
1856 1862 It will also raise unless use in proper context manager.
1857 1863
1858 1864 Parameters
1859 1865 ----------
1860 1866 text : str
1861 1867 Full text of the current input, multi line string.
1862 1868 offset : int
1863 1869 Integer representing the position of the cursor in ``text``. Offset
1864 1870 is 0-based indexed.
1865 1871
1866 1872 Yields
1867 1873 ------
1868 1874 Completion
1869 1875
1870 1876 Notes
1871 1877 -----
1872 1878 The cursor on a text can either be seen as being "in between"
1873 1879 characters or "On" a character depending on the interface visible to
1874 1880 the user. For consistency the cursor being on "in between" characters X
1875 1881 and Y is equivalent to the cursor being "on" character Y, that is to say
1876 1882 the character the cursor is on is considered as being after the cursor.
1877 1883
1878 1884 Combining characters may span more that one position in the
1879 1885 text.
1880 1886
1881 1887 .. note::
1882 1888
1883 1889 If ``IPCompleter.debug`` is :any:`True` will yield a ``--jedi/ipython--``
1884 1890 fake Completion token to distinguish completion returned by Jedi
1885 1891 and usual IPython completion.
1886 1892
1887 1893 .. note::
1888 1894
1889 1895 Completions are not completely deduplicated yet. If identical
1890 1896 completions are coming from different sources this function does not
1891 1897 ensure that each completion object will only be present once.
1892 1898 """
1893 1899 warnings.warn("_complete is a provisional API (as of IPython 6.0). "
1894 1900 "It may change without warnings. "
1895 1901 "Use in corresponding context manager.",
1896 1902 category=ProvisionalCompleterWarning, stacklevel=2)
1897 1903
1898 1904 seen = set()
1899 1905 profiler:Optional[cProfile.Profile]
1900 1906 try:
1901 1907 if self.profile_completions:
1902 1908 import cProfile
1903 1909 profiler = cProfile.Profile()
1904 1910 profiler.enable()
1905 1911 else:
1906 1912 profiler = None
1907 1913
1908 1914 for c in self._completions(text, offset, _timeout=self.jedi_compute_type_timeout/1000):
1909 1915 if c and (c in seen):
1910 1916 continue
1911 1917 yield c
1912 1918 seen.add(c)
1913 1919 except KeyboardInterrupt:
1914 1920 """if completions take too long and users send keyboard interrupt,
1915 1921 do not crash and return ASAP. """
1916 1922 pass
1917 1923 finally:
1918 1924 if profiler is not None:
1919 1925 profiler.disable()
1920 1926 ensure_dir_exists(self.profiler_output_dir)
1921 1927 output_path = os.path.join(self.profiler_output_dir, str(uuid.uuid4()))
1922 1928 print("Writing profiler output to", output_path)
1923 1929 profiler.dump_stats(output_path)
1924 1930
1925 1931 def _completions(self, full_text: str, offset: int, *, _timeout) -> Iterator[Completion]:
1926 1932 """
1927 1933 Core completion module.Same signature as :any:`completions`, with the
1928 1934 extra `timeout` parameter (in seconds).
1929 1935
1930 1936 Computing jedi's completion ``.type`` can be quite expensive (it is a
1931 1937 lazy property) and can require some warm-up, more warm up than just
1932 1938 computing the ``name`` of a completion. The warm-up can be :
1933 1939
1934 1940 - Long warm-up the first time a module is encountered after
1935 1941 install/update: actually build parse/inference tree.
1936 1942
1937 1943 - first time the module is encountered in a session: load tree from
1938 1944 disk.
1939 1945
1940 1946 We don't want to block completions for tens of seconds so we give the
1941 1947 completer a "budget" of ``_timeout`` seconds per invocation to compute
1942 1948 completions types, the completions that have not yet been computed will
1943 1949 be marked as "unknown" an will have a chance to be computed next round
1944 1950 are things get cached.
1945 1951
1946 1952 Keep in mind that Jedi is not the only thing treating the completion so
1947 1953 keep the timeout short-ish as if we take more than 0.3 second we still
1948 1954 have lots of processing to do.
1949 1955
1950 1956 """
1951 1957 deadline = time.monotonic() + _timeout
1952 1958
1953 1959
1954 1960 before = full_text[:offset]
1955 1961 cursor_line, cursor_column = position_to_cursor(full_text, offset)
1956 1962
1957 1963 matched_text, matches, matches_origin, jedi_matches = self._complete(
1958 1964 full_text=full_text, cursor_line=cursor_line, cursor_pos=cursor_column)
1959 1965
1960 1966 iter_jm = iter(jedi_matches)
1961 1967 if _timeout:
1962 1968 for jm in iter_jm:
1963 1969 try:
1964 1970 type_ = jm.type
1965 1971 except Exception:
1966 1972 if self.debug:
1967 1973 print("Error in Jedi getting type of ", jm)
1968 1974 type_ = None
1969 1975 delta = len(jm.name_with_symbols) - len(jm.complete)
1970 1976 if type_ == 'function':
1971 1977 signature = _make_signature(jm)
1972 1978 else:
1973 1979 signature = ''
1974 1980 yield Completion(start=offset - delta,
1975 1981 end=offset,
1976 1982 text=jm.name_with_symbols,
1977 1983 type=type_,
1978 1984 signature=signature,
1979 1985 _origin='jedi')
1980 1986
1981 1987 if time.monotonic() > deadline:
1982 1988 break
1983 1989
1984 1990 for jm in iter_jm:
1985 1991 delta = len(jm.name_with_symbols) - len(jm.complete)
1986 1992 yield Completion(start=offset - delta,
1987 1993 end=offset,
1988 1994 text=jm.name_with_symbols,
1989 1995 type='<unknown>', # don't compute type for speed
1990 1996 _origin='jedi',
1991 1997 signature='')
1992 1998
1993 1999
1994 2000 start_offset = before.rfind(matched_text)
1995 2001
1996 2002 # TODO:
1997 2003 # Suppress this, right now just for debug.
1998 2004 if jedi_matches and matches and self.debug:
1999 2005 yield Completion(start=start_offset, end=offset, text='--jedi/ipython--',
2000 2006 _origin='debug', type='none', signature='')
2001 2007
2002 2008 # I'm unsure if this is always true, so let's assert and see if it
2003 2009 # crash
2004 2010 assert before.endswith(matched_text)
2005 2011 for m, t in zip(matches, matches_origin):
2006 2012 yield Completion(start=start_offset, end=offset, text=m, _origin=t, signature='', type='<unknown>')
2007 2013
2008 2014
2009 2015 def complete(self, text=None, line_buffer=None, cursor_pos=None) -> Tuple[str, Sequence[str]]:
2010 2016 """Find completions for the given text and line context.
2011 2017
2012 2018 Note that both the text and the line_buffer are optional, but at least
2013 2019 one of them must be given.
2014 2020
2015 2021 Parameters
2016 2022 ----------
2017 2023 text : string, optional
2018 2024 Text to perform the completion on. If not given, the line buffer
2019 2025 is split using the instance's CompletionSplitter object.
2020 2026 line_buffer : string, optional
2021 2027 If not given, the completer attempts to obtain the current line
2022 2028 buffer via readline. This keyword allows clients which are
2023 2029 requesting for text completions in non-readline contexts to inform
2024 2030 the completer of the entire text.
2025 2031 cursor_pos : int, optional
2026 2032 Index of the cursor in the full line buffer. Should be provided by
2027 2033 remote frontends where kernel has no access to frontend state.
2028 2034
2029 2035 Returns
2030 2036 -------
2031 2037 Tuple of two items:
2032 2038 text : str
2033 2039 Text that was actually used in the completion.
2034 2040 matches : list
2035 2041 A list of completion matches.
2036 2042
2037 2043 Notes
2038 2044 -----
2039 2045 This API is likely to be deprecated and replaced by
2040 2046 :any:`IPCompleter.completions` in the future.
2041 2047
2042 2048 """
2043 2049 warnings.warn('`Completer.complete` is pending deprecation since '
2044 2050 'IPython 6.0 and will be replaced by `Completer.completions`.',
2045 2051 PendingDeprecationWarning)
2046 2052 # potential todo, FOLD the 3rd throw away argument of _complete
2047 2053 # into the first 2 one.
2048 2054 return self._complete(line_buffer=line_buffer, cursor_pos=cursor_pos, text=text, cursor_line=0)[:2]
2049 2055
2050 2056 def _complete(self, *, cursor_line, cursor_pos, line_buffer=None, text=None,
2051 2057 full_text=None) -> _CompleteResult:
2052 2058 """
2053 2059 Like complete but can also returns raw jedi completions as well as the
2054 2060 origin of the completion text. This could (and should) be made much
2055 2061 cleaner but that will be simpler once we drop the old (and stateful)
2056 2062 :any:`complete` API.
2057 2063
2058 2064 With current provisional API, cursor_pos act both (depending on the
2059 2065 caller) as the offset in the ``text`` or ``line_buffer``, or as the
2060 2066 ``column`` when passing multiline strings this could/should be renamed
2061 2067 but would add extra noise.
2062 2068
2063 2069 Parameters
2064 2070 ----------
2065 2071 cursor_line :
2066 2072 Index of the line the cursor is on. 0 indexed.
2067 2073 cursor_pos :
2068 2074 Position of the cursor in the current line/line_buffer/text. 0
2069 2075 indexed.
2070 2076 line_buffer : optional, str
2071 2077 The current line the cursor is in, this is mostly due to legacy
2072 2078 reason that readline coudl only give a us the single current line.
2073 2079 Prefer `full_text`.
2074 2080 text : str
2075 2081 The current "token" the cursor is in, mostly also for historical
2076 2082 reasons. as the completer would trigger only after the current line
2077 2083 was parsed.
2078 2084 full_text : str
2079 2085 Full text of the current cell.
2080 2086
2081 2087 Returns
2082 2088 -------
2083 2089 A tuple of N elements which are (likely):
2084 2090 matched_text: ? the text that the complete matched
2085 2091 matches: list of completions ?
2086 2092 matches_origin: ? list same length as matches, and where each completion came from
2087 2093 jedi_matches: list of Jedi matches, have it's own structure.
2088 2094 """
2089 2095
2090 2096
2091 2097 # if the cursor position isn't given, the only sane assumption we can
2092 2098 # make is that it's at the end of the line (the common case)
2093 2099 if cursor_pos is None:
2094 2100 cursor_pos = len(line_buffer) if text is None else len(text)
2095 2101
2096 2102 if self.use_main_ns:
2097 2103 self.namespace = __main__.__dict__
2098 2104
2099 2105 # if text is either None or an empty string, rely on the line buffer
2100 2106 if (not line_buffer) and full_text:
2101 2107 line_buffer = full_text.split('\n')[cursor_line]
2102 2108 if not text: # issue #11508: check line_buffer before calling split_line
2103 2109 text = self.splitter.split_line(line_buffer, cursor_pos) if line_buffer else ''
2104 2110
2105 2111 if self.backslash_combining_completions:
2106 2112 # allow deactivation of these on windows.
2107 2113 base_text = text if not line_buffer else line_buffer[:cursor_pos]
2108 2114
2109 2115 for meth in (self.latex_matches,
2110 2116 self.unicode_name_matches,
2111 2117 back_latex_name_matches,
2112 2118 back_unicode_name_matches,
2113 2119 self.fwd_unicode_match):
2114 2120 name_text, name_matches = meth(base_text)
2115 2121 if name_text:
2116 2122 return _CompleteResult(name_text, name_matches[:MATCHES_LIMIT], \
2117 2123 [meth.__qualname__]*min(len(name_matches), MATCHES_LIMIT), ())
2118 2124
2119 2125
2120 2126 # If no line buffer is given, assume the input text is all there was
2121 2127 if line_buffer is None:
2122 2128 line_buffer = text
2123 2129
2124 2130 self.line_buffer = line_buffer
2125 2131 self.text_until_cursor = self.line_buffer[:cursor_pos]
2126 2132
2127 2133 # Do magic arg matches
2128 2134 for matcher in self.magic_arg_matchers:
2129 2135 matches = list(matcher(line_buffer))[:MATCHES_LIMIT]
2130 2136 if matches:
2131 2137 origins = [matcher.__qualname__] * len(matches)
2132 2138 return _CompleteResult(text, matches, origins, ())
2133 2139
2134 2140 # Start with a clean slate of completions
2135 2141 matches = []
2136 2142
2137 2143 # FIXME: we should extend our api to return a dict with completions for
2138 2144 # different types of objects. The rlcomplete() method could then
2139 2145 # simply collapse the dict into a list for readline, but we'd have
2140 2146 # richer completion semantics in other environments.
2141 2147 completions:Iterable[Any] = []
2142 2148 if self.use_jedi:
2143 2149 if not full_text:
2144 2150 full_text = line_buffer
2145 2151 completions = self._jedi_matches(
2146 2152 cursor_pos, cursor_line, full_text)
2147 2153
2148 2154 if self.merge_completions:
2149 2155 matches = []
2150 2156 for matcher in self.matchers:
2151 2157 try:
2152 2158 matches.extend([(m, matcher.__qualname__)
2153 2159 for m in matcher(text)])
2154 2160 except:
2155 2161 # Show the ugly traceback if the matcher causes an
2156 2162 # exception, but do NOT crash the kernel!
2157 2163 sys.excepthook(*sys.exc_info())
2158 2164 else:
2159 2165 for matcher in self.matchers:
2160 2166 matches = [(m, matcher.__qualname__)
2161 2167 for m in matcher(text)]
2162 2168 if matches:
2163 2169 break
2164 2170
2165 2171 seen = set()
2166 2172 filtered_matches = set()
2167 2173 for m in matches:
2168 2174 t, c = m
2169 2175 if t not in seen:
2170 2176 filtered_matches.add(m)
2171 2177 seen.add(t)
2172 2178
2173 2179 _filtered_matches = sorted(filtered_matches, key=lambda x: completions_sorting_key(x[0]))
2174 2180
2175 2181 custom_res = [(m, 'custom') for m in self.dispatch_custom_completer(text) or []]
2176 2182
2177 2183 _filtered_matches = custom_res or _filtered_matches
2178 2184
2179 2185 _filtered_matches = _filtered_matches[:MATCHES_LIMIT]
2180 2186 _matches = [m[0] for m in _filtered_matches]
2181 2187 origins = [m[1] for m in _filtered_matches]
2182 2188
2183 2189 self.matches = _matches
2184 2190
2185 2191 return _CompleteResult(text, _matches, origins, completions)
2186 2192
2187 2193 def fwd_unicode_match(self, text:str) -> Tuple[str, Sequence[str]]:
2188 2194 """
2189 2195 Forward match a string starting with a backslash with a list of
2190 2196 potential Unicode completions.
2191 2197
2192 2198 Will compute list list of Unicode character names on first call and cache it.
2193 2199
2194 2200 Returns
2195 2201 -------
2196 2202 At tuple with:
2197 2203 - matched text (empty if no matches)
2198 2204 - list of potential completions, empty tuple otherwise)
2199 2205 """
2200 2206 # TODO: self.unicode_names is here a list we traverse each time with ~100k elements.
2201 2207 # We could do a faster match using a Trie.
2202 2208
2203 2209 # Using pygtrie the following seem to work:
2204 2210
2205 2211 # s = PrefixSet()
2206 2212
2207 2213 # for c in range(0,0x10FFFF + 1):
2208 2214 # try:
2209 2215 # s.add(unicodedata.name(chr(c)))
2210 2216 # except ValueError:
2211 2217 # pass
2212 2218 # [''.join(k) for k in s.iter(prefix)]
2213 2219
2214 2220 # But need to be timed and adds an extra dependency.
2215 2221
2216 2222 slashpos = text.rfind('\\')
2217 2223 # if text starts with slash
2218 2224 if slashpos > -1:
2219 2225 # PERF: It's important that we don't access self._unicode_names
2220 2226 # until we're inside this if-block. _unicode_names is lazily
2221 2227 # initialized, and it takes a user-noticeable amount of time to
2222 2228 # initialize it, so we don't want to initialize it unless we're
2223 2229 # actually going to use it.
2224 2230 s = text[slashpos+1:]
2225 2231 candidates = [x for x in self.unicode_names if x.startswith(s)]
2226 2232 if candidates:
2227 2233 return s, candidates
2228 2234 else:
2229 2235 return '', ()
2230 2236
2231 2237 # if text does not start with slash
2232 2238 else:
2233 2239 return '', ()
2234 2240
2235 2241 @property
2236 2242 def unicode_names(self) -> List[str]:
2237 2243 """List of names of unicode code points that can be completed.
2238 2244
2239 2245 The list is lazily initialized on first access.
2240 2246 """
2241 2247 if self._unicode_names is None:
2242 2248 names = []
2243 2249 for c in range(0,0x10FFFF + 1):
2244 2250 try:
2245 2251 names.append(unicodedata.name(chr(c)))
2246 2252 except ValueError:
2247 2253 pass
2248 2254 self._unicode_names = _unicode_name_compute(_UNICODE_RANGES)
2249 2255
2250 2256 return self._unicode_names
2251 2257
2252 2258 def _unicode_name_compute(ranges:List[Tuple[int,int]]) -> List[str]:
2253 2259 names = []
2254 2260 for start,stop in ranges:
2255 2261 for c in range(start, stop) :
2256 2262 try:
2257 2263 names.append(unicodedata.name(chr(c)))
2258 2264 except ValueError:
2259 2265 pass
2260 2266 return names
1 NO CONTENT: modified file
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@@ -1,425 +1,425 b''
1 1 # -*- coding: utf-8 -*-
2 2 """Pylab (matplotlib) support utilities."""
3 3
4 4 # Copyright (c) IPython Development Team.
5 5 # Distributed under the terms of the Modified BSD License.
6 6
7 7 from io import BytesIO
8 8 from binascii import b2a_base64
9 9 from functools import partial
10 10 import warnings
11 11
12 12 from IPython.core.display import _pngxy
13 13 from IPython.utils.decorators import flag_calls
14 14
15 15 # If user specifies a GUI, that dictates the backend, otherwise we read the
16 16 # user's mpl default from the mpl rc structure
17 17 backends = {
18 18 "tk": "TkAgg",
19 19 "gtk": "GTKAgg",
20 20 "gtk3": "GTK3Agg",
21 21 "gtk4": "GTK4Agg",
22 22 "wx": "WXAgg",
23 23 "qt4": "Qt4Agg",
24 24 "qt5": "Qt5Agg",
25 25 "qt6": "QtAgg",
26 26 "qt": "Qt5Agg",
27 27 "osx": "MacOSX",
28 28 "nbagg": "nbAgg",
29 29 "notebook": "nbAgg",
30 30 "agg": "agg",
31 31 "svg": "svg",
32 32 "pdf": "pdf",
33 33 "ps": "ps",
34 34 "inline": "module://matplotlib_inline.backend_inline",
35 35 "ipympl": "module://ipympl.backend_nbagg",
36 36 "widget": "module://ipympl.backend_nbagg",
37 37 }
38 38
39 39 # We also need a reverse backends2guis mapping that will properly choose which
40 40 # GUI support to activate based on the desired matplotlib backend. For the
41 41 # most part it's just a reverse of the above dict, but we also need to add a
42 42 # few others that map to the same GUI manually:
43 43 backend2gui = dict(zip(backends.values(), backends.keys()))
44 44 # In the reverse mapping, there are a few extra valid matplotlib backends that
45 45 # map to the same GUI support
46 46 backend2gui["GTK"] = backend2gui["GTKCairo"] = "gtk"
47 47 backend2gui["GTK3Cairo"] = "gtk3"
48 48 backend2gui["GTK4Cairo"] = "gtk4"
49 49 backend2gui["WX"] = "wx"
50 50 backend2gui["CocoaAgg"] = "osx"
51 51 # There needs to be a hysteresis here as the new QtAgg Matplotlib backend
52 52 # supports either Qt5 or Qt6 and the IPython qt event loop support Qt4, Qt5,
53 53 # and Qt6.
54 54 backend2gui["QtAgg"] = "qt"
55 55 backend2gui["Qt4Agg"] = "qt"
56 56 backend2gui["Qt5Agg"] = "qt"
57 57
58 58 # And some backends that don't need GUI integration
59 59 del backend2gui["nbAgg"]
60 60 del backend2gui["agg"]
61 61 del backend2gui["svg"]
62 62 del backend2gui["pdf"]
63 63 del backend2gui["ps"]
64 64 del backend2gui["module://matplotlib_inline.backend_inline"]
65 65 del backend2gui["module://ipympl.backend_nbagg"]
66 66
67 67 #-----------------------------------------------------------------------------
68 68 # Matplotlib utilities
69 69 #-----------------------------------------------------------------------------
70 70
71 71
72 72 def getfigs(*fig_nums):
73 73 """Get a list of matplotlib figures by figure numbers.
74 74
75 75 If no arguments are given, all available figures are returned. If the
76 76 argument list contains references to invalid figures, a warning is printed
77 77 but the function continues pasting further figures.
78 78
79 79 Parameters
80 80 ----------
81 81 figs : tuple
82 82 A tuple of ints giving the figure numbers of the figures to return.
83 83 """
84 84 from matplotlib._pylab_helpers import Gcf
85 85 if not fig_nums:
86 86 fig_managers = Gcf.get_all_fig_managers()
87 87 return [fm.canvas.figure for fm in fig_managers]
88 88 else:
89 89 figs = []
90 90 for num in fig_nums:
91 91 f = Gcf.figs.get(num)
92 92 if f is None:
93 93 print('Warning: figure %s not available.' % num)
94 94 else:
95 95 figs.append(f.canvas.figure)
96 96 return figs
97 97
98 98
99 99 def figsize(sizex, sizey):
100 100 """Set the default figure size to be [sizex, sizey].
101 101
102 102 This is just an easy to remember, convenience wrapper that sets::
103 103
104 104 matplotlib.rcParams['figure.figsize'] = [sizex, sizey]
105 105 """
106 106 import matplotlib
107 107 matplotlib.rcParams['figure.figsize'] = [sizex, sizey]
108 108
109 109
110 110 def print_figure(fig, fmt="png", bbox_inches="tight", base64=False, **kwargs):
111 111 """Print a figure to an image, and return the resulting file data
112 112
113 113 Returned data will be bytes unless ``fmt='svg'``,
114 114 in which case it will be unicode.
115 115
116 116 Any keyword args are passed to fig.canvas.print_figure,
117 117 such as ``quality`` or ``bbox_inches``.
118 118
119 119 If `base64` is True, return base64-encoded str instead of raw bytes
120 120 for binary-encoded image formats
121 121
122 .. versionadded: 7.29
122 .. versionadded:: 7.29
123 123 base64 argument
124 124 """
125 125 # When there's an empty figure, we shouldn't return anything, otherwise we
126 126 # get big blank areas in the qt console.
127 127 if not fig.axes and not fig.lines:
128 128 return
129 129
130 130 dpi = fig.dpi
131 131 if fmt == 'retina':
132 132 dpi = dpi * 2
133 133 fmt = 'png'
134 134
135 135 # build keyword args
136 136 kw = {
137 137 "format":fmt,
138 138 "facecolor":fig.get_facecolor(),
139 139 "edgecolor":fig.get_edgecolor(),
140 140 "dpi":dpi,
141 141 "bbox_inches":bbox_inches,
142 142 }
143 143 # **kwargs get higher priority
144 144 kw.update(kwargs)
145 145
146 146 bytes_io = BytesIO()
147 147 if fig.canvas is None:
148 148 from matplotlib.backend_bases import FigureCanvasBase
149 149 FigureCanvasBase(fig)
150 150
151 151 fig.canvas.print_figure(bytes_io, **kw)
152 152 data = bytes_io.getvalue()
153 153 if fmt == 'svg':
154 154 data = data.decode('utf-8')
155 155 elif base64:
156 156 data = b2a_base64(data).decode("ascii")
157 157 return data
158 158
159 159 def retina_figure(fig, base64=False, **kwargs):
160 160 """format a figure as a pixel-doubled (retina) PNG
161 161
162 162 If `base64` is True, return base64-encoded str instead of raw bytes
163 163 for binary-encoded image formats
164 164
165 .. versionadded: 7.29
165 .. versionadded:: 7.29
166 166 base64 argument
167 167 """
168 168 pngdata = print_figure(fig, fmt="retina", base64=False, **kwargs)
169 169 # Make sure that retina_figure acts just like print_figure and returns
170 170 # None when the figure is empty.
171 171 if pngdata is None:
172 172 return
173 173 w, h = _pngxy(pngdata)
174 174 metadata = {"width": w//2, "height":h//2}
175 175 if base64:
176 176 pngdata = b2a_base64(pngdata).decode("ascii")
177 177 return pngdata, metadata
178 178
179 179
180 180 # We need a little factory function here to create the closure where
181 181 # safe_execfile can live.
182 182 def mpl_runner(safe_execfile):
183 183 """Factory to return a matplotlib-enabled runner for %run.
184 184
185 185 Parameters
186 186 ----------
187 187 safe_execfile : function
188 188 This must be a function with the same interface as the
189 189 :meth:`safe_execfile` method of IPython.
190 190
191 191 Returns
192 192 -------
193 193 A function suitable for use as the ``runner`` argument of the %run magic
194 194 function.
195 195 """
196 196
197 197 def mpl_execfile(fname,*where,**kw):
198 198 """matplotlib-aware wrapper around safe_execfile.
199 199
200 200 Its interface is identical to that of the :func:`execfile` builtin.
201 201
202 202 This is ultimately a call to execfile(), but wrapped in safeties to
203 203 properly handle interactive rendering."""
204 204
205 205 import matplotlib
206 206 import matplotlib.pyplot as plt
207 207
208 208 #print '*** Matplotlib runner ***' # dbg
209 209 # turn off rendering until end of script
210 210 is_interactive = matplotlib.rcParams['interactive']
211 211 matplotlib.interactive(False)
212 212 safe_execfile(fname,*where,**kw)
213 213 matplotlib.interactive(is_interactive)
214 214 # make rendering call now, if the user tried to do it
215 215 if plt.draw_if_interactive.called:
216 216 plt.draw()
217 217 plt.draw_if_interactive.called = False
218 218
219 219 # re-draw everything that is stale
220 220 try:
221 221 da = plt.draw_all
222 222 except AttributeError:
223 223 pass
224 224 else:
225 225 da()
226 226
227 227 return mpl_execfile
228 228
229 229
230 230 def _reshow_nbagg_figure(fig):
231 231 """reshow an nbagg figure"""
232 232 try:
233 233 reshow = fig.canvas.manager.reshow
234 234 except AttributeError as e:
235 235 raise NotImplementedError() from e
236 236 else:
237 237 reshow()
238 238
239 239
240 240 def select_figure_formats(shell, formats, **kwargs):
241 241 """Select figure formats for the inline backend.
242 242
243 243 Parameters
244 244 ==========
245 245 shell : InteractiveShell
246 246 The main IPython instance.
247 247 formats : str or set
248 248 One or a set of figure formats to enable: 'png', 'retina', 'jpeg', 'svg', 'pdf'.
249 249 **kwargs : any
250 250 Extra keyword arguments to be passed to fig.canvas.print_figure.
251 251 """
252 252 import matplotlib
253 253 from matplotlib.figure import Figure
254 254
255 255 svg_formatter = shell.display_formatter.formatters['image/svg+xml']
256 256 png_formatter = shell.display_formatter.formatters['image/png']
257 257 jpg_formatter = shell.display_formatter.formatters['image/jpeg']
258 258 pdf_formatter = shell.display_formatter.formatters['application/pdf']
259 259
260 260 if isinstance(formats, str):
261 261 formats = {formats}
262 262 # cast in case of list / tuple
263 263 formats = set(formats)
264 264
265 265 [ f.pop(Figure, None) for f in shell.display_formatter.formatters.values() ]
266 266 mplbackend = matplotlib.get_backend().lower()
267 267 if mplbackend == 'nbagg' or mplbackend == 'module://ipympl.backend_nbagg':
268 268 formatter = shell.display_formatter.ipython_display_formatter
269 269 formatter.for_type(Figure, _reshow_nbagg_figure)
270 270
271 271 supported = {'png', 'png2x', 'retina', 'jpg', 'jpeg', 'svg', 'pdf'}
272 272 bad = formats.difference(supported)
273 273 if bad:
274 274 bs = "%s" % ','.join([repr(f) for f in bad])
275 275 gs = "%s" % ','.join([repr(f) for f in supported])
276 276 raise ValueError("supported formats are: %s not %s" % (gs, bs))
277 277
278 278 if "png" in formats:
279 279 png_formatter.for_type(
280 280 Figure, partial(print_figure, fmt="png", base64=True, **kwargs)
281 281 )
282 282 if "retina" in formats or "png2x" in formats:
283 283 png_formatter.for_type(Figure, partial(retina_figure, base64=True, **kwargs))
284 284 if "jpg" in formats or "jpeg" in formats:
285 285 jpg_formatter.for_type(
286 286 Figure, partial(print_figure, fmt="jpg", base64=True, **kwargs)
287 287 )
288 288 if "svg" in formats:
289 289 svg_formatter.for_type(Figure, partial(print_figure, fmt="svg", **kwargs))
290 290 if "pdf" in formats:
291 291 pdf_formatter.for_type(
292 292 Figure, partial(print_figure, fmt="pdf", base64=True, **kwargs)
293 293 )
294 294
295 295 #-----------------------------------------------------------------------------
296 296 # Code for initializing matplotlib and importing pylab
297 297 #-----------------------------------------------------------------------------
298 298
299 299
300 300 def find_gui_and_backend(gui=None, gui_select=None):
301 301 """Given a gui string return the gui and mpl backend.
302 302
303 303 Parameters
304 304 ----------
305 305 gui : str
306 306 Can be one of ('tk','gtk','wx','qt','qt4','inline','agg').
307 307 gui_select : str
308 308 Can be one of ('tk','gtk','wx','qt','qt4','inline').
309 309 This is any gui already selected by the shell.
310 310
311 311 Returns
312 312 -------
313 313 A tuple of (gui, backend) where backend is one of ('TkAgg','GTKAgg',
314 314 'WXAgg','Qt4Agg','module://matplotlib_inline.backend_inline','agg').
315 315 """
316 316
317 317 import matplotlib
318 318
319 319 if gui and gui != 'auto':
320 320 # select backend based on requested gui
321 321 backend = backends[gui]
322 322 if gui == 'agg':
323 323 gui = None
324 324 else:
325 325 # We need to read the backend from the original data structure, *not*
326 326 # from mpl.rcParams, since a prior invocation of %matplotlib may have
327 327 # overwritten that.
328 328 # WARNING: this assumes matplotlib 1.1 or newer!!
329 329 backend = matplotlib.rcParamsOrig['backend']
330 330 # In this case, we need to find what the appropriate gui selection call
331 331 # should be for IPython, so we can activate inputhook accordingly
332 332 gui = backend2gui.get(backend, None)
333 333
334 334 # If we have already had a gui active, we need it and inline are the
335 335 # ones allowed.
336 336 if gui_select and gui != gui_select:
337 337 gui = gui_select
338 338 backend = backends[gui]
339 339
340 340 return gui, backend
341 341
342 342
343 343 def activate_matplotlib(backend):
344 344 """Activate the given backend and set interactive to True."""
345 345
346 346 import matplotlib
347 347 matplotlib.interactive(True)
348 348
349 349 # Matplotlib had a bug where even switch_backend could not force
350 350 # the rcParam to update. This needs to be set *before* the module
351 351 # magic of switch_backend().
352 352 matplotlib.rcParams['backend'] = backend
353 353
354 354 # Due to circular imports, pyplot may be only partially initialised
355 355 # when this function runs.
356 356 # So avoid needing matplotlib attribute-lookup to access pyplot.
357 357 from matplotlib import pyplot as plt
358 358
359 359 plt.switch_backend(backend)
360 360
361 361 plt.show._needmain = False
362 362 # We need to detect at runtime whether show() is called by the user.
363 363 # For this, we wrap it into a decorator which adds a 'called' flag.
364 364 plt.draw_if_interactive = flag_calls(plt.draw_if_interactive)
365 365
366 366
367 367 def import_pylab(user_ns, import_all=True):
368 368 """Populate the namespace with pylab-related values.
369 369
370 370 Imports matplotlib, pylab, numpy, and everything from pylab and numpy.
371 371
372 372 Also imports a few names from IPython (figsize, display, getfigs)
373 373
374 374 """
375 375
376 376 # Import numpy as np/pyplot as plt are conventions we're trying to
377 377 # somewhat standardize on. Making them available to users by default
378 378 # will greatly help this.
379 379 s = ("import numpy\n"
380 380 "import matplotlib\n"
381 381 "from matplotlib import pylab, mlab, pyplot\n"
382 382 "np = numpy\n"
383 383 "plt = pyplot\n"
384 384 )
385 385 exec(s, user_ns)
386 386
387 387 if import_all:
388 388 s = ("from matplotlib.pylab import *\n"
389 389 "from numpy import *\n")
390 390 exec(s, user_ns)
391 391
392 392 # IPython symbols to add
393 393 user_ns['figsize'] = figsize
394 394 from IPython.display import display
395 395 # Add display and getfigs to the user's namespace
396 396 user_ns['display'] = display
397 397 user_ns['getfigs'] = getfigs
398 398
399 399
400 400 def configure_inline_support(shell, backend):
401 401 """
402 .. deprecated: 7.23
402 .. deprecated:: 7.23
403 403
404 404 use `matplotlib_inline.backend_inline.configure_inline_support()`
405 405
406 406 Configure an IPython shell object for matplotlib use.
407 407
408 408 Parameters
409 409 ----------
410 410 shell : InteractiveShell instance
411 411
412 412 backend : matplotlib backend
413 413 """
414 414 warnings.warn(
415 415 "`configure_inline_support` is deprecated since IPython 7.23, directly "
416 416 "use `matplotlib_inline.backend_inline.configure_inline_support()`",
417 417 DeprecationWarning,
418 418 stacklevel=2,
419 419 )
420 420
421 421 from matplotlib_inline.backend_inline import (
422 422 configure_inline_support as configure_inline_support_orig,
423 423 )
424 424
425 425 configure_inline_support_orig(shell, backend)
@@ -1,749 +1,752 b''
1 1 # encoding: utf-8
2 2 """
3 3 Utilities for working with strings and text.
4 4
5 5 Inheritance diagram:
6 6
7 7 .. inheritance-diagram:: IPython.utils.text
8 8 :parts: 3
9 9 """
10 10
11 11 import os
12 12 import re
13 13 import string
14 14 import sys
15 15 import textwrap
16 16 from string import Formatter
17 17 from pathlib import Path
18 18
19 19
20 20 # datetime.strftime date format for ipython
21 21 if sys.platform == 'win32':
22 22 date_format = "%B %d, %Y"
23 23 else:
24 24 date_format = "%B %-d, %Y"
25 25
26 26 class LSString(str):
27 27 """String derivative with a special access attributes.
28 28
29 29 These are normal strings, but with the special attributes:
30 30
31 31 .l (or .list) : value as list (split on newlines).
32 32 .n (or .nlstr): original value (the string itself).
33 33 .s (or .spstr): value as whitespace-separated string.
34 34 .p (or .paths): list of path objects (requires path.py package)
35 35
36 36 Any values which require transformations are computed only once and
37 37 cached.
38 38
39 39 Such strings are very useful to efficiently interact with the shell, which
40 40 typically only understands whitespace-separated options for commands."""
41 41
42 42 def get_list(self):
43 43 try:
44 44 return self.__list
45 45 except AttributeError:
46 46 self.__list = self.split('\n')
47 47 return self.__list
48 48
49 49 l = list = property(get_list)
50 50
51 51 def get_spstr(self):
52 52 try:
53 53 return self.__spstr
54 54 except AttributeError:
55 55 self.__spstr = self.replace('\n',' ')
56 56 return self.__spstr
57 57
58 58 s = spstr = property(get_spstr)
59 59
60 60 def get_nlstr(self):
61 61 return self
62 62
63 63 n = nlstr = property(get_nlstr)
64 64
65 65 def get_paths(self):
66 66 try:
67 67 return self.__paths
68 68 except AttributeError:
69 69 self.__paths = [Path(p) for p in self.split('\n') if os.path.exists(p)]
70 70 return self.__paths
71 71
72 72 p = paths = property(get_paths)
73 73
74 74 # FIXME: We need to reimplement type specific displayhook and then add this
75 75 # back as a custom printer. This should also be moved outside utils into the
76 76 # core.
77 77
78 78 # def print_lsstring(arg):
79 79 # """ Prettier (non-repr-like) and more informative printer for LSString """
80 80 # print "LSString (.p, .n, .l, .s available). Value:"
81 81 # print arg
82 82 #
83 83 #
84 84 # print_lsstring = result_display.register(LSString)(print_lsstring)
85 85
86 86
87 87 class SList(list):
88 88 """List derivative with a special access attributes.
89 89
90 90 These are normal lists, but with the special attributes:
91 91
92 92 * .l (or .list) : value as list (the list itself).
93 93 * .n (or .nlstr): value as a string, joined on newlines.
94 94 * .s (or .spstr): value as a string, joined on spaces.
95 95 * .p (or .paths): list of path objects (requires path.py package)
96 96
97 97 Any values which require transformations are computed only once and
98 98 cached."""
99 99
100 100 def get_list(self):
101 101 return self
102 102
103 103 l = list = property(get_list)
104 104
105 105 def get_spstr(self):
106 106 try:
107 107 return self.__spstr
108 108 except AttributeError:
109 109 self.__spstr = ' '.join(self)
110 110 return self.__spstr
111 111
112 112 s = spstr = property(get_spstr)
113 113
114 114 def get_nlstr(self):
115 115 try:
116 116 return self.__nlstr
117 117 except AttributeError:
118 118 self.__nlstr = '\n'.join(self)
119 119 return self.__nlstr
120 120
121 121 n = nlstr = property(get_nlstr)
122 122
123 123 def get_paths(self):
124 124 try:
125 125 return self.__paths
126 126 except AttributeError:
127 127 self.__paths = [Path(p) for p in self if os.path.exists(p)]
128 128 return self.__paths
129 129
130 130 p = paths = property(get_paths)
131 131
132 132 def grep(self, pattern, prune = False, field = None):
133 133 """ Return all strings matching 'pattern' (a regex or callable)
134 134
135 135 This is case-insensitive. If prune is true, return all items
136 136 NOT matching the pattern.
137 137
138 138 If field is specified, the match must occur in the specified
139 139 whitespace-separated field.
140 140
141 141 Examples::
142 142
143 143 a.grep( lambda x: x.startswith('C') )
144 144 a.grep('Cha.*log', prune=1)
145 145 a.grep('chm', field=-1)
146 146 """
147 147
148 148 def match_target(s):
149 149 if field is None:
150 150 return s
151 151 parts = s.split()
152 152 try:
153 153 tgt = parts[field]
154 154 return tgt
155 155 except IndexError:
156 156 return ""
157 157
158 158 if isinstance(pattern, str):
159 159 pred = lambda x : re.search(pattern, x, re.IGNORECASE)
160 160 else:
161 161 pred = pattern
162 162 if not prune:
163 163 return SList([el for el in self if pred(match_target(el))])
164 164 else:
165 165 return SList([el for el in self if not pred(match_target(el))])
166 166
167 167 def fields(self, *fields):
168 168 """ Collect whitespace-separated fields from string list
169 169
170 170 Allows quick awk-like usage of string lists.
171 171
172 172 Example data (in var a, created by 'a = !ls -l')::
173 173
174 174 -rwxrwxrwx 1 ville None 18 Dec 14 2006 ChangeLog
175 175 drwxrwxrwx+ 6 ville None 0 Oct 24 18:05 IPython
176 176
177 177 * ``a.fields(0)`` is ``['-rwxrwxrwx', 'drwxrwxrwx+']``
178 178 * ``a.fields(1,0)`` is ``['1 -rwxrwxrwx', '6 drwxrwxrwx+']``
179 179 (note the joining by space).
180 180 * ``a.fields(-1)`` is ``['ChangeLog', 'IPython']``
181 181
182 182 IndexErrors are ignored.
183 183
184 184 Without args, fields() just split()'s the strings.
185 185 """
186 186 if len(fields) == 0:
187 187 return [el.split() for el in self]
188 188
189 189 res = SList()
190 190 for el in [f.split() for f in self]:
191 191 lineparts = []
192 192
193 193 for fd in fields:
194 194 try:
195 195 lineparts.append(el[fd])
196 196 except IndexError:
197 197 pass
198 198 if lineparts:
199 199 res.append(" ".join(lineparts))
200 200
201 201 return res
202 202
203 203 def sort(self,field= None, nums = False):
204 204 """ sort by specified fields (see fields())
205 205
206 206 Example::
207 207
208 208 a.sort(1, nums = True)
209 209
210 210 Sorts a by second field, in numerical order (so that 21 > 3)
211 211
212 212 """
213 213
214 214 #decorate, sort, undecorate
215 215 if field is not None:
216 216 dsu = [[SList([line]).fields(field), line] for line in self]
217 217 else:
218 218 dsu = [[line, line] for line in self]
219 219 if nums:
220 220 for i in range(len(dsu)):
221 221 numstr = "".join([ch for ch in dsu[i][0] if ch.isdigit()])
222 222 try:
223 223 n = int(numstr)
224 224 except ValueError:
225 225 n = 0
226 226 dsu[i][0] = n
227 227
228 228
229 229 dsu.sort()
230 230 return SList([t[1] for t in dsu])
231 231
232 232
233 233 # FIXME: We need to reimplement type specific displayhook and then add this
234 234 # back as a custom printer. This should also be moved outside utils into the
235 235 # core.
236 236
237 237 # def print_slist(arg):
238 238 # """ Prettier (non-repr-like) and more informative printer for SList """
239 239 # print "SList (.p, .n, .l, .s, .grep(), .fields(), sort() available):"
240 240 # if hasattr(arg, 'hideonce') and arg.hideonce:
241 241 # arg.hideonce = False
242 242 # return
243 243 #
244 244 # nlprint(arg) # This was a nested list printer, now removed.
245 245 #
246 246 # print_slist = result_display.register(SList)(print_slist)
247 247
248 248
249 249 def indent(instr,nspaces=4, ntabs=0, flatten=False):
250 250 """Indent a string a given number of spaces or tabstops.
251 251
252 252 indent(str,nspaces=4,ntabs=0) -> indent str by ntabs+nspaces.
253 253
254 254 Parameters
255 255 ----------
256 256 instr : basestring
257 257 The string to be indented.
258 258 nspaces : int (default: 4)
259 259 The number of spaces to be indented.
260 260 ntabs : int (default: 0)
261 261 The number of tabs to be indented.
262 262 flatten : bool (default: False)
263 263 Whether to scrub existing indentation. If True, all lines will be
264 264 aligned to the same indentation. If False, existing indentation will
265 265 be strictly increased.
266 266
267 267 Returns
268 268 -------
269 269 str|unicode : string indented by ntabs and nspaces.
270 270
271 271 """
272 272 if instr is None:
273 273 return
274 274 ind = '\t'*ntabs+' '*nspaces
275 275 if flatten:
276 276 pat = re.compile(r'^\s*', re.MULTILINE)
277 277 else:
278 278 pat = re.compile(r'^', re.MULTILINE)
279 279 outstr = re.sub(pat, ind, instr)
280 280 if outstr.endswith(os.linesep+ind):
281 281 return outstr[:-len(ind)]
282 282 else:
283 283 return outstr
284 284
285 285
286 286 def list_strings(arg):
287 287 """Always return a list of strings, given a string or list of strings
288 288 as input.
289 289
290 290 Examples
291 291 --------
292 292 ::
293 293
294 294 In [7]: list_strings('A single string')
295 295 Out[7]: ['A single string']
296 296
297 297 In [8]: list_strings(['A single string in a list'])
298 298 Out[8]: ['A single string in a list']
299 299
300 300 In [9]: list_strings(['A','list','of','strings'])
301 301 Out[9]: ['A', 'list', 'of', 'strings']
302 302 """
303 303
304 304 if isinstance(arg, str):
305 305 return [arg]
306 306 else:
307 307 return arg
308 308
309 309
310 310 def marquee(txt='',width=78,mark='*'):
311 311 """Return the input string centered in a 'marquee'.
312 312
313 313 Examples
314 314 --------
315 315 ::
316 316
317 317 In [16]: marquee('A test',40)
318 318 Out[16]: '**************** A test ****************'
319 319
320 320 In [17]: marquee('A test',40,'-')
321 321 Out[17]: '---------------- A test ----------------'
322 322
323 323 In [18]: marquee('A test',40,' ')
324 324 Out[18]: ' A test '
325 325
326 326 """
327 327 if not txt:
328 328 return (mark*width)[:width]
329 329 nmark = (width-len(txt)-2)//len(mark)//2
330 330 if nmark < 0: nmark =0
331 331 marks = mark*nmark
332 332 return '%s %s %s' % (marks,txt,marks)
333 333
334 334
335 335 ini_spaces_re = re.compile(r'^(\s+)')
336 336
337 337 def num_ini_spaces(strng):
338 338 """Return the number of initial spaces in a string"""
339 339
340 340 ini_spaces = ini_spaces_re.match(strng)
341 341 if ini_spaces:
342 342 return ini_spaces.end()
343 343 else:
344 344 return 0
345 345
346 346
347 347 def format_screen(strng):
348 348 """Format a string for screen printing.
349 349
350 350 This removes some latex-type format codes."""
351 351 # Paragraph continue
352 352 par_re = re.compile(r'\\$',re.MULTILINE)
353 353 strng = par_re.sub('',strng)
354 354 return strng
355 355
356 356
357 357 def dedent(text):
358 358 """Equivalent of textwrap.dedent that ignores unindented first line.
359 359
360 360 This means it will still dedent strings like:
361 361 '''foo
362 362 is a bar
363 363 '''
364 364
365 365 For use in wrap_paragraphs.
366 366 """
367 367
368 368 if text.startswith('\n'):
369 369 # text starts with blank line, don't ignore the first line
370 370 return textwrap.dedent(text)
371 371
372 372 # split first line
373 373 splits = text.split('\n',1)
374 374 if len(splits) == 1:
375 375 # only one line
376 376 return textwrap.dedent(text)
377 377
378 378 first, rest = splits
379 379 # dedent everything but the first line
380 380 rest = textwrap.dedent(rest)
381 381 return '\n'.join([first, rest])
382 382
383 383
384 384 def wrap_paragraphs(text, ncols=80):
385 385 """Wrap multiple paragraphs to fit a specified width.
386 386
387 387 This is equivalent to textwrap.wrap, but with support for multiple
388 388 paragraphs, as separated by empty lines.
389 389
390 390 Returns
391 391 -------
392 392 list of complete paragraphs, wrapped to fill `ncols` columns.
393 393 """
394 394 paragraph_re = re.compile(r'\n(\s*\n)+', re.MULTILINE)
395 395 text = dedent(text).strip()
396 396 paragraphs = paragraph_re.split(text)[::2] # every other entry is space
397 397 out_ps = []
398 398 indent_re = re.compile(r'\n\s+', re.MULTILINE)
399 399 for p in paragraphs:
400 400 # presume indentation that survives dedent is meaningful formatting,
401 401 # so don't fill unless text is flush.
402 402 if indent_re.search(p) is None:
403 403 # wrap paragraph
404 404 p = textwrap.fill(p, ncols)
405 405 out_ps.append(p)
406 406 return out_ps
407 407
408 408
409 409 def strip_email_quotes(text):
410 410 """Strip leading email quotation characters ('>').
411 411
412 412 Removes any combination of leading '>' interspersed with whitespace that
413 413 appears *identically* in all lines of the input text.
414 414
415 415 Parameters
416 416 ----------
417 417 text : str
418 418
419 419 Examples
420 420 --------
421 421
422 422 Simple uses::
423 423
424 424 In [2]: strip_email_quotes('> > text')
425 425 Out[2]: 'text'
426 426
427 427 In [3]: strip_email_quotes('> > text\\n> > more')
428 428 Out[3]: 'text\\nmore'
429 429
430 430 Note how only the common prefix that appears in all lines is stripped::
431 431
432 432 In [4]: strip_email_quotes('> > text\\n> > more\\n> more...')
433 433 Out[4]: '> text\\n> more\\nmore...'
434 434
435 435 So if any line has no quote marks ('>'), then none are stripped from any
436 436 of them ::
437 437
438 438 In [5]: strip_email_quotes('> > text\\n> > more\\nlast different')
439 439 Out[5]: '> > text\\n> > more\\nlast different'
440 440 """
441 441 lines = text.splitlines()
442 442 strip_len = 0
443 443
444 444 for characters in zip(*lines):
445 445 # Check if all characters in this position are the same
446 446 if len(set(characters)) > 1:
447 447 break
448 448 prefix_char = characters[0]
449 449
450 450 if prefix_char in string.whitespace or prefix_char == ">":
451 451 strip_len += 1
452 452 else:
453 453 break
454 454
455 455 text = "\n".join([ln[strip_len:] for ln in lines])
456 456 return text
457 457
458 458
459 459 def strip_ansi(source):
460 460 """
461 461 Remove ansi escape codes from text.
462 462
463 463 Parameters
464 464 ----------
465 465 source : str
466 466 Source to remove the ansi from
467 467 """
468 468 return re.sub(r'\033\[(\d|;)+?m', '', source)
469 469
470 470
471 471 class EvalFormatter(Formatter):
472 472 """A String Formatter that allows evaluation of simple expressions.
473 473
474 474 Note that this version interprets a : as specifying a format string (as per
475 475 standard string formatting), so if slicing is required, you must explicitly
476 476 create a slice.
477 477
478 478 This is to be used in templating cases, such as the parallel batch
479 479 script templates, where simple arithmetic on arguments is useful.
480 480
481 481 Examples
482 482 --------
483 483 ::
484 484
485 485 In [1]: f = EvalFormatter()
486 486 In [2]: f.format('{n//4}', n=8)
487 487 Out[2]: '2'
488 488
489 489 In [3]: f.format("{greeting[slice(2,4)]}", greeting="Hello")
490 490 Out[3]: 'll'
491 491 """
492 492 def get_field(self, name, args, kwargs):
493 493 v = eval(name, kwargs)
494 494 return v, name
495 495
496 496 #XXX: As of Python 3.4, the format string parsing no longer splits on a colon
497 497 # inside [], so EvalFormatter can handle slicing. Once we only support 3.4 and
498 498 # above, it should be possible to remove FullEvalFormatter.
499 499
500 500 class FullEvalFormatter(Formatter):
501 501 """A String Formatter that allows evaluation of simple expressions.
502 502
503 503 Any time a format key is not found in the kwargs,
504 504 it will be tried as an expression in the kwargs namespace.
505 505
506 506 Note that this version allows slicing using [1:2], so you cannot specify
507 507 a format string. Use :class:`EvalFormatter` to permit format strings.
508 508
509 509 Examples
510 510 --------
511 511 ::
512 512
513 513 In [1]: f = FullEvalFormatter()
514 514 In [2]: f.format('{n//4}', n=8)
515 515 Out[2]: '2'
516 516
517 517 In [3]: f.format('{list(range(5))[2:4]}')
518 518 Out[3]: '[2, 3]'
519 519
520 520 In [4]: f.format('{3*2}')
521 521 Out[4]: '6'
522 522 """
523 523 # copied from Formatter._vformat with minor changes to allow eval
524 524 # and replace the format_spec code with slicing
525 525 def vformat(self, format_string:str, args, kwargs)->str:
526 526 result = []
527 527 for literal_text, field_name, format_spec, conversion in \
528 528 self.parse(format_string):
529 529
530 530 # output the literal text
531 531 if literal_text:
532 532 result.append(literal_text)
533 533
534 534 # if there's a field, output it
535 535 if field_name is not None:
536 536 # this is some markup, find the object and do
537 537 # the formatting
538 538
539 539 if format_spec:
540 540 # override format spec, to allow slicing:
541 541 field_name = ':'.join([field_name, format_spec])
542 542
543 543 # eval the contents of the field for the object
544 544 # to be formatted
545 545 obj = eval(field_name, kwargs)
546 546
547 547 # do any conversion on the resulting object
548 548 obj = self.convert_field(obj, conversion)
549 549
550 550 # format the object and append to the result
551 551 result.append(self.format_field(obj, ''))
552 552
553 553 return ''.join(result)
554 554
555 555
556 556 class DollarFormatter(FullEvalFormatter):
557 557 """Formatter allowing Itpl style $foo replacement, for names and attribute
558 558 access only. Standard {foo} replacement also works, and allows full
559 559 evaluation of its arguments.
560 560
561 561 Examples
562 562 --------
563 563 ::
564 564
565 565 In [1]: f = DollarFormatter()
566 566 In [2]: f.format('{n//4}', n=8)
567 567 Out[2]: '2'
568 568
569 569 In [3]: f.format('23 * 76 is $result', result=23*76)
570 570 Out[3]: '23 * 76 is 1748'
571 571
572 572 In [4]: f.format('$a or {b}', a=1, b=2)
573 573 Out[4]: '1 or 2'
574 574 """
575 575 _dollar_pattern_ignore_single_quote = re.compile(r"(.*?)\$(\$?[\w\.]+)(?=([^']*'[^']*')*[^']*$)")
576 576 def parse(self, fmt_string):
577 577 for literal_txt, field_name, format_spec, conversion \
578 578 in Formatter.parse(self, fmt_string):
579 579
580 580 # Find $foo patterns in the literal text.
581 581 continue_from = 0
582 582 txt = ""
583 583 for m in self._dollar_pattern_ignore_single_quote.finditer(literal_txt):
584 584 new_txt, new_field = m.group(1,2)
585 585 # $$foo --> $foo
586 586 if new_field.startswith("$"):
587 587 txt += new_txt + new_field
588 588 else:
589 589 yield (txt + new_txt, new_field, "", None)
590 590 txt = ""
591 591 continue_from = m.end()
592 592
593 593 # Re-yield the {foo} style pattern
594 594 yield (txt + literal_txt[continue_from:], field_name, format_spec, conversion)
595 595
596 def __repr__(self):
597 return "<DollarFormatter>"
598
596 599 #-----------------------------------------------------------------------------
597 600 # Utils to columnize a list of string
598 601 #-----------------------------------------------------------------------------
599 602
600 603 def _col_chunks(l, max_rows, row_first=False):
601 604 """Yield successive max_rows-sized column chunks from l."""
602 605 if row_first:
603 606 ncols = (len(l) // max_rows) + (len(l) % max_rows > 0)
604 607 for i in range(ncols):
605 608 yield [l[j] for j in range(i, len(l), ncols)]
606 609 else:
607 610 for i in range(0, len(l), max_rows):
608 611 yield l[i:(i + max_rows)]
609 612
610 613
611 614 def _find_optimal(rlist, row_first=False, separator_size=2, displaywidth=80):
612 615 """Calculate optimal info to columnize a list of string"""
613 616 for max_rows in range(1, len(rlist) + 1):
614 617 col_widths = list(map(max, _col_chunks(rlist, max_rows, row_first)))
615 618 sumlength = sum(col_widths)
616 619 ncols = len(col_widths)
617 620 if sumlength + separator_size * (ncols - 1) <= displaywidth:
618 621 break
619 622 return {'num_columns': ncols,
620 623 'optimal_separator_width': (displaywidth - sumlength) // (ncols - 1) if (ncols - 1) else 0,
621 624 'max_rows': max_rows,
622 625 'column_widths': col_widths
623 626 }
624 627
625 628
626 629 def _get_or_default(mylist, i, default=None):
627 630 """return list item number, or default if don't exist"""
628 631 if i >= len(mylist):
629 632 return default
630 633 else :
631 634 return mylist[i]
632 635
633 636
634 637 def compute_item_matrix(items, row_first=False, empty=None, *args, **kwargs) :
635 638 """Returns a nested list, and info to columnize items
636 639
637 640 Parameters
638 641 ----------
639 642 items
640 643 list of strings to columize
641 644 row_first : (default False)
642 645 Whether to compute columns for a row-first matrix instead of
643 646 column-first (default).
644 647 empty : (default None)
645 648 default value to fill list if needed
646 649 separator_size : int (default=2)
647 650 How much characters will be used as a separation between each columns.
648 651 displaywidth : int (default=80)
649 652 The width of the area onto which the columns should enter
650 653
651 654 Returns
652 655 -------
653 656 strings_matrix
654 657 nested list of string, the outer most list contains as many list as
655 658 rows, the innermost lists have each as many element as columns. If the
656 659 total number of elements in `items` does not equal the product of
657 660 rows*columns, the last element of some lists are filled with `None`.
658 661 dict_info
659 662 some info to make columnize easier:
660 663
661 664 num_columns
662 665 number of columns
663 666 max_rows
664 667 maximum number of rows (final number may be less)
665 668 column_widths
666 669 list of with of each columns
667 670 optimal_separator_width
668 671 best separator width between columns
669 672
670 673 Examples
671 674 --------
672 675 ::
673 676
674 677 In [1]: l = ['aaa','b','cc','d','eeeee','f','g','h','i','j','k','l']
675 678 In [2]: list, info = compute_item_matrix(l, displaywidth=12)
676 679 In [3]: list
677 680 Out[3]: [['aaa', 'f', 'k'], ['b', 'g', 'l'], ['cc', 'h', None], ['d', 'i', None], ['eeeee', 'j', None]]
678 681 In [4]: ideal = {'num_columns': 3, 'column_widths': [5, 1, 1], 'optimal_separator_width': 2, 'max_rows': 5}
679 682 In [5]: all((info[k] == ideal[k] for k in ideal.keys()))
680 683 Out[5]: True
681 684 """
682 685 info = _find_optimal(list(map(len, items)), row_first, *args, **kwargs)
683 686 nrow, ncol = info['max_rows'], info['num_columns']
684 687 if row_first:
685 688 return ([[_get_or_default(items, r * ncol + c, default=empty) for c in range(ncol)] for r in range(nrow)], info)
686 689 else:
687 690 return ([[_get_or_default(items, c * nrow + r, default=empty) for c in range(ncol)] for r in range(nrow)], info)
688 691
689 692
690 693 def columnize(items, row_first=False, separator=' ', displaywidth=80, spread=False):
691 694 """ Transform a list of strings into a single string with columns.
692 695
693 696 Parameters
694 697 ----------
695 698 items : sequence of strings
696 699 The strings to process.
697 700 row_first : (default False)
698 701 Whether to compute columns for a row-first matrix instead of
699 702 column-first (default).
700 703 separator : str, optional [default is two spaces]
701 704 The string that separates columns.
702 705 displaywidth : int, optional [default is 80]
703 706 Width of the display in number of characters.
704 707
705 708 Returns
706 709 -------
707 710 The formatted string.
708 711 """
709 712 if not items:
710 713 return '\n'
711 714 matrix, info = compute_item_matrix(items, row_first=row_first, separator_size=len(separator), displaywidth=displaywidth)
712 715 if spread:
713 716 separator = separator.ljust(int(info['optimal_separator_width']))
714 717 fmatrix = [filter(None, x) for x in matrix]
715 718 sjoin = lambda x : separator.join([ y.ljust(w, ' ') for y, w in zip(x, info['column_widths'])])
716 719 return '\n'.join(map(sjoin, fmatrix))+'\n'
717 720
718 721
719 722 def get_text_list(list_, last_sep=' and ', sep=", ", wrap_item_with=""):
720 723 """
721 724 Return a string with a natural enumeration of items
722 725
723 726 >>> get_text_list(['a', 'b', 'c', 'd'])
724 727 'a, b, c and d'
725 728 >>> get_text_list(['a', 'b', 'c'], ' or ')
726 729 'a, b or c'
727 730 >>> get_text_list(['a', 'b', 'c'], ', ')
728 731 'a, b, c'
729 732 >>> get_text_list(['a', 'b'], ' or ')
730 733 'a or b'
731 734 >>> get_text_list(['a'])
732 735 'a'
733 736 >>> get_text_list([])
734 737 ''
735 738 >>> get_text_list(['a', 'b'], wrap_item_with="`")
736 739 '`a` and `b`'
737 740 >>> get_text_list(['a', 'b', 'c', 'd'], " = ", sep=" + ")
738 741 'a + b + c = d'
739 742 """
740 743 if len(list_) == 0:
741 744 return ''
742 745 if wrap_item_with:
743 746 list_ = ['%s%s%s' % (wrap_item_with, item, wrap_item_with) for
744 747 item in list_]
745 748 if len(list_) == 1:
746 749 return list_[0]
747 750 return '%s%s%s' % (
748 751 sep.join(i for i in list_[:-1]),
749 752 last_sep, list_[-1])
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