"""Completion for IPython. This module started as fork of the rlcompleter module in the Python standard library. The original enhancements made to rlcompleter have been sent upstream and were accepted as of Python 2.3, This module now support a wide variety of completion mechanism both available for normal classic Python code, as well as completer for IPython specific Syntax like magics. Latex and Unicode completion ============================ IPython and compatible frontends not only can complete your code, but can help you to input a wide range of characters. In particular we allow you to insert a unicode character using the tab completion mechanism. Forward latex/unicode completion -------------------------------- Forward completion allows you to easily type a unicode character using its latex name, or unicode long description. To do so type a backslash follow by the relevant name and press tab: Using latex completion: .. code:: \\alpha α or using unicode completion: .. code:: \\GREEK SMALL LETTER ALPHA α Only valid Python identifiers will complete. Combining characters (like arrow or dots) are also available, unlike latex they need to be put after the their counterpart that is to say, `F\\\\vec` is correct, not `\\\\vecF`. Some browsers are known to display combining characters incorrectly. Backward latex completion ------------------------- It is sometime challenging to know how to type a character, if you are using IPython, or any compatible frontend you can prepend backslash to the character and press `` to expand it to its latex form. .. code:: \\α \\alpha Both forward and backward completions can be deactivated by setting the ``Completer.backslash_combining_completions`` option to ``False``. Experimental ============ Starting with IPython 6.0, this module can make use of the Jedi library to generate completions both using static analysis of the code, and dynamically inspecting multiple namespaces. Jedi is an autocompletion and static analysis for Python. The APIs attached to this new mechanism is unstable and will raise unless use in an :any:`provisionalcompleter` context manager. You will find that the following are experimental: - :any:`provisionalcompleter` - :any:`IPCompleter.completions` - :any:`Completion` - :any:`rectify_completions` .. note:: better name for :any:`rectify_completions` ? We welcome any feedback on these new API, and we also encourage you to try this module in debug mode (start IPython with ``--Completer.debug=True``) in order to have extra logging information if :any:`jedi` is crashing, or if current IPython completer pending deprecations are returning results not yet handled by :any:`jedi` Using Jedi for tab completion allow snippets like the following to work without having to execute any code: >>> myvar = ['hello', 42] ... myvar[1].bi Tab completion will be able to infer that ``myvar[1]`` is a real number without executing any code unlike the previously available ``IPCompleter.greedy`` option. Be sure to update :any:`jedi` to the latest stable version or to try the current development version to get better completions. """ # Copyright (c) IPython Development Team. # Distributed under the terms of the Modified BSD License. # # Some of this code originated from rlcompleter in the Python standard library # Copyright (C) 2001 Python Software Foundation, www.python.org import builtins as builtin_mod import glob import inspect import itertools import keyword import os import re import string import sys import time import unicodedata import uuid import warnings from contextlib import contextmanager from importlib import import_module from types import SimpleNamespace from typing import Iterable, Iterator, List, Tuple, Union, Any, Sequence, Dict, NamedTuple, Pattern, Optional from IPython.core.error import TryNext from IPython.core.inputtransformer2 import ESC_MAGIC from IPython.core.latex_symbols import latex_symbols, reverse_latex_symbol from IPython.core.oinspect import InspectColors from IPython.utils import generics from IPython.utils.dir2 import dir2, get_real_method from IPython.utils.path import ensure_dir_exists from IPython.utils.process import arg_split from traitlets import Bool, Enum, Int, List as ListTrait, Unicode, default, observe from traitlets.config.configurable import Configurable import __main__ # skip module docstests skip_doctest = True try: import jedi jedi.settings.case_insensitive_completion = False import jedi.api.helpers import jedi.api.classes JEDI_INSTALLED = True except ImportError: JEDI_INSTALLED = False #----------------------------------------------------------------------------- # Globals #----------------------------------------------------------------------------- # Public API __all__ = ['Completer','IPCompleter'] if sys.platform == 'win32': PROTECTABLES = ' ' else: PROTECTABLES = ' ()[]{}?=\\|;:\'#*"^&' # Protect against returning an enormous number of completions which the frontend # may have trouble processing. MATCHES_LIMIT = 500 _deprecation_readline_sentinel = object() class ProvisionalCompleterWarning(FutureWarning): """ Exception raise by an experimental feature in this module. Wrap code in :any:`provisionalcompleter` context manager if you are certain you want to use an unstable feature. """ pass warnings.filterwarnings('error', category=ProvisionalCompleterWarning) @contextmanager def provisionalcompleter(action='ignore'): """ This context manager has to be used in any place where unstable completer behavior and API may be called. >>> with provisionalcompleter(): ... completer.do_experimental_things() # works >>> completer.do_experimental_things() # raises. .. note:: Unstable By using this context manager you agree that the API in use may change without warning, and that you won't complain if they do so. You also understand that, if the API is not to your liking, you should report a bug to explain your use case upstream. We'll be happy to get your feedback, feature requests, and improvements on any of the unstable APIs! """ with warnings.catch_warnings(): warnings.filterwarnings(action, category=ProvisionalCompleterWarning) yield def has_open_quotes(s): """Return whether a string has open quotes. This simply counts whether the number of quote characters of either type in the string is odd. Returns ------- If there is an open quote, the quote character is returned. Else, return False. """ # We check " first, then ', so complex cases with nested quotes will get # the " to take precedence. if s.count('"') % 2: return '"' elif s.count("'") % 2: return "'" else: return False def protect_filename(s, protectables=PROTECTABLES): """Escape a string to protect certain characters.""" if set(s) & set(protectables): if sys.platform == "win32": return '"' + s + '"' else: return "".join(("\\" + c if c in protectables else c) for c in s) else: return s def expand_user(path:str) -> Tuple[str, bool, str]: """Expand ``~``-style usernames in strings. This is similar to :func:`os.path.expanduser`, but it computes and returns extra information that will be useful if the input was being used in computing completions, and you wish to return the completions with the original '~' instead of its expanded value. Parameters ---------- path : str String to be expanded. If no ~ is present, the output is the same as the input. Returns ------- newpath : str Result of ~ expansion in the input path. tilde_expand : bool Whether any expansion was performed or not. tilde_val : str The value that ~ was replaced with. """ # Default values tilde_expand = False tilde_val = '' newpath = path if path.startswith('~'): tilde_expand = True rest = len(path)-1 newpath = os.path.expanduser(path) if rest: tilde_val = newpath[:-rest] else: tilde_val = newpath return newpath, tilde_expand, tilde_val def compress_user(path:str, tilde_expand:bool, tilde_val:str) -> str: """Does the opposite of expand_user, with its outputs. """ if tilde_expand: return path.replace(tilde_val, '~') else: return path def completions_sorting_key(word): """key for sorting completions This does several things: - Demote any completions starting with underscores to the end - Insert any %magic and %%cellmagic completions in the alphabetical order by their name """ prio1, prio2 = 0, 0 if word.startswith('__'): prio1 = 2 elif word.startswith('_'): prio1 = 1 if word.endswith('='): prio1 = -1 if word.startswith('%%'): # If there's another % in there, this is something else, so leave it alone if not "%" in word[2:]: word = word[2:] prio2 = 2 elif word.startswith('%'): if not "%" in word[1:]: word = word[1:] prio2 = 1 return prio1, word, prio2 class _FakeJediCompletion: """ This is a workaround to communicate to the UI that Jedi has crashed and to report a bug. Will be used only id :any:`IPCompleter.debug` is set to true. Added in IPython 6.0 so should likely be removed for 7.0 """ def __init__(self, name): self.name = name self.complete = name self.type = 'crashed' self.name_with_symbols = name self.signature = '' self._origin = 'fake' def __repr__(self): return '' class Completion: """ Completion object used and return by IPython completers. .. warning:: Unstable This function is unstable, API may change without warning. It will also raise unless use in proper context manager. This act as a middle ground :any:`Completion` object between the :any:`jedi.api.classes.Completion` object and the Prompt Toolkit completion object. While Jedi need a lot of information about evaluator and how the code should be ran/inspected, PromptToolkit (and other frontend) mostly need user facing information. - Which range should be replaced replaced by what. - Some metadata (like completion type), or meta information to displayed to the use user. For debugging purpose we can also store the origin of the completion (``jedi``, ``IPython.python_matches``, ``IPython.magics_matches``...). """ __slots__ = ['start', 'end', 'text', 'type', 'signature', '_origin'] def __init__(self, start: int, end: int, text: str, *, type: str=None, _origin='', signature='') -> None: warnings.warn("``Completion`` is a provisional API (as of IPython 6.0). " "It may change without warnings. " "Use in corresponding context manager.", category=ProvisionalCompleterWarning, stacklevel=2) self.start = start self.end = end self.text = text self.type = type self.signature = signature self._origin = _origin def __repr__(self): return '' % \ (self.start, self.end, self.text, self.type or '?', self.signature or '?') def __eq__(self, other)->Bool: """ Equality and hash do not hash the type (as some completer may not be able to infer the type), but are use to (partially) de-duplicate completion. Completely de-duplicating completion is a bit tricker that just comparing as it depends on surrounding text, which Completions are not aware of. """ return self.start == other.start and \ self.end == other.end and \ self.text == other.text def __hash__(self): return hash((self.start, self.end, self.text)) _IC = Iterable[Completion] def _deduplicate_completions(text: str, completions: _IC)-> _IC: """ Deduplicate a set of completions. .. warning:: Unstable This function is unstable, API may change without warning. Parameters ---------- text: str text that should be completed. completions: Iterator[Completion] iterator over the completions to deduplicate Yields ------ `Completions` objects Completions coming from multiple sources, may be different but end up having the same effect when applied to ``text``. If this is the case, this will consider completions as equal and only emit the first encountered. Not folded in `completions()` yet for debugging purpose, and to detect when the IPython completer does return things that Jedi does not, but should be at some point. """ completions = list(completions) if not completions: return new_start = min(c.start for c in completions) new_end = max(c.end for c in completions) seen = set() for c in completions: new_text = text[new_start:c.start] + c.text + text[c.end:new_end] if new_text not in seen: yield c seen.add(new_text) def rectify_completions(text: str, completions: _IC, *, _debug=False)->_IC: """ Rectify a set of completions to all have the same ``start`` and ``end`` .. warning:: Unstable This function is unstable, API may change without warning. It will also raise unless use in proper context manager. Parameters ---------- text: str text that should be completed. completions: Iterator[Completion] iterator over the completions to rectify :any:`jedi.api.classes.Completion` s returned by Jedi may not have the same start and end, though the Jupyter Protocol requires them to behave like so. This will readjust the completion to have the same ``start`` and ``end`` by padding both extremities with surrounding text. During stabilisation should support a ``_debug`` option to log which completion are return by the IPython completer and not found in Jedi in order to make upstream bug report. """ warnings.warn("`rectify_completions` is a provisional API (as of IPython 6.0). " "It may change without warnings. " "Use in corresponding context manager.", category=ProvisionalCompleterWarning, stacklevel=2) completions = list(completions) if not completions: return starts = (c.start for c in completions) ends = (c.end for c in completions) new_start = min(starts) new_end = max(ends) seen_jedi = set() seen_python_matches = set() for c in completions: new_text = text[new_start:c.start] + c.text + text[c.end:new_end] if c._origin == 'jedi': seen_jedi.add(new_text) elif c._origin == 'IPCompleter.python_matches': seen_python_matches.add(new_text) yield Completion(new_start, new_end, new_text, type=c.type, _origin=c._origin, signature=c.signature) diff = seen_python_matches.difference(seen_jedi) if diff and _debug: print('IPython.python matches have extras:', diff) if sys.platform == 'win32': DELIMS = ' \t\n`!@#$^&*()=+[{]}|;\'",<>?' else: DELIMS = ' \t\n`!@#$^&*()=+[{]}\\|;:\'",<>?' GREEDY_DELIMS = ' =\r\n' class CompletionSplitter(object): """An object to split an input line in a manner similar to readline. By having our own implementation, we can expose readline-like completion in a uniform manner to all frontends. This object only needs to be given the line of text to be split and the cursor position on said line, and it returns the 'word' to be completed on at the cursor after splitting the entire line. What characters are used as splitting delimiters can be controlled by setting the ``delims`` attribute (this is a property that internally automatically builds the necessary regular expression)""" # Private interface # A string of delimiter characters. The default value makes sense for # IPython's most typical usage patterns. _delims = DELIMS # The expression (a normal string) to be compiled into a regular expression # for actual splitting. We store it as an attribute mostly for ease of # debugging, since this type of code can be so tricky to debug. _delim_expr = None # The regular expression that does the actual splitting _delim_re = None def __init__(self, delims=None): delims = CompletionSplitter._delims if delims is None else delims self.delims = delims @property def delims(self): """Return the string of delimiter characters.""" return self._delims @delims.setter def delims(self, delims): """Set the delimiters for line splitting.""" expr = '[' + ''.join('\\'+ c for c in delims) + ']' self._delim_re = re.compile(expr) self._delims = delims self._delim_expr = expr def split_line(self, line, cursor_pos=None): """Split a line of text with a cursor at the given position. """ l = line if cursor_pos is None else line[:cursor_pos] return self._delim_re.split(l)[-1] class Completer(Configurable): greedy = Bool(False, help="""Activate greedy completion PENDING DEPRECTION. this is now mostly taken care of with Jedi. This will enable completion on elements of lists, results of function calls, etc., but can be unsafe because the code is actually evaluated on TAB. """ ).tag(config=True) use_jedi = Bool(default_value=JEDI_INSTALLED, help="Experimental: Use Jedi to generate autocompletions. " "Default to True if jedi is installed.").tag(config=True) jedi_compute_type_timeout = Int(default_value=400, help="""Experimental: restrict time (in milliseconds) during which Jedi can compute types. Set to 0 to stop computing types. Non-zero value lower than 100ms may hurt performance by preventing jedi to build its cache. """).tag(config=True) debug = Bool(default_value=False, help='Enable debug for the Completer. Mostly print extra ' 'information for experimental jedi integration.')\ .tag(config=True) backslash_combining_completions = Bool(True, help="Enable unicode completions, e.g. \\alpha . " "Includes completion of latex commands, unicode names, and expanding " "unicode characters back to latex commands.").tag(config=True) def __init__(self, namespace=None, global_namespace=None, **kwargs): """Create a new completer for the command line. Completer(namespace=ns, global_namespace=ns2) -> completer instance. If unspecified, the default namespace where completions are performed is __main__ (technically, __main__.__dict__). Namespaces should be given as dictionaries. An optional second namespace can be given. This allows the completer to handle cases where both the local and global scopes need to be distinguished. """ # Don't bind to namespace quite yet, but flag whether the user wants a # specific namespace or to use __main__.__dict__. This will allow us # to bind to __main__.__dict__ at completion time, not now. if namespace is None: self.use_main_ns = True else: self.use_main_ns = False self.namespace = namespace # The global namespace, if given, can be bound directly if global_namespace is None: self.global_namespace = {} else: self.global_namespace = global_namespace self.custom_matchers = [] super(Completer, self).__init__(**kwargs) def complete(self, text, state): """Return the next possible completion for 'text'. This is called successively with state == 0, 1, 2, ... until it returns None. The completion should begin with 'text'. """ if self.use_main_ns: self.namespace = __main__.__dict__ if state == 0: if "." in text: self.matches = self.attr_matches(text) else: self.matches = self.global_matches(text) try: return self.matches[state] except IndexError: return None def global_matches(self, text): """Compute matches when text is a simple name. Return a list of all keywords, built-in functions and names currently defined in self.namespace or self.global_namespace that match. """ matches = [] match_append = matches.append n = len(text) for lst in [keyword.kwlist, builtin_mod.__dict__.keys(), self.namespace.keys(), self.global_namespace.keys()]: for word in lst: if word[:n] == text and word != "__builtins__": match_append(word) snake_case_re = re.compile(r"[^_]+(_[^_]+)+?\Z") for lst in [self.namespace.keys(), self.global_namespace.keys()]: shortened = {"_".join([sub[0] for sub in word.split('_')]) : word for word in lst if snake_case_re.match(word)} for word in shortened.keys(): if word[:n] == text and word != "__builtins__": match_append(shortened[word]) return matches def attr_matches(self, text): """Compute matches when text contains a dot. Assuming the text is of the form NAME.NAME....[NAME], and is evaluatable in self.namespace or self.global_namespace, it will be evaluated and its attributes (as revealed by dir()) are used as possible completions. (For class instances, class members are also considered.) WARNING: this can still invoke arbitrary C code, if an object with a __getattr__ hook is evaluated. """ # Another option, seems to work great. Catches things like ''. m = re.match(r"(\S+(\.\w+)*)\.(\w*)$", text) if m: expr, attr = m.group(1, 3) elif self.greedy: m2 = re.match(r"(.+)\.(\w*)$", self.line_buffer) if not m2: return [] expr, attr = m2.group(1,2) else: return [] try: obj = eval(expr, self.namespace) except: try: obj = eval(expr, self.global_namespace) except: return [] if self.limit_to__all__ and hasattr(obj, '__all__'): words = get__all__entries(obj) else: words = dir2(obj) try: words = generics.complete_object(obj, words) except TryNext: pass except AssertionError: raise except Exception: # Silence errors from completion function #raise # dbg pass # Build match list to return n = len(attr) return [u"%s.%s" % (expr, w) for w in words if w[:n] == attr ] def get__all__entries(obj): """returns the strings in the __all__ attribute""" try: words = getattr(obj, '__all__') except: return [] return [w for w in words if isinstance(w, str)] def match_dict_keys(keys: List[Union[str, bytes]], prefix: str, delims: str) -> Tuple[str, int, List[str]]: """Used by dict_key_matches, matching the prefix to a list of keys Parameters ========== keys: list of keys in dictionary currently being completed. prefix: Part of the text already typed by the user. e.g. `mydict[b'fo` delims: String of delimiters to consider when finding the current key. Returns ======= A tuple of three elements: ``quote``, ``token_start``, ``matched``, with ``quote`` being the quote that need to be used to close current string. ``token_start`` the position where the replacement should start occurring, ``matches`` a list of replacement/completion """ keys = [k for k in keys if isinstance(k, (str, bytes))] if not prefix: return '', 0, [repr(k) for k in keys if isinstance(k, (str, bytes))] quote_match = re.search('["\']', prefix) assert quote_match is not None # silence mypy quote = quote_match.group() try: prefix_str = eval(prefix + quote, {}) except Exception: return '', 0, [] pattern = '[^' + ''.join('\\' + c for c in delims) + ']*$' token_match = re.search(pattern, prefix, re.UNICODE) assert token_match is not None # silence mypy token_start = token_match.start() token_prefix = token_match.group() matched:List[str] = [] for key in keys: try: if not key.startswith(prefix_str): continue except (AttributeError, TypeError, UnicodeError): # Python 3+ TypeError on b'a'.startswith('a') or vice-versa continue # reformat remainder of key to begin with prefix rem = key[len(prefix_str):] # force repr wrapped in ' rem_repr = repr(rem + '"') if isinstance(rem, str) else repr(rem + b'"') rem_repr = rem_repr[1 + rem_repr.index("'"):-2] if quote == '"': # The entered prefix is quoted with ", # but the match is quoted with '. # A contained " hence needs escaping for comparison: rem_repr = rem_repr.replace('"', '\\"') # then reinsert prefix from start of token matched.append('%s%s' % (token_prefix, rem_repr)) return quote, token_start, matched def cursor_to_position(text:str, line:int, column:int)->int: """ Convert the (line,column) position of the cursor in text to an offset in a string. Parameters ---------- text : str The text in which to calculate the cursor offset line : int Line of the cursor; 0-indexed column : int Column of the cursor 0-indexed Return ------ Position of the cursor in ``text``, 0-indexed. See Also -------- position_to_cursor: reciprocal of this function """ lines = text.split('\n') assert line <= len(lines), '{} <= {}'.format(str(line), str(len(lines))) return sum(len(l) + 1 for l in lines[:line]) + column def position_to_cursor(text:str, offset:int)->Tuple[int, int]: """ Convert the position of the cursor in text (0 indexed) to a line number(0-indexed) and a column number (0-indexed) pair Position should be a valid position in ``text``. Parameters ---------- text : str The text in which to calculate the cursor offset offset : int Position of the cursor in ``text``, 0-indexed. Return ------ (line, column) : (int, int) Line of the cursor; 0-indexed, column of the cursor 0-indexed See Also -------- cursor_to_position : reciprocal of this function """ assert 0 <= offset <= len(text) , "0 <= %s <= %s" % (offset , len(text)) before = text[:offset] blines = before.split('\n') # ! splitnes trim trailing \n line = before.count('\n') col = len(blines[-1]) return line, col def _safe_isinstance(obj, module, class_name): """Checks if obj is an instance of module.class_name if loaded """ return (module in sys.modules and isinstance(obj, getattr(import_module(module), class_name))) def back_unicode_name_matches(text:str) -> Tuple[str, Sequence[str]]: """Match Unicode characters back to Unicode name This does ``☃`` -> ``\\snowman`` Note that snowman is not a valid python3 combining character but will be expanded. Though it will not recombine back to the snowman character by the completion machinery. This will not either back-complete standard sequences like \\n, \\b ... Returns ======= Return a tuple with two elements: - The Unicode character that was matched (preceded with a backslash), or empty string, - a sequence (of 1), name for the match Unicode character, preceded by backslash, or empty if no match. """ if len(text)<2: return '', () maybe_slash = text[-2] if maybe_slash != '\\': return '', () char = text[-1] # no expand on quote for completion in strings. # nor backcomplete standard ascii keys if char in string.ascii_letters or char in ('"',"'"): return '', () try : unic = unicodedata.name(char) return '\\'+char,('\\'+unic,) except KeyError: pass return '', () def back_latex_name_matches(text:str) -> Tuple[str, Sequence[str]] : """Match latex characters back to unicode name This does ``\\ℵ`` -> ``\\aleph`` """ if len(text)<2: return '', () maybe_slash = text[-2] if maybe_slash != '\\': return '', () char = text[-1] # no expand on quote for completion in strings. # nor backcomplete standard ascii keys if char in string.ascii_letters or char in ('"',"'"): return '', () try : latex = reverse_latex_symbol[char] # '\\' replace the \ as well return '\\'+char,[latex] except KeyError: pass return '', () def _formatparamchildren(parameter) -> str: """ Get parameter name and value from Jedi Private API Jedi does not expose a simple way to get `param=value` from its API. Parameter ========= parameter: Jedi's function `Param` Returns ======= A string like 'a', 'b=1', '*args', '**kwargs' """ description = parameter.description if not description.startswith('param '): raise ValueError('Jedi function parameter description have change format.' 'Expected "param ...", found %r".' % description) return description[6:] def _make_signature(completion)-> str: """ Make the signature from a jedi completion Parameter ========= completion: jedi.Completion object does not complete a function type Returns ======= a string consisting of the function signature, with the parenthesis but without the function name. example: `(a, *args, b=1, **kwargs)` """ # it looks like this might work on jedi 0.17 if hasattr(completion, 'get_signatures'): signatures = completion.get_signatures() if not signatures: return '(?)' c0 = completion.get_signatures()[0] return '('+c0.to_string().split('(', maxsplit=1)[1] return '(%s)'% ', '.join([f for f in (_formatparamchildren(p) for signature in completion.get_signatures() for p in signature.defined_names()) if f]) class _CompleteResult(NamedTuple): matched_text : str matches: Sequence[str] matches_origin: Sequence[str] jedi_matches: Any class IPCompleter(Completer): """Extension of the completer class with IPython-specific features""" __dict_key_regexps: Optional[Dict[bool,Pattern]] = None @observe('greedy') def _greedy_changed(self, change): """update the splitter and readline delims when greedy is changed""" if change['new']: self.splitter.delims = GREEDY_DELIMS else: self.splitter.delims = DELIMS dict_keys_only = Bool(False, help="""Whether to show dict key matches only""") merge_completions = Bool(True, help="""Whether to merge completion results into a single list If False, only the completion results from the first non-empty completer will be returned. """ ).tag(config=True) omit__names = Enum((0,1,2), default_value=2, help="""Instruct the completer to omit private method names Specifically, when completing on ``object.``. When 2 [default]: all names that start with '_' will be excluded. When 1: all 'magic' names (``__foo__``) will be excluded. When 0: nothing will be excluded. """ ).tag(config=True) limit_to__all__ = Bool(False, help=""" DEPRECATED as of version 5.0. Instruct the completer to use __all__ for the completion Specifically, when completing on ``object.``. When True: only those names in obj.__all__ will be included. When False [default]: the __all__ attribute is ignored """, ).tag(config=True) profile_completions = Bool( default_value=False, help="If True, emit profiling data for completion subsystem using cProfile." ).tag(config=True) profiler_output_dir = Unicode( default_value=".completion_profiles", help="Template for path at which to output profile data for completions." ).tag(config=True) @observe('limit_to__all__') def _limit_to_all_changed(self, change): warnings.warn('`IPython.core.IPCompleter.limit_to__all__` configuration ' 'value has been deprecated since IPython 5.0, will be made to have ' 'no effects and then removed in future version of IPython.', UserWarning) def __init__(self, shell=None, namespace=None, global_namespace=None, use_readline=_deprecation_readline_sentinel, config=None, **kwargs): """IPCompleter() -> completer Return a completer object. Parameters ---------- shell a pointer to the ipython shell itself. This is needed because this completer knows about magic functions, and those can only be accessed via the ipython instance. namespace : dict, optional an optional dict where completions are performed. global_namespace : dict, optional secondary optional dict for completions, to handle cases (such as IPython embedded inside functions) where both Python scopes are visible. use_readline : bool, optional DEPRECATED, ignored since IPython 6.0, will have no effects """ self.magic_escape = ESC_MAGIC self.splitter = CompletionSplitter() if use_readline is not _deprecation_readline_sentinel: warnings.warn('The `use_readline` parameter is deprecated and ignored since IPython 6.0.', DeprecationWarning, stacklevel=2) # _greedy_changed() depends on splitter and readline being defined: Completer.__init__(self, namespace=namespace, global_namespace=global_namespace, config=config, **kwargs) # List where completion matches will be stored self.matches = [] self.shell = shell # Regexp to split filenames with spaces in them self.space_name_re = re.compile(r'([^\\] )') # Hold a local ref. to glob.glob for speed self.glob = glob.glob # Determine if we are running on 'dumb' terminals, like (X)Emacs # buffers, to avoid completion problems. term = os.environ.get('TERM','xterm') self.dumb_terminal = term in ['dumb','emacs'] # Special handling of backslashes needed in win32 platforms if sys.platform == "win32": self.clean_glob = self._clean_glob_win32 else: self.clean_glob = self._clean_glob #regexp to parse docstring for function signature self.docstring_sig_re = re.compile(r'^[\w|\s.]+\(([^)]*)\).*') self.docstring_kwd_re = re.compile(r'[\s|\[]*(\w+)(?:\s*=\s*.*)') #use this if positional argument name is also needed #= re.compile(r'[\s|\[]*(\w+)(?:\s*=?\s*.*)') self.magic_arg_matchers = [ self.magic_config_matches, self.magic_color_matches, ] # This is set externally by InteractiveShell self.custom_completers = None # This is a list of names of unicode characters that can be completed # into their corresponding unicode value. The list is large, so we # laziliy initialize it on first use. Consuming code should access this # attribute through the `@unicode_names` property. self._unicode_names = None @property def matchers(self) -> List[Any]: """All active matcher routines for completion""" if self.dict_keys_only: return [self.dict_key_matches] if self.use_jedi: return [ *self.custom_matchers, self.file_matches, self.magic_matches, self.dict_key_matches, ] else: return [ *self.custom_matchers, self.python_matches, self.file_matches, self.magic_matches, self.python_func_kw_matches, self.dict_key_matches, ] def all_completions(self, text:str) -> List[str]: """ Wrapper around the completion methods for the benefit of emacs. """ prefix = text.rpartition('.')[0] with provisionalcompleter(): return ['.'.join([prefix, c.text]) if prefix and self.use_jedi else c.text for c in self.completions(text, len(text))] return self.complete(text)[1] def _clean_glob(self, text:str): return self.glob("%s*" % text) def _clean_glob_win32(self, text:str): return [f.replace("\\","/") for f in self.glob("%s*" % text)] def file_matches(self, text:str)->List[str]: """Match filenames, expanding ~USER type strings. Most of the seemingly convoluted logic in this completer is an attempt to handle filenames with spaces in them. And yet it's not quite perfect, because Python's readline doesn't expose all of the GNU readline details needed for this to be done correctly. For a filename with a space in it, the printed completions will be only the parts after what's already been typed (instead of the full completions, as is normally done). I don't think with the current (as of Python 2.3) Python readline it's possible to do better.""" # chars that require escaping with backslash - i.e. chars # that readline treats incorrectly as delimiters, but we # don't want to treat as delimiters in filename matching # when escaped with backslash if text.startswith('!'): text = text[1:] text_prefix = u'!' else: text_prefix = u'' text_until_cursor = self.text_until_cursor # track strings with open quotes open_quotes = has_open_quotes(text_until_cursor) if '(' in text_until_cursor or '[' in text_until_cursor: lsplit = text else: try: # arg_split ~ shlex.split, but with unicode bugs fixed by us lsplit = arg_split(text_until_cursor)[-1] except ValueError: # typically an unmatched ", or backslash without escaped char. if open_quotes: lsplit = text_until_cursor.split(open_quotes)[-1] else: return [] except IndexError: # tab pressed on empty line lsplit = "" if not open_quotes and lsplit != protect_filename(lsplit): # if protectables are found, do matching on the whole escaped name has_protectables = True text0,text = text,lsplit else: has_protectables = False text = os.path.expanduser(text) if text == "": return [text_prefix + protect_filename(f) for f in self.glob("*")] # Compute the matches from the filesystem if sys.platform == 'win32': m0 = self.clean_glob(text) else: m0 = self.clean_glob(text.replace('\\', '')) if has_protectables: # If we had protectables, we need to revert our changes to the # beginning of filename so that we don't double-write the part # of the filename we have so far len_lsplit = len(lsplit) matches = [text_prefix + text0 + protect_filename(f[len_lsplit:]) for f in m0] else: if open_quotes: # if we have a string with an open quote, we don't need to # protect the names beyond the quote (and we _shouldn't_, as # it would cause bugs when the filesystem call is made). matches = m0 if sys.platform == "win32" else\ [protect_filename(f, open_quotes) for f in m0] else: matches = [text_prefix + protect_filename(f) for f in m0] # Mark directories in input list by appending '/' to their names. return [x+'/' if os.path.isdir(x) else x for x in matches] def magic_matches(self, text:str): """Match magics""" # Get all shell magics now rather than statically, so magics loaded at # runtime show up too. lsm = self.shell.magics_manager.lsmagic() line_magics = lsm['line'] cell_magics = lsm['cell'] pre = self.magic_escape pre2 = pre+pre explicit_magic = text.startswith(pre) # Completion logic: # - user gives %%: only do cell magics # - user gives %: do both line and cell magics # - no prefix: do both # In other words, line magics are skipped if the user gives %% explicitly # # We also exclude magics that match any currently visible names: # https://github.com/ipython/ipython/issues/4877, unless the user has # typed a %: # https://github.com/ipython/ipython/issues/10754 bare_text = text.lstrip(pre) global_matches = self.global_matches(bare_text) if not explicit_magic: def matches(magic): """ Filter magics, in particular remove magics that match a name present in global namespace. """ return ( magic.startswith(bare_text) and magic not in global_matches ) else: def matches(magic): return magic.startswith(bare_text) comp = [ pre2+m for m in cell_magics if matches(m)] if not text.startswith(pre2): comp += [ pre+m for m in line_magics if matches(m)] return comp def magic_config_matches(self, text:str) -> List[str]: """ Match class names and attributes for %config magic """ texts = text.strip().split() if len(texts) > 0 and (texts[0] == 'config' or texts[0] == '%config'): # get all configuration classes classes = sorted(set([ c for c in self.shell.configurables if c.__class__.class_traits(config=True) ]), key=lambda x: x.__class__.__name__) classnames = [ c.__class__.__name__ for c in classes ] # return all classnames if config or %config is given if len(texts) == 1: return classnames # match classname classname_texts = texts[1].split('.') classname = classname_texts[0] classname_matches = [ c for c in classnames if c.startswith(classname) ] # return matched classes or the matched class with attributes if texts[1].find('.') < 0: return classname_matches elif len(classname_matches) == 1 and \ classname_matches[0] == classname: cls = classes[classnames.index(classname)].__class__ help = cls.class_get_help() # strip leading '--' from cl-args: help = re.sub(re.compile(r'^--', re.MULTILINE), '', help) return [ attr.split('=')[0] for attr in help.strip().splitlines() if attr.startswith(texts[1]) ] return [] def magic_color_matches(self, text:str) -> List[str] : """ Match color schemes for %colors magic""" texts = text.split() if text.endswith(' '): # .split() strips off the trailing whitespace. Add '' back # so that: '%colors ' -> ['%colors', ''] texts.append('') if len(texts) == 2 and (texts[0] == 'colors' or texts[0] == '%colors'): prefix = texts[1] return [ color for color in InspectColors.keys() if color.startswith(prefix) ] return [] def _jedi_matches(self, cursor_column:int, cursor_line:int, text:str) -> Iterable[Any]: """ Return a list of :any:`jedi.api.Completions` object from a ``text`` and cursor position. Parameters ---------- cursor_column : int column position of the cursor in ``text``, 0-indexed. cursor_line : int line position of the cursor in ``text``, 0-indexed text : str text to complete Debugging --------- If ``IPCompleter.debug`` is ``True`` may return a :any:`_FakeJediCompletion` object containing a string with the Jedi debug information attached. """ namespaces = [self.namespace] if self.global_namespace is not None: namespaces.append(self.global_namespace) completion_filter = lambda x:x offset = cursor_to_position(text, cursor_line, cursor_column) # filter output if we are completing for object members if offset: pre = text[offset-1] if pre == '.': if self.omit__names == 2: completion_filter = lambda c:not c.name.startswith('_') elif self.omit__names == 1: completion_filter = lambda c:not (c.name.startswith('__') and c.name.endswith('__')) elif self.omit__names == 0: completion_filter = lambda x:x else: raise ValueError("Don't understand self.omit__names == {}".format(self.omit__names)) interpreter = jedi.Interpreter(text[:offset], namespaces) try_jedi = True try: # find the first token in the current tree -- if it is a ' or " then we are in a string completing_string = False try: first_child = next(c for c in interpreter._get_module().tree_node.children if hasattr(c, 'value')) except StopIteration: pass else: # note the value may be ', ", or it may also be ''' or """, or # in some cases, """what/you/typed..., but all of these are # strings. completing_string = len(first_child.value) > 0 and first_child.value[0] in {"'", '"'} # if we are in a string jedi is likely not the right candidate for # now. Skip it. try_jedi = not completing_string except Exception as e: # many of things can go wrong, we are using private API just don't crash. if self.debug: print("Error detecting if completing a non-finished string :", e, '|') if not try_jedi: return [] try: return filter(completion_filter, interpreter.complete(column=cursor_column, line=cursor_line + 1)) except Exception as e: if self.debug: return [_FakeJediCompletion('Oops Jedi has crashed, please report a bug with the following:\n"""\n%s\ns"""' % (e))] else: return [] def python_matches(self, text:str)->List[str]: """Match attributes or global python names""" if "." in text: try: matches = self.attr_matches(text) if text.endswith('.') and self.omit__names: if self.omit__names == 1: # true if txt is _not_ a __ name, false otherwise: no__name = (lambda txt: re.match(r'.*\.__.*?__',txt) is None) else: # true if txt is _not_ a _ name, false otherwise: no__name = (lambda txt: re.match(r'\._.*?',txt[txt.rindex('.'):]) is None) matches = filter(no__name, matches) except NameError: # catches . matches = [] else: matches = self.global_matches(text) return matches def _default_arguments_from_docstring(self, doc): """Parse the first line of docstring for call signature. Docstring should be of the form 'min(iterable[, key=func])\n'. It can also parse cython docstring of the form 'Minuit.migrad(self, int ncall=10000, resume=True, int nsplit=1)'. """ if doc is None: return [] #care only the firstline line = doc.lstrip().splitlines()[0] #p = re.compile(r'^[\w|\s.]+\(([^)]*)\).*') #'min(iterable[, key=func])\n' -> 'iterable[, key=func]' sig = self.docstring_sig_re.search(line) if sig is None: return [] # iterable[, key=func]' -> ['iterable[' ,' key=func]'] sig = sig.groups()[0].split(',') ret = [] for s in sig: #re.compile(r'[\s|\[]*(\w+)(?:\s*=\s*.*)') ret += self.docstring_kwd_re.findall(s) return ret def _default_arguments(self, obj): """Return the list of default arguments of obj if it is callable, or empty list otherwise.""" call_obj = obj ret = [] if inspect.isbuiltin(obj): pass elif not (inspect.isfunction(obj) or inspect.ismethod(obj)): if inspect.isclass(obj): #for cython embedsignature=True the constructor docstring #belongs to the object itself not __init__ ret += self._default_arguments_from_docstring( getattr(obj, '__doc__', '')) # for classes, check for __init__,__new__ call_obj = (getattr(obj, '__init__', None) or getattr(obj, '__new__', None)) # for all others, check if they are __call__able elif hasattr(obj, '__call__'): call_obj = obj.__call__ ret += self._default_arguments_from_docstring( getattr(call_obj, '__doc__', '')) _keeps = (inspect.Parameter.KEYWORD_ONLY, inspect.Parameter.POSITIONAL_OR_KEYWORD) try: sig = inspect.signature(call_obj) ret.extend(k for k, v in sig.parameters.items() if v.kind in _keeps) except ValueError: pass return list(set(ret)) def python_func_kw_matches(self, text): """Match named parameters (kwargs) of the last open function""" if "." in text: # a parameter cannot be dotted return [] try: regexp = self.__funcParamsRegex except AttributeError: regexp = self.__funcParamsRegex = re.compile(r''' '.*?(?,a=1)", the candidate is "foo" tokens = regexp.findall(self.text_until_cursor) iterTokens = reversed(tokens); openPar = 0 for token in iterTokens: if token == ')': openPar -= 1 elif token == '(': openPar += 1 if openPar > 0: # found the last unclosed parenthesis break else: return [] # 2. Concatenate dotted names ("foo.bar" for "foo.bar(x, pa" ) ids = [] isId = re.compile(r'\w+$').match while True: try: ids.append(next(iterTokens)) if not isId(ids[-1]): ids.pop(); break if not next(iterTokens) == '.': break except StopIteration: break # Find all named arguments already assigned to, as to avoid suggesting # them again usedNamedArgs = set() par_level = -1 for token, next_token in zip(tokens, tokens[1:]): if token == '(': par_level += 1 elif token == ')': par_level -= 1 if par_level != 0: continue if next_token != '=': continue usedNamedArgs.add(token) argMatches = [] try: callableObj = '.'.join(ids[::-1]) namedArgs = self._default_arguments(eval(callableObj, self.namespace)) # Remove used named arguments from the list, no need to show twice for namedArg in set(namedArgs) - usedNamedArgs: if namedArg.startswith(text): argMatches.append(u"%s=" %namedArg) except: pass return argMatches @staticmethod def _get_keys(obj: Any) -> List[Any]: # Objects can define their own completions by defining an # _ipy_key_completions_() method. method = get_real_method(obj, '_ipython_key_completions_') if method is not None: return method() # Special case some common in-memory dict-like types if isinstance(obj, dict) or\ _safe_isinstance(obj, 'pandas', 'DataFrame'): try: return list(obj.keys()) except Exception: return [] elif _safe_isinstance(obj, 'numpy', 'ndarray') or\ _safe_isinstance(obj, 'numpy', 'void'): return obj.dtype.names or [] return [] def dict_key_matches(self, text:str) -> List[str]: "Match string keys in a dictionary, after e.g. 'foo[' " if self.__dict_key_regexps is not None: regexps = self.__dict_key_regexps else: dict_key_re_fmt = r'''(?x) ( # match dict-referring expression wrt greedy setting %s ) \[ # open bracket \s* # and optional whitespace ([uUbB]? # string prefix (r not handled) (?: # unclosed string '(?:[^']|(? key_start: leading = '' else: leading = text[text_start:completion_start] # the index of the `[` character bracket_idx = match.end(1) # append closing quote and bracket as appropriate # this is *not* appropriate if the opening quote or bracket is outside # the text given to this method suf = '' continuation = self.line_buffer[len(self.text_until_cursor):] if key_start > text_start and closing_quote: # quotes were opened inside text, maybe close them if continuation.startswith(closing_quote): continuation = continuation[len(closing_quote):] else: suf += closing_quote if bracket_idx > text_start: # brackets were opened inside text, maybe close them if not continuation.startswith(']'): suf += ']' return [leading + k + suf for k in matches] @staticmethod def unicode_name_matches(text:str) -> Tuple[str, List[str]] : """Match Latex-like syntax for unicode characters base on the name of the character. This does ``\\GREEK SMALL LETTER ETA`` -> ``η`` Works only on valid python 3 identifier, or on combining characters that will combine to form a valid identifier. """ slashpos = text.rfind('\\') if slashpos > -1: s = text[slashpos+1:] try : unic = unicodedata.lookup(s) # allow combining chars if ('a'+unic).isidentifier(): return '\\'+s,[unic] except KeyError: pass return '', [] def latex_matches(self, text): u"""Match Latex syntax for unicode characters. This does both ``\\alp`` -> ``\\alpha`` and ``\\alpha`` -> ``α`` """ slashpos = text.rfind('\\') if slashpos > -1: s = text[slashpos:] if s in latex_symbols: # Try to complete a full latex symbol to unicode # \\alpha -> α return s, [latex_symbols[s]] else: # If a user has partially typed a latex symbol, give them # a full list of options \al -> [\aleph, \alpha] matches = [k for k in latex_symbols if k.startswith(s)] if matches: return s, matches return u'', [] def dispatch_custom_completer(self, text): if not self.custom_completers: return line = self.line_buffer if not line.strip(): return None # Create a little structure to pass all the relevant information about # the current completion to any custom completer. event = SimpleNamespace() event.line = line event.symbol = text cmd = line.split(None,1)[0] event.command = cmd event.text_until_cursor = self.text_until_cursor # for foo etc, try also to find completer for %foo if not cmd.startswith(self.magic_escape): try_magic = self.custom_completers.s_matches( self.magic_escape + cmd) else: try_magic = [] for c in itertools.chain(self.custom_completers.s_matches(cmd), try_magic, self.custom_completers.flat_matches(self.text_until_cursor)): try: res = c(event) if res: # first, try case sensitive match withcase = [r for r in res if r.startswith(text)] if withcase: return withcase # if none, then case insensitive ones are ok too text_low = text.lower() return [r for r in res if r.lower().startswith(text_low)] except TryNext: pass except KeyboardInterrupt: """ If custom completer take too long, let keyboard interrupt abort and return nothing. """ break return None def completions(self, text: str, offset: int)->Iterator[Completion]: """ Returns an iterator over the possible completions .. warning:: Unstable This function is unstable, API may change without warning. It will also raise unless use in proper context manager. Parameters ---------- text:str Full text of the current input, multi line string. offset:int Integer representing the position of the cursor in ``text``. Offset is 0-based indexed. Yields ------ :any:`Completion` object The cursor on a text can either be seen as being "in between" characters or "On" a character depending on the interface visible to the user. For consistency the cursor being on "in between" characters X and Y is equivalent to the cursor being "on" character Y, that is to say the character the cursor is on is considered as being after the cursor. Combining characters may span more that one position in the text. .. note:: If ``IPCompleter.debug`` is :any:`True` will yield a ``--jedi/ipython--`` fake Completion token to distinguish completion returned by Jedi and usual IPython completion. .. note:: Completions are not completely deduplicated yet. If identical completions are coming from different sources this function does not ensure that each completion object will only be present once. """ warnings.warn("_complete is a provisional API (as of IPython 6.0). " "It may change without warnings. " "Use in corresponding context manager.", category=ProvisionalCompleterWarning, stacklevel=2) seen = set() profiler:Optional[cProfile.Profile] try: if self.profile_completions: import cProfile profiler = cProfile.Profile() profiler.enable() else: profiler = None for c in self._completions(text, offset, _timeout=self.jedi_compute_type_timeout/1000): if c and (c in seen): continue yield c seen.add(c) except KeyboardInterrupt: """if completions take too long and users send keyboard interrupt, do not crash and return ASAP. """ pass finally: if profiler is not None: profiler.disable() ensure_dir_exists(self.profiler_output_dir) output_path = os.path.join(self.profiler_output_dir, str(uuid.uuid4())) print("Writing profiler output to", output_path) profiler.dump_stats(output_path) def _completions(self, full_text: str, offset: int, *, _timeout) -> Iterator[Completion]: """ Core completion module.Same signature as :any:`completions`, with the extra `timeout` parameter (in seconds). Computing jedi's completion ``.type`` can be quite expensive (it is a lazy property) and can require some warm-up, more warm up than just computing the ``name`` of a completion. The warm-up can be : - Long warm-up the first time a module is encountered after install/update: actually build parse/inference tree. - first time the module is encountered in a session: load tree from disk. We don't want to block completions for tens of seconds so we give the completer a "budget" of ``_timeout`` seconds per invocation to compute completions types, the completions that have not yet been computed will be marked as "unknown" an will have a chance to be computed next round are things get cached. Keep in mind that Jedi is not the only thing treating the completion so keep the timeout short-ish as if we take more than 0.3 second we still have lots of processing to do. """ deadline = time.monotonic() + _timeout before = full_text[:offset] cursor_line, cursor_column = position_to_cursor(full_text, offset) matched_text, matches, matches_origin, jedi_matches = self._complete( full_text=full_text, cursor_line=cursor_line, cursor_pos=cursor_column) iter_jm = iter(jedi_matches) if _timeout: for jm in iter_jm: try: type_ = jm.type except Exception: if self.debug: print("Error in Jedi getting type of ", jm) type_ = None delta = len(jm.name_with_symbols) - len(jm.complete) if type_ == 'function': signature = _make_signature(jm) else: signature = '' yield Completion(start=offset - delta, end=offset, text=jm.name_with_symbols, type=type_, signature=signature, _origin='jedi') if time.monotonic() > deadline: break for jm in iter_jm: delta = len(jm.name_with_symbols) - len(jm.complete) yield Completion(start=offset - delta, end=offset, text=jm.name_with_symbols, type='', # don't compute type for speed _origin='jedi', signature='') start_offset = before.rfind(matched_text) # TODO: # Suppress this, right now just for debug. if jedi_matches and matches and self.debug: yield Completion(start=start_offset, end=offset, text='--jedi/ipython--', _origin='debug', type='none', signature='') # I'm unsure if this is always true, so let's assert and see if it # crash assert before.endswith(matched_text) for m, t in zip(matches, matches_origin): yield Completion(start=start_offset, end=offset, text=m, _origin=t, signature='', type='') def complete(self, text=None, line_buffer=None, cursor_pos=None) -> Tuple[str, Sequence[str]]: """Find completions for the given text and line context. Note that both the text and the line_buffer are optional, but at least one of them must be given. Parameters ---------- text : string, optional Text to perform the completion on. If not given, the line buffer is split using the instance's CompletionSplitter object. line_buffer : string, optional If not given, the completer attempts to obtain the current line buffer via readline. This keyword allows clients which are requesting for text completions in non-readline contexts to inform the completer of the entire text. cursor_pos : int, optional Index of the cursor in the full line buffer. Should be provided by remote frontends where kernel has no access to frontend state. Returns ------- Tuple of two items: text : str Text that was actually used in the completion. matches : list A list of completion matches. .. note:: This API is likely to be deprecated and replaced by :any:`IPCompleter.completions` in the future. """ warnings.warn('`Completer.complete` is pending deprecation since ' 'IPython 6.0 and will be replaced by `Completer.completions`.', PendingDeprecationWarning) # potential todo, FOLD the 3rd throw away argument of _complete # into the first 2 one. return self._complete(line_buffer=line_buffer, cursor_pos=cursor_pos, text=text, cursor_line=0)[:2] def _complete(self, *, cursor_line, cursor_pos, line_buffer=None, text=None, full_text=None) -> _CompleteResult: """ Like complete but can also returns raw jedi completions as well as the origin of the completion text. This could (and should) be made much cleaner but that will be simpler once we drop the old (and stateful) :any:`complete` API. With current provisional API, cursor_pos act both (depending on the caller) as the offset in the ``text`` or ``line_buffer``, or as the ``column`` when passing multiline strings this could/should be renamed but would add extra noise. Return ====== A tuple of N elements which are (likely): matched_text: ? the text that the complete matched matches: list of completions ? matches_origin: ? list same lenght as matches, and where each completion came from jedi_matches: list of Jedi matches, have it's own structure. """ # if the cursor position isn't given, the only sane assumption we can # make is that it's at the end of the line (the common case) if cursor_pos is None: cursor_pos = len(line_buffer) if text is None else len(text) if self.use_main_ns: self.namespace = __main__.__dict__ # if text is either None or an empty string, rely on the line buffer if (not line_buffer) and full_text: line_buffer = full_text.split('\n')[cursor_line] if not text: text = self.splitter.split_line(line_buffer, cursor_pos) if self.backslash_combining_completions: # allow deactivation of these on windows. base_text = text if not line_buffer else line_buffer[:cursor_pos] for meth in (self.latex_matches, self.unicode_name_matches, back_latex_name_matches, back_unicode_name_matches, self.fwd_unicode_match): name_text, name_matches = meth(base_text) if name_text: return _CompleteResult(name_text, name_matches[:MATCHES_LIMIT], \ [meth.__qualname__]*min(len(name_matches), MATCHES_LIMIT), ()) # If no line buffer is given, assume the input text is all there was if line_buffer is None: line_buffer = text self.line_buffer = line_buffer self.text_until_cursor = self.line_buffer[:cursor_pos] # Do magic arg matches for matcher in self.magic_arg_matchers: matches = list(matcher(line_buffer))[:MATCHES_LIMIT] if matches: origins = [matcher.__qualname__] * len(matches) return _CompleteResult(text, matches, origins, ()) # Start with a clean slate of completions matches = [] # FIXME: we should extend our api to return a dict with completions for # different types of objects. The rlcomplete() method could then # simply collapse the dict into a list for readline, but we'd have # richer completion semantics in other environments. completions:Iterable[Any] = [] if self.use_jedi: if not full_text: full_text = line_buffer completions = self._jedi_matches( cursor_pos, cursor_line, full_text) if self.merge_completions: matches = [] for matcher in self.matchers: try: matches.extend([(m, matcher.__qualname__) for m in matcher(text)]) except: # Show the ugly traceback if the matcher causes an # exception, but do NOT crash the kernel! sys.excepthook(*sys.exc_info()) else: for matcher in self.matchers: matches = [(m, matcher.__qualname__) for m in matcher(text)] if matches: break seen = set() filtered_matches = set() for m in matches: t, c = m if t not in seen: filtered_matches.add(m) seen.add(t) _filtered_matches = sorted(filtered_matches, key=lambda x: completions_sorting_key(x[0])) custom_res = [(m, 'custom') for m in self.dispatch_custom_completer(text) or []] _filtered_matches = custom_res or _filtered_matches _filtered_matches = _filtered_matches[:MATCHES_LIMIT] _matches = [m[0] for m in _filtered_matches] origins = [m[1] for m in _filtered_matches] self.matches = _matches return _CompleteResult(text, _matches, origins, completions) def fwd_unicode_match(self, text:str) -> Tuple[str, Iterable[str]]: """ Forward match a string starting with a backslash with a list of potential Unicode completions. Will compute list list of Unicode character names on first call and cache it. Return ====== At tuple with: - matched text (empty if no matches) - list of potential completions, empty tuple otherwise) """ # TODO: self.unicode_names is here a list we traverse each time with ~100k elements. # We could do a faster match using a Trie. # Using pygtrie the follwing seem to work: # s = PrefixSet() # for c in range(0,0x10FFFF + 1): # try: # s.add(unicodedata.name(chr(c))) # except ValueError: # pass # [''.join(k) for k in s.iter(prefix)] # But need to be timed and adds an extra dependency. slashpos = text.rfind('\\') # if text starts with slash if slashpos > -1: # PERF: It's important that we don't access self._unicode_names # until we're inside this if-block. _unicode_names is lazily # initialized, and it takes a user-noticeable amount of time to # initialize it, so we don't want to initialize it unless we're # actually going to use it. s = text[slashpos+1:] candidates = [x for x in self.unicode_names if x.startswith(s)] if candidates: return s, candidates else: return '', () # if text does not start with slash else: return '', () @property def unicode_names(self) -> List[str]: """List of names of unicode code points that can be completed. The list is lazily initialized on first access. """ if self._unicode_names is None: names = [] for c in range(0,0x10FFFF + 1): try: names.append(unicodedata.name(chr(c))) except ValueError: pass self._unicode_names = names return self._unicode_names