""" Utilities for working with strings and text. Inheritance diagram: .. inheritance-diagram:: IPython.utils.text :parts: 3 """ import os import re import string import sys import textwrap import warnings from string import Formatter from pathlib import Path from typing import ( List, Dict, Tuple, Optional, cast, Sequence, Mapping, Any, Union, Callable, Iterator, TypeVar, ) if sys.version_info < (3, 12): from typing_extensions import Self else: from typing import Self class LSString(str): """String derivative with a special access attributes. These are normal strings, but with the special attributes: .l (or .list) : value as list (split on newlines). .n (or .nlstr): original value (the string itself). .s (or .spstr): value as whitespace-separated string. .p (or .paths): list of path objects (requires path.py package) Any values which require transformations are computed only once and cached. Such strings are very useful to efficiently interact with the shell, which typically only understands whitespace-separated options for commands.""" __list: List[str] __spstr: str __paths: List[Path] def get_list(self) -> List[str]: try: return self.__list except AttributeError: self.__list = self.split('\n') return self.__list l = list = property(get_list) def get_spstr(self) -> str: try: return self.__spstr except AttributeError: self.__spstr = self.replace('\n',' ') return self.__spstr s = spstr = property(get_spstr) def get_nlstr(self) -> Self: return self n = nlstr = property(get_nlstr) def get_paths(self) -> List[Path]: try: return self.__paths except AttributeError: self.__paths = [Path(p) for p in self.split('\n') if os.path.exists(p)] return self.__paths p = paths = property(get_paths) # FIXME: We need to reimplement type specific displayhook and then add this # back as a custom printer. This should also be moved outside utils into the # core. # def print_lsstring(arg): # """ Prettier (non-repr-like) and more informative printer for LSString """ # print("LSString (.p, .n, .l, .s available). Value:") # print(arg) # # # print_lsstring = result_display.register(LSString)(print_lsstring) class SList(list): """List derivative with a special access attributes. These are normal lists, but with the special attributes: * .l (or .list) : value as list (the list itself). * .n (or .nlstr): value as a string, joined on newlines. * .s (or .spstr): value as a string, joined on spaces. * .p (or .paths): list of path objects (requires path.py package) Any values which require transformations are computed only once and cached.""" __spstr: str __nlstr: str __paths: List[Path] def get_list(self) -> Self: return self l = list = property(get_list) def get_spstr(self) -> str: try: return self.__spstr except AttributeError: self.__spstr = ' '.join(self) return self.__spstr s = spstr = property(get_spstr) def get_nlstr(self) -> str: try: return self.__nlstr except AttributeError: self.__nlstr = '\n'.join(self) return self.__nlstr n = nlstr = property(get_nlstr) def get_paths(self) -> List[Path]: try: return self.__paths except AttributeError: self.__paths = [Path(p) for p in self if os.path.exists(p)] return self.__paths p = paths = property(get_paths) def grep( self, pattern: Union[str, Callable[[Any], re.Match[str] | None]], prune: bool = False, field: Optional[int] = None, ) -> Self: """Return all strings matching 'pattern' (a regex or callable) This is case-insensitive. If prune is true, return all items NOT matching the pattern. If field is specified, the match must occur in the specified whitespace-separated field. Examples:: a.grep( lambda x: x.startswith('C') ) a.grep('Cha.*log', prune=1) a.grep('chm', field=-1) """ def match_target(s: str) -> str: if field is None: return s parts = s.split() try: tgt = parts[field] return tgt except IndexError: return "" if isinstance(pattern, str): pred = lambda x : re.search(pattern, x, re.IGNORECASE) else: pred = pattern if not prune: return type(self)([el for el in self if pred(match_target(el))]) else: return type(self)([el for el in self if not pred(match_target(el))]) def fields(self, *fields: List[str]) -> List[List[str]]: """Collect whitespace-separated fields from string list Allows quick awk-like usage of string lists. Example data (in var a, created by 'a = !ls -l'):: -rwxrwxrwx 1 ville None 18 Dec 14 2006 ChangeLog drwxrwxrwx+ 6 ville None 0 Oct 24 18:05 IPython * ``a.fields(0)`` is ``['-rwxrwxrwx', 'drwxrwxrwx+']`` * ``a.fields(1,0)`` is ``['1 -rwxrwxrwx', '6 drwxrwxrwx+']`` (note the joining by space). * ``a.fields(-1)`` is ``['ChangeLog', 'IPython']`` IndexErrors are ignored. Without args, fields() just split()'s the strings. """ if len(fields) == 0: return [el.split() for el in self] res = SList() for el in [f.split() for f in self]: lineparts = [] for fd in fields: try: lineparts.append(el[fd]) except IndexError: pass if lineparts: res.append(" ".join(lineparts)) return res def sort( # type:ignore[override] self, field: Optional[List[str]] = None, nums: bool = False, ) -> Self: """sort by specified fields (see fields()) Example:: a.sort(1, nums = True) Sorts a by second field, in numerical order (so that 21 > 3) """ #decorate, sort, undecorate if field is not None: dsu = [[SList([line]).fields(field), line] for line in self] else: dsu = [[line, line] for line in self] if nums: for i in range(len(dsu)): numstr = "".join([ch for ch in dsu[i][0] if ch.isdigit()]) try: n = int(numstr) except ValueError: n = 0 dsu[i][0] = n dsu.sort() return type(self)([t[1] for t in dsu]) def indent(instr: str, nspaces: int = 4, ntabs: int = 0, flatten: bool = False) -> str: """Indent a string a given number of spaces or tabstops. indent(str, nspaces=4, ntabs=0) -> indent str by ntabs+nspaces. Parameters ---------- instr : basestring The string to be indented. nspaces : int (default: 4) The number of spaces to be indented. ntabs : int (default: 0) The number of tabs to be indented. flatten : bool (default: False) Whether to scrub existing indentation. If True, all lines will be aligned to the same indentation. If False, existing indentation will be strictly increased. Returns ------- str : string indented by ntabs and nspaces. """ ind = "\t" * ntabs + " " * nspaces if flatten: pat = re.compile(r'^\s*', re.MULTILINE) else: pat = re.compile(r'^', re.MULTILINE) outstr = re.sub(pat, ind, instr) if outstr.endswith(os.linesep+ind): return outstr[:-len(ind)] else: return outstr def list_strings(arg: Union[str, List[str]]) -> List[str]: """Always return a list of strings, given a string or list of strings as input. Examples -------- :: In [7]: list_strings('A single string') Out[7]: ['A single string'] In [8]: list_strings(['A single string in a list']) Out[8]: ['A single string in a list'] In [9]: list_strings(['A','list','of','strings']) Out[9]: ['A', 'list', 'of', 'strings'] """ if isinstance(arg, str): return [arg] else: return arg def marquee(txt: str = "", width: int = 78, mark: str = "*") -> str: """Return the input string centered in a 'marquee'. Examples -------- :: In [16]: marquee('A test',40) Out[16]: '**************** A test ****************' In [17]: marquee('A test',40,'-') Out[17]: '---------------- A test ----------------' In [18]: marquee('A test',40,' ') Out[18]: ' A test ' """ if not txt: return (mark*width)[:width] nmark = (width-len(txt)-2)//len(mark)//2 if nmark < 0: nmark =0 marks = mark*nmark return '%s %s %s' % (marks,txt,marks) def format_screen(strng: str) -> str: """Format a string for screen printing. This removes some latex-type format codes.""" # Paragraph continue par_re = re.compile(r'\\$',re.MULTILINE) strng = par_re.sub('',strng) return strng def dedent(text: str) -> str: """Equivalent of textwrap.dedent that ignores unindented first line. This means it will still dedent strings like: '''foo is a bar ''' For use in wrap_paragraphs. """ if text.startswith('\n'): # text starts with blank line, don't ignore the first line return textwrap.dedent(text) # split first line splits = text.split('\n',1) if len(splits) == 1: # only one line return textwrap.dedent(text) first, rest = splits # dedent everything but the first line rest = textwrap.dedent(rest) return '\n'.join([first, rest]) def strip_email_quotes(text: str) -> str: """Strip leading email quotation characters ('>'). Removes any combination of leading '>' interspersed with whitespace that appears *identically* in all lines of the input text. Parameters ---------- text : str Examples -------- Simple uses:: In [2]: strip_email_quotes('> > text') Out[2]: 'text' In [3]: strip_email_quotes('> > text\\n> > more') Out[3]: 'text\\nmore' Note how only the common prefix that appears in all lines is stripped:: In [4]: strip_email_quotes('> > text\\n> > more\\n> more...') Out[4]: '> text\\n> more\\nmore...' So if any line has no quote marks ('>'), then none are stripped from any of them :: In [5]: strip_email_quotes('> > text\\n> > more\\nlast different') Out[5]: '> > text\\n> > more\\nlast different' """ lines = text.splitlines() strip_len = 0 for characters in zip(*lines): # Check if all characters in this position are the same if len(set(characters)) > 1: break prefix_char = characters[0] if prefix_char in string.whitespace or prefix_char == ">": strip_len += 1 else: break text = "\n".join([ln[strip_len:] for ln in lines]) return text class EvalFormatter(Formatter): """A String Formatter that allows evaluation of simple expressions. Note that this version interprets a `:` as specifying a format string (as per standard string formatting), so if slicing is required, you must explicitly create a slice. This is to be used in templating cases, such as the parallel batch script templates, where simple arithmetic on arguments is useful. Examples -------- :: In [1]: f = EvalFormatter() In [2]: f.format('{n//4}', n=8) Out[2]: '2' In [3]: f.format("{greeting[slice(2,4)]}", greeting="Hello") Out[3]: 'll' """ def get_field(self, name: str, args: Any, kwargs: Any) -> Tuple[Any, str]: v = eval(name, kwargs) return v, name #XXX: As of Python 3.4, the format string parsing no longer splits on a colon # inside [], so EvalFormatter can handle slicing. Once we only support 3.4 and # above, it should be possible to remove FullEvalFormatter. class FullEvalFormatter(Formatter): """A String Formatter that allows evaluation of simple expressions. Any time a format key is not found in the kwargs, it will be tried as an expression in the kwargs namespace. Note that this version allows slicing using [1:2], so you cannot specify a format string. Use :class:`EvalFormatter` to permit format strings. Examples -------- :: In [1]: f = FullEvalFormatter() In [2]: f.format('{n//4}', n=8) Out[2]: '2' In [3]: f.format('{list(range(5))[2:4]}') Out[3]: '[2, 3]' In [4]: f.format('{3*2}') Out[4]: '6' """ # copied from Formatter._vformat with minor changes to allow eval # and replace the format_spec code with slicing def vformat( self, format_string: str, args: Sequence[Any], kwargs: Mapping[str, Any] ) -> str: result = [] conversion: Optional[str] for literal_text, field_name, format_spec, conversion in self.parse( format_string ): # output the literal text if literal_text: result.append(literal_text) # if there's a field, output it if field_name is not None: # this is some markup, find the object and do # the formatting if format_spec: # override format spec, to allow slicing: field_name = ':'.join([field_name, format_spec]) # eval the contents of the field for the object # to be formatted obj = eval(field_name, dict(kwargs)) # do any conversion on the resulting object # type issue in typeshed, fined in https://github.com/python/typeshed/pull/11377 obj = self.convert_field(obj, conversion) # type: ignore[arg-type] # format the object and append to the result result.append(self.format_field(obj, '')) return ''.join(result) class DollarFormatter(FullEvalFormatter): """Formatter allowing Itpl style $foo replacement, for names and attribute access only. Standard {foo} replacement also works, and allows full evaluation of its arguments. Examples -------- :: In [1]: f = DollarFormatter() In [2]: f.format('{n//4}', n=8) Out[2]: '2' In [3]: f.format('23 * 76 is $result', result=23*76) Out[3]: '23 * 76 is 1748' In [4]: f.format('$a or {b}', a=1, b=2) Out[4]: '1 or 2' """ _dollar_pattern_ignore_single_quote = re.compile( r"(.*?)\$(\$?[\w\.]+)(?=([^']*'[^']*')*[^']*$)" ) def parse(self, fmt_string: str) -> Iterator[Tuple[Any, Any, Any, Any]]: # type: ignore[explicit-override] for literal_txt, field_name, format_spec, conversion in Formatter.parse( self, fmt_string ): # Find $foo patterns in the literal text. continue_from = 0 txt = "" for m in self._dollar_pattern_ignore_single_quote.finditer(literal_txt): new_txt, new_field = m.group(1,2) # $$foo --> $foo if new_field.startswith("$"): txt += new_txt + new_field else: yield (txt + new_txt, new_field, "", None) txt = "" continue_from = m.end() # Re-yield the {foo} style pattern yield (txt + literal_txt[continue_from:], field_name, format_spec, conversion) def __repr__(self) -> str: return "" #----------------------------------------------------------------------------- # Utils to columnize a list of string #----------------------------------------------------------------------------- def _col_chunks( l: List[int], max_rows: int, row_first: bool = False ) -> Iterator[List[int]]: """Yield successive max_rows-sized column chunks from l.""" if row_first: ncols = (len(l) // max_rows) + (len(l) % max_rows > 0) for i in range(ncols): yield [l[j] for j in range(i, len(l), ncols)] else: for i in range(0, len(l), max_rows): yield l[i:(i + max_rows)] def _find_optimal( rlist: List[int], row_first: bool, separator_size: int, displaywidth: int ) -> Dict[str, Any]: """Calculate optimal info to columnize a list of string""" for max_rows in range(1, len(rlist) + 1): col_widths = list(map(max, _col_chunks(rlist, max_rows, row_first))) sumlength = sum(col_widths) ncols = len(col_widths) if sumlength + separator_size * (ncols - 1) <= displaywidth: break return {'num_columns': ncols, 'optimal_separator_width': (displaywidth - sumlength) // (ncols - 1) if (ncols - 1) else 0, 'max_rows': max_rows, 'column_widths': col_widths } T = TypeVar("T") def _get_or_default(mylist: List[T], i: int, default: T) -> T: """return list item number, or default if don't exist""" if i >= len(mylist): return default else : return mylist[i] def get_text_list( list_: List[str], last_sep: str = " and ", sep: str = ", ", wrap_item_with: str = "" ) -> str: """ Return a string with a natural enumeration of items >>> get_text_list(['a', 'b', 'c', 'd']) 'a, b, c and d' >>> get_text_list(['a', 'b', 'c'], ' or ') 'a, b or c' >>> get_text_list(['a', 'b', 'c'], ', ') 'a, b, c' >>> get_text_list(['a', 'b'], ' or ') 'a or b' >>> get_text_list(['a']) 'a' >>> get_text_list([]) '' >>> get_text_list(['a', 'b'], wrap_item_with="`") '`a` and `b`' >>> get_text_list(['a', 'b', 'c', 'd'], " = ", sep=" + ") 'a + b + c = d' """ if len(list_) == 0: return '' if wrap_item_with: list_ = ['%s%s%s' % (wrap_item_with, item, wrap_item_with) for item in list_] if len(list_) == 1: return list_[0] return '%s%s%s' % ( sep.join(i for i in list_[:-1]), last_sep, list_[-1])