from __future__ import annotations import builtins import functools import keyword import re import token as T import tokenize import unicodedata import _colorize from collections import deque from io import StringIO from tokenize import TokenInfo as TI from typing import Iterable, Iterator, Match, NamedTuple, Self from .types import CharBuffer, CharWidths from .trace import trace ANSI_ESCAPE_SEQUENCE = re.compile(r"\x1b\[[ -@]*[A-~]") ZERO_WIDTH_BRACKET = re.compile(r"\x01.*?\x02") ZERO_WIDTH_TRANS = str.maketrans({"\x01": "", "\x02": ""}) IDENTIFIERS_AFTER = {"def", "class"} BUILTINS = {str(name) for name in dir(builtins) if not name.startswith('_')} def THEME(**kwargs): # Not cached: the user can modify the theme inside the interactive session. return _colorize.get_theme(**kwargs).syntax class Span(NamedTuple): """Span indexing that's inclusive on both ends.""" start: int end: int @classmethod def from_re(cls, m: Match[str], group: int | str) -> Self: re_span = m.span(group) return cls(re_span[0], re_span[1] - 1) @classmethod def from_token(cls, token: TI, line_len: list[int]) -> Self: end_offset = -1 if (token.type in {T.FSTRING_MIDDLE, T.TSTRING_MIDDLE} and token.string.endswith(("{", "}"))): # gh-134158: a visible trailing brace comes from a double brace in input end_offset += 1 return cls( line_len[token.start[0] - 1] + token.start[1], line_len[token.end[0] - 1] + token.end[1] + end_offset, ) class ColorSpan(NamedTuple): span: Span tag: str @functools.cache def str_width(c: str) -> int: if ord(c) < 128: return 1 w = unicodedata.east_asian_width(c) if w in ("N", "Na", "H", "A"): return 1 return 2 def wlen(s: str) -> int: if len(s) == 1 and s != "\x1a": return str_width(s) length = sum(str_width(i) for i in s) # remove lengths of any escape sequences sequence = ANSI_ESCAPE_SEQUENCE.findall(s) ctrl_z_cnt = s.count("\x1a") return length - sum(len(i) for i in sequence) + ctrl_z_cnt def unbracket(s: str, including_content: bool = False) -> str: r"""Return `s` with \001 and \002 characters removed. If `including_content` is True, content between \001 and \002 is also stripped. """ if including_content: return ZERO_WIDTH_BRACKET.sub("", s) return s.translate(ZERO_WIDTH_TRANS) def gen_colors(buffer: str) -> Iterator[ColorSpan]: """Returns a list of index spans to color using the given color tag. The input `buffer` should be a valid start of a Python code block, i.e. it cannot be a block starting in the middle of a multiline string. """ sio = StringIO(buffer) line_lengths = [0] + [len(line) for line in sio.readlines()] # make line_lengths cumulative for i in range(1, len(line_lengths)): line_lengths[i] += line_lengths[i-1] sio.seek(0) gen = tokenize.generate_tokens(sio.readline) last_emitted: ColorSpan | None = None try: for color in gen_colors_from_token_stream(gen, line_lengths): yield color last_emitted = color except SyntaxError: return except tokenize.TokenError as te: yield from recover_unterminated_string( te, line_lengths, last_emitted, buffer ) def recover_unterminated_string( exc: tokenize.TokenError, line_lengths: list[int], last_emitted: ColorSpan | None, buffer: str, ) -> Iterator[ColorSpan]: msg, loc = exc.args if loc is None: return line_no, column = loc if msg.startswith( ( "unterminated string literal", "unterminated f-string literal", "unterminated t-string literal", "EOF in multi-line string", "unterminated triple-quoted f-string literal", "unterminated triple-quoted t-string literal", ) ): start = line_lengths[line_no - 1] + column - 1 end = line_lengths[-1] - 1 # in case FSTRING_START was already emitted if last_emitted and start <= last_emitted.span.start: trace("before last emitted = {s}", s=start) start = last_emitted.span.end + 1 span = Span(start, end) trace("yielding span {a} -> {b}", a=span.start, b=span.end) yield ColorSpan(span, "string") else: trace( "unhandled token error({buffer}) = {te}", buffer=repr(buffer), te=str(exc), ) def gen_colors_from_token_stream( token_generator: Iterator[TI], line_lengths: list[int], ) -> Iterator[ColorSpan]: token_window = prev_next_window(token_generator) is_def_name = False bracket_level = 0 for prev_token, token, next_token in token_window: assert token is not None if token.start == token.end: continue match token.type: case ( T.STRING | T.FSTRING_START | T.FSTRING_MIDDLE | T.FSTRING_END | T.TSTRING_START | T.TSTRING_MIDDLE | T.TSTRING_END ): span = Span.from_token(token, line_lengths) yield ColorSpan(span, "string") case T.COMMENT: span = Span.from_token(token, line_lengths) yield ColorSpan(span, "comment") case T.NUMBER: span = Span.from_token(token, line_lengths) yield ColorSpan(span, "number") case T.OP: if token.string in "([{": bracket_level += 1 elif token.string in ")]}": bracket_level -= 1 span = Span.from_token(token, line_lengths) yield ColorSpan(span, "op") case T.NAME: if is_def_name: is_def_name = False span = Span.from_token(token, line_lengths) yield ColorSpan(span, "definition") elif keyword.iskeyword(token.string): span = Span.from_token(token, line_lengths) yield ColorSpan(span, "keyword") if token.string in IDENTIFIERS_AFTER: is_def_name = True elif ( keyword.issoftkeyword(token.string) and bracket_level == 0 and is_soft_keyword_used(prev_token, token, next_token) ): span = Span.from_token(token, line_lengths) yield ColorSpan(span, "soft_keyword") elif token.string in BUILTINS: span = Span.from_token(token, line_lengths) yield ColorSpan(span, "builtin") keyword_first_sets_match = {"False", "None", "True", "await", "lambda", "not"} keyword_first_sets_case = {"False", "None", "True"} def is_soft_keyword_used(*tokens: TI | None) -> bool: """Returns True if the current token is a keyword in this context. For the `*tokens` to match anything, they have to be a three-tuple of (previous, current, next). """ trace("is_soft_keyword_used{t}", t=tokens) match tokens: case ( None | TI(T.NEWLINE) | TI(T.INDENT) | TI(string=":"), TI(string="match"), TI(T.NUMBER | T.STRING | T.FSTRING_START | T.TSTRING_START) | TI(T.OP, string="(" | "*" | "[" | "{" | "~" | "...") ): return True case ( None | TI(T.NEWLINE) | TI(T.INDENT) | TI(string=":"), TI(string="match"), TI(T.NAME, string=s) ): if keyword.iskeyword(s): return s in keyword_first_sets_match return True case ( None | TI(T.NEWLINE) | TI(T.INDENT) | TI(string=":"), TI(string="case"), TI(T.NUMBER | T.STRING | T.FSTRING_START | T.TSTRING_START) | TI(T.OP, string="(" | "*" | "-" | "[" | "{") ): return True case ( None | TI(T.NEWLINE) | TI(T.INDENT) | TI(string=":"), TI(string="case"), TI(T.NAME, string=s) ): if keyword.iskeyword(s): return s in keyword_first_sets_case return True case (TI(string="case"), TI(string="_"), TI(string=":")): return True case _: return False def disp_str( buffer: str, colors: list[ColorSpan] | None = None, start_index: int = 0, force_color: bool = False, ) -> tuple[CharBuffer, CharWidths]: r"""Decompose the input buffer into a printable variant with applied colors. Returns a tuple of two lists: - the first list is the input buffer, character by character, with color escape codes added (while those codes contain multiple ASCII characters, each code is considered atomic *and is attached for the corresponding visible character*); - the second list is the visible width of each character in the input buffer. Note on colors: - The `colors` list, if provided, is partially consumed within. We're using a list and not a generator since we need to hold onto the current unfinished span between calls to disp_str in case of multiline strings. - The `colors` list is computed from the start of the input block. `buffer` is only a subset of that input block, a single line within. This is why we need `start_index` to inform us which position is the start of `buffer` actually within user input. This allows us to match color spans correctly. Examples: >>> utils.disp_str("a = 9") (['a', ' ', '=', ' ', '9'], [1, 1, 1, 1, 1]) >>> line = "while 1:" >>> colors = list(utils.gen_colors(line)) >>> utils.disp_str(line, colors=colors) (['\x1b[1;34mw', 'h', 'i', 'l', 'e\x1b[0m', ' ', '1', ':'], [1, 1, 1, 1, 1, 1, 1, 1]) """ chars: CharBuffer = [] char_widths: CharWidths = [] if not buffer: return chars, char_widths while colors and colors[0].span.end < start_index: # move past irrelevant spans colors.pop(0) theme = THEME(force_color=force_color) pre_color = "" post_color = "" if colors and colors[0].span.start < start_index: # looks like we're continuing a previous color (e.g. a multiline str) pre_color = theme[colors[0].tag] for i, c in enumerate(buffer, start_index): if colors and colors[0].span.start == i: # new color starts now pre_color = theme[colors[0].tag] if c == "\x1a": # CTRL-Z on Windows chars.append(c) char_widths.append(2) elif ord(c) < 128: chars.append(c) char_widths.append(1) elif unicodedata.category(c).startswith("C"): c = r"\u%04x" % ord(c) chars.append(c) char_widths.append(len(c)) else: chars.append(c) char_widths.append(str_width(c)) if colors and colors[0].span.end == i: # current color ends now post_color = theme.reset colors.pop(0) chars[-1] = pre_color + chars[-1] + post_color pre_color = "" post_color = "" if colors and colors[0].span.start < i and colors[0].span.end > i: # even though the current color should be continued, reset it for now. # the next call to `disp_str()` will revive it. chars[-1] += theme.reset return chars, char_widths def prev_next_window[T]( iterable: Iterable[T] ) -> Iterator[tuple[T | None, ...]]: """Generates three-tuples of (previous, current, next) items. On the first iteration previous is None. On the last iteration next is None. In case of exception next is None and the exception is re-raised on a subsequent next() call. Inspired by `sliding_window` from `itertools` recipes. """ iterator = iter(iterable) window = deque((None, next(iterator)), maxlen=3) try: for x in iterator: window.append(x) yield tuple(window) except Exception: raise finally: window.append(None) yield tuple(window)