compiler/front_end/tokenizer.py - third_party/github/google/emboss - Git at Google

 # Copyright 2019 Google LLC
 #
 # Licensed under the Apache License, Version 2.0 (the "License");
 # you may not use this file except in compliance with the License.
 # You may obtain a copy of the License at
 #
 #     https://www.apache.org/licenses/LICENSE-2.0
 #
 # Unless required by applicable law or agreed to in writing, software
 # distributed under the License is distributed on an "AS IS" BASIS,
 # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 # See the License for the specific language governing permissions and
 # limitations under the License.

 """Tokenization for the Emboss definition language.

 This module exports the tokenize function and various errors.

 In addition, a couple of lists are exported for the use of
 generate_grammar_md.py:

 LITERAL_TOKEN_PATTERNS: A list of literal strings which are matched against
   input.
 REGEX_TOKEN_PATTERNS: A list of regexes used for tokenization.
   REGEX_TOKEN_PATTERNS[n].regex is an re.RegexObject
   (REGEX_TOKEN_PATTERNS[n].regex.pattern contains the text of the pattern), and
   REGEX_TOKEN_PATTERNS[n].symbol is the name of the symbol assigned to tokens
   which match the pattern.
 """

 import collections
 import re

 from compiler.util import error
 from compiler.util import parser_types


 def tokenize(text, file_name):
   # TODO(bolms): suppress end-of-line, indent, and dedent tokens between matched
   # delimiters ([], (), and {}).
   """Tokenizes its argument.

   Arguments:
     text: The raw text of a .emb file.
     file_name: The name of the file to use in errors.

   Returns:
     A tuple of:
       a list of parser_types.Tokens or None
       a possibly-empty list of errors.
   """
   tokens = []
   indent_stack = [""]
   line_number = 0
   for line in text.splitlines():
     line_number += 1

     # _tokenize_line splits the actual text into tokens.
     line_tokens, errors = _tokenize_line(line, line_number, file_name)
     if errors:
       return None, errors

     # Lines with only whitespace and comments are not used for Indent/Dedent
     # calculation, and do not produce end-of-line tokens.
     for token in line_tokens:
       if token.symbol != "Comment":
         break
     else:
       tokens.extend(line_tokens)
       tokens.append(parser_types.Token(
           '"\\n"', "\n", parser_types.make_location(
               (line_number, len(line) + 1), (line_number, len(line) + 1))))
       continue

     # Leading whitespace is whatever .lstrip() removes.
     leading_whitespace = line[0:len(line) - len(line.lstrip())]
     if leading_whitespace == indent_stack[-1]:
       # If the current leading whitespace is equal to the last leading
       # whitespace, do not emit an Indent or Dedent token.
       pass
     elif leading_whitespace.startswith(indent_stack[-1]):
       # If the current leading whitespace is longer than the last leading
       # whitespace, emit an Indent token.  For the token text, take the new
       # part of the whitespace.
       tokens.append(
           parser_types.Token(
               "Indent", leading_whitespace[len(indent_stack[-1]):],
               parser_types.make_location(
                   (line_number, len(indent_stack[-1]) + 1),
                   (line_number, len(leading_whitespace) + 1))))
       indent_stack.append(leading_whitespace)
     else:
       # Otherwise, search for the unclosed indentation level that matches
       # the current indentation level.  Emit a Dedent token for each
       # newly-closed indentation level.
       for i in range(len(indent_stack) - 1, -1, -1):
         if leading_whitespace == indent_stack[i]:
           break
         tokens.append(
             parser_types.Token("Dedent", "", parser_types.make_location(
                 (line_number, len(leading_whitespace) + 1),
                 (line_number, len(leading_whitespace) + 1))))
         del indent_stack[i]
       else:
         return None, [[error.error(
             file_name, parser_types.make_location(
                 (line_number, 1), (line_number, len(leading_whitespace) + 1)),
             "Bad indentation")]]

     tokens.extend(line_tokens)

     # Append an end-of-line token (for non-whitespace lines).
     tokens.append(parser_types.Token(
         '"\\n"', "\n", parser_types.make_location(
             (line_number, len(line) + 1), (line_number, len(line) + 1))))
   for i in range(len(indent_stack) - 1):
     tokens.append(parser_types.Token("Dedent", "", parser_types.make_location(
         (line_number + 1, 1), (line_number + 1, 1))))
   return tokens, []

 # Token patterns used by _tokenize_line.
 LITERAL_TOKEN_PATTERNS = (
     "[ ] ( ) : = + - * . ? == != && || < > <= >= , "
     "$static_size_in_bits $is_statically_sized "
     "$max $present $upper_bound $lower_bound "
     "$size_in_bits $size_in_bytes "
     "$max_size_in_bits $max_size_in_bytes $min_size_in_bits $min_size_in_bytes "
     "$default struct bits enum external import as if let").split()
 _T = collections.namedtuple("T", ["regex", "symbol"])
 REGEX_TOKEN_PATTERNS = [
     # Words starting with variations of "emboss reserved" are reserved for
     # internal use by the Emboss compiler.
     _T(re.compile(r"EmbossReserved[A-Za-z0-9]*"), "BadWord"),
     _T(re.compile(r"emboss_reserved[_a-z0-9]*"), "BadWord"),
     _T(re.compile(r"EMBOSS_RESERVED[_A-Z0-9]*"), "BadWord"),
     _T(re.compile(r'"(?:[^"\n\\]|\\[n\\"])*"'), "String"),
     _T(re.compile("[0-9]+"), "Number"),
     _T(re.compile("[0-9]{1,3}(?:_[0-9]{3})*"), "Number"),
     _T(re.compile("0x[0-9a-fA-F]+"), "Number"),
     _T(re.compile("0x_?[0-9a-fA-F]{1,4}(?:_[0-9a-fA-F]{4})*"), "Number"),
     _T(re.compile("0x_?[0-9a-fA-F]{1,8}(?:_[0-9a-fA-F]{8})*"), "Number"),
     _T(re.compile("0b[01]+"), "Number"),
     _T(re.compile("0b_?[01]{1,4}(?:_[01]{4})*"), "Number"),
     _T(re.compile("0b_?[01]{1,8}(?:_[01]{8})*"), "Number"),
     _T(re.compile("true|false"), "BooleanConstant"),
     _T(re.compile("[a-z][a-z_0-9]*"), "SnakeWord"),
     # Single-letter ShoutyWords (like "A") and single-letter-followed-by-number
     # ShoutyWords ("A100") are disallowed due to ambiguity with CamelWords.  A
     # ShoutyWord must start with an upper case letter and contain at least one
     # more upper case letter or '_'.
     _T(re.compile("[A-Z][A-Z_0-9]*[A-Z_][A-Z_0-9]*"), "ShoutyWord"),
     # A CamelWord starts with A-Z and contains at least one a-z, and no _.
     _T(re.compile("[A-Z][a-zA-Z0-9]*[a-z][a-zA-Z0-9]*"), "CamelWord"),
     _T(re.compile("-- .*"), "Documentation"),
     _T(re.compile("--$"), "Documentation"),
     _T(re.compile("--.*"), "BadDocumentation"),
     _T(re.compile(r"\s+"), None),
     _T(re.compile("#.*"), "Comment"),
     # BadWord and BadNumber are a catch-alls for words and numbers so that
     # something like "abcDef" doesn't tokenize to [SnakeWord, CamelWord].
     #
     # This is preferable to returning an error because the BadWord and BadNumber
     # token types can be used in example-based errors.
     _T(re.compile("[0-9][bxBX]?[0-9a-fA-F_]*"), "BadNumber"),
     _T(re.compile("[a-zA-Z_$0-9]+"), "BadWord"),
 ]
 del _T


 def _tokenize_line(line, line_number, file_name):
   """Tokenizes a single line of input.

   Arguments:
     line: The line of text to tokenize.
     line_number: The line number (used when constructing token objects).
     file_name: The name of a file to use in errors.

   Returns:
     A tuple of:
       A list of token objects or None.
       A possibly-empty list of errors.
   """
   tokens = []
   offset = 0
   while offset < len(line):
     best_candidate = ""
     best_candidate_symbol = None
     # Find the longest match.  Ties go to the first match.  This way, keywords
     # ("struct") are matched as themselves, but words that only happen to start
     # with keywords ("structure") are matched as words.
     #
     # There is never a reason to try to match a literal after a regex that
     # could also match that literal, so check literals first.
     for literal in LITERAL_TOKEN_PATTERNS:
       if line[offset:].startswith(literal) and len(literal) > len(
           best_candidate):
         best_candidate = literal
         # For Emboss, the name of a literal token is just the literal in quotes,
         # so that the grammar can read a little more naturally, e.g.:
         #
         #     expression -> expression "+" expression
         #
         # instead of
         #
         #     expression -> expression Plus expression
         best_candidate_symbol = '"' + literal + '"'
     for pattern in REGEX_TOKEN_PATTERNS:
       match_result = pattern.regex.match(line[offset:])
       if match_result and len(match_result.group(0)) > len(best_candidate):
         best_candidate = match_result.group(0)
         best_candidate_symbol = pattern.symbol
     if not best_candidate:
       return None, [[error.error(
           file_name, parser_types.make_location(
               (line_number, offset + 1), (line_number, offset + 2)),
           "Unrecognized token")]]
     if best_candidate_symbol:
       tokens.append(parser_types.Token(
           best_candidate_symbol, best_candidate, parser_types.make_location(
               (line_number, offset + 1),
               (line_number, offset + len(best_candidate) + 1))))
     offset += len(best_candidate)
   return tokens, None
	# Copyright 2019 Google LLC
	#
	# Licensed under the Apache License, Version 2.0 (the "License");
	# you may not use this file except in compliance with the License.
	# You may obtain a copy of the License at
	#
	# https://www.apache.org/licenses/LICENSE-2.0
	#
	# Unless required by applicable law or agreed to in writing, software
	# distributed under the License is distributed on an "AS IS" BASIS,
	# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	# See the License for the specific language governing permissions and
	# limitations under the License.

	"""Tokenization for the Emboss definition language.

	This module exports the tokenize function and various errors.

	In addition, a couple of lists are exported for the use of
	generate_grammar_md.py:

	LITERAL_TOKEN_PATTERNS: A list of literal strings which are matched against
	input.
	REGEX_TOKEN_PATTERNS: A list of regexes used for tokenization.
	REGEX_TOKEN_PATTERNS[n].regex is an re.RegexObject
	(REGEX_TOKEN_PATTERNS[n].regex.pattern contains the text of the pattern), and
	REGEX_TOKEN_PATTERNS[n].symbol is the name of the symbol assigned to tokens
	which match the pattern.
	"""

	import collections
	import re

	from compiler.util import error
	from compiler.util import parser_types


	def tokenize(text, file_name):
	# TODO(bolms): suppress end-of-line, indent, and dedent tokens between matched
	# delimiters ([], (), and {}).
	"""Tokenizes its argument.

	Arguments:
	text: The raw text of a .emb file.
	file_name: The name of the file to use in errors.

	Returns:
	A tuple of:
	a list of parser_types.Tokens or None
	a possibly-empty list of errors.
	"""
	tokens = []
	indent_stack = [""]
	line_number = 0
	for line in text.splitlines():
	line_number += 1

	# _tokenize_line splits the actual text into tokens.
	line_tokens, errors = _tokenize_line(line, line_number, file_name)
	if errors:
	return None, errors

	# Lines with only whitespace and comments are not used for Indent/Dedent
	# calculation, and do not produce end-of-line tokens.
	for token in line_tokens:
	if token.symbol != "Comment":
	break
	else:
	tokens.extend(line_tokens)
	tokens.append(parser_types.Token(
	'"\\n"', "\n", parser_types.make_location(
	(line_number, len(line) + 1), (line_number, len(line) + 1))))
	continue

	# Leading whitespace is whatever .lstrip() removes.
	leading_whitespace = line[0:len(line) - len(line.lstrip())]
	if leading_whitespace == indent_stack[-1]:
	# If the current leading whitespace is equal to the last leading
	# whitespace, do not emit an Indent or Dedent token.
	pass
	elif leading_whitespace.startswith(indent_stack[-1]):
	# If the current leading whitespace is longer than the last leading
	# whitespace, emit an Indent token. For the token text, take the new
	# part of the whitespace.
	tokens.append(
	parser_types.Token(
	"Indent", leading_whitespace[len(indent_stack[-1]):],
	parser_types.make_location(
	(line_number, len(indent_stack[-1]) + 1),
	(line_number, len(leading_whitespace) + 1))))
	indent_stack.append(leading_whitespace)
	else:
	# Otherwise, search for the unclosed indentation level that matches
	# the current indentation level. Emit a Dedent token for each
	# newly-closed indentation level.
	for i in range(len(indent_stack) - 1, -1, -1):
	if leading_whitespace == indent_stack[i]:
	break
	tokens.append(
	parser_types.Token("Dedent", "", parser_types.make_location(
	(line_number, len(leading_whitespace) + 1),
	(line_number, len(leading_whitespace) + 1))))
	del indent_stack[i]
	else:
	return None, [[error.error(
	file_name, parser_types.make_location(
	(line_number, 1), (line_number, len(leading_whitespace) + 1)),
	"Bad indentation")]]

	tokens.extend(line_tokens)

	# Append an end-of-line token (for non-whitespace lines).
	tokens.append(parser_types.Token(
	'"\\n"', "\n", parser_types.make_location(
	(line_number, len(line) + 1), (line_number, len(line) + 1))))
	for i in range(len(indent_stack) - 1):
	tokens.append(parser_types.Token("Dedent", "", parser_types.make_location(
	(line_number + 1, 1), (line_number + 1, 1))))
	return tokens, []

	# Token patterns used by _tokenize_line.
	LITERAL_TOKEN_PATTERNS = (
	"[ ] ( ) : = + - * . ? == != && \|\| < > <= >= , "
	"$static_size_in_bits $is_statically_sized "
	"$max $present $upper_bound $lower_bound "
	"$size_in_bits $size_in_bytes "
	"$max_size_in_bits $max_size_in_bytes $min_size_in_bits $min_size_in_bytes "
	"$default struct bits enum external import as if let").split()
	_T = collections.namedtuple("T", ["regex", "symbol"])
	REGEX_TOKEN_PATTERNS = [
	# Words starting with variations of "emboss reserved" are reserved for
	# internal use by the Emboss compiler.
	_T(re.compile(r"EmbossReserved[A-Za-z0-9]*"), "BadWord"),
	_T(re.compile(r"emboss_reserved[_a-z0-9]*"), "BadWord"),
	_T(re.compile(r"EMBOSS_RESERVED[_A-Z0-9]*"), "BadWord"),
	_T(re.compile(r'"(?:[^"\n\\]\|\\[n\\"])*"'), "String"),
	_T(re.compile("[0-9]+"), "Number"),
	_T(re.compile("[0-9]{1,3}(?:_[0-9]{3})*"), "Number"),
	_T(re.compile("0x[0-9a-fA-F]+"), "Number"),
	_T(re.compile("0x_?[0-9a-fA-F]{1,4}(?:_[0-9a-fA-F]{4})*"), "Number"),
	_T(re.compile("0x_?[0-9a-fA-F]{1,8}(?:_[0-9a-fA-F]{8})*"), "Number"),
	_T(re.compile("0b[01]+"), "Number"),
	_T(re.compile("0b_?[01]{1,4}(?:_[01]{4})*"), "Number"),
	_T(re.compile("0b_?[01]{1,8}(?:_[01]{8})*"), "Number"),
	_T(re.compile("true\|false"), "BooleanConstant"),
	_T(re.compile("[a-z][a-z_0-9]*"), "SnakeWord"),
	# Single-letter ShoutyWords (like "A") and single-letter-followed-by-number
	# ShoutyWords ("A100") are disallowed due to ambiguity with CamelWords. A
	# ShoutyWord must start with an upper case letter and contain at least one
	# more upper case letter or '_'.
	_T(re.compile("[A-Z][A-Z_0-9][A-Z_][A-Z_0-9]"), "ShoutyWord"),
	# A CamelWord starts with A-Z and contains at least one a-z, and no _.
	_T(re.compile("[A-Z][a-zA-Z0-9][a-z][a-zA-Z0-9]"), "CamelWord"),
	_T(re.compile("-- .*"), "Documentation"),
	_T(re.compile("--$"), "Documentation"),
	_T(re.compile("--.*"), "BadDocumentation"),
	_T(re.compile(r"\s+"), None),
	_T(re.compile("#.*"), "Comment"),
	# BadWord and BadNumber are a catch-alls for words and numbers so that
	# something like "abcDef" doesn't tokenize to [SnakeWord, CamelWord].
	#
	# This is preferable to returning an error because the BadWord and BadNumber
	# token types can be used in example-based errors.
	_T(re.compile("[0-9][bxBX]?[0-9a-fA-F_]*"), "BadNumber"),
	_T(re.compile("[a-zA-Z_$0-9]+"), "BadWord"),
	]
	del _T


	def _tokenize_line(line, line_number, file_name):
	"""Tokenizes a single line of input.

	Arguments:
	line: The line of text to tokenize.
	line_number: The line number (used when constructing token objects).
	file_name: The name of a file to use in errors.

	Returns:
	A tuple of:
	A list of token objects or None.
	A possibly-empty list of errors.
	"""
	tokens = []
	offset = 0
	while offset < len(line):
	best_candidate = ""
	best_candidate_symbol = None
	# Find the longest match. Ties go to the first match. This way, keywords
	# ("struct") are matched as themselves, but words that only happen to start
	# with keywords ("structure") are matched as words.
	#
	# There is never a reason to try to match a literal after a regex that
	# could also match that literal, so check literals first.
	for literal in LITERAL_TOKEN_PATTERNS:
	if line[offset:].startswith(literal) and len(literal) > len(
	best_candidate):
	best_candidate = literal
	# For Emboss, the name of a literal token is just the literal in quotes,
	# so that the grammar can read a little more naturally, e.g.:
	#
	# expression -> expression "+" expression
	#
	# instead of
	#
	# expression -> expression Plus expression
	best_candidate_symbol = '"' + literal + '"'
	for pattern in REGEX_TOKEN_PATTERNS:
	match_result = pattern.regex.match(line[offset:])
	if match_result and len(match_result.group(0)) > len(best_candidate):
	best_candidate = match_result.group(0)
	best_candidate_symbol = pattern.symbol
	if not best_candidate:
	return None, [[error.error(
	file_name, parser_types.make_location(
	(line_number, offset + 1), (line_number, offset + 2)),
	"Unrecognized token")]]
	if best_candidate_symbol:
	tokens.append(parser_types.Token(
	best_candidate_symbol, best_candidate, parser_types.make_location(
	(line_number, offset + 1),
	(line_number, offset + len(best_candidate) + 1))))
	offset += len(best_candidate)
	return tokens, None