src/tools/idl_parser/idl_lexer.py - cobalt - Git at Google

 #!/usr/bin/env python
 # Copyright (c) 2013 The Chromium Authors. All rights reserved.
 # Use of this source code is governed by a BSD-style license that can be
 # found in the LICENSE file.

 """ Lexer for PPAPI IDL

 The lexer uses the PLY library to build a tokenizer which understands both
 WebIDL and Pepper tokens.

 WebIDL, and WebIDL regular expressions can be found at:
    http://heycam.github.io/webidl/
 PLY can be found at:
    http://www.dabeaz.com/ply/
 """

 import os.path
 import sys

 SRC_DIR = os.path.join(os.path.dirname(__file__), os.pardir, os.pardir)
 sys.path.insert(0, os.path.join(SRC_DIR, 'third_party'))
 from ply import lex


 #
 # IDL Lexer
 #
 class IDLLexer(object):
   # 'literals' is a value expected by lex which specifies a list of valid
   # literal tokens, meaning the token type and token value are identical.
   literals = r'"*.(){}[],;:=+-/~|&^?<>'

   # 't_ignore' contains ignored characters (spaces and tabs)
   t_ignore = ' \t'

   # 'tokens' is a value required by lex which specifies the complete list
   # of valid token types.
   tokens = [
     # Data types
       'float',
       'integer',
       'string',

     # Symbol and keywords types
       'COMMENT',
       'identifier',

     # MultiChar operators
       'ELLIPSIS',
   ]

   # 'keywords' is a map of string to token type.  All tokens matching
   # KEYWORD_OR_SYMBOL are matched against keywords dictionary, to determine
   # if the token is actually a keyword.
   keywords = {
     'any' : 'ANY',
     'attribute' : 'ATTRIBUTE',
     'boolean' : 'BOOLEAN',
     'byte' : 'BYTE',
     'ByteString' : 'BYTESTRING',
     'callback' : 'CALLBACK',
     'const' : 'CONST',
     'creator' : 'CREATOR',
     'Date' : 'DATE',
     'deleter' : 'DELETER',
     'dictionary' : 'DICTIONARY',
     'DOMString' : 'DOMSTRING',
     'double' : 'DOUBLE',
     'enum'  : 'ENUM',
     'exception' : 'EXCEPTION',
     'false' : 'FALSE',
     'float' : 'FLOAT',
     'FrozenArray' : 'FROZENARRAY',
     'getter': 'GETTER',
     'implements' : 'IMPLEMENTS',
     'Infinity' : 'INFINITY',
     'inherit' : 'INHERIT',
     'interface' : 'INTERFACE',
     'iterable': 'ITERABLE',
     'legacycaller' : 'LEGACYCALLER',
     'legacyiterable' : 'LEGACYITERABLE',
     'long' : 'LONG',
     'maplike': 'MAPLIKE',
     'Nan' : 'NAN',
     'null' : 'NULL',
     'object' : 'OBJECT',
     'octet' : 'OCTET',
     'optional' : 'OPTIONAL',
     'or' : 'OR',
     'partial' : 'PARTIAL',
     'Promise' : 'PROMISE',
     'readonly' : 'READONLY',
     'RegExp' : 'REGEXP',
     'record' : 'RECORD',
     'required' : 'REQUIRED',
     'sequence' : 'SEQUENCE',
     'serializer' : 'SERIALIZER',
     'setlike' : 'SETLIKE',
     'setter': 'SETTER',
     'short' : 'SHORT',
     'static' : 'STATIC',
     'stringifier' : 'STRINGIFIER',
     'typedef' : 'TYPEDEF',
     'true' : 'TRUE',
     'unsigned' : 'UNSIGNED',
     'unrestricted' : 'UNRESTRICTED',
     'USVString' : 'USVSTRING',
     'void' : 'VOID'
   }

   # Token definitions
   #
   # Lex assumes any value or function in the form of 't_<TYPE>' represents a
   # regular expression where a match will emit a token of type <TYPE>.  In the
   # case of a function, the function is called when a match is made. These
   # definitions come from WebIDL.
   #
   # These need to be methods for lexer construction, despite not using self.
   # pylint: disable=R0201
   def t_ELLIPSIS(self, t):
     r'\.\.\.'
     return t

   # Regex needs to be in the docstring
   # pylint: disable=C0301
   def t_float(self, t):
     r'-?(([0-9]+\.[0-9]*|[0-9]*\.[0-9]+)([Ee][+-]?[0-9]+)?|[0-9]+[Ee][+-]?[0-9]+)'
     return t

   def t_integer(self, t):
     r'-?([1-9][0-9]*|0[Xx][0-9A-Fa-f]+|0[0-7]*)'
     return t


   # A line ending '\n', we use this to increment the line number
   def t_LINE_END(self, t):
     r'\n+'
     self.AddLines(len(t.value))

   # We do not process escapes in the IDL strings.  Strings are exclusively
   # used for attributes and enums, and not used as typical 'C' constants.
   def t_string(self, t):
     r'"[^"]*"'
     t.value = t.value[1:-1]
     self.AddLines(t.value.count('\n'))
     return t

   # A C or C++ style comment:  /* xxx */ or //
   def t_COMMENT(self, t):
     r'(/\*(.|\n)*?\*/)|(//.*(\n[ \t]*//.*)*)'
     self.AddLines(t.value.count('\n'))
     return t

   # A symbol or keyword.
   def t_KEYWORD_OR_SYMBOL(self, t):
     r'_?[A-Za-z][A-Za-z_0-9]*'

     # All non-keywords are assumed to be symbols
     t.type = self.keywords.get(t.value, 'identifier')

     # We strip leading underscores so that you can specify symbols with the same
     # value as a keywords (E.g. a dictionary named 'interface').
     if t.value[0] == '_':
       t.value = t.value[1:]
     return t

   def t_ANY_error(self, t):
     msg = 'Unrecognized input'
     line = self.Lexer().lineno

     # If that line has not been accounted for, then we must have hit
     # EoF, so compute the beginning of the line that caused the problem.
     if line >= len(self.index):
       # Find the offset in the line of the first word causing the issue
       word = t.value.split()[0]
       offs = self.lines[line - 1].find(word)
       # Add the computed line's starting position
       self.index.append(self.Lexer().lexpos - offs)
       msg = 'Unexpected EoF reached after'

     pos = self.Lexer().lexpos - self.index[line]
     out = self.ErrorMessage(line, pos, msg)
     sys.stderr.write(out + '\n')
     self._lex_errors += 1


   def AddLines(self, count):
     # Set the lexer position for the beginning of the next line.  In the case
     # of multiple lines, tokens can not exist on any of the lines except the
     # last one, so the recorded value for previous lines are unused.  We still
     # fill the array however, to make sure the line count is correct.
     self.Lexer().lineno += count
     for _ in range(count):
       self.index.append(self.Lexer().lexpos)

   def FileLineMsg(self, line, msg):
     # Generate a message containing the file and line number of a token.
     filename = self.Lexer().filename
     if filename:
       return "%s(%d) : %s" % (filename, line + 1, msg)
     return "<BuiltIn> : %s" % msg

   def SourceLine(self, line, pos):
     # Create a source line marker
     caret = ' ' * pos + '^'
     # We decrement the line number since the array is 0 based while the
     # line numbers are 1 based.
     return "%s\n%s" % (self.lines[line - 1], caret)

   def ErrorMessage(self, line, pos, msg):
     return "\n%s\n%s" % (
         self.FileLineMsg(line, msg),
         self.SourceLine(line, pos))

 #
 # Tokenizer
 #
 # The token function returns the next token provided by IDLLexer for matching
 # against the leaf paterns.
 #
   def token(self):
     tok = self.Lexer().token()
     if tok:
       self.last = tok
     return tok


   def GetTokens(self):
     outlist = []
     while True:
       t = self.Lexer().token()
       if not t:
         break
       outlist.append(t)
     return outlist

   def Tokenize(self, data, filename='__no_file__'):
     lexer = self.Lexer()
     lexer.lineno = 1
     lexer.filename = filename
     lexer.input(data)
     self.lines = data.split('\n')

   def KnownTokens(self):
     return self.tokens

   def Lexer(self):
     if not self._lexobj:
       self._lexobj = lex.lex(object=self, lextab=None, optimize=0)
     return self._lexobj

   def _AddToken(self, token):
     if token in self.tokens:
       raise RuntimeError('Same token: ' + token)
     self.tokens.append(token)

   def _AddTokens(self, tokens):
     for token in tokens:
       self._AddToken(token)

   def _AddKeywords(self, keywords):
     for key in keywords:
       value = key.upper()
       self._AddToken(value)
       self.keywords[key] = value

   def _DelKeywords(self, keywords):
     for key in keywords:
       self.tokens.remove(key.upper())
       del self.keywords[key]

   def __init__(self):
     self.index = [0]
     self._lex_errors = 0
     self.linex = []
     self.filename = None
     self.keywords = {}
     self.tokens = []
     self._AddTokens(IDLLexer.tokens)
     self._AddKeywords(IDLLexer.keywords)
     self._lexobj = None
     self.last = None
     self.lines = None

 # If run by itself, attempt to build the lexer
 if __name__ == '__main__':
   lexer_object = IDLLexer()
	#!/usr/bin/env python
	# Copyright (c) 2013 The Chromium Authors. All rights reserved.
	# Use of this source code is governed by a BSD-style license that can be
	# found in the LICENSE file.

	""" Lexer for PPAPI IDL

	The lexer uses the PLY library to build a tokenizer which understands both
	WebIDL and Pepper tokens.

	WebIDL, and WebIDL regular expressions can be found at:
	http://heycam.github.io/webidl/
	PLY can be found at:
	http://www.dabeaz.com/ply/
	"""

	import os.path
	import sys

	SRC_DIR = os.path.join(os.path.dirname(__file__), os.pardir, os.pardir)
	sys.path.insert(0, os.path.join(SRC_DIR, 'third_party'))
	from ply import lex


	#
	# IDL Lexer
	#
	class IDLLexer(object):
	# 'literals' is a value expected by lex which specifies a list of valid
	# literal tokens, meaning the token type and token value are identical.
	literals = r'"*.(){}[],;:=+-/~\|&^?<>'

	# 't_ignore' contains ignored characters (spaces and tabs)
	t_ignore = ' \t'

	# 'tokens' is a value required by lex which specifies the complete list
	# of valid token types.
	tokens = [
	# Data types
	'float',
	'integer',
	'string',

	# Symbol and keywords types
	'COMMENT',
	'identifier',

	# MultiChar operators
	'ELLIPSIS',
	]

	# 'keywords' is a map of string to token type. All tokens matching
	# KEYWORD_OR_SYMBOL are matched against keywords dictionary, to determine
	# if the token is actually a keyword.
	keywords = {
	'any' : 'ANY',
	'attribute' : 'ATTRIBUTE',
	'boolean' : 'BOOLEAN',
	'byte' : 'BYTE',
	'ByteString' : 'BYTESTRING',
	'callback' : 'CALLBACK',
	'const' : 'CONST',
	'creator' : 'CREATOR',
	'Date' : 'DATE',
	'deleter' : 'DELETER',
	'dictionary' : 'DICTIONARY',
	'DOMString' : 'DOMSTRING',
	'double' : 'DOUBLE',
	'enum' : 'ENUM',
	'exception' : 'EXCEPTION',
	'false' : 'FALSE',
	'float' : 'FLOAT',
	'FrozenArray' : 'FROZENARRAY',
	'getter': 'GETTER',
	'implements' : 'IMPLEMENTS',
	'Infinity' : 'INFINITY',
	'inherit' : 'INHERIT',
	'interface' : 'INTERFACE',
	'iterable': 'ITERABLE',
	'legacycaller' : 'LEGACYCALLER',
	'legacyiterable' : 'LEGACYITERABLE',
	'long' : 'LONG',
	'maplike': 'MAPLIKE',
	'Nan' : 'NAN',
	'null' : 'NULL',
	'object' : 'OBJECT',
	'octet' : 'OCTET',
	'optional' : 'OPTIONAL',
	'or' : 'OR',
	'partial' : 'PARTIAL',
	'Promise' : 'PROMISE',
	'readonly' : 'READONLY',
	'RegExp' : 'REGEXP',
	'record' : 'RECORD',
	'required' : 'REQUIRED',
	'sequence' : 'SEQUENCE',
	'serializer' : 'SERIALIZER',
	'setlike' : 'SETLIKE',
	'setter': 'SETTER',
	'short' : 'SHORT',
	'static' : 'STATIC',
	'stringifier' : 'STRINGIFIER',
	'typedef' : 'TYPEDEF',
	'true' : 'TRUE',
	'unsigned' : 'UNSIGNED',
	'unrestricted' : 'UNRESTRICTED',
	'USVString' : 'USVSTRING',
	'void' : 'VOID'
	}

	# Token definitions
	#
	# Lex assumes any value or function in the form of 't_<TYPE>' represents a
	# regular expression where a match will emit a token of type <TYPE>. In the
	# case of a function, the function is called when a match is made. These
	# definitions come from WebIDL.
	#
	# These need to be methods for lexer construction, despite not using self.
	# pylint: disable=R0201
	def t_ELLIPSIS(self, t):
	r'\.\.\.'
	return t

	# Regex needs to be in the docstring
	# pylint: disable=C0301
	def t_float(self, t):
	r'-?(([0-9]+\.[0-9]\|[0-9]\.[0-9]+)([Ee][+-]?[0-9]+)?\|[0-9]+[Ee][+-]?[0-9]+)'
	return t

	def t_integer(self, t):
	r'-?([1-9][0-9]\|0[Xx][0-9A-Fa-f]+\|0[0-7])'
	return t


	# A line ending '\n', we use this to increment the line number
	def t_LINE_END(self, t):
	r'\n+'
	self.AddLines(len(t.value))

	# We do not process escapes in the IDL strings. Strings are exclusively
	# used for attributes and enums, and not used as typical 'C' constants.
	def t_string(self, t):
	r'"[^"]*"'
	t.value = t.value[1:-1]
	self.AddLines(t.value.count('\n'))
	return t

	# A C or C++ style comment: /* xxx */ or //
	def t_COMMENT(self, t):
	r'(/\(.\|\n)?\/)\|(//.(\n[ \t]//.)*)'
	self.AddLines(t.value.count('\n'))
	return t

	# A symbol or keyword.
	def t_KEYWORD_OR_SYMBOL(self, t):
	r'_?[A-Za-z][A-Za-z_0-9]*'

	# All non-keywords are assumed to be symbols
	t.type = self.keywords.get(t.value, 'identifier')

	# We strip leading underscores so that you can specify symbols with the same
	# value as a keywords (E.g. a dictionary named 'interface').
	if t.value[0] == '_':
	t.value = t.value[1:]
	return t

	def t_ANY_error(self, t):
	msg = 'Unrecognized input'
	line = self.Lexer().lineno

	# If that line has not been accounted for, then we must have hit
	# EoF, so compute the beginning of the line that caused the problem.
	if line >= len(self.index):
	# Find the offset in the line of the first word causing the issue
	word = t.value.split()[0]
	offs = self.lines[line - 1].find(word)
	# Add the computed line's starting position
	self.index.append(self.Lexer().lexpos - offs)
	msg = 'Unexpected EoF reached after'

	pos = self.Lexer().lexpos - self.index[line]
	out = self.ErrorMessage(line, pos, msg)
	sys.stderr.write(out + '\n')
	self._lex_errors += 1


	def AddLines(self, count):
	# Set the lexer position for the beginning of the next line. In the case
	# of multiple lines, tokens can not exist on any of the lines except the
	# last one, so the recorded value for previous lines are unused. We still
	# fill the array however, to make sure the line count is correct.
	self.Lexer().lineno += count
	for _ in range(count):
	self.index.append(self.Lexer().lexpos)

	def FileLineMsg(self, line, msg):
	# Generate a message containing the file and line number of a token.
	filename = self.Lexer().filename
	if filename:
	return "%s(%d) : %s" % (filename, line + 1, msg)
	return "<BuiltIn> : %s" % msg

	def SourceLine(self, line, pos):
	# Create a source line marker
	caret = ' ' * pos + '^'
	# We decrement the line number since the array is 0 based while the
	# line numbers are 1 based.
	return "%s\n%s" % (self.lines[line - 1], caret)

	def ErrorMessage(self, line, pos, msg):
	return "\n%s\n%s" % (
	self.FileLineMsg(line, msg),
	self.SourceLine(line, pos))

	#
	# Tokenizer
	#
	# The token function returns the next token provided by IDLLexer for matching
	# against the leaf paterns.
	#
	def token(self):
	tok = self.Lexer().token()
	if tok:
	self.last = tok
	return tok


	def GetTokens(self):
	outlist = []
	while True:
	t = self.Lexer().token()
	if not t:
	break
	outlist.append(t)
	return outlist

	def Tokenize(self, data, filename='__no_file__'):
	lexer = self.Lexer()
	lexer.lineno = 1
	lexer.filename = filename
	lexer.input(data)
	self.lines = data.split('\n')

	def KnownTokens(self):
	return self.tokens

	def Lexer(self):
	if not self._lexobj:
	self._lexobj = lex.lex(object=self, lextab=None, optimize=0)
	return self._lexobj

	def _AddToken(self, token):
	if token in self.tokens:
	raise RuntimeError('Same token: ' + token)
	self.tokens.append(token)

	def _AddTokens(self, tokens):
	for token in tokens:
	self._AddToken(token)

	def _AddKeywords(self, keywords):
	for key in keywords:
	value = key.upper()
	self._AddToken(value)
	self.keywords[key] = value

	def _DelKeywords(self, keywords):
	for key in keywords:
	self.tokens.remove(key.upper())
	del self.keywords[key]

	def __init__(self):
	self.index = [0]
	self._lex_errors = 0
	self.linex = []
	self.filename = None
	self.keywords = {}
	self.tokens = []
	self._AddTokens(IDLLexer.tokens)
	self._AddKeywords(IDLLexer.keywords)
	self._lexobj = None
	self.last = None
	self.lines = None

	# If run by itself, attempt to build the lexer
	if __name__ == '__main__':
	lexer_object = IDLLexer()