ppapi/generators/idl_lexer.py - chromium/src.git - Git at Google

 #!/usr/bin/env python
 # Copyright (c) 2012 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 """

 #
 # IDL Lexer
 #
 # The lexer is uses the PLY lex library to build a tokenizer which understands
 # WebIDL tokens.
 #
 # WebIDL, and WebIDL regular expressions can be found at:
 #   http://dev.w3.org/2006/webapi/WebIDL/
 # PLY can be found at:
 #   http://www.dabeaz.com/ply/

 import os.path
 import re
 import sys

 #
 # Try to load the ply module, if not, then assume it is in the third_party
 # directory, relative to ppapi
 #
 try:
   from ply import lex
 except:
   module_path, module_name = os.path.split(__file__)
   third_party = os.path.join(module_path, '..', '..', 'third_party')
   sys.path.append(third_party)
   from ply import lex

 from idl_option import GetOption, Option, ParseOptions


 Option('output', 'Generate output.')

 #
 # IDL Lexer
 #
 class IDLLexer(object):
   # 'tokens' is a value required by lex which specifies the complete list
   # of valid token types.
   tokens = [
     # Symbol and keywords types
       'COMMENT',
       'DESCRIBE',
       'ENUM',
       'LABEL',
       'SYMBOL',
       'INLINE',
       'INTERFACE',
       'STRUCT',
       'TYPEDEF',
       'OR',

     # Extra WebIDL keywords
       'CALLBACK',
       'DICTIONARY',
       'OPTIONAL',
       'STATIC',

     # Invented for apps use
       'NAMESPACE',

     # Data types
       'FLOAT',
       'OCT',
       'INT',
       'HEX',
       'STRING',

     # Operators
       'LSHIFT',
       'RSHIFT'
   ]

   # 'keywords' is a map of string to token type.  All SYMBOL tokens are
   # matched against keywords, to determine if the token is actually a keyword.
   keywords = {
     'describe' : 'DESCRIBE',
     'enum'  : 'ENUM',
     'label' : 'LABEL',
     'interface' : 'INTERFACE',
     'readonly' : 'READONLY',
     'struct' : 'STRUCT',
     'typedef' : 'TYPEDEF',

     'callback' : 'CALLBACK',
     'dictionary' : 'DICTIONARY',
     'optional' : 'OPTIONAL',
     'static' : 'STATIC',
     'namespace' : 'NAMESPACE',

     'or' : 'OR',
   }

   # '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 = '"*.(){}[],;:=+-/~|&^?'

   # 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.

   # 't_ignore' is a special match of items to ignore
   t_ignore = ' \t'

   # Constant values
   t_FLOAT = r'-?(\d+\.\d*|\d*\.\d+)([Ee][+-]?\d+)?|-?\d+[Ee][+-]?\d+'
   t_INT = r'-?[0-9]+[uU]?'
   t_OCT = r'-?0[0-7]+'
   t_HEX = r'-?0[Xx][0-9A-Fa-f]+'
   t_LSHIFT = r'<<'
   t_RSHIFT = r'>>'

   # 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 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

   # Return a "preprocessor" inline block
   def t_INLINE(self, t):
     r'\#inline (.|\n)*?\#endinl.*'
     self.AddLines(t.value.count('\n'))
     return t

   # A symbol or keyword.
   def t_KEYWORD_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, 'SYMBOL')

     # 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.lexobj.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.lexobj.lexpos - offs)
       msg = "Unexpected EoF reached after"

     pos = self.lexobj.lexpos - self.index[line]
     file = self.lexobj.filename
     out = self.ErrorMessage(file, 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.lexobj.lineno += count
     for i in range(count):
       self.index.append(self.lexobj.lexpos)

   def FileLineMsg(self, file, line, msg):
     if file:  return "%s(%d) : %s" % (file, line + 1, msg)
     return "<BuiltIn> : %s" % msg

   def SourceLine(self, file, line, pos):
     caret = '\t^'.expandtabs(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, file, line, pos, msg):
     return "\n%s\n%s" % (
         self.FileLineMsg(file, line, msg),
         self.SourceLine(file, line, pos))

   def SetData(self, filename, data):
     # Start with line 1, not zero
     self.lexobj.lineno = 1
     self.lexobj.filename = filename
     self.lines = data.split('\n')
     self.index = [0]
     self.lexobj.input(data)
     self.lex_errors = 0

   def __init__(self):
     self.lexobj = lex.lex(object=self, lextab=None, optimize=0)


 #
 # FilesToTokens
 #
 # From a set of source file names, generate a list of tokens.
 #
 def FilesToTokens(filenames, verbose=False):
   lexer = IDLLexer()
   outlist = []
   for filename in filenames:
     data = open(filename).read()
     lexer.SetData(filename, data)
     if verbose: sys.stdout.write('  Loaded %s...\n' % filename)
     while 1:
       t = lexer.lexobj.token()
       if t is None: break
       outlist.append(t)
   return outlist


 def TokensFromText(text):
   lexer = IDLLexer()
   lexer.SetData('unknown', text)
   outlist = []
   while 1:
     t = lexer.lexobj.token()
     if t is None: break
     outlist.append(t.value)
   return outlist

 #
 # TextToTokens
 #
 # From a block of text, generate a list of tokens
 #
 def TextToTokens(source):
   lexer = IDLLexer()
   outlist = []
   lexer.SetData('AUTO', source)
   while 1:
     t = lexer.lexobj.token()
     if t is None: break
     outlist.append(t.value)
   return outlist


 #
 # TestSame
 #
 # From a set of token values, generate a new source text by joining with a
 # single space.  The new source is then tokenized and compared against the
 # old set.
 #
 def TestSame(values1):
   # Recreate the source from the tokens.  We use newline instead of whitespace
   # since the '//' and #inline regex are line sensitive.
   text = '\n'.join(values1)
   values2 = TextToTokens(text)

   count1 = len(values1)
   count2 = len(values2)
   if count1 != count2:
     print "Size mismatch original %d vs %d\n" % (count1, count2)
     if count1 > count2: count1 = count2

   for i in range(count1):
     if values1[i] != values2[i]:
       print "%d >>%s<< >>%s<<" % (i, values1[i], values2[i])

   if GetOption('output'):
     sys.stdout.write('Generating original.txt and tokenized.txt\n')
     open('original.txt', 'w').write(src1)
     open('tokenized.txt', 'w').write(src2)

   if values1 == values2:
     sys.stdout.write('Same: Pass\n')
     return 0

   print "****************\n%s\n%s***************\n" % (src1, src2)
   sys.stdout.write('Same: Failed\n')
   return -1


 #
 # TestExpect
 #
 # From a set of tokens pairs, verify the type field of the second matches
 # the value of the first, so that:
 # INT 123 FLOAT 1.1
 # will generate a passing test, where the first token is the SYMBOL INT,
 # and the second token is the INT 123, third token is the SYMBOL FLOAT and
 # the fourth is the FLOAT 1.1, etc...
 def TestExpect(tokens):
   count = len(tokens)
   index = 0
   errors = 0
   while index < count:
     type = tokens[index].value
     token = tokens[index + 1]
     index += 2

     if type != token.type:
       sys.stderr.write('Mismatch:  Expected %s, but got %s = %s.\n' %
                        (type, token.type, token.value))
       errors += 1

   if not errors:
     sys.stdout.write('Expect: Pass\n')
     return 0

   sys.stdout.write('Expect: Failed\n')
   return -1


 def Main(args):
   filenames = ParseOptions(args)

   try:
     tokens = FilesToTokens(filenames, GetOption('verbose'))
     values = [tok.value for tok in tokens]
     if GetOption('output'): sys.stdout.write(' <> '.join(values) + '\n')
     if GetOption('test'):
       if TestSame(values):
         return -1
       if TestExpect(tokens):
         return -1
     return 0

   except lex.LexError as le:
     sys.stderr.write('%s\n' % str(le))
   return -1


 if __name__ == '__main__':
   sys.exit(Main(sys.argv[1:]))
	#!/usr/bin/env python
	# Copyright (c) 2012 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 """

	#
	# IDL Lexer
	#
	# The lexer is uses the PLY lex library to build a tokenizer which understands
	# WebIDL tokens.
	#
	# WebIDL, and WebIDL regular expressions can be found at:
	# http://dev.w3.org/2006/webapi/WebIDL/
	# PLY can be found at:
	# http://www.dabeaz.com/ply/

	import os.path
	import re
	import sys

	#
	# Try to load the ply module, if not, then assume it is in the third_party
	# directory, relative to ppapi
	#
	try:
	from ply import lex
	except:
	module_path, module_name = os.path.split(__file__)
	third_party = os.path.join(module_path, '..', '..', 'third_party')
	sys.path.append(third_party)
	from ply import lex

	from idl_option import GetOption, Option, ParseOptions


	Option('output', 'Generate output.')

	#
	# IDL Lexer
	#
	class IDLLexer(object):
	# 'tokens' is a value required by lex which specifies the complete list
	# of valid token types.
	tokens = [
	# Symbol and keywords types
	'COMMENT',
	'DESCRIBE',
	'ENUM',
	'LABEL',
	'SYMBOL',
	'INLINE',
	'INTERFACE',
	'STRUCT',
	'TYPEDEF',
	'OR',

	# Extra WebIDL keywords
	'CALLBACK',
	'DICTIONARY',
	'OPTIONAL',
	'STATIC',

	# Invented for apps use
	'NAMESPACE',

	# Data types
	'FLOAT',
	'OCT',
	'INT',
	'HEX',
	'STRING',

	# Operators
	'LSHIFT',
	'RSHIFT'
	]

	# 'keywords' is a map of string to token type. All SYMBOL tokens are
	# matched against keywords, to determine if the token is actually a keyword.
	keywords = {
	'describe' : 'DESCRIBE',
	'enum' : 'ENUM',
	'label' : 'LABEL',
	'interface' : 'INTERFACE',
	'readonly' : 'READONLY',
	'struct' : 'STRUCT',
	'typedef' : 'TYPEDEF',

	'callback' : 'CALLBACK',
	'dictionary' : 'DICTIONARY',
	'optional' : 'OPTIONAL',
	'static' : 'STATIC',
	'namespace' : 'NAMESPACE',

	'or' : 'OR',
	}

	# '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 = '"*.(){}[],;:=+-/~\|&^?'

	# 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.

	# 't_ignore' is a special match of items to ignore
	t_ignore = ' \t'

	# Constant values
	t_FLOAT = r'-?(\d+\.\d\|\d\.\d+)([Ee][+-]?\d+)?\|-?\d+[Ee][+-]?\d+'
	t_INT = r'-?[0-9]+[uU]?'
	t_OCT = r'-?0[0-7]+'
	t_HEX = r'-?0[Xx][0-9A-Fa-f]+'
	t_LSHIFT = r'<<'
	t_RSHIFT = r'>>'

	# 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 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

	# Return a "preprocessor" inline block
	def t_INLINE(self, t):
	r'\#inline (.\|\n)?\#endinl.'
	self.AddLines(t.value.count('\n'))
	return t

	# A symbol or keyword.
	def t_KEYWORD_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, 'SYMBOL')

	# 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.lexobj.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.lexobj.lexpos - offs)
	msg = "Unexpected EoF reached after"

	pos = self.lexobj.lexpos - self.index[line]
	file = self.lexobj.filename
	out = self.ErrorMessage(file, 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.lexobj.lineno += count
	for i in range(count):
	self.index.append(self.lexobj.lexpos)

	def FileLineMsg(self, file, line, msg):
	if file: return "%s(%d) : %s" % (file, line + 1, msg)
	return "<BuiltIn> : %s" % msg

	def SourceLine(self, file, line, pos):
	caret = '\t^'.expandtabs(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, file, line, pos, msg):
	return "\n%s\n%s" % (
	self.FileLineMsg(file, line, msg),
	self.SourceLine(file, line, pos))

	def SetData(self, filename, data):
	# Start with line 1, not zero
	self.lexobj.lineno = 1
	self.lexobj.filename = filename
	self.lines = data.split('\n')
	self.index = [0]
	self.lexobj.input(data)
	self.lex_errors = 0

	def __init__(self):
	self.lexobj = lex.lex(object=self, lextab=None, optimize=0)



	#
	# FilesToTokens
	#
	# From a set of source file names, generate a list of tokens.
	#
	def FilesToTokens(filenames, verbose=False):
	lexer = IDLLexer()
	outlist = []
	for filename in filenames:
	data = open(filename).read()
	lexer.SetData(filename, data)
	if verbose: sys.stdout.write(' Loaded %s...\n' % filename)
	while 1:
	t = lexer.lexobj.token()
	if t is None: break
	outlist.append(t)
	return outlist


	def TokensFromText(text):
	lexer = IDLLexer()
	lexer.SetData('unknown', text)
	outlist = []
	while 1:
	t = lexer.lexobj.token()
	if t is None: break
	outlist.append(t.value)
	return outlist

	#
	# TextToTokens
	#
	# From a block of text, generate a list of tokens
	#
	def TextToTokens(source):
	lexer = IDLLexer()
	outlist = []
	lexer.SetData('AUTO', source)
	while 1:
	t = lexer.lexobj.token()
	if t is None: break
	outlist.append(t.value)
	return outlist


	#
	# TestSame
	#
	# From a set of token values, generate a new source text by joining with a
	# single space. The new source is then tokenized and compared against the
	# old set.
	#
	def TestSame(values1):
	# Recreate the source from the tokens. We use newline instead of whitespace
	# since the '//' and #inline regex are line sensitive.
	text = '\n'.join(values1)
	values2 = TextToTokens(text)

	count1 = len(values1)
	count2 = len(values2)
	if count1 != count2:
	print "Size mismatch original %d vs %d\n" % (count1, count2)
	if count1 > count2: count1 = count2

	for i in range(count1):
	if values1[i] != values2[i]:
	print "%d >>%s<< >>%s<<" % (i, values1[i], values2[i])

	if GetOption('output'):
	sys.stdout.write('Generating original.txt and tokenized.txt\n')
	open('original.txt', 'w').write(src1)
	open('tokenized.txt', 'w').write(src2)

	if values1 == values2:
	sys.stdout.write('Same: Pass\n')
	return 0

	print "**************\n%s\n%s*************\n" % (src1, src2)
	sys.stdout.write('Same: Failed\n')
	return -1


	#
	# TestExpect
	#
	# From a set of tokens pairs, verify the type field of the second matches
	# the value of the first, so that:
	# INT 123 FLOAT 1.1
	# will generate a passing test, where the first token is the SYMBOL INT,
	# and the second token is the INT 123, third token is the SYMBOL FLOAT and
	# the fourth is the FLOAT 1.1, etc...
	def TestExpect(tokens):
	count = len(tokens)
	index = 0
	errors = 0
	while index < count:
	type = tokens[index].value
	token = tokens[index + 1]
	index += 2

	if type != token.type:
	sys.stderr.write('Mismatch: Expected %s, but got %s = %s.\n' %
	(type, token.type, token.value))
	errors += 1

	if not errors:
	sys.stdout.write('Expect: Pass\n')
	return 0

	sys.stdout.write('Expect: Failed\n')
	return -1


	def Main(args):
	filenames = ParseOptions(args)

	try:
	tokens = FilesToTokens(filenames, GetOption('verbose'))
	values = [tok.value for tok in tokens]
	if GetOption('output'): sys.stdout.write(' <> '.join(values) + '\n')
	if GetOption('test'):
	if TestSame(values):
	return -1
	if TestExpect(tokens):
	return -1
	return 0

	except lex.LexError as le:
	sys.stderr.write('%s\n' % str(le))
	return -1


	if __name__ == '__main__':
	sys.exit(Main(sys.argv[1:]))