tools/grit/grit/pseudo.py - chromium/src - Git at Google

 #!/usr/bin/python2.4
 # Copyright (c) 2006-2008 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.

 '''Pseudotranslation support.  Our pseudotranslations are based on the
 P-language, which is a simple vowel-extending language.  Examples of P:
   - "hello" becomes "hepellopo"
   - "howdie" becomes "hopowdiepie"
   - "because" becomes "bepecaupause" (but in our implementation we don't
     handle the silent e at the end so it actually would return "bepecaupausepe"

 The P-language has the excellent quality of increasing the length of text
 by around 30-50% which is great for pseudotranslations, to stress test any
 GUI layouts etc.

 To make the pseudotranslations more obviously "not a translation" and to make
 them exercise any code that deals with encodings, we also transform all English
 vowels into equivalent vowels with diacriticals on them (rings, acutes,
 diaresis, and circumflex), and we write the "p" in the P-language as a Hebrew
 character Qof.  It looks sort of like a latin character "p" but it is outside
 the latin-1 character set which will stress character encoding bugs.
 '''

 import re
 import types

 from grit import tclib


 # An RFC language code for the P pseudolanguage.
 PSEUDO_LANG = 'x-P-pseudo'

 # Hebrew character Qof.  It looks kind of like a 'p' but is outside
 # the latin-1 character set which is good for our purposes.
 # TODO(joi) For now using P instead of Qof, because of some bugs it used.  Find
 # a better solution, i.e. one that introduces a non-latin1 character into the
 # pseudotranslation.
 #_QOF = u'\u05e7'
 _QOF = u'P'

 # How we map each vowel.
 _VOWELS = {
   u'a' : u'\u00e5',  # a with ring
   u'e' : u'\u00e9',  # e acute
   u'i' : u'\u00ef',  # i diaresis
   u'o' : u'\u00f4',  # o circumflex
   u'u' : u'\u00fc',  # u diaresis
   u'y' : u'\u00fd',  # y acute
   u'A' : u'\u00c5',  # A with ring
   u'E' : u'\u00c9',  # E acute
   u'I' : u'\u00cf',  # I diaresis
   u'O' : u'\u00d4',  # O circumflex
   u'U' : u'\u00dc',  # U diaresis
   u'Y' : u'\u00dd',  # Y acute
 }

 # Matches vowels and P
 _PSUB_RE = re.compile("(%s)" % '|'.join(_VOWELS.keys() + ['P']))


 # Pseudotranslations previously created.  This is important for performance
 # reasons, especially since we routinely pseudotranslate the whole project
 # several or many different times for each build.
 _existing_translations = {}


 def MapVowels(str, also_p = False):
   '''Returns a copy of 'str' where characters that exist as keys in _VOWELS
   have been replaced with the corresponding value.  If also_p is true, this
   function will also change capital P characters into a Hebrew character Qof.
   '''
   def Repl(match):
     if match.group() == 'p':
       if also_p:
         return _QOF
       else:
         return 'p'
     else:
       return _VOWELS[match.group()]
   return _PSUB_RE.sub(Repl, str)


 def PseudoString(str):
   '''Returns a pseudotranslation of the provided string, in our enhanced
   P-language.'''
   if str in _existing_translations:
     return _existing_translations[str]

   outstr = u''
   ix = 0
   while ix < len(str):
     if str[ix] not in _VOWELS.keys():
       outstr += str[ix]
       ix += 1
     else:
       # We want to treat consecutive vowels as one composite vowel.  This is not
       # always accurate e.g. in composite words but good enough.
       consecutive_vowels = u''
       while ix < len(str) and str[ix] in _VOWELS.keys():
         consecutive_vowels += str[ix]
         ix += 1
       changed_vowels = MapVowels(consecutive_vowels)
       outstr += changed_vowels
       outstr += _QOF
       outstr += changed_vowels

   _existing_translations[str] = outstr
   return outstr


 def PseudoMessage(message):
   '''Returns a pseudotranslation of the provided message.

   Args:
     message: tclib.Message()

   Return:
     tclib.Translation()
   '''
   transl = tclib.Translation()

   for part in message.GetContent():
     if isinstance(part, tclib.Placeholder):
       transl.AppendPlaceholder(part)
     else:
       transl.AppendText(PseudoString(part))

   return transl
	#!/usr/bin/python2.4
	# Copyright (c) 2006-2008 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.

	'''Pseudotranslation support. Our pseudotranslations are based on the
	P-language, which is a simple vowel-extending language. Examples of P:
	- "hello" becomes "hepellopo"
	- "howdie" becomes "hopowdiepie"
	- "because" becomes "bepecaupause" (but in our implementation we don't
	handle the silent e at the end so it actually would return "bepecaupausepe"

	The P-language has the excellent quality of increasing the length of text
	by around 30-50% which is great for pseudotranslations, to stress test any
	GUI layouts etc.

	To make the pseudotranslations more obviously "not a translation" and to make
	them exercise any code that deals with encodings, we also transform all English
	vowels into equivalent vowels with diacriticals on them (rings, acutes,
	diaresis, and circumflex), and we write the "p" in the P-language as a Hebrew
	character Qof. It looks sort of like a latin character "p" but it is outside
	the latin-1 character set which will stress character encoding bugs.
	'''

	import re
	import types

	from grit import tclib


	# An RFC language code for the P pseudolanguage.
	PSEUDO_LANG = 'x-P-pseudo'

	# Hebrew character Qof. It looks kind of like a 'p' but is outside
	# the latin-1 character set which is good for our purposes.
	# TODO(joi) For now using P instead of Qof, because of some bugs it used. Find
	# a better solution, i.e. one that introduces a non-latin1 character into the
	# pseudotranslation.
	#_QOF = u'\u05e7'
	_QOF = u'P'

	# How we map each vowel.
	_VOWELS = {
	u'a' : u'\u00e5', # a with ring
	u'e' : u'\u00e9', # e acute
	u'i' : u'\u00ef', # i diaresis
	u'o' : u'\u00f4', # o circumflex
	u'u' : u'\u00fc', # u diaresis
	u'y' : u'\u00fd', # y acute
	u'A' : u'\u00c5', # A with ring
	u'E' : u'\u00c9', # E acute
	u'I' : u'\u00cf', # I diaresis
	u'O' : u'\u00d4', # O circumflex
	u'U' : u'\u00dc', # U diaresis
	u'Y' : u'\u00dd', # Y acute
	}

	# Matches vowels and P
	_PSUB_RE = re.compile("(%s)" % '\|'.join(_VOWELS.keys() + ['P']))


	# Pseudotranslations previously created. This is important for performance
	# reasons, especially since we routinely pseudotranslate the whole project
	# several or many different times for each build.
	_existing_translations = {}


	def MapVowels(str, also_p = False):
	'''Returns a copy of 'str' where characters that exist as keys in _VOWELS
	have been replaced with the corresponding value. If also_p is true, this
	function will also change capital P characters into a Hebrew character Qof.
	'''
	def Repl(match):
	if match.group() == 'p':
	if also_p:
	return _QOF
	else:
	return 'p'
	else:
	return _VOWELS[match.group()]
	return _PSUB_RE.sub(Repl, str)


	def PseudoString(str):
	'''Returns a pseudotranslation of the provided string, in our enhanced
	P-language.'''
	if str in _existing_translations:
	return _existing_translations[str]

	outstr = u''
	ix = 0
	while ix < len(str):
	if str[ix] not in _VOWELS.keys():
	outstr += str[ix]
	ix += 1
	else:
	# We want to treat consecutive vowels as one composite vowel. This is not
	# always accurate e.g. in composite words but good enough.
	consecutive_vowels = u''
	while ix < len(str) and str[ix] in _VOWELS.keys():
	consecutive_vowels += str[ix]
	ix += 1
	changed_vowels = MapVowels(consecutive_vowels)
	outstr += changed_vowels
	outstr += _QOF
	outstr += changed_vowels

	_existing_translations[str] = outstr
	return outstr


	def PseudoMessage(message):
	'''Returns a pseudotranslation of the provided message.

	Args:
	message: tclib.Message()

	Return:
	tclib.Translation()
	'''
	transl = tclib.Translation()

	for part in message.GetContent():
	if isinstance(part, tclib.Placeholder):
	transl.AppendPlaceholder(part)
	else:
	transl.AppendText(PseudoString(part))

	return transl