src/build/android/convert_dex_profile.py - cobalt - Git at Google

 #!/usr/bin/env vpython
 #
 # Copyright 2018 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.

 import argparse
 import collections
 import logging
 import re
 import subprocess
 import sys

 DEX_CLASS_NAME_RE = re.compile(r'\'L(?P<class_name>[^;]+);\'')
 DEX_METHOD_NAME_RE = re.compile(r'\'(?P<method_name>[^\']+)\'')
 DEX_METHOD_TYPE_RE = re.compile( # type descriptor method signature re
     r'\''
     r'\('
     r'(?P<method_params>[^)]*)'
     r'\)'
     r'(?P<method_return_type>[^\']+)'
     r'\'')
 DEX_METHOD_LINE_NR_RE = re.compile(r'line=(?P<line_number>\d+)')

 PROFILE_METHOD_RE = re.compile(
     r'(?P<tags>[HSP]+)' # tags such as H/S/P
     r'(?P<class_name>L[^;]+;)' # class name in type descriptor format
     r'->(?P<method_name>[^(]+)'
     r'\((?P<method_params>[^)]*)\)'
     r'(?P<method_return_type>.+)')

 PROGUARD_CLASS_MAPPING_RE = re.compile(
     r'(?P<original_name>[^ ]+)'
     r' -> '
     r'(?P<obfuscated_name>[^:]+):')
 PROGUARD_METHOD_MAPPING_RE = re.compile(
     # line_start:line_end: (optional)
     r'((?P<line_start>\d+):(?P<line_end>\d+):)?'
     r'(?P<return_type>[^ ]+)' # original method return type
     # original method class name (if exists)
     r' (?:(?P<original_method_class>[a-zA-Z_\d.$]+)\.)?'
     r'(?P<original_method_name>[^.\(]+)'
     r'\((?P<params>[^\)]*)\)' # original method params
     r'(?:[^ ]*)' # original method line numbers (ignored)
     r' -> '
     r'(?P<obfuscated_name>.+)') # obfuscated method name

 TYPE_DESCRIPTOR_RE = re.compile(
     r'(?P<brackets>\[*)'
     r'(?:'
     r'(?P<class_name>L[^;]+;)'
     r'|'
     r'[VZBSCIJFD]'
     r')')

 DOT_NOTATION_MAP = {
     '': '',
     'boolean': 'Z',
     'byte': 'B',
     'void': 'V',
     'short': 'S',
     'char': 'C',
     'int': 'I',
     'long': 'J',
     'float': 'F',
     'double': 'D'
 }

 class Method(object):
   def __init__(self, name, class_name, param_types=None, return_type=None):
     self.name = name
     self.class_name = class_name
     self.param_types = param_types
     self.return_type = return_type

   def __str__(self):
     return '{}->{}({}){}'.format(self.class_name, self.name,
         self.param_types or '', self.return_type or '')

   def __repr__(self):
     return 'Method<{}->{}({}){}>'.format(self.class_name, self.name,
         self.param_types or '', self.return_type or '')

   def __cmp__(self, other):
     return cmp((self.class_name, self.name, self.param_types, self.return_type),
         (other.class_name, other.name, other.param_types, other.return_type))

   def __hash__(self):
     # only hash name and class_name since other fields may not be set yet.
     return hash((self.name, self.class_name))


 class Class(object):
   def __init__(self, name):
     self.name = name
     self._methods = []

   def AddMethod(self, method, line_numbers):
     self._methods.append((method, set(line_numbers)))

   def FindMethodsAtLine(self, method_name, line_start, line_end=None):
     """Searches through dex class for a method given a name and line numbers

     The dex maps methods to line numbers, this method, given the a method name
     in this class as well as a start line and an optional end line (which act as
     hints as to which function in the class is being looked for), returns a list
     of possible matches (or none if none are found).

     Args:
       method_name: name of method being searched for
       line_start: start of hint range for lines in this method
       line_end: end of hint range for lines in this method (optional)

     Returns:
       A list of Method objects that could match the hints given, or None if no
       method is found.
     """
     found_methods = []
     if line_end is None:
       hint_lines = set([line_start])
     else:
       hint_lines = set(range(line_start, line_end+1))

     named_methods = [(method, l) for method, l in self._methods
                      if method.name == method_name]

     if len(named_methods) == 1:
       return [method for method, l in named_methods]
     if len(named_methods) == 0:
       return None

     for method, line_numbers in named_methods:
       if not hint_lines.isdisjoint(line_numbers):
         found_methods.append(method)

     if len(found_methods) > 0:
       if len(found_methods) > 1:
         logging.warning('ambigous methods in dex %s at lines %s in class "%s"',
             found_methods, hint_lines, self.name)
       return found_methods

     for method, line_numbers in named_methods:
       if (max(hint_lines) >= min(line_numbers)
           and min(hint_lines) <= max(line_numbers)):
         found_methods.append(method)

     if len(found_methods) > 0:
       if len(found_methods) > 1:
         logging.warning('ambigous methods in dex %s at lines %s in class "%s"',
             found_methods, hint_lines, self.name)
       return found_methods
     else:
       logging.warning('No method named "%s" in class "%s" is '
                       'mapped to lines %s', method_name, self.name, hint_lines)
       return None


 class Profile(object):
   def __init__(self):
     # {Method: set(char)}
     self._methods = collections.defaultdict(set)
     self._classes = []

   def AddMethod(self, method, tags):
     for tag in tags:
       self._methods[method].add(tag)

   def AddClass(self, cls):
     self._classes.append(cls)

   def WriteToFile(self, path):
     with open(path, 'w') as output_profile:
       for cls in sorted(self._classes):
         output_profile.write(cls + '\n')
       for method in sorted(self._methods):
         tags = sorted(self._methods[method])
         line = '{}{}\n'.format(''.join(tags), str(method))
         output_profile.write(line)


 class ProguardMapping(object):
   def __init__(self):
     # {Method: set(Method)}
     self._method_mapping = collections.defaultdict(set)
     # {String: String} String is class name in type descriptor format
     self._class_mapping = dict()

   def AddMethodMapping(self, from_method, to_method):
     self._method_mapping[from_method].add(to_method)

   def AddClassMapping(self, from_class, to_class):
     self._class_mapping[from_class] = to_class

   def GetMethodMapping(self, from_method):
     return self._method_mapping.get(from_method)

   def GetClassMapping(self, from_class):
     return self._class_mapping.get(from_class, from_class)

   def MapTypeDescriptor(self, type_descriptor):
     match = TYPE_DESCRIPTOR_RE.search(type_descriptor)
     assert match is not None
     class_name = match.group('class_name')
     if class_name is not None:
       return match.group('brackets') + self.GetClassMapping(class_name)
     # just a native type, return as is
     return match.group()

   def MapTypeDescriptorList(self, type_descriptor_list):
     return TYPE_DESCRIPTOR_RE.sub(
         lambda match: self.MapTypeDescriptor(match.group()),
         type_descriptor_list)


 class MalformedLineException(Exception):
   def __init__(self, message, line_number):
     super(MalformedLineException, self).__init__(message)
     self.line_number = line_number

   def __str__(self):
     return self.message + ' at line {}'.format(self.line_number)


 class MalformedProguardMappingException(MalformedLineException):
   pass


 class MalformedProfileException(MalformedLineException):
   pass


 def _RunDexDump(dexdump_path, dex_file_path):
   return subprocess.check_output([dexdump_path, dex_file_path]).splitlines()


 def _ReadFile(file_path):
   with open(file_path, 'r') as f:
     return f.readlines()


 def _ToTypeDescriptor(dot_notation):
   """Parses a dot notation type and returns it in type descriptor format

   eg:
   org.chromium.browser.ChromeActivity -> Lorg/chromium/browser/ChromeActivity;
   boolean -> Z
   int[] -> [I

   Args:
     dot_notation: trimmed string with a single type in dot notation format

   Returns:
     A string with the type in type descriptor format
   """
   dot_notation = dot_notation.strip()
   prefix = ''
   while dot_notation.endswith('[]'):
     prefix += '['
     dot_notation = dot_notation[:-2]
   if dot_notation in DOT_NOTATION_MAP:
     return prefix + DOT_NOTATION_MAP[dot_notation]
   return prefix + 'L' + dot_notation.replace('.', '/') + ';'


 def _DotNotationListToTypeDescriptorList(dot_notation_list_string):
   """Parses a param list of dot notation format and returns it in type
   descriptor format

   eg:
   org.chromium.browser.ChromeActivity,boolean,int[] ->
       Lorg/chromium/browser/ChromeActivity;Z[I

   Args:
     dot_notation_list_string: single string with multiple comma separated types
                               in dot notation format

   Returns:
     A string with the param list in type descriptor format
   """
   return ''.join(_ToTypeDescriptor(param) for param in
       dot_notation_list_string.split(','))


 def ProcessDex(dex_dump):
   """Parses dexdump output returning a dict of class names to Class objects

   Parses output of the dexdump command on a dex file and extracts information
   about classes and their respective methods and which line numbers a method is
   mapped to.

   Methods that are not mapped to any line number are ignored and not listed
   inside their respective Class objects.

   Args:
     dex_dump: An array of lines of dexdump output

   Returns:
     A dict that maps from class names in type descriptor format (but without the
     surrounding 'L' and ';') to Class objects.
   """
   # class_name: Class
   classes_by_name = {}
   current_class = None
   current_method = None
   reading_positions = False
   reading_methods = False
   method_line_numbers = []
   for line in dex_dump:
     line = line.strip()
     if line.startswith('Class descriptor'):
       # New class started, no longer reading methods.
       reading_methods = False
       current_class = Class(DEX_CLASS_NAME_RE.search(line).group('class_name'))
       classes_by_name[current_class.name] = current_class
     elif (line.startswith('Direct methods')
           or line.startswith('Virtual methods')):
       reading_methods = True
     elif reading_methods and line.startswith('name'):
       assert current_class is not None
       current_method = Method(
           DEX_METHOD_NAME_RE.search(line).group('method_name'),
           "L" + current_class.name + ";")
     elif reading_methods and line.startswith('type'):
       assert current_method is not None
       match = DEX_METHOD_TYPE_RE.search(line)
       current_method.param_types = match.group('method_params')
       current_method.return_type = match.group('method_return_type')
     elif line.startswith('positions'):
       assert reading_methods
       reading_positions = True
       method_line_numbers = []
     elif reading_positions and line.startswith('0x'):
       line_number = DEX_METHOD_LINE_NR_RE.search(line).group('line_number')
       method_line_numbers.append(int(line_number))
     elif reading_positions and line.startswith('locals'):
       if len(method_line_numbers) > 0:
         current_class.AddMethod(current_method, method_line_numbers)
       # finished reading method line numbers
       reading_positions = False
   return classes_by_name


 def ProcessProguardMapping(proguard_mapping_lines, dex):
   """Parses a proguard mapping file

   This takes proguard mapping file lines and then uses the obfuscated dex to
   create a mapping of unobfuscated methods to obfuscated ones and vice versa.

   The dex is used because the proguard mapping file only has the name of the
   obfuscated methods but not their signature, thus the dex is read to look up
   which method with a specific name was mapped to the lines mentioned in the
   proguard mapping file.

   Args:
     proguard_mapping_lines: Array of strings, each is a line from the proguard
                             mapping file (in order).
     dex: a dict of class name (in type descriptor format but without the
          enclosing 'L' and ';') to a Class object.
   Returns:
     Two dicts the first maps from obfuscated methods to a set of non-obfuscated
     ones. It also maps the obfuscated class names to original class names, both
     in type descriptor format (with the enclosing 'L' and ';')
   """
   mapping = ProguardMapping()
   reverse_mapping = ProguardMapping()
   to_be_obfuscated = []
   current_class_orig = None
   current_class_obfs = None
   for index, line in enumerate(proguard_mapping_lines):
     if line.strip() == '':
       continue
     if not line.startswith(' '):
       match = PROGUARD_CLASS_MAPPING_RE.search(line)
       if match is None:
         raise MalformedProguardMappingException(
             'Malformed class mapping', index)
       current_class_orig = match.group('original_name')
       current_class_obfs = match.group('obfuscated_name')
       mapping.AddClassMapping(_ToTypeDescriptor(current_class_obfs),
                               _ToTypeDescriptor(current_class_orig))
       reverse_mapping.AddClassMapping(_ToTypeDescriptor(current_class_orig),
                                       _ToTypeDescriptor(current_class_obfs))
       continue

     assert current_class_orig is not None
     assert current_class_obfs is not None
     line = line.strip()
     match = PROGUARD_METHOD_MAPPING_RE.search(line)
     # check if is a method mapping (we ignore field mappings)
     if match is not None:
       # check if this line is an inlining by reading ahead 1 line.
       if index + 1 < len(proguard_mapping_lines):
         next_match = PROGUARD_METHOD_MAPPING_RE.search(
             proguard_mapping_lines[index+1].strip())
         if (next_match and match.group('line_start') is not None
             and next_match.group('line_start') == match.group('line_start')
             and next_match.group('line_end') == match.group('line_end')):
           continue # This is an inlining, skip

       original_method = Method(
           match.group('original_method_name'),
           _ToTypeDescriptor(
               match.group('original_method_class') or current_class_orig),
           _DotNotationListToTypeDescriptorList(match.group('params')),
           _ToTypeDescriptor(match.group('return_type')))

       if match.group('line_start') is not None:
         obfs_methods = (dex[current_class_obfs.replace('.', '/')]
             .FindMethodsAtLine(
                 match.group('obfuscated_name'),
                 int(match.group('line_start')),
                 int(match.group('line_end'))))

         if obfs_methods is None:
           continue

         for obfs_method in obfs_methods:
           mapping.AddMethodMapping(obfs_method, original_method)
           reverse_mapping.AddMethodMapping(original_method, obfs_method)
       else:
         to_be_obfuscated.append(
             (original_method, match.group('obfuscated_name')))

   for original_method, obfuscated_name in to_be_obfuscated:
     obfuscated_method = Method(
         obfuscated_name,
         reverse_mapping.GetClassMapping(original_method.class_name),
         reverse_mapping.MapTypeDescriptorList(original_method.param_types),
         reverse_mapping.MapTypeDescriptor(original_method.return_type))
     mapping.AddMethodMapping(obfuscated_method, original_method)
     reverse_mapping.AddMethodMapping(original_method, obfuscated_method)
   return mapping, reverse_mapping


 def ProcessProfile(input_profile, proguard_mapping):
   """Parses an android profile and uses the proguard mapping to (de)obfuscate it

   This takes the android profile lines and for each method or class for the
   profile, it uses the mapping to either obfuscate or deobfuscate (based on the
   provided mapping) and returns a Profile object that stores this information.

   Args:
     input_profile: array of lines of the input profile
     proguard_mapping: a proguard mapping that would map from the classes and
                       methods in the input profile to the classes and methods
                       that should be in the output profile.

   Returns:
     A Profile object that stores the information (ie list of mapped classes and
     methods + tags)
   """
   profile = Profile()
   for index, line in enumerate(input_profile):
     line = line.strip()
     if line.startswith('L'):
       profile.AddClass(proguard_mapping.GetClassMapping(line))
       continue
     match = PROFILE_METHOD_RE.search(line)
     if not match:
       raise MalformedProfileException("Malformed line", index)

     method = Method(
         match.group('method_name'),
         match.group('class_name'),
         match.group('method_params'),
         match.group('method_return_type'))

     mapped_methods = proguard_mapping.GetMethodMapping(method)
     if mapped_methods is None:
       logging.warning('No method matching "%s" has been found in the proguard '
                       'mapping file', method)
       continue

     for original_method in mapped_methods:
       profile.AddMethod(original_method, match.group('tags'))

   return profile


 def ObfuscateProfile(nonobfuscated_profile, dex_file, proguard_mapping,
                      dexdump_path, output_filename):
   """Helper method for obfuscating a profile.

   Args:
     nonobfuscated_profile: a profile with nonobfuscated symbols.
     dex_file: path to the dex file matching the mapping.
     proguard_mapping: a mapping from nonobfuscated to obfuscated symbols used
       in the dex file.
     dexdump_path: path to the dexdump utility.
     output_filename: output filename in which to write the obfuscated profile.
   """
   dexinfo = ProcessDex(_RunDexDump(dexdump_path, dex_file))
   _, reverse_mapping = ProcessProguardMapping(
       _ReadFile(proguard_mapping), dexinfo)
   obfuscated_profile = ProcessProfile(
       _ReadFile(nonobfuscated_profile), reverse_mapping)
   obfuscated_profile.WriteToFile(output_filename)


 def main(args):
   parser = argparse.ArgumentParser()
   parser.add_argument(
       '--dexdump-path',
       required=True,
       help='Path to dexdump binary.')
   parser.add_argument(
       '--dex-path',
       required=True,
       help='Path to dex file corresponding to the proguard mapping file.')
   parser.add_argument(
       '--proguard-mapping-path',
       required=True,
       help='Path to input proguard mapping file corresponding to the dex file.')
   parser.add_argument(
       '--output-profile-path',
       required=True,
       help='Path to output profile.')
   parser.add_argument(
       '--input-profile-path',
       required=True,
       help='Path to output profile.')
   parser.add_argument(
       '--verbose',
       action='store_true',
       default=False,
       help='Print verbose output.')
   obfuscation = parser.add_mutually_exclusive_group(required=True)
   obfuscation.add_argument('--obfuscate', action='store_true',
       help='Indicates to output an obfuscated profile given a deobfuscated '
      'one.')
   obfuscation.add_argument('--deobfuscate', dest='obfuscate',
       action='store_false', help='Indicates to output a deobfuscated profile '
       'given an obfuscated one.')
   options = parser.parse_args(args)

   if options.verbose:
     log_level = logging.WARNING
   else:
     log_level = logging.ERROR
   logging.basicConfig(format='%(levelname)s: %(message)s', level=log_level)

   dex = ProcessDex(_RunDexDump(options.dexdump_path, options.dex_path))
   proguard_mapping, reverse_proguard_mapping = ProcessProguardMapping(
       _ReadFile(options.proguard_mapping_path), dex)
   if options.obfuscate:
     profile = ProcessProfile(
         _ReadFile(options.input_profile_path),
         reverse_proguard_mapping)
   else:
     profile = ProcessProfile(
         _ReadFile(options.input_profile_path),
         proguard_mapping)
   profile.WriteToFile(options.output_profile_path)


 if __name__ == '__main__':
   main(sys.argv[1:])
	#!/usr/bin/env vpython
	#
	# Copyright 2018 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.

	import argparse
	import collections
	import logging
	import re
	import subprocess
	import sys

	DEX_CLASS_NAME_RE = re.compile(r'\'L(?P<class_name>[^;]+);\'')
	DEX_METHOD_NAME_RE = re.compile(r'\'(?P<method_name>[^\']+)\'')
	DEX_METHOD_TYPE_RE = re.compile( # type descriptor method signature re
	r'\''
	r'\('
	r'(?P<method_params>[^)]*)'
	r'\)'
	r'(?P<method_return_type>[^\']+)'
	r'\'')
	DEX_METHOD_LINE_NR_RE = re.compile(r'line=(?P<line_number>\d+)')

	PROFILE_METHOD_RE = re.compile(
	r'(?P<tags>[HSP]+)' # tags such as H/S/P
	r'(?P<class_name>L[^;]+;)' # class name in type descriptor format
	r'->(?P<method_name>[^(]+)'
	r'\((?P<method_params>[^)]*)\)'
	r'(?P<method_return_type>.+)')

	PROGUARD_CLASS_MAPPING_RE = re.compile(
	r'(?P<original_name>[^ ]+)'
	r' -> '
	r'(?P<obfuscated_name>[^:]+):')
	PROGUARD_METHOD_MAPPING_RE = re.compile(
	# line_start:line_end: (optional)
	r'((?P<line_start>\d+):(?P<line_end>\d+):)?'
	r'(?P<return_type>[^ ]+)' # original method return type
	# original method class name (if exists)
	r' (?:(?P<original_method_class>[a-zA-Z_\d.$]+)\.)?'
	r'(?P<original_method_name>[^.\(]+)'
	r'\((?P<params>[^\)]*)\)' # original method params
	r'(?:[^ ]*)' # original method line numbers (ignored)
	r' -> '
	r'(?P<obfuscated_name>.+)') # obfuscated method name

	TYPE_DESCRIPTOR_RE = re.compile(
	r'(?P<brackets>\[*)'
	r'(?:'
	r'(?P<class_name>L[^;]+;)'
	r'\|'
	r'[VZBSCIJFD]'
	r')')

	DOT_NOTATION_MAP = {
	'': '',
	'boolean': 'Z',
	'byte': 'B',
	'void': 'V',
	'short': 'S',
	'char': 'C',
	'int': 'I',
	'long': 'J',
	'float': 'F',
	'double': 'D'
	}

	class Method(object):
	def __init__(self, name, class_name, param_types=None, return_type=None):
	self.name = name
	self.class_name = class_name
	self.param_types = param_types
	self.return_type = return_type

	def __str__(self):
	return '{}->{}({}){}'.format(self.class_name, self.name,
	self.param_types or '', self.return_type or '')

	def __repr__(self):
	return 'Method<{}->{}({}){}>'.format(self.class_name, self.name,
	self.param_types or '', self.return_type or '')

	def __cmp__(self, other):
	return cmp((self.class_name, self.name, self.param_types, self.return_type),
	(other.class_name, other.name, other.param_types, other.return_type))

	def __hash__(self):
	# only hash name and class_name since other fields may not be set yet.
	return hash((self.name, self.class_name))


	class Class(object):
	def __init__(self, name):
	self.name = name
	self._methods = []

	def AddMethod(self, method, line_numbers):
	self._methods.append((method, set(line_numbers)))

	def FindMethodsAtLine(self, method_name, line_start, line_end=None):
	"""Searches through dex class for a method given a name and line numbers

	The dex maps methods to line numbers, this method, given the a method name
	in this class as well as a start line and an optional end line (which act as
	hints as to which function in the class is being looked for), returns a list
	of possible matches (or none if none are found).

	Args:
	method_name: name of method being searched for
	line_start: start of hint range for lines in this method
	line_end: end of hint range for lines in this method (optional)

	Returns:
	A list of Method objects that could match the hints given, or None if no
	method is found.
	"""
	found_methods = []
	if line_end is None:
	hint_lines = set([line_start])
	else:
	hint_lines = set(range(line_start, line_end+1))

	named_methods = [(method, l) for method, l in self._methods
	if method.name == method_name]

	if len(named_methods) == 1:
	return [method for method, l in named_methods]
	if len(named_methods) == 0:
	return None

	for method, line_numbers in named_methods:
	if not hint_lines.isdisjoint(line_numbers):
	found_methods.append(method)

	if len(found_methods) > 0:
	if len(found_methods) > 1:
	logging.warning('ambigous methods in dex %s at lines %s in class "%s"',
	found_methods, hint_lines, self.name)
	return found_methods

	for method, line_numbers in named_methods:
	if (max(hint_lines) >= min(line_numbers)
	and min(hint_lines) <= max(line_numbers)):
	found_methods.append(method)

	if len(found_methods) > 0:
	if len(found_methods) > 1:
	logging.warning('ambigous methods in dex %s at lines %s in class "%s"',
	found_methods, hint_lines, self.name)
	return found_methods
	else:
	logging.warning('No method named "%s" in class "%s" is '
	'mapped to lines %s', method_name, self.name, hint_lines)
	return None


	class Profile(object):
	def __init__(self):
	# {Method: set(char)}
	self._methods = collections.defaultdict(set)
	self._classes = []

	def AddMethod(self, method, tags):
	for tag in tags:
	self._methods[method].add(tag)

	def AddClass(self, cls):
	self._classes.append(cls)

	def WriteToFile(self, path):
	with open(path, 'w') as output_profile:
	for cls in sorted(self._classes):
	output_profile.write(cls + '\n')
	for method in sorted(self._methods):
	tags = sorted(self._methods[method])
	line = '{}{}\n'.format(''.join(tags), str(method))
	output_profile.write(line)


	class ProguardMapping(object):
	def __init__(self):
	# {Method: set(Method)}
	self._method_mapping = collections.defaultdict(set)
	# {String: String} String is class name in type descriptor format
	self._class_mapping = dict()

	def AddMethodMapping(self, from_method, to_method):
	self._method_mapping[from_method].add(to_method)

	def AddClassMapping(self, from_class, to_class):
	self._class_mapping[from_class] = to_class

	def GetMethodMapping(self, from_method):
	return self._method_mapping.get(from_method)

	def GetClassMapping(self, from_class):
	return self._class_mapping.get(from_class, from_class)

	def MapTypeDescriptor(self, type_descriptor):
	match = TYPE_DESCRIPTOR_RE.search(type_descriptor)
	assert match is not None
	class_name = match.group('class_name')
	if class_name is not None:
	return match.group('brackets') + self.GetClassMapping(class_name)
	# just a native type, return as is
	return match.group()

	def MapTypeDescriptorList(self, type_descriptor_list):
	return TYPE_DESCRIPTOR_RE.sub(
	lambda match: self.MapTypeDescriptor(match.group()),
	type_descriptor_list)


	class MalformedLineException(Exception):
	def __init__(self, message, line_number):
	super(MalformedLineException, self).__init__(message)
	self.line_number = line_number

	def __str__(self):
	return self.message + ' at line {}'.format(self.line_number)


	class MalformedProguardMappingException(MalformedLineException):
	pass


	class MalformedProfileException(MalformedLineException):
	pass


	def _RunDexDump(dexdump_path, dex_file_path):
	return subprocess.check_output([dexdump_path, dex_file_path]).splitlines()


	def _ReadFile(file_path):
	with open(file_path, 'r') as f:
	return f.readlines()


	def _ToTypeDescriptor(dot_notation):
	"""Parses a dot notation type and returns it in type descriptor format

	eg:
	org.chromium.browser.ChromeActivity -> Lorg/chromium/browser/ChromeActivity;
	boolean -> Z
	int[] -> [I

	Args:
	dot_notation: trimmed string with a single type in dot notation format

	Returns:
	A string with the type in type descriptor format
	"""
	dot_notation = dot_notation.strip()
	prefix = ''
	while dot_notation.endswith('[]'):
	prefix += '['
	dot_notation = dot_notation[:-2]
	if dot_notation in DOT_NOTATION_MAP:
	return prefix + DOT_NOTATION_MAP[dot_notation]
	return prefix + 'L' + dot_notation.replace('.', '/') + ';'


	def _DotNotationListToTypeDescriptorList(dot_notation_list_string):
	"""Parses a param list of dot notation format and returns it in type
	descriptor format

	eg:
	org.chromium.browser.ChromeActivity,boolean,int[] ->
	Lorg/chromium/browser/ChromeActivity;Z[I

	Args:
	dot_notation_list_string: single string with multiple comma separated types
	in dot notation format

	Returns:
	A string with the param list in type descriptor format
	"""
	return ''.join(_ToTypeDescriptor(param) for param in
	dot_notation_list_string.split(','))


	def ProcessDex(dex_dump):
	"""Parses dexdump output returning a dict of class names to Class objects

	Parses output of the dexdump command on a dex file and extracts information
	about classes and their respective methods and which line numbers a method is
	mapped to.

	Methods that are not mapped to any line number are ignored and not listed
	inside their respective Class objects.

	Args:
	dex_dump: An array of lines of dexdump output

	Returns:
	A dict that maps from class names in type descriptor format (but without the
	surrounding 'L' and ';') to Class objects.
	"""
	# class_name: Class
	classes_by_name = {}
	current_class = None
	current_method = None
	reading_positions = False
	reading_methods = False
	method_line_numbers = []
	for line in dex_dump:
	line = line.strip()
	if line.startswith('Class descriptor'):
	# New class started, no longer reading methods.
	reading_methods = False
	current_class = Class(DEX_CLASS_NAME_RE.search(line).group('class_name'))
	classes_by_name[current_class.name] = current_class
	elif (line.startswith('Direct methods')
	or line.startswith('Virtual methods')):
	reading_methods = True
	elif reading_methods and line.startswith('name'):
	assert current_class is not None
	current_method = Method(
	DEX_METHOD_NAME_RE.search(line).group('method_name'),
	"L" + current_class.name + ";")
	elif reading_methods and line.startswith('type'):
	assert current_method is not None
	match = DEX_METHOD_TYPE_RE.search(line)
	current_method.param_types = match.group('method_params')
	current_method.return_type = match.group('method_return_type')
	elif line.startswith('positions'):
	assert reading_methods
	reading_positions = True
	method_line_numbers = []
	elif reading_positions and line.startswith('0x'):
	line_number = DEX_METHOD_LINE_NR_RE.search(line).group('line_number')
	method_line_numbers.append(int(line_number))
	elif reading_positions and line.startswith('locals'):
	if len(method_line_numbers) > 0:
	current_class.AddMethod(current_method, method_line_numbers)
	# finished reading method line numbers
	reading_positions = False
	return classes_by_name


	def ProcessProguardMapping(proguard_mapping_lines, dex):
	"""Parses a proguard mapping file

	This takes proguard mapping file lines and then uses the obfuscated dex to
	create a mapping of unobfuscated methods to obfuscated ones and vice versa.

	The dex is used because the proguard mapping file only has the name of the
	obfuscated methods but not their signature, thus the dex is read to look up
	which method with a specific name was mapped to the lines mentioned in the
	proguard mapping file.

	Args:
	proguard_mapping_lines: Array of strings, each is a line from the proguard
	mapping file (in order).
	dex: a dict of class name (in type descriptor format but without the
	enclosing 'L' and ';') to a Class object.
	Returns:
	Two dicts the first maps from obfuscated methods to a set of non-obfuscated
	ones. It also maps the obfuscated class names to original class names, both
	in type descriptor format (with the enclosing 'L' and ';')
	"""
	mapping = ProguardMapping()
	reverse_mapping = ProguardMapping()
	to_be_obfuscated = []
	current_class_orig = None
	current_class_obfs = None
	for index, line in enumerate(proguard_mapping_lines):
	if line.strip() == '':
	continue
	if not line.startswith(' '):
	match = PROGUARD_CLASS_MAPPING_RE.search(line)
	if match is None:
	raise MalformedProguardMappingException(
	'Malformed class mapping', index)
	current_class_orig = match.group('original_name')
	current_class_obfs = match.group('obfuscated_name')
	mapping.AddClassMapping(_ToTypeDescriptor(current_class_obfs),
	_ToTypeDescriptor(current_class_orig))
	reverse_mapping.AddClassMapping(_ToTypeDescriptor(current_class_orig),
	_ToTypeDescriptor(current_class_obfs))
	continue

	assert current_class_orig is not None
	assert current_class_obfs is not None
	line = line.strip()
	match = PROGUARD_METHOD_MAPPING_RE.search(line)
	# check if is a method mapping (we ignore field mappings)
	if match is not None:
	# check if this line is an inlining by reading ahead 1 line.
	if index + 1 < len(proguard_mapping_lines):
	next_match = PROGUARD_METHOD_MAPPING_RE.search(
	proguard_mapping_lines[index+1].strip())
	if (next_match and match.group('line_start') is not None
	and next_match.group('line_start') == match.group('line_start')
	and next_match.group('line_end') == match.group('line_end')):
	continue # This is an inlining, skip

	original_method = Method(
	match.group('original_method_name'),
	_ToTypeDescriptor(
	match.group('original_method_class') or current_class_orig),
	_DotNotationListToTypeDescriptorList(match.group('params')),
	_ToTypeDescriptor(match.group('return_type')))

	if match.group('line_start') is not None:
	obfs_methods = (dex[current_class_obfs.replace('.', '/')]
	.FindMethodsAtLine(
	match.group('obfuscated_name'),
	int(match.group('line_start')),
	int(match.group('line_end'))))

	if obfs_methods is None:
	continue

	for obfs_method in obfs_methods:
	mapping.AddMethodMapping(obfs_method, original_method)
	reverse_mapping.AddMethodMapping(original_method, obfs_method)
	else:
	to_be_obfuscated.append(
	(original_method, match.group('obfuscated_name')))

	for original_method, obfuscated_name in to_be_obfuscated:
	obfuscated_method = Method(
	obfuscated_name,
	reverse_mapping.GetClassMapping(original_method.class_name),
	reverse_mapping.MapTypeDescriptorList(original_method.param_types),
	reverse_mapping.MapTypeDescriptor(original_method.return_type))
	mapping.AddMethodMapping(obfuscated_method, original_method)
	reverse_mapping.AddMethodMapping(original_method, obfuscated_method)
	return mapping, reverse_mapping


	def ProcessProfile(input_profile, proguard_mapping):
	"""Parses an android profile and uses the proguard mapping to (de)obfuscate it

	This takes the android profile lines and for each method or class for the
	profile, it uses the mapping to either obfuscate or deobfuscate (based on the
	provided mapping) and returns a Profile object that stores this information.

	Args:
	input_profile: array of lines of the input profile
	proguard_mapping: a proguard mapping that would map from the classes and
	methods in the input profile to the classes and methods
	that should be in the output profile.

	Returns:
	A Profile object that stores the information (ie list of mapped classes and
	methods + tags)
	"""
	profile = Profile()
	for index, line in enumerate(input_profile):
	line = line.strip()
	if line.startswith('L'):
	profile.AddClass(proguard_mapping.GetClassMapping(line))
	continue
	match = PROFILE_METHOD_RE.search(line)
	if not match:
	raise MalformedProfileException("Malformed line", index)

	method = Method(
	match.group('method_name'),
	match.group('class_name'),
	match.group('method_params'),
	match.group('method_return_type'))

	mapped_methods = proguard_mapping.GetMethodMapping(method)
	if mapped_methods is None:
	logging.warning('No method matching "%s" has been found in the proguard '
	'mapping file', method)
	continue

	for original_method in mapped_methods:
	profile.AddMethod(original_method, match.group('tags'))

	return profile


	def ObfuscateProfile(nonobfuscated_profile, dex_file, proguard_mapping,
	dexdump_path, output_filename):
	"""Helper method for obfuscating a profile.

	Args:
	nonobfuscated_profile: a profile with nonobfuscated symbols.
	dex_file: path to the dex file matching the mapping.
	proguard_mapping: a mapping from nonobfuscated to obfuscated symbols used
	in the dex file.
	dexdump_path: path to the dexdump utility.
	output_filename: output filename in which to write the obfuscated profile.
	"""
	dexinfo = ProcessDex(_RunDexDump(dexdump_path, dex_file))
	_, reverse_mapping = ProcessProguardMapping(
	_ReadFile(proguard_mapping), dexinfo)
	obfuscated_profile = ProcessProfile(
	_ReadFile(nonobfuscated_profile), reverse_mapping)
	obfuscated_profile.WriteToFile(output_filename)


	def main(args):
	parser = argparse.ArgumentParser()
	parser.add_argument(
	'--dexdump-path',
	required=True,
	help='Path to dexdump binary.')
	parser.add_argument(
	'--dex-path',
	required=True,
	help='Path to dex file corresponding to the proguard mapping file.')
	parser.add_argument(
	'--proguard-mapping-path',
	required=True,
	help='Path to input proguard mapping file corresponding to the dex file.')
	parser.add_argument(
	'--output-profile-path',
	required=True,
	help='Path to output profile.')
	parser.add_argument(
	'--input-profile-path',
	required=True,
	help='Path to output profile.')
	parser.add_argument(
	'--verbose',
	action='store_true',
	default=False,
	help='Print verbose output.')
	obfuscation = parser.add_mutually_exclusive_group(required=True)
	obfuscation.add_argument('--obfuscate', action='store_true',
	help='Indicates to output an obfuscated profile given a deobfuscated '
	'one.')
	obfuscation.add_argument('--deobfuscate', dest='obfuscate',
	action='store_false', help='Indicates to output a deobfuscated profile '
	'given an obfuscated one.')
	options = parser.parse_args(args)

	if options.verbose:
	log_level = logging.WARNING
	else:
	log_level = logging.ERROR
	logging.basicConfig(format='%(levelname)s: %(message)s', level=log_level)

	dex = ProcessDex(_RunDexDump(options.dexdump_path, options.dex_path))
	proguard_mapping, reverse_proguard_mapping = ProcessProguardMapping(
	_ReadFile(options.proguard_mapping_path), dex)
	if options.obfuscate:
	profile = ProcessProfile(
	_ReadFile(options.input_profile_path),
	reverse_proguard_mapping)
	else:
	profile = ProcessProfile(
	_ReadFile(options.input_profile_path),
	proguard_mapping)
	profile.WriteToFile(options.output_profile_path)


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