tools/cygprofile/patch_orderfile.py - chromium/src - Git at Google

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

 """Patch an orderfile.

 Starting with a list of symbols in a binary and an orderfile (ordered list of
 symbols), matches the symbols in the orderfile and augments each symbol with
 the symbols residing at the same address (due to having identical code).  The
 output is a list of symbols appropriate for the linker
 option --symbol-ordering-file for lld. Note this is not usable with gold (which
 uses section names to order the binary).

 Note: It is possible to have.
 - Several symbols mapping to the same offset in the binary.
 - Several offsets for a given symbol (because we strip the ".clone." and other
   suffixes)

 The general pipeline is:
 1. Get the symbol infos (name, offset, size, section) from the binary
 2. Get the symbol names from the orderfile
 3. Find the orderfile symbol names in the symbols coming from the binary
 4. For each symbol found, get all the symbols at the same address
 5. Output them to an updated orderfile suitable lld
 """

 import argparse
 import collections
 import logging
 import re
 import sys

 import cyglog_to_orderfile
 import cygprofile_utils
 import symbol_extractor

 # Suffixes for symbols.  These are due to method splitting for inlining and
 # method cloning for various reasons including constant propagation and
 # inter-procedural optimization.
 _SUFFIXES = ('.clone.', '.part.', '.isra.', '.constprop.')


 # The pattern and format for a linker-generated outlined function.
 _OUTLINED_FUNCTION_RE = re.compile(r'OUTLINED_FUNCTION_(?P<index>\d+)$')
 _OUTLINED_FUNCTION_FORMAT = 'OUTLINED_FUNCTION_{}'

 def RemoveSuffixes(name):
   """Strips method name suffixes from cloning and splitting.

   .clone. comes from cloning in -O3.
   .part.  comes from partial method splitting for inlining.
   .isra.  comes from inter-procedural optimizations.
   .constprop. is cloning for constant propagation.
   """
   for suffix in _SUFFIXES:
     name = name.split(suffix)[0]
   return name


 def _UniqueGenerator(generator):
   """Converts a generator to skip yielding elements already seen.

   Example:
     @_UniqueGenerator
     def Foo():
       yield 1
       yield 2
       yield 1
       yield 3

     Foo() yields 1,2,3.
   """
   def _FilteringFunction(*args, **kwargs):
     returned = set()
     for item in generator(*args, **kwargs):
       if item in returned:
         continue
       returned.add(item)
       yield item

   return _FilteringFunction


 def _GroupSymbolsByOffset(binary_filename):
   """Produce a map symbol name -> all symbol names at same offset.

   Suffixes are stripped.
   """
   symbol_infos = [
       s._replace(name=RemoveSuffixes(s.name))
       for s in symbol_extractor.SymbolInfosFromBinary(binary_filename)]
   offset_map = symbol_extractor.GroupSymbolInfosByOffset(symbol_infos)
   missing_offsets = 0
   sym_to_matching = {}
   for sym in symbol_infos:
     if sym.offset not in offset_map:
       missing_offsets += 1
       continue
     matching = [s.name for s in offset_map[sym.offset]]
     assert sym.name in matching
     sym_to_matching[sym.name] = matching
   return sym_to_matching


 def _GetMaxOutlinedIndex(sym_dict):
   """Find the largest index of an outlined functions.

   See _OUTLINED_FUNCTION_RE for the definition of the index. In practice the
   maximum index equals the total number of outlined functions. This function
   asserts that the index is near the total number of outlined functions.

   Args:
     sym_dict: Dict with symbol names as keys.

   Returns:
     The largest index of an outlined function seen in the keys of |sym_dict|.
   """
   seen = set()
   for sym in sym_dict:
     m = _OUTLINED_FUNCTION_RE.match(sym)
     if m:
       seen.add(int(m.group('index')))
   if not seen:
     return None
   max_index = max(seen)
   # Assert that the number of outlined functions is reasonable compared to the
   # indices we've seen. At the time of writing, outlined functions are indexed
   # consecutively from 0. If this radically changes, then other outlining
   # behavior may have changed to violate some assumptions.
   assert max_index < 2 * len(seen)
   return max_index


 def _StripSuffixes(section_list):
   """Remove all suffixes on items in a list of symbols."""
   return [RemoveSuffixes(section) for section in section_list]


 def _PatchedSymbols(symbol_to_matching, profiled_symbols, max_outlined_index):
   """Internal computation of an orderfile.

   Args:
     symbol_to_matching: ({symbol name -> [symbols at same offset]}), as from
       _GroupSymbolsByOffset.
     profiled_symbols: ([symbol names]) as from the unpatched orderfile.
     max_outlined_index: (int or None) if not None, add outlined function names
       to the end of the patched orderfile.

   Yields:
     Patched symbols, in a consistent order to profiled_symbols.
   """
   missing_symbol_count = 0
   seen_symbols = set()
   for sym in profiled_symbols:
     if _OUTLINED_FUNCTION_RE.match(sym):
       continue
     if sym in seen_symbols:
       continue
     if sym not in symbol_to_matching:
       missing_symbol_count += 1
       continue
     for matching in symbol_to_matching[sym]:
       if matching in seen_symbols:
         continue
       if _OUTLINED_FUNCTION_RE.match(matching):
         continue
       yield matching
       seen_symbols.add(matching)
     assert sym in seen_symbols
   logging.warning('missing symbol count = %d', missing_symbol_count)

   if max_outlined_index is not None:
     # The number of outlined functions may change with each build, so only
     # ordering the outlined functions currently in the binary will not
     # guarantee ordering after code changes before the next orderfile is
     # generated. So we double the number of outlined functions as a measure of
     # security.
     for idx in xrange(2 * max_outlined_index + 1):
       yield _OUTLINED_FUNCTION_FORMAT.format(idx)


 @_UniqueGenerator
 def ReadOrderfile(orderfile):
   """Reads an orderfile and cleans up symbols.

   Args:
     orderfile: The name of the orderfile.

   Yields:
     Symbol names, cleaned and unique.
   """
   with open(orderfile) as f:
     for line in f.xreadlines():
       line = line.strip()
       if line:
         yield line


 def GeneratePatchedOrderfile(unpatched_orderfile, native_lib_filename,
                              output_filename, order_outlined=False):
   """Writes a patched orderfile.

   Args:
     unpatched_orderfile: (str) Path to the unpatched orderfile.
     native_lib_filename: (str) Path to the native library.
     output_filename: (str) Path to the patched orderfile.
     order_outlined: (bool) If outlined function symbols are present in the
       native library, then add ordering of them to the orderfile. If there
       are no outlined function symbols present then this flag has no effect.
   """
   symbol_to_matching = _GroupSymbolsByOffset(native_lib_filename)
   if order_outlined:
     max_outlined_index = _GetMaxOutlinedIndex(symbol_to_matching)
     if not max_outlined_index:
       # Only generate ordered outlined functions if they already appeared in
       # the library.
       max_outlined_index = None
   else:
     max_outlined_index = None  # Ignore outlining.
   profiled_symbols = ReadOrderfile(unpatched_orderfile)

   with open(output_filename, 'w') as f:
     # Make sure the anchor functions are located in the right place, here and
     # after everything else.
     # See the comment in //base/android/library_loader/anchor_functions.cc.
     #
     # __cxx_global_var_init is one of the largest symbols (~38kB as of May
     # 2018), called extremely early, and not instrumented.
     for first_section in ('dummy_function_start_of_ordered_text',
                           '__cxx_global_var_init'):
       f.write(first_section + '\n')

     for sym in _PatchedSymbols(symbol_to_matching, profiled_symbols,
                                max_outlined_index):
       f.write(sym + '\n')

     f.write('dummy_function_end_of_ordered_text\n')


 def _CreateArgumentParser():
   """Creates and returns the argument parser."""
   parser = argparse.ArgumentParser()
   parser.add_argument('--target-arch', action='store', default='arm',
                       choices=['arm', 'arm64', 'x86', 'x86_64', 'x64', 'mips'],
                       help='The target architecture for the library.')
   parser.add_argument('--unpatched-orderfile', required=True,
                       help='Path to the unpatched orderfile')
   parser.add_argument('--native-library', required=True,
                       help='Path to the native library')
   parser.add_argument('--output-file', required=True, help='Output filename')
   return parser


 def main():
   parser = _CreateArgumentParser()
   options = parser.parse_args()
   symbol_extractor.SetArchitecture(options.target_arch)
   GeneratePatchedOrderfile(options.unpatched_orderfile, options.native_library,
                            options.output_file)
   return 0


 if __name__ == '__main__':
   logging.basicConfig(level=logging.INFO)
   sys.exit(main())
	#!/usr/bin/env vpython
	# Copyright 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.

	"""Patch an orderfile.

	Starting with a list of symbols in a binary and an orderfile (ordered list of
	symbols), matches the symbols in the orderfile and augments each symbol with
	the symbols residing at the same address (due to having identical code). The
	output is a list of symbols appropriate for the linker
	option --symbol-ordering-file for lld. Note this is not usable with gold (which
	uses section names to order the binary).

	Note: It is possible to have.
	- Several symbols mapping to the same offset in the binary.
	- Several offsets for a given symbol (because we strip the ".clone." and other
	suffixes)

	The general pipeline is:
	1. Get the symbol infos (name, offset, size, section) from the binary
	2. Get the symbol names from the orderfile
	3. Find the orderfile symbol names in the symbols coming from the binary
	4. For each symbol found, get all the symbols at the same address
	5. Output them to an updated orderfile suitable lld
	"""

	import argparse
	import collections
	import logging
	import re
	import sys

	import cyglog_to_orderfile
	import cygprofile_utils
	import symbol_extractor

	# Suffixes for symbols. These are due to method splitting for inlining and
	# method cloning for various reasons including constant propagation and
	# inter-procedural optimization.
	_SUFFIXES = ('.clone.', '.part.', '.isra.', '.constprop.')


	# The pattern and format for a linker-generated outlined function.
	_OUTLINED_FUNCTION_RE = re.compile(r'OUTLINED_FUNCTION_(?P<index>\d+)$')
	_OUTLINED_FUNCTION_FORMAT = 'OUTLINED_FUNCTION_{}'

	def RemoveSuffixes(name):
	"""Strips method name suffixes from cloning and splitting.

	.clone. comes from cloning in -O3.
	.part. comes from partial method splitting for inlining.
	.isra. comes from inter-procedural optimizations.
	.constprop. is cloning for constant propagation.
	"""
	for suffix in _SUFFIXES:
	name = name.split(suffix)[0]
	return name


	def _UniqueGenerator(generator):
	"""Converts a generator to skip yielding elements already seen.

	Example:
	@_UniqueGenerator
	def Foo():
	yield 1
	yield 2
	yield 1
	yield 3

	Foo() yields 1,2,3.
	"""
	def _FilteringFunction(args, *kwargs):
	returned = set()
	for item in generator(args, *kwargs):
	if item in returned:
	continue
	returned.add(item)
	yield item

	return _FilteringFunction


	def _GroupSymbolsByOffset(binary_filename):
	"""Produce a map symbol name -> all symbol names at same offset.

	Suffixes are stripped.
	"""
	symbol_infos = [
	s._replace(name=RemoveSuffixes(s.name))
	for s in symbol_extractor.SymbolInfosFromBinary(binary_filename)]
	offset_map = symbol_extractor.GroupSymbolInfosByOffset(symbol_infos)
	missing_offsets = 0
	sym_to_matching = {}
	for sym in symbol_infos:
	if sym.offset not in offset_map:
	missing_offsets += 1
	continue
	matching = [s.name for s in offset_map[sym.offset]]
	assert sym.name in matching
	sym_to_matching[sym.name] = matching
	return sym_to_matching


	def _GetMaxOutlinedIndex(sym_dict):
	"""Find the largest index of an outlined functions.

	See _OUTLINED_FUNCTION_RE for the definition of the index. In practice the
	maximum index equals the total number of outlined functions. This function
	asserts that the index is near the total number of outlined functions.

	Args:
	sym_dict: Dict with symbol names as keys.

	Returns:
	The largest index of an outlined function seen in the keys of \|sym_dict\|.
	"""
	seen = set()
	for sym in sym_dict:
	m = _OUTLINED_FUNCTION_RE.match(sym)
	if m:
	seen.add(int(m.group('index')))
	if not seen:
	return None
	max_index = max(seen)
	# Assert that the number of outlined functions is reasonable compared to the
	# indices we've seen. At the time of writing, outlined functions are indexed
	# consecutively from 0. If this radically changes, then other outlining
	# behavior may have changed to violate some assumptions.
	assert max_index < 2 * len(seen)
	return max_index


	def _StripSuffixes(section_list):
	"""Remove all suffixes on items in a list of symbols."""
	return [RemoveSuffixes(section) for section in section_list]


	def _PatchedSymbols(symbol_to_matching, profiled_symbols, max_outlined_index):
	"""Internal computation of an orderfile.

	Args:
	symbol_to_matching: ({symbol name -> [symbols at same offset]}), as from
	_GroupSymbolsByOffset.
	profiled_symbols: ([symbol names]) as from the unpatched orderfile.
	max_outlined_index: (int or None) if not None, add outlined function names
	to the end of the patched orderfile.

	Yields:
	Patched symbols, in a consistent order to profiled_symbols.
	"""
	missing_symbol_count = 0
	seen_symbols = set()
	for sym in profiled_symbols:
	if _OUTLINED_FUNCTION_RE.match(sym):
	continue
	if sym in seen_symbols:
	continue
	if sym not in symbol_to_matching:
	missing_symbol_count += 1
	continue
	for matching in symbol_to_matching[sym]:
	if matching in seen_symbols:
	continue
	if _OUTLINED_FUNCTION_RE.match(matching):
	continue
	yield matching
	seen_symbols.add(matching)
	assert sym in seen_symbols
	logging.warning('missing symbol count = %d', missing_symbol_count)

	if max_outlined_index is not None:
	# The number of outlined functions may change with each build, so only
	# ordering the outlined functions currently in the binary will not
	# guarantee ordering after code changes before the next orderfile is
	# generated. So we double the number of outlined functions as a measure of
	# security.
	for idx in xrange(2 * max_outlined_index + 1):
	yield _OUTLINED_FUNCTION_FORMAT.format(idx)


	@_UniqueGenerator
	def ReadOrderfile(orderfile):
	"""Reads an orderfile and cleans up symbols.

	Args:
	orderfile: The name of the orderfile.

	Yields:
	Symbol names, cleaned and unique.
	"""
	with open(orderfile) as f:
	for line in f.xreadlines():
	line = line.strip()
	if line:
	yield line


	def GeneratePatchedOrderfile(unpatched_orderfile, native_lib_filename,
	output_filename, order_outlined=False):
	"""Writes a patched orderfile.

	Args:
	unpatched_orderfile: (str) Path to the unpatched orderfile.
	native_lib_filename: (str) Path to the native library.
	output_filename: (str) Path to the patched orderfile.
	order_outlined: (bool) If outlined function symbols are present in the
	native library, then add ordering of them to the orderfile. If there
	are no outlined function symbols present then this flag has no effect.
	"""
	symbol_to_matching = _GroupSymbolsByOffset(native_lib_filename)
	if order_outlined:
	max_outlined_index = _GetMaxOutlinedIndex(symbol_to_matching)
	if not max_outlined_index:
	# Only generate ordered outlined functions if they already appeared in
	# the library.
	max_outlined_index = None
	else:
	max_outlined_index = None # Ignore outlining.
	profiled_symbols = ReadOrderfile(unpatched_orderfile)

	with open(output_filename, 'w') as f:
	# Make sure the anchor functions are located in the right place, here and
	# after everything else.
	# See the comment in //base/android/library_loader/anchor_functions.cc.
	#
	# __cxx_global_var_init is one of the largest symbols (~38kB as of May
	# 2018), called extremely early, and not instrumented.
	for first_section in ('dummy_function_start_of_ordered_text',
	'__cxx_global_var_init'):
	f.write(first_section + '\n')

	for sym in _PatchedSymbols(symbol_to_matching, profiled_symbols,
	max_outlined_index):
	f.write(sym + '\n')

	f.write('dummy_function_end_of_ordered_text\n')


	def _CreateArgumentParser():
	"""Creates and returns the argument parser."""
	parser = argparse.ArgumentParser()
	parser.add_argument('--target-arch', action='store', default='arm',
	choices=['arm', 'arm64', 'x86', 'x86_64', 'x64', 'mips'],
	help='The target architecture for the library.')
	parser.add_argument('--unpatched-orderfile', required=True,
	help='Path to the unpatched orderfile')
	parser.add_argument('--native-library', required=True,
	help='Path to the native library')
	parser.add_argument('--output-file', required=True, help='Output filename')
	return parser


	def main():
	parser = _CreateArgumentParser()
	options = parser.parse_args()
	symbol_extractor.SetArchitecture(options.target_arch)
	GeneratePatchedOrderfile(options.unpatched_orderfile, options.native_library,
	options.output_file)
	return 0


	if __name__ == '__main__':
	logging.basicConfig(level=logging.INFO)
	sys.exit(main())