scripts/fmp/ELF.py - LeafOS-Devices/android_kernel_samsung_gta4xl - Gitiles

 #!/usr/bin/env python3
 # -*- coding: utf-8 -*-

 """
 Module ELF contains ELF, Symbol, Section classes for manipulation over ELF files.
 It can parse, and change ELF file. This version works only with vmlinux and doesn't properly work with ELF that contains
 UND symbols
 """

 import subprocess
 import re
 import os
 import struct
 from Utils import Utils
 from collections import OrderedDict
 from binascii import unhexlify

 __author__ = "Vadym Stupakov"
 __copyright__ = "Copyright (c) 2017 Samsung Electronics"
 __credits__ = ["Vadym Stupakov"]
 __version__ = "1.0"
 __maintainer__ = "Vadym Stupakov"
 __email__ = "v.stupakov@samsung.com"
 __status__ = "Production"


 class Symbol:
     def __init__(self, name=str(), sym_type=str(), bind=str(), visibility=str(), addr=int(), size=int(), ndx=str()):
         self.utils = Utils()
         self.name = str(name)
         self.type = str(sym_type)
         self.bind = str(bind)
         self.ndx = str(ndx)
         self.visibility = str(visibility)
         self.addr = self.utils.to_int(addr)
         self.size = self.utils.to_int(size)

     def __str__(self):
         return "name: '{}', type: '{}', bind: '{}', ndx: '{}', visibility: '{}', address: '{}', size: '{}'".format(
             self.name, self.type, self.bind, self.ndx, self.visibility, hex(self.addr), hex(self.size)
         )

     def __lt__(self, other):
         return self.addr <= other.addr


 class Section:
     def __init__(self, name=str(), sec_type=str(), addr=int(), offset=int(), size=int()):
         self.utils = Utils()
         self.name = str(name)
         self.type = str(sec_type)
         self.addr = self.utils.to_int(addr)
         self.offset = self.utils.to_int(offset)
         self.size = self.utils.to_int(size)

     def __str__(self):
         return "name: '{}', type: '{}', address: '{}', offset: '{}', size: '{}'".format(
             self.name, self.type, hex(self.addr), hex(self.offset), hex(self.size)
         )

     def __lt__(self, other):
         return self.addr <= other.addr


 class ELF:
     """
     Utils for manipulating over ELF
     """
     def __init__(self, elf_file, readelf_path=os.environ.get('CROSS_COMPILE')+"readelf"):
         self.__elf_file = elf_file
         self.utils = Utils()
         self.__readelf_path = readelf_path
         self.__sections = OrderedDict()
         self.__symbols = OrderedDict()
         self.__relocs = list()
         self.__re_hexdecimal = "\s*[0-9A-Fa-f]+\s*"
         self.__re_sec_name = "\s*[._a-zA-Z]+\s*"
         self.__re_type = "\s*[A-Z]+\s*"

     def __readelf_raw(self, options):
         """
         Execute readelf with options and print raw output
         :param options readelf options: ["opt1", "opt2", "opt3", ..., "optN"]
         :returns raw output
         """
         ret = subprocess.Popen(args=[self.__readelf_path] + options,
                                stdout=subprocess.PIPE,
                                stderr=subprocess.PIPE)
         stdout, stderr = ret.communicate()
         if "readelf: Error: the PHDR segment is not covered by a LOAD segment" in stderr.decode("utf-8").strip():
             ret.returncode = 0
         if ret.returncode != 0:
             raise ChildProcessError(stderr.decode("utf-8") + stdout.decode("utf-8"))
         return stdout.decode("utf-8")

     def set_elf_file(self, elf_file):
         if os.path.abspath(self.__elf_file) != os.path.abspath(elf_file):
             self.__elf_file = os.path.abspath(elf_file)
             self.__sections.clear()
             self.__symbols.clear()
             self.__relocs.clear()

     def get_elf_file(self):
         return os.path.abspath(self.__elf_file)

     def get_sections(self):
         """"
         Execute -> parse -> transform to dict() readelf output
         :returns dict: {sec_addr : Section()}
         """
         if len(self.__sections) == 0:
             sec_header = self.__readelf_raw(["-SW",  self.__elf_file]).strip()
             secs = re.compile("^.*\[.*\](" + self.__re_sec_name + self.__re_type + self.__re_hexdecimal +
                               self.__re_hexdecimal + self.__re_hexdecimal + ")", re.MULTILINE)
             found = secs.findall(sec_header)
             for line in found:
                 line = line.split()
                 if len(line) == 5:
                     self.__sections[int(line[2], 16)] = Section(name=line[0], sec_type=line[1], addr=int(line[2], 16),
                                                                 offset=int(line[3], 16), size=int(line[4], 16))
             self.__sections = OrderedDict(sorted(self.__sections.items()))
         return self.__sections

     def get_symbols(self):
         """"
         Execute -> parse -> transform to dict() readelf output
         :returns dict: {sym_addr : Symbol()}
         """
         if len(self.__symbols) == 0:
             sym_tab = self.__readelf_raw(["-sW",  self.__elf_file])
             syms = re.compile(r"^.*\d+:\s(.*$)", re.MULTILINE)
             found = syms.findall(sym_tab.strip())
             for line in found:
                 line = line.split()
                 if len(line) == 7:
                     size = line[1]
                     # This needs, because readelf prints sizes in hex if size is large
                     if size[:2].upper() == "0X":
                         size = int(size, 16)
                     else:
                         size = int(size, 10)
                     """
                     Do not include additional compiler information with name $d and $x
                     $d and $x is mapping symbols, their virtual addresses may coincide with virtual addresses
                     of the real objects
                     """
                     if line[6] not in ("$d", "$x") and (size != 0):
                         self.__symbols[int(line[0], 16)] = Symbol(addr=int(line[0], 16), size=size, sym_type=line[2],
                                                                   bind=line[3], visibility=line[4], ndx=line[5],
                                                                   name=line[6])
             self.__symbols = OrderedDict(sorted(self.__symbols.items()))
         return self.__symbols

     def get_relocs(self, start_addr=None, end_addr=None):
         """"
         :param start_addr: start address :int
         :param end_addr: end address: int
         :returns list: [reloc1, reloc2, reloc3, ..., relocN]
         """
         if len(self.__relocs) == 0:
             relocs = self.__readelf_raw(["-rW",  self.__elf_file])
             rel = re.compile(r"^(" + self.__re_hexdecimal + ")\s*", re.MULTILINE)
             self.__relocs = [self.utils.to_int(el) for el in rel.findall(relocs.strip())]

         if start_addr and end_addr is not None:
             ranged_rela = list()
             for el in self.__relocs:
                 if self.utils.to_int(start_addr) <= self.utils.to_int(el) <= self.utils.to_int(end_addr):
                     ranged_rela.append(el)
             return ranged_rela
         return self.__relocs

     def get_altinstructions(self, start_addr=None, end_addr=None):
         """
         :param start_addr: start address :int
         :param end_addr: end address: int
         :returns list: [[alt_inst1_addr, length1], [alt_inst2_addr, length2], ...]

         .altinstructions section contains an array of struct alt_instr.
         As instance, for kernel 4.14 from /arch/arm64/include/asm/alternative.h
         struct alt_instr {
             s32 orig_offset;    /* offset to original instruction */
             s32 alt_offset;     /* offset to replacement instruction */
             u16 cpufeature;     /* cpufeature bit set for replacement */
             u8  orig_len;       /* size of original instruction(s) */
             u8  alt_len;        /* size of new instruction(s), <= orig_len */
         };

         Later, address of original instruction can be calculated as
         at runtime     : &(alt_instr->orig_offset) + alt_instr->orig_offset + kernel offset
         ELF processing : address of .altinstruction section + in section offset of alt_instr structure + value of alt_instr.orig_offset
         details in /arch/arm64/kernel/alternative.c, void __apply_alternatives(void *, bool)
         """

         # The struct_format should reflect <struct alt_instr> content
         struct_format = '<iiHBB'
         pattern_altinst_section_content = "^ *0x[0-9A-Fa-f]{16} (.*) .*.{16}$"
         pattern_altinstr_section_addr = "^ *(0x[0-9A-Fa-f]{16}).*.*.{16}$"

         ranged_altinst = list()

         __hex_dump = self.__readelf_raw(["--hex-dump=.altinstructions", self.__elf_file])
         if len(__hex_dump) == 0:
             return ranged_altinst

         # .altinstruction section start addr in ELF
         __altinstr_section_addr = int(re.findall(pattern_altinstr_section_addr, __hex_dump, re.MULTILINE)[0], 16)

         # To provide .altinstruction section content using host readelf only
         # some magic with string parcing is needed
         hex_dump_list = re.findall(pattern_altinst_section_content, __hex_dump, re.MULTILINE)
         __hex_dump_str = ''.join(hex_dump_list).replace(" ", "")
         __altinstr_section_bin = unhexlify(__hex_dump_str)

         __struct_size = struct.calcsize(struct_format)

         if (len(__altinstr_section_bin) % __struct_size) != 0:
             return ranged_altinst

         if start_addr and end_addr is not None:
             __i = 0
             while __i < (len(__altinstr_section_bin) - __struct_size):
                 __struct_byte = __altinstr_section_bin[__i: __i + __struct_size]
                 __struct_value = list(struct.unpack(struct_format, __struct_byte))

                 # original instruction addr (going to be replaced) considered as "gap"
                 __original_instruction_addr = __struct_value[0] + __altinstr_section_addr + __i

                 # derive the target ARM instruction(s) length.
                 __target_instruction_len = __struct_value[4]

                 if self.utils.to_int(start_addr) <= __original_instruction_addr <= self.utils.to_int(end_addr):
                     ranged_altinst.append([__original_instruction_addr, __target_instruction_len])
                 __i = __i + __struct_size

         return ranged_altinst

     def get_symbol_by_name(self, sym_names):
         """
         Get symbol by_name
         :param sym_names: "sym_name" : str or list
         :return: Symbol() or [Symbol()]
         """
         if isinstance(sym_names, str):
             for addr, symbol_obj in self.get_symbols().items():
                 if symbol_obj.name == sym_names:
                     return symbol_obj
         elif isinstance(sym_names, list):
             symbols = [self.get_symbol_by_name(sym_name) for sym_name in sym_names]
             return symbols
         else:
             raise ValueError
         return None

     def get_symbol_by_vaddr(self, vaddrs=None):
         """
         Get symbol by virtual address
         :param vaddrs: vaddr : int or list
         :return: Symbol() or [Symbol()]
         """
         if isinstance(vaddrs, int):
             if vaddrs in self.get_symbols():
                 return self.get_symbols()[vaddrs]
             for addr, symbol_obj in self.get_symbols().items():
                 if (addr + symbol_obj.size) >= vaddrs >= addr:
                     return symbol_obj
         elif isinstance(vaddrs, list):
             symbol = [self.get_symbol_by_vaddr(vaddr) for vaddr in vaddrs]
             return symbol
         else:
             raise ValueError
         return None

     def get_section_by_name(self, sec_names=None):
         """
         Get section by_name
         :param sec_names: "sec_name" : str or list
         :return: Section() or [Section()]
         """
         if isinstance(sec_names, str):
             for addr, section_obj in self.get_sections().items():
                 if section_obj.name == sec_names:
                     return section_obj
         elif isinstance(sec_names, list):
             sections = [self.get_section_by_name(sec_name) for sec_name in sec_names]
             return sections
         else:
             raise ValueError
         return None

     def get_section_by_vaddr(self, vaddrs=None):
         """
         Get section by virtual address
         :param vaddrs: vaddr : int  or list
         :return: Section() or [Section()]
         """
         if isinstance(vaddrs, int):
             if vaddrs in self.get_sections():
                 return self.get_sections()[vaddrs]
             for addr, section_obj in self.get_sections().items():
                 if (addr + section_obj.size) >= vaddrs >= addr:
                     return section_obj
         elif isinstance(vaddrs, list):
             sections = [self.get_symbol_by_vaddr(vaddr) for vaddr in vaddrs]
             return sections
         else:
             raise ValueError
         return None

     def vaddr_to_file_offset(self, vaddrs):
         """
         Transform virtual address to file offset
         :param vaddrs: addr string or int or list
         :returns file offset or list
         """
         if isinstance(vaddrs, str) or isinstance(vaddrs, int):
             section = self.get_section_by_vaddr(vaddrs)
             return self.utils.to_int(vaddrs, 16) - section.addr + section.offset
         elif isinstance(vaddrs, list):
             return [self.vaddr_to_file_offset(vaddr) for vaddr in vaddrs]
         else:
             raise ValueError

     def read_data_from_vaddr(self, vaddr, size, out_file):
         with open(self.__elf_file, "rb") as elf_fp:
             elf_fp.seek(self.vaddr_to_file_offset(vaddr))
             with open(out_file, "wb") as out_fp:
                 out_fp.write(elf_fp.read(size))
	#!/usr/bin/env python3
	# -- coding: utf-8 --

	"""
	Module ELF contains ELF, Symbol, Section classes for manipulation over ELF files.
	It can parse, and change ELF file. This version works only with vmlinux and doesn't properly work with ELF that contains
	UND symbols
	"""

	import subprocess
	import re
	import os
	import struct
	from Utils import Utils
	from collections import OrderedDict
	from binascii import unhexlify

	__author__ = "Vadym Stupakov"
	__copyright__ = "Copyright (c) 2017 Samsung Electronics"
	__credits__ = ["Vadym Stupakov"]
	__version__ = "1.0"
	__maintainer__ = "Vadym Stupakov"
	__email__ = "v.stupakov@samsung.com"
	__status__ = "Production"


	class Symbol:
	def __init__(self, name=str(), sym_type=str(), bind=str(), visibility=str(), addr=int(), size=int(), ndx=str()):
	self.utils = Utils()
	self.name = str(name)
	self.type = str(sym_type)
	self.bind = str(bind)
	self.ndx = str(ndx)
	self.visibility = str(visibility)
	self.addr = self.utils.to_int(addr)
	self.size = self.utils.to_int(size)

	def __str__(self):
	return "name: '{}', type: '{}', bind: '{}', ndx: '{}', visibility: '{}', address: '{}', size: '{}'".format(
	self.name, self.type, self.bind, self.ndx, self.visibility, hex(self.addr), hex(self.size)
	)

	def __lt__(self, other):
	return self.addr <= other.addr


	class Section:
	def __init__(self, name=str(), sec_type=str(), addr=int(), offset=int(), size=int()):
	self.utils = Utils()
	self.name = str(name)
	self.type = str(sec_type)
	self.addr = self.utils.to_int(addr)
	self.offset = self.utils.to_int(offset)
	self.size = self.utils.to_int(size)

	def __str__(self):
	return "name: '{}', type: '{}', address: '{}', offset: '{}', size: '{}'".format(
	self.name, self.type, hex(self.addr), hex(self.offset), hex(self.size)
	)

	def __lt__(self, other):
	return self.addr <= other.addr


	class ELF:
	"""
	Utils for manipulating over ELF
	"""
	def __init__(self, elf_file, readelf_path=os.environ.get('CROSS_COMPILE')+"readelf"):
	self.__elf_file = elf_file
	self.utils = Utils()
	self.__readelf_path = readelf_path
	self.__sections = OrderedDict()
	self.__symbols = OrderedDict()
	self.__relocs = list()
	self.__re_hexdecimal = "\s[0-9A-Fa-f]+\s"
	self.__re_sec_name = "\s[._a-zA-Z]+\s"
	self.__re_type = "\s[A-Z]+\s"

	def __readelf_raw(self, options):
	"""
	Execute readelf with options and print raw output
	:param options readelf options: ["opt1", "opt2", "opt3", ..., "optN"]
	:returns raw output
	"""
	ret = subprocess.Popen(args=[self.__readelf_path] + options,
	stdout=subprocess.PIPE,
	stderr=subprocess.PIPE)
	stdout, stderr = ret.communicate()
	if "readelf: Error: the PHDR segment is not covered by a LOAD segment" in stderr.decode("utf-8").strip():
	ret.returncode = 0
	if ret.returncode != 0:
	raise ChildProcessError(stderr.decode("utf-8") + stdout.decode("utf-8"))
	return stdout.decode("utf-8")

	def set_elf_file(self, elf_file):
	if os.path.abspath(self.__elf_file) != os.path.abspath(elf_file):
	self.__elf_file = os.path.abspath(elf_file)
	self.__sections.clear()
	self.__symbols.clear()
	self.__relocs.clear()

	def get_elf_file(self):
	return os.path.abspath(self.__elf_file)

	def get_sections(self):
	""""
	Execute -> parse -> transform to dict() readelf output
	:returns dict: {sec_addr : Section()}
	"""
	if len(self.__sections) == 0:
	sec_header = self.__readelf_raw(["-SW", self.__elf_file]).strip()
	secs = re.compile("^.\[.\](" + self.__re_sec_name + self.__re_type + self.__re_hexdecimal +
	self.__re_hexdecimal + self.__re_hexdecimal + ")", re.MULTILINE)
	found = secs.findall(sec_header)
	for line in found:
	line = line.split()
	if len(line) == 5:
	self.__sections[int(line[2], 16)] = Section(name=line[0], sec_type=line[1], addr=int(line[2], 16),
	offset=int(line[3], 16), size=int(line[4], 16))
	self.__sections = OrderedDict(sorted(self.__sections.items()))
	return self.__sections

	def get_symbols(self):
	""""
	Execute -> parse -> transform to dict() readelf output
	:returns dict: {sym_addr : Symbol()}
	"""
	if len(self.__symbols) == 0:
	sym_tab = self.__readelf_raw(["-sW", self.__elf_file])
	syms = re.compile(r"^.\d+:\s(.$)", re.MULTILINE)
	found = syms.findall(sym_tab.strip())
	for line in found:
	line = line.split()
	if len(line) == 7:
	size = line[1]
	# This needs, because readelf prints sizes in hex if size is large
	if size[:2].upper() == "0X":
	size = int(size, 16)
	else:
	size = int(size, 10)
	"""
	Do not include additional compiler information with name $d and $x
	$d and $x is mapping symbols, their virtual addresses may coincide with virtual addresses
	of the real objects
	"""
	if line[6] not in ("$d", "$x") and (size != 0):
	self.__symbols[int(line[0], 16)] = Symbol(addr=int(line[0], 16), size=size, sym_type=line[2],
	bind=line[3], visibility=line[4], ndx=line[5],
	name=line[6])
	self.__symbols = OrderedDict(sorted(self.__symbols.items()))
	return self.__symbols

	def get_relocs(self, start_addr=None, end_addr=None):
	""""
	:param start_addr: start address :int
	:param end_addr: end address: int
	:returns list: [reloc1, reloc2, reloc3, ..., relocN]
	"""
	if len(self.__relocs) == 0:
	relocs = self.__readelf_raw(["-rW", self.__elf_file])
	rel = re.compile(r"^(" + self.__re_hexdecimal + ")\s*", re.MULTILINE)
	self.__relocs = [self.utils.to_int(el) for el in rel.findall(relocs.strip())]

	if start_addr and end_addr is not None:
	ranged_rela = list()
	for el in self.__relocs:
	if self.utils.to_int(start_addr) <= self.utils.to_int(el) <= self.utils.to_int(end_addr):
	ranged_rela.append(el)
	return ranged_rela
	return self.__relocs

	def get_altinstructions(self, start_addr=None, end_addr=None):
	"""
	:param start_addr: start address :int
	:param end_addr: end address: int
	:returns list: [[alt_inst1_addr, length1], [alt_inst2_addr, length2], ...]

	.altinstructions section contains an array of struct alt_instr.
	As instance, for kernel 4.14 from /arch/arm64/include/asm/alternative.h
	struct alt_instr {
	s32 orig_offset; /* offset to original instruction */
	s32 alt_offset; /* offset to replacement instruction */
	u16 cpufeature; /* cpufeature bit set for replacement */
	u8 orig_len; /* size of original instruction(s) */
	u8 alt_len; /* size of new instruction(s), <= orig_len */
	};

	Later, address of original instruction can be calculated as
	at runtime : &(alt_instr->orig_offset) + alt_instr->orig_offset + kernel offset
	ELF processing : address of .altinstruction section + in section offset of alt_instr structure + value of alt_instr.orig_offset
	details in /arch/arm64/kernel/alternative.c, void __apply_alternatives(void *, bool)
	"""

	# The struct_format should reflect <struct alt_instr> content
	struct_format = '<iiHBB'
	pattern_altinst_section_content = "^ 0x[0-9A-Fa-f]{16} (.) .*.{16}$"
	pattern_altinstr_section_addr = "^ (0x[0-9A-Fa-f]{16})..*.{16}$"

	ranged_altinst = list()

	__hex_dump = self.__readelf_raw(["--hex-dump=.altinstructions", self.__elf_file])
	if len(__hex_dump) == 0:
	return ranged_altinst

	# .altinstruction section start addr in ELF
	__altinstr_section_addr = int(re.findall(pattern_altinstr_section_addr, __hex_dump, re.MULTILINE)[0], 16)

	# To provide .altinstruction section content using host readelf only
	# some magic with string parcing is needed
	hex_dump_list = re.findall(pattern_altinst_section_content, __hex_dump, re.MULTILINE)
	__hex_dump_str = ''.join(hex_dump_list).replace(" ", "")
	__altinstr_section_bin = unhexlify(__hex_dump_str)

	__struct_size = struct.calcsize(struct_format)

	if (len(__altinstr_section_bin) % __struct_size) != 0:
	return ranged_altinst

	if start_addr and end_addr is not None:
	__i = 0
	while __i < (len(__altinstr_section_bin) - __struct_size):
	__struct_byte = __altinstr_section_bin[__i: __i + __struct_size]
	__struct_value = list(struct.unpack(struct_format, __struct_byte))

	# original instruction addr (going to be replaced) considered as "gap"
	__original_instruction_addr = __struct_value[0] + __altinstr_section_addr + __i

	# derive the target ARM instruction(s) length.
	__target_instruction_len = __struct_value[4]

	if self.utils.to_int(start_addr) <= __original_instruction_addr <= self.utils.to_int(end_addr):
	ranged_altinst.append([__original_instruction_addr, __target_instruction_len])
	__i = __i + __struct_size

	return ranged_altinst

	def get_symbol_by_name(self, sym_names):
	"""
	Get symbol by_name
	:param sym_names: "sym_name" : str or list
	:return: Symbol() or [Symbol()]
	"""
	if isinstance(sym_names, str):
	for addr, symbol_obj in self.get_symbols().items():
	if symbol_obj.name == sym_names:
	return symbol_obj
	elif isinstance(sym_names, list):
	symbols = [self.get_symbol_by_name(sym_name) for sym_name in sym_names]
	return symbols
	else:
	raise ValueError
	return None

	def get_symbol_by_vaddr(self, vaddrs=None):
	"""
	Get symbol by virtual address
	:param vaddrs: vaddr : int or list
	:return: Symbol() or [Symbol()]
	"""
	if isinstance(vaddrs, int):
	if vaddrs in self.get_symbols():
	return self.get_symbols()[vaddrs]
	for addr, symbol_obj in self.get_symbols().items():
	if (addr + symbol_obj.size) >= vaddrs >= addr:
	return symbol_obj
	elif isinstance(vaddrs, list):
	symbol = [self.get_symbol_by_vaddr(vaddr) for vaddr in vaddrs]
	return symbol
	else:
	raise ValueError
	return None

	def get_section_by_name(self, sec_names=None):
	"""
	Get section by_name
	:param sec_names: "sec_name" : str or list
	:return: Section() or [Section()]
	"""
	if isinstance(sec_names, str):
	for addr, section_obj in self.get_sections().items():
	if section_obj.name == sec_names:
	return section_obj
	elif isinstance(sec_names, list):
	sections = [self.get_section_by_name(sec_name) for sec_name in sec_names]
	return sections
	else:
	raise ValueError
	return None

	def get_section_by_vaddr(self, vaddrs=None):
	"""
	Get section by virtual address
	:param vaddrs: vaddr : int or list
	:return: Section() or [Section()]
	"""
	if isinstance(vaddrs, int):
	if vaddrs in self.get_sections():
	return self.get_sections()[vaddrs]
	for addr, section_obj in self.get_sections().items():
	if (addr + section_obj.size) >= vaddrs >= addr:
	return section_obj
	elif isinstance(vaddrs, list):
	sections = [self.get_symbol_by_vaddr(vaddr) for vaddr in vaddrs]
	return sections
	else:
	raise ValueError
	return None

	def vaddr_to_file_offset(self, vaddrs):
	"""
	Transform virtual address to file offset
	:param vaddrs: addr string or int or list
	:returns file offset or list
	"""
	if isinstance(vaddrs, str) or isinstance(vaddrs, int):
	section = self.get_section_by_vaddr(vaddrs)
	return self.utils.to_int(vaddrs, 16) - section.addr + section.offset
	elif isinstance(vaddrs, list):
	return [self.vaddr_to_file_offset(vaddr) for vaddr in vaddrs]
	else:
	raise ValueError

	def read_data_from_vaddr(self, vaddr, size, out_file):
	with open(self.__elf_file, "rb") as elf_fp:
	elf_fp.seek(self.vaddr_to_file_offset(vaddr))
	with open(out_file, "wb") as out_fp:
	out_fp.write(elf_fp.read(size))