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lscan.py
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lscan.py
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'''
lscan is a tool which identifying library in statically linked/stripped binaries.
The tool is useful for the reverse engineering and computer forensics.
It helps recognizing common functions in compiled binaries and determining libraries they are using.
lscan uses FLIRT (Fast Library Identification and Recognition Technology) signatures to perform library identification.
'''
__author__ = "Marouene Boubakri"
__copyright__ = "Copyright 2016, Semester Project"
__version__ = "0.6"
__email__ = "marouene.boubakri@eurecom.fr"
__status__ = "Development"
import struct
import io
import zlib
import cStringIO
import sys
from elftools.elf.elffile import ELFFile
from elftools.elf.sections import SymbolTableSection
from elftools.common.exceptions import ELFError
import optparse
import os
import re
import pefile
# max function name length
MAX_FLIRT_FUNCTION_NAME = 1024
# architecture flags
ARCH = [
"386",
"Z80",
"I860",
"8051",
"TMS",
"6502",
"PDP",
"68K",
"JAVA",
"6800",
"ST7",
"MC6812",
"MIPS",
"ARM",
"TMSC6",
"PPC",
"80196",
"Z8",
"SH",
"NET",
"AVR",
"H8",
"PIC",
"SPARC",
"ALPHA",
"HPPA",
"H8500",
"TRICORE",
"DSP56K",
"C166",
"ST20",
"IA64",
"I960",
"F2MC",
"TMS320C54",
"TMS320C55",
"TRIMEDIA",
"M32R",
"NEC_78K0",
"NEC_78K0S",
"M740",
"M7700",
"ST9",
"FR",
"MC6816",
"M7900",
"TMS320C3",
"KR1878",
"AD218X",
"OAKDSP",
"TLCS900",
"C39",
"CR16",
"MN102L00",
"TMS320C1X",
"NEC_V850X",
"SCR_ADPT",
"EBC",
"MSP430",
"SPU",
"DALVIK"]
# file types flags
FILE_TYPE = {
"DOSEXE(OLD)": 0x1,
"DOSCOM(OLD)": 0x2,
"BIN": 0x4,
"DOSDRV": 0x8,
"NE": 0x10,
"INTEL_HEX": 0x20,
"MOS_HEX": 0x40,
"LX": 0x80,
"LE": 0x100,
"NLM": 0x200,
"COFF": 0x400,
"PE": 0x800,
"OMF": 0x1000,
"SREC": 0x2000,
"ZIP": 0x4000,
"OMFLIB": 0x8000,
"AR": 0x10000,
"LOADER": 0x20000,
"ELF": 0x40000,
"W32RUN": 0x80000,
"AOUT": 0x100000,
"PILOT": 0x200000,
"DOS_EXE": 0x400000,
"DOS_COM": 0x800000,
"AIXAR": 0x1000000}
# OS types flags
OS_TYPE = {
"MSDOS": 0x01,
"WIN": 0x02,
"OS/2": 0x04,
"NETWARE": 0x08,
"UNIX": 0x10,
"OTHER": 0x20}
# application types flags
APP_TYPE = {
"CONSOLE": 0x1,
"GRAPHICS": 0x2,
"EXE": 0x4,
"DLL": 0x8,
"DRV": 0x10,
"SINGLE-THREADED": 0x20,
"MULTI-THREADED": 0x40,
"16BIT": 0x80,
"32BIT": 0x100,
"64BIT": 0x200}
# features flags
FEATURES = {
"STARTUP": 0x01,
"CTYPE_CRC": 0x02,
"2BYTE_CTYPE": 0x04,
"ALT_CTYPE_CRC": 0x08,
"COMPRESSED": 0x10}
# parsing flags
PARSE_MORE_PUBLIC_NAMES = 0x1
PARSE_TAIL_BYTES = 0x2
PARSE_REF_FUNCTIONS = 0x4
PARSE_MORE_MODULES_WITH_SAME_CRC = 0x8
PARSE_MORE_MODULES = 0x10
# function flags
# function appears as "d" in dumpsig
FUNCTION_D = 0x1
FUNCTION_LOCAL = 0x2
# function appears as "?" in dumpsig
FUNCTION_Q = 0x4
FUNCTION_UNRESOLVED_COLLISION = 0x08
# stores the identified functions names/offsets
matches = {}
class BinaryFunction:
name = ""
offset = 0
size = 0
buf = ""
class FlirtHeader:
magic = "" # char a[6]
version = 0 # uint8_t
arch = 0 # uint8_t
file_types = 0 # uint32_t
os_types = 0 # uint16_t
app_types = 0 # uint16_t
features = 0 # uint8_t
old_n_fcns = 0 # uint16_t
crc16 = 0 # uint16_t
ctype = "" # char a[12]
lib_name_len = 0 # uint8_t
ctypes_crc16 = 0 # uint16_t
n_fcns = 0 # uint32_t # introduced with flirt version 6
pat_size = 0 # uint16_t # introduced with flirt version 8
ctype_unknown_field = 0 # uint16_t # introduced with flirt version 10
lib_name = "" # char a[]
num_fcns = 0
class FlirtNode:
len = 0
var_mask = 0
pat_bytes = None
var_bool_arr = None
childs = []
modules = []
parent = None
class FlirtModule:
crc_len = 0
crc16 = 0
len = 0
pub_fcns = None
tail_bytes = None
ref_fcns = None
class FlirtFunction:
name = ""
offset = 0
neg_offset = 0
is_loc = False
is_col = False
class FlirtTailByte:
offset = 0
value = 0
class FlirtFlag:
flags = 0
class BinarySegment:
offset = 0
size = 0
addr = 0
def parse_pe(pefilepath):
'''Parses a PE executable and return the list of sections,
the import table and the raw content
Args:
pefile (str): path to a pe binary file
Returns:
imgbase: image base
segs: segment list
funcs: import table
'''
funcs = []
segs = []
pe = pefile.PE(pefilepath, fast_load=True)
try:
for sec in pe.sections:
seg = BinarySegment()
seg.addr = sec.VirtualAddress
seg.size = sec.SizeOfRawData
seg.offset = 0
segs.append(seg)
#needed ti calculate function address in virtual space
imgbase = pe.OPTIONAL_HEADER.ImageBase
#get imports
'''pe.parse_data_directories()
for entry in pe.DIRECTORY_ENTRY_IMPORT:
for imp in entry.imports:
fcn = BinaryFunction()
fcn.name = imp.name
fcn.offset = hex(imp.address)
fcn.size = 0
funcs.append(fcn)
'''
except pefile.PEFormatError:
sys.stderr.write('Unable to parse PE file')
sys.exit(1)
return imgbase, segs, funcs
def parse_elf(elffile):
'''Parses an ELF executable and return the image base, list of sections,
the symbol table
Args:
elfffile (str): path to an ELF file
Returns:
imgbase: image base
segs: binary segments list
funcs: binary functions list from symbol table
'''
funcs = []
segs = []
#imgbase not needed here, function's virtual address is calculated based on segments(address, offset, size)
imgbase = 0
try:
with open(elffile, 'rb') as f:
elffile = ELFFile(f)
sec = elffile.get_section_by_name('.symtab')
if not sec:
sys.stderr.write("No symbol table found bin binary\n")
'''if isinstance(sec, SymbolTableSection):
for i in range(1, sec.num_symbols() + 1):
if sec.get_symbol(i)["st_info"]["type"] == "STT_FUNC":
fcn = BinaryFunction()
fcn.name = sec.get_symbol(i).name
fcn.offset = sec.get_symbol(i)["st_value"]
fcn.size = sec.get_symbol(i)["st_size"]
funcs.append(fcn)
'''
f.seek(0)
for segment in elffile.iter_segments():
if segment['p_type'] == 'PT_LOAD':
seg = BinarySegment()
seg.addr = segment['p_vaddr']
seg.size = segment['p_filesz']
seg.offset = segment['p_offset']
segs.append(seg)
except ELFError:
sys.stderr.write('Unable to parse ELF file')
sys.exit(1)
return imgbase, segs, funcs
def parse_binary_file(binfile):
fd = open(binfile, 'rb')
raw = fd.read()
fd.close()
if raw[:4] == b'\x7f\x45\x4c\x46':
imgbase, segs, funcs = parse_elf(binfile)
format = 'ELF'
elif raw[:2] == b'\x4d\x5a':
imgbase, segs, funcs = parse_pe(binfile)
format = 'PE'
else:
sys.stderr.write('ELF or PE not recognized. The file will be analyzed as a RAW binary object...\n')
imgbase, segs, funcs = None, None, None
format = 'RAW'
return raw, format, imgbase, segs, funcs
def next_byte(buf):
'''Read one byte from a flirt signature file'''
byte = struct.unpack("B", buf.read(1))[0]
if byte != '':
return byte
return 0
def next_short (buf):
'''Read a short value from a flirt signature file'''
val = (next_byte(buf) << 8)
val += next_byte(buf)
return val
def next_word (buf):
'''Read a word value from a flirt signature file'''
val = (next_short (buf) << 16)
val += next_short (buf)
return val
def next_multibytes (buf):
'''Read multi-bytes from a flirt signature file (up to 5 bytes)'''
byte = next_byte(buf)
if (byte & 0x80) != 0x80:
return byte
if (byte & 0xc0) != 0xc0:
return ((byte & 0x7f) << 8) + next_byte(buf)
if (byte & 0xe0) != 0xe0:
byte = ((byte & 0x3f) << 24) + ( next_byte(buf) << 16)
byte += next_short(buf)
return byte
return next_word(buf)
def next_max2bytes(buf):
'''Read max 2 bytes from a flirt signature file'''
byte = next_byte(buf)
if byte & 0x80:
return ((byte & 0x7f) << 8) + next_byte(buf)
return byte
def parse_node_length(node, buf):
'''parse node length. node length is the pattern size of the node'''
node.len = next_byte(buf)
return node
def parse_node_variant_mask(node, buf):
'''parse the mask defining the variant bytes'''
if node.len < 0x10:
node.var_mask = next_max2bytes(buf)
elif node.len <= 0x20:
node.var_mask = next_multibytes(buf)
elif node.len <= 0x40:
node.var_mask = (next_multibytes(buf) << 32)+ next_multibytes(buf)
def parse_node_bytes(node, buf):
'''parse node bytes and variant bytes'''
cur_mask_bit = 1 << (node.len - 1)
node.var_bool_arr = []
node.pat_bytes = []
for i in range(node.len):
node.var_bool_arr.append(True if (node.var_mask & cur_mask_bit) else False)
if node.var_mask & cur_mask_bit:
node.pat_bytes.append(0x00)
else:
node.pat_bytes.append(next_byte(buf))
cur_mask_bit >>= 1
def parse_module_public_functions(module, buf, flags, header):
'''parses module public functions.
function list is added to the module
Args:
module (:obj:`FlirtModule`): current module being parsed by parse_leaf() function
flags (:obj:`FlirtFlag`): parsing flags
header (:obj:`FlirtHeader`): parsed header of the signature file
'''
# initialize module's public functions list
module.pub_fcns = []
offset = 0
while True:
fcn = FlirtFunction()
# parse function offset.
# if flirt signature version >= 9 parse up to 5 bytes.
# else parse 2 bytes
if header.version >= 9 :
offset += next_multibytes(buf)
else:
offset += next_max2bytes(buf)
fcn.offset = offset
cur_byte = next_byte(buf)
# current byte is a parsing flag
if cur_byte < 0x20:
# is function local ?
if cur_byte & FUNCTION_LOCAL :
fcn.is_loc = True
# is it an unresolved collision ?
if cur_byte & FUNCTION_UNRESOLVED_COLLISION :
fcn.is_col = True
if (cur_byte & FUNCTION_D) or (cur_byte & FUNCTION_Q):
print "investig. flag of pub name..."
cur_byte = next_byte(buf)
for i in range(MAX_FLIRT_FUNCTION_NAME):
if cur_byte < 0x20:
break
# current byte is part of the function name
fcn.name+= chr(cur_byte)
cur_byte = next_byte(buf)
# current function's name is too long
if i == MAX_FLIRT_FUNCTION_NAME:
# print "Function name too long"
break
# parsing flag
flags.flags = cur_byte
# append the parsed function to the current module
module.pub_fcns.append(fcn)
# increment functions number
header.num_fcns+=1
# parse more public functions ?
if flags.flags & PARSE_MORE_PUBLIC_NAMES == 0:
break
def parse_module_tail_bytes (module, buf, header):
'''parses module tail bytes.
tail bytes list is added to the module
Args:
module (:obj:`FlirtModule`): current module being parsed by parse_leaf() function
buf (str): signature file's raw content
header (:obj:`FlirtHeader`): parsed header of the signature file
'''
# initialize module's tail bytes list
module.tail_bytes = []
# how many tail bytes ?
# assume that we have 1 tail byte if flirt signature version < 8
if header.version >= 8 :
tail_bytes_nbr = next_byte (buf)
else:
tail_bytes_nbr = 1
for i in range(tail_bytes_nbr):
tail_byte = FlirtTailByte()
# parse tail byte offset
if header.version >= 9:
tail_byte.offset = next_multibytes(buf)
else:
tail_byte.offset = next_max2bytes(buf)
# parse tail byte value
tail_byte.value = next_byte(buf)
# add tail bytes to the current module
module.tail_bytes.append(tail_byte)
def parse_module_referenced_functions(module, buf, header):
'''parses module referenced functions.
referenced functions list is added to the module
Args:
module (:obj:`FlirtModule`): current module being parsed by parse_leaf() function
buf (str): signature file's raw content
header (:obj:`FlirtHeader`): parsed header of the signature file
'''
# initialize module's referenced functions list
module.ref_fcns = []
# how many referenced functions ?
# assume that we have 1 referenced function if flirt signature version < 8
if header.version >= 8 :
ref_fcn_nbr = next_byte(buf)
else:
ref_fcn_nbr = 1
for i in range(ref_fcn_nbr):
ref_fcn = FlirtFunction()
# parse referenced function offset
if header.version >= 9 :
ref_fcn.offset = next_multibytes(buf)
else:
ref_fcn.offset = next_max2bytes(buf)
# parse referenced function's name length
ref_fcn_name_len = next_byte(buf)
if ref_fcn_name_len == 0 :
ref_fcn_name_len = next_multibytes(buf)
for i in range(ref_fcn_name_len):
ref_fcn.name += chr(next_byte(buf))
# if function name is null terminated then the offset is negative
if ref_fcn.name[ref_fcn_name_len-1] == 0:
ref_fcn.neg_offset = True
# append the parsed referenced function to the current module
module.ref_fcns.append(ref_fcn)
def parse_leaf (buf, node, header):
'''parse a flirt signature leaf.
a leaf has modules with same leading pattern.
module list is added to the node
Args:
buf (str): raw content of the signature file
node (:obj:`FlirtNode`): current node being parsed
header (:obj:`FlirtHeader`): parsed header of the signature file
'''
# node module list
node.modules = []
# parsing flags
flags = FlirtFlag()
while True:
# parse crc length
crc_len = next_byte(buf)
# parse crc value
crc16 = next_short(buf)
while True:
module = FlirtModule()
module.crc_len = crc_len
module.crc16 = crc16
# parse module length.
# If flirt sig version >= 9 read up to 5 bytes
# else read 2 bytes
if header.version >= 9:
module.len = next_multibytes(buf)
else:
module.len = next_max2bytes(buf)
# parse module public functions
parse_module_public_functions(module, buf, flags, header)
# parse module tail bytes
if flags.flags & PARSE_TAIL_BYTES:
parse_module_tail_bytes(module, buf, header)
# parse module referenced functions
if flags.flags & PARSE_REF_FUNCTIONS:
parse_module_referenced_functions(module, buf, header)
# append the parsed module to the current node
node.modules.append(module)
# parse funtion with same crc
if flags.flags & PARSE_MORE_MODULES_WITH_SAME_CRC == 0:
break
# parse another module
if flags.flags & PARSE_MORE_MODULES == 0:
break
def parse_tree(buf, root_node, header):
'''parse a tree or a sub-tree
Args:
buf (str): raw content of the signature file
root_node (:obj:`FlirtNode`): current node being parsed
header (:obj:`FlirtHeader`): parsed header of the signature file
'''
# How many initial root nodes ?
tree_nodes = next_multibytes(buf)
# If it is equal to 0 then it is a leaf. go and parse it
if tree_nodes == 0:
parse_leaf(buf, root_node, header)
root_node.childs = []
# for each root node
for i in range(tree_nodes):
node = FlirtNode()
# parse node length
node = parse_node_length(node, buf)
# parse node variant mask
parse_node_variant_mask(node, buf)
# parse node non-variant bytes
parse_node_bytes(node, buf)
# assign current node to its parent node
node.parent = root_node
# append the current node to parent's nodes
root_node.childs.append(node)
# parse children
parse_tree(buf, node, header)
def dump_node_pattern (node):
'''Prints node's variant and non-variant bytes'''
for i in range(node.len):
if node.var_bool_arr[i]:
sys.stdout.write("..")
else:
sys.stdout.write("%02X"%node.pat_bytes[i])
print ":"
def ident(indent):
for i in range(indent):
print " ",
def dump_module(module):
'''Prints module's public functions, tail bytes and referenced functions'''
sys.stdout.write("%02X %04X %04X"%(module.crc_len, module.crc16, module.len))
for func in module.pub_fcns:
if func.is_loc or func.is_col:
sys.stdout.write("(")
if func.is_loc:
sys.stdout.write("l")
if func.is_col:
sys.stdout.write("!")
sys.stdout.write(")")
sys.stdout.write("%04X:%s"%(func.offset, func.name))
if module.tail_bytes:
for tail_byte in module.tail_bytes:
sys.stdout.write(" (%04X: %02X)"%(tail_byte.offset, tail_byte.value))
if module.ref_fcns:
print " (REF ",
for ref_func in module.ref_fcns:
sys.stdout.write("%04X: %s"%(ref_func.offset, ref_func.name))
sys.stdout.write(")")
print " "
def dump_node(node,indent = 0):
'''dump a flirt signature node, the output is the same as the dumpsig command output'''
if node.pat_bytes is not None:
ident(indent)
dump_node_pattern(node)
if len(node.childs):
for child in node.childs:
dump_node(child, indent + 1)
elif len(node.modules):
i = 0
for module in node.modules:
ident (indent + 1)
print "%d."%i,
dump_module(module)
i+=1
def parse_flg_str(flag, value, str):
if flag & value:
return str
return ""
def dump_header(header):
'''Prints signature file header
Args:
header (:obj:`FlirtHeader`): a parsed signature file header, use parse_signature_file() function to parse the header
'''
print "lib: %s"%header.lib_name
print "magic: %s"%header.magic
print "version: %d"%header.version
print "arch: %s"%ARCH[header.arch]
file_types = ""
for file_type in FILE_TYPE:
file_types+= parse_flg_str(FILE_TYPE[file_type],header.file_types, file_type)+" "
print "file type: %s"%file_types
os_types = ""
for os_type in OS_TYPE:
os_types+= parse_flg_str(OS_TYPE[os_type],header.os_types, os_type)+" "
print "os type: %s"%os_types
app_types = ""
for app_type in APP_TYPE:
app_types+= parse_flg_str(APP_TYPE[app_type],header.app_types, app_type)+" "
print "app type: %s"%app_types
features = ""
for feature in FEATURES:
features+= parse_flg_str(FEATURES[feature],header.features, feature)+" "
print "features: %s"%features
print "old n functions: %04x"%header.old_n_fcns
print "crc16: %04x"%header.crc16
print "ctype: %s"%header.ctype
print "lib name len: %s"%header.lib_name_length
print "ctypes crc16: %04x"%header.ctypes_crc16
if header.version >= 6:
print "n functions: %08x"%header.n_fcns
if header.version >= 8:
print "pattern size: %d"%header.pat_size
if header.version >= 10:
print "unknown v10: %02x"%header.ctype_unknown_field
print "lib name: %s"%header.lib_name
def parse_signature_file(file):
'''Parse a flirt signature file
Args:
path (str): path to a .sig signature file
Returns:
root_node: (:obj:`FlirtNode`): the root node
header: (:obj:`FlirtHeader`): parsed signature file header
'''
sigfile = open(file, 'rb')
# parse the header
header = FlirtHeader()
buf = io.BytesIO(sigfile.read())
buf.seek(0)
header.magic = buf.read(6)
if header.magic != "IDASGN":
print 'Not a FLIRT signature'
return
header.version = next_byte(buf)
header.arch = next_byte(buf)
header.file_types = next_word(buf)
header.os_types = next_short(buf)
header.app_types = next_short(buf)
header.features = next_short(buf)
header.old_n_fcns = next_short(buf)
header.crc16 = next_short(buf)
header.ctype = buf.read(12)
header.lib_name_length = next_byte(buf)
header.ctypes_crc16 = next_short(buf)
if header.version >= 6:
header.n_fcns = next_word(buf)
if header.version >= 8:
header.pat_size = next_short(buf)
if header.version >= 10:
header.ctype_unknown_field = next_short(buf)
header.lib_name = buf.read(header.lib_name_length)
# read raw content
buf = buf.read(sigfile.tell() - buf.tell())
# if the signature file is compressed then decompress it
if header.features & 0x10:
if header.version == 5 :
print 'Compression is not supported in version 5'
return
z = zlib.decompressobj()
buf = z.decompress(buf)
buf = cStringIO.StringIO(buf)
buf.seek(0)
# create the root node
root_node = FlirtNode()
# start parsing
parse_tree(buf, root_node, header)
return root_node, header
def crc16(buf, len):
'''Compute the crc16 of a buffer content with given length
Args:
buf (str): buffer
len(int): buffer length
Returns:
crc: crc16 value
'''
poly = 0x8408
reg = 0xffff
i = 0
while i < len:
byte = buf[i]
mask = 0x01
while mask < 0x100:
lowbit = reg & 1
reg >>= 1
if ord(byte) & mask:
lowbit ^= 1
mask <<= 1
if lowbit:
reg ^= poly
i+=1
reg ^= 0xffff
crc = chr(reg & 0xff) + chr(reg >> 8)
return int(crc.encode("hex"),16)
def node_compare_pattern(node, buf,debug=False):
'''compare node variant and non-variant bytes to a given buffer
Args:
node (:obj:`FlirtNode`): a node
buf (str): binary file raw content
debug (bool): Prints debugging information
'''
for i in range(node.len):
if i >= len(buf):
break
if not node.var_bool_arr[i]:
if i < node.len and node.pat_bytes[i] != ord(buf[i]):
return False
return True
def node_compare_buffer(node, buf, fcn, debug=False):
if node_compare_pattern(node, buf):
if node.childs:
for child in node.childs:
if node_compare_buffer(child, buf[node.len:],fcn, debug):
return True
elif node.modules:
for module in node.modules:
if module_compare_buffer(module, fcn, fcn.buf, debug):
return True
return False
def identify_functions(node, buf, debug=False):
'''Searches inside a binary content, bytes that match the current node pattern.
Args:
node (:obj:`FlirtNode`): root node or a child node from signature file
buf (str): binary raw content
debug (bool): set to True to print debug information
'''
# if the current node has children
if len(node.childs):
for child in node.childs:
identify_functions(child, buf, debug)
# if the current node has modules
elif len(node.modules):
pattern = []
variant = []
nnode = node
while nnode:
if nnode.pat_bytes:
pattern = nnode.pat_bytes + pattern
variant = nnode.var_bool_arr + variant
nnode = nnode.parent
# build regex expression for non-variant and variant pattern
re_pat = b""
for i in range(len(pattern)):
if variant[i]:
re_pat+=b"(.)"
else:
re_pat+=re.escape(chr(pattern[i]))
# compile the regex
regex = re.compile(re_pat, re.DOTALL+re.MULTILINE)
# search inside the binary for bytes that match the current node pattern
matchs = regex.finditer(buf)
for match in matchs:
# We found a match, let's see if the current offset of the binary is the offset of a known funtion
for module in node.modules:
#if module.crc_len == 0:
# break
# compute the crc value of the buffer starting from the function offset+32 to crc length
bufcrc16 = crc16(buf[match.start()+32:match.start()+32+module.crc_len], module.crc_len)
if bufcrc16 != module.crc16:
break
# we have the same crc, let's see if the module has tail bytes and try to match them against the current buffer
if module.tail_bytes:
for tail_byte in module.tail_bytes:
if ord(buf[match.start()+ 32 + module.crc_len + tail_byte.offset]) == tail_byte.value:
# Tail bytes are equal, great, the buffer belongs to a known module so let's read function details from the module and append them to the final result
for ffcn in module.pub_fcns:
addr = hex(ffcn.offset+match.start())
if addr in matches:
matches[addr].add(ffcn.name)
else:
matches[addr] = set([ffcn.name])
break
# great the buffer belongs to a known module so let's read function details from the module and append them to the final result
for ffcn in module.pub_fcns:
if True:
addr = hex(ffcn.offset+match.start())
if addr in matches:
matches[addr].add(ffcn.name)
else:
matches[addr] = set([ffcn.name])
def lscan(sigfile, binfile, debug = False, dump = False):
'''
This is the entrypoint. Match a binary file against a signature file
Args:
sigfile (str)- path to signature file
binfile (str)- path to binary file
debug (bool)- set to True the function prints function offset/name pair
'''
sigfiles = []
if os.path.isfile(sigfile):
sigfiles.append(sigfile)
elif os.path.isdir(sigfile):
sigfiles.extend([os.path.join(sigfile,fn) for fn in next(os.walk(sigfile))[2]])
# read the binary file
buf, format, imgbase, segs, funcs = parse_binary_file(binfile)
# print "Total functions in binary %d"%len(fcns)
for sigf in sigfiles:
matches.clear()
# parse a signature file
root_node, header = parse_signature_file(sigf)
if dump:
dump_header(header)
dump_node(root_node)
# do the job
identify_functions(root_node, buf, debug)
print "%s %d/%d (%s%%)"%(sigf, len(matches), header.num_fcns, "{:.2f}".format(100 * float(len(matches))/float(header.num_fcns)))
# print the result
if debug:
for addr in matches:
if len(matches[addr]) == 1:
string_head = "\033[0;32m[+]\033[0m"
else:
string_head = "\033[0;31m[-]\033[0m"
if format == 'ELF':
found = False
for seg in segs:
if seg.addr + int(addr,16) < seg.addr + seg.size:
found = True
print "\t%s 0x%08x %s"%(string_head, seg.addr + int(addr,16), ', '.join(matches[addr]))
break
if not found:
print "\t%s 0x%x: %s \033[0;33m<- not within a segment\033[0m"%(string_head, imgbase + int(addr,16), ', '.join(matches[addr]))
elif format == 'PE':
print "\t%s 0x%x: %s"%(string_head, imgbase + int(addr,16), ', '.join(matches[addr]))
elif format == 'RAW':
print "\t%s 0x%x: %s"%(string_head, int(addr,16), ', '.join(matches[addr]))
if __name__ == "__main__":
pars = optparse.OptionParser()
pars.add_option('-v', '--versbose',action="store_true", dest="verbose", help="Verbose mode", default=False)
pars.add_option('-s', '--sig',action="store", dest="sigfile", type="string", help="Signature file",default=None)
pars.add_option('-S', '--sigs',action="store", type="string", dest="sigdir", help="Signature folder",default=None)
pars.add_option('-f', '--file',action="store", type="string", dest="binfile", help="ELF file",default=None)
pars.add_option('-d', '--dump',action="store_true", dest="dump", help="Dump signature filre",default=None)
opts, args = pars.parse_args()
if not opts.binfile:
pars.error('No binary file given')
if not opts.sigfile and not opts.sigdir:
pars.error('Signature File/Folder not given')
if opts.sigdir and not os.path.isdir(opts.sigdir):
pars.error('%s is not a directory'%opts.sigdir)
if opts.sigfile and os.path.isdir(opts.sigfile):
pars.error('%s is a directory'%opts.sigfile)
lscan(opts.sigdir if opts.sigdir else opts.sigfile, opts.binfile, opts.verbose, opts.dump)