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absblk.py
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absblk.py
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#!/#!/usr/bin/env python2
# -------------------------------------------------------------------------------------------------
#
# ,ggggggggggg, _,gggggg,_ ,ggggggggggg, ,gggg,
# dP"""88""""""Y8, ,d8P""d8P"Y8b, dP"""88""""""Y8, ,88"""Y8b,
# Yb, 88 `8b,d8' Y8 "8b,dPYb, 88 `8b d8" `Y8
# `" 88 ,8Pd8' `Ybaaad88P' `" 88 ,8Pd8' 8b d8
# 88aaaad8P" 8P `""""Y8 88aaaad8P",8I "Y88P'
# 88""""Y8ba 8b d8 88""""" I8'
# 88 `8bY8, ,8P 88 d8
# 88 ,8P`Y8, ,8P' 88 Y8,
# 88_____,d8' `Y8b,,__,,d8P' 88 `Yba,,_____,
# 88888888P" `"Y8888P"' 88 `"Y8888888
#
# The Block Oriented Programming (BOP) Compiler - v2.1
#
#
# Kyriakos Ispoglou (ispo) - [email protected]
# PURDUE University, Fall 2016-18
# -------------------------------------------------------------------------------------------------
#
#
# absblk.py:
#
# This module implements the basic block "abstractions". Abstraction is a process that summarizes
# a basic block into the "impact" on program's state.
#
# -------------------------------------------------------------------------------------------------
from coreutils import *
import signal
import simuvex
import claripy
import archinfo
import angr
# ------------------------------------------------------------------------------------------------
# Constant Definitions
# ------------------------------------------------------------------------------------------------
_STACK_SZ = 0x1000 # size of symbolic stack
# -------------------------------------------------------------------------------------------------
# abstract_ng: This class implements the next generation of the basic block "abstraction". So
# far, the following abstractions are supported:
#
# * * Register Writes * *
# A dictionary that contains all registers that are being written. The "write" information is
# another dictionary with the following fields:
#
# * type : Can be 'concrete', 'deref', 'mod' or 'clob'. A register is of type 'clob'
# when, it does not fall to any of the other types
# * const : ('concrete' and 'mod' types). The constant value that is written to the
# register
# * writable : ('concrete' types). If the constant value is a valid and writable memory
# address, then this field is set to True
# * op : ('mod' types). The modification operator
# * addr : ('deref' types). The address that register value is loaded from
# * deps : ('deref' types). Any registers that participate in addr field
# * sym : ('deref' types). A mapping between registers and their symbolic variables
# * memrd : ('deref' types). When the register write can be used as a memory read, this
# field contains the size of the memory read in bytes (1,2,4,8). Otherwise it
# is set to None
#
# Example:
# regwr = {
# rsp : {'type': 'concrete', 'const': 576460752303357888L, 'writable': True },
# rcx : {'type': 'deref', 'addr': <BV64 rsi_43_64 + 0x10>, 'deps': ['rsi']},
# r9 : {'type': 'mod', 'op': '+', 'const': 1337L}
# }
#
#
# * * Memory Reads * *
# A list of tuples (address, size) for every memory read.
#
# Example:
# memrd = set([(<SAO <BV64 0x7ffffffffff0810>>, 64), (<SAO <BV64 0x7ffffffffff0818>>, 64)])
#
#
# * * Memory Writes * *
# A list of tuples (address, data) for every memory write (len(data) indicates the size)
#
# Example:
# memwr = set([(<SAO <BV64 0x7ffffffffff07f8>>, <SAO <BV64 rbx_1_64>>),
# (<SAO <BV64 0x7ffffffffff07e0>>, <SAO <BV64 0x416631>>)])
#
#
# * * Concrete Writes * *
# A list of tuples (address, size) for every concrete memory write.
#
# Example:
# conwr = set([(576460752303359992L, 64), (576460752303359968L, 64)])
#
#
# * * SPL Memory Writes * *
# A list of dictionaries for every SPL memory write (memory writes that are in the form:
# "mov [rax], rbx"). Each dictionary contains the following fields:
#
# * mem : The register that holds the address to write (string)
# * val : The register that holds the value to be written (string)
# * size : The number of bytes to write (e.g., mov [rax], cl, mov [rbx], dx)
# * sym : A mapping between registers and their symbolic variables
#
# Example:
# splmemwr = [{
# 'mem' : 'rbx',
# 'val' : 'rax',
# 'size' : 4,
# 'sym' : {'rax': <BV64 rax_0_64>, 'rbx': <BV64 rbx_1_64>}
# }]
#
#
# * * Calls * *
# A dictionary with the following fields:
#
# * type : Can be 'syscall', or 'libcall'
# * name : The name of the call
#
# Example:
# call = {'type': 'libcall', 'name': u'puts'}
#
#
# * * Conditional Jumps * *
# A dictionary with the following fields:
#
# * form : The form of the conditional jump ('simple' / 'extended')
# * reg : The register that participates in the conditional jump
# * const : The constant value that register is compared against
# * op : The comparison operator
# * mod_op : ('extended' types). The operator of the register modification
# * mod_const : ('extended' types). The constant of the register modification
#
# Example:
# cond = {'reg': 'r11', 'op': '==', 'const': 11L}
# cond = {'mod_op': '^', 'const': 0L, 'form': 'extended', 'op': '=='}
#
#
# * * Symbolic Variables * *
# A dictionary that maps the symbolic variables to their actual addresses that they correspond
#
# Example:
# symvar = {<BV64 mem_7fffffffffef1e8_82_64>' : 0x7fffffffffef1e8}
#
#
# * * * ---===== TODO list =====--- *
#
# [1]. Make absblk more precise i.e., check the order of memory writes
# [2]. Move this list at the beginning of the file.
#
class abstract_ng( object ):
''' ======================================================================================= '''
''' AUXILIARY FUNCTIONS '''
''' ======================================================================================= '''
# ---------------------------------------------------------------------------------------------
# __reg_w(): Analyze the register writes of the symbolic execution.
#
# :Arg state: Program's state after symbolic execution
# :Ret: None.
#
def __reg_w( self, state ):
visited = set() # visited registers
for action in reversed(state.actions): # for every action (start backwards)
if not (action.type == 'reg' and action.action == 'write'):
continue # we care about register writes only
try:
# we only care about the most recent register write only
reg = self.__proj.arch.register_names[action.offset]
except KeyError:
continue
# get the last write only
if reg not in HARDWARE_REGISTERS or reg in visited:
continue
data = { } # various data related to the write
visited.add(reg) # make sure that you won't visit this again
# ---------------------------------------------------------------------------
# If some address (initialized or not) is used as a dereference, the regwr
# entry for that register must be preserved (we should not overwrite register
# with the actual value in that address)
# ---------------------------------------------------------------------------
if reg in self.regwr and self.regwr[ reg ]['type'] == 'deref':
continue
# The register is being modified, so we start by marking it as clobbering
if reg not in self.regwr:
self.regwr[ reg ] = {'type' : 'clob'}
# -----------------------------------------------------------------
if action.data.concrete: # if register gets a concrete value,
value = state.se.eval(action.data) # concretize it
data['type'] = 'concrete' # set data
data['const'] = value
data['writable'] = True # initialize this first
in_section = False
# now, check whether this value is a writable address
try:
# The problem: There are some weird sections (.e.g., ".comment") whose VA
# starts from 0. Therefore, we may have register writes with constants like
# 1, 2 and so on, which are marked as +W. This means that at the end we can
# have memory reservations (writes) at those addresses. Our old approach with
# "state.memory.permissions(value)" doesn't work here.
#
# So iterate over ELF sections looking for it
for _, sec in self.__proj.loader.main_object.sections_map.iteritems():
# it's possible for the value to be part of >1 sections (usually when
# section's VA is 0; sec.vaddr != 0). We mark value as +W only when *all*
# sections are writable
if sec.contains_addr(value):
data['writable'] &= sec.is_writable
in_section = True
# if can't find section (b/c it's generated at runtime, like .stack)
if not in_section:
# TODO: check if value+1, value+2, etc. are writable as well
rwx = state.memory.permissions(value)
if state.se.eval(rwx) & 2 == 2: # is +W (2nd bit) set?
data['writable'] = True
else:
data['writable'] = False
except Exception, e: # page does not exist at given address
data['writable'] = False # not writable at all
try:
# special case when a stack address is in the next page (-W)
if value & 0x07ffffffffff0000 == 0x07ffffffffff0000:
rwx = state.memory.permissions(value-0x4000)
# give it a second change
if state.se.eval(rwx) & 2 == 2:
data['writable'] = True
except Exception, e: # or angr.errors.SimMemoryError
pass
# -----------------------------------------------------------------
else: # register doesn't get a concrete value
# register gets an expression. Check for simple register modifications:
# "<reg> <op>= <const>" (we can easily scale this to <reg> <op>= <reg>)
# Note that modified register should be the same with action.offset
node = [leaf for leaf in action.data.recursive_leaf_asts]
# we need an AST with depth 2, 2 leaves and 1 variable (i.e., register)
if action.data.depth == 2 and len(action.data.variables) == 1 and len(node) == 2:
try:
data['op'] = { # cast operator
'__add__' : '+',
'__sub__' : '-',
'__mul__' : '*',
'__div__' : '/',
'__and__' : '&',
'__or__' : '|',
'__xor__' : '^',
'__invert__' : '~',
'__lshift__' : '<<',
'__rshift__' : '>>'
}[ action.data.op ]
# if constant is on the left, swap sides
if node[0].op == 'BVV' and node[0].concrete:
node[0], node[1] = node[1], node[0]
# check if we're in the form: <reg> <op> <const>
if node[0].op == 'BVS' and self.__symreg[node[0]] == reg and \
node[1].op == 'BVV' and node[1].concrete:
data['type'] = 'mod'
data['const'] = state.se.eval(node[1])
else: # not in the right form
continue
except KeyError: # __symreg() threw an exception
continue
# -----------------------------------------------------------------------
# Consider the following case:
# .text:000000000040BA49 mov eax, [rbp+tfd]
# .text:000000000040BA52 mov edi, eax ; fd
#
# Here, edi gets exactly the same value with eax, but edi is marked as
# 'clob', while eax as 'deref'. The root cause is that edi does not
# participate in any memory reads and the assigned value is not constant
# (i.e., it doesn't come directly from a register).
#
# To fix that we check whether a 'clob' register has *exactly* the same
# symbolic value with another one (eax in our example), and if so we
# assign the same regwr entry to it.
# -----------------------------------------------------------------------
else:
# iterate over previous writes
for reg2, val in self.__reg_rawval.iteritems():
try:
# check if raw values match
if reg != reg2 and val.shallow_repr() == action.data.shallow_repr():
self.regwr[ reg ] = self.regwr[ reg2 ]
pass
except KeyError:
pass
# -----------------------------------------------------------------
if data:
self.regwr[ reg ] = data # set data to this register
# ---------------------------------------------------------------------------------------------
# __mem_r(): Analyze the memory reads of the symbolic execution.
#
# :Arg state: Program's state after symbolic execution
# :Ret: None.
#
def __mem_r( self, state ):
for action in state.actions: # for every action
if not (action.type == 'mem' and action.action == 'read'):
continue # we care about memory reads only
# simply add address (can be an expression) and size to the list
self.memrd.add( (action.addr, len(action.data)) )
# ---------------------------------------------------------------------------------------------
# __mem_w(): Analyze the memory writes of the symbolic execution.
#
# :Arg state: Program's state after symbolic execution
# :Ret: None.
#
def __mem_w( self, state ):
for action in state.actions: # for every action
if not (action.type == 'mem' and action.action == 'write'):
continue # we care about memory writes only
# simply add address (can be an expression) and data to the list
self.memwr.add( (action.addr, action.data) )
if action.addr.concrete: # if address is concrete
# concretize it as well
self.conwr.add( (state.se.eval(action.addr), len(action.data)) )
deps = [ ]
symtab = { }
# -----------------------------------------------------------------
# Check for memory register writes (mov [rax], rbx)
#
# In this case, both action.addr and action.data will consist of a
# single leaf in their ast which is a register
# -----------------------------------------------------------------
mem_reg = [leaf for leaf in action.addr.recursive_leaf_asts]
val_reg = [leaf for leaf in action.data.recursive_leaf_asts]
# print 'ADDR', mem_reg, action.addr
# print 'ADDR', val_reg, action.addr
# check AST have a single leaf
if len(mem_reg) == 1 and len(val_reg) == 1:
mem, val = None, None
# check whether the leaf is a register
for sym, nam in self.__symreg.iteritems():
# skip registers that are not symbolic (e.g., rbp)
if isinstance(sym.args[0], str) and sym.args[0] in mem_reg[0].shallow_repr():
symtab[nam] = sym
mem = nam
elif isinstance(sym.args[0], str) and sym.args[0] in val_reg[0].shallow_repr():
symtab[nam] = sym
val = nam
# if both leaves are registers we have a memory register write!
if mem and val:
self.splmemwr.append({
'mem' : mem,
'val' : val,
'size' : int(action.size) >> 3,
'sym' : symtab,
})
# ---------------------------------------------------------------------------------------------
# __call(): Analyze the (sys|lib)calls of the symbolic execution. Because we're analyzing a
# single basic block, we can have up to one such (sys|lib)call (the last instruction).
#
# :Arg state: Program's state after symbolic execution
# :Ret: None.
#
def __call( self, state ):
blk = self.__proj.factory.block(self.__entry)
# check if symbolic execution stopped on a syscall
# (don't use "if self.__proj._simos.is_syscall_addr(state.addr)"; it throws exceptions)
if blk.vex.jumpkind == "Ijk_Sys_syscall":
# a system call was invoked
# we assume that simproc.cc == SimCCAMD64LinuxSyscall
simproc = self.__proj._simos.syscall(state)
self.call['type'] = 'syscall'
self.call['name'] = simproc.display_name
# self.call['nargs'] = simproc.num_args
else:
if blk.vex.jumpkind != "Ijk_Call": # skip block when it doesn't end with a call
return
# check if symbolic execution stopped on a library call
for action in reversed(state.actions): # for every action
if action.type != 'exit':
continue # we care about branches only
# concretize function's entry point
target = state.se.eval(action.target)
# Note: Before you use kb.functions, calculate CFG (e.g., analyses.CFGFast())
try:
self.call['type'] = 'libcall'
self.call['name'] = self.__proj.kb.functions[target].name
except Exception: # no function name at that address
self.call = { }
# ---------------------------------------------------------------------------------------------
# __cond(): Analyze the conditional jump of the symbolic execution. Because we're analyzing a
# single basic block, we can have up to one conditional jump.
#
# :Arg state: Program's state after symbolic execution
# :Ret: None.
#
def __cond( self, state ):
for action in reversed(state.actions): # for every action
if not (action.type == 'exit' and action.exit_type == 'conditional'):
continue # we care about conditional jumps only
# as in __reg_w(), we only care about simple conditional jumps: "<reg> <op> <const>"
if len(action.condition.variables) == 1:
try:
self.cond['op'] = { # cast operator
'__eq__' : '==',
'__ne__' : '!=',
'__le__' : '<=',
'__lt__' : '<',
'__ge__' : '>=',
'__gt__' : '>',
'SGT' : '>',
'SGE' : '>=',
'SLT' : '<',
'SLE' : '<=',
'UGT' : '>', # do not distinguish signed/unsigned operators
'UGE' : '>=',
'ULT' : '<',
'ULE' : '<=',
}[ action.condition.op ]
except KeyError:
warn('Unknown conditional jump operator "%s"' % action.condition.op)
self.cond = { }
return
node = [leaf for leaf in action.condition.recursive_leaf_asts]
# -----------------------------------------------------------------------
# Check if we're in the simple form: <reg> <op> <const>
# -----------------------------------------------------------------------
if len(node) == 2: # we need 2 leaves + 1 operator
self.cond['form'] = 'simple' # we're in the simple form
try:
# swap register and constant if needed
if node[1].op == 'BVS' and node[0].op == 'BVV' and node[0].concrete:
node[0], node[1] = node[1], node[0]
# if we're in the right form (reg and const), we have our condition
if node[0].op == 'BVS' and node[1].op == 'BVV' and node[1].concrete:
self.cond['reg'] = self.__symreg[node[0]]
self.cond['const'] = state.se.eval(node[1])
else:
self.cond = { } # not in the right form
return
except KeyError:
# if not in the right form, __symreg() will throw a KeyError exception
self.cond = { }
return
# -----------------------------------------------------------------------
# Check if we're in the extended form: (<reg> <op> <const>) <op> <const>
# (example: "<SAO <Bool (rbx_1_64 + 0x1) == 0x8>>")
#
# This is when the iterator (register) gets modified and compared at the
# same basic block.
# -----------------------------------------------------------------------
elif len(node) == 3: # we need 3 leaves and 2 operators
self.cond['form'] = 'extended' # we're in the extended form
try:
# get left and right side of the comparison
left, right = action.condition.split( action.condition.op )
# if the constant is on the left side, swap sides
if left.op == 'BVV' and left.concrete:
left, right = right, left
mod_ops = { # register modification operations
'__add__' : '+',
'__sub__' : '-',
'__mul__' : '*',
'__div__' : '/',
'__and__' : '&',
'__or__' : '|',
'__xor__' : '^',
'__invert__' : '~',
'__lshift__' : '<<',
'__rshift__' : '>>'
}
# if the left side is a modification and the right side a constant
if left.op in mod_ops and right.op == 'BVV' and right.concrete:
self.cond['const'] = state.se.eval(right)
self.cond['mod_op'] = mod_ops[ left.op ]
reg, const = left.split( left.op )
# if the constant is on the left side, swap sides
if reg.op == 'BVV' and reg.concrete:
reg, const = const, reg
# if the modification uses a constant and a register
if reg.op == 'BVS' and reg in self.__symreg and \
const.op == 'BVV' and const.concrete:
self.cond['reg'] = self.__symreg[reg]
self.cond['mod_const'] = state.se.eval(const)
else:
self.cond = { } # something is not in the right form
return
else:
self.cond = { }
return
except ValueError: # != 2 values to split()
self.cond = { }
return
# -----------------------------------------------------------------------
# Otherwise we're not in the right form
# -----------------------------------------------------------------------
else:
self.cond = { }
continue
# The problem here, is that simgr sometimes "inverts" the condition, so the
# "target" basic block is the block immediately after the current block. To
# be consistent, we have to "invert" the operator, so the target basic block
# is executed when the jump is taken.
blk = self.__proj.factory.block(self.__entry)
# check if the target is the next block (assume action.target is concrete)
if state.se.eval(action.target) == blk.addr + blk.size:
self.cond['op'] = { # invert the condition
'==' : '!=',
'!=' : '==',
'>' : '<=',
'>=' : '<',
'<' : '>=',
'<=' : '>'
}[ self.cond['op'] ]
break # there's up to 1 conditional jump
# ---------------------------------------------------------------------------------------------
# __add_sym_vars(): This function extracts all (memory) symbolic variables from an expression.
# For instance, given the expression: <BV64 mem_7fffffffffef1e8_82_64 + 0x68>, we want to
# map the variable 'mem_7fffffffffef1e8_82_64' to its actual address: 0x7fffffffffef1e8.
#
# :Arg addr_expr: The address expression to get variables from
# :Ret: None.
#
def __add_sym_vars( self, addr_expr ):
# A memory symbolic variable is in the form: mem_ADDRESS_RANDOM_SIZE. The AST leaf
# will be like this: "<BV64 mem_7ffffffffff13e8_4928_64{UNINITIALIZED}>"
#
# We want to extract the ADDRESS and SIZE fields
for leaf in addr_expr.recursive_leaf_asts: # for each leaf in the AST
leafstr = leaf.shallow_repr() # cast it to sting
# if leaf is a memory variable, extract its address and its size
if re.search(r'mem_[0-9a-f]+_[0-9]+_[0-9]+', leafstr):
_, addr, rand, size = leafstr.split('_')
# size might be followed by the "{UNINITIALIZED}" keyword, so it must be dropped
# if not the ">" must also be dropped
size = size.replace("{UNINITIALIZED}>", "").replace(">", "")
# add the symbolic variable to the map
self.symvars[ leaf ] = (int(addr, 16), int(size, 10) >> 3)
# ---------------------------------------------------------------------------------------------
# __memread_callback(): This function is invoked every time that a memory read operation is
# performed.
#
# :Arg state: Current state to read memory from
# :Ret: None.
#
def __memread_callback( self, state ):
if self.__callback_mutex == 1: # if mutex is taken, return
return
self.__callback_mutex = 1 # get lock
# ---------------------------------------------------------------------
# If address is part of the .bss/.data, it will be initialized with a
# default value of 0. However, it can get any value (due to AWP) so it
# should get a symbolic value.
# ---------------------------------------------------------------------
# get ELF sections that give default values to their uninitialized variables
bss = self.__proj.loader.main_object.sections_map[".bss"]
data = self.__proj.loader.main_object.sections_map[".data"]
addr = state.se.eval(state.inspect.mem_read_address)
# print '=== READ', hex(state.inspect.instruction), hex(addr)
# check if address is inside .bss or .data sections
if bss.min_addr <= addr and addr <= bss.max_addr or \
data.min_addr <= addr and addr <= data.max_addr:
# This is also works, but is for Big Endian:
# state.memory.make_symbolic('mem', state.inspect.mem_read_address, length)
# make address symbolic
symv = state.se.BVS("mem_%x" % addr, state.inspect.mem_read_length << 3)
state.memory.store(state.inspect.mem_read_address, symv,
state.inspect.mem_read_length, endness=archinfo.Endness.LE)
# we should read it to update state.inspect.mem_read_expr
state.memory.load(state.inspect.mem_read_address,
state.inspect.mem_read_length, endness=archinfo.Endness.LE)
# -------------------------------------------------------------------------------
# Identifying dereferences is a two stage process. Here (1st step) we capture all
# memory load information (which happens before the register write) that happen
# at this instruction (x64 has 1 distinct memory read per insruction; however
# instructions like popad do multiple register writes, but this is not an issue
# here).
# -------------------------------------------------------------------------------
self.__load[ state.inspect.instruction ] = (
state.inspect.mem_read_address,
state.inspect.mem_read_length,
state.inspect.mem_read_expr # this will be updated
)
# associate memory expression with memory address (needed for later on)
self.__mem2addr[ state.inspect.mem_read_expr.shallow_repr() ] = \
(state.inspect.mem_read_address, state.inspect.mem_read_length)
# extract memory symbolic variables
self.__add_sym_vars( state.inspect.mem_read_address )
self.__callback_mutex = 0 # release lock
# ---------------------------------------------------------------------------------------------
# __regwrite_callback(): This function is invoked every time that a register write operation
# is performed.
#
# :Arg state: Current state to write register to
# :Ret: None.
#
def __regwrite_callback( self, state ):
if self.__callback_mutex == 1: # if mutex is taken, return
return
self.__callback_mutex = 1 # get lock
try:
# get register that is being written
reg = self.__proj.arch.register_names[state.inspect.reg_write_offset]
except KeyError: # just in case
return
# TODO: Regwrite only checks writes, but it doesn't check if the previous value perists after
# .text:000000000040BCEA mov eax, [rbp+ac]
# .text:000000000040BCF0 cdqe
# .text:000000000040BCF2 shl rax, 3
# .text:000000000040BCF6 mov rcx, rax
# .text:000000000040BCF9 add rcx, [rbp+nargv]
#
# ('sudo' example)
#
# We should add some checks to test whether the regwrite is "mov" or something else
# print '--------------- ', hex(state.addr), hex(state.inspect.instruction), reg,
# state.inspect.reg_write_expr
# remember the "raw" value that is being written to the register
self.__reg_rawval[ reg ] = state.inspect.reg_write_expr
if reg not in HARDWARE_REGISTERS: # we only care about specific registers
self.__callback_mutex = 0 # release lock
return
# -------------------------------------------------------------------------------
# This is the 2nd step of the dereference identification process. At this point
# we match the instruction that writes a register with the instruction that read
# from memory. This is because we want to match the memory read expression with
# the register write.
# -------------------------------------------------------------------------------
elif state.inspect.instruction in self.__load:
addr, length, _ = self.__load[ state.inspect.instruction ]
# ok we have a dereference!
deps = [ ] # dependent registers
symtab = { }
# find register dependencies on the address (e.g., rsi on <BV64 rsi_44_64 + 0x18>)
for sym, nam in self.__symreg.iteritems():
# skip registers that are not symbolic (e.g., rbp)
if isinstance(sym.args[0], str) and sym.args[0] in addr.shallow_repr():
deps.append(nam)
symtab[nam] = sym
# there might be dependencies with constant memory addresses as well (i.e., reading
# from global variables). Such dependencies are handled during trace searching, so
# we ignore them for now. However the register dependencies are needed to check
# whether a register mapping is valid or not.
# if "deps" has a single element, we know that a register is containted in "addr"
# expression. If also that expression has a single node, we know that this will be
# that register.
if len(deps) == 1 and len([leaf for leaf in addr.recursive_leaf_asts]) == 1:
memrd = length
else:
memrd = None
# (if basic block has >1 dereferences on the same register, use the most recent one)
self.regwr[ reg ] = { # set data
'type' : 'deref',
'addr' : addr,
'deps' : deps,
'sym' : symtab,
'memrd' : memrd
}
# -------------------------------------------------------------------------------
# The current approach for detecting dereferences is not transitive. Consider the
# following example:
# mov rcx, [rsi + 0x10]
# mov rdi, rcx
#
# In the 2nd register write, rdi gets an unconstrained symbolic variable (e.g.,
# <SAO <BV64 Reverse(symbolic_read_unconstrained_17_64)>>) and therefore it's of
# type 'clob'. However, we want rdi to be treated in the same way with rcx, as
# they both have the exact same value. Because SE engine gives a unique symbolic
# variable on every memory cell, we can associate them with their addresses.
# Thus, when a register gets a random symbolic value, we can figure out whether
# it is actually a dereference.
# -------------------------------------------------------------------------------
elif state.inspect.reg_write_expr.shallow_repr() in self.__mem2addr:
addr, length = self.__mem2addr[ state.inspect.reg_write_expr.shallow_repr() ]
# this code is copy-pasta from above
deps = [ ]
symtab = { }
for sym, nam in self.__symreg.iteritems():
if isinstance(sym.args[0], str) and sym.args[0] in addr.shallow_repr():
deps.append(nam)
symtab[nam] = sym
if len(deps) == 1 and len([leaf for leaf in addr.recursive_leaf_asts]) == 1:
memrd = length
else:
memrd = None
self.regwr[ reg ] = {
'type' : 'deref',
'addr' : addr,
'deps' : deps,
'sym' : symtab,
'memrd' : memrd
}
# -------------------------------------------------------------------------------
self.__callback_mutex = 0 # release lock
# ---------------------------------------------------------------------------------------------
# __sig_handler(): Symbolic execution may take forever to complete. To deal with it, we set
# an alarm. When the alarm is triggered, this singal handler is invoked and throws an
# exception that causes the symbolic execution to halt.
#
# :Arg signum: Signal number
# :Arg frame: Current stack frame
# :Ret: None.
#
def __sig_handler( self, signum, frame ):
if signum == signal.SIGALRM: # we only care about SIGALRM
# angr may ignore the exception, so let's throw many of them :P
raise Exception("Alarm triggered after %d seconds" % ABSBLK_TIMEOUT)
raise Exception("Alarm triggered after %d seconds" % ABSBLK_TIMEOUT)
raise Exception("Alarm triggered after %d seconds" % ABSBLK_TIMEOUT)
raise Exception("Alarm triggered after %d seconds" % ABSBLK_TIMEOUT)
# ---------------------------------------------------------------------------------------------
''' ======================================================================================= '''
''' CLASS INTERFACE '''
''' ======================================================================================= '''
# ---------------------------------------------------------------------------------------------
# __init__(): Class constructor. This function initializes the environment for the symbolic
# execution, it executes the basic block, and performs the abstraction.
#
# :Arg project: Instance of angr project
# :Arg addr: Entry point of the basic block
# :Ret: None.
#
def __init__( self, project, addr ):
self.__proj = project # we'll need these
self.__entry = addr
# ---------------------------------------------------------------------
# initialize abstraction variables
# ---------------------------------------------------------------------
self.regwr = { } # all register writes for that block
self.memrd = set() # all memory reads for that block
self.memwr = set() # all memory writes for that block
self.conwr = set() # all concrete memory writes for that block
self.splmemwr = [ ] # all memory register writes for that block
self.call = { } # function/system call (if any) for that block
self.cond = { } # conditional jumps (if any) for that block
self.symvars = { } # symbolic variables for memory
self.__load = { } # memory loads (for internal use)
self.__mem2addr = { } # map between memory expressions and addresses
self.__mem = { }
self.__reg_rawval = { }
# ---------------------------------------------------------------------
# Create a blank state and prepare it for symbolic execution.
#
# TODO: Check options again
# ---------------------------------------------------------------------
inist = self.__proj.factory.blank_state( # create a blank state
addr=addr, # set address
#mode='symbolic',
add_options={ # configure options
simuvex.o.AVOID_MULTIVALUED_READS,
simuvex.o.AVOID_MULTIVALUED_WRITES,
simuvex.o.NO_SYMBOLIC_JUMP_RESOLUTION,
simuvex.o.CGC_NO_SYMBOLIC_RECEIVE_LENGTH,
simuvex.o.NO_SYMBOLIC_SYSCALL_RESOLUTION,
simuvex.o.TRACK_ACTION_HISTORY,
# newly added option
simuvex.o.SYMBOLIC_INITIAL_VALUES
},
remove_options=simuvex.o.resilience_options | simuvex.o.simplification
)
# configure more options (add/remove)
inist.options.discard(simuvex.o.CGC_ZERO_FILL_UNCONSTRAINED_MEMORY)
inist.options.update( {
simuvex.o.TRACK_REGISTER_ACTIONS,
simuvex.o.TRACK_MEMORY_ACTIONS,
simuvex.o.TRACK_JMP_ACTIONS,
simuvex.o.TRACK_CONSTRAINT_ACTIONS }
)
# ---------------------------------------------------------------------
# initialize all registers with a symbolic variable
# ---------------------------------------------------------------------
inist.regs.rax = inist.se.BVS("rax", 64) # give convenient names
inist.regs.rbx = inist.se.BVS("rbx", 64)
inist.regs.rcx = inist.se.BVS("rcx", 64)
inist.regs.rdx = inist.se.BVS("rdx", 64)
inist.regs.rsi = inist.se.BVS("rsi", 64)
inist.regs.rdi = inist.se.BVS("rdi", 64)
# rbp may also needed as it's mostly used to access local variables (e.g.,
# rax = [rbp-0x40]) but some binaries don't use rbp and all references are
# rsp related. In these cases it may worth to use rbp as well.
if MAKE_RBP_SYMBOLIC:
inist.regs.rbp = inist.se.BVS("rbp",64) # keep rbp symbolic
else:
inist.registers.store('rbp', FRAMEPTR_BASE_ADDR, size=8, endness=archinfo.Endness.LE)
# rsp must be concrete and properly initialized
inist.registers.store('rsp', RSP_BASE_ADDR, size=8, endness=archinfo.Endness.LE)
inist.regs.r8 = inist.se.BVS("r08", 64)
inist.regs.r9 = inist.se.BVS("r09", 64)
inist.regs.r10 = inist.se.BVS("r10", 64)
inist.regs.r11 = inist.se.BVS("r11", 64)
inist.regs.r12 = inist.se.BVS("r12", 64)
inist.regs.r13 = inist.se.BVS("r13", 64)
inist.regs.r14 = inist.se.BVS("r14", 64)
inist.regs.r15 = inist.se.BVS("r15", 64)
# ---------------------------------------------------------------------
# Other initializations
# ---------------------------------------------------------------------
# map symbolic names to registers
# self.__symreg = { self.__getreg(inist, r):r for r in HARDWARE_REGISTERS }
self.__symreg = {
inist.regs.rax : 'rax',
inist.regs.rbx : 'rbx',
inist.regs.rcx : 'rcx',
inist.regs.rdx : 'rdx',
inist.regs.rsi : 'rsi',
inist.regs.rdi : 'rdi',
inist.regs.rbp : 'rbp',
inist.regs.rsp : 'rsp',
inist.regs.r8 : 'r8',
inist.regs.r9 : 'r9',
inist.regs.r10 : 'r10',
inist.regs.r11 : 'r11',
inist.regs.r12 : 'r12',
inist.regs.r13 : 'r13',
inist.regs.r14 : 'r14',
inist.regs.r15 : 'r15'
}
# UPDATE: Don't create a symbolic stack, as this consumes all the Virtual Memory and
# may crash the machine. By carefully configuring rsp and rbp within the limit of virtual
# page limit, we can achieve the same effect, so we don't need a symbolic stack.
#
# The main issue here are the permissions (stack may not appear as R+W), but as long as
# both rsp and rbp point in the same page, there is no problem.
#
#
# # create a symbolic stack (required to have writable pages)
# stack = inist.se.BVS("stack", self.__proj.arch.bits * _STACK_SZ)
#
# # write symbolic stack to memory
# # inist.memory.store(inist.regs.sp, stack, endness=archinfo.Endness.LE)
# inist.memory.store(STACK_BASE_ADDR, stack, endness=archinfo.Endness.LE)
# when solver gives up (in milliseconds)
inist.se._solver.timeout = ABSBLK_TIMEOUT*1000