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solve-vm-multiple-br.py
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solve-vm-multiple-br.py
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#!/usr/bin/env python2
## -*- coding: utf-8 -*-
##
## This file do the same thing that solve-vm.py but use a worklist for
## cover all paths.
##
## /!\ You have to use the dev-v0.6 of the libTriton.
##
from functools import wraps
from triton import *
from arybo.tools.triton_ import tritonexprs2arybo, tritonast2arybo
from arybo.lib.exprs_asm import to_llvm_function
from arybo.lib.mba_exprs import ExprCond
import ctypes
import errno
import lief
import os
import random
import signal
import string
import struct
import sys
import threading
import time
import argparse
# Used for nested vm
sys.setrecursionlimit(100000)
# Script options
DEBUG = False
TIMEOUT = float(120.0)
METRICS = True
OPAQUE = False
VM_INPUT = 1234
# Some constants
SYMBOLIZE = 0
CONCRETIZE = 1
# The debug function
def debug(s):
if DEBUG:
sys.stdout.flush()
print '%s %s\033[0m' %(threading.currentThread().getName(), s)
return
# This class is used to execute a binary with a seed and get constraints
# along this trace.
class Trace(object):
def __init__(self, path):
self.path = path
# The current seeds during the execution
self.seeds = [{}]
# During the trace it's possible that we need to generate new inputs
# at specific program points.
self.newInputs = list()
# Memory mapping
self.BASE_PLT = 0x10000000
self.BASE_ARGV = 0x20000000
self.BASE_ALLOC = 0x30000000
self.BASE_STACK = 0x9fffffff
self.BASE_LIBC = 0xa0000000
# Signal handlers used by raise() and signal()
self.sigHandlers = dict()
# File descriptors used by fopen() and fprintf()
self.fdHandlers = dict()
# Allocation information used by malloc()
self.mallocCurrentAllocation = 0
self.mallocMaxAllocation = 2048
self.mallocBase = self.BASE_ALLOC
self.mallocChunkSize = 0x00010000
# Total of instructions executed
self.totalInstructions = 0
self.totalUniqueInstructions = {}
# Total of functions simulated
self.totalFunctions = 0
# Time of execution
self.startTime = None
self.endTime = None
# Get a Triton context
self.ctx = TritonContext()
# Condition summaries
# When we make function summaries, we define some pre-conditions onto
# the current path constraint. It's a workaround for this tool. We should
# add this feature into the libTriton. (pop(), push() constraint (see #350))
self.preconditions = list()
# custom PLT
self.customRelocation = [
['__libc_start_main', self.libcMainHandler, None], # symbolic
['__errno_location', self.errnoHandler, None], # concrete
['atoi', self.atoiHandler, None], # symbolic
['calloc', self.callocHandler, None], # concrete
['fopen', self.fopenHandler, None], # concrete
['fprintf', self.fprintfHandler, None], # concrete
['free', self.freeHandler, None], # concrete
['malloc', self.mallocHandler, None], # concrete
['printf', self.printfHandler, None], # concrete
['putchar', self.putcharHandler, None], # concrete
['puts', self.putsHandler, None], # concrete
['raise', self.raiseHandler, None], # concrete
['rand', self.randHandler, None], # concrete
['signal', self.signalHandler, None], # concrete
['strcmp', self.strcmpHandler, None], # symbolic
['strcpy', self.strcpyHandler, None], # symbolic
['strlen', self.strlenHandler, None], # symbolic
['strncpy', self.strncpyHandler, None], # symbolic
['strtoul', self.strtoulHandler, None], # concrete
['strtoull', self.strtoulHandler, None], # concrete
]
return
def getMemoryString(self, addr):
s = str()
index = 0
while self.ctx.getConcreteMemoryValue(addr+index):
c = chr(self.ctx.getConcreteMemoryValue(addr+index))
#if c not in string.printable: c = ""
s += c
index += 1
return s
def getFormatString(self, addr):
return self.getMemoryString(addr) \
.replace("%s", "{}").replace("%d", "{:d}").replace("%#02x", "{:#02x}") \
.replace("%#x", "{:#x}").replace("%x", "{:x}").replace("%02X", "{:02x}") \
.replace("%c", "{:c}").replace("%02x", "{:02x}").replace("%ld", "{:d}") \
.replace("%*s", "").replace("%lX", "{:x}").replace("%08x", "{:08x}") \
.replace("%u", "{:d}").replace("%lu", "{:d}") \
# Return true if a memory cell is symbolized
def isMemoryCellSymbolized(self, ptr, size):
for index in range(size):
if self.ctx.isMemorySymbolized(ptr+index) == True:
return True
return False
# Simulate the rand() function
def randHandler(self):
debug('[+] rand hooked')
# Return value
return (CONCRETIZE, random.randrange(0xffffffff))
# Simulate the malloc() function
def mallocHandler(self):
debug('[+] malloc hooked')
# Get arguments
size = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi)
if size > self.mallocChunkSize:
debug('[+] malloc failed: size too big')
sys.exit(-1)
if self.mallocCurrentAllocation >= self.mallocMaxAllocation:
debug('[+] malloc failed: too many allocations done')
sys.exit(-1)
area = self.mallocBase + (self.mallocCurrentAllocation * self.mallocChunkSize)
self.mallocCurrentAllocation += 1
# Return value
return (CONCRETIZE, area)
# Simulate the calloc() function
def callocHandler(self):
debug('[+] malloc hooked')
# Get arguments
nmemb = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi)
size = self.ctx.getConcreteRegisterValue(self.ctx.registers.rsi)
# Total size
size = nmemb * size
if size > self.mallocChunkSize:
slef.debug('[+] malloc failed: size too big')
sys.exit(-1)
if self.mallocCurrentAllocation >= self.mallocMaxAllocation:
debug('[+] malloc failed: too many allocations done')
sys.exit(-1)
area = self.mallocBase + (self.mallocCurrentAllocation * self.mallocChunkSize)
self.mallocCurrentAllocation += 1
# Return value
return (CONCRETIZE, area)
# Simulate the signal() function
def signalHandler(self):
debug('[+] signal hooked')
# Get arguments
signal = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi)
handler = self.ctx.getConcreteRegisterValue(self.ctx.registers.rsi)
self.sigHandlers.update({signal: handler})
# Return value (void)
return (CONCRETIZE, self.ctx.getConcreteRegisterValue(self.ctx.registers.rax))
# Simulate the raise() function
def raiseHandler(self):
debug('[+] raise hooked')
# Get arguments
signal = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi)
try:
# FIXME: Add classical handler (SIGHUP, SIGINT, ...)
handler = self.sigHandlers[signal]
self.ctx.processing(Instruction("\x6A\x00")) # push 0
self.emulate(handler)
except:
pass
# Return value
return (CONCRETIZE, 0)
# Simulate the strcmp() function
def strcmpHandler(self):
debug('[+] strcmp hooked')
s1 = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi)
s2 = self.ctx.getConcreteRegisterValue(self.ctx.registers.rsi)
maxlen = max(len(self.getMemoryString(s1)), len(self.getMemoryString(s2)))
ast = self.ctx.getAstContext()
res = ast.bv(0, 64)
for index in range(maxlen):
cells1 = self.ctx.buildSymbolicMemory(MemoryAccess(s1+index, 1))
cells2 = self.ctx.buildSymbolicMemory(MemoryAccess(s2+index, 1))
res = res + ast.ite(cells1 == cells2, ast.bv(0, 64), ast.bv(1, 64))
# create a new symbolic expression for this summary
expr = self.ctx.newSymbolicExpression(res, "strcmp summary")
return (SYMBOLIZE, expr)
# Simulate the strcpy() function
def strcpyHandler(self):
debug('[+] strcpy hooked')
dst = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi)
src = self.ctx.getConcreteRegisterValue(self.ctx.registers.rsi)
for index in range(len(self.getMemoryString(src))):
dmem = MemoryAccess(dst + index, 1)
smem = MemoryAccess(src + index, 1)
cell = self.ctx.buildSymbolicMemory(smem)
expr = self.ctx.newSymbolicExpression(cell, "strcpy byte")
self.ctx.assignSymbolicExpressionToMemory(expr, dmem)
self.ctx.setConcreteMemoryValue(dmem, cell.evaluate())
return (CONCRETIZE, dst)
# Simulate the strncpy() function
def strncpyHandler(self):
debug('[+] strncpy hooked')
dst = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi)
src = self.ctx.getConcreteRegisterValue(self.ctx.registers.rsi)
cnt = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdx)
for index in range(cnt):
dmem = MemoryAccess(dst + index, 1)
smem = MemoryAccess(src + index, 1)
cell = self.ctx.buildSymbolicMemory(smem)
expr = self.ctx.newSymbolicExpression(cell, "strncpy byte")
self.ctx.assignSymbolicExpressionToMemory(expr, dmem)
self.ctx.setConcreteMemoryValue(dmem, cell.evaluate())
return (CONCRETIZE, dst)
# Simulate the strtoul() function
def strtoulHandler(self):
debug('[+] strtoul hooked')
# Get arguments
nptr = self.getMemoryString(self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi))
endptr = self.ctx.getConcreteRegisterValue(self.ctx.registers.rsi)
base = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdx)
# Return value
return (CONCRETIZE, long(nptr, base))
# Simulate the strlen() function
def strlenHandler(self):
debug('[+] strlen hooked')
# Get arguments
s = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi)
ast = self.ctx.getAstContext()
def rec(res, s, deep, maxdeep):
if deep == maxdeep:
return res
cell = self.ctx.buildSymbolicMemory(MemoryAccess(s + deep, 1))
res = ast.ite(cell == 0x00, ast.bv(deep, 64), rec(res, s, deep+1, maxdeep))
return res
sze = len(self.getMemoryString(s))
res = ast.bv(sze, 64)
res = rec(res, s, 0, sze)
# create a new symbolic expression for this summary
expr = self.ctx.newSymbolicExpression(res, "strlen summary")
return (SYMBOLIZE, expr)
# Simulate the atoi() function
def atoiHandler(self):
debug('[+] atoi hooked')
res = self.ctx.getAstContext().bv(0, 32)
rdi = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi)
while self.ctx.getConcreteMemoryValue(rdi):
# input
cell = self.ctx.buildSymbolicMemory(MemoryAccess(rdi, 1))
# pre condition for ascii numbers
self.preconditions.append(self.ctx.getAstContext().land([cell >= 0x30, cell <= 0x39]))
# atoi semantics
cell = self.ctx.getAstContext().zx(24, cell)
res = ((res * 10) + cell - 0x30)
# inc buffer
rdi += 1
res = self.ctx.getAstContext().sx(32, res)
# create a new symbolic expression for this summary
expr = self.ctx.newSymbolicExpression(res, "atoi summary")
return (SYMBOLIZE, expr)
# Simulate the printf() function
def printfHandler(self):
debug('[+] printf hooked')
# Get arguments
arg1 = self.getFormatString(self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi))
arg2 = self.ctx.getConcreteRegisterValue(self.ctx.registers.rsi)
arg3 = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdx)
arg4 = self.ctx.getConcreteRegisterValue(self.ctx.registers.rcx)
arg5 = self.ctx.getConcreteRegisterValue(self.ctx.registers.r8)
arg6 = self.ctx.getConcreteRegisterValue(self.ctx.registers.r9)
nbArgs = arg1.count("{")
args = [arg2, arg3, arg4, arg5, arg6][:nbArgs]
s = arg1.format(*args)
if DEBUG:
sys.stdout.write(s)
sys.stdout.flush()
# Return value
return (CONCRETIZE, len(s))
# Simulate the putchar() function
def putcharHandler(self):
debug('[+] putchar hooked')
# Get arguments
arg1 = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi)
sys.stdout.write(chr(arg1) + '\n')
sys.stdout.flush()
# Return value
return (CONCRETIZE, 2)
# Simulate the puts() function
def putsHandler(self):
debug('[+] puts hooked')
# Get arguments
arg1 = self.getMemoryString(self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi))
sys.stdout.write(arg1 + '\n')
sys.stdout.flush()
# Return value
return (CONCRETIZE, len(arg1) + 1)
# Simulate the printf() function
def fprintfHandler(self):
debug('[+] fprintf hooked')
# Get arguments
arg1 = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi)
arg2 = self.getFormatString(self.ctx.getConcreteRegisterValue(self.ctx.registers.rsi))
arg3 = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdx)
arg4 = self.ctx.getConcreteRegisterValue(self.ctx.registers.rcx)
arg5 = self.ctx.getConcreteRegisterValue(self.ctx.registers.r8)
arg6 = self.ctx.getConcreteRegisterValue(self.ctx.registers.r9)
nbArgs = arg2.count("{")
args = [arg3, arg4, arg5, arg6][:nbArgs]
s = arg2.format(*args)
self.fdHandlers[arg1].write(s)
# Return value
return (CONCRETIZE, len(s))
# Simulate the free() function (skip this behavior)
def freeHandler(self):
debug('[+] free hooked')
return None
# Simulate the fopen() function
def fopenHandler(self):
debug('[+] fopen hooked')
# Get arguments
arg1 = self.getFormatString(self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi))
arg2 = self.getFormatString(self.ctx.getConcreteRegisterValue(self.ctx.registers.rsi))
fd = open(arg1, arg2)
idf = len(self.fdHandlers) + 3 # 3 because 0, 1, 2 are already reserved.
self.fdHandlers.update({idf : fd})
# Return value
return (CONCRETIZE, idf)
def libcMainHandler(self):
debug('[+] __libc_start_main hooked')
# Get arguments
main = self.ctx.getConcreteRegisterValue(self.ctx.registers.rdi)
# Push the return value to jump into the main() function
self.ctx.concretizeRegister(self.ctx.registers.rsp)
self.ctx.setConcreteRegisterValue(self.ctx.registers.rsp, self.ctx.getConcreteRegisterValue(self.ctx.registers.rsp)-CPUSIZE.QWORD)
ret2main = MemoryAccess(self.ctx.getConcreteRegisterValue(self.ctx.registers.rsp), CPUSIZE.QWORD)
self.ctx.concretizeMemory(ret2main)
self.ctx.setConcreteMemoryValue(ret2main, main)
# Setup argc / argv
self.ctx.concretizeRegister(self.ctx.registers.rdi)
self.ctx.concretizeRegister(self.ctx.registers.rsi)
argvs = [
self.path, # argv[0]
str(VM_INPUT), # argv[1]
]
# Define argc / argv
base = self.BASE_ARGV
addrs = list()
index = 0
for argv in argvs:
addrs.append(base)
self.ctx.setConcreteMemoryAreaValue(base, argv+'\x00')
base += len(argv)+1
debug('[+] argv[%d] = %s' %(index, argv))
index += 1
argc = len(argvs)
argv = base
for addr in addrs:
self.ctx.setConcreteMemoryValue(MemoryAccess(base, CPUSIZE.QWORD), addr)
base += CPUSIZE.QWORD
self.ctx.setConcreteRegisterValue(self.ctx.registers.rdi, argc)
self.ctx.setConcreteRegisterValue(self.ctx.registers.rsi, argv)
return (CONCRETIZE, 0)
def errnoHandler(self):
debug('[+] __errno_location hooked')
errno = 0xdeadbeaf
self.ctx.setConcreteMemoryValue(MemoryAccess(errno, CPUSIZE.QWORD), 0)
return (CONCRETIZE, errno)
def hookingHandler(self):
pc = self.ctx.getConcreteRegisterValue(self.ctx.registers.rip)
for rel in self.customRelocation:
if rel[2] == pc:
# Emulate the routine and the return value
ret_value = rel[1]()
if ret_value is not None:
if ret_value[0] == CONCRETIZE:
self.ctx.concretizeRegister(self.ctx.registers.rax)
self.ctx.setConcreteRegisterValue(self.ctx.registers.rax, ret_value[1])
elif ret_value[0] == SYMBOLIZE:
self.ctx.setConcreteRegisterValue(self.ctx.registers.rax, ret_value[1].getAst().evaluate())
self.ctx.assignSymbolicExpressionToRegister(ret_value[1], self.ctx.registers.rax)
# Used for metric
self.totalFunctions += 1
# tigress user input
if rel[0] == 'strtoul':
debug('[+] Symbolizing the strtoul return')
var = self.ctx.symbolizeRegister(self.ctx.registers.rax)
self.ctx.setConcreteVariableValue(var, VM_INPUT)
# tigress user input
if rel[0] == 'printf':
debug('[+] Slicing end-point user expression')
return False
# Get the return address
ret_addr = self.ctx.getConcreteMemoryValue(MemoryAccess(self.ctx.getConcreteRegisterValue(self.ctx.registers.rsp), CPUSIZE.QWORD))
# Hijack RIP to skip the call
self.ctx.concretizeRegister(self.ctx.registers.rip)
self.ctx.setConcreteRegisterValue(self.ctx.registers.rip, ret_addr)
# Restore RSP (simulate the ret)
self.ctx.concretizeRegister(self.ctx.registers.rsp)
self.ctx.setConcreteRegisterValue(self.ctx.registers.rsp, self.ctx.getConcreteRegisterValue(self.ctx.registers.rsp)+CPUSIZE.QWORD)
return True
# Generate new models when a LEA is symbolic
def symbolicLea(self, lea):
pc = self.ctx.getPathConstraintsAst()
ast = self.ctx.getAstContext()
crst = ast.land([pc == pc, lea != lea.evaluate()])
models = self.ctx.getModels(crst, 255)
for model in models:
seed = list()
argc = self.ctx.getSymbolicVariable(0)
seed.append({
'comment': argc.getComment(),
'id': argc.getId(),
'memory address': argc.getOrigin(),
'model result': self.ctx.getConcreteVariableValue(argc),
'name': argc.getName(),
'src': None,
'dst': None,
})
for k,v in model.items():
# Get the symbolic variable assigned to the model
symVar = self.ctx.getSymbolicVariable(k)
# Save the new input as seed.
seed.append({
'comment': symVar.getComment(),
'id': symVar.getId(),
'memory address': symVar.getOrigin(),
'model result': v.getValue(),
'name': symVar.getName(),
'src': None,
'dst': None,
})
self.newInputs.append(seed)
return
# Emulate the binary.
def emulate(self, pc):
count = 0
while pc:
# Fetch opcodes
opcodes = self.ctx.getConcreteMemoryAreaValue(pc, 16)
# Create the Triton instruction
instruction = Instruction()
instruction.setOpcode(opcodes)
instruction.setAddress(pc)
# Process
if self.ctx.processing(instruction) == False:
debug('[-] Instruction not supported: %s' %(str(instruction)))
break
count += 1
#print instruction
for op in instruction.getOperands():
if op.getType() == OPERAND.MEM:
lea = op.getLeaAst()
if lea is not None and lea.isSymbolized():
self.symbolicLea(lea)
if pc in self.totalUniqueInstructions:
self.totalUniqueInstructions[pc] += 1
else:
self.totalUniqueInstructions[pc] = 1
# Simulate routines
if not self.hookingHandler():
break
# Next
pc = self.ctx.getConcreteRegisterValue(self.ctx.registers.rip)
# Used for metric
self.totalInstructions += count
return
def loadBinary(self, binary):
# Map the binary into the memory
phdrs = binary.segments
for phdr in phdrs:
size = phdr.physical_size
vaddr = phdr.virtual_address
debug('[+] Loading 0x%06x - 0x%06x' %(vaddr, vaddr+size))
self.ctx.setConcreteMemoryAreaValue(vaddr, phdr.content)
return
def makeDynamicRelocation(self, binary):
# Initialize PLT
for index in range(len(self.customRelocation)):
self.customRelocation[index][2] = self.BASE_PLT + index
# Perform our own relocations
try:
for rel in binary.pltgot_relocations:
symbolName = rel.symbol.name
symbolRelo = rel.address
for crel in self.customRelocation:
if symbolName == crel[0]:
debug('[+] Hooking %s' %(symbolName))
self.ctx.setConcreteMemoryValue(MemoryAccess(symbolRelo, CPUSIZE.QWORD), crel[2])
except:
pass
# Perform our own relocations
try:
for rel in binary.dynamic_relocations:
symbolName = rel.symbol.name
symbolRelo = rel.address
for crel in self.customRelocation:
if symbolName == crel[0]:
debug('[+] Hooking %s' %(symbolName))
self.ctx.setConcreteMemoryValue(MemoryAccess(symbolRelo, CPUSIZE.QWORD), crel[2])
except:
pass
return
def makeStaticRelocation(self, binary):
for rel in self.customRelocation:
try:
rel[2] = binary.get_symbol(rel[0]).value
debug('[+] Hooking %s at %#x' %(rel[0], rel[2]))
except:
rel[2] = None
return
def injectModels(self, api, mem):
dst = mem.getAddress()
sze = mem.getSize()
if sze > CPUSIZE.BYTE:
return
for seed in self.seeds:
if seed and dst == seed['memory address']:
self.ctx.setConcreteMemoryValue(mem, seed['model result'])
return
def run(self):
global VM_INPUT
# Set the architecture
self.ctx.setArchitecture(ARCH.X86_64)
# Set optimization
self.ctx.enableMode(MODE.ALIGNED_MEMORY, True)
self.ctx.enableMode(MODE.ONLY_ON_SYMBOLIZED, True)
# Callback to inject symbolic models
self.ctx.addCallback(self.injectModels, CALLBACK.GET_CONCRETE_MEMORY_VALUE)
# AST representation as Python syntax
self.ctx.setAstRepresentationMode(AST_REPRESENTATION.PYTHON)
# Set seed
if self.seeds[0]:
VM_INPUT = self.seeds[0]['model result']
else:
VM_INPUT = 1234
# Parse the binary
lief.Logger.disable()
binary = lief.parse(self.path)
# Load the binary
self.loadBinary(binary)
# Perform our own relocations
#self.makeStaticRelocation(binary)
self.makeDynamicRelocation(binary)
# Define a fake stack
self.ctx.setConcreteRegisterValue(self.ctx.registers.rbp, self.BASE_STACK)
self.ctx.setConcreteRegisterValue(self.ctx.registers.rsp, self.BASE_STACK)
# Let's emulate the binary from the entry point
debug('[+] Starting emulation.')
self.startTime = time.clock()
self.emulate(binary.entrypoint)
self.endTime = time.clock()
debug('[+] Emulation done.')
debug('[+] Instructions executed: %d' %(self.totalInstructions))
debug('[+] Unique instructions executed: %d' %(len(self.totalUniqueInstructions)))
debug('[+] Symbolic conditions: %d' %(len(self.ctx.getPathConstraints())))
debug('[+] Time of execution: %f seconds' %(self.endTime - self.startTime))
debug('[+] Return value: %#x' %(self.ctx.getConcreteRegisterValue(self.ctx.registers.rax)))
return self.ctx.getConcreteRegisterValue(self.ctx.registers.rax)
# This class is used to represent a node of a tree execution (ite)
class IteTreeNode(object):
def __init__(self):
self.src = None # Address of the condition
self.dst = None # Dst of the condition
self.condition = None # Condition expression
self.taken = None # The taken branch
self.ntaken = None # The not taken branch
def __repr__(self):
return "(ite %s %s %s)" %(self.condition, self.taken, self.ntaken)
# This class is used to represent a node of a tree execution (ret expr)
class ExprTreeNode(object):
def __init__(self, e):
self.expr = e
def __repr__(self):
return str(self.expr)
# This class execute several Trace to explore the binary.
class PathsExploration(object):
STRATEGY_FIFO = 0b00000001
STRATEGY_LIFO = 0b00000010
STRATEGY_RAND = 0b00000100
def __init__(self, path):
self.path = path # binary path
self.wl = [[{}]] # work list
self.dl = [] # done list
self.bbcov = {} # list of basic block already covered
self.cstrts = [] # list of constraints already asked for a model
self.traces = [] # list of context for each tarce executed
self.numExec = 0 # number of executions
self.stop = False
self.ret = None
self.ts = time.clock()
self.strategy = None
return
# The worker thread.
def worker(self, seeds):
# Inc number of execution
self.numExec += 1
if TIMEOUT and (time.clock() - self.ts) >= TIMEOUT:
debug('[+] Time out.')
self.stop = True
return
# Execute the binary with seeds
trace = Trace(self.path)
trace.seeds = seeds
self.ret = trace.run()
# Save the context of the trace
self.traces.append(trace.ctx)
# Generate new inputs
debug('[+] Getting models, please wait...')
inputs = self.getNewInput(trace) + trace.newInputs
for m in inputs:
if m not in self.dl:
self.wl.append(m)
debug('[+] Time after solving: %f seconds' %(time.clock() - self.ts))
debug('[+] Work list size: %d' %(len(self.wl)))
debug('[+] Done list size: %d' %(len(self.dl)))
return
# Returns a seed based on a strategy
def pickSeed(self):
if self.strategy == PathsExploration.STRATEGY_LIFO:
return self.wl.pop()
elif self.strategy == PathsExploration.STRATEGY_FIFO:
return self.wl.pop(0)
elif self.strategy == PathsExploration.STRATEGY_RAND:
return self.wl.pop(random.randrange(0, len(self.wl)))
def explore(self):
while self.wl and not self.stop:
# Take seeds
seeds = self.pickSeed()
self.dl.append(seeds)
# Execution into a thread
t = threading.Thread(name='\033[0;%dm[exec:%d]' %((31 + (self.numExec % 4)), self.numExec), target=self.worker, args=[seeds])
t.start()
t.join()
return
def _deepMerge(self, ctx, pcs, node, ret):
if not len(pcs):
return
pc = pcs.pop(0)
for l in pc.getBranchConstraints():
if l['isTaken'] == True:
if not node.src:
node.condition = ctx.getAstContext().unrollAst(l['constraint'])
node.src = l['srcAddr']
node.dst = l['dstAddr']
if len(pcs):
if not node.taken:
node.taken = IteTreeNode()
self._deepMerge(ctx, pcs, node.taken, ret)
else:
if not node.taken:
node.taken = ExprTreeNode(ctx.getAstContext().unrollAst(ret))
elif node.src == l['srcAddr'] and node.dst != l['dstAddr']:
if len(pcs):
if not node.ntaken:
node.ntaken = IteTreeNode()
self._deepMerge(ctx, pcs, node.ntaken, ret)
else:
if not node.ntaken:
#node.ntaken = ExprTreeNode(ret)
node.ntaken = ExprTreeNode(ctx.getAstContext().unrollAst(ret))
elif node.src == l['srcAddr'] and node.dst == l['dstAddr']:
self._deepMerge(ctx, pcs, node.taken, ret)
else:
raise Exception('???')
def tracesMerging(self):
ret = self.traces[0].getSymbolicRegisters()[REG.X86_64.RSI].getAst() # RSI car printf
pcs = self.traces[0].getPathConstraints()
if not len(pcs):
node = ExprTreeNode(self.traces[0].getAstContext().unrollAst(ret))
return node
node = IteTreeNode()
for ctx in self.traces:
self._deepMerge(ctx, ctx.getPathConstraints(), node, ret)
return node
# This function returns a set of new inputs based on the last trace.
def getNewInput(self, trace):
# Set of new inputs
inputs = list()
# Get path constraints from the last execution
pco = trace.ctx.getPathConstraints()
# Get the astContext
astCtxt = trace.ctx.getAstContext()
# We start with any input. T (Top)
previousConstraints = astCtxt.equal(astCtxt.bvtrue(), astCtxt.bvtrue())
# Apply pre conditions defined during the trace
for i in trace.preconditions:
previousConstraints = astCtxt.land([previousConstraints, i])
# Go through the path constraints
for pc in pco:
# If there is a condition
if pc.isMultipleBranches():
# Get all branches
branches = pc.getBranchConstraints()
for branch in branches:
# Get the constraint of the branch which has not been taken.
if branch['isTaken'] == False:
# Check timeout
if TIMEOUT and (time.clock() - self.ts) >= TIMEOUT:
return inputs
# Create the constraint
cstrts = astCtxt.land([previousConstraints, branch['constraint']])
# Only ask for a model if the constraints has never been asked
if frozenset([str(cstrts), branch['dstAddr']]) not in self.cstrts:
models = trace.ctx.getModels(cstrts, 1)
for model in models:
#model = trace.ctx.getModel(cstrts)
seed = list()
for k, v in model.items():
# Get the symbolic variable assigned to the model
symVar = trace.ctx.getSymbolicVariable(k)
# Save the new input as seed.
seed.append({
'comment': symVar.getComment(),
'id': symVar.getId(),
'memory address': symVar.getOrigin(),
'model result': v.getValue(),
'name': symVar.getName(),
'src': branch['srcAddr'],
'dst': branch['dstAddr'],
})
if seed:
self.cstrts.append(frozenset([str(cstrts), branch['dstAddr']]))
self.bbcov.update({branch['dstAddr'] : True})
inputs.append(seed)
# Update the previous constraints with true branch to keep a good path.
previousConstraints = astCtxt.land([previousConstraints, pc.getTakenPathConstraintAst()])
return inputs
def get_all_filepaths(path, ext):
ret = list()
for root, dirs, files in os.walk(path):
for name in files:
if name.lower().endswith(ext):
ret.append(os.path.join(root, name))
return ret
def toTritonAst(ctx, node):
if isinstance(node, IteTreeNode):
b1 = toTritonAst(ctx, node.taken)
b2 = toTritonAst(ctx, node.ntaken)
sz = (b1.getBitvectorSize() if b1 else (b2.getBitvectorSize() if b2 else 0))
if not sz:
raise Exception('Invalid node')
b1 = (b1 if b1 else ctx.getAstContext().bv(0, sz))
b2 = (b2 if b2 else ctx.getAstContext().bv(0, sz))
return ctx.getAstContext().ite(node.condition, b1, b2)
elif isinstance(node, ExprTreeNode):
return node.expr
def toLLVMIR(ctx, node):
# strtoul
var0 = ctx.newSymbolicVariable(64)
# Used to get symvar names
tt_vars = set()