def visit_MLIL_LOAD_SSA(self, expr): src = self.visit(expr.src) if src is None: return memory = self._memory # we're assuming Little Endian for now if expr.size == 1: return memory[src] elif expr.size == 2: return Concat(memory[src+1], memory[src]) elif expr.size == 4: return Concat( memory[src+3], memory[src+2], memory[src+1], memory[src] ) elif expr.size == 8: return Concat( memory[src+7], memory[src+6], memory[src+5], memory[src+4], memory[src+3], memory[src+2], memory[src+1], memory[src] )
def mload(self, offset: BitVecNumRef): if isinstance(offset, BitVecNumRef): offset = offset.as_long() elif not isinstance(offset, int): raise DevelopmentErorr( 'Does not support memory operations indexed by symbol variables.' ) if offset + WORDBYTESIZE > len(self.__immediate_data): # ~ index out of bounds ~ # generate a symblolic variable newmemvar = self.__generateMemoryVar() d = offset + WORDBYTESIZE - len(self.__immediate_data) if d < WORDBYTESIZE: for i in range(d): self.__immediate_data.append( Extract((d - i - 1) * 8 + 7, (d - i - 1) * 8, newmemvar)) return simplify( Concat(self.__immediate_data[offset:WORDBYTESIZE + offset])) else: self.mstore(BitVecVal256(offset), newmemvar) return newmemvar else: return simplify( Concat(self.__immediate_data[offset:WORDBYTESIZE + offset]))
def right_one_extension(formula, bit_places): """Set the rest of bits on the right to 1. """ complement = BitVecVal(0, formula.size() - bit_places) - 1 formula = Concat( Extract(formula.size() - 1, formula.size() - bit_places, formula), complement) return formula
def is_byte_swap(self): try: self.model_variable() except ModelIsConstrained: return False # Figure out if this might be a byte swap byte_values_len = len(self.byte_values) #print self.byte_values if 1 < byte_values_len <= self.var.src.var.type.width: var = create_BitVec(self.var.src, self.var.src.var.type.width) ordering = list(reversed([ self.byte_values[x] for x in sorted(self.byte_values.keys()) ])) reverse_var = Concat( *reversed([ Extract(i-1, i-8, var) for i in range(len(ordering) * 8, 0, -8) ]) ) if len(ordering) < 4: reverse_var = Concat( Extract( 31, len(ordering)*8, var ), reverse_var ) reversed_ordering = reversed(ordering) reversed_ordering = Concat(*reversed_ordering) # The idea here is that if we add the negation of this, if it's # not satisfiable, then that means there is no value such that # the equivalence does not hold. If that is the case, then this # should be a byte-swapped value. self.solver.add( Not( And( var == ZeroExt( var.size() - len(ordering)*8, Concat(*ordering) ), reverse_var == ZeroExt( reverse_var.size() - reversed_ordering.size(), reversed_ordering ) ) ) ) if self.solver.check() == unsat: return True return False
def sign_extension(formula, bit_places): """Set the rest of bits on the left to the value of the sign bit. """ sign_bit = Extract(bit_places - 1, bit_places - 1, formula) complement = sign_bit for _ in range(formula.size() - bit_places - 1): complement = Concat(sign_bit, complement) formula = Concat(complement, (Extract(bit_places - 1, 0, formula))) return formula
def right_sign_extension(formula, bit_places): """Set the rest of bits on the right to the value of the sign bit. """ sign_bit_position = formula.size() - bit_places sign_bit = Extract(sign_bit_position, sign_bit_position, formula) complement = sign_bit for _ in range(sign_bit_position - 1): complement = Concat(sign_bit, complement) formula = Concat(Extract(formula.size() - 1, sign_bit_position, formula), complement) return formula
def zero_extension(formula, bit_places): """Set the rest of bits on the left to 0. """ complement = BitVecVal(0, formula.size() - bit_places) formula = Concat(complement, (Extract(bit_places - 1, 0, formula))) return formula
def test_instruction_semantics_call(self): # call #0xdead raw = b'\xb0\x12\xad\xde' ip = 0xc0de ins, _ = decode_instruction(ip, raw) state = blank_state() state.cpu.registers['R0'] = BitVecVal(ip + len(raw), 16) # ip preincrement state.cpu.registers['R1'] = BitVecVal(0x1234, 16) new_states = state.cpu.step_call(state, ins) self.assertEqual(len(new_states), 1) new_state = new_states[0] lo = new_state.memory[0x1232] hi = new_state.memory[0x1233] pushed_val = Concat(hi, lo) self.assertEqual(intval(pushed_val), ip + len(raw)) self.assertEqual(intval(new_state.cpu.registers['R1']), 0x1232) self.assertEqual(intval(new_state.cpu.registers['R0']), 0xdead)
def array_to_bv64(array): return Concat(Select(array, BitVecVal(7, 32)), Select(array, BitVecVal(6, 32)), Select(array, BitVecVal(5, 32)), Select(array, BitVecVal(4, 32)), Select(array, BitVecVal(3, 32)), Select(array, BitVecVal(2, 32)), Select(array, BitVecVal(1, 32)), Select(array, BitVecVal(0, 32)))
def set_region_bit(bv, p): i = region_names.index(REGIONS[p.y][p.x]) chunks = [] if i < bits - 1: chunks.append(Extract(bits - 1, i + 1, bv)) chunks.append(BitVecVal(1, 1)) if i > 0: chunks.append(Extract(i - 1, 0, bv)) return Concat(*chunks)
def identity(data: Union[bytes, str, List[int]]) -> bytes: # Group up into an array of 32 byte words instead # of an array of bytes. If saved to memory, 32 byte # words are currently needed, but a correct memory # implementation would be byte indexed for the most # part. return data result = [] for i in range(0, len(data), 32): result.append(simplify(Concat(data[i:i + 32]))) return result
def byte_(self, global_state): mstate = global_state.mstate op0, op1 = mstate.stack.pop(), mstate.stack.pop() try: index = util.get_concrete_int(op0) offset = (31 - index) * 8 result = Concat(BitVecVal(0, 248), Extract(offset + 7, offset, op1)) except AttributeError: logging.debug("BYTE: Unsupported symbolic byte offset") result = BitVec(str(simplify(op1)) + "_" + str(simplify(op0)), 256) mstate.stack.append(simplify(result)) return [global_state]
def byte_(self, global_state): mstate = global_state.mstate op0, op1 = mstate.stack.pop(), mstate.stack.pop() if not isinstance(op1, ExprRef): op1 = BitVecVal(op1, 256) try: index = util.get_concrete_int(op0) offset = (31 - index) * 8 if offset >= 0: result = simplify(Concat(BitVecVal(0, 248), Extract(offset + 7, offset, op1))) else: result = 0 except AttributeError: logging.debug("BYTE: Unsupported symbolic byte offset") result = BitVec(str(simplify(op1)) + "[" + str(simplify(op0)) + "]", 256) mstate.stack.append(result) return [global_state]
def test_instruction_semantics_push(self): # push #0xdead raw = b'\x30\x12\xad\xde' ip = 0x1234 ins, _ = decode_instruction(ip, raw) state = blank_state() state.cpu.registers['R1'] = BitVecVal(0x1234, 16) new_states = state.cpu.step_push(state, ins) self.assertEqual(len(new_states), 1) new_state = new_states[0] lo = new_state.memory[0x1232] hi = new_state.memory[0x1233] pushed_val = Concat(hi, lo) self.assertEqual(intval(pushed_val), 0xdead) self.assertEqual(intval(new_state.cpu.registers['R1']), 0x1232)
def __getitem__(self, item): if isinstance(item, slice): try: current_index = (item.start if isinstance( item.start, BitVecRef) else BitVecVal(item.start, 256)) dataparts = [] while simplify(current_index != item.stop): dataparts.append(self[current_index]) current_index = simplify(current_index + 1) except Z3Exception: raise IndexError("Invalid Calldata Slice") return simplify(Concat(dataparts)) if self.concrete: try: return self._calldata[get_concrete_int(item)] except IndexError: return BitVecVal(0, 8) else: return self._calldata[item]
def __getitem__(self, item: Union[int, slice]) -> Any: if isinstance(item, int) or isinstance(item, ExprRef): return self._load(item) if isinstance(item, slice): start = 0 if item.start is None else item.start step = 1 if item.step is None else item.step stop = self.size if item.stop is None else item.stop try: current_index = ( start if isinstance(start, BitVecRef) else BitVecVal(start, 256) ) parts = [] while simplify(current_index != stop): parts.append(self._load(current_index)) current_index = simplify(current_index + step) except Z3Exception: raise IndexError("Invalid Calldata Slice") return simplify(Concat(parts)) raise ValueError
def __getitem__(self, item: Union[int, slice]) -> Any: if isinstance(item, slice): start, step, stop = item.start, item.step, item.stop try: if start is None: start = 0 if step is None: step = 1 if stop is None: stop = self.calldatasize current_index = (start if isinstance(start, BitVecRef) else BitVecVal(start, 256)) dataparts = [] while simplify(current_index != stop): dataparts.append(self[current_index]) current_index = simplify(current_index + step) except Z3Exception: raise IndexError("Invalid Calldata Slice") values, constraints = zip(*dataparts) result_constraints = [] for c in constraints: result_constraints.extend(c) return simplify(Concat(values)), result_constraints if self.concrete: try: return self._calldata[get_concrete_int(item)], () except IndexError: return BitVecVal(0, 8), () else: constraints = [ Implies(self._calldata[item] != 0, UGT(self.calldatasize, item)) ] return self._calldata[item], constraints
def BVSignedUpCast(x, n_bits): assert x.size() <= n_bits if x.size() < n_bits: return Concat(If(x < 0, BitVecVal(-1, n_bits - x.size()), BitVecVal(0, n_bits - x.size())), x) else: return x
from pwn import * import itertools from z3 import BitVec, BitVecVal, Solver, If, simplify, Concat, Extract, And, Or, LShR, UDiv, sat, Int from ictf import iCTF from multiprocessing import Pool i = iCTF() team = i.login('*****@*****.**', 'HZBrKynG4XAMvWPa') BVV = BitVecVal BV = BitVec int128 = lambda x: Concat(BVV(0, 64), x) int64 = lambda x: Extract(63, 0, x) def weird_op(x): k = x - (1337331 * LShR(int64(LShR(0x0C8B98A756AA1D561 * int128(x), 64)), 20)) return int64(k) def choose_op(a1, a2, op): r = If(op == 0, a2 + a1, If(op == 1, a1 - a2, If(op == 2, a2 * a1, If(op == 3 and a2 != 0, UDiv(a1, a2), False ) ) )
def make_load(src, size): mem = Array('mem', BitVecSort(32), BitVecSort(8)) load_bytes = [mem[src + i] for i in range(0, size)] return Concat(*load_bytes)
s = Solver() flag = [BitVec(f'f{i}', 8) for i in range(16)] shuffle = bytes.fromhex('02060701050B090E030F04080A0C0D00') add32 = bytes.fromhex('EFBEADDEADDEE1FE3713371366746367') xor = bytes.fromhex('7658B4498D1A5F38D423F834EB86F9AA') expected_prefix = b'CTF{}'[:-1] for f, v in zip(flag, expected_prefix): s.add(f == v) dest = [flag[b] for b in shuffle] words = [] for i in range(0, len(dest), 4): words.append(Concat(dest[i + 3], dest[i + 2], dest[i + 1], dest[i])) for i in range(len(words)): words[i] += struct.unpack('<I', add32[i * 4:][:4])[0] for i in range(len(words)): j = i * 4 dest[j + 0] = Extract(7, 0, words[i]) dest[j + 1] = Extract(15, 8, words[i]) dest[j + 2] = Extract(23, 16, words[i]) dest[j + 3] = Extract(31, 24, words[i]) for i in range(len(dest)): dest[i] ^= xor[i] for i in range(len(flag)):
from opcodes import BYTE from rule import Rule from z3 import BitVec, BitVecVal, Concat, Extract """ Checks that the byte opcode (implemented using shift) is equivalent to a canonical definition of byte using extract. """ rule = Rule() n_bits = 256 x = BitVec('X', n_bits) for i in range(0, 32): # For Byte, i = 0 corresponds to most significant bit # But for extract i = 0 corresponds to the least significant bit lsb = 31 - i rule.check( BYTE(BitVecVal(i, n_bits), x), Concat(BitVecVal(0, n_bits - 8), Extract(8 * lsb + 7, 8 * lsb, x)))
def find_n_root_domains_ignoring_wildcards(solver: z3.Solver, symbols: Dict[int, List[str]], require_literal_dot_in_domain: bool, levels: int, max_finds: int): """If enough root domains are found, report vulnerability. :param levels: number of levels of domains to consider as part of the root domain. Either 2 or 3. If 3, the TLD needs to be a Country Code. :param max_finds: threshold number of root domains to find before considering as vulnerability. :return: tuple of sat result, witness or debug info """ from z3 import Not, And, Or, Xor, Contains, String, StringVal, Length, Implies, SuffixOf, Concat tld = String('tld') sld = String('sld') third_ld = String('3ld') DNS_root = String('DNS_root') dot_in_domain = Contains(root_domain, '.') domain_expr = z3.simplify(And( Or(DNS_root == StringVal('.'), DNS_root == StringVal('')), Xor(Concat(root_domain, DNS_root) == fqdn, And(SuffixOf(Concat(StringVal('.'), root_domain, DNS_root), fqdn), dot_in_domain)), Implies(dot_in_domain, And(Not(Contains(tld, '.')), Not(Contains(sld, '.')), Length(tld) > 0, root_domain == (Concat(sld, StringVal('.'), tld) if levels < 3 else Concat(third_ld, StringVal('.'), sld, StringVal('.'), tld)))), Implies(Not(dot_in_domain), And(Concat(root_domain, DNS_root) == fqdn, tld == StringVal(''), sld == StringVal(''),)), )) with solver_frame(solver): solver.add(domain_expr) solver.add(RegexStringExpr.ignore_wildcards) if require_literal_dot_in_domain or levels >= 3: solver.add(dot_in_domain) if levels >= 3: solver.add(z3.simplify(And( Not(Contains(third_ld, '.')), Length(sld) > 0, Length(third_ld) > 0, Or(*(tld == StringVal(ss) for ss in cc_tlds)), ))) results = [] found = set() found_root_domains = set() result = z3.sat logger.info('searching for n root_domains') _concs = lambda zs: concretizations(z3_str_to_bytes(zs), symbols) solution = None while len(found_root_domains) < max_finds and result == z3.sat: result = solver.check() results.append(result) if result == z3.sat: model = solver.model() _root_domain = model[root_domain] parts = (model[proto], model[proto_delimiter], model[fqdn]) assert all(part is not None for part in parts) logger.info(public_vars(model)) found.update(_concs(z3.simplify(z3.Concat(*parts)))) found_root_domains.update(_concs(_root_domain)) solver.add(root_domain != _root_domain) solution = tz.first(_concs(model[unknown_string])) # if not sat, return the would-be witness for debugging if result == z3.sat: root_domains_label = 'witness' else: root_domains_label = 'root_domains' return result, {'strategy': 'find_n_root_domains_ignoring_wildcards', 'found': list(found), root_domains_label: list(found_root_domains), 'levels': levels, 'solution': solution}
def to_smt(r): # type: (Rtl) -> Tuple[List[ExprRef], Z3VarMap] """ Encode a concrete primitive Rtl r sa z3 query. Returns a tuple (query, var_m) where: - query is a list of z3 expressions - var_m is a map from Vars v with non-BVType to their correspodning z3 bitvector variable. """ assert r.is_concrete() # Should contain only primitives primitives = set(PRIMITIVES.instructions) assert set(d.expr.inst for d in r.rtl).issubset(primitives) q = [] # type: List[ExprRef] m = {} # type: Z3VarMap # Build declarations for any bitvector Vars var_to_bv = {} # type: Z3VarMap for v in r.vars(): typ = v.get_typevar().singleton_type() if not isinstance(typ, BVType): continue var_to_bv[v] = BitVec(v.name, typ.bits) # Encode each instruction as a equality assertion for d in r.rtl: inst = d.expr.inst exp = None # type: ExprRef # For prim_to_bv/prim_from_bv just update var_m. No assertion needed if inst == prim_to_bv: assert isinstance(d.expr.args[0], Var) m[d.expr.args[0]] = var_to_bv[d.defs[0]] continue if inst == prim_from_bv: assert isinstance(d.expr.args[0], Var) m[d.defs[0]] = var_to_bv[d.expr.args[0]] continue if inst in [bvadd, bvult]: # Binary instructions assert len(d.expr.args) == 2 and len(d.defs) == 1 lhs = d.expr.args[0] rhs = d.expr.args[1] df = d.defs[0] assert isinstance(lhs, Var) and isinstance(rhs, Var) if inst == bvadd: # Normal binary - output type same as args exp = (var_to_bv[lhs] + var_to_bv[rhs]) else: assert inst == bvult exp = (var_to_bv[lhs] < var_to_bv[rhs]) # Comparison binary - need to convert bool to BitVec 1 exp = If(exp, BitVecVal(1, 1), BitVecVal(0, 1)) exp = mk_eq(var_to_bv[df], exp) elif inst == bvzeroext: arg = d.expr.args[0] df = d.defs[0] assert isinstance(arg, Var) fromW = arg.get_typevar().singleton_type().width() toW = df.get_typevar().singleton_type().width() exp = mk_eq(var_to_bv[df], ZeroExt(toW - fromW, var_to_bv[arg])) elif inst == bvsignext: arg = d.expr.args[0] df = d.defs[0] assert isinstance(arg, Var) fromW = arg.get_typevar().singleton_type().width() toW = df.get_typevar().singleton_type().width() exp = mk_eq(var_to_bv[df], SignExt(toW - fromW, var_to_bv[arg])) elif inst == bvsplit: arg = d.expr.args[0] assert isinstance(arg, Var) arg_typ = arg.get_typevar().singleton_type() width = arg_typ.width() assert (width % 2 == 0) lo = d.defs[0] hi = d.defs[1] exp = And( mk_eq(var_to_bv[lo], Extract(width // 2 - 1, 0, var_to_bv[arg])), mk_eq(var_to_bv[hi], Extract(width - 1, width // 2, var_to_bv[arg]))) elif inst == bvconcat: assert isinstance(d.expr.args[0], Var) and \ isinstance(d.expr.args[1], Var) lo = d.expr.args[0] hi = d.expr.args[1] df = d.defs[0] # Z3 Concat expects hi bits first, then lo bits exp = mk_eq(var_to_bv[df], Concat(var_to_bv[hi], var_to_bv[lo])) else: assert False, "Unknown primitive instruction {}".format(inst) q.append(exp) return (q, m)
def array_to_bv32(array): return Concat(Select(array, BitVecVal(3, 32)), Select(array, BitVecVal(2, 32)), Select(array, BitVecVal(1, 32)), Select(array, BitVecVal(0, 32)))
def BVUnsignedUpCast(x, n_bits): assert x.size() <= n_bits if x.size() < n_bits: return Concat(BitVecVal(0, n_bits - x.size()), x) else: return x
n_bits = 256 # Check that YulUtilFunction::cleanupFunction cleanup matches BVSignedCleanupFunction for type_bits in range(8, 256, 8): rule = Rule() # Input vars X = BitVec('X', n_bits) arg = BitVecVal(type_bits / 8 - 1, n_bits) cleaned_reference = BVSignedCleanupFunction(X, type_bits) cleaned = SIGNEXTEND(arg, X) rule.check(cleaned, cleaned_reference) # Check that BVSignedCleanupFunction properly cleans up values. for type_bits in range(8, 256, 8): rule = Rule() # Input vars X_short = BitVec('X', type_bits) dirt = BitVec('dirt', n_bits - type_bits) X = BVSignedUpCast(X_short, n_bits) X_dirty = Concat(dirt, X_short) X_cleaned = BVSignedCleanupFunction(X_dirty, type_bits) rule.check(X, X_cleaned)