Security analysis tool for EVM bytecode. Supports smart contracts built for Ethereum, Hedera, Quorum, Vechain, Roostock, Tron and other EVM-compatible blockchains.
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mythril/tests/laser/smt/bitvecfunc_test.py

197 lines
5.4 KiB

from mythril.laser.smt import Solver, symbol_factory, bitvec
import z3
import pytest
import operator
@pytest.mark.parametrize(
"operation,expected",
[
(operator.add, z3.unsat),
(operator.sub, z3.unsat),
(operator.and_, z3.sat),
(operator.or_, z3.sat),
(operator.xor, z3.unsat),
],
)
def test_bitvecfunc_arithmetic(operation, expected):
# Arrange
s = Solver()
input_ = symbol_factory.BitVecVal(1, 8)
bvf = symbol_factory.BitVecFuncSym("bvf", "sha3", 256, input_=input_)
x = symbol_factory.BitVecSym("x", 256)
y = symbol_factory.BitVecSym("y", 256)
# Act
s.add(x != y)
s.add(operation(bvf, x) == operation(y, bvf))
# Assert
assert s.check() == expected
@pytest.mark.parametrize(
"operation,expected",
[
(operator.eq, z3.sat),
(operator.ne, z3.unsat),
(operator.lt, z3.unsat),
(operator.le, z3.sat),
(operator.gt, z3.unsat),
(operator.ge, z3.sat),
(bitvec.UGT, z3.unsat),
(bitvec.UGE, z3.sat),
(bitvec.ULT, z3.unsat),
(bitvec.ULE, z3.sat),
],
)
def test_bitvecfunc_bitvecfunc_comparison(operation, expected):
# Arrange
s = Solver()
input1 = symbol_factory.BitVecSym("input1", 256)
input2 = symbol_factory.BitVecSym("input2", 256)
bvf1 = symbol_factory.BitVecFuncSym("bvf1", "sha3", 256, input_=input1)
bvf2 = symbol_factory.BitVecFuncSym("bvf2", "sha3", 256, input_=input2)
# Act
s.add(operation(bvf1, bvf2))
s.add(input1 == input2)
# Assert
assert s.check() == expected
def test_bitvecfunc_bitvecfuncval_comparison():
# Arrange
s = Solver()
input1 = symbol_factory.BitVecSym("input1", 256)
input2 = symbol_factory.BitVecVal(1337, 256)
bvf1 = symbol_factory.BitVecFuncSym("bvf1", "sha3", 256, input_=input1)
bvf2 = symbol_factory.BitVecFuncVal(12345678910, "sha3", 256, input_=input2)
# Act
s.add(bvf1 == bvf2)
# Assert
assert s.check() == z3.sat
assert s.model().eval(input2.raw) == 1337
def test_bitvecfunc_nested_comparison():
# arrange
s = Solver()
input1 = symbol_factory.BitVecSym("input1", 256)
input2 = symbol_factory.BitVecSym("input2", 256)
bvf1 = symbol_factory.BitVecFuncSym("bvf1", "sha3", 256, input_=input1)
bvf2 = symbol_factory.BitVecFuncSym("bvf2", "sha3", 256, input_=bvf1)
bvf3 = symbol_factory.BitVecFuncSym("bvf3", "sha3", 256, input_=input2)
bvf4 = symbol_factory.BitVecFuncSym("bvf4", "sha3", 256, input_=bvf3)
# Act
s.add(input1 == input2)
s.add(bvf2 == bvf4)
# Assert
assert s.check() == z3.sat
def test_bitvecfunc_unequal_nested_comparison():
# arrange
s = Solver()
input1 = symbol_factory.BitVecSym("input1", 256)
input2 = symbol_factory.BitVecSym("input2", 256)
bvf1 = symbol_factory.BitVecFuncSym("bvf1", "sha3", 256, input_=input1)
bvf2 = symbol_factory.BitVecFuncSym("bvf2", "sha3", 256, input_=bvf1)
bvf3 = symbol_factory.BitVecFuncSym("bvf3", "sha3", 256, input_=input2)
bvf4 = symbol_factory.BitVecFuncSym("bvf4", "sha3", 256, input_=bvf3)
# Act
s.add(input1 != input2)
s.add(bvf2 == bvf4)
# Assert
assert s.check() == z3.unsat
def test_bitvecfunc_ext_nested_comparison():
# arrange
s = Solver()
input1 = symbol_factory.BitVecSym("input1", 256)
input2 = symbol_factory.BitVecSym("input2", 256)
input3 = symbol_factory.BitVecSym("input3", 256)
input4 = symbol_factory.BitVecSym("input4", 256)
bvf1 = symbol_factory.BitVecFuncSym("bvf1", "sha3", 256, input_=input1)
bvf2 = symbol_factory.BitVecFuncSym("bvf2", "sha3", 256, input_=bvf1 + input3)
bvf3 = symbol_factory.BitVecFuncSym("bvf3", "sha3", 256, input_=input2)
bvf4 = symbol_factory.BitVecFuncSym("bvf4", "sha3", 256, input_=bvf3 + input4)
# Act
s.add(input1 == input2)
s.add(input3 == input4)
s.add(bvf2 == bvf4)
# Assert
assert s.check() == z3.sat
def test_bitvecfunc_ext_unequal_nested_comparison():
# Arrange
s = Solver()
input1 = symbol_factory.BitVecSym("input1", 256)
input2 = symbol_factory.BitVecSym("input2", 256)
input3 = symbol_factory.BitVecSym("input3", 256)
input4 = symbol_factory.BitVecSym("input4", 256)
bvf1 = symbol_factory.BitVecFuncSym("bvf1", "sha3", 256, input_=input1)
bvf2 = symbol_factory.BitVecFuncSym("bvf2", "sha3", 256, input_=bvf1 + input3)
bvf3 = symbol_factory.BitVecFuncSym("bvf3", "sha3", 256, input_=input2)
bvf4 = symbol_factory.BitVecFuncSym("bvf4", "sha3", 256, input_=bvf3 + input4)
# Act
s.add(input1 == input2)
s.add(input3 != input4)
s.add(bvf2 == bvf4)
# Assert
assert s.check() == z3.unsat
def test_bitvecfunc_ext_unequal_nested_comparison_f():
# Arrange
s = Solver()
input1 = symbol_factory.BitVecSym("input1", 256)
input2 = symbol_factory.BitVecSym("input2", 256)
input3 = symbol_factory.BitVecSym("input3", 256)
input4 = symbol_factory.BitVecSym("input4", 256)
bvf1 = symbol_factory.BitVecFuncSym("bvf1", "sha3", 256, input_=input1)
bvf2 = symbol_factory.BitVecFuncSym("bvf2", "sha3", 256, input_=bvf1 + input3)
bvf3 = symbol_factory.BitVecFuncSym("bvf3", "sha3", 256, input_=input2)
bvf4 = symbol_factory.BitVecFuncSym("bvf4", "sha3", 256, input_=bvf3 + input4)
# Act
s.add(input1 != input2)
s.add(input3 == input4)
s.add(bvf2 == bvf4)
# Assert
assert s.check() == z3.unsat