예제 #1
0
    def _post_member_access(self, expression):
        expr = get(expression.expression)

        # Look for type(X).max / min
        # Because we looked at the AST structure, we need to look into the nested expression
        # Hopefully this is always on a direct sub field, and there is no weird construction
        if isinstance(expression.expression, CallExpression) and expression.member_name in [
            "min",
            "max",
        ]:
            if isinstance(expression.expression.called, Identifier):
                if expression.expression.called.value == SolidityFunction("type()"):
                    assert len(expression.expression.arguments) == 1
                    val = TemporaryVariable(self._node)
                    type_expression_found = expression.expression.arguments[0]
                    assert isinstance(type_expression_found, ElementaryTypeNameExpression)
                    type_found = type_expression_found.type
                    if expression.member_name == "min:":
                        op = Assignment(val, Constant(str(type_found.min), type_found), type_found,)
                    else:
                        op = Assignment(val, Constant(str(type_found.max), type_found), type_found,)
                    self._result.append(op)
                    set_val(expression, val)
                    return

        val = ReferenceVariable(self._node)
        member = Member(expr, Constant(expression.member_name), val)
        member.set_expression(expression)
        self._result.append(member)
        set_val(expression, val)
예제 #2
0
 def _post_member_access(self, expression):
     expr = get(expression.expression)
     val = ReferenceVariable(self._node)
     member = Member(expr, Constant(expression.member_name), val)
     member.set_expression(expression)
     self._result.append(member)
     set_val(expression, val)
예제 #3
0
    def _post_call_expression(self, expression):
        called = get(expression.called)
        args = [get(a) for a in expression.arguments if a]
        for arg in args:
            arg_ = Argument(arg)
            arg_.set_expression(expression)
            self._result.append(arg_)
        if isinstance(called, Function):
            # internal call

            # If tuple
            if expression.type_call.startswith('tuple(') and expression.type_call != 'tuple()':
                val = TupleVariable(self._node)
            else:
                val = TemporaryVariable(self._node)
            internal_call = InternalCall(called, len(args), val, expression.type_call)
            internal_call.set_expression(expression)
            self._result.append(internal_call)
            set_val(expression, val)
        else:
            # yul things
            if called.name == 'caller()':
                val = TemporaryVariable(self._node)
                var = Assignment(val, SolidityVariableComposed('msg.sender'), 'uint256')
                self._result.append(var)
                set_val(expression, val)
            elif called.name == 'origin()':
                val = TemporaryVariable(self._node)
                var = Assignment(val, SolidityVariableComposed('tx.origin'), 'uint256')
                self._result.append(var)
                set_val(expression, val)
            elif called.name == 'extcodesize(uint256)':
                val = ReferenceVariable(self._node)
                var = Member(args[0], Constant('codesize'), val)
                self._result.append(var)
                set_val(expression, val)
            elif called.name == 'selfbalance()':
                val = TemporaryVariable(self._node)
                var = TypeConversion(val, SolidityVariable('this'), ElementaryType('address'))
                self._result.append(var)

                val1 = ReferenceVariable(self._node)
                var1 = Member(val, Constant('balance'), val1)
                self._result.append(var1)
                set_val(expression, val1)
            elif called.name == 'address()':
                val = TemporaryVariable(self._node)
                var = TypeConversion(val, SolidityVariable('this'), ElementaryType('address'))
                self._result.append(var)
                set_val(expression, val)
            elif called.name == 'callvalue()':
                val = TemporaryVariable(self._node)
                var = Assignment(val, SolidityVariableComposed('msg.value'), 'uint256')
                self._result.append(var)
                set_val(expression, val)
            else:
                # If tuple
                if expression.type_call.startswith('tuple(') and expression.type_call != 'tuple()':
                    val = TupleVariable(self._node)
                else:
                    val = TemporaryVariable(self._node)

                message_call = TmpCall(called, len(args), val, expression.type_call)
                message_call.set_expression(expression)
                # Gas/value are only accessible here if the syntax {gas: , value: }
                # Is used over .gas().value()
                if expression.call_gas:
                    call_gas = get(expression.call_gas)
                    message_call.call_gas = call_gas
                if expression.call_value:
                    call_value = get(expression.call_value)
                    message_call.call_value = call_value
                if expression.call_salt:
                    call_salt = get(expression.call_salt)
                    message_call.call_salt = call_salt
                self._result.append(message_call)
                set_val(expression, val)
예제 #4
0
파일: ssa.py 프로젝트: gyDBD/slither
def copy_ir(ir, local_variables_instances, state_variables_instances,
            temporary_variables_instances, reference_variables_instances,
            all_local_variables_instances):
    '''
    Args:
        ir (Operation)
        local_variables_instances(dict(str -> LocalVariable))
        state_variables_instances(dict(str -> StateVariable))
        temporary_variables_instances(dict(int -> Variable))
        reference_variables_instances(dict(int -> Variable))

    Note: temporary and reference can be indexed by int, as they dont need phi functions
    '''
    def get(variable):
        if isinstance(variable, LocalVariable):
            if variable.name in local_variables_instances:
                return local_variables_instances[variable.name]
            new_var = LocalIRVariable(variable)
            local_variables_instances[variable.name] = new_var
            all_local_variables_instances[variable.name] = new_var
            return new_var
        if isinstance(
                variable, StateVariable
        ) and variable.canonical_name in state_variables_instances:
            return state_variables_instances[variable.canonical_name]
        elif isinstance(variable, ReferenceVariable):
            if not variable.index in reference_variables_instances:
                new_variable = ReferenceVariable(variable.node,
                                                 index=variable.index)
                if variable.points_to:
                    new_variable.points_to = get(variable.points_to)
                new_variable.set_type(variable.type)
                reference_variables_instances[variable.index] = new_variable
            return reference_variables_instances[variable.index]
        elif isinstance(variable, TemporaryVariable):
            if not variable.index in temporary_variables_instances:
                new_variable = TemporaryVariable(variable.node,
                                                 index=variable.index)
                new_variable.set_type(variable.type)
                temporary_variables_instances[variable.index] = new_variable
            return temporary_variables_instances[variable.index]
        return variable

    def get_variable(ir, f):
        variable = f(ir)
        variable = get(variable)
        return variable

    def get_arguments(ir):
        arguments = []
        for arg in ir.arguments:
            arg = get(arg)
            arguments.append(arg)
        return arguments

    def get_rec_values(ir, f):
        # Use by InitArray and NewArray
        # Potential recursive array(s)
        ori_init_values = f(ir)

        def traversal(values):
            ret = []
            for v in values:
                if isinstance(v, list):
                    v = traversal(v)
                else:
                    v = get(v)
                ret.append(v)
            return ret

        return traversal(ori_init_values)

    if isinstance(ir, Assignment):
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        rvalue = get_variable(ir, lambda x: ir.rvalue)
        variable_return_type = ir.variable_return_type
        return Assignment(lvalue, rvalue, variable_return_type)
    elif isinstance(ir, Balance):
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        value = get_variable(ir, lambda x: ir.value)
        return Balance(value, lvalue)
    elif isinstance(ir, Binary):
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        variable_left = get_variable(ir, lambda x: ir.variable_left)
        variable_right = get_variable(ir, lambda x: ir.variable_right)
        operation_type = ir.type
        return Binary(lvalue, variable_left, variable_right, operation_type)
    elif isinstance(ir, Condition):
        val = get_variable(ir, lambda x: ir.value)
        return Condition(val)
    elif isinstance(ir, Delete):
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        variable = get_variable(ir, lambda x: ir.variable)
        return Delete(lvalue, variable)
    elif isinstance(ir, EventCall):
        name = ir.name
        return EventCall(name)
    elif isinstance(ir, HighLevelCall):  # include LibraryCall
        destination = get_variable(ir, lambda x: ir.destination)
        function_name = ir.function_name
        nbr_arguments = ir.nbr_arguments
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        type_call = ir.type_call
        if isinstance(ir, LibraryCall):
            new_ir = LibraryCall(destination, function_name, nbr_arguments,
                                 lvalue, type_call)
        else:
            new_ir = HighLevelCall(destination, function_name, nbr_arguments,
                                   lvalue, type_call)
        new_ir.call_id = ir.call_id
        new_ir.call_value = get_variable(ir, lambda x: ir.call_value)
        new_ir.call_gas = get_variable(ir, lambda x: ir.call_gas)
        new_ir.arguments = get_arguments(ir)
        new_ir.function = ir.function
        return new_ir
    elif isinstance(ir, Index):
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        variable_left = get_variable(ir, lambda x: ir.variable_left)
        variable_right = get_variable(ir, lambda x: ir.variable_right)
        index_type = ir.index_type
        return Index(lvalue, variable_left, variable_right, index_type)
    elif isinstance(ir, InitArray):
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        init_values = get_rec_values(ir, lambda x: ir.init_values)
        return InitArray(init_values, lvalue)
    elif isinstance(ir, InternalCall):
        function = ir.function
        nbr_arguments = ir.nbr_arguments
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        type_call = ir.type_call
        new_ir = InternalCall(function, nbr_arguments, lvalue, type_call)
        new_ir.arguments = get_arguments(ir)
        return new_ir
    elif isinstance(ir, InternalDynamicCall):
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        function = ir.function
        function_type = ir.function_type
        new_ir = InternalDynamicCall(lvalue, function, function_type)
        new_ir.arguments = get_arguments(ir)
        return new_ir
    elif isinstance(ir, LowLevelCall):
        destination = get_variable(ir, lambda x: x.destination)
        function_name = ir.function_name
        nbr_arguments = ir.nbr_arguments
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        type_call = ir.type_call
        new_ir = LowLevelCall(destination, function_name, nbr_arguments,
                              lvalue, type_call)
        new_ir.call_id = ir.call_id
        new_ir.call_value = get_variable(ir, lambda x: ir.call_value)
        new_ir.call_gas = get_variable(ir, lambda x: ir.call_gas)
        new_ir.arguments = get_arguments(ir)
        return new_ir
    elif isinstance(ir, Member):
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        variable_left = get_variable(ir, lambda x: ir.variable_left)
        variable_right = get_variable(ir, lambda x: ir.variable_right)
        return Member(variable_left, variable_right, lvalue)
    elif isinstance(ir, NewArray):
        depth = ir.depth
        array_type = ir.array_type
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        new_ir = NewArray(depth, array_type, lvalue)
        new_ir.arguments = get_rec_values(ir, lambda x: ir.arguments)
        return new_ir
    elif isinstance(ir, NewElementaryType):
        new_type = ir.type
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        new_ir = NewElementaryType(new_type, lvalue)
        new_ir.arguments = get_arguments(ir)
        return new_ir
    elif isinstance(ir, NewContract):
        contract_name = ir.contract_name
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        new_ir = NewContract(contract_name, lvalue)
        new_ir.arguments = get_arguments(ir)
        return new_ir
    elif isinstance(ir, NewStructure):
        structure = ir.structure
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        new_ir = NewStructure(structure, lvalue)
        new_ir.arguments = get_arguments(ir)
        return new_ir
    elif isinstance(ir, Push):
        array = get_variable(ir, lambda x: ir.array)
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        return Push(array, lvalue)
    elif isinstance(ir, Return):
        value = [get_variable(x, lambda y: y) for x in ir.values]
        return Return(value)
    elif isinstance(ir, Send):
        destination = get_variable(ir, lambda x: ir.destination)
        value = get_variable(ir, lambda x: ir.call_value)
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        return Send(destination, value, lvalue)
    elif isinstance(ir, SolidityCall):
        function = ir.function
        nbr_arguments = ir.nbr_arguments
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        type_call = ir.type_call
        new_ir = SolidityCall(function, nbr_arguments, lvalue, type_call)
        new_ir.arguments = get_arguments(ir)
        return new_ir
    elif isinstance(ir, Transfer):
        destination = get_variable(ir, lambda x: ir.destination)
        value = get_variable(ir, lambda x: ir.call_value)
        return Transfer(destination, value)
    elif isinstance(ir, TypeConversion):
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        variable = get_variable(ir, lambda x: ir.variable)
        variable_type = ir.type
        return TypeConversion(lvalue, variable, variable_type)
    elif isinstance(ir, Unary):
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        rvalue = get_variable(ir, lambda x: ir.rvalue)
        operation_type = ir.type
        return Unary(lvalue, rvalue, operation_type)
    elif isinstance(ir, Unpack):
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        tuple_var = ir.tuple
        idx = ir.index
        return Unpack(lvalue, tuple_var, idx)
    elif isinstance(ir, Length):
        lvalue = get_variable(ir, lambda x: ir.lvalue)
        value = get_variable(ir, lambda x: ir.value)
        return Length(value, lvalue)

    logger.error('Impossible ir copy on {} ({})'.format(ir, type(ir)))
    exit(-1)
예제 #5
0
def copy_ir(ir, *instances):
    '''
    Args:
        ir (Operation)
        local_variables_instances(dict(str -> LocalVariable))
        state_variables_instances(dict(str -> StateVariable))
        temporary_variables_instances(dict(int -> Variable))
        reference_variables_instances(dict(int -> Variable))

    Note: temporary and reference can be indexed by int, as they dont need phi functions
    '''
    if isinstance(ir, Assignment):
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        rvalue = get_variable(ir, lambda x: x.rvalue, *instances)
        variable_return_type = ir.variable_return_type
        return Assignment(lvalue, rvalue, variable_return_type)
    elif isinstance(ir, Balance):
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        value = get_variable(ir, lambda x: x.value, *instances)
        return Balance(value, lvalue)
    elif isinstance(ir, Binary):
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        variable_left = get_variable(ir, lambda x: x.variable_left, *instances)
        variable_right = get_variable(ir, lambda x: x.variable_right,
                                      *instances)
        operation_type = ir.type
        return Binary(lvalue, variable_left, variable_right, operation_type)
    elif isinstance(ir, Condition):
        val = get_variable(ir, lambda x: x.value, *instances)
        return Condition(val)
    elif isinstance(ir, Delete):
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        variable = get_variable(ir, lambda x: x.variable, *instances)
        return Delete(lvalue, variable)
    elif isinstance(ir, EventCall):
        name = ir.name
        return EventCall(name)
    elif isinstance(ir, HighLevelCall):  # include LibraryCall
        destination = get_variable(ir, lambda x: x.destination, *instances)
        function_name = ir.function_name
        nbr_arguments = ir.nbr_arguments
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        type_call = ir.type_call
        if isinstance(ir, LibraryCall):
            new_ir = LibraryCall(destination, function_name, nbr_arguments,
                                 lvalue, type_call)
        else:
            new_ir = HighLevelCall(destination, function_name, nbr_arguments,
                                   lvalue, type_call)
        new_ir.call_id = ir.call_id
        new_ir.call_value = get_variable(ir, lambda x: x.call_value,
                                         *instances)
        new_ir.call_gas = get_variable(ir, lambda x: x.call_gas, *instances)
        new_ir.arguments = get_arguments(ir, *instances)
        new_ir.function = ir.function
        return new_ir
    elif isinstance(ir, Index):
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        variable_left = get_variable(ir, lambda x: x.variable_left, *instances)
        variable_right = get_variable(ir, lambda x: x.variable_right,
                                      *instances)
        index_type = ir.index_type
        return Index(lvalue, variable_left, variable_right, index_type)
    elif isinstance(ir, InitArray):
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        init_values = get_rec_values(ir, lambda x: x.init_values, *instances)
        return InitArray(init_values, lvalue)
    elif isinstance(ir, InternalCall):
        function = ir.function
        nbr_arguments = ir.nbr_arguments
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        type_call = ir.type_call
        new_ir = InternalCall(function, nbr_arguments, lvalue, type_call)
        new_ir.arguments = get_arguments(ir, *instances)
        return new_ir
    elif isinstance(ir, InternalDynamicCall):
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        function = get_variable(ir, lambda x: x.function, *instances)
        function_type = ir.function_type
        new_ir = InternalDynamicCall(lvalue, function, function_type)
        new_ir.arguments = get_arguments(ir, *instances)
        return new_ir
    elif isinstance(ir, LowLevelCall):
        destination = get_variable(ir, lambda x: x.destination, *instances)
        function_name = ir.function_name
        nbr_arguments = ir.nbr_arguments
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        type_call = ir.type_call
        new_ir = LowLevelCall(destination, function_name, nbr_arguments,
                              lvalue, type_call)
        new_ir.call_id = ir.call_id
        new_ir.call_value = get_variable(ir, lambda x: x.call_value,
                                         *instances)
        new_ir.call_gas = get_variable(ir, lambda x: x.call_gas, *instances)
        new_ir.arguments = get_arguments(ir, *instances)
        return new_ir
    elif isinstance(ir, Member):
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        variable_left = get_variable(ir, lambda x: x.variable_left, *instances)
        variable_right = get_variable(ir, lambda x: x.variable_right,
                                      *instances)
        return Member(variable_left, variable_right, lvalue)
    elif isinstance(ir, NewArray):
        depth = ir.depth
        array_type = ir.array_type
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        new_ir = NewArray(depth, array_type, lvalue)
        new_ir.arguments = get_rec_values(ir, lambda x: x.arguments,
                                          *instances)
        return new_ir
    elif isinstance(ir, NewElementaryType):
        new_type = ir.type
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        new_ir = NewElementaryType(new_type, lvalue)
        new_ir.arguments = get_arguments(ir, *instances)
        return new_ir
    elif isinstance(ir, NewContract):
        contract_name = ir.contract_name
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        new_ir = NewContract(contract_name, lvalue)
        new_ir.arguments = get_arguments(ir, *instances)
        return new_ir
    elif isinstance(ir, NewStructure):
        structure = ir.structure
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        new_ir = NewStructure(structure, lvalue)
        new_ir.arguments = get_arguments(ir, *instances)
        return new_ir
    elif isinstance(ir, Push):
        array = get_variable(ir, lambda x: x.array, *instances)
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        return Push(array, lvalue)
    elif isinstance(ir, Return):
        values = get_rec_values(ir, lambda x: x.values, *instances)
        return Return(values)
    elif isinstance(ir, Send):
        destination = get_variable(ir, lambda x: x.destination, *instances)
        value = get_variable(ir, lambda x: x.call_value, *instances)
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        return Send(destination, value, lvalue)
    elif isinstance(ir, SolidityCall):
        function = ir.function
        nbr_arguments = ir.nbr_arguments
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        type_call = ir.type_call
        new_ir = SolidityCall(function, nbr_arguments, lvalue, type_call)
        new_ir.arguments = get_arguments(ir, *instances)
        return new_ir
    elif isinstance(ir, Transfer):
        destination = get_variable(ir, lambda x: x.destination, *instances)
        value = get_variable(ir, lambda x: x.call_value, *instances)
        return Transfer(destination, value)
    elif isinstance(ir, TypeConversion):
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        variable = get_variable(ir, lambda x: x.variable, *instances)
        variable_type = ir.type
        return TypeConversion(lvalue, variable, variable_type)
    elif isinstance(ir, Unary):
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        rvalue = get_variable(ir, lambda x: x.rvalue, *instances)
        operation_type = ir.type
        return Unary(lvalue, rvalue, operation_type)
    elif isinstance(ir, Unpack):
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        tuple_var = get_variable(ir, lambda x: x.tuple, *instances)
        idx = ir.index
        return Unpack(lvalue, tuple_var, idx)
    elif isinstance(ir, Length):
        lvalue = get_variable(ir, lambda x: x.lvalue, *instances)
        value = get_variable(ir, lambda x: x.value, *instances)
        return Length(value, lvalue)

    logger.error('Impossible ir copy on {} ({})'.format(ir, type(ir)))
    exit(-1)
    def _post_call_expression(self, expression):  # pylint: disable=too-many-branches,too-many-statements
        called = get(expression.called)
        args = [get(a) for a in expression.arguments if a]
        for arg in args:
            arg_ = Argument(arg)
            arg_.set_expression(expression)
            self._result.append(arg_)
        if isinstance(called, Function):
            # internal call

            # If tuple
            if expression.type_call.startswith(
                    "tuple(") and expression.type_call != "tuple()":
                val = TupleVariable(self._node)
            else:
                val = TemporaryVariable(self._node)
            internal_call = InternalCall(called, len(args), val,
                                         expression.type_call)
            internal_call.set_expression(expression)
            self._result.append(internal_call)
            set_val(expression, val)
        else:
            # yul things
            if called.name == "caller()":
                val = TemporaryVariable(self._node)
                var = Assignment(val, SolidityVariableComposed("msg.sender"),
                                 "uint256")
                self._result.append(var)
                set_val(expression, val)
            elif called.name == "origin()":
                val = TemporaryVariable(self._node)
                var = Assignment(val, SolidityVariableComposed("tx.origin"),
                                 "uint256")
                self._result.append(var)
                set_val(expression, val)
            elif called.name == "extcodesize(uint256)":
                val = ReferenceVariable(self._node)
                var = Member(args[0], Constant("codesize"), val)
                self._result.append(var)
                set_val(expression, val)
            elif called.name == "selfbalance()":
                val = TemporaryVariable(self._node)
                var = TypeConversion(val, SolidityVariable("this"),
                                     ElementaryType("address"))
                self._result.append(var)

                val1 = ReferenceVariable(self._node)
                var1 = Member(val, Constant("balance"), val1)
                self._result.append(var1)
                set_val(expression, val1)
            elif called.name == "address()":
                val = TemporaryVariable(self._node)
                var = TypeConversion(val, SolidityVariable("this"),
                                     ElementaryType("address"))
                self._result.append(var)
                set_val(expression, val)
            elif called.name == "callvalue()":
                val = TemporaryVariable(self._node)
                var = Assignment(val, SolidityVariableComposed("msg.value"),
                                 "uint256")
                self._result.append(var)
                set_val(expression, val)
            else:
                # If tuple
                if expression.type_call.startswith(
                        "tuple(") and expression.type_call != "tuple()":
                    val = TupleVariable(self._node)
                else:
                    val = TemporaryVariable(self._node)

                message_call = TmpCall(called, len(args), val,
                                       expression.type_call)
                message_call.set_expression(expression)
                # Gas/value are only accessible here if the syntax {gas: , value: }
                # Is used over .gas().value()
                if expression.call_gas:
                    call_gas = get(expression.call_gas)
                    message_call.call_gas = call_gas
                if expression.call_value:
                    call_value = get(expression.call_value)
                    message_call.call_value = call_value
                if expression.call_salt:
                    call_salt = get(expression.call_salt)
                    message_call.call_salt = call_salt
                self._result.append(message_call)
                set_val(expression, val)
    def _post_member_access(self, expression):
        expr = get(expression.expression)

        # Look for type(X).max / min
        # Because we looked at the AST structure, we need to look into the nested expression
        # Hopefully this is always on a direct sub field, and there is no weird construction
        if isinstance(expression.expression,
                      CallExpression) and expression.member_name in [
                          "min",
                          "max",
                      ]:
            if isinstance(expression.expression.called, Identifier):
                if expression.expression.called.value == SolidityFunction(
                        "type()"):
                    assert len(expression.expression.arguments) == 1
                    val = TemporaryVariable(self._node)
                    type_expression_found = expression.expression.arguments[0]
                    assert isinstance(type_expression_found,
                                      ElementaryTypeNameExpression)
                    type_found = type_expression_found.type
                    if expression.member_name == "min:":
                        op = Assignment(
                            val,
                            Constant(str(type_found.min), type_found),
                            type_found,
                        )
                    else:
                        op = Assignment(
                            val,
                            Constant(str(type_found.max), type_found),
                            type_found,
                        )
                    self._result.append(op)
                    set_val(expression, val)
                    return

        # This does not support solidity 0.4 contract_name.balance
        if (isinstance(expr, Variable)
                and expr.type == ElementaryType("address")
                and expression.member_name in ["balance", "code", "codehash"]):
            val = TemporaryVariable(self._node)
            name = expression.member_name + "(address)"
            sol_func = SolidityFunction(name)
            s = SolidityCall(
                sol_func,
                1,
                val,
                sol_func.return_type,
            )
            s.set_expression(expression)
            s.arguments.append(expr)
            self._result.append(s)
            set_val(expression, val)
            return

        if isinstance(expr, TypeAlias) and expression.member_name in [
                "wrap", "unwrap"
        ]:
            # The logic is be handled by _post_call_expression
            set_val(expression, expr)
            return

        # Early lookup to detect user defined types from other contracts definitions
        # contract A { type MyInt is int}
        # contract B { function f() public{ A.MyInt test = A.MyInt.wrap(1);}}
        # The logic is handled by _post_call_expression
        if isinstance(expr, Contract):
            if expression.member_name in expr.file_scope.user_defined_types:
                set_val(
                    expression,
                    expr.file_scope.user_defined_types[expression.member_name])
                return

        val = ReferenceVariable(self._node)
        member = Member(expr, Constant(expression.member_name), val)
        member.set_expression(expression)
        self._result.append(member)
        set_val(expression, val)