You can subclass a
namedtuple-produced class, but you need to study the generated class more closely. You'll need to add another
__slots__ attribute with the extra fields, update the
_fields attribute, create new
_replace methods (they hardcode the field list and class name) and add extra
property objects for the additional fields. See the example in the documentation.
That's all a little too much work. Rather than subclass, I'd just reuse the
somenamedtuple._fields attribute of the source type:
LookupElement = namedtuple('LookupElement', ReadElement._fields + ('lookups',))
field_names argument to the
namedtuple() constructor doesn't have to be a string, it can also be a sequence of strings. Simply take the
_fields and add more elements by concatenating a new tuple.
>>> from collections import namedtuple
>>> ReadElement = namedtuple('ReadElement', 'address value')
>>> LookupElement = namedtuple('LookupElement', ReadElement._fields + ('lookups',))
('address', 'value', 'lookups')
>>> LookupElement('addr', 'val', 'lookup')
LookupElement(address='addr', value='val', lookups='lookup')
This does mean that the extended type is not a subclass of the base type. If you must have a class hierarchy, then rather than try to make named tuples fit that model, I'd switch to using dataclasses instead. Dataclasses can serve the same purpose in most usecases named tuples are used for, but can easily be subclassed.