# Best way to define algebraic data types in Python? [closed]

I know that Python is NOT Haskell or Ocaml, but which is the best way to define algebraic data types in Python (2 or 3)?

• Python has a very loose type system in the first place; what exactly are you trying to get out of this? Apr 28 '13 at 1:18
• @Amber not loose. very strong, but duck. Apr 28 '13 at 1:19
• @Elazar When I say "loose", I mean things like functions not having particular type signatures. But you're right, Python is not weakly typed. Apr 28 '13 at 1:25
• @Amber I see what you mean. Apr 28 '13 at 1:28
• @Amber Rather than "loose" maybe saying it's dynamically typed rather than statically typed would have been clearer. Jan 8 '17 at 16:23

Macropy provides algebraic data types, pattern matching and more!

• The linked project is no longer maintained. Nov 27 '16 at 6:50
• As of january 2019, the latest commit dates from september 2018, so I guess the project is not 100% dead.
– bli
Jan 18 '19 at 14:36
• What other functionality does it provide that `@dataclass` introduced in python 3.7 does not have? Jan 19 at 14:48

The `typing` module provides `Union` which, dissimilar to C, is a sum type. You'll need to use mypy to do static type checking, and there's a notable lack of pattern matching, but combined with tuples (product types), that's the two common algebraic types.

``````from dataclasses import dataclass
from typing import Union

@dataclass
class Point:
x: float
y: float

@dataclass
class Circle:
x: float
y: float
r: float

@dataclass
class Rectangle:
x: float
y: float
w: float
h: float

Shape = Union[Point, Circle, Rectangle]

def print_shape(shape: Shape):
if isinstance(shape, Point):
print(f"Point {shape.x} {shape.y}")
elif isinstance(shape, Circle):
print(f"Circle {shape.x} {shape.y} {shape.r}")
elif isinstance(shape, Rectangle):
print(f"Rectangle {shape.x} {shape.y} {shape.w} {shape.h}")

print_shape(Point(1, 2))
print_shape(Circle(3, 5, 7))
print_shape(Rectangle(11, 13, 17, 19))
# print_shape(4)  # mypy type error
``````
• Hi! If you are using mypy, you can check the exhaustiveness of your "pattern matching" using the `assert_never` idiom: github.com/python/typing/issues/735 Nov 5 '20 at 10:40
• And PEP 622 (pattern matching) makes using sum types even more similar to functional languages. Dec 9 '20 at 10:52
• This isn't really sum types since it just relies on RTTI to identify the type. May 12 at 13:56

I have developed a simple library that allows one to define tagged unions based on @dataclases with optional fields here:

https://pypi.org/project/tagged-dataclasses/

Here's an implementation of sum types in relatively Pythonic way.

``````import attr

@attr.s(frozen=True)
class CombineMode(object):
kind = attr.ib(type=str)
params = attr.ib(factory=list)

def match(self, expected_kind, f):
if self.kind == expected_kind:
return f(*self.params)
else:
return None

@classmethod
def join(cls):
return cls("join")

@classmethod
def select(cls, column: str):
return cls("select", params=[column])
``````

Crack open an interpreter and you'll see familiar behavior:

``````>>> CombineMode.join()
CombineMode(kind='join_by_entity', params=[])

>>> CombineMode.select('a') == CombineMode.select('b')
False

>>> CombineMode.select('a') == CombineMode.select('a')
True

>>> CombineMode.select('foo').match('select', print)
foo
``````

Note: The `@attr.s` decorator comes from the attrs library, it implements `__init__`, `__repr__`, and `__eq__`, but it also freezes the object. I included it because it cuts down on the implementation size, but it's also widely available and quite stable.

Sum types are sometimes called tagged unions. Here I used the `kind` member to implement the tag. Additional per-variant parameters are implemented via a list. In true Pythonic fashion, this is duck-typed on the input & output sides but not strictly enforced internally.

I also included a `match` function that does basic pattern matching. Type safety is also implemented via duck typing, a `TypeError` will be raised if the passed lambda's function signature doesn't align with the actual variant you're trying to match on.

These sum types can be combined with product types (`list` or `tuple`) and still retain a lot of the critical functionality required for algebraic data types.

Problems

This doesn't strictly constrain the set of variants.