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)?

  • 1
    Python has a very loose type system in the first place; what exactly are you trying to get out of this?
    – Amber
    Apr 28 '13 at 1:18
  • 9
    @Amber not loose. very strong, but duck.
    – Elazar
    Apr 28 '13 at 1:19
  • 5
    @Elazar When I say "loose", I mean things like functions not having particular type signatures. But you're right, Python is not weakly typed.
    – Amber
    Apr 28 '13 at 1:25
  • 3
    @Amber I see what you mean.
    – Elazar
    Apr 28 '13 at 1:28
  • 2
    @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!

  • 12
    The linked project is no longer maintained.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?
    – Moberg
    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

class Point:
    x: float
    y: float

class Circle:
    x: float
    y: float
    r: float

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
  • 3
    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
  • 3
    And PEP 622 (pattern matching) makes using sum types even more similar to functional languages. Dec 9 '20 at 10:52
  • 2
    This isn't really sum types since it just relies on RTTI to identify the type.
    – Timmmm
    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:



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

import attr

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)
            return None

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

    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')

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

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

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.


This doesn't strictly constrain the set of variants.

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