A Python implementation of microkanren extended with constraints
Project description
microkanren
microkanren
is an implementation of a miniKanren style relational programming language, embedded in Python. The solver is implemented in the style of μKanren[^1]. It provides a framework for extending the language with constraints, as well as a basic implementation of disequality and finite domain constraints, in the style of cKanren[^2].
Due to the differences between Python and the reference implementation languages (Scheme, Racket), some divergences from the typical miniKanren API are necessary. It is a goal to capture the spirit of the miniKanren language family, but not the exact API.
Installation
pip install microkanren
Usage
Basic usage
The basic goal constructor is eq
. eq
takes two terms as arguments, and returns a goal that will succeed if the terms can be unified, and fails otherwise.
>>> from microkanren import eq
>>> eq("🍕", "🍕")
<microkanren.core.Goal object at 0x7f07d85cced0>
To run a goal, use one of the provided interfaces: run
, run_all
, or irun
. run
takes two arguments:
- an integer, the maximum number of results to return; and
- a callable with positional-only arguments, each of which will receive a fresh logic variable.
run_all
and irun
take a single argument, the fresh-var-receiver.
>>> from microkanren import run
>>> run(1, lambda x: eq(x, "🍕"))
['🍕']
The return type of run
and run_all
is a (possibly-empty) list of results. If the list is empty, there are no solutions that satisfy the goal. irun
returns a generator that yields single results.
>>> from microkanren import irun
>>> rs = irun(lambda x: eq(x, "😁"))
>>> next(rs)
'😁'
>>> next(rs)
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
StopIteration
Conjunction and disjunction
Conjunction and disjunction are provided by the vararg conj
and disj
functions. Goal
objects support combination using |
and &
operators, which map to conj
and disj
.
>>> from microkanren import run_all
>>> run_all(lambda x: disj(eq(x, "α"), eq(x, "β"), eq(x, "δ")))
['α', 'β', 'δ']
>>> run_all(lambda x: eq(x, "α") | eq(x, "β") | eq(x, "δ"))
['α', 'β', 'δ']
>>> run_all(lambda x: eq(x, "ω") & eq(x, "ω"))
['ω']
>>> run_all(lambda x: conj(eq(x, "ω"), eq(x, "ω")))
['ω']
The result type and multiple top-level variables
If the fresh-var-receiver provided to an interface has arity 1, results will be single elements. If it has arity > 1, the results will be a tuple of values, each mapping position-wise to the receiver's arguments.
>>> run_all(lambda x, y: eq(x, "foo") & eq(y, "bar") | eq(x, "hello") & eq(y, "world"))
[('foo', 'bar'), ('hello', 'world')]
Defining goal constructors
Calling goal constructors in your top-level program quickly becomes unwieldy. To mitigate this, you can define your own goal constructors.
A goal constructor is a function that takes zero or more arguments, and returns a Goal
(or some object that implements the GoalProto
).
A Goal
is a callable that takes a State
and returns a Stream
of State
objects.
A Stream
is either:
- empty (
mzero
); - a callable of no arguments that returns a
Stream
(a thunk); or - a tuple,
(State, Stream)
.
>>> def likes_pizza(person, out):
... return eq(out, (person, "likes 🍕"))
...
>>> run_all(lambda q: likes_pizza("Jane", q) | likes_pizza("Bill", q))
[('Jane', 'likes 🍕'), ('Bill', 'likes 🍕')]
As shown in the above example, it can be convenient to define goals in terms of the combination of other goals. However, if you require access to the current state, you can define the goal returned by your goal constructor explicitly.
def my_constructor(x):
def _my_constructor(state):
if there_is_something_about(x):
return unit(state)
return mzero
return Goal(_my_constructor)
Wrapping your goal with Goal
means it will be combinable with other goals using |
and &
.
Recursive goal constructors and snooze
(Zzz)
If your goal constructor is directly recursive, it will never terminate.
>>> def always_pizza(x):
... return eq(x, "🍕") | always_pizza(x)
...
>>> run(1, lambda x: always_pizza(x))
...
RecursionError: maximum recursion depth exceeded while calling a Python object
We provide snooze
to delay the construction of a goal until it is needed. Using snooze
we can fix always_pizza
to return an infinite stream of pizza[^3].
>>> def always_pizza(x):
... return eq(x, "🍕") | snooze(always_pizza, x)
...
>>> rs = irun(lambda x: always_pizza(x))
>>> next(rs)
'🍕'
>>> next(rs)
'🍕'
>>> next(rs)
'🍕'
>>> next(rs)
'🍕'
Developing microkanren
microkanren
currently requires Python 3.11.
git clone git@github.com:jams2/microkanren.git
pip install -e .[dev,testing]
Run the tests with pytest
.
Format code with black
and ruff
:
black .
ruff check --fix src tests
[^1]: μKanren: A Minimal Functional Core for Relational Programming (Hemann & Friedman, 2013)
[^2]: cKanren: miniKanren with constraints (Alvis et al, 2011)
[^3]: original example fives
from the μKanren paper altered here to provide more pizza
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