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a Go implementation of miniKanren, an embedded Domain Specific Language for logic programming.

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gominikanren

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gominikarnen is an implementation of miniKanren in Go.

Watch the video

miniKanren is an embedded Domain Specific Language for logic programming.

Implementations

Currently there are 3 implementations included in this repository:

  1. gomini - the concurrent version that works on any Go data type that is a pointer
  2. micro - the minimal implementation based on the paper (only works on ast.SExpr)
  3. mini - extends micro with operators from the book The Reasoned Schemer (only works on ast.SExpr)

Installation

First install Go

And then run on the command line

$ go get github.com/awalterschulze/gominikanren

Example: ConcatO using gomini

ConcatO is a goal that concats the first two input arguments into the third input argument. In this example we use ConcatO to get all the combinations that can produce the linked list [a, b, c, d].

package main

import (
    "context"

    . "github.com/awalterschulze/gominikanren/gomini"
    . "github.com/awalterschulze/gominikanren/gomini/concato"
)

type Pair struct {
    Left  *Node
    Right *Node
}

func main() {
    pairs := toStrings(RunTake(context.Background(), -1, NewState(), func(q *Pair) Goal {
        return ExistO(func(x *Node) Goal {
            return ExistO(func(y *Node) Goal {
                return ConjO(
                    EqualO(&Pair{x, y}, q),
                    ConcatO(
                        x,
                        y,
                        NewNode("a", NewNode("b", NewNode("c", NewNode("d", nil)))),
                    ),
                )
            })
        })
    }))
    fmt.Println(pairs)
}

// Output:
// [
//   {[], [a,b,c,d]},
//   {[a,b,c,d], []},
//   {[a,b,c], [d]},
//   {[a,b], [c,d]},
//   {[a], [b,c,d]},
// ]

Example: Translating Math to miniKanren

gominikanren includes the four logic operators:

  • $=$ => EqualO
  • $\exists$ => ExistO
  • $\land$ (and) => ConjO
  • $\lor$ (or) => DisjO

The next two operators are implicit most programming languages:

  • $\forall$ => a function parameter
  • $\in$ => providing a type

ConcatO was created using the mathematical formula:

$$ \forall\ \Phi\ \Psi\ \Omega, \\ \oplus\ \Phi\ \Psi\ \Omega \equiv \\ (\Phi = \emptyset \land \Omega = \Psi) \lor \\ (\exists\ \alpha\ \phi\ \omega, \Phi = \alpha \dblcolon \phi \land \Omega = \alpha \dblcolon \omega \land \oplus\ \phi\ \Psi\ \omega ) $$

This looks rather intimidating, but we can give these variables some better names:

$$ \begin{align*} &\ \forall\ \ xs\ ys\ zs &&\in [string],\ \\ &\oplus\ xs\ ys\ zs &&\equiv (xs = [] \land zs = ys) \\ & && \ \lor (\exists \ head \in string, \\ & && \ \ \ \ \ \ \ \exists \ xtail\ ztail \in [string], \\ & && \ \ \ \ \ \ \ \ \ \ \ \ \ xs = [head, xtail \ldots] \\ & && \ \ \ \ \ \ \ \ \ \land zs = [head, ztail \ldots] \\ & && \ \ \ \ \ \ \ \ \ \land \oplus\ xtail\ ys\ ztail \ ) \end{align*} $$

Then we can use this to translate it to gominikanren:

type Node struct {
    Value  *string
    Next   *Node
}

func ConcatO(xs, ys, zs *Node) Goal {
    return DisjO(
        ConjO(
            EqualO(xs, nil),
            EqualO(ys, zs),
        ),
        ExistO(func(head *string) Goal {
            return ExistO(func(xtail *Node) Goal {
                return ExistO(func(ztail *Node) Goal {
                    return ConjO(
                        EqualO(xs, &Node{head, xtail}),
                        EqualO(zs, &Node{head, ztail}),
                        ConcatO(xtail, ys, ztail),
                    )
                })
            })
        }),
    )
}

Example: Original AppendO using micro, mini and ast.SExpr

AppendO is a goal that appends the first two input arguments into the third input argument. In this example we use AppendO to get all the combinations that can produce the list (cake & ice d t).

package main

import (
    "github.com/awalterschulze/gominikanren/sexpr/ast"
    "github.com/awalterschulze/gominikanren/micro"
    "github.com/awalterschulze/gominikanren/mini"
)

func main() {
    states := micro.RunGoal(
        -1,
        micro.CallFresh(func(x *ast.SExpr) micro.Goal {
            return micro.CallFresh(func(y *ast.SExpr) micro.Goal {
                return micro.ConjunctionO(
                    // (== ,q (cons ,x ,y))
                    micro.EqualO(
                        ast.Cons(x, ast.Cons(y, nil)),
                        ast.NewVariable("q"),
                    ),
                    // (appendo ,x ,y (cake & ice d t))
                    mini.AppendO(
                        x,
                        y,
                        ast.NewList(
                            ast.NewSymbol("cake"),
                            ast.NewSymbol("&"),
                            ast.NewSymbol("ice"),
                            ast.NewSymbol("d"),
                            ast.NewSymbol("t"),
                        ),
                    ),
                )
            })
        }),
    )
    sexprs := micro.Reify("q", states)
    fmt.Println(ast.NewList(sexprs...).String())
}
//Output:
//(
//  (() (cake & ice d t))
//  ((cake) (& ice d t))
//  ((cake &) (ice d t))
//  ((cake & ice) (d t))
//  ((cake & ice d) (t))
//  ((cake & ice d t) ())
//)

Learn More about miniKanren

If you are unfamiliar with miniKanren here is a great introduction video by Bodil Stokke:

IMAGE ALT TEXT HERE

If you like that, then the book, The Reasoned Schemer, explains logical programming in miniKanren by example.

If you want to delve even deeper, then this implementation is based on a very readable paper, µKanren: A Minimal Functional Core for Relational Programming, that explains the core algorithm of miniKanren.

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