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mk-c.ss
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mk-c.ss
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;;; miniKanren from Dan Friedman, William Byrd and Oleg Kiselyov
;;; modified by Yin Wang to support a negation operator
;;; (noto) and a disjoint branching operator (condc). The
;;; limitation is that they cannot be nested.
;;; Lazy streams are used to make the connections more modular.
;;; This file was generated by writeminikanren.pl
;;; Generated at 2007-10-25 15:24:42
(define *debug-tags* '())
(define debug
(lambda (tags format . args)
(let* ((tags (if (not (pair? tags)) (list tags) tags))
(fs (string-append "[" (symbol->string (car tags)) "] " format "\n")))
(cond
[(null? tags)]
[(pair? tags)
(if (member (car tags) *debug-tags*)
(apply printf fs args)
(void))]
))))
(define-syntax lambdag@
(syntax-rules ()
((_ (p ...) e ...) (lambda (p ...) e ...))))
(define-syntax lambdaf@
(syntax-rules ()
((_ () e ...) (lambda () e ...))))
(define-syntax inc
(syntax-rules () ((_ e) (lambdaf@ () e))))
(define defunc
(lambda (f)
(if (procedure? f) (defunc (f)) f)))
;;------------ stream primitives ------------
(define snull 'snull)
(define snull?
(lambda (s)
(eq? s snull)))
(define-syntax scons
(syntax-rules ()
((_ a d) (cons a (lambda () d)))))
(define scar
(lambda (s)
(cond
[(procedure? s) (scar (s))]
[else (car s)])))
(define scdr
(lambda (s)
(cond
[(procedure? s) (scdr (s))]
[else ((cdr s))])))
(define-syntax sunit
(syntax-rules ()
((_ a) (scons a snull))))
(define slift
(lambda (f)
(lambda args
(sunit (apply f args)))))
(define-syntax make-stream
(syntax-rules ()
((_) snull)
((_ e1 e2 ...) (scons e1 (make-stream e2 ...)))))
(define taken
(lambda (n s)
(if (and n (zero? n))
'()
(let ([s (defunc s)])
(cond
[(snull? s) '()]
[else (cons (scar s) (taken (and n (- n 1)) (scdr s)))])))))
(define smerge
(lambda (s1 s2)
(cond
[(snull? s1) s2]
[(procedure? s1)
(lambda () (smerge s2 (s1)))]
[else (scons (scar s1) (smerge s2 (scdr s1)))])))
(define stream-merge
(lambda (ss)
(cond
[(snull? ss) snull]
[(procedure? ss) (lambda () (stream-merge (ss)))]
[(snull? (scar ss)) (stream-merge (scdr ss))]
[(procedure? (scar ss)) (lambda ()
(smerge (stream-merge (scdr ss))
(scar ss)))]
[else (scons (scar (scar ss)) (smerge (scdr (scar ss))
(stream-merge (scdr ss))))])))
(define smap
(lambda (f s)
(cond
[(snull? s) snull]
[(procedure? s) (lambda () (smap f (s)))]
[else (scons (f (scar s)) (smap f (scdr s)))])))
;; Substitution
(define-syntax rhs
(syntax-rules ()
((_ x) (cdr x))))
(define-syntax lhs
(syntax-rules ()
((_ x) (car x))))
(define-syntax size-s
(syntax-rules ()
((_ x) (length x))))
(define-syntax var
(syntax-rules ()
((_ x) (vector x))))
(define-syntax var?
(syntax-rules ()
((_ x) (vector? x))))
(define empty-s '())
(define ext-s
(lambda (x v s)
(cons `(,x . ,v) s)))
(define walk
(lambda (v s)
(cond
((var? v)
(let ((a (assq v s)))
(cond
(a (walk (rhs a) s))
(else v))))
(else v))))
(define unify
(lambda (v w s env)
((Env-unify env) v w s env)))
(define unify-good
(lambda (v w s env)
; (printf "[unify-good]: ~a <--> ~a :: ~a\n" v w s)
(let ((v (walk v s))
(w (walk w s)))
(cond
((eq? v w) s)
((var? v) (ext-s v w s))
((var? w) (ext-s w v s))
((and (pair? v) (pair? w))
(let ((s (unify-good (car v) (car w) s env)))
(and s (unify-good (cdr v) (cdr w) s env))))
((equal? v w) s)
(else #f)))))
(define unify-evil
(lambda (v w s env)
(debug '(unify-evil unify)
"v=~a, w=~a, cvars: ~a\n subst:~a" v w (Env-cvars env) s)
(let ((vv (walk v s))
(ww (walk w s)))
(cond
((eq? vv ww) s)
((and (var? vv) (memq v (Env-cvars env))) #f)
((and (var? ww) (memq w (Env-cvars env))) #f)
((var? vv) (ext-s vv ww s))
((var? ww) (ext-s ww vv s))
((and (pair? vv) (pair? ww))
(let ((s (unify-evil (car vv) (car ww) s env)))
(and s (unify-evil (cdr vv) (cdr ww) s env))))
((equal? vv ww) s)
(else #f)))))
(define switch-unify
(lambda (env)
(if (eq? (Env-unify env) unify-good)
(change-unify env unify-evil)
(change-unify env unify-good))))
(define unify-check
(lambda (u v s)
(let ((u (walk u s))
(v (walk v s)))
(cond
((eq? u v) s)
((var? u) (ext-s-check u v s))
((var? v) (ext-s-check v u s))
((and (pair? u) (pair? v))
(let ((s (unify-check (car u) (car v) s)))
(and s (unify-check (cdr u) (cdr v) s))))
((equal? u v) s)
(else #f)))))
(define ext-s-check
(lambda (x v s)
(cond
((occurs-check x v s) #f)
(else (ext-s x v s)))))
(define occurs-check
(lambda (x v s)
(let ((v (walk v s)))
(cond
((var? v) (eq? v x))
((pair? v)
(or
(occurs-check x (car v) s)
(occurs-check x (cdr v) s)))
(else #f)))))
(define walk*
(lambda (w s)
(let ((v (walk w s)))
(cond
((var? v) v)
((pair? v)
(cons
(walk* (car v) s)
(walk* (cdr v) s)))
(else v)))))
(define reify-s
(lambda (v s)
(debug 'reify-s "v: ~a\ns:~a" v s)
(let ((v (walk v s)))
(cond
((var? v)
(ext-s v (reify-name (size-s s)) s))
((pair? v) (reify-s (cdr v)
(reify-s (car v) s)))
(else s)))))
(define reify-name
(lambda (n)
(string->symbol
(string-append "_" "." (number->string n)))))
(define reify
(lambda (v s)
(let ((v (walk* v s)))
(walk* v (reify-s v empty-s)))))
;-------------------------------------------------------------
; data structures
;-------------------------------------------------------------
(struct Pkg (subst constraints) #:transparent)
;; constraints save the current environment vars
(struct Constraint (goal vars text) #:transparent)
;; environment
(struct Env (unify constraints vars cvars) #:transparent)
(define Env-constraint-goals
(lambda (p)
(map Constraint-goal (Env-constraint p))))
(define ext-pkg-constraints
(lambda (p cs ctexts env)
(let ([newc (map (lambda (g t)
(Constraint g (Env-vars env) t))
cs ctexts)])
(Pkg (Pkg-subst p) (append newc (Pkg-constraints p))))))
;; convenience functions
(define change-unify
(lambda (p u)
(match p
[(Env _ constraints vars cvars)
(Env u constraints vars cvars)])))
(define change-constraints
(lambda (p c)
(match p
[(Env unify _ vars cvars)
(Env unify c vars cvars)])))
(define change-vars
(lambda (p v)
(match p
[(Env unify constraints _ cvars)
(Env unify constraints v cvars)])))
(define change-cvars
(lambda (p cv)
(match p
[(Env unify constraints vars _)
(Env unify constraints vars cv)])))
(define ext-constraint
(lambda (env new-cg)
(let ([newc (map (lambda (g) (Constraint g (Env-vars env) 'a))
new-cg)])
(change-constraints env newc))))
(define ext-vars
(lambda (env new-vars)
(change-vars env (append new-vars (Env-vars env)))))
(define ext-cvars
(lambda (env new-cvars)
(change-cvars env (append new-cvars (Env-cvars env)))))
;-------------------------------------------------------------
; miniKanren
;-------------------------------------------------------------
(define succeed (lambda (s env) (sunit s)))
(define fail (lambda (s env) snull))
(define bind
(lambda (s f env)
(cond
[(procedure? s) (lambda () (bind (s) f env))]
[else
(stream-merge (smap (lambda (s) (f s env)) s))])))
(define bind*
(lambda (s goals env)
(cond
[(null? goals)
(stream-merge
(smap (lambda (s)
(bind-constraints (sunit s) (Pkg-constraints s) env))
s))]
[(snull? s) snull]
[else (bind* (bind s (car goals) env) (cdr goals) env)])))
(define bind*
(lambda (s goals env)
(cond
[(null? goals) s]
[(snull? s) snull]
[else (bind* (bind s (car goals) env) (cdr goals) env)])))
(define bind-constraints
(lambda (s cs env)
(cond
[(null? cs) s]
[(snull? s) snull]
[else
(debug 'bind-constraints
"checking constraint: ~a" (Constraint-text (car cs)))
(bind-constraints
(bind s
(Constraint-goal (car cs))
(Env (Env-unify env)
'() ; no constraints
(Env-vars env)
(Constraint-vars (car cs))))
(cdr cs)
env)])))
(define ==
(lambda (u v)
(lambdag@ (s env)
(let ((s1 ((Env-unify env) u v (Pkg-subst s) env)))
(cond
[(not s1) snull]
[else (sunit (Pkg s1 (Pkg-constraints s)))])))))
(define ==
(lambda (u v)
(lambdag@ (s env)
(let ((s1 ((Env-unify env) u v (Pkg-subst s) env)))
(cond
[(not s1) snull]
[else
(let ([cc (bind-constraints (sunit (Pkg s1 '()))
(Pkg-constraints s) env)])
(if (snull? cc)
snull
(sunit (Pkg s1 (filter (lambda (c)
(not (tautology? c (Pkg-subst s))))
(Pkg-constraints s))))))])))))
(define ando
(lambda goals
(lambdag@ (s env)
(bind* (sunit s) goals env))))
(define org2
(lambda (goals)
(lambdag@ (s env)
(cond
[(null? goals) snull]
[else
(scons (bind (sunit s) (car goals) env)
((org2 (cdr goals)) s env))]))))
(define oro
(lambda goals
(lambdag@ (s env)
(stream-merge ((org2 goals) s env)))))
(define noto
(lambda (g)
(lambdag@ (s env)
(let ([ans (defunc (g s (switch-unify env)))])
(if (snull? ans)
(succeed s env)
(fail s env))))))
(define-syntax exist
(syntax-rules ()
((_ (x ...) g0 g ...)
(lambdag@ (s env)
(inc
(let ((x (var 'x)) ...)
((ando g0 g ...) s (ext-vars env (list x ...)))))))))
(define-syntax forall
(syntax-rules ()
((_ (x ...) g0 g ...)
(lambdag@ (s env)
(inc
(let ((x (var 'x)) ...)
((ando g0 g ...)
(let loop ([ss (Pkg-subst s)] [vars (list x ...)])
(cond
[(null? vars) ss]
[else (loop (ext-s (car vars) (gensym) ss) (cdr vars))]))
(ext-vars env (list x ...)))))))))
(define-syntax conde
(syntax-rules ()
((_ (g0 g ...) (g1 g^ ...) ...)
(lambdag@ (s env)
(inc
((oro (ando g0 g ...)
(ando g1 g^ ...) ...) s env))))))
(define-syntax condc
(syntax-rules ()
((_ (g0 g ...)) (ando g0 g ...))
((_ (g0 g ...) g^ ...)
(lambdag@ (s env)
(inc
((oro (ando g0 g ...)
(assert ((noto g0))
(condc g^ ...))) s env))))))
(define reify-constraint
(lambda (s)
(lambda (c)
(let ((ct (Constraint-text c)))
(cond
[(pair? ct)
(cons (car ct)
(map (lambda (v) (walk* v (Pkg-subst s))) (cdr ct)))]
[else ct])))))
(define format-constraints
(lambda (s)
(debug 'format-constraints "subst: ~a\nconstraints: ~a\n"
(Pkg-subst s)
(Pkg-constraints s))
(map (reify-constraint s)
(filter (lambda (c)
(not (tautology? c (Pkg-subst s))))
(Pkg-constraints s)))))
(define-syntax run
(syntax-rules ()
((_ n (x) g0 g ...)
(let ((x (var 'x)))
(let ([ss ((ando g0 g ...) (Pkg empty-s '())
(Env unify-good '() (list x) '()))])
(taken n (smap (lambda (s)
(let* ((x (walk* x (Pkg-subst s)))
(rs (reify-s x empty-s)))
(list
(walk* x rs)
(let ((ctext (walk* (format-constraints s) rs)))
(if (null? ctext)
'()
(list 'constraints: ctext))))))
ss)))))))
(define tautology?
(lambda (c s)
(debug 'tautology?
"constraint: ~a\nvars: ~a\nsubst:~a\n"
(Constraint-text c)
(Constraint-vars c)
s)
(not (snull?
(defunc ((Constraint-goal c)
(Pkg s '())
(Env unify-evil '() '() (Constraint-vars c))))))))
(define-syntax run*
(syntax-rules ()
((_ (x) g ...) (run #f (x) g ...))))
(define-syntax make-text
(syntax-rules (quote quasiquote)
((_ (quote a)) (quote a))
((_ (quasiquote a)) (quasiquote a))
((_ (g a0 ...)) (list 'g (make-text a0) ...))
((_ a) a)))
(define-syntax make-text*
(syntax-rules (quote quasiquote)
((_) '())
((_ (quote a)) (quote a))
((_ (quasiquote a)) (quasiquote a))
((_ (g0 a ...) g ...)
(list (make-text (g0 a ...)) (make-text g) ...))
((_ a) 'a)))
;; (make-text* `b)
;; (make-text* (noto (== `(,a ,d) (cons u v))) (noto (appendo a b c)))
;; (define a 1)
;; (define b 2)
;; (define c 3)
;; (define d 4)
;; (define u 5)
;; (define v 6)
;; (make-text* (a b c) `(,c a))
;; (define q 10)
; (make-text* (noto (== q 3)))
(define-syntax assert
(syntax-rules ()
((_ (c0 c ...) g ...)
(lambdag@ (s env)
(inc
((ando g ...)
(ext-pkg-constraints s (list c0 c ...) (make-text* c0 c ...) env)
(ext-constraint env (list c0 c ...))))))))
(define-syntax conda
(syntax-rules ()
((_ (g0 g ...) (g1 g^ ...) ...)
(lambdag@ (s)
(inc
(ifa ((g0 s) g ...)
((g1 s) g^ ...) ...))))))
(define-syntax ifa
(syntax-rules ()
((_) snull)
((_ (e g ...) b ...)
(cond
[(snull? (defunc e)) (ifa b ...)]
[else (bind* e (list g ...))]))))
(define-syntax condu
(syntax-rules ()
((_ (g0 g ...) (g1 g^ ...) ...)
(lambdag@ (s)
(inc
(ifu ((g0 s) g ...)
((g1 s) g^ ...) ...))))))
(define-syntax ifu
(syntax-rules ()
((_) snull)
((_ (e g ...) b ...)
(cond
[(snull? (defunc e)) (ifa b ...)]
[else (bind* (sunit (scar e)) (list g ...))]))))
(define-syntax project
(syntax-rules ()
((_ (x ...) g g* ...)
(lambdag@ (s env)
(let ((x (walk* x s)) ...)
((exist () g g* ...) s env))))))
(define prints
(lambda (s env)
(begin
(printf "#[prints]:: ~s\n" s)
(succeed s env))))
(define print-env
(lambdag@ (s env)
(begin
(printf "env: ~s\n" env)
(succeed s env))))
(define print-var
(lambda (name v)
(lambda (s env)
(begin
(printf "#[print-var] ~a = ~s\n" name (walk v s))
(succeed s env)))))
(define-syntax print-var
(syntax-rules ()
((_ v) (lambda (s env)
(begin
(printf "#[print-var] ~a = ~s\n" 'v (walk* v (Pkg-subst s)))
(succeed s env))))))
(define print-constraintso
(lambda (s env)
(printf "#[constraints] \n~a\n"
(map (lambda (s) (format "~a\n" s))
(map (reify-constraint s) (Pkg-constraints s))))
(succeed s env)))
;-------------------------------------------------------------
; basic definitions (from TRS)
;-------------------------------------------------------------
(define caro
(lambda (p a)
(exist (d)
(== (cons a d) p))))
(define cdro
(lambda (p d)
(exist (a)
(== (cons a d) p))))
(define conso
(lambda (a d p)
(== (cons a d) p)))
(define nullo
(lambda (x)
(== '() x)))
(define eqo
(lambda (x y)
(== x y)))
(define pairo
(lambda (p)
(exist (a d)
(conso a d p))))
(define nullo
(lambda (x)
(== '() x)))
;-------------------------------------------------------------
; rembero (TRS frame 30)
;-------------------------------------------------------------
;; using conde operator
(define rembero1
(lambda (x l out)
(conde
((nullo l) (== '() out))
((caro l x) (cdro l out))
((exist (res)
(exist (d)
(cdro l d)
(rembero1 x d res))
(exist (a)
(caro l a)
(conso a res out)))))))
;; example
(run* (out)
(exist (y)
(rembero1 y `(a b ,y d peas e) out)))
;; We got 7 answers, 4 of which shouldn't happen, because
;; the fresh variable y should never fail to remove itself
;; and thus go on to remove d, peas and e.
;; =>
;; (((b a d peas e) ()) ; y == a
;; ((a b d peas e) ()) ; y == b
;; ((a b d peas e) ()) ; y == y
;; ((a b d peas e) ()) ; unreasonable beyond this point
;; ((a b peas d e) ())
;; ((a b e d peas) ())
;; ((a b _.0 d peas e) ()))
;; using condc operator
(define rembero
(lambda (x l out)
(condc
((nullo l) (== '() out))
((caro l x) (cdro l out))
((exist (res)
(exist (d)
(cdro l d)
(rembero x d res))
(exist (a)
(caro l a)
(conso a res out)))))))
;; example
(run* (out)
(exist (y)
(rembero y `(a b ,y d peas e) out)))
;; We got only 3 answers, plus two constraints for the third
;; answer. The constraints are basically saying: If we are
;; to have this answer, neither (caro (b y d peas e) y) nor
;; (caro (a b y d peas e) y) should hold.
;; =>
;; (((b a d peas e) ())
;; ((a b d peas e) ())
;; ((a b d peas e)
;; (constraints:
;; ((noto (caro (b #1(y) d peas e) #1(y)))
;; (noto (caro (a b #1(y) d peas e) #1(y)))))))
;-------------------------------------------------------------
; Oleg's comments (Jul 23)
;-------------------------------------------------------------
(run 5 (out)
(exist (y l r)
(== out (list y l r))
(rembero y l r)))
;; =>
;; '(((_.0 () ()) ())
;; ((_.0 (_.0 . _.1) _.1) ())
;; ((_.0 (_.1) (_.1))
;; (constraints: ((noto (caro (_.1) _.0)))))
;; ((_.0 (_.1 _.0 . _.2) (_.1 . _.2))
;; (constraints: ((noto (caro (_.1 _.0 . _.2) _.0)))))
;; ((_.0 (_.1 _.2) (_.1 _.2))
;; (constraints: ((noto (caro (_.2) _.0))
;; (noto (caro (_.1 _.2) _.0))))))
;; Here, the constraints are really part of the answer: the answer
;; (_.0 (_.1) (_.1)) does not make sense without the constraint that
;; _.0 must be different from _.1. The easy way to see that (_.0 (_.1)
;; (_.1)) is not an answer is to instantiate both variables to 1:
(run 5 (out)
(exist (y l r)
(== out '(1 (1) (1)))
(== out (list y l r))
(rembero y l r)))
;; produces (). Thus constraints must be, in general, part of the
;; answer. Hence what I said about the need to normalize constraints
;; applies. Here is the simple example where constraint normalization
;; may help:
(run* (out)
(exist (x y)
(== out (list x y))
(condc
((caro (list x) y))
((caro (list y) x))
((caro (list y) 1))
((caro (list x) 1)))))
;; =>
;; '(((_.0 _.0) ())
;; ((_.0 1)
;; (constraints:
;; ((noto (caro (list 1) _.0))
;; (noto (caro (list _.0) 1)))))
;; ((1 _.0)
;; (constraints:
;; ((noto (caro (list _.0) 1))
;; (noto (caro (list _.0) 1))
;; (noto (caro (list 1) _.0))))))
;; The three constraints in the last answer are identical, aren't they?
;; Here is why we need a genuine constraint solver.
; num predicate
(define (num x)
(conde
((== x '()))
((exist (y)
(== x (cons 1 y))
(num y)))))
(run 5 (out) (num out))
; greater-than on num
(define (gt x y)
(conde
((== y '()) (pairo x))
((exist (x1 y1)
(== x (cons 1 x1))
(== y (cons 1 y1))
(gt x1 y1)))))
(run* (out) (gt '(1 1 1 1) out))
;; (run 1 (out)
;; (exist (x y)
;; (condc
;; ((gt x y) fail)
;; ((gt x (cons 1 y))
;; (num x) (num y) (== out 'really?)))))
;; => diverges
;; rewritten this way
;; (run 1 (out)
;; (exist (x y)
;; (== out (list x y))
;; (num x) (num y)
;; (condc
;; ((gt x y) fail)
;; ((gt x (cons 1 y))))))
;; The genuine constraint solver for naturals would have determined
;; that if NOT(x > y) then x > y+1 cannot succeed. The CLP system will
;; return the finite failure. This is the fundamental difference
;; between CLP and ordinary Prolog: Prolog is based on `generate and
;; test', whereas CLP do `test and then generate'. They solve
;; constraints using uninstantiated variables; they instantiate
;; afterwards.
;; Incidentally, your noto does not play well will committed choice
;; like condu and conda, which is expected (one has to be very careful
;; nesting of condu and conda). There is an easy way to make condu and
;; conda sound (at least, reporting a run-time error when attempting
;; to instantiate a non-local variable). The best way to solve this
;; problems is with mode inference (as Mercury or Twelf do).
;; Incidentally, the mini-Kanren is based on lazy lists (on streams).
;; The monad of mini-Kanren is
;; data L a = Zero | One a | Cons a (() -> L a)
;; which is the ordinary lazy list with the special case for
;; one-element list.
;; Cheers,
;; Oleg