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typesetting/csp/csp.rkt

217 lines
8.3 KiB
Racket

#lang debug racket
(provide (all-defined-out))
(struct $csp ([vars #:mutable]
[constraints #:mutable]) #:transparent)
(define (new-csp) ($csp null null))
(struct $var (name vals) #:transparent)
(define $var-name? symbol?)
(struct $constraint (names proc) #:transparent
#:property prop:procedure
(λ (constraint csp)
(unless ($csp? csp)
(raise-argument-error '$constraint-proc "$csp" csp))
(match-define ($constraint names proc) constraint)
(cond
[(empty? names) (proc)]
[else
(match-define (cons name other-names) names)
(for/and ([val (in-list ($csp-vals csp name))])
;; todo: reconsider efficiency of currying every value
(($constraint other-names (curry proc val)) csp))])))
(define/contract (check-name-in-csp! caller csp name)
(symbol? $csp? $var-name? . -> . void?)
(define names (map $var-name ($csp-vars csp)))
(unless (memq name names)
(raise-argument-error caller (format "csp variable name: ~v" names) name)))
(define/contract (nary-constraint? constraint n)
($constraint? exact-nonnegative-integer? . -> . boolean?)
(= n (length ($constraint-names constraint))))
(define/contract (unary-constraint? constraint)
($constraint? . -> . boolean?)
(nary-constraint? constraint 1))
(define/contract (binary-constraint? constraint)
($constraint? . -> . boolean?)
(nary-constraint? constraint 2))
(define/contract (add-var! csp name [vals empty])
(($csp? $var-name?) ((listof any/c)) . ->* . void?)
(when (memq name (map $var-name ($csp-vars csp)))
(raise-argument-error 'add-var! "var that doesn't exist" name))
(set-$csp-vars! csp (cons ($var name vals) ($csp-vars csp))))
(define (unique-varnames? xs)
(and (andmap $var-name? xs) (not (check-duplicates xs eq?))))
(define/contract (add-constraint! csp proc . var-names)
(($csp? procedure?) #:rest (listof $var-name?) . ->* . void?)
(for ([name (in-list var-names)])
(check-name-in-csp! 'add-constraint! csp name))
(set-$csp-constraints! csp (cons ($constraint var-names proc) ($csp-constraints csp))))
(define/contract (no-solutions? csp)
($csp? . -> . boolean?)
(for/or ([var (in-list ($csp-vars csp))])
(empty? ($var-vals var))))
(struct $csp-inconsistent () #:transparent)
(define/contract (apply-unary-constraint csp constraint)
($csp? unary-constraint? . -> . $csp?)
(match-define ($constraint (list constraint-name) proc) constraint)
(define new-csp ($csp (for/list ([var (in-list ($csp-vars csp))])
(match-define ($var name vals) var)
(if (eq? name constraint-name)
($var name (if (promise? proc)
(force proc)
(filter proc vals)))
var))
;; once the constraint is applied, it can go away
(remove constraint ($csp-constraints csp))))
(when (no-solutions? new-csp) (raise ($csp-inconsistent)))
new-csp)
(define/contract (make-nodes-consistent csp)
($csp? . -> . $csp?)
(for/fold ([csp csp])
([constraint (in-list ($csp-constraints csp))]
#:when (unary-constraint? constraint))
(apply-unary-constraint csp constraint)))
(define/contract ($csp-vals csp name)
($csp? $var-name? . -> . (listof any/c))
(check-name-in-csp! '$csp-vals csp name)
(for/first ([var (in-list ($csp-vars csp))]
#:when (eq? name ($var-name var)))
($var-vals var)))
(struct $arc (name constraint) #:transparent)
(define/contract (revise csp arc)
($csp? $arc? . -> . $csp?)
(match-define ($arc name ($constraint names constraint-proc)) arc)
(match-define (list other-name) (remove name names))
(define proc (if (eq? name (first names)) ; name is on left
constraint-proc ; so val goes on left
(λ (val other-val) (constraint-proc other-val val)))) ; otherwise reverse arg order
(define (satisfies-arc? val)
(for/or ([other-val (in-list ($csp-vals csp other-name))])
(proc val other-val)))
(apply-unary-constraint csp ($constraint (list name)
(procedure-rename
satisfies-arc?
(string->symbol (format "satisfies-arc-with-~a?" other-name))))))
(define/contract (binary-constraints->arcs constraints)
((listof binary-constraint?) . -> . (listof $arc?))
(for*/list ([constraint (in-list constraints)]
[name (in-list ($constraint-names constraint))])
($arc name constraint)))
(define/contract (terminating-at arcs name)
((listof $arc?) $var-name? . -> . (listof $arc?))
(for/list ([arc (in-list arcs)]
#:when (eq? name (second ($constraint-names ($arc-constraint arc)))))
arc))
(define/contract (ac-3 csp)
($csp? . -> . $csp?)
;; as described by AIMA @ 265
(define all-arcs (binary-constraints->arcs (filter binary-constraint? ($csp-constraints csp))))
(for/fold ([csp csp]
[arcs all-arcs]
#:result csp)
([i (in-naturals)]
#:break (empty? arcs))
(match-define (cons arc other-arcs) arcs)
(match-define ($arc name _) arc)
(define revised-csp (revise csp arc))
(values revised-csp (if (= (length ($csp-vals csp name)) (length ($csp-vals revised-csp name)))
;; revision did not reduce the domain, so keep going
other-arcs
;; revision reduced the domain, so supplement the list of arcs
(remove-duplicates (append (all-arcs . terminating-at . name) other-arcs))))))
(define/contract (make-arcs-consistent csp)
($csp? . -> . $csp?)
;; csp is arc-consistent if every pair of variables (x y)
;; has values in their domain that satisfy every binary constraint
(ac-3 csp))
(define/contract (var-assigned? var)
($var? . -> . boolean?)
(= 1 (length ($var-vals var))))
(define/contract (assignment-complete? csp)
($csp? . -> . boolean?)
(andmap var-assigned? ($csp-vars csp)))
(define (assigned-helper csp) (partition var-assigned? ($csp-vars csp)))
(define/contract (unassigned-vars csp)
($csp? . -> . (listof $var?))
(match-define-values (assigned unassigned) (assigned-helper csp))
unassigned)
(define/contract (assigned-vars csp)
($csp? . -> . (listof $var?))
(match-define-values (assigned unassigned) (assigned-helper csp))
assigned)
(define/contract (select-unassigned-var csp)
($csp? . -> . $var?)
;; minimum remaining values (MRV) rule
(argmin (λ (var) (length ($var-vals var))) (unassigned-vars csp)))
(define/contract (order-domain-values vals)
((listof any/c) . -> . (listof any/c))
;; todo: least constraining value sort
vals)
;; todo: inferences between assignments
(define infer values)
(define/contract (assign-val csp name val)
($csp? $var-name? any/c . -> . $csp?)
(validate-assignment (apply-unary-constraint csp ($constraint (list name) (delay (list val)))) name))
(define/contract (validate-assignment csp name)
($csp? $var-name? . -> . $csp?)
(define assigned-names (map $var-name (assigned-vars csp)))
(for/fold ([csp csp])
([constraint (in-list ($csp-constraints csp))]
#:when (match-let ([($constraint cnames _) constraint])
(and (memq name cnames)
(for/and ([cname (in-list cnames)])
(memq cname assigned-names)))))
(unless (constraint csp) (raise ($csp-inconsistent)))
($csp ($csp-vars csp) (remove constraint ($csp-constraints csp)))))
(define/contract (backtrack csp)
($csp? . -> . $csp?)
(cond
[(assignment-complete? csp) csp]
[(match-let ([($var name vals) (select-unassigned-var csp)])
(for/or ([val (in-list (order-domain-values vals))])
(with-handlers ([$csp-inconsistent? (λ (exn) #f)])
(backtrack (infer (assign-val csp name val))))))]
[else (raise ($csp-inconsistent))]))
(define/contract (solve csp [finish-proc values])
(($csp?) (procedure?) . ->* . any/c)
(finish-proc (backtrack (make-arcs-consistent (make-nodes-consistent csp)))))
(define ($csp-ref csp name)
(car ($csp-vals csp name)))
(define/contract (alldiff . xs)
(() #:rest (listof any/c) . ->* . boolean?)
(for/and ([comb (in-combinations xs 2)])
(not (apply equal? comb))))