typesetting/csp/csp/sudoku-jm.rkt

#lang racket/base
(require racket/match
         racket/list
         racket/set)

(define anything (seteq 1 2 3 4 5 6 7 8 9))
(struct cell (x y can-be) #:transparent)

(define (cell-solved? c)
  (= 1 (set-count (cell-can-be c))))

(define (floor3 x)
  (floor (/ x 3)))

(define (neighbor-of? l r)
  (or (same-row? l r)
      (same-col? l r)
      (same-box? l r)))
(define (same-box? l r)
  (and (= (floor3 (cell-x l)) (floor3 (cell-x r)))
       (= (floor3 (cell-y l)) (floor3 (cell-y r)))))
(define (same-row? l r)
  (= (cell-x l) (cell-x r)))
(define (same-col? l r)
  (= (cell-y l) (cell-y r)))

;; a grid is a list of cells

(define hrule "-----------")

;; board : string ... -> grid
(define (board . ss)
  (match-define
   (list r1 r2 r3 (== hrule)
         r4 r5 r6 (== hrule)
         r7 r8 r9)
   ss)
  (define rs
    (list r1 r2 r3 r4 r5 r6 r7 r8 r9))
  (flatten
   (for/list ([r (in-list rs)]
              [y (in-naturals)])
     (parse-row y r))))

(define (parse-row y r)
  (for/list ([c (in-string r)]
             [i (in-naturals)])
    (cond
      [(or (= i 3) (= i 7))
       (if (char=? c #\|)
         empty
         (error 'parse-row))]
      [else
       (define x
         (cond [(< i 3) (- i 0)]
               [(< i 7) (- i 1)]
               [   else (- i 2)]))
       (parse-cell y x c)])))

(define (parse-cell y x c)
  (cell x y
        (if (char=? #\space c)
          anything
          (seteq (string->number (string c))))))

(define (propagate-one top cs)
  (let/ec return
    ;; If this is solved, then push its constraints to neighbors
    (when (cell-solved? top)
      (define-values (changed? ncs)
        (for/fold ([changed? #f] [ncs empty])
            ([c (in-list cs)])
          (cond
            [(neighbor-of? top c)
             (define before
               (cell-can-be c))
             (define after
               (set-subtract before (cell-can-be top)))
             (if (= (set-count before)
                    (set-count after))
               (values changed?
                       (cons c ncs))
               (values #t
                       (cons (struct-copy cell c
                                          [can-be after])
                             ncs)))]
            [else
             (values changed? (cons c ncs))])))
      (return changed? top ncs))

    ;; If this is not solved, then look for cliques that force it to
    ;; be one thing
    (define (try-clique same-x?)
      (define before (cell-can-be top))
      (define after
        (for/fold ([before before])
            ([c (in-list cs)])
          (if (same-x? top c)
            (set-subtract before (cell-can-be c))
            before)))
      (when (= (set-count after) 1)
        (return #t
                (struct-copy cell top
                             [can-be after])
                cs)))

    (try-clique same-row?)
    (try-clique same-col?)
    (try-clique same-box?)

    ;; Look for two cells in our clique that have the same can-be sets
    ;; and remove them from everything else
    (define (only2-clique same-x?)
      (define before (cell-can-be top))
      (when (= (set-count before) 2)
        (define other
          (for/or ([c (in-list cs)])
            (and (same-x? top c) (equal? before (cell-can-be c)) c)))
        (when other
          (define changed? #f)
          (define ncs
            (for/list ([c (in-list cs)])
              (cond
                [(and (not (eq? other c)) (same-x? top c))
                 (define cbefore
                   (cell-can-be c))
                 (define cafter
                   (set-subtract cbefore before))
                 (unless (equal? cbefore cafter)
                   (set! changed? #t))
                 (struct-copy cell c
                              [can-be cafter])]
                [else
                 c])))
          (return changed? top
                  ncs))))

    (only2-clique same-row?)
    (only2-clique same-col?)
    (only2-clique same-box?)

    (values #f
            top
            cs)))

(define (find-pivot f l)
  (let loop ([tried empty]
             [to-try l])
    (match to-try
      [(list)
       (values #f l)]
      [(list-rest top more)
       (define-values (changed? ntop nmore)
         (f top (append tried more)))
       (if changed?
         (values #t (cons ntop nmore))
         (loop (cons top tried) more))])))

(define (propagate g)
  (find-pivot propagate-one g))

(define (until-fixed-point f o bad? end-f)
  (define-values (changed? no) (f o))
  (if changed?
    (cons
     no
     (if (bad? no)
       (end-f no)
       (until-fixed-point f no bad? end-f)))
    (end-f o)))

(define (solved? g)
  (andmap (λ (c) (= (set-count (cell-can-be c)) 1)) g))

(define (failed-solution? g)
  (ormap (λ (c) (= (set-count (cell-can-be c)) 0)) g))

;; solve-it : grid -> (listof grid)
(define (solve-it g)
  (let solve-loop
      ([g g]
       [backtrack!
        (λ (i)
          (error 'solve-it "Failed!"))])
    (define (done? g)
      (cond
        [(solved? g)
         empty]
        [(failed-solution? g)
         (backtrack! #f)]
        [else
         (search g)]))
    (define (search g)
      (define sg (sort g < #:key (λ (c) (set-count (cell-can-be c)))))
      (let iter-loop ([before empty]
                      [after sg])
        (cond
          [(empty? after)
           (backtrack! #f)]
          [else
           (define c (first after))
           (define cb (cell-can-be c))
           (or (and (not (= (set-count cb) 1))
                    (for/or ([o (in-set cb)])
                      (let/ec new-backtrack!
                        (define nc
                          (struct-copy cell c
                                       [can-be (seteq o)]))
                        (solve-loop
                         (cons
                          nc
                          (append before (rest after)))
                         new-backtrack!))))
               (iter-loop (cons c before)
                          (rest after)))])))
    (until-fixed-point propagate g failed-solution? done?)))

(require 2htdp/image
         2htdp/universe)
(define (fig s) (text/font s 12 "black" #f 'modern 'normal 'normal #f))
(define MIN-FIG (fig "1"))
(define CELL-W (* 3 (image-width MIN-FIG)))
(define CELL-H (* 3 (image-height MIN-FIG)))

(struct draw-state (i before after))
(define (draw-it! gs)
  (define (move-right ds)
    (match-define (draw-state i before after) ds)
    (cond
      [(empty? (rest after))
       ds]
      [else
       (draw-state (add1 i)
                   (cons (first after) before)
                   (rest after))]))
  (define (draw-can-be can-be)
    (define (figi i)
      (if (set-member? can-be i)
        (fig (number->string i))
        (fig " ")))
    (place-image/align
     (if (= 1 (set-count can-be))
       (scale 3 (fig (number->string (set-first can-be))))
       (above (beside (figi 1) (figi 2) (figi 3))
              (beside (figi 4) (figi 5) (figi 6))
              (beside (figi 7) (figi 8) (figi 9))))
     0 0
     "left" "top"
     (rectangle CELL-W CELL-H
                "outline" "black")))
  (define (draw-draw-state ds)
    (match-define (draw-state i before after) ds)
    (define g (first after))
    (for/fold ([i
                (empty-scene (* CELL-W 11)
                             (* CELL-H 11))])
        ([c (in-list g)])
      (match-define (cell x y can-be) c)
      (place-image/align
       (draw-can-be can-be)
       (* CELL-W
          (cond [(<= x 2) (+ x 0)]
                [(<= x 5) (+ x 1)]
                [   else  (+ x 2)]))
       (* CELL-H
          (cond [(<= y 2) (+ y 0)]
                [(<= y 5) (+ y 1)]
                [   else  (+ y 2)]))
       "left" "top"
       i)))
  (big-bang (draw-state 0 empty gs)
            (on-tick move-right 1/8)
            (on-draw draw-draw-state)))

;; Wikipedia Example
  (define b1
    (board
     "53 | 7 |   "
     "6  |195|   "
     " 98|   | 6 "
     "-----------"
     "8  | 6 |  3"
     "4  |8 3|  1"
     "7  | 2 |  6"
     "-----------"
     " 6 |   |28 "
     "   |419|  5"
     "   | 8 | 79"))

  ;; "Hard" example
  (define b2
    (board
     " 7 | 2 |  5"
     "  9| 87|  3"
     " 6 |   | 4 "
     "-----------"
     "   | 6 | 17"
     "9 4|   |8 6"
     "71 | 5 |   "
     "-----------"
     " 9 |   | 8 "
     "5  |21 |4  "
     "4  | 9 | 6 "))

  ;; "Evil" example
  (define b3
    (board
     "  8|   | 45"
     "   | 8 |9  "
     "  2|4  |   "
     "-----------"
     "5  |  1|76 "
     " 1 | 7 | 8 "
     " 79|5  |  1"
     "-----------"
     "   |  7|4  "
     "  7| 6 |   "
     "65 |   |3  "))

  #;(draw-state-i
   (draw-it!
    (solve-it
     b2)))


(require sugar/debug)
(time-avg 10 (void (solve-it b1)))
(time-avg 10 (void (solve-it b2)))
(time-avg 10 (void (solve-it b3)))