(define flexvector-unfold (case-lambda ((p f g seed) (define fv (flexvector)) (assume (procedure? p)) (assume (procedure? f)) (assume (procedure? g)) (do ((seed seed (g seed))) ((p seed) fv) (flexvector-add-back! fv (f seed)))) ((p f g . seeds) (define fv (flexvector)) (assume (procedure? p)) (assume (procedure? f)) (assume (procedure? g)) (do ((seeds seeds (let-values ((seeds (apply g seeds))) seeds))) ((apply p seeds) fv) (flexvector-add-back! fv (apply f seeds)))))) (define (flexvector-unfold-right . args) (define fv (apply flexvector-unfold args)) (flexvector-reverse! fv) fv) (define flexvector-fill! (case-lambda ((fv fill) (flexvector-fill! fv fill 0 (flexvector-length fv))) ((fv fill start) (flexvector-fill! fv fill start (flexvector-length fv))) ((fv fill start end) (let ((actual-end (min end (flexvector-length fv)))) (do ((i (max 0 start) (+ i 1))) ((>= i actual-end)) (flexvector-set! fv i fill)))))) (define (flexvector-reverse-copy . args) (define fv (apply flexvector-copy args)) (flexvector-reverse! fv) fv) (define flexvector-reverse-copy! (case-lambda ((to at from) (assume (flexvector? from)) (flexvector-reverse-copy! to at from 0 (flexvector-length from))) ((to at from start) (assume (flexvector? from)) (flexvector-reverse-copy! to at from start (flexvector-length from))) ((to at from start end) (flexvector-copy! to at from start end) (flexvector-reverse! to at (+ at (- end start)))))) (define (flexvector-append! fv . fvs) (assume (flexvector? fv)) (assume (every flexvector? fvs)) (for-each (lambda (fv2) (flexvector-copy! fv (flexvector-length fv) fv2)) fvs) fv) (define (flexvector-front fv) (assume (flexvector? fv)) (assume (not (flexvector-empty? fv))) (flexvector-ref fv 0)) (define (flexvector-back fv) (assume (flexvector? fv)) (assume (not (flexvector-empty? fv))) (flexvector-ref fv (- (flexvector-length fv) 1))) (define flexvector-add-front! (case-lambda ((fv x) (flexvector-add! fv 0 x)) ((fv . xs) (apply flexvector-add! fv 0 xs)))) (define (flexvector-remove-front! fv) (assume (flexvector? fv)) (assume (not (flexvector-empty? fv))) (flexvector-remove! fv 0)) (define (flexvector-remove-back! fv) (assume (flexvector? fv)) (assume (not (flexvector-empty? fv))) (flexvector-remove! fv (- (flexvector-length fv) 1))) (define (flexvector=? eq . o) (cond ((null? o) #t) ((null? (cdr o)) #t) (else (and (let* ((fv1 (car o)) (fv2 (cadr o)) (len (flexvector-length fv1))) (and (= len (flexvector-length fv2)) (let lp ((i 0)) (or (>= i len) (and (eq (flexvector-ref fv1 i) (flexvector-ref fv2 i)) (lp (+ i 1))))))) (apply flexvector=? eq (cdr o)))))) (define (flexvector-fold kons knil fv1 . o) (assume (procedure? kons)) (assume (flexvector? fv1)) (let ((len (flexvector-length fv1))) (if (null? o) (let lp ((i 0) (acc knil)) (if (>= i len) acc (lp (+ i 1) (kons acc (flexvector-ref fv1 i))))) (let lp ((i 0) (acc knil)) (if (>= i len) acc (lp (+ i 1) (apply kons acc (flexvector-ref fv1 i) (map (lambda (fv) (flexvector-ref fv i)) o)))))))) (define (flexvector-fold-right kons knil fv1 . o) (assume (procedure? kons)) (assume (flexvector? fv1)) (let ((len (flexvector-length fv1))) (if (null? o) (let lp ((i (- len 1)) (acc knil)) (if (negative? i) acc (lp (- i 1) (kons acc (flexvector-ref fv1 i))))) (let lp ((i (- len 1)) (acc knil)) (if (negative? i) acc (lp (- i 1) (apply kons acc (flexvector-ref fv1 i) (map (lambda (fv) (flexvector-ref fv i)) o)))))))) (define flexvector-for-each/index (case-lambda ((proc fv) (assume (procedure? proc)) (assume (flexvector? fv)) (let ((len (flexvector-length fv))) (do ((i 0 (+ i 1))) ((= i len)) (proc i (flexvector-ref fv i))))) ((proc . fvs) (assume (procedure? proc)) (let ((len (apply min (map flexvector-length fvs)))) (do ((i 0 (+ i 1))) ((= i len)) (apply proc i (map (lambda (fv) (flexvector-ref fv i)) fvs))))))) (define flexvector-for-each (case-lambda ((proc fv) (assume (procedure? proc)) (flexvector-for-each/index (lambda (i x) (proc x)) fv)) ((proc . fvs) (assume (procedure? proc)) (apply flexvector-for-each/index (lambda (i . xs) (apply proc xs)) fvs)))) (define flexvector-map/index! (case-lambda ((proc fv) (assume (procedure? proc)) (assume (flexvector? fv)) (flexvector-for-each/index (lambda (i x) (flexvector-set! fv i (proc i x))) fv) fv) ((proc fv . fvs) (assume (procedure? proc)) (assume (flexvector? fv)) (apply flexvector-for-each/index (lambda (i . xs) (flexvector-set! fv i (apply proc i xs))) fv fvs) fv))) (define flexvector-map! (case-lambda ((proc fv) (assume (procedure? proc)) (flexvector-map/index! (lambda (i x) (proc x)) fv)) ((proc . fvs) (assume (procedure? proc)) (apply flexvector-map/index! (lambda (i . xs) (apply proc xs)) fvs)))) (define (flexvector-map/index proc fv . fvs) (assume (flexvector? fv)) (apply flexvector-map/index! proc (flexvector-copy fv) fvs)) (define (flexvector-map proc fv . fvs) (assume (flexvector? fv)) (apply flexvector-map! proc (flexvector-copy fv) fvs)) (define (flexvector-append-map/index proc fv . fvs) (define out (flexvector)) (flexvector-for-each (lambda (x) (flexvector-append! out x)) (apply flexvector-map/index proc fv fvs)) out) (define (flexvector-append-map proc fv . fvs) (define out (flexvector)) (flexvector-for-each (lambda (x) (flexvector-append! out x)) (apply flexvector-map proc fv fvs)) out) (define flexvector-filter! (case-lambda ((pred? fv) (assume (procedure? pred?)) (assume (flexvector? fv)) (flexvector-filter/index! (lambda (i x) (pred? x)) fv)) ((pred? . fvs) (assume (procedure? pred?)) (apply flexvector-filter/index! (lambda (i . xs) (apply pred? xs)) fvs)))) (define (flexvector-filter/index proc fv . fvs) (assume (flexvector? fv)) (apply flexvector-filter/index! proc (flexvector-copy fv) fvs)) (define (flexvector-filter proc fv . fvs) (assume (flexvector? fv)) (apply flexvector-filter! proc (flexvector-copy fv) fvs)) (define (flexvector-index pred? fv1 . o) (assume (procedure? pred?)) (assume (flexvector? fv1)) (let ((len (flexvector-length fv1))) (let lp ((i 0)) (and (< i len) (if (apply pred? (flexvector-ref fv1 i) (map (lambda (fv) (flexvector-ref fv i)) o)) i (lp (+ i 1))))))) (define (flexvector-index-right pred? fv1 . o) (assume (procedure? pred?)) (assume (flexvector? fv1)) (let ((len (flexvector-length fv1))) (let lp ((i (- len 1))) (and (>= i 0) (if (apply pred? (flexvector-ref fv1 i) (map (lambda (fv) (flexvector-ref fv i)) o)) i (lp (- i 1))))))) (define (complement f) (lambda args (not (apply f args)))) (define (flexvector-skip pred? fv1 . o) (assume (procedure? pred?)) (assume (flexvector? fv1)) (apply flexvector-index (complement pred?) fv1 o)) (define (flexvector-skip-right pred? fv1 . o) (assume (procedure? pred?)) (assume (flexvector? fv1)) (apply flexvector-index-right (complement pred?) fv1 o)) (define flexvector-binary-search (case-lambda ((fv value cmp) (flexvector-binary-search fv value cmp 0 (flexvector-length fv))) ((fv value cmp start) (flexvector-binary-search fv value cmp start (flexvector-length fv))) ((fv value cmp start end) (assume (flexvector? fv)) (assume (procedure? cmp)) (assume (integer? start)) (assume (integer? end)) (assume (<= start end)) (let lp ((lo (max start 0)) (hi (- (min end (flexvector-length fv)) 1))) (and (<= lo hi) (let* ((mid (quotient (+ lo hi) 2)) (x (flexvector-ref fv mid)) (y (cmp value x))) (cond ((< y 0) (lp lo (- mid 1))) ((> y 0) (lp (+ mid 1) hi)) (else mid)))))))) (define (flexvector-any pred? fv . o) (assume (procedure? pred?)) (assume (flexvector? fv)) (let ((len (apply min (flexvector-length fv) (map flexvector-length o)))) (let lp ((i 0)) (and (< i len) (or (apply pred? (flexvector-ref fv i) (map (lambda (v) (flexvector-ref v i)) o)) (lp (+ i 1))))))) (define (flexvector-every pred? fv . o) (assume (procedure? pred?)) (assume (flexvector? fv)) (let ((len (apply min (flexvector-length fv) (map flexvector-length o)))) (or (zero? len) (let lp ((i 0)) (let ((x (apply pred? (flexvector-ref fv i) (map (lambda (v) (flexvector-ref v i)) o)))) (if (= i (- len 1)) x (and x (lp (+ i 1))))))))) (define (flexvector-swap! fv i j) (assume (flexvector? fv)) (assume (integer? i)) (assume (integer? j)) (let ((tmp (flexvector-ref fv i))) (flexvector-set! fv i (flexvector-ref fv j)) (flexvector-set! fv j tmp))) (define (flexvector-reverse! fv . o) (assume (flexvector? fv)) (let lp ((left (if (pair? o) (car o) 0)) (right (- (if (and (pair? o) (pair? (cdr o))) (cadr o) (flexvector-length fv)) 1))) (cond ((>= left right) (if #f #f)) (else (flexvector-swap! fv left right) (lp (+ left 1) (- right 1)))))) (define (flexvector-append fv . fvs) (assume (flexvector? fv)) (apply flexvector-append! (flexvector-copy fv) fvs)) (define (flexvector-concatenate ls) (apply flexvector-append ls)) (define (flexvector-append-subvectors . o) (let lp ((ls o) (vecs '())) (if (null? ls) (flexvector-concatenate (reverse vecs)) (lp (cdr (cddr ls)) (cons (flexvector-copy (car ls) (cadr ls) (car (cddr ls))) vecs))))) (define (flexvector-empty? fv) (assume (flexvector? fv)) (zero? (flexvector-length fv))) (define (flexvector-count pred? fv1 . o) (assume (procedure? pred?)) (assume (flexvector? fv1)) (apply flexvector-fold (lambda (count . x) (+ count (if (apply pred? x) 1 0))) 0 fv1 o)) (define (flexvector-cumulate f knil fv) (assume (procedure? f)) (assume (flexvector? fv)) (let* ((len (flexvector-length fv)) (res (make-vector len))) (let lp ((i 0) (acc knil)) (if (>= i len) (vector->flexvector res) (let ((acc (f acc (flexvector-ref fv i)))) (vector-set! res i acc) (lp (+ i 1) acc)))))) (define (flexvector-partition pred? fv) (assume (procedure? pred?)) (assume (flexvector? fv)) (let ((left (flexvector)) (right (flexvector))) (flexvector-for-each (lambda (x) (flexvector-add-back! (if (pred? x) left right) x)) fv) (values left right))) (define (flexvector->list fv) (assume (flexvector? fv)) (flexvector-fold-right (lambda (x y) (cons y x)) '() fv)) (define (reverse-flexvector->list fv . o) (assume (flexvector? fv)) (flexvector->list (apply flexvector-reverse-copy fv o))) (define (reverse-list->flexvector ls) (assume (list? ls)) (let ((fv (list->flexvector ls))) (flexvector-reverse! fv) fv)) (define (string->flexvector s . o) (assume (string? s)) (vector->flexvector (apply string->vector s o))) (define (flexvector->string fv . o) (assume (flexvector? fv)) (vector->string (apply flexvector->vector fv o))) (define (generator->flexvector g) (assume (procedure? g)) (flexvector-unfold eof-object? (lambda (x) x) (lambda (_) (g)) (g))) (define (flexvector->generator fv) (assume (flexvector? fv)) (let ((i 0)) (lambda () (if (< i (flexvector-length fv)) (let ((element (flexvector-ref fv i))) (set! i (+ i 1)) element) (eof-object)))))