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#lang scribble/manual
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@(require scribble/eval (for-label racket sugar))
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@(define my-eval (make-base-eval))
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@(my-eval `(require sugar racket/list))
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@title{List}
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@defmodule[#:multi (sugar/list (submod sugar/list safe))]
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@defproc[
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(trimf
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[lst list?]
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[pred procedure?])
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list?]
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Drop elements from each end of @racket[_lst] that satisfy @racket[_pred]. Exactly equivalent to @racket[(dropf-right (dropf _lst _pred) _pred)].
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@examples[#:eval my-eval
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(trimf '(1 2 3 a b c 4 5 6) integer?)
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(trimf '(1 2 3 a b c) integer?)
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(trimf '(a b c) integer?)
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(trimf '(a b c 1 2 3 d e f) integer?)]
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@defproc[
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(filter-split
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[lst list?]
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[pred procedure?])
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(listof list?)]
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Like @racket[string-split], but for lists. Drop elements from anywhere in @racket[_lst] that satisfy @racket[_pred] — ends, middle, you name it — and return a list of the sublists that remain.
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@examples[#:eval my-eval
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(filter-split '(1 a b c 2 d e f 3) integer?)
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(filter-split '(1 a b c 2 d e f 3) (compose not integer?))
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(filter-split '(a b c 1 2 3 d e f) integer?)
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(filter-split '(a b c 1 2 3 d e f) (compose not integer?))]
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@defproc[
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(slice-at
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[lst list?]
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[len (and/c integer? positive?)]
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[force? boolean? #f])
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(listof list?)]
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Divide @racket[_lst] into sublists of length @racket[_len]. If @racket[_lst] cannot be divided evenly by @racket[_len], the last sublist will be shorter. If this displeases you, set @racket[_force?] to @racket[#t] and a stumpy final sublist will be ignored.
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@examples[#:eval my-eval
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(slice-at (range 5) 1)
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(slice-at (range 5) 2)
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(slice-at (range 5) 2 #t)
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(slice-at (range 5) 3)
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(slice-at (range 5) 5)
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(slice-at (range 5) 5 #t)
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(slice-at (range 5) 100000)
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(slice-at (range 5) 100000 #t)]
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@defproc[
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(slicef
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[lst list?]
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[pred procedure?])
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(listof list?)]
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Divide @racket[_lst] into sublists that are homogeneously @racket[_pred] or not @racket[_pred]. If none of the elements match @racket[_pred], there is no slice to be made, and the result is the whole input list.
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@examples[#:eval my-eval
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(slicef '(1 2 2 1 2) even?)
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(slicef (range 5) odd?)
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(slicef (range 5) string?)]
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@defproc[
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(slicef-at
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[lst list?]
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[pred procedure?]
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[force? boolean? #f])
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(listof list?)]
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Divide @racket[_lst] into sublists starting with elements matching @racket[_pred]. The first element of the first sublist may not match @racket[_pred]. Or, if you really & truly want only the sublists starting with an element matching @racket[_pred], set @racket[_force?] to @racket[#t].
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@examples[#:eval my-eval
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(slicef-at (range 5) even?)
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(slicef-at '(1 2 2 1 2) even?)
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(slicef-at '(1 2 2 1 2) even? #t)
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(slicef-at (range 5) odd?)
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(slicef-at (range 5) odd? #t)]
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@defproc[
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(slicef-after
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[lst list?]
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[pred procedure?])
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(listof list?)]
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Divide @racket[_lst] into sublists ending with elements matching @racket[_pred]. (Distinct from @racket[slicef-at], which gives you sublists that @italic{start} with elements matching @racket[_pred].) If none of the elements match @racket[_pred], there is no slice to be made, and the result is the whole input list.
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@examples[#:eval my-eval
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(slicef-after '(1 2 2 1 2) even?)
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(slicef-after (range 5) odd?)
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(slicef-after (range 5) string?)]
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@defproc[
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(frequency-hash
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[lst list?])
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hash?]
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Count the frequency of each element in @racket[_lst], and return a hash whose keys are the unique elements of @racket[_lst], and each value is the frequency of that element within @racket[_lst].
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@examples[#:eval my-eval
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(frequency-hash '(a b b c c c))
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(frequency-hash '(c b c a b c))
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]
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@defproc[
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(members-unique?
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[container (or/c list? vector? string?)])
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boolean?]
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Return @racket[#t] if every element in @racket[_container] is unique, otherwise @racket[#f].
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@examples[#:eval my-eval
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(members-unique? '(a b c d e f))
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(members-unique? '(a b c d e f a))
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]
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@defproc[
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(members-unique?/error
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[container (or/c list? vector? string?)])
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boolean?]
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Same as @racket[members-unique?], but if the members are not unique, raises a descriptive error rather than returning @racket[#f].
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@examples[#:eval my-eval
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(members-unique?/error '(a b c d e f))
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(members-unique?/error '(a b c d e f a))
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(members-unique?/error '(a b c d e f a b))
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]
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@defform[(values->list values)]
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Convert @racket[_values] to a simple list.
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@examples[#:eval my-eval
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(split-at '(a b c d e f) 3)
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(values->list (split-at '(a b c d e f) 3))
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]
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@defproc[
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(sublist
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[lst list?]
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[start-idx (and/c integer? (not/c negative?))]
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[end-idx (and/c integer? (not/c negative?))])
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list?]
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Return a sublist of the @racket[_lst] starting with item @racket[_start-idx] and ending one item @bold{before} item @racket[_end-idx]. (Similar to how list slices are denominated in Python.) Thus the maximum value for @racket[_end-idx] is @racketfont{(length @racket[_lst])}. Errors will be triggered by nonsensical values for @racket[_end-idx].
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Bear in mind that @racket[sublist] is built for convenience, not performance. If you need to do a lot of random access into the middle of an ordered sequence of items, you'd be better off putting them into a @racket[vector] and using @racket[vector-copy].
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@examples[#:eval my-eval
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(sublist '(0 1 2 3 4 5 6 7 8) 0 8)
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(sublist '(0 1 2 3 4 5 6 7 8) 8 9)
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(sublist '(0 1 2 3 4 5 6 7 8) 2 5)
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(sublist '(0 1 2 3 4 5 6 7 8) 5 2)
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(sublist '(0 1 2 3 4 5 6 7 8) 2 10)
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]
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@defproc[
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(break-at
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[lst list?]
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[indexes (or/c integer? (listof integer?))])
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(listof list?)]
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Break @racket[_lst] into smaller lists at the index positions in @racket[_indexes]. If a single integer value is given for @racket[_indexes], it's treated as a one-element list. Errors will arise if a breakpoint index exceeds the length of the list, or if the breakpoints are not increasing.
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@examples[#:eval my-eval
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(break-at '(0 1 2 3 4 5 6 7 8) 3)
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(break-at '(0 1 2 3 4 5 6 7 8) '(3))
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(break-at '(0 1 2 3 4 5 6 7 8) '(3 6))
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(break-at '(0 1 2 3 4 5 6 7 8) '(3 6 8))
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(break-at '(0 1 2 3 4 5 6 7 8) '(3 6 8 10))
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]
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@defproc[
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(shift
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[lst list?]
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[how-far integer?]
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[fill-item any/c #f]
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[cycle? boolean? #f])
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list?]
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Move the items in @racket[_lst] to the right (if @racket[_how-far] is positive) or left (if @racket[_how-far] is negative). By default, vacated spaces in the list are filled with @racket[_fill-item]. But if @racket[_cycle?] is true, elements of the list wrap around (and @racket[_fill-item] is ignored). Either way, the result list is always the same length as the input list. (If you don't care about the lengths being the same, you probably want @racket[take] or @racket[drop] instead.) If @racket[_how-far] is 0, return the original list. If @racket[_how-far] is bigger than the length of @racket[_lst], raise an error.
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@examples[#:eval my-eval
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(define xs (range 5))
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(shift xs 2)
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(shift xs -2 0)
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(shift xs 2 'boing)
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(shift xs 2 'boing #t)
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(shift xs 0)
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(shift xs 42)
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]
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@defproc[
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(shifts
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[lst list?]
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[how-far (listof integer?)]
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[fill-item any/c #f]
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[cycle? boolean? #f])
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(listof list?)]
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Same as @racket[shift], but @racket[_how-far] is a list of integers rather than a single integer, and the result is a list of lists rather than a single list.
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@examples[#:eval my-eval
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(define xs (range 5))
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(shifts xs '(-2 2))
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(shifts xs '(-2 2) 0)
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(shifts xs '(-2 2) 'boing)
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(shifts xs '(-2 2) 'boing #t)
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]
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@defproc[
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(shift/values
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[lst list?]
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[how-far (or/c integer? (listof integer?))]
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[fill-item any/c #f])
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any]
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When @racket[_how-far] is a single integer, same as @racket[shift], but the resulting list is returned as values. When @racket[_how-far] is a list of integers, same as @racket[shifts], but the resulting lists are returned as multiple values rather than as a list of lists.
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@examples[#:eval my-eval
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(define xs (range 5))
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(shift xs 1)
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(shift/values xs 1)
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(shifts xs '(-1 0 1))
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(shift/values xs '(-1 0 1))
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]
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