/usr/share/scheme48-1.9/srfi/srfi-13.scm is in scheme48 1.9-5.
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2022 2023 2024 2025 2026 2027 2028 2029 2030 2031 2032 2033 2034 2035 2036 2037 2038 2039 2040 2041 2042 2043 2044 2045 2046 2047 2048 2049 2050 2051 2052 2053 2054 2055 2056 2057 2058 2059 2060 2061 2062 2063 2064 2065 2066 2067 2068 2069 2070 2071 2072 2073 2074 2075 2076 2077 2078 2079 2080 2081 2082 2083 2084 2085 2086 2087 2088 2089 2090 2091 2092 2093 2094 2095 2096 2097 2098 2099 2100 2101 2102 2103 2104 2105 2106 2107 2108 2109 2110 2111 2112 2113 2114 2115 2116 2117 2118 2119 2120 | ;;; SRFI 13 string library reference implementation -*- Scheme -*-
;;; Olin Shivers 7/2000
;;;
;;; Copyright (c) 1988-1994 Massachusetts Institute of Technology.
;;; Copyright (c) 1998, 1999, 2000 Olin Shivers. All rights reserved.
;;; The details of the copyrights appear at the end of the file. Short
;;; summary: BSD-style open source.
;;; Exports:
;;; string-map string-map!
;;; string-fold string-unfold
;;; string-fold-right string-unfold-right
;;; string-tabulate string-for-each string-for-each-index
;;; string-every string-any
;;; string-hash string-hash-ci
;;; string-compare string-compare-ci
;;; string= string< string> string<= string>= string<>
;;; string-ci= string-ci< string-ci> string-ci<= string-ci>= string-ci<>
;;; string-downcase string-upcase string-titlecase
;;; string-downcase! string-upcase! string-titlecase!
;;; string-take string-take-right
;;; string-drop string-drop-right
;;; string-pad string-pad-right
;;; string-trim string-trim-right string-trim-both
;;; string-filter string-delete
;;; string-index string-index-right
;;; string-skip string-skip-right
;;; string-count
;;; string-prefix-length string-prefix-length-ci
;;; string-suffix-length string-suffix-length-ci
;;; string-prefix? string-prefix-ci?
;;; string-suffix? string-suffix-ci?
;;; string-contains string-contains-ci
;;; string-copy! substring/shared
;;; string-reverse string-reverse! reverse-list->string
;;; string-concatenate string-concatenate/shared string-concatenate-reverse
;;; string-append/shared
;;; xsubstring string-xcopy!
;;; string-null?
;;; string-join
;;; string-tokenize
;;; string-replace
;;;
;;; R5RS extended:
;;; string->list string-copy string-fill!
;;;
;;; R5RS re-exports:
;;; string? make-string string-length string-ref string-set!
;;;
;;; R5RS re-exports (also defined here but commented-out):
;;; string string-append list->string
;;;
;;; Low-level routines:
;;; make-kmp-restart-vector string-kmp-partial-search kmp-step
;;; string-parse-start+end
;;; string-parse-final-start+end
;;; let-string-start+end
;;; check-substring-spec
;;; substring-spec-ok?
;;; Imports
;;; This is a fairly large library. While it was written for portability, you
;;; must be aware of its dependencies in order to run it in a given scheme
;;; implementation. Here is a complete list of the dependencies it has and the
;;; assumptions it makes beyond stock R5RS Scheme:
;;;
;;; This code has the following non-R5RS dependencies:
;;; - (RECEIVE (var ...) mv-exp body ...) multiple-value binding macro;
;;;
;;; - Various imports from the char-set library for the routines that can
;;; take char-set arguments;
;;;
;;; - An ASSERTION-VIOLATION procedure;
;;;
;;; - BITWISE-AND for the hash functions;
;;;
;;; - A simple CHECK-ARG procedure for checking parameter values; it is
;;; (lambda (pred val proc)
;;; (if (pred val) val (assertion-violation 'check-arg "Bad arg" val pred proc)))
;;;
;;; - :OPTIONAL and LET-OPTIONALS* macros for parsing, defaulting &
;;; type-checking optional parameters from a rest argument;
;;;
;;; - CHAR-CASED? and CHAR-TITLECASE for the STRING-TITLECASE &
;;; STRING-TITLECASE! procedures. The former returns true iff a character is
;;; one that has case distinctions; in ASCII it returns true on a-z and A-Z.
;;; CHAR-TITLECASE is analagous to CHAR-UPCASE and CHAR-DOWNCASE. In ASCII &
;;; Latin-1, it is the same as CHAR-UPCASE.
;;;
;;; The code depends upon a small set of core string primitives from R5RS:
;;; MAKE-STRING STRING-REF STRING-SET! STRING? STRING-LENGTH SUBSTRING
;;; (Actually, SUBSTRING is not a primitive, but we assume that an
;;; implementation's native version is probably faster than one we could
;;; define, so we import it from R5RS.)
;;;
;;; The code depends upon a small set of R5RS character primitives:
;;; char? char=? char-ci=? char<? char-ci<?
;;; char-upcase char-downcase
;;; char->integer (for the hash functions)
;;;
;;; We assume the following:
;;; - CHAR-DOWNCASE o CHAR-UPCASE = CHAR-DOWNCASE
;;; - CHAR-CI=? is equivalent to
;;; (lambda (c1 c2) (char=? (char-downcase (char-upcase c1))
;;; (char-downcase (char-upcase c2))))
;;; - CHAR-UPCASE, CHAR-DOWNCASE and CHAR-TITLECASE are locale-insensitive
;;; and consistent with Unicode's 1-1 char-mapping spec.
;;; These things are typically true, but if not, you would need to modify
;;; the case-mapping and case-insensitive routines.
;;; Enough introductory blather. On to the source code. (But see the end of
;;; the file for further notes on porting & performance tuning.)
; Start S48 additions
(define (check-arg pred val caller)
(if (not (pred val))
(assertion-violation caller "invalid argument" val))
val)
(define-syntax :optional
(syntax-rules ()
((:optional rest default-exp)
(let ((maybe-arg rest))
(if (pair? maybe-arg)
(if (null? (cdr maybe-arg)) (car maybe-arg)
(apply assertion-violation ':optional
"too many optional arguments" maybe-arg))
default-exp)))
((:optional rest default-exp arg-test)
(let ((maybe-arg rest))
(if (pair? maybe-arg)
(if (null? (cdr maybe-arg))
(let ((val (car maybe-arg)))
(if (arg-test val)
val
(assertion-violation ':optional
"Optional argument failed test"
arg-test val)))
(apply assertion-violation ':optional
"too many optional arguments"
maybe-arg))
default-exp)))))
(define-syntax let-optionals*
(syntax-rules ()
((let-optionals* arg (opt-clause ...) body ...)
(let ((rest arg))
(%let-optionals* rest (opt-clause ...) body ...)))))
(define-syntax %let-optionals*
(syntax-rules ()
((%let-optionals* arg (((var ...) xparser) opt-clause ...) body ...)
(call-with-values (lambda () (xparser arg))
(lambda (rest var ...)
(%let-optionals* rest (opt-clause ...) body ...))))
((%let-optionals* arg ((var default) opt-clause ...) body ...)
(call-with-values (lambda () (if (null? arg) (values default '())
(values (car arg) (cdr arg))))
(lambda (var rest)
(%let-optionals* rest (opt-clause ...) body ...))))
((%let-optionals* arg ((var default test) opt-clause ...) body ...)
(call-with-values (lambda ()
(if (null? arg) (values default '())
(let ((var (car arg)))
(if test (values var (cdr arg))
(assertion-violation 'let-opt
"arg failed LET-OPT test" var)))))
(lambda (var rest)
(%let-optionals* rest (opt-clause ...) body ...))))
((%let-optionals* arg ((var default test supplied?) opt-clause ...) body ...)
(call-with-values (lambda ()
(if (null? arg) (values default #f '())
(let ((var (car arg)))
(if test (values var #t (cdr arg))
(assertion-violation 'let-opt
"arg failed LET-OPT test" var)))))
(lambda (var supplied? rest)
(%let-optionals* rest (opt-clause ...) body ...))))
((%let-optionals* arg (rest) body ...)
(let ((rest arg)) body ...))
((%let-optionals* arg () body ...)
(if (null? arg) (begin body ...)
(assertion-violation 'let-opt "Too many arguments in let-opt" arg)))))
(define (char-cased? c)
(or (char-lower-case? c)
(char-upper-case? c)
(char-title-case? c)))
; End S48 additions
;;; Support for START/END substring specs
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; This macro parses optional start/end arguments from arg lists, defaulting
;;; them to 0/(string-length s), and checks them for correctness.
(define-syntax let-string-start+end
(syntax-rules ()
((let-string-start+end (start end) proc s-exp args-exp body ...)
(receive (start end) (string-parse-final-start+end 'proc s-exp args-exp)
body ...))
((let-string-start+end (start end rest) proc s-exp args-exp body ...)
(receive (rest start end) (string-parse-start+end 'proc s-exp args-exp)
body ...))))
;;; This one parses out a *pair* of final start/end indices.
;;; Not exported; for internal use.
(define-syntax let-string-start+end2
(syntax-rules ()
((l-s-s+e2 (start1 end1 start2 end2) proc s1 s2 args body ...)
(let ((procv proc)) ; Make sure PROC is only evaluated once.
(let-string-start+end (start1 end1 rest) procv s1 args
(let-string-start+end (start2 end2) procv s2 rest
body ...))))))
;;; Returns three values: rest start end
(define (string-parse-start+end proc s args)
(if (not (string? s)) (assertion-violation proc "Non-string value" s))
(let ((slen (string-length s)))
(if (pair? args)
(let ((start (car args))
(args (cdr args)))
(if (and (integer? start) (exact? start) (>= start 0))
(receive (end args)
(if (pair? args)
(let ((end (car args))
(args (cdr args)))
(if (and (integer? end) (exact? end) (<= end slen))
(values end args)
(assertion-violation proc "Illegal substring END spec"
end s)))
(values slen args))
(if (<= start end) (values args start end)
(assertion-violation proc "Illegal substring START/END spec"
start end s)))
(assertion-violation proc "Illegal substring START spec" start s)))
(values '() 0 slen))))
(define (string-parse-final-start+end proc s args)
(receive (rest start end) (string-parse-start+end proc s args)
(if (pair? rest)
(assertion-violation proc "Extra arguments to procedure" rest)
(values start end))))
(define (substring-spec-ok? s start end)
(and (string? s)
(integer? start)
(exact? start)
(integer? end)
(exact? end)
(<= 0 start)
(<= start end)
(<= end (string-length s))))
(define (check-substring-spec proc s start end)
(if (not (substring-spec-ok? s start end))
(assertion-violation proc "Illegal substring spec." s start end)))
;;; Defined by R5RS, so commented out here.
;(define (string . chars)
; (let* ((len (length chars))
; (ans (make-string len)))
; (do ((i 0 (+ i 1))
; (chars chars (cdr chars)))
; ((>= i len))
; (string-set! ans i (car chars)))
; ans))
;
;(define (string . chars) (string-unfold null? car cdr chars))
;;; substring/shared S START [END]
;;; string-copy S [START END]
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; All this goop is just arg parsing & checking surrounding a call to the
;;; actual primitive, %SUBSTRING/SHARED.
(define (substring/shared s start . maybe-end)
(check-arg string? s 'substring/shared)
(let ((slen (string-length s)))
(check-arg (lambda (start) (and (integer? start) (exact? start) (<= 0 start)))
start 'substring/shared)
(%substring/shared s start
(:optional maybe-end slen
(lambda (end) (and (integer? end)
(exact? end)
(<= start end)
(<= end slen)))))))
;;; Split out so that other routines in this library can avoid arg-parsing
;;; overhead for END parameter.
(define (%substring/shared s start end)
(if (and (zero? start) (= end (string-length s))) s
(substring s start end)))
(define (string-copy s . maybe-start+end)
(let-string-start+end (start end) string-copy s maybe-start+end
(substring s start end)))
;This library uses the R5RS SUBSTRING, but doesn't export it.
;Here is a definition, just for completeness.
;(define (substring s start end)
; (check-substring-spec 'substring s start end)
; (let* ((slen (- end start))
; (ans (make-string slen)))
; (do ((i 0 (+ i 1))
; (j start (+ j 1)))
; ((>= i slen) ans)
; (string-set! ans i (string-ref s j)))))
;;; Basic iterators and other higher-order abstractions
;;; (string-map proc s [start end])
;;; (string-map! proc s [start end])
;;; (string-fold kons knil s [start end])
;;; (string-fold-right kons knil s [start end])
;;; (string-unfold p f g seed [base make-final])
;;; (string-unfold-right p f g seed [base make-final])
;;; (string-for-each proc s [start end])
;;; (string-for-each-index proc s [start end])
;;; (string-every char-set/char/pred s [start end])
;;; (string-any char-set/char/pred s [start end])
;;; (string-tabulate proc len)
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; You want compiler support for high-level transforms on fold and unfold ops.
;;; You'd at least like a lot of inlining for clients of these procedures.
;;; Don't hold your breath.
(define (string-map proc s . maybe-start+end)
(check-arg procedure? proc 'string-map)
(let-string-start+end (start end) string-map s maybe-start+end
(%string-map proc s start end)))
(define (%string-map proc s start end) ; Internal utility
(let* ((len (- end start))
(ans (make-string len)))
(do ((i (- end 1) (- i 1))
(j (- len 1) (- j 1)))
((< j 0))
(string-set! ans j (proc (string-ref s i))))
ans))
(define (string-map! proc s . maybe-start+end)
(check-arg procedure? proc 'string-map!)
(let-string-start+end (start end) string-map! s maybe-start+end
(%string-map! proc s start end)))
(define (%string-map! proc s start end)
(do ((i (- end 1) (- i 1)))
((< i start))
(string-set! s i (proc (string-ref s i)))))
(define (string-fold kons knil s . maybe-start+end)
(check-arg procedure? kons 'string-fold)
(let-string-start+end (start end) string-fold s maybe-start+end
(let lp ((v knil) (i start))
(if (< i end) (lp (kons (string-ref s i) v) (+ i 1))
v))))
(define (string-fold-right kons knil s . maybe-start+end)
(check-arg procedure? kons 'string-fold-right)
(let-string-start+end (start end) string-fold-right s maybe-start+end
(let lp ((v knil) (i (- end 1)))
(if (>= i start) (lp (kons (string-ref s i) v) (- i 1))
v))))
;;; (string-unfold p f g seed [base make-final])
;;; This is the fundamental constructor for strings.
;;; - G is used to generate a series of "seed" values from the initial seed:
;;; SEED, (G SEED), (G^2 SEED), (G^3 SEED), ...
;;; - P tells us when to stop -- when it returns true when applied to one
;;; of these seed values.
;;; - F maps each seed value to the corresponding character
;;; in the result string. These chars are assembled into the
;;; string in a left-to-right order.
;;; - BASE is the optional initial/leftmost portion of the constructed string;
;;; it defaults to the empty string "".
;;; - MAKE-FINAL is applied to the terminal seed value (on which P returns
;;; true) to produce the final/rightmost portion of the constructed string.
;;; It defaults to (LAMBDA (X) "").
;;;
;;; In other words, the following (simple, inefficient) definition holds:
;;; (define (string-unfold p f g seed base make-final)
;;; (string-append base
;;; (let recur ((seed seed))
;;; (if (p seed) (make-final seed)
;;; (string-append (string (f seed))
;;; (recur (g seed)))))))
;;;
;;; STRING-UNFOLD is a fairly powerful constructor -- you can use it to
;;; reverse a string, copy a string, convert a list to a string, read
;;; a port into a string, and so forth. Examples:
;;; (port->string port) =
;;; (string-unfold (compose eof-object? peek-char)
;;; read-char values port)
;;;
;;; (list->string lis) = (string-unfold null? car cdr lis)
;;;
;;; (tabulate-string f size) = (string-unfold (lambda (i) (= i size)) f add1 0)
;;; A problem with the following simple formulation is that it pushes one
;;; stack frame for every char in the result string -- an issue if you are
;;; using it to read a 100kchar string. So we don't use it -- but I include
;;; it to give a clear, straightforward description of what the function
;;; does.
;(define (string-unfold p f g seed base make-final)
; (let ((ans (let recur ((seed seed) (i (string-length base)))
; (if (p seed)
; (let* ((final (make-final seed))
; (ans (make-string (+ i (string-length final)))))
; (string-copy! ans i final)
; ans)
;
; (let* ((c (f seed))
; (s (recur (g seed) (+ i 1))))
; (string-set! s i c)
; s)))))
; (string-copy! ans 0 base)
; ans))
;;; The strategy is to allocate a series of chunks into which we stash the
;;; chars as we generate them. Chunk size goes up in powers of two starting
;;; with 40 and levelling out at 4k, i.e.
;;; 40 40 80 160 320 640 1280 2560 4096 4096 4096 4096 4096...
;;; This should work pretty well for short strings, 1-line (80 char) strings,
;;; and longer ones. When done, we allocate an answer string and copy the
;;; chars over from the chunk buffers.
(define (string-unfold p f g seed . base+make-final)
(check-arg procedure? p 'string-unfold)
(check-arg procedure? f 'string-unfold)
(check-arg procedure? g 'string-unfold)
(let-optionals* base+make-final
((base "" (string? base))
(make-final (lambda (x) "") (procedure? make-final)))
(let lp ((chunks '()) ; Previously filled chunks
(nchars 0) ; Number of chars in CHUNKS
(chunk (make-string 40)) ; Current chunk into which we write
(chunk-len 40)
(i 0) ; Number of chars written into CHUNK
(seed seed))
(let lp2 ((i i) (seed seed))
(if (not (p seed))
(let ((c (f seed))
(seed (g seed)))
(if (< i chunk-len)
(begin (string-set! chunk i c)
(lp2 (+ i 1) seed))
(let* ((nchars2 (+ chunk-len nchars))
(chunk-len2 (min 4096 nchars2))
(new-chunk (make-string chunk-len2)))
(string-set! new-chunk 0 c)
(lp (cons chunk chunks) (+ nchars chunk-len)
new-chunk chunk-len2 1 seed))))
;; We're done. Make the answer string & install the bits.
(let* ((final (make-final seed))
(flen (string-length final))
(base-len (string-length base))
(j (+ base-len nchars i))
(ans (make-string (+ j flen))))
(%string-copy! ans j final 0 flen) ; Install FINAL.
(let ((j (- j i)))
(%string-copy! ans j chunk 0 i) ; Install CHUNK[0,I).
(let lp ((j j) (chunks chunks)) ; Install CHUNKS.
(if (pair? chunks)
(let* ((chunk (car chunks))
(chunks (cdr chunks))
(chunk-len (string-length chunk))
(j (- j chunk-len)))
(%string-copy! ans j chunk 0 chunk-len)
(lp j chunks)))))
(%string-copy! ans 0 base 0 base-len) ; Install BASE.
ans))))))
(define (string-unfold-right p f g seed . base+make-final)
(let-optionals* base+make-final
((base "" (string? base))
(make-final (lambda (x) "") (procedure? make-final)))
(let lp ((chunks '()) ; Previously filled chunks
(nchars 0) ; Number of chars in CHUNKS
(chunk (make-string 40)) ; Current chunk into which we write
(chunk-len 40)
(i 40) ; Number of chars available in CHUNK
(seed seed))
(let lp2 ((i i) (seed seed)) ; Fill up CHUNK from right
(if (not (p seed)) ; to left.
(let ((c (f seed))
(seed (g seed)))
(if (> i 0)
(let ((i (- i 1)))
(string-set! chunk i c)
(lp2 i seed))
(let* ((nchars2 (+ chunk-len nchars))
(chunk-len2 (min 4096 nchars2))
(new-chunk (make-string chunk-len2))
(i (- chunk-len2 1)))
(string-set! new-chunk i c)
(lp (cons chunk chunks) (+ nchars chunk-len)
new-chunk chunk-len2 i seed))))
;; We're done. Make the answer string & install the bits.
(let* ((final (make-final seed))
(flen (string-length final))
(base-len (string-length base))
(chunk-used (- chunk-len i))
(j (+ base-len nchars chunk-used))
(ans (make-string (+ j flen))))
(%string-copy! ans 0 final 0 flen) ; Install FINAL.
(%string-copy! ans flen chunk i chunk-len); Install CHUNK[I,).
(let lp ((j (+ flen chunk-used)) ; Install CHUNKS.
(chunks chunks))
(if (pair? chunks)
(let* ((chunk (car chunks))
(chunks (cdr chunks))
(chunk-len (string-length chunk)))
(%string-copy! ans j chunk 0 chunk-len)
(lp (+ j chunk-len) chunks))
(%string-copy! ans j base 0 base-len))); Install BASE.
ans))))))
(define (string-for-each proc s . maybe-start+end)
(check-arg procedure? proc 'string-for-each)
(let-string-start+end (start end) string-for-each s maybe-start+end
(let lp ((i start))
(if (< i end)
(begin (proc (string-ref s i))
(lp (+ i 1)))))))
(define (string-for-each-index proc s . maybe-start+end)
(check-arg procedure? proc 'string-for-each-index)
(let-string-start+end (start end) string-for-each-index s maybe-start+end
(let lp ((i start))
(if (< i end) (begin (proc i) (lp (+ i 1)))))))
(define (string-every criterion s . maybe-start+end)
(let-string-start+end (start end) string-every s maybe-start+end
(cond ((char? criterion)
(let lp ((i start))
(or (>= i end)
(and (char=? criterion (string-ref s i))
(lp (+ i 1))))))
((char-set? criterion)
(let lp ((i start))
(or (>= i end)
(and (char-set-contains? criterion (string-ref s i))
(lp (+ i 1))))))
((procedure? criterion) ; Slightly funky loop so that
(or (= start end) ; final (PRED S[END-1]) call
(let lp ((i start)) ; is a tail call.
(let ((c (string-ref s i))
(i1 (+ i 1)))
(if (= i1 end) (criterion c) ; Tail call.
(and (criterion c) (lp i1)))))))
(else (assertion-violation 'string-every
"Second param is neither char-set, char, or predicate procedure."
criterion)))))
(define (string-any criterion s . maybe-start+end)
(let-string-start+end (start end) string-any s maybe-start+end
(cond ((char? criterion)
(let lp ((i start))
(and (< i end)
(or (char=? criterion (string-ref s i))
(lp (+ i 1))))))
((char-set? criterion)
(let lp ((i start))
(and (< i end)
(or (char-set-contains? criterion (string-ref s i))
(lp (+ i 1))))))
((procedure? criterion) ; Slightly funky loop so that
(and (< start end) ; final (PRED S[END-1]) call
(let lp ((i start)) ; is a tail call.
(let ((c (string-ref s i))
(i1 (+ i 1)))
(if (= i1 end) (criterion c) ; Tail call
(or (criterion c) (lp i1)))))))
(else (assertion-violation 'string-any
"Second param is neither char-set, char, or predicate procedure."
criterion)))))
(define (string-tabulate proc len)
(check-arg procedure? proc 'string-tabulate)
(check-arg (lambda (val) (and (integer? val) (exact? val) (<= 0 val)))
len 'string-tabulate)
(let ((s (make-string len)))
(do ((i (- len 1) (- i 1)))
((< i 0))
(string-set! s i (proc i)))
s))
;;; string-prefix-length[-ci] s1 s2 [start1 end1 start2 end2]
;;; string-suffix-length[-ci] s1 s2 [start1 end1 start2 end2]
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; Find the length of the common prefix/suffix.
;;; It is not required that the two substrings passed be of equal length.
;;; This was microcode in MIT Scheme -- a very tightly bummed primitive.
;;; %STRING-PREFIX-LENGTH is the core routine of all string-comparisons,
;;; so should be as tense as possible.
(define (%string-prefix-length s1 start1 end1 s2 start2 end2)
(let* ((delta (min (- end1 start1) (- end2 start2)))
(end1 (+ start1 delta)))
(if (and (eq? s1 s2) (= start1 start2)) ; EQ fast path
delta
(let lp ((i start1) (j start2)) ; Regular path
(if (or (>= i end1)
(not (char=? (string-ref s1 i)
(string-ref s2 j))))
(- i start1)
(lp (+ i 1) (+ j 1)))))))
(define (%string-suffix-length s1 start1 end1 s2 start2 end2)
(let* ((delta (min (- end1 start1) (- end2 start2)))
(start1 (- end1 delta)))
(if (and (eq? s1 s2) (= end1 end2)) ; EQ fast path
delta
(let lp ((i (- end1 1)) (j (- end2 1))) ; Regular path
(if (or (< i start1)
(not (char=? (string-ref s1 i)
(string-ref s2 j))))
(- (- end1 i) 1)
(lp (- i 1) (- j 1)))))))
(define (%string-prefix-length-ci s1 start1 end1 s2 start2 end2)
(let* ((delta (min (- end1 start1) (- end2 start2)))
(end1 (+ start1 delta)))
(if (and (eq? s1 s2) (= start1 start2)) ; EQ fast path
delta
(let lp ((i start1) (j start2)) ; Regular path
(if (or (>= i end1)
(not (char-ci=? (string-ref s1 i)
(string-ref s2 j))))
(- i start1)
(lp (+ i 1) (+ j 1)))))))
(define (%string-suffix-length-ci s1 start1 end1 s2 start2 end2)
(let* ((delta (min (- end1 start1) (- end2 start2)))
(start1 (- end1 delta)))
(if (and (eq? s1 s2) (= end1 end2)) ; EQ fast path
delta
(let lp ((i (- end1 1)) (j (- end2 1))) ; Regular path
(if (or (< i start1)
(not (char-ci=? (string-ref s1 i)
(string-ref s2 j))))
(- (- end1 i) 1)
(lp (- i 1) (- j 1)))))))
(define (string-prefix-length s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-prefix-length s1 s2 maybe-starts+ends
(%string-prefix-length s1 start1 end1 s2 start2 end2)))
(define (string-suffix-length s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-suffix-length s1 s2 maybe-starts+ends
(%string-suffix-length s1 start1 end1 s2 start2 end2)))
(define (string-prefix-length-ci s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-prefix-length-ci s1 s2 maybe-starts+ends
(%string-prefix-length-ci s1 start1 end1 s2 start2 end2)))
(define (string-suffix-length-ci s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-suffix-length-ci s1 s2 maybe-starts+ends
(%string-suffix-length-ci s1 start1 end1 s2 start2 end2)))
;;; string-prefix? s1 s2 [start1 end1 start2 end2]
;;; string-suffix? s1 s2 [start1 end1 start2 end2]
;;; string-prefix-ci? s1 s2 [start1 end1 start2 end2]
;;; string-suffix-ci? s1 s2 [start1 end1 start2 end2]
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; These are all simple derivatives of the previous counting funs.
(define (string-prefix? s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-prefix? s1 s2 maybe-starts+ends
(%string-prefix? s1 start1 end1 s2 start2 end2)))
(define (string-suffix? s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-suffix? s1 s2 maybe-starts+ends
(%string-suffix? s1 start1 end1 s2 start2 end2)))
(define (string-prefix-ci? s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-prefix-ci? s1 s2 maybe-starts+ends
(%string-prefix-ci? s1 start1 end1 s2 start2 end2)))
(define (string-suffix-ci? s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-suffix-ci? s1 s2 maybe-starts+ends
(%string-suffix-ci? s1 start1 end1 s2 start2 end2)))
;;; Here are the internal routines that do the real work.
(define (%string-prefix? s1 start1 end1 s2 start2 end2)
(let ((len1 (- end1 start1)))
(and (<= len1 (- end2 start2)) ; Quick check
(= (%string-prefix-length s1 start1 end1
s2 start2 end2)
len1))))
(define (%string-suffix? s1 start1 end1 s2 start2 end2)
(let ((len1 (- end1 start1)))
(and (<= len1 (- end2 start2)) ; Quick check
(= len1 (%string-suffix-length s1 start1 end1
s2 start2 end2)))))
(define (%string-prefix-ci? s1 start1 end1 s2 start2 end2)
(let ((len1 (- end1 start1)))
(and (<= len1 (- end2 start2)) ; Quick check
(= len1 (%string-prefix-length-ci s1 start1 end1
s2 start2 end2)))))
(define (%string-suffix-ci? s1 start1 end1 s2 start2 end2)
(let ((len1 (- end1 start1)))
(and (<= len1 (- end2 start2)) ; Quick check
(= len1 (%string-suffix-length-ci s1 start1 end1
s2 start2 end2)))))
;;; string-compare s1 s2 proc< proc= proc> [start1 end1 start2 end2]
;;; string-compare-ci s1 s2 proc< proc= proc> [start1 end1 start2 end2]
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; Primitive string-comparison functions.
;;; Continuation order is different from MIT Scheme.
;;; Continuations are applied to s1's mismatch index;
;;; in the case of equality, this is END1.
(define (%string-compare s1 start1 end1 s2 start2 end2
proc< proc= proc>)
(let ((size1 (- end1 start1))
(size2 (- end2 start2)))
(let ((match (%string-prefix-length s1 start1 end1 s2 start2 end2)))
(if (= match size1)
((if (= match size2) proc= proc<) end1)
((if (= match size2)
proc>
(if (char<? (string-ref s1 (+ start1 match))
(string-ref s2 (+ start2 match)))
proc< proc>))
(+ match start1))))))
(define (%string-compare-ci s1 start1 end1 s2 start2 end2
proc< proc= proc>)
(let ((size1 (- end1 start1))
(size2 (- end2 start2)))
(let ((match (%string-prefix-length-ci s1 start1 end1 s2 start2 end2)))
(if (= match size1)
((if (= match size2) proc= proc<) end1)
((if (= match size2) proc>
(if (char-ci<? (string-ref s1 (+ start1 match))
(string-ref s2 (+ start2 match)))
proc< proc>))
(+ start1 match))))))
(define (string-compare s1 s2 proc< proc= proc> . maybe-starts+ends)
(check-arg procedure? proc< 'string-compare)
(check-arg procedure? proc= 'string-compare)
(check-arg procedure? proc> 'string-compare)
(let-string-start+end2 (start1 end1 start2 end2)
string-compare s1 s2 maybe-starts+ends
(%string-compare s1 start1 end1 s2 start2 end2 proc< proc= proc>)))
(define (string-compare-ci s1 s2 proc< proc= proc> . maybe-starts+ends)
(check-arg procedure? proc< 'string-compare-ci)
(check-arg procedure? proc= 'string-compare-ci)
(check-arg procedure? proc> 'string-compare-ci)
(let-string-start+end2 (start1 end1 start2 end2)
string-compare-ci s1 s2 maybe-starts+ends
(%string-compare-ci s1 start1 end1 s2 start2 end2 proc< proc= proc>)))
;;; string= string<> string-ci= string-ci<>
;;; string< string> string-ci< string-ci>
;;; string<= string>= string-ci<= string-ci>=
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; Simple definitions in terms of the previous comparison funs.
;;; I sure hope the %STRING-COMPARE calls get integrated.
(define (string= s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string= s1 s2 maybe-starts+ends
(and (= (- end1 start1) (- end2 start2)) ; Quick filter
(or (and (eq? s1 s2) (= start1 start2)) ; Fast path
(%string-compare s1 start1 end1 s2 start2 end2 ; Real test
(lambda (i) #f)
(lambda (i) #t)
(lambda (i) #f))))))
(define (string<> s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string<> s1 s2 maybe-starts+ends
(or (not (= (- end1 start1) (- end2 start2))) ; Fast path
(and (not (and (eq? s1 s2) (= start1 start2))) ; Quick filter
(%string-compare s1 start1 end1 s2 start2 end2 ; Real test
(lambda (i) #t)
(lambda (i) #f)
(lambda (i) #t))))))
(define (string< s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string< s1 s2 maybe-starts+ends
(if (and (eq? s1 s2) (= start1 start2)) ; Fast path
(< end1 end2)
(%string-compare s1 start1 end1 s2 start2 end2 ; Real test
(lambda (i) #t)
(lambda (i) #f)
(lambda (i) #f)))))
(define (string> s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string> s1 s2 maybe-starts+ends
(if (and (eq? s1 s2) (= start1 start2)) ; Fast path
(> end1 end2)
(%string-compare s1 start1 end1 s2 start2 end2 ; Real test
(lambda (i) #f)
(lambda (i) #f)
(lambda (i) #t)))))
(define (string<= s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string<= s1 s2 maybe-starts+ends
(if (and (eq? s1 s2) (= start1 start2)) ; Fast path
(<= end1 end2)
(%string-compare s1 start1 end1 s2 start2 end2 ; Real test
(lambda (i) #t)
(lambda (i) #t)
(lambda (i) #f)))))
(define (string>= s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string>= s1 s2 maybe-starts+ends
(if (and (eq? s1 s2) (= start1 start2)) ; Fast path
(>= end1 end2)
(%string-compare s1 start1 end1 s2 start2 end2 ; Real test
(lambda (i) #f)
(lambda (i) #t)
(lambda (i) #t)))))
(define (string-ci= s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-ci= s1 s2 maybe-starts+ends
(and (= (- end1 start1) (- end2 start2)) ; Quick filter
(or (and (eq? s1 s2) (= start1 start2)) ; Fast path
(%string-compare-ci s1 start1 end1 s2 start2 end2 ; Real test
(lambda (i) #f)
(lambda (i) #t)
(lambda (i) #f))))))
(define (string-ci<> s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-ci<> s1 s2 maybe-starts+ends
(or (not (= (- end1 start1) (- end2 start2))) ; Fast path
(and (not (and (eq? s1 s2) (= start1 start2))) ; Quick filter
(%string-compare-ci s1 start1 end1 s2 start2 end2 ; Real test
(lambda (i) #t)
(lambda (i) #f)
(lambda (i) #t))))))
(define (string-ci< s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-ci< s1 s2 maybe-starts+ends
(if (and (eq? s1 s2) (= start1 start2)) ; Fast path
(< end1 end2)
(%string-compare-ci s1 start1 end1 s2 start2 end2 ; Real test
(lambda (i) #t)
(lambda (i) #f)
(lambda (i) #f)))))
(define (string-ci> s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-ci> s1 s2 maybe-starts+ends
(if (and (eq? s1 s2) (= start1 start2)) ; Fast path
(> end1 end2)
(%string-compare-ci s1 start1 end1 s2 start2 end2 ; Real test
(lambda (i) #f)
(lambda (i) #f)
(lambda (i) #t)))))
(define (string-ci<= s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-ci<= s1 s2 maybe-starts+ends
(if (and (eq? s1 s2) (= start1 start2)) ; Fast path
(<= end1 end2)
(%string-compare-ci s1 start1 end1 s2 start2 end2 ; Real test
(lambda (i) #t)
(lambda (i) #t)
(lambda (i) #f)))))
(define (string-ci>= s1 s2 . maybe-starts+ends)
(let-string-start+end2 (start1 end1 start2 end2)
string-ci>= s1 s2 maybe-starts+ends
(if (and (eq? s1 s2) (= start1 start2)) ; Fast path
(>= end1 end2)
(%string-compare-ci s1 start1 end1 s2 start2 end2 ; Real test
(lambda (i) #f)
(lambda (i) #t)
(lambda (i) #t)))))
;;; Hash
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; Compute (c + 37 c + 37^2 c + ...) modulo BOUND, with sleaze thrown in
;;; to keep the intermediate values small. (We do the calculation with just
;;; enough bits to represent BOUND, masking off high bits at each step in
;;; calculation. If this screws up any important properties of the hash
;;; function I'd like to hear about it. -Olin)
;;;
;;; If you keep BOUND small enough, the intermediate calculations will
;;; always be fixnums. How small is dependent on the underlying Scheme system;
;;; we use a default BOUND of 2^22 = 4194304, which should hack it in
;;; Schemes that give you at least 29 signed bits for fixnums. The core
;;; calculation that you don't want to overflow is, worst case,
;;; (+ 65535 (* 37 (- bound 1)))
;;; where 65535 is the max character code. Choose the default BOUND to be the
;;; biggest power of two that won't cause this expression to fixnum overflow,
;;; and everything will be copacetic.
(define (%string-hash s char->int bound start end)
(let ((iref (lambda (s i) (char->int (string-ref s i))))
;; Compute a 111...1 mask that will cover BOUND-1:
(mask (let lp ((i #x10000)) ; Let's skip first 16 iterations, eh?
(if (>= i bound) (- i 1) (lp (+ i i))))))
(let lp ((i start) (ans 0))
(if (>= i end) (modulo ans bound)
(lp (+ i 1) (bitwise-and mask (+ (* 37 ans) (iref s i))))))))
(define (string-hash s . maybe-bound+start+end)
(let-optionals* maybe-bound+start+end ((bound 4194304 (and (integer? bound)
(exact? bound)
(<= 0 bound)))
rest)
(let ((bound (if (zero? bound) 4194304 bound))) ; 0 means default.
(let-string-start+end (start end) string-hash s rest
(%string-hash s char->integer bound start end)))))
(define (string-hash-ci s . maybe-bound+start+end)
(let-optionals* maybe-bound+start+end ((bound 4194304 (and (integer? bound)
(exact? bound)
(<= 0 bound)))
rest)
(let ((bound (if (zero? bound) 4194304 bound))) ; 0 means default.
(let-string-start+end (start end) string-hash-ci s rest
(%string-hash s (lambda (c) (char->integer (char-downcase c)))
bound start end)))))
;;; Case hacking
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; string-upcase s [start end]
;;; string-upcase! s [start end]
;;; string-downcase s [start end]
;;; string-downcase! s [start end]
;;;
;;; string-titlecase s [start end]
;;; string-titlecase! s [start end]
;;; Capitalize every contiguous alpha sequence: capitalise
;;; first char, lowercase rest.
(define (string-upcase s . maybe-start+end)
(let-string-start+end (start end) string-upcase s maybe-start+end
(%string-map char-upcase s start end)))
(define (string-upcase! s . maybe-start+end)
(let-string-start+end (start end) string-upcase! s maybe-start+end
(%string-map! char-upcase s start end)))
(define (string-downcase s . maybe-start+end)
(let-string-start+end (start end) string-downcase s maybe-start+end
(%string-map char-downcase s start end)))
(define (string-downcase! s . maybe-start+end)
(let-string-start+end (start end) string-downcase! s maybe-start+end
(%string-map! char-downcase s start end)))
(define (%string-titlecase! s start end)
(let lp ((i start))
(cond ((string-index s char-cased? i end) =>
(lambda (i)
(string-set! s i (char-titlecase (string-ref s i)))
(let ((i1 (+ i 1)))
(cond ((string-skip s char-cased? i1 end) =>
(lambda (j)
(string-downcase! s i1 j)
(lp (+ j 1))))
(else (string-downcase! s i1 end)))))))))
(define (string-titlecase! s . maybe-start+end)
(let-string-start+end (start end) string-titlecase! s maybe-start+end
(%string-titlecase! s start end)))
(define (string-titlecase s . maybe-start+end)
(let-string-start+end (start end) string-titlecase! s maybe-start+end
(let ((ans (substring s start end)))
(%string-titlecase! ans 0 (- end start))
ans)))
;;; Cutting & pasting strings
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; string-take string nchars
;;; string-drop string nchars
;;;
;;; string-take-right string nchars
;;; string-drop-right string nchars
;;;
;;; string-pad string k [char start end]
;;; string-pad-right string k [char start end]
;;;
;;; string-trim string [char/char-set/pred start end]
;;; string-trim-right string [char/char-set/pred start end]
;;; string-trim-both string [char/char-set/pred start end]
;;;
;;; These trimmers invert the char-set meaning from MIT Scheme -- you
;;; say what you want to trim.
(define (string-take s n)
(check-arg string? s 'string-take)
(check-arg (lambda (val) (and (integer? n) (exact? n)
(<= 0 n (string-length s))))
n 'string-take)
(%substring/shared s 0 n))
(define (string-take-right s n)
(check-arg string? s 'string-take-right)
(let ((len (string-length s)))
(check-arg (lambda (val) (and (integer? n) (exact? n) (<= 0 n len)))
n 'string-take-right)
(%substring/shared s (- len n) len)))
(define (string-drop s n)
(check-arg string? s 'string-drop)
(let ((len (string-length s)))
(check-arg (lambda (val) (and (integer? n) (exact? n) (<= 0 n len)))
n 'string-drop)
(%substring/shared s n len)))
(define (string-drop-right s n)
(check-arg string? s 'string-drop-right)
(let ((len (string-length s)))
(check-arg (lambda (val) (and (integer? n) (exact? n) (<= 0 n len)))
n 'string-drop-right)
(%substring/shared s 0 (- len n))))
(define (string-trim s . criterion+start+end)
(let-optionals* criterion+start+end ((criterion char-set:whitespace) rest)
(let-string-start+end (start end) string-trim s rest
(cond ((string-skip s criterion start end) =>
(lambda (i) (%substring/shared s i end)))
(else "")))))
(define (string-trim-right s . criterion+start+end)
(let-optionals* criterion+start+end ((criterion char-set:whitespace) rest)
(let-string-start+end (start end) string-trim-right s rest
(cond ((string-skip-right s criterion start end) =>
(lambda (i) (%substring/shared s 0 (+ 1 i))))
(else "")))))
(define (string-trim-both s . criterion+start+end)
(let-optionals* criterion+start+end ((criterion char-set:whitespace) rest)
(let-string-start+end (start end) string-trim-both s rest
(cond ((string-skip s criterion start end) =>
(lambda (i)
(%substring/shared s i (+ 1 (string-skip-right s criterion i end)))))
(else "")))))
(define (string-pad-right s n . char+start+end)
(let-optionals* char+start+end ((char #\space (char? char)) rest)
(let-string-start+end (start end) string-pad-right s rest
(check-arg (lambda (n) (and (integer? n) (exact? n) (<= 0 n)))
n 'string-pad-right)
(let ((len (- end start)))
(if (<= n len)
(%substring/shared s start (+ start n))
(let ((ans (make-string n char)))
(%string-copy! ans 0 s start end)
ans))))))
(define (string-pad s n . char+start+end)
(let-optionals* char+start+end ((char #\space (char? char)) rest)
(let-string-start+end (start end) string-pad s rest
(check-arg (lambda (n) (and (integer? n) (exact? n) (<= 0 n)))
n 'string-pad)
(let ((len (- end start)))
(if (<= n len)
(%substring/shared s (- end n) end)
(let ((ans (make-string n char)))
(%string-copy! ans (- n len) s start end)
ans))))))
;;; Filtering strings
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; string-delete char/char-set/pred string [start end]
;;; string-filter char/char-set/pred string [start end]
;;;
;;; If the criterion is a char or char-set, we scan the string twice with
;;; string-fold -- once to determine the length of the result string,
;;; and once to do the filtered copy.
;;; If the criterion is a predicate, we don't do this double-scan strategy,
;;; because the predicate might have side-effects or be very expensive to
;;; compute. So we preallocate a temp buffer pessimistically, and only do
;;; one scan over S. This is likely to be faster and more space-efficient
;;; than consing a list.
(define (string-delete criterion s . maybe-start+end)
(let-string-start+end (start end) string-delete s maybe-start+end
(if (procedure? criterion)
(let* ((slen (- end start))
(temp (make-string slen))
(ans-len (string-fold (lambda (c i)
(if (criterion c) i
(begin (string-set! temp i c)
(+ i 1))))
0 s start end)))
(if (= ans-len slen) temp (substring temp 0 ans-len)))
(let* ((cset (cond ((char-set? criterion) criterion)
((char? criterion) (char-set criterion))
(else
(assertion-violation 'string-delete "string-delete criterion not predicate, char or char-set" criterion))))
(len (string-fold (lambda (c i) (if (char-set-contains? cset c)
i
(+ i 1)))
0 s start end))
(ans (make-string len)))
(string-fold (lambda (c i) (if (char-set-contains? cset c)
i
(begin (string-set! ans i c)
(+ i 1))))
0 s start end)
ans))))
(define (string-filter criterion s . maybe-start+end)
(let-string-start+end (start end) string-filter s maybe-start+end
(if (procedure? criterion)
(let* ((slen (- end start))
(temp (make-string slen))
(ans-len (string-fold (lambda (c i)
(if (criterion c)
(begin (string-set! temp i c)
(+ i 1))
i))
0 s start end)))
(if (= ans-len slen) temp (substring temp 0 ans-len)))
(let* ((cset (cond ((char-set? criterion) criterion)
((char? criterion) (char-set criterion))
(else (assertion-violation 'string-filter "string-filter criterion not predicate, char or char-set" criterion))))
(len (string-fold (lambda (c i) (if (char-set-contains? cset c)
(+ i 1)
i))
0 s start end))
(ans (make-string len)))
(string-fold (lambda (c i) (if (char-set-contains? cset c)
(begin (string-set! ans i c)
(+ i 1))
i))
0 s start end)
ans))))
;;; String search
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; string-index string char/char-set/pred [start end]
;;; string-index-right string char/char-set/pred [start end]
;;; string-skip string char/char-set/pred [start end]
;;; string-skip-right string char/char-set/pred [start end]
;;; string-count string char/char-set/pred [start end]
;;; There's a lot of replicated code here for efficiency.
;;; For example, the char/char-set/pred discrimination has
;;; been lifted above the inner loop of each proc.
(define (string-index str criterion . maybe-start+end)
(let-string-start+end (start end) string-index str maybe-start+end
(cond ((char? criterion)
(let lp ((i start))
(and (< i end)
(if (char=? criterion (string-ref str i)) i
(lp (+ i 1))))))
((char-set? criterion)
(let lp ((i start))
(and (< i end)
(if (char-set-contains? criterion (string-ref str i)) i
(lp (+ i 1))))))
((procedure? criterion)
(let lp ((i start))
(and (< i end)
(if (criterion (string-ref str i)) i
(lp (+ i 1))))))
(else (assertion-violation 'string-index
"Second param is neither char-set, char, or predicate procedure."
criterion)))))
(define (string-index-right str criterion . maybe-start+end)
(let-string-start+end (start end) string-index-right str maybe-start+end
(cond ((char? criterion)
(let lp ((i (- end 1)))
(and (>= i start)
(if (char=? criterion (string-ref str i)) i
(lp (- i 1))))))
((char-set? criterion)
(let lp ((i (- end 1)))
(and (>= i start)
(if (char-set-contains? criterion (string-ref str i)) i
(lp (- i 1))))))
((procedure? criterion)
(let lp ((i (- end 1)))
(and (>= i start)
(if (criterion (string-ref str i)) i
(lp (- i 1))))))
(else (assertion-violation
'string-index-right
"Second param is neither char-set, char, or predicate procedure."
criterion)))))
(define (string-skip str criterion . maybe-start+end)
(let-string-start+end (start end) string-skip str maybe-start+end
(cond ((char? criterion)
(let lp ((i start))
(and (< i end)
(if (char=? criterion (string-ref str i))
(lp (+ i 1))
i))))
((char-set? criterion)
(let lp ((i start))
(and (< i end)
(if (char-set-contains? criterion (string-ref str i))
(lp (+ i 1))
i))))
((procedure? criterion)
(let lp ((i start))
(and (< i end)
(if (criterion (string-ref str i)) (lp (+ i 1))
i))))
(else (assertion-violation
'string-skip
"Second param is neither char-set, char, or predicate procedure."
criterion)))))
(define (string-skip-right str criterion . maybe-start+end)
(let-string-start+end (start end) string-skip-right str maybe-start+end
(cond ((char? criterion)
(let lp ((i (- end 1)))
(and (>= i start)
(if (char=? criterion (string-ref str i))
(lp (- i 1))
i))))
((char-set? criterion)
(let lp ((i (- end 1)))
(and (>= i start)
(if (char-set-contains? criterion (string-ref str i))
(lp (- i 1))
i))))
((procedure? criterion)
(let lp ((i (- end 1)))
(and (>= i start)
(if (criterion (string-ref str i)) (lp (- i 1))
i))))
(else (assertion-violation 'string-skip-right
"CRITERION param is neither char-set or char."
criterion)))))
(define (string-count s criterion . maybe-start+end)
(let-string-start+end (start end) string-count s maybe-start+end
(cond ((char? criterion)
(do ((i start (+ i 1))
(count 0 (if (char=? criterion (string-ref s i))
(+ count 1)
count)))
((>= i end) count)))
((char-set? criterion)
(do ((i start (+ i 1))
(count 0 (if (char-set-contains? criterion (string-ref s i))
(+ count 1)
count)))
((>= i end) count)))
((procedure? criterion)
(do ((i start (+ i 1))
(count 0 (if (criterion (string-ref s i)) (+ count 1) count)))
((>= i end) count)))
(else (assertion-violation
'string-count
"CRITERION param is neither char-set or char."
criterion)))))
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; string-fill! string char [start end]
;;;
;;; string-copy! to tstart from [fstart fend]
;;; Guaranteed to work, even if s1 eq s2.
(define (string-fill! s char . maybe-start+end)
(check-arg char? char 'string-fill!)
(let-string-start+end (start end) string-fill! s maybe-start+end
(do ((i (- end 1) (- i 1)))
((< i start))
(string-set! s i char))))
(define (string-copy! to tstart from . maybe-fstart+fend)
(let-string-start+end (fstart fend) string-copy! from maybe-fstart+fend
(check-arg integer? tstart 'string-copy!)
(check-substring-spec 'string-copy! to tstart (+ tstart (- fend fstart)))
(%string-copy! to tstart from fstart fend)))
;;; Library-internal routine
(define (%string-copy! to tstart from fstart fend)
(if (> fstart tstart)
(do ((i fstart (+ i 1))
(j tstart (+ j 1)))
((>= i fend))
(string-set! to j (string-ref from i)))
(do ((i (- fend 1) (- i 1))
(j (+ -1 tstart (- fend fstart)) (- j 1)))
((< i fstart))
(string-set! to j (string-ref from i)))))
;;; Returns starting-position in STRING or #f if not true.
;;; This implementation is slow & simple. It is useful as a "spec" or for
;;; comparison testing with fancier implementations.
;;; See below for fast KMP version.
;(define (string-contains string substring . maybe-starts+ends)
; (let-string-start+end2 (start1 end1 start2 end2)
; string-contains string substring maybe-starts+ends
; (let* ((len (- end2 start2))
; (i-bound (- end1 len)))
; (let lp ((i start1))
; (and (< i i-bound)
; (if (string= string substring i (+ i len) start2 end2)
; i
; (lp (+ i 1))))))))
;;; Searching for an occurrence of a substring
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(define (string-contains text pattern . maybe-starts+ends)
(let-string-start+end2 (t-start t-end p-start p-end)
string-contains text pattern maybe-starts+ends
(%kmp-search pattern text char=? p-start p-end t-start t-end)))
(define (string-contains-ci text pattern . maybe-starts+ends)
(let-string-start+end2 (t-start t-end p-start p-end)
string-contains-ci text pattern maybe-starts+ends
(%kmp-search pattern text char-ci=? p-start p-end t-start t-end)))
;;; Knuth-Morris-Pratt string searching
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; See
;;; "Fast pattern matching in strings"
;;; SIAM J. Computing 6(2):323-350 1977
;;; D. E. Knuth, J. H. Morris and V. R. Pratt
;;; also described in
;;; "Pattern matching in strings"
;;; Alfred V. Aho
;;; Formal Language Theory - Perspectives and Open Problems
;;; Ronald V. Brook (editor)
;;; This algorithm is O(m + n) where m and n are the
;;; lengths of the pattern and string respectively
;;; KMP search source[start,end) for PATTERN. Return starting index of
;;; leftmost match or #f.
(define (%kmp-search pattern text c= p-start p-end t-start t-end)
(let ((plen (- p-end p-start))
(rv (make-kmp-restart-vector pattern c= p-start p-end)))
;; The search loop. TJ & PJ are redundant state.
(let lp ((ti t-start) (pi 0)
(tj (- t-end t-start)) ; (- tlen ti) -- how many chars left.
(pj plen)) ; (- plen pi) -- how many chars left.
(if (= pi plen)
(- ti plen) ; Win.
(and (<= pj tj) ; Lose.
(if (c= (string-ref text ti) ; Search.
(string-ref pattern (+ p-start pi)))
(lp (+ 1 ti) (+ 1 pi) (- tj 1) (- pj 1)) ; Advance.
(let ((pi (vector-ref rv pi))) ; Retreat.
(if (= pi -1)
(lp (+ ti 1) 0 (- tj 1) plen) ; Punt.
(lp ti pi tj (- plen pi))))))))))
;;; (make-kmp-restart-vector pattern [c= start end]) -> integer-vector
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; Compute the KMP restart vector RV for string PATTERN. If
;;; we have matched chars 0..i-1 of PATTERN against a search string S, and
;;; PATTERN[i] doesn't match S[k], then reset i := RV[i], and try again to
;;; match S[k]. If RV[i] = -1, then punt S[k] completely, and move on to
;;; S[k+1] and PATTERN[0] -- no possible match of PAT[0..i] contains S[k].
;;;
;;; In other words, if you have matched the first i chars of PATTERN, but
;;; the i+1'th char doesn't match, RV[i] tells you what the next-longest
;;; prefix of PATTERN is that you have matched.
;;;
;;; - C= (default CHAR=?) is used to compare characters for equality.
;;; Pass in CHAR-CI=? for case-folded string search.
;;;
;;; - START & END restrict the pattern to the indicated substring; the
;;; returned vector will be of length END - START. The numbers stored
;;; in the vector will be values in the range [0,END-START) -- that is,
;;; they are valid indices into the restart vector; you have to add START
;;; to them to use them as indices into PATTERN.
;;;
;;; I've split this out as a separate function in case other constant-string
;;; searchers might want to use it.
;;;
;;; E.g.:
;;; a b d a b x
;;; #(-1 0 0 -1 1 2)
(define (make-kmp-restart-vector pattern . maybe-c=+start+end)
(let-optionals* maybe-c=+start+end
((c= char=? (procedure? c=))
((start end) (lambda (args)
(string-parse-start+end 'make-kmp-restart-vector
pattern args))))
(let* ((rvlen (- end start))
(rv (make-vector rvlen -1)))
(if (> rvlen 0)
(let ((rvlen-1 (- rvlen 1))
(c0 (string-ref pattern start)))
;; Here's the main loop. We have set rv[0] ... rv[i].
;; K = I + START -- it is the corresponding index into PATTERN.
(let lp1 ((i 0) (j -1) (k start))
(if (< i rvlen-1)
;; lp2 invariant:
;; pat[(k-j) .. k-1] matches pat[start .. start+j-1]
;; or j = -1.
(let lp2 ((j j))
(cond ((= j -1)
(let ((i1 (+ 1 i)))
(if (not (c= (string-ref pattern (+ k 1)) c0))
(vector-set! rv i1 0))
(lp1 i1 0 (+ k 1))))
;; pat[(k-j) .. k] matches pat[start..start+j].
((c= (string-ref pattern k) (string-ref pattern (+ j start)))
(let* ((i1 (+ 1 i))
(j1 (+ 1 j)))
(vector-set! rv i1 j1)
(lp1 i1 j1 (+ k 1))))
(else (lp2 (vector-ref rv j)))))))))
rv)))
;;; We've matched I chars from PAT. C is the next char from the search string.
;;; Return the new I after handling C.
;;;
;;; The pattern is (VECTOR-LENGTH RV) chars long, beginning at index PAT-START
;;; in PAT (PAT-START is usually 0). The I chars of the pattern we've matched
;;; are
;;; PAT[PAT-START .. PAT-START + I].
;;;
;;; It's *not* an oversight that there is no friendly error checking or
;;; defaulting of arguments. This is a low-level, inner-loop procedure
;;; that we want integrated/inlined into the point of call.
(define (kmp-step pat rv c i c= p-start)
(let lp ((i i))
(if (c= c (string-ref pat (+ i p-start))) ; Match =>
(+ i 1) ; Done.
(let ((i (vector-ref rv i))) ; Back up in PAT.
(if (= i -1) 0 ; Can't back up further.
(lp i)))))) ; Keep trying for match.
;;; Zip through S[start,end), looking for a match of PAT. Assume we've
;;; already matched the first I chars of PAT when we commence at S[start].
;;; - <0: If we find a match *ending* at index J, return -J.
;;; - >=0: If we get to the end of the S[start,end) span without finding
;;; a complete match, return the number of chars from PAT we'd matched
;;; when we ran off the end.
;;;
;;; This is useful for searching *across* buffers -- that is, when your
;;; input comes in chunks of text. We hand-integrate the KMP-STEP loop
;;; for speed.
(define (string-kmp-partial-search pat rv s i . c=+p-start+s-start+s-end)
(check-arg vector? rv 'string-kmp-partial-search)
(let-optionals* c=+p-start+s-start+s-end
((c= char=? (procedure? c=))
(p-start 0 (and (integer? p-start) (exact? p-start) (<= 0 p-start)))
((s-start s-end) (lambda (args)
(string-parse-start+end 'string-kmp-partial-search
s args))))
(let ((patlen (vector-length rv)))
(check-arg (lambda (i) (and (integer? i) (exact? i) (<= 0 i) (< i patlen)))
i 'string-kmp-partial-search)
;; Enough prelude. Here's the actual code.
(let lp ((si s-start) ; An index into S.
(vi i)) ; An index into RV.
(cond ((= vi patlen) (- si)) ; Win.
((= si s-end) vi) ; Ran off the end.
(else ; Match s[si] & loop.
(let ((c (string-ref s si)))
(lp (+ si 1)
(let lp2 ((vi vi)) ; This is just KMP-STEP.
(if (c= c (string-ref pat (+ vi p-start)))
(+ vi 1)
(let ((vi (vector-ref rv vi)))
(if (= vi -1) 0
(lp2 vi)))))))))))))
;;; Misc
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; (string-null? s)
;;; (string-reverse s [start end])
;;; (string-reverse! s [start end])
;;; (reverse-list->string clist)
;;; (string->list s [start end])
(define (string-null? s) (zero? (string-length s)))
(define (string-reverse s . maybe-start+end)
(let-string-start+end (start end) string-reverse s maybe-start+end
(let* ((len (- end start))
(ans (make-string len)))
(do ((i start (+ i 1))
(j (- len 1) (- j 1)))
((< j 0))
(string-set! ans j (string-ref s i)))
ans)))
(define (string-reverse! s . maybe-start+end)
(let-string-start+end (start end) string-reverse! s maybe-start+end
(do ((i (- end 1) (- i 1))
(j start (+ j 1)))
((<= i j))
(let ((ci (string-ref s i)))
(string-set! s i (string-ref s j))
(string-set! s j ci)))))
(define (reverse-list->string clist)
(let* ((len (length clist))
(s (make-string len)))
(do ((i (- len 1) (- i 1)) (clist clist (cdr clist)))
((not (pair? clist)))
(string-set! s i (car clist)))
s))
;(define (string->list s . maybe-start+end)
; (apply string-fold-right cons '() s maybe-start+end))
(define (string->list s . maybe-start+end)
(let-string-start+end (start end) string->list s maybe-start+end
(do ((i (- end 1) (- i 1))
(ans '() (cons (string-ref s i) ans)))
((< i start) ans))))
;;; Defined by R5RS, so commented out here.
;(define (list->string lis) (string-unfold null? car cdr lis))
;;; string-concatenate string-list -> string
;;; string-concatenate/shared string-list -> string
;;; string-append/shared s ... -> string
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; STRING-APPEND/SHARED has license to return a string that shares storage
;;; with any of its arguments. In particular, if there is only one non-empty
;;; string amongst its parameters, it is permitted to return that string as
;;; its result. STRING-APPEND, by contrast, always allocates new storage.
;;;
;;; STRING-CONCATENATE & STRING-CONCATENATE/SHARED are passed a list of
;;; strings, which they concatenate into a result string. STRING-CONCATENATE
;;; always allocates a fresh string; STRING-CONCATENATE/SHARED may (or may
;;; not) return a result that shares storage with any of its arguments. In
;;; particular, if it is applied to a singleton list, it is permitted to
;;; return the car of that list as its value.
(define (string-append/shared . strings) (string-concatenate/shared strings))
(define (string-concatenate/shared strings)
(let lp ((strings strings) (nchars 0) (first #f))
(cond ((pair? strings) ; Scan the args, add up total
(let* ((string (car strings)) ; length, remember 1st
(tail (cdr strings)) ; non-empty string.
(slen (string-length string)))
(if (zero? slen)
(lp tail nchars first)
(lp tail (+ nchars slen) (or first strings)))))
((zero? nchars) "")
;; Just one non-empty string! Return it.
((= nchars (string-length (car first))) (car first))
(else (let ((ans (make-string nchars)))
(let lp ((strings first) (i 0))
(if (pair? strings)
(let* ((s (car strings))
(slen (string-length s)))
(%string-copy! ans i s 0 slen)
(lp (cdr strings) (+ i slen)))))
ans)))))
; Alas, Scheme 48's APPLY blows up if you have many, many arguments.
;(define (string-concatenate strings) (apply string-append strings))
;;; Here it is written out. I avoid using REDUCE to add up string lengths
;;; to avoid non-R5RS dependencies.
(define (string-concatenate strings)
(let* ((total (do ((strings strings (cdr strings))
(i 0 (+ i (string-length (car strings)))))
((not (pair? strings)) i)))
(ans (make-string total)))
(let lp ((i 0) (strings strings))
(if (pair? strings)
(let* ((s (car strings))
(slen (string-length s)))
(%string-copy! ans i s 0 slen)
(lp (+ i slen) (cdr strings)))))
ans))
;;; Defined by R5RS, so commented out here.
;(define (string-append . strings) (string-concatenate strings))
;;; string-concatenate-reverse string-list [final-string end] -> string
;;; string-concatenate-reverse/shared string-list [final-string end] -> string
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; Return
;;; (string-concatenate
;;; (reverse
;;; (cons (substring final-string 0 end) string-list)))
(define (string-concatenate-reverse string-list . maybe-final+end)
(let-optionals* maybe-final+end ((final "" (string? final))
(end (string-length final)
(and (integer? end)
(exact? end)
(<= 0 end (string-length final)))))
(let ((len (let lp ((sum 0) (lis string-list))
(if (pair? lis)
(lp (+ sum (string-length (car lis))) (cdr lis))
sum))))
(%finish-string-concatenate-reverse len string-list final end))))
(define (string-concatenate-reverse/shared string-list . maybe-final+end)
(let-optionals* maybe-final+end ((final "" (string? final))
(end (string-length final)
(and (integer? end)
(exact? end)
(<= 0 end (string-length final)))))
;; Add up the lengths of all the strings in STRING-LIST; also get a
;; pointer NZLIST into STRING-LIST showing where the first non-zero-length
;; string starts.
(let lp ((len 0) (nzlist #f) (lis string-list))
(if (pair? lis)
(let ((slen (string-length (car lis))))
(lp (+ len slen)
(if (or nzlist (zero? slen)) nzlist lis)
(cdr lis)))
(cond ((zero? len) (substring/shared final 0 end))
;; LEN > 0, so NZLIST is non-empty.
((and (zero? end) (= len (string-length (car nzlist))))
(car nzlist))
(else (%finish-string-concatenate-reverse len nzlist final end)))))))
(define (%finish-string-concatenate-reverse len string-list final end)
(let ((ans (make-string (+ end len))))
(%string-copy! ans len final 0 end)
(let lp ((i len) (lis string-list))
(if (pair? lis)
(let* ((s (car lis))
(lis (cdr lis))
(slen (string-length s))
(i (- i slen)))
(%string-copy! ans i s 0 slen)
(lp i lis))))
ans))
;;; string-replace s1 s2 start1 end1 [start2 end2] -> string
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; Replace S1[START1,END1) with S2[START2,END2).
(define (string-replace s1 s2 start1 end1 . maybe-start+end)
(check-substring-spec 'string-replace s1 start1 end1)
(let-string-start+end (start2 end2) string-replace s2 maybe-start+end
(let* ((slen1 (string-length s1))
(sublen2 (- end2 start2))
(alen (+ (- slen1 (- end1 start1)) sublen2))
(ans (make-string alen)))
(%string-copy! ans 0 s1 0 start1)
(%string-copy! ans start1 s2 start2 end2)
(%string-copy! ans (+ start1 sublen2) s1 end1 slen1)
ans)))
;;; string-tokenize s [token-set start end] -> list
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; Break S up into a list of token strings, where a token is a maximal
;;; non-empty contiguous sequence of chars belonging to TOKEN-SET.
;;; (string-tokenize "hello, world") => ("hello," "world")
(define (string-tokenize s . token-chars+start+end)
(let-optionals* token-chars+start+end
((token-chars char-set:graphic (char-set? token-chars)) rest)
(let-string-start+end (start end) string-tokenize s rest
(let lp ((i end) (ans '()))
(cond ((and (< start i) (string-index-right s token-chars start i)) =>
(lambda (tend-1)
(let ((tend (+ 1 tend-1)))
(cond ((string-skip-right s token-chars start tend-1) =>
(lambda (tstart-1)
(lp tstart-1
(cons (substring s (+ 1 tstart-1) tend)
ans))))
(else (cons (substring s start tend) ans))))))
(else ans))))))
;;; xsubstring s from [to start end] -> string
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; S is a string; START and END are optional arguments that demarcate
;;; a substring of S, defaulting to 0 and the length of S (e.g., the whole
;;; string). Replicate this substring up and down index space, in both the
;; positive and negative directions. For example, if S = "abcdefg", START=3,
;;; and END=6, then we have the conceptual bidirectionally-infinite string
;;; ... d e f d e f d e f d e f d e f d e f d e f ...
;;; ... -9 -8 -7 -6 -5 -4 -3 -2 -1 0 1 2 3 4 5 6 7 8 9 ...
;;; XSUBSTRING returns the substring of this string beginning at index FROM,
;;; and ending at TO (which defaults to FROM+(END-START)).
;;;
;;; You can use XSUBSTRING in many ways:
;;; - To rotate a string left: (xsubstring "abcdef" 2) => "cdefab"
;;; - To rotate a string right: (xsubstring "abcdef" -2) => "efabcd"
;;; - To replicate a string: (xsubstring "abc" 0 7) => "abcabca"
;;;
;;; Note that
;;; - The FROM/TO indices give a half-open range -- the characters from
;;; index FROM up to, but not including index TO.
;;; - The FROM/TO indices are not in terms of the index space for string S.
;;; They are in terms of the replicated index space of the substring
;;; defined by S, START, and END.
;;;
;;; It is an error if START=END -- although this is allowed by special
;;; dispensation when FROM=TO.
(define (xsubstring s from . maybe-to+start+end)
(check-arg (lambda (val) (and (integer? val) (exact? val)))
from 'xsubstring)
(receive (to start end)
(if (pair? maybe-to+start+end)
(let-string-start+end (start end) xsubstring s (cdr maybe-to+start+end)
(let ((to (car maybe-to+start+end)))
(check-arg (lambda (val) (and (integer? val)
(exact? val)
(<= from val)))
to 'xsubstring)
(values to start end)))
(let ((slen (string-length (check-arg string? s 'xsubstring))))
(values (+ from slen) 0 slen)))
(let ((slen (- end start))
(anslen (- to from)))
(cond ((zero? anslen) "")
((zero? slen) (assertion-violation 'xsubstring
"Cannot replicate empty (sub)string"
s from to start end))
((= 1 slen) ; Fast path for 1-char replication.
(make-string anslen (string-ref s start)))
;; Selected text falls entirely within one span.
((= (floor (/ from slen)) (floor (/ to slen)))
(substring s (+ start (modulo from slen))
(+ start (modulo to slen))))
;; Selected text requires multiple spans.
(else (let ((ans (make-string anslen)))
(%multispan-repcopy! ans 0 s from to start end)
ans))))))
;;; string-xcopy! target tstart s sfrom [sto start end] -> unspecific
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; Exactly the same as xsubstring, but the extracted text is written
;;; into the string TARGET starting at index TSTART.
;;; This operation is not defined if (EQ? TARGET S) -- you cannot copy
;;; a string on top of itself.
(define (string-xcopy! target tstart s sfrom . maybe-sto+start+end)
(check-arg (lambda (val) (and (integer? val) (exact? val)))
sfrom 'string-xcopy!)
(receive (sto start end)
(if (pair? maybe-sto+start+end)
(let-string-start+end (start end) string-xcopy! s (cdr maybe-sto+start+end)
(let ((sto (car maybe-sto+start+end)))
(check-arg (lambda (val) (and (integer? val) (exact? val)))
sto 'string-xcopy!)
(values sto start end)))
(let ((slen (string-length s)))
(values (+ sfrom slen) 0 slen)))
(let* ((tocopy (- sto sfrom))
(tend (+ tstart tocopy))
(slen (- end start)))
(check-substring-spec 'string-xcopy! target tstart tend)
(cond ((zero? tocopy))
((zero? slen)
(assertion-violation 'string-xcopy!
"Cannot replicate empty (sub)string"
target tstart s sfrom sto start end))
((= 1 slen) ; Fast path for 1-char replication.
(string-fill! target (string-ref s start) tstart tend))
;; Selected text falls entirely within one span.
((= (floor (/ sfrom slen)) (floor (/ sto slen)))
(%string-copy! target tstart s
(+ start (modulo sfrom slen))
(+ start (modulo sto slen))))
;; Multi-span copy.
(else (%multispan-repcopy! target tstart s sfrom sto start end))))))
;;; This is the core copying loop for XSUBSTRING and STRING-XCOPY!
;;; Internal -- not exported, no careful arg checking.
(define (%multispan-repcopy! target tstart s sfrom sto start end)
(let* ((slen (- end start))
(i0 (+ start (modulo sfrom slen)))
(total-chars (- sto sfrom)))
;; Copy the partial span @ the beginning
(%string-copy! target tstart s i0 end)
(let* ((ncopied (- end i0)) ; We've copied this many.
(nleft (- total-chars ncopied)) ; # chars left to copy.
(nspans (quotient nleft slen))) ; # whole spans to copy
;; Copy the whole spans in the middle.
(do ((i (+ tstart ncopied) (+ i slen)) ; Current target index.
(nspans nspans (- nspans 1))) ; # spans to copy
((zero? nspans)
;; Copy the partial-span @ the end & we're done.
(%string-copy! target i s start (+ start (- total-chars (- i tstart)))))
(%string-copy! target i s start end))))); Copy a whole span.
;;; (string-join string-list [delimiter grammar]) => string
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; Paste strings together using the delimiter string.
;;;
;;; (join-strings '("foo" "bar" "baz") ":") => "foo:bar:baz"
;;;
;;; DELIMITER defaults to a single space " "
;;; GRAMMAR is one of the symbols {prefix, infix, strict-infix, suffix}
;;; and defaults to 'infix.
;;;
;;; I could rewrite this more efficiently -- precompute the length of the
;;; answer string, then allocate & fill it in iteratively. Using
;;; STRING-CONCATENATE is less efficient.
(define (string-join strings . delim+grammar)
(let-optionals* delim+grammar ((delim " " (string? delim))
(grammar 'infix))
(let ((buildit (lambda (lis final)
(let recur ((lis lis))
(if (pair? lis)
(cons delim (cons (car lis) (recur (cdr lis))))
final)))))
(cond ((pair? strings)
(string-concatenate
(case grammar
((infix strict-infix)
(cons (car strings) (buildit (cdr strings) '())))
((prefix) (buildit strings '()))
((suffix)
(cons (car strings) (buildit (cdr strings) (list delim))))
(else (assertion-violation 'string-join
"Illegal join grammar"
grammar)))))
((not (null? strings))
(assertion-violation 'string-join
"STRINGS parameter not list." strings))
;; STRINGS is ()
((eq? grammar 'strict-infix)
(assertion-violation 'string-join
"Empty list cannot be joined with STRICT-INFIX grammar."))
(else ""))))) ; Special-cased for infix grammar.
;;; Porting & performance-tuning notes
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; See the section at the beginning of this file on external dependencies.
;;;
;;; The biggest issue with respect to porting is the LET-OPTIONALS* macro.
;;; There are many, many optional arguments in this library; the complexity
;;; of parsing, defaulting & type-testing these parameters is handled with the
;;; aid of this macro. There are about 15 uses of LET-OPTIONALS*. You can
;;; rewrite the uses, port the hairy macro definition (which is implemented
;;; using a Clinger-Rees low-level explicit-renaming macro system), or port
;;; the simple, high-level definition, which is less efficient.
;;;
;;; There is a fair amount of argument checking. This is, strictly speaking,
;;; unnecessary -- the actual body of the procedures will blow up if, say, a
;;; START/END index is improper. However, the error message will not be as
;;; good as if the error were caught at the "higher level." Also, a very, very
;;; smart Scheme compiler may be able to exploit having the type checks done
;;; early, so that the actual body of the procedures can assume proper values.
;;; This isn't likely; this kind of compiler technology isn't common any
;;; longer.
;;;
;;; The overhead of optional-argument parsing is irritating. The optional
;;; arguments must be consed into a rest list on entry, and then parsed out.
;;; Function call should be a matter of a few register moves and a jump; it
;;; should not involve heap allocation! Your Scheme system may have a superior
;;; non-R5RS optional-argument system that can eliminate this overhead. If so,
;;; then this is a prime candidate for optimising these procedures,
;;; *especially* the many optional START/END index parameters.
;;;
;;; Note that optional arguments are also a barrier to procedure integration.
;;; If your Scheme system permits you to specify alternate entry points
;;; for a call when the number of optional arguments is known in a manner
;;; that enables inlining/integration, this can provide performance
;;; improvements.
;;;
;;; There is enough *explicit* error checking that *all* string-index
;;; operations should *never* produce a bounds error. Period. Feel like
;;; living dangerously? *Big* performance win to be had by replacing
;;; STRING-REF's and STRING-SET!'s with unsafe equivalents in the loops.
;;; Similarly, fixnum-specific operators can speed up the arithmetic done on
;;; the index values in the inner loops. The only arguments that are not
;;; completely error checked are
;;; - string lists (complete checking requires time proportional to the
;;; length of the list)
;;; - procedure arguments, such as char->char maps & predicates.
;;; There is no way to check the range & domain of procedures in Scheme.
;;; Procedures that take these parameters cannot fully check their
;;; arguments. But all other types to all other procedures are fully
;;; checked.
;;;
;;; This does open up the alternate possibility of simply *removing* these
;;; checks, and letting the safe primitives raise the errors. On a dumb
;;; Scheme system, this would provide speed (by eliminating the redundant
;;; error checks) at the cost of error-message clarity.
;;;
;;; See the comments preceding the hash function code for notes on tuning
;;; the default bound so that the code never overflows your implementation's
;;; fixnum size into bignum calculation.
;;;
;;; In an interpreted Scheme, some of these procedures, or the internal
;;; routines with % prefixes, are excellent candidates for being rewritten
;;; in C. Consider STRING-HASH, %STRING-COMPARE, the
;;; %STRING-{SUF,PRE}FIX-LENGTH routines, STRING-COPY!, STRING-INDEX &
;;; STRING-SKIP (char-set & char cases), SUBSTRING and SUBSTRING/SHARED,
;;; %KMP-SEARCH, and %MULTISPAN-REPCOPY!.
;;;
;;; It would also be nice to have the ability to mark some of these
;;; routines as candidates for inlining/integration.
;;;
;;; All the %-prefixed routines in this source code are written
;;; to be called internally to this library. They do *not* perform
;;; friendly error checks on the inputs; they assume everything is
;;; proper. They also do not take optional arguments. These two properties
;;; save calling overhead and enable procedure integration -- but they
;;; are not appropriate for exported routines.
;;; Copyright details
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; The prefix/suffix and comparison routines in this code had (extremely
;;; distant) origins in MIT Scheme's string lib, and was substantially
;;; reworked by Olin Shivers (shivers@ai.mit.edu) 9/98. As such, it is
;;; covered by MIT Scheme's open source copyright. See below for details.
;;;
;;; The KMP string-search code was influenced by implementations written
;;; by Stephen Bevan, Brian Dehneyer and Will Fitzgerald. However, this
;;; version was written from scratch by myself.
;;;
;;; The remainder of this code was written from scratch by myself for scsh.
;;; The scsh copyright is a BSD-style open source copyright. See below for
;;; details.
;;; -Olin Shivers
;;; MIT Scheme copyright terms
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; This material was developed by the Scheme project at the Massachusetts
;;; Institute of Technology, Department of Electrical Engineering and
;;; Computer Science. Permission to copy and modify this software, to
;;; redistribute either the original software or a modified version, and
;;; to use this software for any purpose is granted, subject to the
;;; following restrictions and understandings.
;;;
;;; 1. Any copy made of this software must include this copyright notice
;;; in full.
;;;
;;; 2. Users of this software agree to make their best efforts (a) to
;;; return to the MIT Scheme project any improvements or extensions that
;;; they make, so that these may be included in future releases; and (b)
;;; to inform MIT of noteworthy uses of this software.
;;;
;;; 3. All materials developed as a consequence of the use of this
;;; software shall duly acknowledge such use, in accordance with the usual
;;; standards of acknowledging credit in academic research.
;;;
;;; 4. MIT has made no warrantee or representation that the operation of
;;; this software will be error-free, and MIT is under no obligation to
;;; provide any services, by way of maintenance, update, or otherwise.
;;;
;;; 5. In conjunction with products arising from the use of this material,
;;; there shall be no use of the name of the Massachusetts Institute of
;;; Technology nor of any adaptation thereof in any advertising,
;;; promotional, or sales literature without prior written consent from
;;; MIT in each case.
;;; Scsh copyright terms
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; All rights reserved.
;;;
;;; Redistribution and use in source and binary forms, with or without
;;; modification, are permitted provided that the following conditions
;;; are met:
;;; 1. Redistributions of source code must retain the above copyright
;;; notice, this list of conditions and the following disclaimer.
;;; 2. Redistributions in binary form must reproduce the above copyright
;;; notice, this list of conditions and the following disclaimer in the
;;; documentation and/or other materials provided with the distribution.
;;; 3. The name of the authors may not be used to endorse or promote products
;;; derived from this software without specific prior written permission.
;;;
;;; THIS SOFTWARE IS PROVIDED BY THE AUTHORS ``AS IS'' AND ANY EXPRESS OR
;;; IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
;;; OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
;;; IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY DIRECT, INDIRECT,
;;; INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
;;; NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
;;; DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
;;; THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
;;; (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
;;; THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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