Odd word problem
Write a program that solves the odd word problem with the restrictions given below.
You are encouraged to solve this task according to the task description, using any language you may know.
- Task
- Description
You are promised an input stream consisting of English letters and punctuations.
It is guaranteed that:
- the words (sequence of consecutive letters) are delimited by one and only one punctuation,
- the stream will begin with a word,
- the words will be at least one letter long, and
- a full stop (a period, [.]) appears after, and only after, the last word.
- Example
A stream with six words:
what,is,the;meaning,of:life.
The task is to reverse the letters in every other word while leaving punctuations intact, producing:
what,si,the;gninaem,of:efil.
while observing the following restrictions:
- Only I/O allowed is reading or writing one character at a time, which means: no reading in a string, no peeking ahead, no pushing characters back into the stream, and no storing characters in a global variable for later use;
- You are not to explicitly save characters in a collection data structure, such as arrays, strings, hash tables, etc, for later reversal;
- You are allowed to use recursions, closures, continuations, threads, co-routines, etc., even if their use implies the storage of multiple characters.
- Test cases
Work on both the "life" example given above, and also the text:
we,are;not,in,kansas;any,more.
Ada
This is a rather straightforward approach, using recursion.
<lang Ada>with Ada.Text_IO;
procedure Odd_Word_Problem is
use Ada.Text_IO; -- Get, Put, and Look_Ahead
function Current return Character is
-- reads the current input character, without consuming it
End_Of_Line: Boolean;
C: Character;
begin
Look_Ahead(C, End_Of_Line);
if End_Of_Line then
raise Constraint_Error with "end of line before the terminating '.'";
end if;
return C;
end Current;
procedure Skip is
-- consumes the current input character
C: Character;
begin
Get(C);
end Skip;
function Is_Alpha(Ch: Character) return Boolean is
begin
return (Ch in 'a' .. 'z') or (Ch in 'A' .. 'Z');
end Is_Alpha;
procedure Odd_Word(C: Character) is
begin
if Is_Alpha(C) then
Skip;
Odd_Word(Current);
Put(C);
end if;
end Odd_Word;
begin -- Odd_Word_Problem
Put(Current);
while Is_Alpha(Current) loop -- read an even word
Skip;
Put(Current);
end loop;
if Current /= '.' then -- read an odd word
Skip;
Odd_Word(Current);
Put(Current);
if Current /= '.' then -- read the remaining words
Skip;
Odd_Word_Problem;
end if;
end if;
end Odd_Word_Problem;</lang>
Output:
> ./odd_word_problem what,is,the;meaning,of:life. what,si,the;gninaem,of:efil. > ./odd_word_problem we,are;not,in,kansas;any,more. we,era;not,ni,kansas;yna,more.
ALGOL 68
The words and punctuation should be on a single line. Uses recursion. <lang algol68># recursively reverses the current word in the input and returns the #
- the character that followed it #
- "ch" should contain the first letter of the word on entry and will be #
- updated to the punctuation following the word on exit #
PROC reverse word = ( REF CHAR ch )VOID: BEGIN
CHAR next ch;
read( ( next ch ) );
IF ( next ch <= "Z" AND next ch >= "A" )
OR ( next ch <= "z" AND next ch >= "a" )
THEN
reverse word( next ch )
FI;
print( ( ch ) );
ch := next ch
END; # reverse word #
- recursively prints the current word in the input and returns the #
- character that followed it #
- "ch" should contain the first letter of the word on entry and will be #
- updated to the punctuation following the word on exit #
PROC normal word = ( REF CHAR ch )VOID: BEGIN
print( ( ch ) ); read ( ( ch ) );
IF ( ch <= "Z" AND ch >= "A" )
OR ( ch <= "z" AND ch >= "a" )
THEN
normal word( ch )
FI
END; # normal word #
- read and print words and punctuation from the input stream, reversing #
- every second word #
PROC reverse every other word = VOID: BEGIN
CHAR ch;
read( ( ch ) );
WHILE
ch /= "."
DO
normal word( ch );
IF ch /= "."
THEN
print( ( ch ) );
read ( ( ch ) );
reverse word( ch )
FI
OD;
print( ( ch ) )
END; # reverse every other word #
main: (
reverse every other word
)</lang>
- Output:
what,si,the;gninaem,of:efil. we,era;not,ni,kansas;yna,more.
AutoHotkey
<lang AutoHotkey>str := "what,is,the;meaning,of:life." loop, parse, str if (A_LoopField ~= "punct:") res .= A_LoopField, toggle:=!toggle else res := toggle ? RegExReplace(res, ".*punct:\K", A_LoopField ) : res A_LoopField MsgBox % res</lang>
Outputs:
what,si,the;gninaem,of:efil.
BaCon
<lang qbasic>OPEN "/dev/stdin" FOR DEVICE AS in
FUNCTION get_odd()
LOCAL ch, letter
ch = MEMORY(1) GETBYTE ch FROM in
IF NOT(REGEX(CHR$(PEEK(ch)), "punct:")) THEN letter = get_odd() PRINT CHR$(PEEK(ch)); ELSE letter = PEEK(ch) END IF
FREE ch RETURN letter
END FUNCTION
mem = MEMORY(1) PRINT "Enter string: ";
WHILE TRUE
GETBYTE mem FROM in PRINT CHR$(PEEK(mem));
IF REGEX(CHR$(PEEK(mem)), "punct:") THEN IF PEEK(mem) <> 46 THEN POKE mem, get_odd() PRINT CHR$(PEEK(mem)); END IF IF PEEK(mem) = 46 THEN BREAK END IF
WEND
FREE mem CLOSE DEVICE in
PRINT</lang> This program uses recursion.
- Output:
user@host $ bacon odd_word Converting 'odd_word.bac'... done, 46 lines were processed in 0.003 seconds. Compiling 'odd_word.bac'... cc -c odd_word.bac.c cc -o odd_word odd_word.bac.o -lbacon -lm Done, program 'odd_word' ready. user@host $ ./odd_word Enter string: what,is,the;meaning,of:life. what,si,the;gninaem,of:efil. user@host $ ./odd_word Enter string: we,are;not,in,kansas;any,more. we,era;not,ni,kansas;yna,more.
Bracmat
<lang bracmat>( ( odd-word
= dothis doother forward backward
. ( forward
= ch
. fil$:?ch
& put$!ch
& ( low$!ch:~<a:~>z&forward$
| !ch:~"."
)
)
& ( backward
= ch
. fil$:?ch
& ( low$!ch:~<a:~>z
& backward$() (put$!ch&) { This reduces to the return value of backwards$()}
| '(.put$($ch)&$ch:~".") { Macro, evaluates to a function with actual ch. }
)
)
& fil$(!arg,r)
& ((=forward$).(=(backward$)$))
: (?dothis.?doother)
& whl
' ( !(dothis.)
& (!doother.!dothis):(?dothis.?doother)
)
& (fil$(,SET,-1)|) { This is how a file is closed: seek the impossible. }
)
& put$("what,is,the;meaning,of:life.","life.txt",NEW) & put$("we,are;not,in,kansas;any,more.","kansas.txt",NEW) & odd-word$"life.txt" & put$\n & odd-word$"kansas.txt" { Real file, as Bracmat cannot read a single character from stdin. } );</lang> Output:
what,si,the;gninaem,of:efil. we,era;not,ni,kansas;yna,more.
C
Using GCC nested function as closures. This can only be passed up the stack, not the other way around. It's also doable with makecontext, and may be possible with setjmp.
<lang c>#include <stdio.h>
- include <ctype.h>
int do_char(int odd, void (*f)(void)) { int c = getchar();
void write_out(void) { putchar(c); if (f) f(); }
if (!odd) putchar(c);
if (isalpha(c)) return do_char(odd, write_out);
if (odd) { if (f) f(); putchar(c); }
return c != '.'; }
int main() { int i = 1; while (do_char(i = !i, 0));
return 0; }</lang>
C++
Tested with gcc 4.5, with "-std=c++0x" option.
<lang cpp>#include <iostream>
- include <cctype>
- include <functional>
using namespace std;
bool odd() {
function<void ()> prev = []{};
while(true) {
int c = cin.get();
if (!isalpha(c)) {
prev();
cout.put(c);
return c != '.';
}
prev = [=] { cout.put(c); prev(); };
}
}
bool even() {
while(true) {
int c;
cout.put(c = cin.get());
if (!isalpha(c)) return c != '.';
}
}
int main()
{
bool e = false; while( e ? odd() : even() ) e = !e; return 0;
}</lang>
Ceylon
<lang ceylon> String[] meaning = ["what,", "is,", "the;", "meaning,", "of:", "life."]; String[] kansas = ["we,", "are,", "not,", "in,", "kansas;", "any,", "more."];
shared void run() {
print("".join(reverseWords(meaning)));
print("".join(reverseWords(kansas)));
}
String[] reverseWords(String[] words)
=> recursiveReverseWords(words, []);
String[] recursiveReverseWords(String[] remOrig, String[] revWords)
=> if (nonempty remOrig)
then recursiveReverseWords(remOrig.rest,
revWords.withTrailing(reverseWordRecursive(remOrig.first.sequence(),
[],
revWords.size.even)))
else revWords;
String reverseWordRecursive(Character[] remOldChars, Character[] revChars, Boolean isEven)
=> if (nonempty remOldChars)
then let (char = remOldChars.first) reverseWordRecursive(remOldChars.rest,
conditionalAddChar(char, revChars, isEven),
isEven)
else String(revChars);
Character[] conditionalAddChar(Character char, Character[] chars, Boolean isEven)
=> if (isEven || isPunctuation(char))
then chars.withTrailing(char)
else chars.withLeading(char);
Boolean isPunctuation(Character char)
=> ",.:;".contains(char);
</lang>
- Output:
what,si,the;gninaem,of:efil.
we,era,not,ni,kansas;yna,more.
Clojure
<lang Clojure>(defn next-char []
(char (.read *in*)))
(defn forward []
(let [ch (next-char)]
(print ch)
(if (Character/isLetter ch)
(forward)
(not= ch \.))))
(defn backward []
(let [ch (next-char)]
(if (Character/isLetter ch)
(let [result (backward)]
(print ch)
result)
(fn [] (print ch) (not= ch \.)))) )
(defn odd-word [s]
(with-in-str s
(loop [forward? true]
(when (if forward?
(forward)
((backward)))
(recur (not forward?)))) )
(println))</lang>
Examples:
<lang clojure>user=> (odd-word "what,is,the;meaning,of:life.") what,si,the;gninaem,of:efil. nil user=> (odd-word "we,are;not,in,kansas;any,more.") we,era;not,ni,kansas;yna,more. nil</lang>
CoffeeScript
<lang CoffeeScript>isWordChar = (c) -> /^\w/.test c isLastChar = (c) -> c is '.'
- Pass a function that returns an input character and one that outputs a
- character. JS platforms' ideas of single-character I/O vary widely, but this
- abstraction is adaptable to most or all.
oddWord = (get, put) -> forwardWord = -> loop # No magic here; buffer then immediately output. c = get() put(c) unless isWordChar(c) return not isLastChar(c)
# NB: (->) is a CoffeeScript idiom for no-op. reverseWord = (outputPending = (->)) -> c = get() if isWordChar(c) # Continue word. # Tell recursive call to output this character, then any previously # pending characters, after the next word character, if any, has # been output. reverseWord -> put(c) outputPending() else # Word is done. # Output previously pending characters, then this punctuation. outputPending() put(c) return not isLastChar(c)
# Alternate between forward and reverse until one or the other reports that # the end-of-input mark has been reached (causing a return of false). continue while forwardWord() and reverseWord()</lang>
Same without comments
<lang CoffeeScript>isWordChar = (c) -> /^\w/.test c isLastChar = (c) -> c is '.'
oddWord = (get, put) -> forwardWord = -> loop c = get() put(c) unless isWordChar(c) return not isLastChar(c)
reverseWord = (outputPending = (->)) -> c = get() if isWordChar(c) reverseWord -> put(c) outputPending() else outputPending() put(c) return not isLastChar(c)
continue while forwardWord() and reverseWord()</lang>
Testing code
<lang CoffeeScript># Redefine as necessary for target platform. println = (z) -> console.log z
testData = [ [ "what,is,the;meaning,of:life." "what,si,the;gninaem,of:efil." ] [ "we,are;not,in,kansas;any,more." "we,era;not,ni,kansas;yna,more." ] ]
results = for [testString, expectedResult] in testData # This test machinery uses string buffers for input and output. If your JS # platform sports single-character I/O, by all means, adapt to taste. getCursor = 0 putBuffer = "" get = -> testString.charAt getCursor++ put = (c) -> putBuffer += c oddWord(get,put) [testString, expectedResult, putBuffer, putBuffer is expectedResult]
println result for result in results</lang>
Output in node.js:
[ 'what,is,the;meaning,of:life.', 'what,si,the;gninaem,of:efil.', 'what,si,the;gninaem,of:efil.', true ] [ 'we,are;not,in,kansas;any,more.', 'we,era;not,ni,kansas;yna,more.', 'we,era;not,ni,kansas;yna,more.', true ]
Common Lisp
Even words are straightforward. For odd words, the final punctuation is printed by a closure passed back up the caller chain. <lang lisp>(defun odd-word (s)
(let ((stream (make-string-input-stream s)))
(loop for forwardp = t then (not forwardp)
while (if forwardp
(forward stream)
(funcall (backward stream)))) ))
(defun forward (stream)
(let ((ch (read-char stream))) (write-char ch) (if (alpha-char-p ch)
(forward stream)
(char/= ch #\.))))
(defun backward (stream)
(let ((ch (read-char stream)))
(if (alpha-char-p ch)
(prog1 (backward stream) (write-char ch))
#'(lambda () (write-char ch) (char/= ch #\.)))) )
</lang>
Examples:
<lang lisp>? (odd-word "what,is,the;meaning,of:life.") what,si,the;gninaem,of:efil. NIL ? (odd-word "we,are;not,in,kansas;any,more.") we,era;not,ni,kansas;yna,more. NIL</lang>
D
<lang d>bool doChar(in bool odd, in void delegate() nothrow f=null) nothrow {
import core.stdc.stdio, std.ascii;
immutable int c = getchar;
if (!odd)
c.putchar;
if (c.isAlpha)
return doChar(odd, { c.putchar; if (f) f(); });
if (odd) {
if (f) f();
c.putchar;
}
return c != '.';
}
void main() {
bool i = true;
while (doChar(i = !i)) {}
}</lang>
- Output:
what,is,the;meaning,of:life. what,si,the;gninaem,of:efil.
Delphi
<lang Delphi> program Odd_word_problem;
{$APPTYPE CONSOLE}
uses
System.SysUtils, System.Console, System.Character;
function doChar(isOdd: boolean; f: TProc = nil): Boolean; begin
var c: char := Console.ReadKey(True).KeyChar;
if not isOdd then Write(c);
if c.IsLetter then
exit(doChar(isOdd,
procedure
begin
Write(c);
if assigned(f) then
f();
end));
if isOdd then
begin
if Assigned(f) then
f();
write(c);
end;
exit(c <> '.');
end;
begin
var i: boolean := false; while doChar(i) do i := not i; readln;
end.</lang>
EchoLisp
No character input stream in EchoLisp, which runs in a browser window. We simultate it with a character stream, with the only function read-char, as specified in the task. <lang scheme> (lib 'sequences) (define input-stream null) (define output-stream "")
- ---------------------------
- character I/O simulation
- --------------------------
(define (read-char) (next input-stream)) ;; #f if EOF (define (write-char c) (when c (set! output-stream (string-append output-stream c))))
(define (init-streams sentence) (set! input-stream (procrastinator sentence)) (set! output-stream ""))
- ---------------------------------
- task , using read-char/write-char
- ----------------------------------
(define (flop) ; reverses, and returns first non-alpha after word, or EOF (define c (read-char)) (if (string-alphabetic? c) (begin0 (flop) (write-char c)) c))
(define (flip)
(define c (read-char)) (if (string-alphabetic? c) (begin (write-char c) (flip)) c))
(define (task sentence) (init-streams sentence) (while (and (write-char (flip)) (write-char (flop)))) output-stream )
</lang>
- Output:
<lang scheme> (task "what,is,the;meaning,of:life.")
→ "what,si,the;gninaem,of:efil."
- check diacritical
(task "Longtemps,je me suis couché,héhé,hôhô,de bonne heure.")
→ "Longtemps,ej me sius couché,éhéh,hôhô,ed bonne erueh."
</lang>
Elixir
<lang elixir>defmodule Odd_word do
def handle(s, false, i, o) when ((s >= "a" and s <= "z") or (s >= "A" and s <= "Z")) do
o.(s)
handle(i.(), false, i, o)
end
def handle(s, t, i, o) when ((s >= "a" and s <= "z") or (s >= "A" and s <= "Z")) do
d = handle(i.(), :rec, i, o)
o.(s)
if t == true, do: handle(d, t, i, o), else: d
end
def handle(s, :rec, _, _), do: s
def handle(?., _, _, o), do: o.(?.); :done
def handle(:eof, _, _, _), do: :done
def handle(s, t, i, o) do
o.(s)
handle(i.(), not t, i, o)
end
def main do
i = fn() -> IO.getn("") end
o = fn(s) -> IO.write(s) end
handle(i.(), false, i, o)
end
end
Odd_word.main</lang>
- Output:
C:\Elixir>elixir Odd_word.exs we,are;not,in,kansas;any,more. we,era;not,ni,kansas;yna,more.
Erlang
<lang erlang> handle(S, false, I, O) when (((S >= $a) and (S =< $z)) or ((S >= $A) and (S =< $Z))) ->
O(S), handle(I(), false, I, O);
handle(S, T, I, O) when (((S >= $a) and (S =< $z)) or ((S >= $A) and (S =< $Z))) ->
D = handle(I(), rec, I, O), O(S), case T of true -> handle(D, T, I, O); _ -> D end;
handle(S, rec, _, _) -> S; handle($., _, _, O) -> O($.), done; handle(eof, _, _, _) -> done; handle(S, T, I, O) -> O(S), handle(I(), not T, I, O).
main([]) ->
I = fun() -> hd(io:get_chars([], 1)) end, O = fun(S) -> io:put_chars([S]) end, handle(I(), false, I, O).
</lang>
F#
A recursive solution.
<lang fsharp>open System open System.Text.RegularExpressions
let mutable Inp = Console.In
let Out c = printf "%c" c; (if c = '.' then Environment.Exit 0)
let In() = Inp.Read() |> Convert.ToChar
let (|WordCharacter|OtherCharacter|) c =
if Regex.IsMatch(c.ToString(),"[a-zA-Z]") then
WordCharacter
else
OtherCharacter
let rec forward () =
let c = In()
let rec backward () : char =
let c = In()
match c with
| WordCharacter ->
let s = backward() in Out c; s
| OtherCharacter -> c
Out c
match c with
| WordCharacter -> forward()
| OtherCharacter -> backward()
[<EntryPoint>] let main argv =
if argv.Length > 0 then Inp <- new System.IO.StringReader(argv.[0]) let rec loop () = forward() |> Out; loop() loop() 0</lang>
- Output:
>echo we,are;not,in,kansas;any,more. | RosettaCode we,era;not,ni,kansas;yna,more. >echo what,is,the;meaning,of:life. | RosettaCode what,si,the;gninaem,of:efil.
Factor
This is a delicate program with arcane control flow. To reverse each odd word, this code uses continuations to jump-back into earlier iterations of a while loop. This trick reverses the letters by reversing the loop!
This code is difficult to follow, because it twists its control flow like spaghetti. These continuations form a singly-linked list, where each continuation contains a letter and a previous continuation. The program effectively reverses this linked list.
<lang factor>USING: continuations kernel io io.streams.string locals unicode.categories ; IN: rosetta.odd-word
<PRIVATE ! Save current continuation.
- savecc ( -- continuation/f )
[ ] callcc1 ; inline
! Jump back to continuation, where savecc will return f.
- jump-back ( continuation -- )
f swap continue-with ; inline
PRIVATE>
- read-odd-word ( -- )
f :> first-continuation!
f :> last-continuation!
f :> reverse!
! Read characters. Loop until end of stream.
[ read1 dup ] [
dup Letter? [
! This character is a letter.
reverse [
! Odd word: Write letters in reverse order.
last-continuation savecc dup [
last-continuation!
2drop ! Drop letter and previous continuation.
] [
! After jump: print letters in reverse.
drop ! Drop f.
swap write1 ! Write letter.
jump-back ! Follow chain of continuations.
] if
] [
! Even word: Write letters immediately.
write1
] if
] [
! This character is punctuation.
reverse [
! End odd word. Fix trampoline, follow chain of continuations
! (to print letters in reverse), then bounce off trampoline.
savecc dup [
first-continuation!
last-continuation jump-back
] [ drop ] if
write1 ! Write punctuation.
f reverse! ! Begin even word.
] [
write1 ! Write punctuation.
t reverse! ! Begin odd word.
! Create trampoline to bounce to (future) first-continuation.
savecc dup [
last-continuation!
] [ drop first-continuation jump-back ] if
] if
] if
] while
! Drop f from read1. Then print a cosmetic newline.
drop nl ;
- odd-word ( string -- )
[ read-odd-word ] with-string-reader ;</lang>
USE: rosetta.odd-word ( scratchpad ) "what,is,the;meaning,of:life." odd-word what,si,the;gninaem,of:efil. ( scratchpad ) "we,are;not,in,kansas;any,more." odd-word we,era;not,ni,kansas;yna,more.
FALSE
This solution uses recursion to read the backwards words, to output the characters after having done the rest of that word. <lang false>[$$$$'.=\',=|\';=|\':=|~[^s;!\,]?]s: {recursive reading} [s;!$'.=~[,^f;!]?]r: {reverse words} [[$$$$'.=\',=|\';=|\':=|~][,^]#$'.=~[,^r;!]?]f: {forward words} ^f;!, {start}</lang>
Forth
<lang forth>: word? dup [char] . <> over bl <> and ;
- ?quit dup [char] . = if emit quit then ;
- eatbl begin dup bl = while drop key repeat ?quit ;
- even begin word? while emit key repeat ;
- odd word? if key recurse swap emit then ;
- main cr key eatbl begin even eatbl space odd eatbl space again ;</lang>
Fortran
By not allowing the use of arrays of characters to facilitate the reversing of texts, the obvious solution involves recursion with storage via the stack so that its last-on, first-off style will achieve the required goal. But alas, Fortran compilers were typically written for computers that did not employ a stack mechanism so recursion was not expected even after the introduction of Algol in the 1960s, and the failure of recursively-invoked routines to return correctly became accepted. The standard murmur was that "Fortran is not a recursive language" even though the language contains recursive definitions such as for arithmetic expressions. By contrast, the B6700 system did employ a hardware stack, and, without any fuss, recursion just worked.
But with F90, the language definition was augmented by the menacing word RECURSIVE, and so... <lang Fortran> MODULE ELUDOM !Uses the call stack for auxiliary storage.
INTEGER MSG,INF !I/O unit numbers.
LOGICAL DEFER !To stumble, or not to stumble.
CONTAINS
CHARACTER*1 RECURSIVE FUNCTION GET(IN) !Returns one character, going forwards.
INTEGER IN !The input file.
CHARACTER*1 C !The single character to be read therefrom.
READ (IN,1,ADVANCE="NO",EOR=3,END=4) C !Thus. Not advancing to the next record.
1 FORMAT (A1,$) !For output, no advance to the next line either.
2 IF (("A"<=C .AND. C<="Z").OR.("a"<=C .AND. C<="z")) THEN !Unsafe for EBCDIC.
IF (DEFER) THEN !Are we to reverse the current text?
GET = GET(IN) !Yes. Go for the next letter.
WRITE (MSG,1) C !And now, backing out, reveal the letter at this level.
RETURN !Retreat another level.
END IF !Thus passing back the ending non-letter that was encountered.
ELSE !And if we've encountered a non-letter,
DEFER = .NOT. DEFER !Then our backwardness flips.
END IF !Enough inspection of C.
3 GET = C !Pass it back.
RETURN !And we're done.
4 GET = CHAR(0) !Reserving this for end-of-file.
END FUNCTION GET!That was strange.
END MODULE ELUDOM !But as per the specification.
PROGRAM CONFUSED !Just so.
USE ELUDOM !Forwards? Backwards?
CHARACTER*1 C !A scratchpad for multiple inspections.
MSG = 6 !Standard output.
INF = 10 !This will do.
OPEN (INF,NAME = "Confused.txt",STATUS="OLD",ACTION="READ") !Go for the file.
Chew through the input. A full stop marks the end.
10 DEFER = .FALSE. !Start off going forwards.
11 C = GET(INF) !Get some character from file INF.
IF (ICHAR(C).LE.0) STOP !Perhaps end-of-file is reported.
IF (C.NE." ") WRITE (MSG,12) C !Otherwise, write it. A blank for end-of-record.
12 FORMAT (A1,$) !Obviously, not finishing the line each time.
IF (C.NE.".") GO TO 11 !And if not a full stop, do it again.
WRITE (MSG,"()") !End the line of output.
GO TO 10 !And have another go.
END !That was confusing.</lang>
With file Confused.txt containing the obvious input, the output is
what,si,the;gninaem,of:efil. we,era;not,ni,kansas;yna,more. hot,star.
The basic ploy is that the function returns the next character from the input, but, should DEFER be true, it secretly invokes itself until a non-letter is found then returns (bearing that non-letter as its result) and on the way back out, secretly writes the letter previously read. Each level of recursion has its own version of that letter and by revealing them as the returns proceed, they are written in reverse order of input. Seen from the outside of GET, the value of DEFER is always true but this variable is static with regard to the invocations of GET, it being defined outside GET. If it were defined within there would be a new instance allocated with each level of recursion (as with variable C), which is not what is wanted.
Testing showed that the F90 feature of ADVANCE="NO" was required for the READ action because the $ format code that works for output does not work for input. Should an end-of-record interfere with the READ, the EOR=label is taken, and the character read will be a space. To avoid ugly system messages on running into end-of-file, character zero is reserved, just as a space is reserved for end-of-record encounters and skipped for output. Fortunately, the specification does not include spaces as allowed input. No checks are made as to whether the input conforms to the given specifications.
If the ADVANCE feature is unavailable, then the file could be read as UNFORMATTED, one character at a go with a record length of one. And then would arise the annoyance of dealing with the ASCII world's usage of CR, CRLF, LFCR, or CR as markers for the ends of records.
Go
<lang go>package main
import (
"bytes" "fmt" "io" "os" "unicode"
)
func main() {
owp(os.Stdout, bytes.NewBufferString("what,is,the;meaning,of:life."))
fmt.Println()
owp(os.Stdout, bytes.NewBufferString("we,are;not,in,kansas;any,more."))
fmt.Println()
}
func owp(dst io.Writer, src io.Reader) {
byte_in := func () byte {
bs := make([]byte, 1)
src.Read(bs)
return bs[0]
}
byte_out := func (b byte) { dst.Write([]byte{b}) }
var odd func() byte
odd = func() byte {
s := byte_in()
if unicode.IsPunct(rune(s)) {
return s
}
b := odd()
byte_out(s)
return b
}
for {
for {
b := byte_in()
byte_out(b)
if b == '.' {
return
}
if unicode.IsPunct(rune(b)) {
break
}
}
b := odd()
byte_out(b)
if b == '.' {
return
}
}
}</lang> Output:
what,si,the;gninaem,of:efil. we,era;not,ni,kansas;yna,more.
Using defer
<lang go>package main
import (
"bytes" "fmt" "io" "os" "unicode"
)
func main() {
owp(os.Stdout, bytes.NewBufferString("what,is,the;meaning,of:life."))
fmt.Println()
owp(os.Stdout, bytes.NewBufferString("we,are;not,in,kansas;any,more."))
fmt.Println()
}
func owp(dst io.Writer, src io.Reader) {
byte_in := func () byte {
bs := make([]byte, 1)
src.Read(bs)
return bs[0]
}
byte_out := func (b byte) { dst.Write([]byte{b}) }
odd := func() byte {
for {
b := byte_in()
if unicode.IsPunct(int(b)) {
return b
}
defer byte_out(b)
}
panic("impossible")
}
for {
for {
b := byte_in()
byte_out(b)
if b == '.' {
return
}
if unicode.IsPunct(rune(b)) {
break
}
}
b := odd()
byte_out(b)
if b == '.' {
return
}
}
}</lang>
Using channels and goroutines
<lang go>package main
import (
"bytes" "fmt" "io" "os" "unicode"
)
func main() {
owp(os.Stdout, bytes.NewBufferString("what,is,the;meaning,of:life."))
fmt.Println()
owp(os.Stdout, bytes.NewBufferString("we,are;not,in,kansas;any,more."))
fmt.Println()
}
type Coroutine struct {
out <-chan Coroutine in chan<- byte
}
func owp(dst io.Writer, src io.Reader) {
byte_in := func () (byte, error) {
bs := make([]byte, 1)
_, err := src.Read(bs)
return bs[0], err
}
byte_out := func (b byte) { dst.Write([]byte{b}) }
var f, r Coroutine
f = func () Coroutine {
out := make(chan Coroutine)
in := make(chan byte)
var fwd func (byte) byte
fwd = func (c byte) (z byte) {
if unicode.IsLetter(rune(c)) {
byte_out(c)
out <- f
z = fwd(<- in)
} else {
z = c
}
return
}
go func () {
for {
x, ok := <- in
if !ok { break }
byte_out(fwd(x))
out <- r
}
} ()
return Coroutine{ out, in }
} ()
r = func () Coroutine {
out := make(chan Coroutine)
in := make(chan byte)
var rev func (byte) byte
rev = func (c byte) (z byte) {
if unicode.IsLetter(rune(c)) {
out <- r
z = rev(<- in)
byte_out(c)
} else {
z = c
}
return
}
go func () {
for {
x, ok := <- in
if !ok { break }
byte_out(rev(x))
out <- f
}
} ()
return Coroutine{ out, in }
} ()
for coro := f; ; coro = <- coro.out {
c, err := byte_in()
if err != nil { break }
coro.in <- c
}
close(f.in)
close(r.in)
}</lang>
Haskell
While it seems like this solution would break the task's rules, Haskell is non-strict, therefore this yields the same behavior of reading and printing one character at a time, without excess storage into a "string". To prove it, run the program and manually enter the input string (Windows command prompt does not respect buffering settings, but urxvt on on Linux does). <lang Haskell>import System.IO
(BufferMode(..), getContents, hSetBuffering, stdin, stdout)
import Data.Char (isAlpha)
split :: String -> (String, String) split = span isAlpha
parse :: String -> String parse [] = [] parse l =
let (a, w) = split l
(b, x) = splitAt 1 w
(c, y) = split x
(d, z) = splitAt 1 y
in a <> b <> reverse c <> d <> parse z
main :: IO () main =
hSetBuffering stdin NoBuffering >> hSetBuffering stdout NoBuffering >> getContents >>= putStr . takeWhile (/= '.') . parse >> putStrLn "."</lang>
If the above is not acceptable, or if Haskell was implicitly strict, then this solution would satisfy the requirements: <lang Haskell>isAlpha :: Char -> Bool isAlpha = flip elem $ ['a'..'z'] ++ ['A'..'Z']
parse :: IO () parse = do
x <- getChar
putChar x
case () of
_ | x == '.' -> return ()
| isAlpha x -> parse
| otherwise -> do
c <- revParse
putChar c
if c == '.'
then return ()
else parse
revParse :: IO Char revParse = do
x <- getChar
case () of
_ | x == '.' -> return x
| isAlpha x -> do
c <- revParse
putChar x
return c
| otherwise -> return x
main :: IO () main = hSetBuffering stdin NoBuffering >> hSetBuffering stdout NoBuffering >>
parse >> putStrLn ""</lang>
Linux urxvt output:
$ ./OddWord wwhhaatt,,is,si,tthhee;;meaning,gninaem,ooff::life.efil. $ echo "what,is,the;meaning,of:life." | ./OddWord what,si,the;gninaem,of:efil. $ echo "we,are;not,in,kansas;any,more." | ./OddWord we,era;not,ni,kansas;yna,more.
Windows command prompt output:
>OddWord.exe what,is,the;meaning,of:life. what,si,the;gninaem,of:efil. >echo what,is,the;meaning,of:life. | OddWord.exe what,si,the;gninaem,of;efil. >echo we,are;not,in,kansas;any,more. | OddWord.exe we,era;not,ni,kansas;yna,more.
Icon and Unicon
The following recursive version is based on the non-deferred GO version. A co-expression is used to turn the parameter to the wrapper into a character at a time stream.
<lang Icon>procedure main() every OddWord(!["what,is,the;meaning,of:life.",
"we,are;not,in,kansas;any,more."])
end
procedure OddWord(stream) #: wrapper for demonstration
write("Input stream: ",stream)
writes("Output stream: ") & eWord(create !stream,'.,;:') & write()
end
procedure eWord(stream,marks) #: handle even words
repeat {
repeat
writes(@stream) ? if ="." then return else if any(marks) then break
if writes(oWord(stream,marks)) == '.' then return
}
end
procedure oWord(stream,marks) #: handle odd words (reverse)
if any(marks,s := @stream) then return s return 1(oWord(stream,marks), writes(s))
end</lang>
Output:
Input stream: what,is,the;meaning,of:life. Output stream: what,si,the;gninaem,of:efil. Input stream: we,are;not,in,kansas;any,more. Output stream: we,era;not,ni,kansas;yna,more.
A slightly different solution which uses real I/O from stdin is: <lang Unicon>procedure main(A)
repeat (while writes((any(&letters, c := reads(&input,1)),c))) |
(writes(c) ~== "." ~== writes(rWord())) | break write()
end
procedure rWord(c)
c1 := rWord((any(&letters, c1 := reads(&input,1)),c1)) writes(\c) return c1
end</lang> And some sample runs:
->rw what,is,the;meaning,of:life. what,si,the;gninaem,of:efil. ->rw we,are;not,in,kansas;any,more. we,era;not,ni,kansas;yna,more. ->
J
This task's requirement to perform buffering implicitly rather than explicitly was perplexing from a J point of view (see talk page for some of that discussion). To avoid this issue, this implementation uses a coroutine-like utility.
J also lacks character stream support, so this implementation uses a stream-like implementation.
<lang j>putch=: 4 :0 NB. coroutine verb
outch y return x
)
isletter=: toupper ~: tolower
do_char=: 3 :0 NB. coroutine verb
ch=. getch
if. isletter ch do.
if. odd do.
putch&ch yield do_char return.
end.
else.
odd=: -. odd
end.
return ch
)
evenodd=: 3 :0
clear_outstream begin_instream y odd=: 0 whilst. '.'~:char do. outch char=. do_char coroutine end.
)</lang>
Note that in the couroutine-like support page we defined u yield v y such that it produces a result which, when returned to the coroutine helper verb, will cause the deferred execute u v y in a context where both u and v are expected to be coroutine verbs (they will produce a result either wrapped with yield or with return). Likewise return wraps the result with instructions for the coroutine helper, instructing it to use the returned result "as-is". (And, if return is used with an empty stack in the helper, that instance would be the result of the coroutine helper.)
Note that when we curry putch with ch (in putch&ch) we get a verb which needs only one argument. So in this case, x in putch (its left argument) will be the right argument of the derived verb. In other words, in this example, it will be the result of the do_char instance that uses return ch -- this will be the first non-letter character that is seen when dealing with the odd case.
With this implementation:
<lang j> evenodd 'what,is,the;meaning,of:life.' what,si,the;gninaem,of:efil.
evenodd 'we,are;not,in,kansas;any,more.'
we,era;not,ni,kansas;yna,more.</lang>
That said, note that this implementation has significant overhead when compared to a more direct implementation of the algorithm.
Java
<lang java>public class OddWord {
interface CharHandler {
CharHandler handle(char c) throws Exception;
}
final CharHandler fwd = new CharHandler() {
public CharHandler handle(char c) { System.out.print(c); return (Character.isLetter(c) ? fwd : rev); }
};
class Reverser extends Thread implements CharHandler {
Reverser() { setDaemon(true); start(); } private Character ch; // For inter-thread comms private char recur() throws Exception { notify(); while (ch == null) wait(); char c = ch, ret = c; ch = null; if (Character.isLetter(c)) { ret = recur(); System.out.print(c); } return ret; } public synchronized void run() { try { while (true) { System.out.print(recur()); notify(); } } catch (Exception e) {} } public synchronized CharHandler handle(char c) throws Exception { while (ch != null) wait(); ch = c; notify(); while (ch != null) wait(); return (Character.isLetter(c) ? rev : fwd); }
} final CharHandler rev = new Reverser();
public void loop() throws Exception {
CharHandler handler = fwd; int c; while ((c = System.in.read()) >= 0) { handler = handler.handle((char) c); }
}
public static void main(String[] args) throws Exception {
new OddWord().loop();
}
}</lang> Output is equivalent to that of the Python solution.
Julia
<lang julia># io = readstring(STDIN) io = "what,is,the;meaning,of:life." i = 0
readbyte!() = io[global i += 1] writebyte(c) = print(Char(c))
function odd(prev::Function = () -> false)
a = readbyte!()
if !isalpha(a)
prev()
writebyte(a)
return a != '.'
end
# delay action until later, in the shape of a closure clos() = (writebyte(a); prev())
return odd(clos)
end
function even()
while true
c = readbyte!()
writebyte(c)
if !isalpha(c) return c != '.' end
end
end
evn = false while evn ? odd() : even()
evn = !evn
end</lang>
- Output:
what,si,the;gninaem,of:efil.
Kotlin
<lang scala>// version 1.1.3
typealias Func = () -> Unit
fun doChar(odd: Boolean, f: Func?): Boolean {
val c = System.`in`.read() if (c == -1) return false // end of stream reached val ch = c.toChar()
fun writeOut() {
print(ch)
if (f != null) f()
}
if (!odd) print(ch)
if (ch.isLetter()) return doChar(odd, ::writeOut)
if (odd) {
if (f != null) f()
print(ch)
}
return ch != '.'
}
fun main(args: Array<String>) {
repeat(2) {
var b = true
while (doChar(!b, null)) b = !b
System.`in`.read() // remove '\n' from buffer
println("\n")
}
}</lang>
- Output:
what,is,the;meaning,of:life. what,si,the;gninaem,of:efil. we,are;not,in,kansas;any,more. we,era;not,ni,kansas;yna,more.
Lasso
<lang Lasso>define odd_word_processor(str::string) => { local( isodd = false, pos = 1, invpos = 1, lastpos = 1 ) while(#str->get(#pos) != '.' && #pos <= #str->size) => { if(not #str->isAlpha(#pos)) => { not #isodd ? #isodd = true | #isodd = false } if(#isodd) => { #lastpos = 1 #invpos = 1 while(#str->isAlpha(#pos+#lastpos) && #pos+#lastpos <= #str->size) => { #lastpos++ } 'odd lastpos: '+#lastpos+'\r' local(maxpos = #pos+#lastpos-1) while(#invpos < (#lastpos+1)/2) => { local(i,o,ipos,opos) #ipos = #pos+#invpos #opos = #pos+(#lastpos-#invpos) #i = #str->get(#ipos) #o = #str->get(#opos)
//'switching '+#i+' and '+#o+'\r'
//'insert '+#o+' at '+(#ipos)+'\r' #str = string_insert(#str,-position=(#ipos),-text=#o)
//'remove redundant pos '+(#ipos+1)+'\r' #str->remove(#ipos+1,1)
//'insert '+#i+' at '+(#opos)+'\r' #str = string_insert(#str,-position=(#opos),-text=#i)
//'remove redundant pos '+(#opos+1)+'\r' #str->remove(#opos+1,1)
#invpos++ } #pos += #lastpos - 1 } //#str->get(#pos) + #isodd + '\r' #pos += 1 } return #str }
'orig:\rwhat,is,the;meaning,of:life.\r' 'new:\r' odd_word_processor('what,is,the;meaning,of:life.') '\rShould have:\rwhat,si,the;gninaem,of:efil.'</lang>
- Output:
orig: what,is,the;meaning,of:life. new: what,si,the;gninaem,of:efil. Should have: what,si,the;gninaem,of:efil.
Lua
<lang lua>function reverse()
local ch = io.read(1)
if ch:find("%w") then
local rc = reverse()
io.write(ch)
return rc
end
return ch
end
function forward()
ch = io.read(1)
io.write(ch)
if ch == "." then return false end
if not ch:find("%w") then
ch = reverse()
if ch then io.write(ch) end
if ch == "." then return false end
end
return true
end
while forward() do end</lang>
- Output:
$ echo what,is,the;meaning,of:life.|oddword.lua what,si,the;gninaem,of:efil. $ echo we,are;not,in,kansas;any,more.|oddword.lua we,era;not,ni,kansas;yna,more.
M2000 Interpreter
Using Recursion
PepareStream$() with null string set a lambda which read from keyboard and end reading when . found.
PepareStream$() with not a null string make a file and set a lambda to read it So code works with any stream, until get a null string We can pass by reference the lambda function but here we pass by reference the f factor, which for keyboard check the end, and for file work as file handler and at then end as a flag which check the end.
<lang M2000 Interpreter> Module Checkit {
global out$
document out$
Function PrepareStream$ (buf$) {
\\ get a temporary file
if buf$="" then {
class ref {
f
class:
module ref (.f) { }
}
\\ make f closure by reference
m->ref(false)
=lambda$ m->{
if m=>f then exit
r$=Key$
m=>f=r$="."
=r$
}
\\ exit function
break
}
name$=tempname$
\\ we use Ansi type files
Open name$ for output as F
Print #F, buf$;
Close #F
Open name$ for input as #f
class ref {
f
class:
module ref (.f) { }
}
\\ make f closure by reference
m->ref(f)
=lambda$ m -> {
if m=>f=-1000 then exit
def r$
if not eof(#m=>f) then r$=Input$(#m=>f,2)
=r$
if r$="" or r$="." then close #m=>f : m=>f=-1000
}
}
Module Odd(c$) {
one$=""
Module MyEven(c$, &last$) {
one$=If$(last$=""->c$(), last$)
if one$="" then exit
if not one$ ~"[a-zA-Z]" Then last$=one$: exit
\\ print before
Print one$;
out$<=one$
Call MyEven, c$, &last$
}
Module MyOdd(c$, &last$) {
one$=If$(last$=""->c$(), last$)
if one$="" then exit
if not one$ ~"[a-zA-Z]" Then last$=one$: exit
Call MyOdd, c$, &last$
\\ print after
Print one$;
out$<=one$
}
Do {
one$=""
Call MyEven, c$, &one$
if one$="" then exit
Print one$;
out$<=one$
one$=""
Call MyOdd, c$, &one$
if one$="" then exit
Print one$;
out$<=one$
} Always
Print
out$<={
}
}
\\ Feeding keyboard
keyboard "what,is,the;meaning,of:life."
Odd PrepareStream$("")
\\ Use a file for input
Odd PrepareStream$("we,are;not,in,kansas;any,more.")
clipboard out$
} Checkit </lang>
Using Closure
<lang M2000 Interpreter> Module OddWord {
k$=lambda$->""
state=false
odd=True
do {
a$=key$
if a$ ~"[a-zA-Z]" then {
If state Else state~ : odd~
if state and odd then k$=lambda$ k$, a$->a$+k$() : Continue
Print a$;
} Else {
If state Then state~
if odd then Print k$(); : k$=lambda$->""
Print a$;
}
} until a$="."
Print
} keyboard "what,is,the;meaning,of:life." OddWord Keyboard "we,are;not,in,kansas;any,more." OddWord </lang>
- Output:
what,si,the;gninaem,of:efil. we,era;not,ni,kansas;yna,more.
Nim
<lang nim>import unicode
type Proc = proc(): bool {.closure.}
var nothing: Proc = proc(): bool {.closure.} = false
proc odd(prev = nothing): bool =
let a = stdin.readChar() if not isAlpha(Rune(ord(a))): discard prev() stdout.write(a) return a != '.'
# delay action until later, in the shape of a closure proc clos(): bool = stdout.write(a) prev()
return odd(clos)
proc even(): bool =
while true:
let c = stdin.readChar()
stdout.write(c)
if not isAlpha(Rune(ord(c))):
return c != '.'
var e = false while (if e: odd() else: even()):
e = not e</lang>
Output:
$ echo "what,is,the;meaning,of:life." | ./oddword what,si,the;gninaem,of:efil. echo "we,are;not,in,kansas;any,more." | ./oddword we,era;not,ni,kansas;yna,more.
OCaml
<lang ocaml>let is_alpha c =
c >= 'a' && c <= 'z' || c >= 'A' && c <= 'Z'
let rec odd () =
let c = input_char stdin in if is_alpha c then (let e = odd () in print_char c; e) else (c)
let rec even () =
let c = input_char stdin in if is_alpha c then (print_char c; even ()) else print_char c
let rev_odd_words () =
while true do even (); print_char (odd ()) done
let () =
try rev_odd_words () with End_of_file -> ()</lang>
Executing:
$ echo "what,is,the;meaning,of:life." | ocaml odd_word_problem.ml what,si,the;gninaem,of:efil.
Ol
Use string iterators. <lang scheme> (define (odd_word_problem words)
(letrec ((odd (lambda (s out)
(let loop ((s s) (l '()))
(cond
((null? s)
out)
((pair? s)
(if (<= #\a (car s) #\z)
(loop (cdr s) (cons (car s) l))
(even (cdr s) (cons (cons (reverse l) (car s)) out))))
(else
(loop (s) l))))))
(even (lambda (s out)
(let loop ((s s) (l '()))
(cond
((null? s)
out)
((pair? s)
(if (<= #\a (car s) #\z)
(loop (cdr s) (cons (car s) l))
(odd (cdr s) (cons (cons l (car s)) out))))
(else
(loop (s) l)))))))
(for-each (lambda (p)
(display (runes->string (car p)))
(display (string (cdr p))))
(reverse
(odd (str-iter words) '()))))
(print))
(odd_word_problem "what,is,the;meaning,of:life.") (odd_word_problem "we,are;not,in,kansas;any,more.") </lang>
Output:
what,si,the;gninaem,of:efil. we,era;not,ni,kansas;yna,more.
Perl
All versions process text until EOF, not dot.
Input:
what,is,the;meaning,of:life.
Output:
what,si,the;gninaem,of:efil.
Closure version
<lang Perl>sub r { my ($f, $c) = @_; return sub { print $c; $f->(); }; }
$r = sub {};
while (read STDIN, $_, 1) { $w = /^[a-zA-Z]$/; $n++ if ($w && !$l); $l = $w; if ($n & 1 || !$w) { $r->(); $r = sub{}; print; } else { $r = r($r, $_); } } $r->();</lang>
Recursion version
<lang Perl>sub rev { my $c; read STDIN, $c, 1; if ($c =~ /^[a-zA-Z]$/) { my $r = rev(); print $c; return $r; } else { return $c; } }
while (read STDIN, $_, 1) { $w = /^[a-zA-Z]$/; $n++ if ($w && !$l); $l = $w; if ($n & 1) { print; } else { my $r = rev(); print $_; print $r; $n = 0; $l = 0; } }</lang>
Threads (processes) version
Perl still has weak threads support. Far more safe yet portable is to use processes (fork).
Here, fork is used instead of threads and pipe is used instead of conditional variable. <lang Perl>$|=1;
while (read STDIN, $_, 1) { $w = /^[a-zA-Z]$/; $n++ if ($w && !$l); $l = $w; if ($n & 1 || !$w) { close W; while(wait()!=-1){} print; } else { open W0, ">&", \*W; close W; pipe R,W; if (!fork()) { close W; <R>; print $_; close W0; exit; } close W0; close R; } }</lang>
Phix
Uses plain and simple recursion, no closures, and no other tricks.
To test direct console input, comment out string s .. getchar(), and uncomment getc(0) and the prompt.
Likewise use integer fn = open("somefile","r"), and getc(fn) should you want to test file i/o.
<lang Phix>string s = "what,is,the;meaning,of:life."
--string s = "we,are;not,in,kansas;any,more."
integer i = 0
function getchar()
i += 1 return s[i]
end function
function wrod(integer rev)
integer ch = getchar(), nch
-- integer ch = getc(0), nch
if not find(ch," .,:;!?") then
if rev then
nch = wrod(rev)
end if
puts(1,ch)
if not rev then
nch = wrod(rev)
end if
ch = nch
end if
return ch
end function
--puts(1,"Enter words separated by a single punctuation mark (i.e. !?,.;:) and ending with .\n") integer rev = 0 while 1 do
integer ch = wrod(rev) puts(1,ch) if ch='.' then exit end if rev = 1-rev
end while</lang>
- Output:
what,si,the;gninaem,of:efil. we,era;not,ni,kansas;yna,more.
PHP
<lang PHP>$odd = function ($prev) use ( &$odd ) { $a = fgetc(STDIN); if (!ctype_alpha($a)) { $prev(); fwrite(STDOUT, $a); return $a != '.'; } $clos = function () use ($a , $prev) { fwrite(STDOUT, $a); $prev(); }; return $odd($clos); }; $even = function () { while (true) { $c = fgetc(STDIN); fwrite(STDOUT, $c); if (!ctype_alpha($c)) { return $c != "."; } } }; $prev = function(){}; $e = false; while ($e ? $odd($prev) : $even()) { $e = !$e; }</lang>
PicoLisp
<lang PicoLisp>(de oddWords ()
(use C
(loop
(until (sub? (prin (setq C (char))) "!,.:;?"))
(T (= "." C))
(setq C (char))
(T
(= "."
(prin
(recur (C)
(if (sub? C "!,.:;?")
C
(prog1 (recurse (char)) (prin C)) ) ) ) ) ) )
(prinl) ) )</lang>
Test: <lang PicoLisp>(in "txt1" (oddWords)) (in "txt2" (oddWords))</lang> Output:
what,si,the;gninaem,of:efil. we,era;not,ni,kansas;yna,more.
PL/I
<lang PL/I>test: procedure options (main); /* 2 August 2014 */
declare (ch, ech) character (1); declare odd file;
get_word: procedure recursive;
declare ch character (1);
get file (odd) edit (ch) (a(1));
if index('abcdefghijklmnopqrstuvwxyz', ch) > 0 then call get_word;
if index('abcdefghijklmnopqrstuvwxyz', ch) > 0 then
put edit (ch) (a);
else ech = ch;
end get_word;
open file (odd) input title ('/ODDWORD.DAT,TYPE(text),recsize(100)');
do forever;
do until (index('abcdefghijklmnopqrstuvwxyz', ch) = 0 );
get file (odd) edit (ch) (a(1)); put edit (ch) (a);
end;
if ch = '.' then leave;
call get_word;
put edit (ech) (a);
if ech = '.' then leave;
end;
end test;</lang> file:
what,is,the;meaning,of:life.
output:
what,si,the;gninaem,of:efil.
file:
we,are;not,in,kansas;any,more.
output:
we,era;not,ni,kansas;yna,more.
Prolog
Works with SWI-Prolog. <lang Prolog>odd_word_problem :- read_line_to_codes(user_input, L), even_word(L, Out, []), string_to_list(Str, Out), writeln(Str).
even_word(".") --> ".".
even_word([H | T]) --> {char_type(H,alnum)}, [H], even_word(T).
even_word([H | T]) --> [H], odd_word(T, []).
odd_word(".", R) --> R, ".".
odd_word([H|T], R) --> {char_type(H,alnum)}, odd_word(T, [H | R]).
odd_word([H|T], R) --> R, [H], even_word(T). </lang> Output :
?- odd_word_problem. |: what,is,the;meaning,of:life. what,si,the;gninaem,of:efil. true . ?- odd_word_problem. |: we,are;not,in,kansas;any,more. we,era;not,ni,kansas;yna,more. true .
PureBasic
This example uses recursion. <lang PureBasic>#False = 0
- True = 1
Global *inputPtr.Character
Macro nextChar()
*inputPtr + SizeOf(Character)
EndMacro
Procedure isPunctuation(c.s)
If FindString("!?()[]{},.;:-'" + #DQUOTE$, c)
ProcedureReturn #True
EndIf
ProcedureReturn #False
EndProcedure
Procedure oddWord()
Protected c.c c = *inputPtr\c If isPunctuation(Chr(*inputPtr\c)) ProcedureReturn Else nextChar() oddWord() EndIf Print(Chr(c))
EndProcedure
Procedure oddWordProblem(inputStream.s)
*inputPtr = @inputStream
Define isOdd = #False
While *inputPtr\c
If isOdd
oddWord()
Else
Repeat
Print(Chr(*inputPtr\c))
nextChar()
Until isPunctuation(Chr(*inputPtr\c))
EndIf
Print(Chr(*inputPtr\c))
isOdd ! 1 ;toggle word indicator
nextChar()
Wend
EndProcedure
Define inputStream.s If OpenConsole()
Repeat
PrintN(#CRLF$ + #CRLF$ + "Enter a series of words consisting only of English letters (i.e. a-z, A-Z)")
PrintN("and that are separated by a punctuation mark (i.e. !?()[]{},.;:-' or " + #DQUOTE$ + ").")
inputStream = Input()
oddWordProblem(inputStream) ;assume input is correct
Until inputStream = ""
Print(#CRLF$ + #CRLF$ + "Press ENTER to exit"): Input()
CloseConsole()
EndIf</lang> Sample output:
Enter a series of words consisting only of English letters (i.e. a-z, A-Z)
and that are separated by a punctuation mark (i.e. !?()[]{},.;:-' or ").
what,is,the;meaning,of:life.
what,si,the;gninaem,of:efil.
Enter a series of words consisting only of English letters (i.e. a-z, A-Z)
and that are separated by a punctuation mark (i.e. !?()[]{},.;:-' or ").
we,are;not,in,kansas;any,more.
we,era;not,ni,kansas;yna,more.
Python
<lang python>from sys import stdin, stdout
def char_in(): return stdin.read(1) def char_out(c): stdout.write(c)
def odd(prev = lambda: None): a = char_in() if not a.isalpha(): prev() char_out(a) return a != '.'
# delay action until later, in the shape of a closure def clos(): char_out(a) prev()
return odd(clos)
def even(): while True: c = char_in() char_out(c) if not c.isalpha(): return c != '.'
e = False while odd() if e else even(): e = not e</lang> Running:<lang>$ echo "what,is,the;meaning,of:life." | python odd.py what,si,the;gninaem,of:efil. $ echo "we,are;not,in,kansas;any,more." | python odd.py we,era;not,ni,kansas;yna,more.</lang>
In this version, the action of printing the terminating punctuation is put in a closure and returned by odd().
<lang python>from sys import stdin, stdout
def char_in(): return stdin.read(1) def char_out(c): stdout.write(c)
def odd(): a = char_in() if a.isalpha(): r = odd() char_out(a) return r
# delay printing terminator until later, in the shape of a closure def clos(): char_out(a) return a != '.'
return clos
def even(): while True: c = char_in() char_out(c) if not c.isalpha(): return c != '.'
e = False while odd()() if e else even(): e = not e</lang>
Using coroutines and recursion
<lang python>from sys import stdin, stdout
def fwd(c):
if c.isalpha():
return [stdout.write(c), (yield from fwd((yield f)))][1]
else:
return c
def rev(c):
if c.isalpha():
return [(yield from rev((yield r))), stdout.write(c)][0]
else:
return c
def fw():
while True:
stdout.write((yield from fwd((yield r))))
def re():
while True:
stdout.write((yield from rev((yield f))))
f = fw() r = re() next(f) next(r)
coro = f while True:
c = stdin.read(1)
if not c:
break
coro = coro.send(c)</lang>
Quackery
It is not possible to comply with the requirements of this task to the letter as the task presumes the existence of an implicit stack, e.g. a stack frame storing state information during subroutine calls, including recursive calls. In Quackery such information is stored on a second stack (usually referred to as the stack) which is explicit.
Also, there is no character-at-a-time input stream mechanism implemented in Quackery. Instead, the code uses the word behead which equivalently returns successive characters from a string, one at a time.
Therefore this solution is in the spirit of the requirements, if not the letter.
<lang Quackery>[ upper dup lower != ] is letter ( c --> b )
forward is backwords ( $ --> $ )
[ [ behead
dup letter while emit again ] dup emit char . != if backwords ] is forwords ( $ --> $ )
[ [ behead
dup letter while swap recurse rot emit ] dup emit char . != if forwords ] resolves backwords ( $ --> $ )
[ forwords drop cr ] is oddwords ( $ --> )
$ "we,are;not,in,kansas;any,more." oddwords $ "what,is,the;meaning,of:life." oddwords</lang>
- Output:
we,era;not,ni,kansas;yna,more. what,si,the;gninaem,of:efil.
Racket
Simple solution, using a continuation thunk for the reverse parts. <lang racket>
- !/bin/sh
- |
exec racket -tm- "$0" "$@" |#
- lang racket
(define (even k)
(define c (read-char))
(cond [(eq? c eof) (k)]
[(not (char-alphabetic? c)) (k) (write-char c) (odd)]
[else (even (λ() (write-char c) (k)))]))
(define (odd)
(define c (read-char)) (unless (eq? c eof) (write-char c) (if (char-alphabetic? c) (odd) (even void))))
(provide main) (define (main) (odd) (newline))
- (with-input-from-string "what,is,the;meaning,of
- life." main)
- ;; -> what,si,the;gninaem,of
- efil.
- (with-input-from-string "we,are;not,in,kansas;any,more." main)
- ;; -> we,era;not,ni,kansas;yna,more.
</lang>
Raku
(formerly Perl 6) A recursive solution, with the added feature that it treats each line separately. <lang perl6>my &in = { $*IN.getc // last }
loop {
ew(in); ow(in).print;
}
multi ew ($_ where /\w/) { .print; ew(in); } multi ew ($_) { .print; next when "\n"; }
multi ow ($_ where /\w/) { ow(in) x .print; } multi ow ($_) { $_; }</lang>
- Output:
$ ./oddword we,are;not,in,kansas;any,more. we,era;not,ni,kansas;yna,more. what,is,the;meaning,of:life. what,si,the;gninaem,of:efil.
Note how the even/oddness is reset on the line boundary; if not, the second line might have started out in an odd state and reversed "what" instead of "is". The call to next prevents that by sending the loop back to its initial state.
There is one clever trick here with the x operator; it evaluates both its arguments in order, but in this case only returns the left argument because the right one is always 1 (True). You can think of it as a reversed C-style comma operator.
REXX
The REXX program writes some header information to aid in visual fidelity when displaying the output to the
screen (also a blank line is written to make the screen display righteous; it's assumed that writing titles and
blank lines doesn't break the spirit of the restrictions (single character I/O) [the 8th line with the
three says].
This displaying of informative messages is only to help the observer to know what is being performed.
No recursion or the stack is used. The program could've been written without subroutines. <lang rexx>/*REXX program solves the odd word problem by only using (single) byte input/output.*/
iFID_ = 'ODDWORD.IN' /*Note: numeric suffix is added later.*/
oFID_ = 'ODDWORD.' /* " " " " " " */
do case=1 for 2; #= 0 /*#: is the number of characters read.*/
iFID= iFID_ || case /*read ODDWORD.IN1 or ODDWORD.IN2 */
oFID= oFID_ || case /*write ODDWORD.1 or ODDWORD.2 */
say; say; say '════════ reading file: ' iFID "════════" /* ◄■■■■■■■■■ optional. */
do until x==. /* [↓] perform until reaching a period*/
do until \datatype(x, 'M') /* [↓] " " punctuation found*/
call rChar /*read a single character. */
call wChar /*write " " " */
end /*until \data···*/ /* [↑] read/write until punctuation. */
if x==. then leave /*is this the end─of─sentence (period)?*/
call readLetters; punct= # /*save the location of the punctuation.*/
do j=#-1 by -1 /*read some characters backwards. */
call rChar j /*read previous word (backwards). */
if \datatype(x, 'M') then leave /*Found punctuation? Then leave J. */
call wChar /*write a character (which is a letter)*/
end /*j*/ /* [↑] perform for "even" words. */
call rLett /*read letters until punctuation found.*/
call wChar; #= punct /*write a char; punctuation location. */
end /*until x==.*/
end /*case*/ /* [↑] process both of the input files*/
exit /*stick a fork in it, we're all done. */ /*──────────────────────────────────────────────────────────────────────────────────────*/ rLett: do until \datatype(x, 'M'); call rChar; end; return wChar: call charout , x /*console*/; call charout oFID, x /*file*/; return /*──────────────────────────────────────────────────────────────────────────────────────*/ rChar: if arg()==0 then do; x= charin(iFID); #= #+1; end /*read next char*/
else x= charin(iFID, arg(1) ); /* " specific " */ return</lang>
- output when using the two (default) input files which contain:
- input file ODDWORD.IN1 ───► what,is,the;meaning,of:life.
- input file ODDWORD.IN2 ───► we,are;not,in,kansas;any,more.
The output is written to the terminal screen as well as to a couple of unique files. Only the screen output is
shown here, the output files mirror the display except for the headers (reading file: xxx) and the writing
(SAYing) of blank lines which helps keep the screen righteous after using the REXX charout BIF which
wrote to the terminal.
════════ reading file: ODDWORD.IN1 ════════ what,si,the;gninaem,of:efil. ════════ reading file: ODDWORD.IN2 ════════ we,era;not,ni,kansas;yna,more.
Ring
<lang ring>
- Project : Odd word problem
test = "what,is,the;meaning,of:life." n1 = 1 testarr = [] testorigin = test test = substr(test, ",", " ") test = substr(test, ";", " ") test = substr(test, ":", " ") test = substr(test, ".", " ")
while true
n2 = substring(test, " ", n1)
n3 = substring(test, " ", n2 + 1)
if n2>0 and n3>0
strcut = substr(test, n2 + 1, n3 - n2)
strcut = trim(strcut)
if strcut != ""
add(testarr, strcut)
n1 = n3 + 1
else
exit
ok
ok
end
for n = 1 to len(testarr)
strrev = revstr(testarr[n]) testorigin = substr(testorigin, testarr[n], strrev)
next see testorigin + nl
func Substring str,substr,n
newstr=right(str,len(str)-n+1)
nr = substr(newstr, substr)
return n + nr -1
func revstr(cStr)
cStr2 = ""
for x = len(cStr) to 1 step -1
cStr2 += cStr[x]
next
return cStr2
</lang> Output:
what,si,the;gninaem,of:efil.
Ruby
These Ruby programs store each character in a single-character string.
Using fibers and recursion
<lang ruby>f, r = nil fwd = proc {|c|
c =~ /alpha:/ ? [(print c), fwd[Fiber.yield f]][1] : c }
rev = proc {|c|
c =~ /alpha:/ ? [rev[Fiber.yield r], (print c)][0] : c }
(f = Fiber.new { loop { print fwd[Fiber.yield r] }}).resume (r = Fiber.new { loop { print rev[Fiber.yield f] }}).resume
coro = f until $stdin.eof?
coro = coro.resume($stdin.getc)
end</lang>
Using continuations
<lang ruby>require 'continuation' unless defined? Continuation require 'stringio'
- Save current continuation.
def savecc(*data)
# With MRI 1.8 (but not 1.9), the array literal
# [callcc {|cc| cc}, *data]
# used the wrong return value from callcc. The workaround is to
# put callcc outside the array literal.
continuation = callcc {|cc| cc}
[continuation, *data]
end
- Jump back to continuation, where savecc will return [nil, *data].
def jump_back(continuation)
continuation[nil]
end
def read_odd_word(input, output)
first_continuation, last_continuation = nil reverse = false # Read characters. Loop until end of stream. while c = input.getc c = c.chr # For Ruby 1.8, convert Integer to String. if c =~ /alpha:/ # This character is a letter. if reverse # Odd word: Write letters in reverse order. saving, last_continuation, c = savecc(last_continuation, c) if saving last_continuation = saving else # After jump: print letters in reverse. output.print c jump_back last_continuation end else # Even word: Write letters immediately. output.print c end else # This character is punctuation. if reverse # End odd word. Fix trampoline, follow chain of continuations # (to print letters in reverse), then bounce off trampoline. first_continuation, c = savecc(c) if first_continuation jump_back last_continuation end output.print c # Write punctuation. reverse = false # Begin even word. else output.print c # Write punctuation. reverse = true # Begin odd word. # Create trampoline to bounce to (future) first_continuation. last_continuation, = savecc unless last_continuation jump_back first_continuation end end end end output.puts # Print a cosmetic newline.
end
def odd_word(string)
read_odd_word StringIO.new(string), $stdout
end
odd_word "what,is,the;meaning,of:life." odd_word "we,are;not,in,kansas;any,more."</lang>
Run BASIC
<lang runbasic>open "oddWord.txt" for input as #f ' read input stream while not(eof(#f)) line input #f, a$ oddW$ = "" ' begin the result oddW with blank px = 0 ' begin word search location with 0 count = 0 ' begin the word count to 0 while x < len(a$) ' look at each character x = instr(a$,",",px) ' search for comma (,) if x = 0 then x = len(a$) ' no more commas? x1 = instr(a$,";",px) ' search for (;) x2 = instr(a$,":",px) ' search for (:) if x1 <> 0 then x = min(x,x1) ' what came first the , ; or : if x2 <> 0 then x = min(x,x2)
w$ = mid$(a$,px,x - px) ' get the word seperated by , ; or :
if count and 1 then ' is it the odd word w1$ = "" for i = len(w$) to 1 step -1 w1$ = w1$ + mid$(w$,i,1) ' reverse odd words next i w$ = w1$ end if
oddW$ = oddW$ + w$ + mid$(a$,x,1) ' add the word to the end of oddW$
px = x + 1 ' bump word search location for next while count = count + 1 ' count the words wend print a$;" -> ";oddW$ ' print the original and result next ii wend close #f</lang>
what,is,the;meaning,of:life. -> what,si,the;gninaem,of:efil. we,are;not,in,kansas;any,more. -> we,era;not,ni,kansas;yna,more.
Scala
<lang Scala>import scala.io.Source import java.io.PrintStream
def process(s: Source, p: PrintStream, w: Int = 0): Unit = if (s.hasNext) s.next match {
case '.' => p append '.' case c if !Character.isAlphabetic(c) => p append c; reverse(s, p, w + 1) case c => p append c; process(s, p, w)
}
def reverse(s: Source, p: PrintStream, w: Int = 0, x: Char = '.'): Char = s.next match {
case c if !Character.isAlphabetic(c) => p append x; c
case c => val n = reverse(s, p, w, c);
if (x == '.') {p append n; process(s, p, w + 1)} else p append x; n
}
process(Source.fromString("what,is,the;meaning,of:life."), System.out); println process(Source.fromString("we,are;not,in,kansas;any,more."), System.out); println</lang>
- Output:
what,si,the;gninaem,of:efil. we,era;not,ni,kansas;yna,more.
Scheme
Output is identical to python. <lang lisp>(define (odd)
(let ((c (read-char)))
(if (char-alphabetic? c)
(let ((r (odd)))
(write-char c) r)
(lambda () (write-char c) (char=? c #\.)))))
(define (even)
(let ((c (read-char)))
(write-char c)
(if (char-alphabetic? c)
(even)
(char=? c #\.))))
(let loop ((i #f))
(if (if i ((odd)) (even)) (exit) (loop (not i))))</lang>
Seed7
<lang seed7>$ include "seed7_05.s7i";
include "chartype.s7i";
const func char: doChar (in boolean: doReverse) is func
result
var char: delimiter is ' ';
local
var char: ch is ' ';
begin
ch := getc(IN);
if ch in letter_char then
if doReverse then
delimiter := doChar(doReverse);
write(ch);
else
write(ch);
delimiter := doChar(doReverse);
end if;
else
delimiter := ch;
end if;
end func;
const proc: main is func
local
var char: delimiter is ' ';
var boolean: doReverse is FALSE;
begin
repeat
delimiter := doChar(doReverse);
write(delimiter);
doReverse := not doReverse;
until delimiter = '.';
writeln;
end func;</lang>
- Output:
> s7 oddWordProblem SEED7 INTERPRETER Version 5.0.5203 Copyright (c) 1990-2014 Thomas Mertes what,is,the;meaning,of:life. what,si,the;gninaem,of:efil.
Sidef
Recursive solution:
<lang ruby>func rev {
(var c = STDIN.getc) \\ return()
if (c ~~ /^[a-z]\z/i) {
var r = rev()
print c
return r
}
return c
}
var (n=0, l=false) while (defined(var c = STDIN.getc)) {
var w = (c ~~ /^[a-z]\z/i)
++n if (w && !l)
l = w
if (n & 1) {
print c
} else {
var r = rev()
print(c, r)
n = 0
l = false
}
}</lang>
- Output:
$ echo 'what,is,the;meaning,of:life.' | sidef script.sf what,si,the;gninaem,of:efil. $ echo 'we,are;not,in,kansas;any,more.' | sidef script.sf we,era;not,ni,kansas;yna,more.
Tcl
Although the input is handled as strings, they're all as single-character strings.
<lang tcl>package require Tcl 8.6
proc fwd c {
expr {[string is alpha $c] ? "[fwd [yield f][puts -nonewline $c]]" : $c}
} proc rev c {
expr {[string is alpha $c] ? "[rev [yield r]][puts -nonewline $c]" : $c}
} coroutine f while 1 {puts -nonewline [fwd [yield r]]} coroutine r while 1 {puts -nonewline [rev [yield f]]} for {set coro f} {![eof stdin]} {} {
set coro [$coro [read stdin 1]]
}</lang> Output is identical to Python and Scheme versions.
The only difference between the two coroutines (apart from the different names used when flipping back and forth) is the timing of the write of the character with respect to the recursive call.
TUSCRIPT
<lang tuscript> $$ MODE TUSCRIPT inputstring=* DATA what,is,the;meaning,of:life. DATA we,are;not,in,kansas;any,more.
BUILD C_GROUP >[pu]=".,;:-"
LOOP i=inputstring pu=STRINGS (i,"|>[pu]|") wo=STRINGS (i,"|<></|") outputstring=""
loop n,w=wo,p=pu r=MOD(n,2) IF (r==0) w=TURN (w) outputstring=CONCAT(outputstring,w,p)
ENDLOOP PRINT outputstring ENDLOOP </lang> Output:
what,si,the;gninaem,of:efil.Brian: we,era;not,ni,kansas;yna,more.
VBA
First way : <lang vb>Private Function OddWordFirst(W As String) As String Dim i As Integer, count As Integer, l As Integer, flag As Boolean, temp As String
count = 1
Do
flag = Not flag
l = FindNextPunct(i, W) - count + 1
If flag Then
temp = temp & ExtractWord(W, count, l)
Else
temp = temp & ReverseWord(W, count, l)
End If
Loop While count < Len(W)
OddWordFirst = temp
End Function
Private Function FindNextPunct(d As Integer, W As String) As Integer Const PUNCT As String = ",;:."
Do
d = d + 1
Loop While InStr(PUNCT, Mid(W, d, 1)) = 0
FindNextPunct = d
End Function
Private Function ExtractWord(W As String, c As Integer, i As Integer) As String
ExtractWord = Mid(W, c, i) c = c + Len(ExtractWord)
End Function
Private Function ReverseWord(W As String, c As Integer, i As Integer) As String Dim temp As String, sep As String
temp = Left(Mid(W, c, i), Len(Mid(W, c, i)) - 1) sep = Right(Mid(W, c, i), 1) ReverseWord = StrReverse(temp) & sep c = c + Len(ReverseWord)
End Function</lang> Second way : <lang vb>Private Function OddWordSecond(Words As String) As String Dim i&, count&, t$, cpt&, j&, l&, d&, f As Boolean Const PUNCT As String = ",;:"
For i = 1 To Len(Words)
'first word
If i = 1 Then
cpt = 1
Do
t = t & Mid(Words, cpt, 1)
cpt = cpt + 1
Loop While InStr(PUNCT, Mid(Words, cpt, 1)) = 0 And cpt < Len(Words)
i = cpt
t = t & Mid(Words, i, 1)
End If
If Right(t, 1) = "." Then Exit For
'Odd words ==> reverse
While InStr(PUNCT, Mid(Words, cpt + 1, 1)) = 0 And cpt < Len(Words)
cpt = cpt + 1
Wend
l = IIf(f = True, i, i + 1)
d = IIf(cpt = Len(Words), cpt - 1, cpt)
For j = d To l Step -1
t = t & Mid(Words, j, 1)
Next
If cpt = Len(Words) Then t = t & ".": Exit For
f = True
i = cpt + 1
t = t & Mid(Words, i, 1)
'Even words
cpt = i + 1
t = t & Mid(Words, cpt, 1)
Do
cpt = cpt + 1
t = t & Mid(Words, cpt, 1)
Loop While InStr(PUNCT, Mid(Words, cpt, 1)) = 0 And cpt < Len(Words)
i = cpt
Next
OddWordSecond = t
End Function</lang> To call Functions : <lang vb>Option Explicit
Sub Main()
Debug.Print "Input : " & "we,are;not,in,kansas;any,more."
Debug.Print "First way : " & OddWordFirst("we,are;not,in,kansas;any,more.")
Debug.Print "Second way : " & OddWordSecond("we,are;not,in,kansas;any,more.")
Debug.Print ""
Debug.Print "Input : " & "what,is,the;meaning,of:life."
Debug.Print "First way : " & OddWordFirst("what,is,the;meaning,of:life.")
Debug.Print "Second way : " & OddWordSecond("what,is,the;meaning,of:life.")
End Sub</lang>
- Output:
Input : we,are;not,in,kansas;any,more. First way : we,era;not,ni,kansas;yna,more. Second way : we,era;not,ni,kansas;yna,more. Input : what,is,the;meaning,of:life. First way : what,si,the;gninaem,of:efil. Second way : what,si,the;gninaem,of:efil.
Wren
<lang ecmascript>import "io" for Stdin,Stdout import "/str" for Char
var fwrite = Fn.new { |ch|
System.write(ch) Stdout.flush()
}
var doChar // recursive doChar = Fn.new { |odd, f|
var c = Stdin.readByte() if (!c) return false // end of stream reached var ch = String.fromByte(c)
var writeOut = Fn.new {
fwrite.call(ch)
if (f) f.call()
}
if (!odd) fwrite.call(ch)
if (Char.isLetter(ch)) return doChar.call(odd, writeOut)
if (odd) {
if (f) f.call()
fwrite.call(ch)
}
return ch != "."
}
for (i in 0..1) {
var b = true
while (doChar.call(!b, null)) b = !b
Stdin.readByte() // remove \n from buffer
System.print("\n")
}</lang>
- Output:
what,is,the;meaning,of,life. what,si,the;gninaem,of,efil. we,are;not,in,kansas;any,more. we,era;not,ni,kansas;yna,more.
zkl
<lang zkl>var [const] delim=",:;/?!@#$%^&*()_+", stop="."; fcn oddly(inStream){
inStream=inStream.walker(3); // character iterator: string, file, etc
doWord:=fcn(inStream,rev,f){ // print next word forewards or reverse
c:=inStream.next();
if(not rev) c.print();
if(not (c==stop or delim.holds(c)))
return(self.fcn(inStream,rev,'{ c.print(); f(); }));
if(rev){ f(); c.print(); }
return(c!=stop);
};
tf:=Walker.cycle(False,True); // every other word printed backwords
while(doWord(inStream, tf.next(), Void)) {}
println();
}</lang> Showing two different input streams: <lang zkl>oddly("what,is,the;meaning,of:life."); oddly(Data(0,String,"we,are;not,in,kansas;any,more."));</lang>
- Output:
what,si,the;gninaem,of:efil. we,era;not,ni,kansas;yna,more.