⚠️ Warning: This is a draft ⚠️

This means it might contain formatting issues, incorrect code, conceptual problems, or other severe issues.

If you want to help to improve and eventually enable this page, please fork RosettaGit's repository and open a merge request on GitHub.

;Background: This "longest string challenge" is inspired by a problem that used to be given to students learning Icon. Students were expected to try to solve the problem in Icon and another language with which the student was already familiar. The basic problem is quite simple; the challenge and fun part came through the introduction of restrictions. Experience has shown that the original restrictions required some adjustment to bring out the intent of the challenge and make it suitable for Rosetta Code.

;Basic problem statement Write a program that reads lines from standard input and, upon end of file, writes the longest line to standard output. If there are ties for the longest line, the program writes out all the lines that tie. If there is no input, the program should produce no output.

;Task Implement a solution to the basic problem that adheres to the spirit of the restrictions (see below).

Describe how you circumvented or got around these 'restrictions' and met the 'spirit' of the challenge. Your supporting description may need to describe any challenges to interpreting the restrictions and how you made this interpretation. You should state any assumptions, warnings, or other relevant points. The central idea here is to make the task a bit more interesting by thinking outside of the box and perhaps by showing off the capabilities of your language in a creative way. Because there is potential for considerable variation between solutions, the description is key to helping others see what you've done.

This task is likely to encourage a variety of different types of solutions. They should be substantially different approaches.

Given the input:

```
a
bb
ccc
ddd
ee
f
ggg

```

the output should be (possibly rearranged):

```
ccc
ddd
ggg

```

;Original list of restrictions

# Do not re-read the input file. Avoid using files as a replacement for lists (this restriction became apparent in the discussion).

;Intent of restrictions: Because of the variety of languages on Rosetta Code and the wide variety of concepts used in them, there needs to be a bit of clarification and guidance here to get to the spirit of the challenge and the intent of the restrictions.

The basic problem can be solved very conventionally, but that's boring and pedestrian. The original intent here wasn't to unduly frustrate people with interpreting the restrictions, it was to get people to think outside of their particular box and have a bit of fun doing it.

The guiding principle here should be to be creative in demonstrating some of the capabilities of the programming language being used. If you need to bend the restrictions a bit, explain why and try to follow the intent. If you think you've implemented a 'cheat', call out the fragment yourself and ask readers if they can spot why. If you absolutely can't get around one of the restrictions, explain why in your description.

Now having said that, the restrictions require some elaboration.

• In general, the restrictions are meant to avoid the explicit use of these features.
• "No comparison operators may be used" - At some level there must be some test that allows the solution to get at the length and determine if one string is longer. Comparison operators, in particular any less/greater comparison should be avoided. Representing the length of any string as a number should also be avoided. Various approaches allow for detecting the end of a string. Some of these involve implicitly using equal/not-equal; however, explicitly using equal/not-equal should be acceptable.
• "No arithmetic operations" - Again, at some level something may have to advance through the string. Often there are ways a language can do this implicitly advance a cursor or pointer without explicitly using a +, - , ++, --, add, subtract, etc.
• The datatype restrictions are amongst the most difficult to reinterpret. In the language of the original challenge strings are atomic datatypes and structured datatypes like lists are quite distinct and have many different operations that apply to them. This becomes a bit fuzzier with languages with a different programming paradigm. The intent would be to avoid using an easy structure to accumulate the longest strings and spit them out. There will be some natural reinterpretation here.

To make this a bit more concrete, here are a couple of specific examples: In C, a string is an array of chars, so using a couple of arrays as strings is in the spirit while using a second array in a non-string like fashion would violate the intent. In APL or J, arrays are the core of the language so ruling them out is unfair. Meeting the spirit will come down to how they are used.

Please keep in mind these are just examples and you may hit new territory finding a solution. There will be other cases like these. Explain your reasoning. You may want to open a discussion on the talk page as well.

• The added "No rereading" restriction is for practical reasons, re-reading stdin should be broken. I haven't outright banned the use of other files but I've discouraged them as it is basically another form of a list. Somewhere there may be a language that just sings when doing file manipulation and where that makes sense; however, for most there should be a way to accomplish without resorting to an externality.

At the end of the day for the implementer this should be a bit of fun. As an implementer you represent the expertise in your language, the reader may have no knowledge of your language. For the reader it should give them insight into how people think outside the box in other languages. Comments, especially for non-obvious (to the reader) bits will be extremely helpful. While the implementations may be a bit artificial in the context of this task, the general techniques may be useful elsewhere.

This first solution is prepended to the following earlier solutions that did not fully comply with the restrictions, namely the use of arithmatic operators and language features that return numbers used with them.

In order to comply with the avoidance of greater-than or less-than comparisons and iterations with operators, only Constraint_Error exception handling is used to obtain comparison of less-than, equal-to, or greater-than. With these, only the strings that are longer than previous strings and the succeeding strings, and equal in length to each other are printed. They are printed in reverse order, but this is specifically allowed by the instructions. In order to be clear to the reader, all cases of less-than, equal to, and greater-than are manually iterated through. Since equal-to/not-equal-to testing is allowed, there should be no question that a "case" statement is also allowed.

```with Ada.Text_IO;

procedure Longest_Strings is

-- first, in order to strictly use integer, I use integer in
-- place of an enumeration type: -1 => not-equal
--                                0 => shorter - ignore, no print current string
--                                1 => equal - print current and up-stream
--                                2 => longer - no print upstream, only current and equal subsequent
--                           others => null; -- must never happen.
--
-- Anything else that is tested or used that is not a string or integer
-- is not used explicitly by me, but is a standard part of the language
-- as provided in the standard libraries (like boolean "End_Of_File").

function Measure_And_Print_N (O : String := ""; -- original/old string
N : String := ""  -- next/new string
) return Integer is
T1 : String := O;
T2 : String := N;
L  : Integer := 1; -- Length defaults to the same;
function Test_Length (O : in out String; -- original/old string
N : in out String) -- new/test-subject string
return Integer is
function Test_Equal (O : in out String; N : in out String)
return Integer is
begin
O := N;
return 1;
exception
when Constraint_Error =>
return -1;
end;
begin
case Test_Equal (O, N) is
when -1 =>
O (N'Range) := N;
return 0;
when 1 =>
return 1;
when others =>
return -1;
end case;
exception
when Constraint_Error =>
return 2;
end;
begin
case Test_Length (T1, T2) is
when 0 =>

-- N < O, so return "shorter"  do not print N

if End_Of_File
then
return 0;
else
case Measure_And_Print_N (O, Get_Line) is
when 0 =>
return 0;
when 1 =>
return 0;
when 2 =>
return 2; -- carry up any subsequent canceling of print.
when others =>
raise Numeric_Error;
end case;
end if;
when 1 =>

-- O = N, so return "equal"  print N if all subsequent values are
-- less than or equal to N

if End_Of_File
then
Put_Line (N);
return 1;
else
case Measure_And_Print_N (O, Get_Line) is
when 0 =>
Put_Line (N);
return 1;
when 1 =>
Put_Line (N);
return 1;
when 2 =>  -- carry up the subsequent canceling of print.
null;
return 2;
when others =>
raise Numeric_Error;
end case;
end if;
when 2 =>

-- N > O, so return "longer" to cancel printing all previous values
-- and print N if it is also equal to or greater than descendant
-- values.

if End_Of_File
then
Put_Line (N);
return 2;
else
case Measure_And_Print_N (N, Get_Line) is
when 0 =>
Put_Line (N);
return 2;
when 1 =>
Put_Line (N);
return 2;
when 2 =>  -- printing N cancelled by subsequent input.
null;
return 2;
when others =>
raise Numeric_Error;
end case;
end if;
when others =>

-- This should never happen - raise exception

raise Numeric_Error;
end case;
end;
begin
if End_Of_File
then
null;
else
case Measure_And_Print_N ("", Get_Line) is
when 0 =>
Put_Line (Current_Error,
"Error, Somehow the input line is calculated as less than zero!");
when 1 =>
Put_Line (Current_Error,
"All input lines appear to be blank.");
when 2 =>
null;
when others =>
raise Numeric_Error;
end case;
end if;
end;

```

The output, given the above example input, is:

```ggg
ddd
ccc
```

Keeping the input in order means either appending to a long string with varying segments and a separater character, like below, or possible using a list feature that has been specifically disallowed.

Next follows previous attempts:

How to bypass the restrictions:

• All lines of potential output are stored in an (unbounded) string, named Buffer. On special character (Latin_1.Nul) is used to separate between different lines.

• We can't directly compare the lengths of two strings. So instead, we assign the difference of the lengths to a variable of type Natural (). If the result is outside of Natural, this raises an exception. If there is no exception, we assign the result to a variable of type Positive (), which raises an exception if the result is outside of Positive.

(*) Technically, Natural and Positive are not types but subtypes of Integer: Natural ranges from 0 to Integer'Last, Positive from 1 to Integer'Last.

So this is the first solution.

```with Ada.Strings.Unbounded; use Ada.Strings.Unbounded;

procedure Longest_String_Challenge is
function "+"(S: String) return Unbounded_String renames To_Unbounded_String;

procedure Funny_Stuff(B, L: in out Unbounded_String; N: Unbounded_String) is
-- B holds a list of all longest strings, separated by Separator
-- L holds longest string so far
-- N is the next string to be considered
Nat: Natural;
begin
Nat := Length(N) - Length(L);
-- (1) this raises exception if L longer then N
declare
Pos: Positive;
begin
Pos := Nat; -- (2) this raises exception if L at least as long as N
-- at this point, we know N is longer then L
B   := N;
L   := N;
exception
when Constraint_Error -- come from (2)
-- at this point, we know L and N are of the same length
=> B := B & Separator & N; -- add N to the set of solutions
end;
exception
when Constraint_Error => null; -- come from (1)
-- at this point, we know L is longer then N
end Funny_Stuff;

Buffer: Unbounded_String := +"";
Longest: Unbounded_String := +"";
Next: Unbounded_String;

begin
while True loop
-- (3) raises exception when trying to read beyond the end of file
Funny_Stuff(Buffer, Longest, Next);
end loop;
exception
when others => -- come from (3)
for I in To_String(Buffer)'Range loop
if To_String(Buffer)(I) = Separator then
else
end if;
end loop;
end Longest_String_Challenge;
```

Output, when run with its own source code as the input:

```   function "+"(S: String) return Unbounded_String renames To_Unbounded_String;
procedure Funny_Stuff(B, L: in out Unbounded_String; N: Unbounded_String) is
```

Here is the second solution. It also makes heavy use of exceptions, but it does not require to compute the difference (which is an arithmetic operation, i.e., a bit of a cheat). Instead, the procedure Funny_Stuff carries some auxiliary strings S, T. If they are unequal and neither is empty, it recursively calls itself with the same strings shortened by 1. At some point of time, either S is empty, or T is empty, or both are empty.

```with Ada.Strings.Unbounded; use Ada.Strings.Unbounded;

procedure Longest_String_Challenge is
function "+"(S: String) return Unbounded_String renames To_Unbounded_String;
function "-"(U: Unbounded_String) return String renames To_String;

procedure Funny_Stuff(B, L: in out Unbounded_String;
N: Unbounded_String;
S, T: String) is
C: Character;
begin
C:= T(T'First); -- (1) raises Constraint_Error if T is empty
begin
C := S(S'First); -- (2) raises Constraint_Error if S is empty
-- at this point, we know that neither S nor T are empty
Funny_Stuff(B,L,N,S(S'First+1 .. S'Last), T(T'First+1..T'Last));
exception
when Constraint_Error => -- come from (2), S is empty, T is not empty!
B   := N;
L   := N;
end;
exception
when Constraint_Error => -- come from (1), T is empty
begin
C := S(S'First); -- (3) raises Constraint_Error if S is empty
-- at this point, we know that T is empty and S isn't
null;
exception
when Constraint_Error => -- come from (3); both S and T are empty
B := B & Separator & N;
end;
end Funny_Stuff;

Buffer: Unbounded_String := +"";
Longest: Unbounded_String := +"";
Next: Unbounded_String;

begin
while True loop
-- (4) raises exception when trying to read beyond end of file
Funny_Stuff(Buffer, Longest, Next, -Longest, -Next);
end loop;
exception
when others => -- come from (4)
for I in To_String(Buffer)'Range loop
if To_String(Buffer)(I) = Separator then
else
end if;
end loop;
end Longest_String_Challenge;
```

The output, when given its own source code as the input:

```   function "+"(S: String) return Unbounded_String renames To_Unbounded_String;
when Constraint_Error => -- come from (2), S is empty, T is not empty!
```

## ALGOL 68

Empty loops are used for comparison for equality; STRING slicing is used to implement subtraction; slicing and concatenation implements addition.

The STRING 'buffer' holds all the input strings and separating newline characters. A dummy zero-length string is tacked on the end so that the final loop terminates cleanly. The start of the STRING 'mask' is filled in with "1" characters at the position of the terminal character in each input string, overwriting any "0" that may have been there. A final scan of 'mask' identifies the maximum string length seen on the input.

The 'char in string' function, here used to slice up the buffer into the original inputs, is an Algol 68 Genie extension. The 'Pedantry' comment draws attention to the explicit voiding of the function result; not strictly necessary but it avoids a complaint if the --pedantic option is given to a68g.

Warts are that all input strings must be shorter than (bound -1) characters and it is assumed that ABS "1" > ABS "0"; this true for every known implementation of Algol 68.

```
BEGIN
INT bound = 1000000;			 CO Arbitrary upper limit on string lengths CO
INT max;				 CO Length of longest string CO
INT len;				 CO Length of string under examination CO
STRING buffer := "";			 CO All characters read from stand in CO
STRING mask := bound * "0";		 CO High water mark of string length seen so far CO
CO Standard boiler plate CO
on file end (stand in, (REF FILE f) BOOL: (close (f); GOTO finished));
DO
STRING line;
buffer PLUSAB line + REPR 10;	CO Concatenate string and newline CO
mask[UPB line] := "1"		CO And set mask where character exists in line CO
OD;
finished:
buffer PLUSAB REPR 10;		CO Guarantee there's a zero-length string at the end CO
CO
Scan backwards through mask looking for highest index used which is equal to the length
of the longest string with its terminating newline.
CO
FOR i FROM bound BY -1 TO 1
DO
FROM ABS mask[i] TO ABS "0" DO max := i OD	CO Exploit ABS "1" > ABS "0" CO
OD;
FROM 1 TO UPB buffer
DO							CO Null loop if buffer is empty CO
VOID (char in string (REPR 10, len, buffer));	CO Pedantry and Algol68 Genie extension CO
FROM max TO len
DO						CO Null loop if len < max CO
FOR i FROM 1 TO max
DO
printf ((\$a\$, buffer[i]))			CO Print string and newline CO
OD
OD;
buffer := buffer[len : UPB buffer];		CO Step over string CO
buffer := buffer[2 : UPB buffer]			CO Step over newline CO
OD
END
```

{{out}}

```printf "a\nbb\nccc\nddd\nee\nf\nggg\n" | a68g Longest_String.a68
ccc
ddd
ggg

```

Alternative recursive solution - the only standard operators used are string concatenation and array upper bound and SIGN (the signum function). Operators ATLEASTASLONGAS and LONGERTHAN are defined without the use of any comparison or arithmetic operators. The input file is processed recursively so this would run out of stack space for a large input file. Exploits some features of Algol 68 STRING slicing.

```# The standard SIGN operator returns -1 if its operand is < 0 #
#                                  ,  0 if its operand is   0 #
#                                  ,  1 if its operand is > 0 #
# This array maps he results of SIGN to FALSE or TRUE for the #
# ATLEASTASLONGAS operator defined below                      #
[ -1 : 1 ]BOOL not shorter;
not shorter[ -1 ] := FALSE;
not shorter[  0 ] := FALSE;
not shorter[  1 ] := TRUE;

# Set the priorities for the dyadic operators defined below   #
# 9 is the highest priority, so a LOMGERTHAN b AND ...        #
# is parsed correctly                                         #
PRIO ATLEASTASLONGAS = 9
, LONGERTHAN      = 9
;

OP   NONEMPTYSTRING  = ( STRING a )STRING: " " + a[ AT 1 ];

# STRING x is at least as long as STRING y if the substring   #
# of x from the upper bound of y to the end of x is at least  #
# one character long                                          #
# Note that Algol 68 doesn't raise an error if the substring  #
# start position is after the upper bound of the string, but  #
# does object if the start position is before the lower bound #
# - hence the need for the NONEMPTYSTRING operator to ensure  #
#   we don't try executing a[ 0 : ] when b is ""              #
OP   ATLEASTASLONGAS = ( STRING x, STRING y )BOOL:
BEGIN
STRING a = NONEMPTYSTRING x;
STRING b = NONEMPTYSTRING y;
END # ATLEASTASLONGAS # ;

# x is longer than y if x is at least as long as y and        #
# y is not at least as long as x                              #
OP   LONGERTHAN      = ( STRING x, STRING y )BOOL: x ATLEASTASLONGAS y AND NOT ( y ATLEASTASLONGAS x );
# additional LONGERTHAN operators to handle single chatracter #
# STRINGs which are actually CHAR values in Algol 68          #
# Not needed for the task, but useful for testing LONGERTHAN  #
OP   LONGERTHAN      = ( CHAR   x, CHAR   y )BOOL: FALSE;
OP   LONGERTHAN      = ( CHAR   x, STRING y )BOOL: STRING( x ) LONGERTHAN y;
OP   LONGERTHAN      = ( STRING x, CHAR   y )BOOL: x LONGERTHAN STRING( y );

COMMENT # basic test of LONGERTHAN: # C-MMENT
print( ( "abc" LONGERTHAN "bbcd", "ABC" LONGERTHAN "", "" LONGERTHAN "abc", "DEF" LONGERTHAN "DEF", "abcd" LONGERTHAN "a", newline ) );
C-MMENT COMMENT

PROC read line = ( REF FILE f )STRING:
BEGIN
STRING line;
get( f, ( line, newline ) );
IF at eof THEN "" ELSE line FI
END # read line # ;

# EOF handler for standard input                              #
BOOL at eof := FALSE;
on logical file end( stand in, ( REF FILE f )BOOL:
BEGIN
at eof := TRUE;
TRUE
END
);

# recursively find the longest line(s) in the specified file  #
# and print them                                              #
PROC print longest lines = ( REF FILE f, STRING longest so far )STRING:
BEGIN
IF at eof THEN
longest so far
ELSE
STRING s = read line( f );
STRING t = IF s LONGERTHAN longest so far
THEN
print longest lines( f, s )
ELSE
print longest lines( f, longest so far )
FI;
IF s ATLEASTASLONGAS t AND t ATLEASTASLONGAS s
THEN
# this line is as long as the longest          #
print( ( s, newline ) );
s
ELSE
# shorter line - return the longest            #
t
FI
FI
END # print longest lines # ;

# find the logest lines from standard inoout                   #
VOID( print longest lines( stand in, read line( stand in ) ) )

```

## AutoHotkey

This was fun to implement. How I bypassed the restrictions: SubStr() returns part of a string starting from somewhere. If it goes past the end of a string, it returns "" which can be treated as false. StrLen() returns the length of a string. Thus: If this line contains a character at position "longestLength" then append it to the output. If the top line of the output does not contain a character at the position of the last character in this line of the input, then reset the output to be this line and set "LongestLength" to be the length of this line. did I break any rules?

```input =
(
a
bb
ccc
ddd
ee
f
ggg
)
longestLen := 0, buffer := ""
Loop Parse, input, `n
{
top := SubStr(buffer, 1, InStr(buffer, "`n"))
StringReplace, top, top, `n
If SubStr(A_LoopField, LongestLen) ; at least as long
buffer .= A_LoopField "`n"
If !SubStr(top, StrLen(A_LoopField)) ; longer
buffer := A_LoopField "`n", LongestLen := StrLen(A_LoopField)
}
MsgBox % buffer
```

## AWK

```#!/usr/bin/awk -f
BEGIN {
maxlen = 0;
lenList = 0;
}

{
if (length(\$0)>maxlen) {
lenList = 1;
List[lenList] = \$0;
maxlen = length(\$0);
} else if (length(\$0)==maxlen)
List[++lenList]=\$0;
}

END {
for (k=1; k <= lenList; k++) print List[k];
}
```

Output:

```ccc
ddd
ggg
```

## BBC BASIC

Key to this solution are the functions '''FNcmp''', which compares the lengths of two strings without using comparison operators, and '''FNinc''', which increments an integer without using arithmetic operators. It also strictly adheres to the requirement to use only integer and string data types (no arrays or pointers) and avoids the use of LEN.

```      DIM buffer% 65535
bufptr% = buffer%
longest\$ = " "

ON ERROR PRINT \$\$buffer%; : END

REPEAT
IF FNcmp(A\$, longest\$) THEN
IF FNcmp(longest\$, A\$) ELSE bufptr% = buffer%
longest\$ = A\$
\$bufptr% = A\$
WHILE ?bufptr%
bufptr% = FNinc(bufptr%)
ENDWHILE
?bufptr% = 10
bufptr% = FNinc(bufptr%)
ENDIF
UNTIL FALSE : REM Loops until 'Out of data' error
END

DATA a, bb, ccc, ddd, ee, f, ggg

DEF FNcmp(a\$, b\$) : REM Returns LEN(a\$)>=LEN(b\$) [if b\$<>""]
LEFT\$(a\$, 65535) = b\$
= INSTR(a\$, b\$)

DEF FNinc(i%) : REM Returns i%+1
FOR i% = i% TO i% : NEXT
= i%
```

Output:

```
ccc
ddd
ggg

```

## C

```#include <stdio.h>
#include <string.h>

int cmp(const char *p, const char *q)
{
while (*p && *q) p = &p[1], q = &q[1];
return *p;
}

int main()
{
char line[65536];
char buf[1000000] = {0};
char *last = buf;
char *next = buf;

while (gets(line)) {
strcat(line, "\n");
if (cmp(last, line)) continue;
if (cmp(line, last)) next = buf;
last = next;
strcpy(next, line);
while (*next) next = &next[1];
}

printf("%s", buf);
return 0;
}
```

Running it:% printf "a\nbb\nccc\nddd\nee\nf\nggg" | ./a.out ccc ddd ggg

```
Note that the above code never checked for memory bounds and long input can overrun the buffers.  It's intentionally made this way to keep it simple, please don't complicate it by adding safety features: if you are really concerned with that, below is a second method that can handle arbitrary length input.
```c
#include <stdio.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>

int inc(int x) { return (int)&((char *)x)[1]; }
int dec(int x) { return (int)&((char *)x)[-1]; }
int gt(int x, int y)
{
while (y && x) y = dec(y), x = dec(x);
return x;
}

int eq(int x, int y)
{
return !gt(x, y) && !gt(y, x);
}

{
while(y) x = inc(x), y = dec(y);
return x;
}

/* strlen(a) + 1 */
int length(const char *a)
{
char *x = 0; // assuming (int)(char*)0 == 0
if (!a) return 0;
while (*a) a++, x++;
return (int)x;
}

char *str_cat(char *a, const char *b)
{
if (!(a = realloc(a, len))) abort();
return strcat(a, b);
}

char *get_line(char *l, FILE *fp)
{
int c, len = 0;
char tmp[2] = {0};

*l = 0;
while ((c = fgetc(fp)) != EOF) {
*tmp = c;
len = inc(len);

l = str_cat(l, tmp);
if (eq(*tmp, '\n')) return l;
}

*tmp = '\n';
return len ? str_cat(l, tmp) : l;
}

int main()
{
int l1, l2;
char *line = malloc(1), *buf = malloc(1), *longest = malloc(1);
while (1) {
line = get_line(line, stdin);

if (!(l1 = length(line))) break;
l2 = length(longest);

if (gt(l1, l2)) {
*buf = *longest = 0;
longest = str_cat(longest, line);
} else if (gt(l2, l1)) continue;

buf = str_cat(buf, line);
}
printf("%s", buf);

free(buf);
free(longest);
free(line);

return 0;
}
```

Here is a more concise variation which exits (with a non-zero return code) if it encounters a buffer overflow:

```#include <stdio.h>
#include <stdlib.h>
#include <string.h>

int longer(const char *p, const char *q) {
while (*p && *q) p = &p[1], q = &q[1];
return *p;
}

int main() {
char line[100000];
char buf[1100001];
char *linend= &line[99999];
char *bufend= &buf[1000000];
char *last = buf;
char *next = buf;

memset(line, 1, 100000);
memset(buf, 1, 1100001);
buf[0]= buf[1100000]= 0;
while (fgets(line, 100000, stdin)) {
if (!*linend) exit(1);
if (longer(last, line)) continue;
if (!longer(bufend, line)) exit(1);
if (longer(line, last)) next = buf;
last = next;
strcpy(next, line);
while (*next) next = &next[1];
}

printf("%s", buf);
exit(0);
}
```

## Clojure

{{trans|Python}}

```ns longest-string
(:gen-class))

(defn longer [a b]
" if a is longer, it returns the characters in a after length b characters have been removed
otherwise it returns nil "
(if (or (empty? a) (empty? b))
(not-empty a)
(recur (rest a) (rest b))))

(defn get-input []
" Gets the data from standard input as a lazy-sequence of lines (i.e. reads lines as needed by caller
Input is terminated by a zero length line (i.e. line with just <CR> "
(if (> (count line) 0)
(lazy-seq (cons line (get-input)))
nil)))

(defn process []
" Returns list of longest lines "
(first                                                             ; takes lines from [lines longest]
(reduce (fn [[lines longest] x]
(cond
(longer x longest) [x x]                               ; new longer line
(not (longer longest x)) [(str lines "\n" x) longest] ; append x to previous longest
:else [lines longest]))                               ; keep previous lines & longest
["" ""] (get-input))))

(println "Input text:")
(println "Output:\n" (process))

```

{{out}}

```
Input text:
a
bb
ccc
ddd
ee
f
ggg

Output:
ccc
ddd
ggg
```

## D

{{trans|Python}}

```import std.stdio, std.array;

/// Return a.length - b.length if positive, 0 otherwise.
int longer(string a, string b) {
while (!a.empty && !b.empty)
a.popFront(), b.popFront();
return a.length;
}

void main() {
string longest, lines;
foreach (string line; stdin.lines())
if (longer(line, longest))
lines = longest = line;
else if (!longer(longest, line))
lines ~= line;

writeln(lines);
}
```

{{out}}

```ccc
ddd
ggg
```

## Go

```package main

import (
"bufio"
"os"
)

func main() {
var blankLine = "\n"
var printLongest func(string) string
printLongest = func(candidate string) (longest string) {
longest = candidate
defer func() {
recover()
defer func() {
recover()
}()
_ = blankLine[0]
func() {
defer func() {
recover()
}()
_ = s[len(longest)]
longest = s
}()
longest = printLongest(longest)
func() {
defer func() {
recover()
os.Stdout.WriteString(s)
}()
_ = longest[len(s)]
s = ""
}()
}()
_ = err.(error)
os.Stdout.WriteString(blankLine)
blankLine = ""
return
}
printLongest("")
}
```

Description: It's basically the recursion+exceptions solution used by others, but staying close to the restrictions.

Restriction 1. The program actually has no operators at all, much less comparison operators. By the Go language specification, assignment is a statement, for example, and an index into a string is simply an "index." For this program, comparisons that control program flow are ones that happen during expression evaluation and then either do or do not trigger a run-time panic, the rough equivalent of throwing an exception in other languages.

Restriction 2. No arithmetic is done on numeric types, and in fact there are no variables of any numeric type in the program. While numeric values do appear at points during expression evaluation (the len function, for example) no arithmetic is explicitly done with them. The compiler certainly generates arithmetic instructions for address calculations underlying an index expression, for example; but the source code here simply supplies numbers as indexes, and relies on the compiler to figure out what arithmetic is appropriate.

Restriction 3. Other than integer and string, data types used are:

• Function: Main is a function, and there is extensive use of function literals in the program.
• os.File: os.Stdin and os.Stdout are predefined in package os.
• bufio.Reader: Used to wrap os.Stdin so the convenient ReadString function can be used to get individual input strings.
• error: A predefined type in Go, returned by many library functions (such as bufio.ReadString.)
• byte: While there are no variables of type byte in the program, single byte values appear at various points in expression evaluation. A byte is the result of indexing into a string, for example.

The spirit of the challenge seems to be prohibiting easy ways of doing things until the only ways left are considered novel. I don't consider recursion a particularly novel way of implementing a list, but it's obviously allowed as a solution so I used it. Avoiding arithmetic was fairly easy using the fact that the Go len function returns the length of a string, but that strings are zero based. Thus,

```
if a[len(b)] panics, it means that len(a) <= len(b)
if a[len(b)] does not panic, it means that len(a) > len(b)

```

The above expressions avoid arithmetic, but not all comparisons, because error values are typically tested and branched on. Eliminating all comparisons leaves no boolean values in the program and no way to use if statements, which in Go require a boolean condition. Conditional flow control is implemented with the following device:

```func() {
// 1. statements executed in either case
// 2. func below is a closure that captures free variables
//    now, although the defer statement keeps the function
//    from running until later
defer func() {
// 5.  function runs either when panic happens, or
//     at the time of a normal function return.
recover()  // this stops panic mode
// 6.  statements executed in either case, just
//     before function returns
}()
// 3. more statements executed in either case
// 4. an expression that may or may not panic
// 4a.  conditional code. executed only if no panic happens
return // 7. function return happens in either case
}()
```

A complication of course is that sometimes you want to conditionally execute code if the expression panics. Without a boolean value to invert, this case requires introducing an extra layer of func..defer..recover with a different expression contrived that will panic with the opposite effect.

## Groovy

Solution: recursive

```def longer = { a, b ->
def aa = a, bb = b
while (bb && aa) {
bb = bb.substring(1)
aa = aa.substring(1)
}
aa ? a : b
}

def longestStrings
longestStrings = { BufferedReader source, String longest = '' ->
def finalLongest = current == null \
? longest \
: longestStrings(source,longer(current,longest))
if (longer(finalLongest, current) == current) {
println current
}
return finalLongest
}
```

Test:

```def source = new BufferedReader(new StringReader('''a
bb
ccc
ddd
ee
f
ggg'''))

longestStrings(source)
```

Output:

```ggg
ddd
ccc
```

Even though lists of strings were disallowed in the rules, I have used them instead of a file handle, mainly to keep my functions pure, and to avoid the hassle of using the IO monad for something more trivial without it.

Another use of lists in the code is for Strings, which are lists of Chars in Haskell by default, which made it easy to compare them by length.

No operators were used except for string/list concatenation.

```
module Main where

import           System.Environment

cmp :: String -> String -> Ordering
cmp [] []         = EQ
cmp [] (_:_)      = LT
cmp (_:_) []      = GT
cmp (_:xs) (_:ys) = cmp xs ys

longest :: String -> String
longest = longest' "" "" . lines
where
longest' acc l []         = acc
longest' [] l (x:xs)      = longest' x x xs
longest' acc l (x:xs) = case cmp l x of
LT -> longest' x x xs
EQ -> longest' (acc ++ '\n':x) l xs
GT -> longest' acc l xs

main :: IO ()
main = do
(file:_) <- getArgs
putStrLn \$ longest contents

```

### String Scanning / Pattern Matching Solution

```procedure main(arglist)
local b  # the current buffer (string)
local l  # the last string
local L  # a \n delimited accumulation of all the longest strings

while b := read() do {
/l := b      # primes l on first pass
b ? ( move(*l), if move(1) then L := (l := b) || "\n" else if move(0) then L := (\L|"") || b || "\n")
#       move(*l) - fails if b is not l characters long
#       move(1)  - succeeds/fails if the string is longer and triggers a reset of L
}

write(\L)
end
```

Sample Output:

```ccc
ddd
ggg

```

### Recursive Solution

Here is a recursive solution using only single character substring-ing (no string scanning/pattern matching).

```procedure main()
longest(".")   # needs a single character seed to throw away
end

procedure longest(Longest)
Line := read() | return Longest        # read until we can return the longest strings
if Line[*Longest] then Longest := Line # prime/reset Longest
Longest := longest(Longest)            # use stack to hold multiples
if Line[*Longest] then write(Line)     # write only longest strings,
# Line must be at least as long as Longest
return Longest                         # feed back longest for length
end
```

Sample Output:

```ggg
ddd
ccc
```

## J

```   isempty =. (0 [ 0&{) :: 1:  NB. 0=#
compare =. (\$:&}.)`((0 1,:_1 0) {~ <@,&isempty)@.(+.&isempty) NB. *@-&#
add =. ,`(,:@[)`] @. (compare {:)
> add&.>/ (}: , ,:&.>@{:) ;: 'a bb ccc ddd ee f ggg'
ccc
ddd
ggg
```

Description:

isempty fetches the first element from an array, and traps the error. The result is false (0) if there was a first element, true (1) otherwise.

compare uses isempty recursively (dropping an element from the array each time) until one (or both) are empty. Once one of the lists is empty a result the pair of numbers from isempty on the two lists is used to pull a value out of an table - the sign of this value indicates which of the two lists was greater. In other words, you get a result of _1 0 or 1, depending on whether one is larger, or neither is larger or the other is larger.

add uses the result from compare to pick from a list of functions which do the right thing when combining lists (add to the current list of results or replace it).

The final expression sets things up for add to function properly and then extracts the result when add is done. (You might think of this as being somewhat like a Haskell monad - though perhaps that analogy should be avoided since a J monad is something very different. J's use of the word "monad" came about decades ago and is related to the use of the word in music theory.)

## Java

Translation of Python via D

```import java.io.File;
import java.util.Scanner;

public class LongestStringChallenge {

public static void main(String[] args) throws Exception {
String lines = "", longest = "";
try (Scanner sc = new Scanner(new File("lines.txt"))) {
while(sc.hasNext()) {
String line = sc.nextLine();
if (longer(longest, line))
lines = longest = line;
else if (!longer(line, longest))
lines = lines.concat("\n").concat(line);
}
}
System.out.println(lines);
}

static boolean longer(String a, String b) {
try {
String dummy = a.substring(b.length());
} catch (StringIndexOutOfBoundsException e) {
return true;
}
return false;
}
}
```
```ccc
ddd
ggg
```

## Julia

{{works with|Julia|0.6}}

```function longer(a, b)
try
b[endof(a)]
catch
return true
end
return false
end

function printlongest(io::IO)
lines = longest = ""
while !eof(io)
if longer(line, longest)
longest = lines = line
elseif !longer(longest, line)
lines *= "\n" * line
end
end
println(lines)
end
printlongest(str::String) = printlongest(IOBuffer(str))

printlongest("a\nbb\nccc\nddd\nee\nf\nggg")
```

{{out}}

```ccc
ddd
ggg
```

## Kotlin

{{trans|Java}}

```// version 1.1.0

import java.io.File
import java.util.*

fun longer(a: String, b: String): Boolean =
try {
a.substring(b.length)
false
}
catch (e: StringIndexOutOfBoundsException) {
true
}

fun main(args: Array<String>) {
var lines = ""
var longest = ""
val sc = Scanner(File("lines.txt"))
while(sc.hasNext()) {
val line = sc.nextLine()
if (longer(longest, line)) {
longest = line
lines = longest
}
else if (!longer(line, longest))
lines = lines.plus("\n").plus(line) // using 'plus' to avoid using '+'
}
sc.close()
println(lines);
println()

// alternatively (but cheating as library functions will use comparisons and lists under the hood)
println(File("lines.txt").readLines().groupBy { it.length }.maxBy { it.key }!!.value.joinToString("\n"))
}
```

{{out}}

```
ccc
ddd
ggg

ccc
ddd
ggg

```

## Lua

```function longer(s1, s2)
while true do
s1 = s1:sub(1, -2)
s2 = s2:sub(1, -2)
if s1:find('^\$') and not s2:find('^\$') then
return false
elseif s2:find('^\$') then
return true
end
end
end

local output = ''
local longest = ''

for line in io.lines() do
local islonger = longer(line, longest)
if islonger and longer(longest, line) then
output = output .. line .. '\n'
elseif islonger then
longest = line
output = line .. '\n'
end
end

print(output)
```

This solution is ispired by the Python one, but since in Lua even an empty string has a boolean true value, it had to be slightly altered. Testing whether a string is empty is done by searching for the Lua string ''pattern'' `'^\$'`. If it is found, i.e. the examined string is empty, `string.find` returns the position of the match, or `nil> if it didn't match. Since in Lua any number is true, we just test for the boolean value of the result.`

``` Note that the longer function returns true even if both strings have the same length, so the return value can either be true or false and we can avoid using a comparison or equality operator in interpreting this return value. The longer function also avoids using the length operator (#), because in the comments on the restrictions of this task it is stated that ''"Representing the length of any string as a number should also be avoided."''. Otherwise it could have been written shorter and faster like this: function longer(s1, s2) if s1:sub(#s2):find('^\$') then return false else return true end end Mathematica FixedPoint[ StringReplace[#, x : "\n" | StartOfString ~~ a : Except["\n"] ... ~~ "\n" ~~ b : Except["\n"] ... ~~ y : "\n" | EndOfString :> x <> Switch[((#1 + #2) + Abs[#1 - #2])/2 &[StringLength@a, StringLength@b], Except[StringLength@a], b, Except[StringLength@b], a, _, a <> "\n" <> b] <> y] &, "a bb ccc ddd ee f ggg"] {{Out}} ccc ddd ggg =={{header|MATLAB}} / {{header|Octave}}== function longestString(file); fid = fopen(file); maxlen = 0; L = {}; while ~feof(fid) line = fgetl(fid); if (length(line)>maxlen) maxlen = length(line); L = {line}; elseif (length(line)==maxlen) L{end+1} = line; end; end; fclose(fid); disp(L); end; Output: L = { [1,1] = ccc [1,2] = ddd [1,3] = ggg } OCaml Without the restrictions, the standard way to solve the task would be to iterate the lines, compare their length, and accumulate the longest lines in a list. Here we bypass the restriction of not using comparison operators (in the function cmp) by taking advantage that characters of strings are indexed from 0 to [length - 1] and trying to access to a character which index is the length of the other string (if it is beyond the end of the string an exception is raised). The other restriction of not using lists is easily bypassed by concatenating the results instead of accumulating it in a list. let input_line_opt ic = try Some (input_line ic) with End_of_file -> None let cmp s1 s2 = try ignore(s1.[String.length s2]); 1 (* s1 is longer *) with _ -> try ignore(s2.[String.length s1]); -1 (* s2 is longer *) with _ -> 0 (* both same length *) let () = let ic = open_in Sys.argv.(1) in let rec loop longest acc = match input_line_opt ic with | Some line -> ( match cmp line longest with | 1 -> loop line (line ^ "\n") | 0 -> loop line (acc ^ line ^ "\n") | _ -> loop longest acc ) | None -> close_in ic; print_string acc in loop "" "" Pascal {{works with|Free_Pascal}} In this version, inc() is used instead of additions. It still has a comparison. program LongestStringChallenge_1(input, output); var Line: string; Lines: array of string; position, len: integer; begin if not eoln(input) then begin len := 1; position := 0; readln (line); setlength(lines, len); lines[position] := line; while not eoln(input) do begin readln (line); if length(line) = length(lines[0]) then begin inc(position); inc(len); setlength(lines, len); lines[position] := line; end; if length(line) > length(lines[0]) then begin position := 0; len := 1; setlength(lines, 1); lines[0] := line; end; end; for position := low(lines) to high(lines) do writeln (lines[position]); end; end. Output: % ./LongestStringChallenge_1 a b ccc ddd ee f ggg ccc ddd ggg {{works with|Free_Pascal}} {{libheader|SysUtils}} This version uses range check exceptions for the comparisons of string lengths. The range checks are compiler specific. With FreePascal its requires the use of the type ANSIstring instead of "classic" type string. program LongestStringChallenge_2(input, output); {\$mode ObjFPC} {\$rangechecks on} uses SysUtils; var Line: ANSIstring; Lines: array of ANSIstring; position: integer; tester: char; begin if not eoln(input) then begin readln (line); position := 0; setlength(lines, 1); lines[0] := line; while not eoln(input) do begin readln (line); try tester := lines[0][length(line)]; try tester := line[length(lines[0])]; inc(position); setlength(lines, succ(position)); lines[position] := line; except end; except position := 0; setlength(lines, 1); lines[0] := line; end; end; for position := low(lines) to high(lines) do writeln (lines[position]); end; end. Output: % ./LongestStringChallenge_2 a b ccc ddd ee f ggg ccc ddd ggg Perl #!/usr/bin/perl -n END{ print \$all } substr(\$_, length(\$l)) and \$all = \$l = \$_ or substr(\$l, length) or \$all .= \$_; Perl 6 my \$l = ''; # Sample longest string seen. my \$a = ''; # Accumulator to save longest strings. while get() -> \$s { my \$n = "\$s\n"; if \$n.substr(\$l.chars) { # Is new string longer? \$a = \$l = \$n; # Reset accumulator. } elsif !\$l.substr(\$n.chars) { # Same length? \$a ~= \$n; # Accumulate it. } } print \$a; Given the example input, returns: ccc ddd ggg Phix A recursive/substring based approach, I can't see any explicit maths/comparisons anyway: integer fn = open(command_line()[2],"r") -- (reading the source file) function allx(string line) line[1..-1] = 'x' return line end function function longest(string mask) object line = gets(fn) string newmask if atom(line) then return mask end if newmask = allx(line) if not match(mask,newmask) then return longest(mask) end if mask = longest(newmask) if match(mask,newmask) then puts(1,line) end if return mask end function ?longest("x") close(fn) Of course it is just a thinly disguised version of: function longest(integer l) object line = gets(fn) if line=-1 then return l end if if l>length(line) then return longest(l) end if l = longest(length(line)) if l=length(line) then puts(1,line) end if return l end function ?longest(0) PicoLisp Not sure if this meets the spirit. I would implement it the same way if there were no "restrictions": (mapc prinl (maxi '((L) (length (car L))) (by length group (in NIL (make (until (eof) (link (line)))) ) ) ) ) Another solution avoids 'group', and builds an associative buffer of lines instead: (let Buf NIL (in NIL (until (eof) (let (Line (line) Len (length Line)) (if (assoc Len Buf) (conc @ (cons Line)) (push 'Buf (cons Len (cons Line))) ) ) ) ) (mapc prinl (cdr (maxi car Buf))) ) Pike things of note: the comparison of strings is done by converting the string into an array of indices: ("abc" becomes ({ 1,2,3 })) the - operation is the set operation $A/B$ and not a numerical subtraction. it removes all the elements in the second array from the first. if there are any left, we know that the string is longer. now, once a longer string is found we call write() to print it. however we don't write it out directly, but instead we store the call in queue of pikes backend. the backend is used to handle callbacks for non-blocking I/O, and it provides a facility to call functions after a delay of time. (call_out(write, 5, "foo"); calls write after 5 seconds with the argument foo) before we add the new call to write, we remove all older calls to write since we don't want them anymore. return -1; starts the backend, which allows pike to execute the remaining call_outs and exit. int main(int argc, array argv) { string longest = ""; foreach(Stdio.stdin.line_iterator();; string line) { if( sizeof(indices(line) - indices(longest))) { while(!zero_type(remove_call_out(write))); longest = line; call_out(write, 0, line+"\n"); } else if( !sizeof(indices(longest) - indices(line))) { call_out(write, 0, line+"\n"); } } call_out(exit, 0.01, 0); return -1; } PL/I read: procedure options (main); /* 18 January 2012. */ declare line character (100) varying controlled; declare text character (100) varying; declare max_length fixed binary; declare in file input; on endfile (in) go to done; open file (in) title ('/readline.pli,type(text),recsize(100)'); max_length = 0; do forever; get file (in) edit (text) (L); put skip list (text); if length (text) > max_length then do; max_length = length(text); /* empty the stack */ do while (allocation(line) > 0); free line; end; allocate line; line = text; end; else if length(text) = max_length then do; allocate line; line = text; end; end; done: put skip list (max_length || ' is the length of the longest line(s)' ); do while (allocation(line) > 0); put skip list (line); free line; end; end read; output (the above file plus the following 3 lines): 74 is the length of the longest line(s) put skip list (max_length || ' is the length of the longest line(s)' ); /* Read lines of a file, and print the longest. (If there is more than */ PowerShell {{works with|PowerShell|2}} # Get-Content strips out any type of line break and creates an array of strings # We'll join them back together and put a specific type of line break back in \$File = ( Get-Content C:\Test\File.txt ) -join "`n" \$LongestString = \$LongestStrings = '' # While the file string still still exists While ( \$File ) { # Set the String to the first string and File to any remaining strings \$String, \$File = \$File.Split( "`n", 2 ) # Strip off characters until one or both strings are zero length \$A = \$LongestString \$B = \$String While ( \$A -and \$B ) { \$A = \$A.Substring( 1 ) \$B = \$B.Substring( 1 ) } # If A is zero length... If ( -not \$A ) { # If \$B is not zero length (and therefore String is longer than LongestString)... If ( \$B ) { \$LongestString = \$String \$LongestStrings = \$String } # Else (\$B is also zero length, and therefore String is the same length as LongestString)... Else { \$LongestStrings = \$LongestStrings, \$String -join "`n" } } } # Output longest strings \$LongestStrings.Split( "`n" ) PowerShell Alternate Version The list restrictions should not apply here because this is essentially one line of code using only the input and no variables. @' a bb ccc ddd ee f ggg '@ -split "`r`n" | Group-Object -Property Length | Sort-Object -Property Name -Descending | Select-Object -Property Count, @{Name="Length"; Expression={[int]\$_.Name}}, Group -First 1 {{Out}} Count Length Group ----- ------ ----- 3 3 {ccc, ddd, ggg} PureBasic Procedure.i ConsoleWrite(t.s) ; compile using /CONSOLE option OpenConsole() PrintN (t.s) CloseConsole() ProcedureReturn 1 EndProcedure Procedure.i StdOut(t.s) ; compile using /CONSOLE option OpenConsole() Print(t.s) CloseConsole() ProcedureReturn 1 EndProcedure DataSection s: Data.s "a" Data.s "bb" Data.s "ccc" Data.s "ddd" Data.s "ee" Data.s "f" Data.s "ggg" Data.s "~" ; the tilda is only to keep the code compact e: ; and easy to understand EndDataSection l\$="" ; memory allocation for strings is automatic a\$="" ; in fact these two lines are unnecessary Restore s Repeat Read.s s\$ If s\$="~":Break:EndIf s\$+#CRLF\$ s=Len(s\$):l=Len(l\$) ; using s\$ allows the use of s as an integer type If s>l :l\$=s\$:a\$=l\$ ElseIf s=l :a\$+s\$ EndIf Forever StdOut(a\$) ;Output: ; Directory of C:\_sys\temp ; 07/14/2012 03:04 PM 4,608 LongestStringChallenge.exe ; 1 File(s) 4,608 bytes ; 0 Dir(s) 434,768,625,664 bytes free ; C:\_sys\temp>LongestStringChallenge.exe ; ccc ; ddd ; ggg Python import fileinput # This returns True if the second string has a value on the # same index as the last index of the first string. It runs # faster than trimming the strings because it runs len once # and is a single index lookup versus slicing both strings # one character at a time. def longer(a, b): try: b[len(a)-1] return False except: return True longest, lines = '', '' for x in fileinput.input(): if longer(x, longest): lines, longest = x, x elif not longer(longest, x): lines += x print(lines, end='') ;Sample runs: paddy@paddy-VirtualBox:~\$ cat <<! | python3.2 longlines.py a bb ccc ddd ee f ggg ! ccc ddd ggg paddy@paddy-VirtualBox:~\$ touch nothing.txt paddy@paddy-VirtualBox:~\$ cat nothing.txt | python3.2 longlines.py paddy@paddy-VirtualBox:~\$ Racket This is an attempt to follow the problem restrictions: use just one list of the complete output (so it's not used as a container of strings), and the work is done by manipulating this list vs the input instead of direct comparisons. #lang racket (define (newline? c) (equal? c #\newline)) (define eof? eof-object?) (let loop ([O '()] [C '(#\newline)] [rI '()] [rO '()] [rC '()]) (let* ([i (read-char)] [o (car C)] [i:rI (cons i rI)] [i:rC (cons i rC)]) (cond [(eof? i) (for-each write-char O)] [(and (newline? o) (newline? i)) (let ([O (reverse i:rC)]) (loop O O '() i:rC i:rC))] [(newline? i) (loop O O '() rO rO)] [(newline? o) (loop O C i:rI rO i:rI)] [else (loop O (cdr C) i:rI rO i:rC)]))) REXX In the REXX language, ''everything'' is a string (characters). read file until not ready This REXX version adheres to spirit (and letter) of all the restrictions for this task: ::* no comparators are used, including those within: ::::* '''if''' (statements) ::::* '''when''' (statements) ::::* '''until''' (clauses) and ::::* '''while''' (clauses) ::* no output is produced when the file is empty (or contains all null strings), ::* no arrays or lists are used, ::* no additions or subtractions are used, and ::* no variables are used to hold the length of (any) record. /*REXX program reads a file and displays the longest [widest] record(s) [line(s)]. */ signal on notReady /*when E-O-F is reached, jump/branch. */ iFID= 'LONGEST.TXT' /*the default file identifier for input*/ parse arg fid . /*obtain optional argument from the CL.*/ do #=1 to length(fid); iFID=fid /*Specified? Then use what's given. */ end /*#*/ != /*the maximum width (so far). */ do forever; _=linein(iFID); ?=_ /*read a line from the input file. */ t=0 /*don't do the initialization next time*/ do #=t for t; !=?; ?=; \$=. || _; end /*just do 1st time.*/ do #=length(!' ') to length(?) for 1; \$=; end /*found widest rec.*/ do #=length(!) to length(?) for 1; \$=\$'a0d'x || _; end /*append it to \$. */ /* [↑] variable # isn't really used.*/ !=left(., max( length(!), length(?) ) ) /*!: is the max length record, so far.*/ end /*forever*/ /* [↓] comes here when file gets E─O─F*/ notReady: do j=length(!) to length(!) for length(!) /*handle the case of no input*/ say substr(\$, 2) /*display (all) the longest records. */ end /*j*/ /*stick a fork in it, we're all done. */ {{out|input|text=file '''LONGEST.TXT''':}} a bb ccc ddd ee f ggg {{out|output|text= when using the default input:}} ccc ddd ggg ===Dual code (works on TSO and PC)=== /* REXX *************************************************************** * 27.10.2010 Walter Pachl **********************************************************************/ Parse Arg fid If fid='' Then Do "ALLOC FI(IN) DA('N561985.PRIV.V100(LL)') SHR REUSE" 'EXECIO * DISKR IN (STEM L. FINIS' /* read all lines */ 'FREE FI(IN)' End Else Do Do i=1 By 1 While lines(fid)>0 l.i=linein(fid) End l.0=i-1 End maxl = 0 /* initialize maximum length */ Do i=1 To l.0 /* loop through all lines */ linl=length(l.i) /* length of current line */ Select When linl>maxl Then Do /* line longer than preceding */ maxl=linl /* initialize maximum length */ mem.0=1 /* memory has one entry */ mem.1=l.i /* the current line */ lin.1=i /* its line number */ End When linl=maxl Then Do /* line as long as maximum */ z=mem.0+1 /* new memory index */ mem.z=l.i /* the current line */ lin.z=i /* its line number */ mem.0=z /* memory size */ End Otherwise /* line is shorter than max. */ Nop /* ignore */ End End If mem.0>0 Then Do Say 'Maximum line length='maxl Say ' Line Contents' Do i=1 To mem.0 Say right(lin.i,5) mem.i End End Else Say 'No lines in input file or file does not exist' Maximum line length=5 Line Contents 1 99999 3 +++++ Ring # Project : Longest string challenge load "stdlib.ring" test = ["a", "bb", "ccc", "ddd", "ee", "f", "ggg"] test1 = [] test2 = [] for n = 1 to len(test) add(test1, [test[n], len(test[n])]) next sortFirstSecond(test1, 2) for n = len(test1) to 2 step -1 if test1[n][2] = test1[n-1][2] add(test2, test1[n][1]) else add(test2, test1[n][1]) exit ok next test2 = sort(test2) see test2 + nl Output: ccc ddd ggg Ruby # Without restrictions BEGIN { v = [ ] m = 0 } n = \$_.length if n == m then v <<= \$_ elsif n > m then v = [\$_] m = n end END { v.each { |s| puts s } } Then ''ruby -n longest.rb < file.txt'' h = \$stdin.group_by(&:size) puts h.max.last unless h.empty? This uses a hash with arrays as values - but not explicit. Run BASIC Uses in memory database sqliteconnect #mem, ":memory:" ' Create in memory DB #mem execute("CREATE TABLE data(str)") ' And fields to hold the string data strings\$ = "a bb ccc ddd ee f ggg" ' The given string data while word\$(strings\$,i + 1," ") <> "" i = i + 1 #mem execute("INSERT INTO data VALUES('";word\$(strings\$,i," ");"')") ' insert the strings in to the DB wend #mem execute("SELECT length(str) as leng, str FROM data ORDER BY leng desc,str") ' pull data in reverse lenght sequence WHILE #mem hasanswer() #row = #mem #nextrow() leng = #row leng() str\$ = #row str\$() print leng;" ";str\$ ' print the data WEND Using a simple sort method strings\$ = "a bb ccc ddd ee f ggg" ' The given string data while word\$(strings\$,numWords + 1," ") <> "" ' Count the words numWords = numWords + 1 wend dim string\$(numWords) ' Dimension the string with the word cound for j = 1 to numWords string\$(j) = word\$(strings\$,j," ") ' put the words from the string into the string array next j h\$ = "1" while h\$ <> "" ' The good old simple bubble sort h\$ = "" for i = 1 to numWords -1 if len(string\$(i)) < len(string\$(i+1)) then ' sort by length descending h\$ = string\$(i) string\$(i) = string\$(i+1) string\$(i+1) = h\$ end if next i wend for i = 1 to numWords print len(string\$(i));" ";string\$(i) ' print out the words in length descending sequence next i 3 ccc 3 ddd 3 ggg 2 bb 2 ee 1 a 1 f Rust use std::cmp::Ordering; use std::io::BufRead; /// Compares the length of two strings by iterating over their characters /// together until either string has run out. fn compare(a: &str, b: &str) -> Ordering { let mut a = a.chars(); let mut b = b.chars(); loop { match (a.next(), b.next()) { (None, None) => return Ordering::Equal, (Some(_), None) => return Ordering::Greater, (None, Some(_)) => return Ordering::Less, (Some(_), Some(_)) => {} } } } /// Returns the longest lines of the input, separated by newlines. fn longest<I: IntoIterator<Item = String>>(input: I) -> String { let mut longest = String::new(); let mut output = String::new(); for line in input { match compare(&line, &longest) { // A longer string replaces the output and longest. Ordering::Greater => { output.clear(); output.push_str(&line); longest = line; } // A string of the same length is appended to the output. Ordering::Equal => { output.push('\n'); output.push_str(&line); } // A shorter string is ignored. Ordering::Less => {} } } output } fn main() { let stdin = std::io::stdin(); let lines = stdin.lock().lines().map(|l| l.expect("Failed to read.")); println!("{}", longest(lines)) } Scala val longest = scala.io.Source.fromFile(args.head).getLines.toIterable.groupBy(_.length).max._2 println(longest mkString "\n") Sidef var l = ''; # Sample longest string seen. var a = ''; # Accumulator to save longest strings. STDIN.each { |n| n.substr(l.len) ? (a = n; l = n) : (!l.substr(n.len) && a.concat!(n)); } print a; Tcl Uses only string comparisons for equality and glob-style matching #!/usr/bin/env tclsh set longest z set output "" while {[gets stdin line] != -1} { set comparison [string repeat z [string length \$line]] if {\$longest eq \$comparison} { # this line is equally long append output \$line \n } elseif {[string match \${longest}z* \$comparison]} { # this line is longer set longest \$comparison set output "\$line\n" } } puts -nonewline \$output Test: \$ ./longest.tcl <<END > a > bb > ccc > ddd > ee > f > ggg > END ccc ddd ggg \$ ./longest.tcl </dev/null \$ {{omit from|Brlcad}} {{omit from|GUISS}} {{omit from|Openscad}} VBScript The solution uses the Mid function to compare string lengths. 'Read the input file. This assumes that the file is in the same 'directory as the script. Set objfso = CreateObject("Scripting.FileSystemObject") Set objfile = objfso.OpenTextFile(objfso.GetParentFolderName(WScript.ScriptFullName) &_ "\input.txt",1) list = "" previous_line = "" l = Len(previous_line) Do Until objfile.AtEndOfStream current_line = objfile.ReadLine If Mid(current_line,l+1,1) <> "" Then list = current_line & vbCrLf previous_line = current_line l = Len(previous_line) ElseIf Mid(current_line,l,1) <> "" And Mid(current_line,(l+1),1) = "" Then list = list & current_line & vbCrLf End If Loop WScript.Echo list objfile.Close Set objfso = Nothing {{Out}} ccc ddd ggg XQuery Port of XSLT solution, this time using a string sequence. let \$seq as xs:string+ := ("a","bb","ccc","ddd","ee","f","ggg") for \$l in max( for \$s in \$seq return string-length(\$s) ) return \$seq[string-length(.) eq \$l] Result: ("ccc","ddd","ggg") XSLT 2.0 This XSLT 2.0 style-sheet... <xsl:stylesheet version="2.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform"> <xsl:output indent="yes" encoding="UTF-8" omit-xml-declaration="yes" /> <xsl:template match="/*"> <xsl:copy-of select="for \$l in max( for \$s in s return string-length(\$s)) return s[string-length(.) eq \$l]" /> </xsl:template> </xsl:stylesheet> ...when applied to this input... <lang><t> <s>a</s> <s>bb</s> <s>ccc</s> <s>ddd</s> <s>ee</s> <s>f</s> <s>ggg</s> </t> ...yields... ccc ddd ggg ## zkl The ops used are: remove a character from the beginning of a string, testing if a string is "" or not, , string concatenation, integer equality. To decide which of two strings is longer, a character is removed from each until one is empty. If one still has text, it is longer. ```zkl fcn longer(a,b){ //-->0,1,2 (same, a longer, b longer) while(a and b){a=a.del(0); b=b.del(0);} if (not a and not b) return(0); // a & b same length if(a) return(1); // a is longer 2 // b is longer } text:=a:=ask("text: ").strip(); while(b:=ask("text: ").strip()){ switch(longer(a,b)){ case(0){ text=String(text,"\n",b) } // a.len()==b.len() case(1){ } // a.len>b.len() case(2){ text=a=b } // a.len>b.len() } //switch } println(text); {{out}} text: a text: bb text: ccc text: ddd text: ee text: f text: ggg text: The longest line(s) are: ccc ddd ggg {{out}} text: text: The longest line(s) are: [[Category:Handicap]] ```
``` ```
``` Created by Adrian Sieber and contributors with Zola Licensed under the GFDL-1.3-or-later ```
``` ```