# Programming Riddle: Counting down without subtracting [closed]

Ok, goal by example : a command-line app that does this:

Countdown.exe 7

prints 7 6 5 4 3 2 1

No form of subtracting (including use of the minus sign) or string reverse what so ever is allowed.

waaaaay too easy apparently :-) An overview of the answers (the principles at least)

2. By using modulo
3. By pushing and popping, (maybe the most obvious?)
4. By using overflow
5. By using trial and error (maybe the least obvious?)
• There is no need to post about someone voting to close. I doubt it will receive anymore votes. Commented Apr 18, 2009 at 18:10
• The original text was: print 7 6 5 4 3 3 2 1, so there where two 3's ;-). Commented Apr 18, 2009 at 18:23
• haha, that was meant to be of course, way too easy without the double 3 ;-) Commented Apr 18, 2009 at 18:46

``````x = param;
while (x > 0) {
print x;
x = (x + param) mod (param + 1);
}
``````
• +1 for good use of modulo arithmetic. Commented Apr 18, 2009 at 18:30
• Mod is division, which by definition is a form of subtraction. I would say that this doesn't count. Commented Apr 18, 2009 at 19:24
• Modulus is not division. q(x) != r(x). Math solved this problem. Commented Apr 18, 2009 at 22:15
• clever subtraction! me like ^_^ Commented Apr 19, 2009 at 1:56
• @Scott — I would content that neither of those statements are true. Modulus is typically defined in terms of division, but that doesn't make it division. Ditto for division != subtraction. Commented Jun 22, 2009 at 18:02

``````public void Print(int i, int max) {
if ( i < max ) {
Print(i+1, max);
}
Console.Write(i);
Console.Write(" ");
}

public void Main(string[] args) {
int max = Int32.Parse(args[0]);
Print(1, max);
}
``````
• That would not work the way he has it as a parameter. But it could be modified. Commented Apr 18, 2009 at 17:51
• @Daniel, see the updated sample Commented Apr 18, 2009 at 17:52
• Yea. I guess you updated when i was typing that. Commented Apr 18, 2009 at 17:53
• haha, exact the solution i came up with, I searched a bit longer I must admit. Commented Apr 18, 2009 at 17:56
• Doest it make sense in CW to accept an answer? Commented Apr 18, 2009 at 17:57

Here's a method you missed, trial and error:

``````import java.util.Random;

public class CountDown
{
public static void main(String[] args)
{
Random rand = new Random();

int currentNum = Integer.parseInt(args[0]);

while (currentNum != 0)
{
System.out.print(currentNum + " ");
int nextNum = 0;
while (nextNum + 1 != currentNum) {
nextNum = rand.nextInt(currentNum);
}

currentNum = nextNum;
}
}
}
``````
• got a chuckle out of that one...
– jim
Commented Apr 22, 2009 at 13:33

Push 1-7 onto a stack. Pop stack one by one. Print 7-1. :)

• isnt't it considered array reversion?? Commented Apr 18, 2009 at 18:08
• There are many many ways to implement a stack. Commented Apr 18, 2009 at 18:22
• The recursive solution just used the call stack as its stack; this is simply a not-necessarily-recursive interpretation. Commented Apr 18, 2009 at 22:16
• The callstack is not a data structure. Commented Apr 19, 2009 at 1:24
• @JP, so if you want to countdown from 100.000.000 you will create a stack of 100.000.000 elements and then pop the stack..... Commented Nov 10, 2009 at 18:25

use 2's compliment, after all this is how a computer deals with negative numbers.

``````int Negate(int i)
{
i = ~i;  // invert bits
return i + 1; // and add 1
}

void Print(int max)
{
for( int i = max; i != 0; i += Negate(1) )
{
printf("%d ", i);
}
}
``````
• Although isn't what you are doing essentially subtracting, since you're adding negative 1? Commented Jun 19, 2009 at 18:45
• Well, the result is the same as if a subtraction had been done, but you'll see the example uses a +=, so it's a plus. But, the effect is the same as if a subtraction had been done. But, you could argue the effect of any other answer to this question is to have subtracted 1... so you could also say this answer is essentially the same as 'adding and recursion', which is the accepted answer. Or you could say it's essentially the same as prepending numbers into a string buffer or whatever. :) Commented Jun 21, 2009 at 20:36

Prepend the numbers into a string buffer.

``````String out = "";
for (int i = 0; i < parm; i++)
{
out = " " + (i+1) + out;
}
System.out.println(out);
``````

c/c++, a bit of arithmetic overflow:

``````void Print(int max)
{
for( int i = max; i > 0; i += 0xFFFFFFFF )
{
printf("%d ", i);
}
}
``````
• Technically, adding a negative number is performing subtraction! d= Commented Apr 19, 2009 at 0:43
• does not work when int==64bit Commented Apr 20, 2009 at 19:08
• yes, true. i think my other answer with the 2's compliment was probably better. this is just an optimization of that that happens to require a 32 bit machine. Commented Apr 20, 2009 at 23:12
• This is the solution I thought of first :)
– Trap
Commented Jun 20, 2009 at 12:39

I note that nobody posted the stupidest possible answer, so I'll go ahead and share it:

``````int main (int argc, char **argv) {
if ( ( argc < 1 ) || ( atoi(argv[1]) != 7 ) ) {
printf("Not supported.\n");
} else {
printf("7 6 5 4 3 2 1\n");
}
}
``````

Don't hate me: See? I admitted it's stupid. :)

use a rounding error:

``````void Decrement(int& i)
{
double d = i * i;
d = d / (((double)i)+0.000001); // d ends up being just smaller than i
i = (int)d; // conversion back to an int rounds down.
}

void Print(int max)
{
for( int i = max; i > 0; Decrement(i) )
{
printf("%d ", i);
}
}
``````
• Pretty nifty, Scott. Way to exploit type-casting. Commented Jun 5, 2009 at 11:12

Bitwise Arithmetic

Constant space, with no additions, subtractions, multiplications, divisions, modulos or arithmetic negations:

``````#include <iostream>
#include <stdlib.h>
int main( int argc, char **argv ) {
for ( unsigned int value = atoi( argv[ 1 ] ); value; ) {
std::cout << value << " ";
for ( unsigned int place = 1; place; place <<= 1 )
if ( value & place ) {
value &= ~place;
break;
} else
value |= place;
}
std::cout << std::endl;
}
``````
• Btw you could get rid of that 'else'
– Trap
Commented Jun 20, 2009 at 13:30

This is not hard. Use the modulus operator.

``````for (int n = 7; n <= 49; n += 7) {
print n mod 8;
}
``````
• upvoted for creativity, but please fix the infinite loop Commented Apr 20, 2009 at 18:07
• The idea is good, but it doesn't work for any n other than 7. Commented Apr 20, 2009 at 19:46

A python version:

``````import sys

items = list(xrange(1, int(sys.argv[1])+1))
for i in xrange(len(items)):
print items.pop()
``````

This is cheating, right?

``````#!/usr/bin/env python
def countdown(n):
for i in range(n):
print n
n = n + (n + ~n)
``````

And just for fun, its recursive brother:

``````def tune_up(n):
print n
if n == 0:
return
else:
return tune_up(n + (n + ~n))
``````

Start with a file containing descending numbers from to the max you're interested in:

``````7 6 5 4 3 2 1
``````

Then... this only works up to 9999

``````#!/bin/sh
MAX_NUM=9999
if [ ! -e descendingnumbers.txt ]; then
seq -f%04.0f -s\  \$MAX_NUM -1 1 > descendingnumbers.txt
fi
tail descendingnumbers.txt -c \$[5 * \$1]
``````

Quick and dirty version in Scala:

``````sealed abstract class Number
case class Elem(num: Number, value: Int) extends Number
case object Nil extends Number

var num: Number = Nil

for (i <- 1 until param)
num = Elem(num, i)

while (num != null)
num match {
case Elem(n, v) => {
System.out.print(v + " ")
num = n
}
case Nil => {
System.out.println("")
num = null
}
}
``````
• There's a minus sign!! .... I'm kidding :-P Commented Apr 19, 2009 at 1:51

Increment a signed integer passed max_int and then "Add" it to the counter... or is this consider illegitimate subtraction?

• It's another case of overflow, ok for me Commented Apr 18, 2009 at 18:56
``````    public void print (int i)
{
Console.Out.Write("{0} ", i);
int j = i;
while (j > 1)
{
int k = 1;
while (k+1 < j)
k++;
j = k;
Console.Out.Write("{0} ", k );
}
}
``````

Kinda nasty but it does the job

``````public class CountUp
{
public static void main(String[] args)
{

int n = Integer.parseInt(args[0]);

while (n != 0)
{
System.out.print(n + " ");
n = (int)(n + 0xffffffffL);
}
}
}
``````
• looks strangely familiar, i like it though! worthy of an up vote. Commented Apr 18, 2009 at 18:15
``````// count up until found the number. the previous number counted is
// the decremented value wanted.
void Decrement(int& i)
{
int theLastOneWas;
for( int isThisIt = 0; isThisIt < i; ++isThisIt )
{
theLastOneWas = isThisIt;
}
i = theLastOneWas;
}

void Print(int max)
{
for( int i = max; i > 0; Decrement(i) )
{
printf("%d ", i);
}
}
``````

Are we golfing this?

``````import sys
for n in reversed(range(int(sys.argv[1]))):print n+1,
``````
``````#!/usr/bin/env ruby

ARGV[0].to_i.downto(1) do |n|
print "#{n} "
end
puts ''
``````

``````import System.Environment (getArgs)

func :: Integer -> [String]
func 0 = []
func n@(x+1) = show n:func x

main = putStrLn . unwords . func . read . head =<< getArgs
``````

A 'feature' called n+k patterns allows this: pattern matching on the addition of two numbers. It is generally not used. A more idiomatic way to do it is with this version of func:

``````func n = foldl (flip \$ (:) . show) [] [1..n]
``````

or, with one number per line:

``````import System.Environment (getArgs)
import Data.Traversable

main = foldrM (const . print) () . enumFromTo 1 . read . head =<< getArgs
``````

Does this count? Only uses an add instruction...

``````int _tmain(int argc, _TCHAR* argv[])
{
int x = 10;
__asm mov eax,x;
__asm mov ebx,0xFFFFFFFF;
while (x > 0)
{
__asm mov x,eax;
__asm push eax;
printf("%d ",x);
__asm pop eax;
}
return 0;
}
``````

Perl:

``````\$n = \$ARGV[0];

while (\$n > 0) {
print "\$n ";
\$n = int(\$n * (\$n / (\$n+1)));
}
``````

subtraction is an illusion anyways

• in that case, please subtract the balance of your bank account and give it to me. (assuming it's not already negative) Commented Apr 19, 2009 at 9:41

I like Dylan Bennett's idea - simple, pragmatic and it adheres to the K.I.S.S principle, which IMHO is one of the most important concepts we should always try to keep in mind when we develop software. After all we write code primarily for other human beings to maintain it, and not for computers to read it. Dylan's solution in good old C:

``````

#include <stdio.h>
int main(void) {
int n;
for (n = 7; n <= 49; n += 7) {
printf("%d ", n % 8);
}
}

``````

In C, using a rotating memory block (note, not something I'm proud of...):

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

#define MAX_MAX 10

void rotate_array (int *array, int size) {
int tmp = array[size - 1];
memmove(array + 1, array, sizeof(int) * (size - 1));
array[0] = tmp;
}

int main (int argc, char **argv) {
int idx, max, tmp_array[MAX_MAX];

if (argc > 1) {
max = atoi(argv[1]);
if (max <= MAX_MAX) {
for (idx = 0; idx < max; ++idx) {
tmp_array[idx] = idx + 1;
}
/* rotate, print, lather, rinse, repeat... */
for (idx = 0; idx < max; ++idx) {
rotate_array(tmp_array, max);
printf("%d ", tmp_array[0]);
}
printf("\n");
}
}

return 0;
}
``````

And a common lisp solution treating lists as ints:

``````(defun foo (max)
(format t "~{~A~^ ~}~%"
(maplist (lambda (x) (length x)) (make-list max))))
``````

Making this into an executable is probably the hardest part and is left as an exercise to the reader.

# Common Lisp

Counting down from 7 (with recursion, or like here, using `loop` and `downto`):

`(loop for n from 7 downto 1 do (print n))`

Alternatively, perhaps a more amusing soluting. Using complex numbers, we simply add i squared repeatedly:

``````(defun complex-decrement (n)
"Decrements N by adding i squared."
(+ n (expt (complex 0 1) 2)))

(loop for n = 7 then (complex-decrement n)
while (> n 0) do (print n))
``````

I like recursive

``````function printCountDown(int x, int y) {
if ( y != x ) printCountDown(x, y++);
print y + " ";
}
``````

You can also use multiplication

``````function printNto1(int x) {
for(int y=x*(MAXINT*2+1);y<=(MAXINT*2+1);y++) {
print (y*(MAXINT*2+1)) + " ";
}
}
``````

An alternative perl version could be:

```#!/usr/local/bin/perl
print reverse join(" ",1 .. \$ARGV[0]) . "\n";
```