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A question I got on my last interview:

Design a function f, such that:

f(f(n)) == -n

Where n is a 32 bit signed integer; you can't use complex numbers arithmetic.

If you can't design such a function for the whole range of numbers, design it for the largest range possible.

Any ideas?

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72  
+1: Nothing wrong with this question, not sure why it was downvoted or has close votes. –  Juliet Apr 8 '09 at 21:13
50  
Apparently there are people who think that maths is not programming related. –  Tamas Czinege Apr 8 '09 at 21:14
39  
Or offensive? Does that button mean "I can't figure it out" now? –  1800 INFORMATION Apr 8 '09 at 21:14
148  
public int f(int n) { throw new NotImplementException("You get the rest of the code when you give me a job."); } –  Juliet Apr 8 '09 at 21:21
237  
What a terrible interview question. –  Daniel Daranas Apr 9 '09 at 9:40

116 Answers 116

In PHP

function f($n) {
    if(is_int($n)) {
        return (string)$n;
    }
    else {
        return (int)$n * (-1);
    }
}

I'm sure you can understand the spirit of this method for other languages. I explicitly casted back to int to make it more clear for people who don't use weakly typed languages. You'd have to overload the function for some languages.

The neat thing about this solution is it works whether you start with a string or an integer, and doesn't visibly change anything when returning f(n).

In my opinion, the interviewer is asking, "does this candidate know how to flag data to be operated on later," and, "does this candidate know how to flag data while least altering it?" You can do this with doubles, strings, or any other data type you feel like casting.

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That's easy!

Every number is mapped to another in cycles of 4, where the needed condition holds.

Example:

The rules are:

  • 0 → 0

  • ±2³¹ → ±2³¹

  • odd → even, even → -odd:

    forall k, 0 < k < 2³⁰: (2k-1) → (2k) → (-2k+1) → (-2k) → (2k-1)

The only not matching values are ±(2³¹-1), because there are only two. There have to be two that cannot match, because there are only a multiple of four of numbers in a two's-complement system where 0 and ±2³¹ are already reserved.

In a one's complement system, there exist +0 and -0. There we go:

forall k, 0 < k < 2³⁰: (+2k) → (+2k+1) → (-2k) → (-2k-1) → (+2k)

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I have another solution that works half of the time:

def f(x):
    if random.randrange(0, 2):
        return -x
    return x
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Easy Python solution made possible by the fact that there were no restrictions on what f(x) was supposed to output, only f(f(x)):

def f(x):
    return (isinstance(x, tuple) and -x[0]) or (x,)
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1  
(x) returns x. I think you mean (x,) –  seppo0010 Jun 25 '13 at 16:47
int f( int n ){
    return n==0?0:(n&1?n:-n)+(n<0?-1:1);
}
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1  
n&1 is used like a bool but yields an int –  Dinah Aug 26 '09 at 16:06
3  
@Dinah assuming this is C or C++, that is just fine –  Kip Aug 27 '09 at 2:49

How about this?

int nasty(int input)
{
    return input + INT_MAX/2;
}
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Although the question said n had to be a 32 bit int, it did not say the parameter or return type had to be a 32 bit int. This should compile in java--in c you could get rid of the != 0

private final long MAGIC_BIT=1<<38;
long f(long n) {
    return n & MAGIC_BIT != 0 ? -(n & !MAGIC_BIT) : n | MAGIC_BIT;
}

edit:

This actually makes for a really good interview question. The best ones are ones difficult or impossible to answer because it forces people to think it through and you can watch and look for:

  • Do they just give up?
  • Do they say it's stupid?
  • Do they try unique approaches?
  • Do they communicate with you while they are working on the problem?
  • Do they ask for further refinements of the requirements?

etc.

Never just answer behavioral questions unless you have a VERY GOOD answer. Always be pleasant and try to involve the questioner. Don't get frustrated and don't give up early! If you really aren't getting anywhere, try something totally illegal that could work, you'll get nearly full credit.

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This is also a solution (but we are bending the rules a little bit):

def f(n):
    if isinstance(n,int):
    	return str(n)
    else:
    	return -int(n)
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I think the answer to these kind of questions are best explained visually by using diagrams. When we disregard zero, then we can partition the integers in small sets of 4 numbers:

 1  → 2    3  → 4    5  → 6
 ↑    ↓    ↑    ↓    ↑    ↓   ...
-2 ← -1   -4 ← -3   -6 ← -5

This is pretty easy to translate to code. Note that even numbers change sign, and the odd numbers are increased or decreased by 1. In C# it would look like this:

public static int f(int x)
{
    if(x == 0)
        return 0;

    if(x > 0)
        return (x % 2 == 0) ? -x+1 : x+1;

    // we know x is negative at this point
    return (x % 2 == 0) ? -x-1 : x-1;
}

Of course you can shorten this method by using clever tricks, but I think this code explains itself best.

Then about the range. The 32-bit integers range from -2^31 upto 2^31-1. The numbers 2^31-1, -2^31-1 and -2^31 fall outside of the range of f(x) because the number 2^31 is missing.

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  1. Convert n to Sign-and-magnitude representation;
  2. Add 1/4 of a range;
  3. Convert back.

    #define STYPE int
    STYPE sign_bit = (unsigned STYPE) 1 << ( sizeof ( STYPE ) * 8  - 1 );
    STYPE f ( STYPE f )
    {
        unsigned STYPE smf = f > 0 ? f : -f | sign_bit;
        smf += sign_bit >> 1;
        return smf & sign_bit ? -( smf & ~sign_bit ) : smf;
    }
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Mine gives the right answer...50% of the time, all the time.

int f (int num) {
    if (rand () / (double) RAND_MAX > 0.5)
         return ~num + 1;
    return num;
}
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1  
Actually, you're wrong. ~7=-8, ergo ~7+1=-7. –  Dan Jun 7 '11 at 2:52

Using the information given in the question, you can

  1. Convert from 2-complement to sign bit representation
  2. If the last bit is set, flip the sign bit and the last bit; otherwise, flip just the last bit
  3. Convert back to 2-complement.

So you basically go odd -> even -> odd or even -> odd -> even, and change the sign only for even numbers. The only number this does not work for is -2^31

Code:

function f(x) {
  var neg = x < 0;
  x = Math.abs(x) ^ 1;
  if (x & 1) {
    neg = !neg;
  }
  return neg ? -x : x;
}
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f(n) { return -1 * abs(n) }

How can I handle overflow problems with this? Or am I missing the point?

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1  
Given the requirements of the question, that's probably an adequate response. It doesn't say that f(n) has to return a different value. The question is a puzzle, so you look for the exploits (loopholes) that would make a feasible solution. –  JasonTrue Apr 8 '09 at 22:14
2  
In your case, f(f(-1)) = f(1) = -1. Therefore f(f(n)) = n, for n<0. –  Steven Aug 25 '09 at 19:07
1  
Works for nearly 50% of the inputs. Is reproducable and threadsafe. :) There are inferior solutions which got more upvotes. :) –  user unknown May 30 '11 at 4:21

Great question!

This took me about 35 secs to think about and write:

int f(int n){
    static int originalN=0;
    if (n!=0)
        originalN=n;
    return n-originalN;
}
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Lua:

function f(n)
    if type(n) == "number" then
        return (-number) .. ""
    else
        return number + 0
    end
end
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A bizarre and only slightly-clever solution in Scala using implicit conversions:

sealed trait IntWrapper {
  val n: Int
}

case class First(n: Int) extends IntWrapper
case class Second(n: Int) extends IntWrapper
case class Last(n: Int) extends IntWrapper

implicit def int2wrapper(n: Int) = First(n)
implicit def wrapper2int(w: IntWrapper) = w.n

def f(n: IntWrapper) = n match {
  case First(x) => Second(x)
  case Second(x) => Last(-x)
}

I don't think that's quite the right idea though.

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Golfing it in coffeescript:

f = (n)-> -n[0] or [n]
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Here's a short Python answer:

def f(n):
  m = -n if n % 2 == 0 else n
  return m + sign(n)

General Case

A slight tweak to the above can handle the case where we want k self-calls to negate the input -- for example, if k = 3, this would mean g(g(g(n))) = -n:

def g(n):
  if n % k: return n + sign(n)
  return -n + (k - 1) * sign(n)

This works by leaving 0 in place and creating cycles of length 2 * k so that, within any cycle, n and -n are distance k apart. Specifically, each cycle looks like:

N * k + 1, N * k + 2, ... , N * k + (k - 1), - N * k - 1, ... , - N * k - (k - 1)

or, to make it easier to understand, here are example cycles with k = 3:

1, 2, 3, -1, -2, -3
4, 5, 6, -4, -5, -6

This set of cycles maximizes the ranges of inputs that will work within any machine type centered around zero, such as signed int32 or signed int64 types.

Analysis of compatible ranges

The map x -> f(x) in fact must form cycles of length 2 * k, where x = 0 is a special case 1-length cycle since -0 = 0. So the problem for general k is solvable if and only if the range of the input - 1 (to compensate for 0) is a multiple of 2 * k, and the positive and negative ranges are opposites.

For signed integer representations, we always have a smallest negative number with no positive counterpart in the range, so the problem becomes unsolveable on the complete range. For example, a signed char has range [-128, 127], so it's impossible for f(f(-128)) = 128 within the given range.

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Doesn't fail on MIN_INT:

int f(n) { return n < 0 ? -abs(n + 1) : -(abs(n) + 1); }
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This will work in a very broad range of numbers:

    static int f(int n)
    {
        int lastBit = int.MaxValue;
        lastBit++;
        int secondLastBit = lastBit >> 1;
        int tuple = lastBit | secondLastBit;
        if ((n & tuple) == tuple)
            return n + lastBit;
        if ((n & tuple) == 0)
            return n + lastBit;
        return -(n + lastBit);
    }

My initial approach was to use the last bit as a check bit to know where we'd be in the first or the second call. Basically, I'd place this bit to 1 after the first call to signal the second call the first had already passed. But, this approach was defeated by negative numbers whose last bit already arrives at 1 during the first call.

The same theory applies to the second last bit for most negative numbers. But, what usually happens is that most of the times, the last and second last bits are the same. Either they are both 1 for negative numbers or they are both 0 for positive numbers.

So my final approach is to check whether they are either both 1 or both 0, meaning that for most cases this is the first call. If the last bit is different from the second last bit, then I assume we are at the second call, and simply re-invert the last bit. Obviously this doesn't work for very big numbers that use those two last bits. But, once again, it works for a very wide range of numbers.

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The problem as stated doesn't require that the function must ONLY accept 32 bit ints, only that n, as given, is a 32-bit int.

Ruby:

def f( n )
  return 0 unless n != 0 
  ( n == n.to_i ) ? 1.0 / n : -(n**-1).to_i
end
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Seems easy enough.

<script type="text/javascript">
function f(n){
    if (typeof n === "string") {
        return parseInt(n, 10)
    }
    return (-n).toString(10);
}

alert(f(f(1)));
</script>
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1  
It specifically states "where n is a signed 32 bit int", not a string –  joshcomley May 30 '09 at 15:32

Perhaps cheating? (python)

def f(n):    
    if isinstance(n, list):
        return -n[0]
    else:
        return [n,0]    
n = 4
print f(f(n))

--output--
-4
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easy:

function f($n) {
   if ($n%2 == 0) return ($n+1)*-1;
   else return ($n-1);
}
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Clojure solution:

(defmacro f [n]
  (if (list? n) `(- ~n) n))

Works on positive and negative integers of any size, doubles, and ratios too!

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In C,

int 
f(int n) {
     static int r = 0;
     if (r == 1) {r--; return -1 * n; };
     r++;
     return n;
}

It would have helped to know what language this was for. Am I missing something? Many "solutions" seem overly complex, and quite frankly, don't work (as I read the problem).

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Here's a C implementation of rossfabricant's answer. Note that since I stick with 32-bit integers at all times, f( f( 2147483647 ) ) == 2147483647, not -2147483647.

int32_t f( int32_t n )
{
    if( n == 0 ) return 0;
    switch( n & 0x80000001 ) {
        case 0x00000000:
            return -1 * ( n - 1 );
        case 0x00000001:
            return n + 1;
        case 0x80000000:
            return -1 * ( n + 1 );
        default:
            return n - 1;
    }
}

If you define the problem to allow f() to accept and return int64_t, then 2147483647 is covered. Of course, the literals used in the switch statement would have to be changed.

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how about this (C language):

int f(int n)
{
    static int t = 1;
    return (t = t ? 0 : 1) ? -n : n;
}

just tried it, and

f(f(1000))

returns -1000

f(f(-1000))

returns 1000

is that correct or am i missing the point?

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1  
This is not thread-safe and won't work when called multiple times. –  Tarnay Kálmán Sep 26 '09 at 2:03

This one's in Python. Works for all negative values of n:

f = abs
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Here's a variant I haven't seen people use. Since this is ruby, the 32-bit integer stuff sort of goes out the window (checks for that can of course be added).

def f(n)
    case n
    when Integer
        proc { n * -1 }
    when Proc
        n.call
    else
        raise "Invalid input #{n.class} #{n.inspect}"
    end
end

(-10..10).each { |num|
    puts "#{num}: #{f(f(num))}"
}
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protected by obi NullPoiиteя kenobi Jun 10 '13 at 5:16

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