# Finding a nonzero integer x where x == -x?

In a course on algorithms and data structures at my university, I received this question:

Which integer has the same bit-pattern as his negative value?

Means: x == -x

I know that 0 works, but I suspect that the instructor was looking for some other number x. What x is it? How would you find it?

• What about `1111111111111111`? Oct 24 '13 at 20:53
• Think about how 2's complement works at the extremes Oct 24 '13 at 20:54
• @LuiggiMendoza: That's -1, but you cannot display this in another way, if I understand this right. :) Oct 24 '13 at 21:07
• Java does not have unsigned integers, therefore 0 is the only solution. In C for example you could interpret the same bit pattern as a signed or unsigned integer. Oct 24 '13 at 21:10
• @lbalazscs Unsigned integers are not required. What is required for this puzzle to have an answer is 2's complement signed integers which have an asymmetric range about 0. Specifically, they have one more negative value than positive values. Oct 24 '13 at 23:49

Integer.MIN_VALUE and Long.MIN_VALUE have no equivalent positive value and when you take the negative value of these, you get the same value.

Negative is the same as flipping all the bits and adding one. i.e.

``````-x = ~x + 1
``````

So -0x80000000 = 0x7fffffff + 1 = 0x8000000

Note: Math.abs(Integer.MIN_VALUE) == Integer.MIN_VALUE which is negative. This is outlined in the javadoc for this method.

Technically there are many answers and types

``````byte x = 0;
short x = 0;
char x = 0;
int x = 0;
int x = Integer.MIN_VALUE;
float x = 0.0f;
float x = -0.0f;
long x = 0;
long x = Long.MIN_VALUE;
double x = 0.0;
double x = -0.0;
Byte x = 0;
Short x = 0;
Character x = 0;
Integer x = 0;
Integer x = Integer.MIN_VALUE;
Float x = 0.0f;
Float x = -0.0f;
Long x = 0L;
Long x = Long.MIN_VALUE;
Double x = 0.0;
Double x = -0.0;
``````

A similar Java Puzzler is; when is the following expression `true`.

``````x != x + 0
``````

EDIT: Floating point has both `+0.0` and `-0.0`. A such you might consider `-0.0` a different value to `0.0` although it is the case that `-0.0 == -(-0.0)`

Note: `Double.compare(0.0, -0.0) > 0` Note:

• @jmiserez for a course about data structures, you should not tie to a specific programming language internals. Oct 24 '13 at 21:13
• So essentially you are saying it's a bit of a trick question? Oct 24 '13 at 21:16
• @jmiserez Well, if you want to be technical, 0 isn't an answer either because it isn't a negative value.
– ajb
Oct 24 '13 at 21:21
• @jmiserez `int x = Integer.MIN_VALUE; if (x != 0 && x == -x)` is true. Oct 24 '13 at 21:21
• What I don't see in your solution: If I negate x and add +1, then it isn't the same number. As I understand his question, this should not be the point. "Is there an existing int-number, which is x == -x?" This is the whole question and in my opinion, this question could not make sense as I understand it. But I think this solution is, what he wanted from us. Thank you very much! :) Oct 24 '13 at 21:25

Suppose that you take the lowest possible representable number in signed two's-complement format. Let's say this number (call it x) has bit pattern `100000...0`, for example. To compute -x, you first flip all the bits to get `01111...1`, then add one to it. This causes a large ripple carry that results in the number `1000....0` again, which is the number that you started with. Thus you would have that `x == -x`. In the case of Java ints, this value is `Integer.MIN_VALUE`, which is -231.

You can actually figure this out mathematically. Since all numbers in signed two's-complement format are represented modulo some power of two (say, 2d), then the statement

x == -x

Really means

x == -x (mod 2d)

This means that

2x == 0 (mod 2d)

Therefore, the solutions to this problem are the set of all numbers x where 2x is 0 mod 2d. These are numbers of the form k × 2d for any integer k. Only two of these values can be represented in signed two's-complement format with d + 1 bits, namely, 0 and -2d. Therefore, the minimum possible negative number will always compare equal to its negative value.

Hope this helps!

• +1 for not forgetting 0 (although this should be obvious when thinking x==-x) Oct 24 '13 at 21:14
• I don't understand how `x == -x (mod 2^d) ` can go to `2x == 0 (mod 2^d)` since `-x` is in a multiplication, not an addition =\ Oct 24 '13 at 21:19
• @LuiggiMendoza add `x` to both sides of the equality??? That works in modular arithmetic.
– ajb
Oct 24 '13 at 21:22
• @ajb that would be `2x == -x(mod2^d) + x`, it is not the same. Oct 24 '13 at 21:23
• @LuiggiMendoza In `x == y (mod m)`, that should be an equivalence symbol in the middle (with three horizontal dashes) instead of `==`. If you're not familiar with this, look up "Modular arithmetic" in Wikipedia. `(mod m)` isn't a modulo "operator", like `(x mod m)` would be. If `a==b (mod m)`, then `a+c == b+c (mod m)`.
– ajb
Oct 24 '13 at 21:29

For an 8 bit integer: `1000 0000` signed this is -128 while unsigned this is 128

To look at this another way: All signed primitive integer types represent integers in the range

-2N-1 to 2N-1-1

(inclusive), where N is the number of bits. Whenever any mathematical integer operation is performed, if the mathematical result is some number Z that is outside that range ("overflow"), then the actual result will be R = Z + 2N * k, where k is some positive or negative integer chosen so that R will be in the range -2N-1 to 2N-1 - 1. So say x = -2N-1, and we compute -x. The mathematical result is Z = 2N-1, but that's out of range because Z > 2N-1-1. So to get it in range, we need to add 2N * k for some k, and k must be -1. Thus the actual result is R = 2N-1 + (2N)*(-1) = 2N-1 - 2N = -2N-1, which is the original value of x. So that's a value that makes x == -x.

Java has only signed integer types, but in languages that have unsigned types, the range for unsigned types is 0 to 2N-1, inclusive. But everything else applies in the same way.

The question, as stated, is ambiguous.

`0` is of course the obvious solution, and as others have discussed there are no other solutions in Java (which is how the question is tagged).

In C, for any signed integer type, the minimum value of the given type may be a solution for some implementations. For example, given a 2's-complement representation, evaluating `-INT_MIN` will probably give you `-INT_MIN`. But in fact, the behavior of evaluating that expression is undefined due to overflow, even if you assume 2's-complement. (Wraparound semantics are very common, but are not guaranteed.) Furthermore, the C standard does not require a 2's-complement representation; it also permits 1's-complement and sign-and-magnitude, neither of which has that extra negative value.

This program:

``````#include <stdio.h>
#include <limits.h>
int main(void) {
int n = INT_MIN;
printf("%d\n%d\n", n, -n); /* Warning: Undefined behavior for -n */
}
``````

produces this output on my system:

``````-2147483648
-2147483648
``````

Operations on C unsigned types have more strictly defined behavior. This program:

``````#include <stdio.h>
#include <limits.h>
int main(void) {
unsigned int n = UINT_MAX / 2 + 1;
printf("%u\n%u\n", n, -n);
}
``````

gives this output on a system with 32-bit `int` (and no padding bits):

``````2147483648
2147483648
``````

and will print two identical lines of output on any conforming implementation.

C++ has the same behavior (or undefined behavior) as C in this area.

In Perl, a large integer will fall over to a floating-point representation if it's too large to be represented as an integer -- but Perl scalars are complicated, and can simultaneously store more than one representation. On my 64-bit system, this Perl program:

``````#!/usr/bin/perl

use strict;
use warnings;

my \$n = -2.0**63;
print \$n, "\n", -\$n, "\n";
printf "%d\n%d\n", \$n, -\$n;
``````

gives this output:

``````-9.22337203685478e+18
9.22337203685478e+18
-9223372036854775808
-9223372036854775808
``````

which I'm not entirely sure I can explain myself.

Python appears to fall back to some form of extended-precision integers, so the issue of overflow doesn't arise, and so there's no numeric value that is its own negation. A number of other languages (including, I think, most Lisp dialects) do the same thing.

In Ada, an integer overflow doesn't have undefined behavior; it's required to raise an exception. This program:

``````with Ada.Text_IO; use Ada.Text_IO;
procedure Foo is
N: Integer := Integer'First;
begin
Put_Line(Integer'Image(N));
Put_Line(Integer'Image(-N));
end Foo;
``````

produces just one line of output:

``````-2147483648
``````

and then dies with a `Constraint_Error` exception.

And so on, and so on, and ....

So unless the instructor is just looking for zero as the answer, it depends very much on the context.

And looking at the question, why do you assume that `0` (which is a perfectly correct and obvious answer to the question as written, and apparently is the only correct answer in Java) isn't what the instructor was looking for?