# Better algorithm for complementing integer value excluding the leading zero binary bits

I will explain first what I mean by "complementing integer value excluding the leading zero binary bits" (from now on, I will call it Non Leading Zero Bits complement or NLZ-Complement for brevity).

For example, there is integer number 92. the binary number is 1011100. If we perform normal bitwise-NOT or Complement, the result is: -93 (signed integer) or 11111111111111111111111110100011 (binary). That's because the leading zero bits are being complemented too.

So, for NLZ-Complement, the leading zero bits are not complemented, then the result of NLZ-complementing of 92 or 1011100 is: 35 or 100011 (binary). The operation is performed by XORing the input value with sequence of 1 bits as much as the non-leading zero value. The illustration:

``````92:  1011100
1111111 (xor)
--------
0100011 => 35
``````

``````public static int nonLeadingZeroComplement(int n) {
if (n == 0) {
return ~n;
}
if (n == 1) {
return 0;
}

//This line is to find how much the non-leading zero (NLZ) bits count.
//This operation is same like: ceil(log2(n))
int binaryBitsCount = Integer.SIZE - Integer.numberOfLeadingZeros(n - 1);

//We use the NLZ bits count to generate sequence of 1 bits as much as the NLZ bits count as complementer
//by using shift left trick that equivalent to: 2 raised to power of binaryBitsCount.
//1L is one value with Long literal that used here because there is possibility binaryBitsCount is 32
//(if the input is -1 for example), thus it will produce 2^32 result whom value can't be contained in
//java signed int type.
int oneBitsSequence = (int)((1L << binaryBitsCount) - 1);

//XORing the input value with the sequence of 1 bits
return n ^ oneBitsSequence;
}
``````

I need an advice how to optimize above algorithm, especially the line for generating sequence of 1 bits complementer (oneBitsSequence), or if anyone can suggest better algorithm?

UPDATE: I also would like to know the known term of this non-leading zero complement?

-
So for all powers of two you want to return 0. So starting from 0 the sequence would be 1, 0, 0, 0, 0, 2, 1, 0, 0, 6, ... What is the use of this? –  Peter Lawrey Aug 6 '12 at 11:30
What you call "NLZ-Complement" is what is known as Ones' Complement. en.wikipedia.org/wiki/One%27s_compliment –  Mister Smith Aug 6 '12 at 11:53
@MisterSmith: are you sure? I think it's not. One's complement also complements the leading zeroes. –  suud Aug 6 '12 at 11:57
In that case, you are right. Will update my answer. –  Mister Smith Aug 6 '12 at 12:08
After some thinking, seems that you have to count the leading 0's. So instead of editing my wrong answer, I'll delete it, since the first answer is the correct. –  Mister Smith Aug 6 '12 at 12:16

You can get the highest one bit through the `Integer.highestOneBit(i)` method, shift this one step left, and then subtract 1. This gets you the correct length of `1`s:

``````private static int nonLeadingZeroComplement(int i) {
int ones = (Integer.highestOneBit(i) << 1) - 1;
return i ^ ones;
}
``````

For example,

``````System.out.println(nonLeadingZeroComplement(92));
``````

prints

``````35
``````
-
I knew it! There must be a built-in function that can make this more simple. Lol, you make this very easy. Do you know the real/known term of this NLZ-complement? –  suud Aug 6 '12 at 11:59
@suud: No, sorry, I don't know a special term for this. –  Keppil Aug 6 '12 at 12:11

obviously @keppil has provided shortest solution. Another solution could be like.

``````private static int integerComplement(int n){

String binaryString = Integer.toBinaryString(n);

String temp = "";
for(char c: binaryString.toCharArray()){
if(c == '1'){
temp += "0";
}
else{
temp += "1";
}
}
int base = 2;
int complement = Integer.parseInt(temp, base);

return complement;
}
``````

For example,

``````System.out.println(nonLeadingZeroComplement(92));
``````