# meaning of (number) & (-number)

What is the meaning of (number) & (-number)? I have searched it but was unable to find the meaning

I want to use i&(-i) in for loop like:

for(i=0;i<=n;i+=i&(-i))

& is the bitwise operator

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A bitwise and with the negation. –  Basile Starynkevitch Oct 10 '12 at 12:08
Why do you want to use it, if you do not know what it means? –  Rowland Shaw Oct 10 '12 at 12:09
You want to use it in a loop but you don't know what it does? –  Mike Oct 10 '12 at 12:09
I hope that i is declared with an unsigned type. –  Charles Bailey Oct 10 '12 at 12:10
The i=0 initialiser does make the loop infinite since i&(-i) is also 0. What's does the content of the loop do? –  Skizz Oct 10 '12 at 12:22

Assuming 2's complement (or that i is unsigned), -i is equal to ~i+1.

i & (~i + 1) is a trick to extract the lowest set bit of i.

It works because what +1 actually does is to set the lowest clear bit, and clear all bits lower than that. So the only bit that is set in both i and ~i+1 is the lowest set bit from i (that is, the lowest clear bit in ~i). The bits lower than that are clear in ~i+1, and the bits higher than that are non-equal between i and ~i.

Using it in a loop seems odd unless the loop body modifies i, because i = i & (-i) is an idempotent operation: doing it twice gives the same result again.

[Edit: in a comment elsewhere you point out that the code is actually i += i & (-i). So what that does for non-zero i is to clear the lowest group of set bits of i, and set the next clear bit above that, for example 101100 -> 110000. For i with no clear bit higher than the lowest set bit (including i = 0), it sets i to 0. So if it weren't for the fact that i starts at 0, each loop would increase i by at least twice as much as the previous loop, sometimes more, until eventually it exceeds n and breaks or goes to 0 and loops forever.

It would normally be inexcusable to write code like this without a comment, but depending on the domain of the problem maybe this is an "obvious" sequence of values to loop over.]

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it seems that he is going to change the value of i in the loops body..i think i=i&(-i) is for keeping it positive –  Anirudh Oct 10 '12 at 12:31
@Anirudha: if it is intended to keep it positive then it doesn't work for the case where only the topmost bit is set. But anyway, the questioner says in a comment that i is unsigned. –  Steve Jessop Oct 10 '12 at 12:32
thanks sir.understood now –  aseem Oct 10 '12 at 14:49

i&(-i) is a trick to check if i has only 1 set bit. In that case the expression evaluates to zero. (also if i==0)

EDIT: it's part of a trick: the actual code to test for single bit is i==(i&(-i)) so, please free to vote this down...

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Your description “trick to check if i has only 1 set bit” reminds me more of i & (i-1) than of i & (-i). –  Pascal Cuoq Oct 10 '12 at 12:14
Given that the value is then assigned to i in the loop I think you need to mention the value if it isn't 0. –  Charles Bailey Oct 10 '12 at 12:15
"In that case the expression evaluates to zero". That's not true. 1 has only 1 set bit, and the expression 1 & (-1) evaluates to 1, not 0. This code is similar to the bit-hack i == i & (-i) but not identical. But I too can't work out from this line what the actual significance is. –  Steve Jessop Oct 10 '12 at 12:18
Generating an infinite loop if i<=n ? –  Aki Suihkonen Oct 10 '12 at 12:27
@Aki: yeah, which it is because it starts at 0. for(int i = 0;;) would seem simpler :-). I'm pretty sure that the real code either modifies i in the loop or else is broken. –  Steve Jessop Oct 10 '12 at 12:37

I thought I'd just take a moment to show how this works. This code gives you the lowest set bit's value:

int i = 0xFFFFFFFF; //Last byte is 1111(base 2), -1(base 10)
int j = -i;         //-(-1) == 1
int k = i&j;        //   1111(2) = -1(10)
// & 0001(2) =  1(10)
// ------------------
//   0001(2) = 1(10). So the lowest set bit here is the 1's bit

int i = 0x80;       //Last 2 bytes are 1000 0000(base 2), 128(base 10)
int j = -i;         //-(128) == -128
int k = i&j;        //   ...0000 0000 1000 0000(2) =  128(10)
// & ...1111 1111 1000 0000(2) = -128(10)
// ---------------------------
//   1000 0000(2) = 128(10). So the lowest set bit here is the 128's bit

int i = 0xFFFFFFC0; //Last 2 bytes are 1100 0000(base 2), -64(base 10)
int j = -i;         //-(-64) == 64
int k = i&j;        //   1100 0000(2) = -64(10)
// & 0100 0000(2) =  64(10)
// ------------------
//   0100 0000(2) = 64(10). So the lowest set bit here is the 64's bit

It works the same for unsigned values, the result is always the lowest set bit's value.