Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I was looking for a way to do a BITOR() with an Oracle database and came across a suggestion to just use BITAND() instead, replacing BITOR(a,b) with a + b - BITAND(a,b).

I tested it by hand a few times and verified it seems to work for all binary numbers I could think of, but I can't think out quick mathematical proof of why this is correct.
Could somebody enlighten me?

share|improve this question
"All binary numbers I could think of" - beut :) Nice question Captain. – martin clayton Oct 22 '09 at 0:01
Why does Oracle have a BITAND() but no BITOR()? – Thanatos Nov 27 '09 at 3:46
up vote 43 down vote accepted

A & B is the set of bits that are on in both A and B. A - (A & B) leaves you with all those bits that are only on in A. Add B to that, and you get all the bits that are on in A or those that are on in B.

Simple addition of A and B won't work because of carrying where both have a 1 bit. By removing the bits common to A and B first, we know that (A-(A&B)) will have no bits in common with B, so adding them together is guaranteed not to produce a carry.

share|improve this answer
Have you written a book? It'll would probably take them a chapter to explain this. Thanks! – Bostone Oct 21 '09 at 23:55
That's a great answer, exactly what I was looking for and easy to understand. Thanks a lot! – Brandon Yarbrough Oct 21 '09 at 23:57
it works just as well evaluated as (a + b) - (a & b), because addition is commutative. – JustJeff Oct 22 '09 at 0:18
@JustJeff: It works, but I wouldn't say that it is simply becuase "addition is commutative", since it doesn't really make it clear why it works. It works because subtraction of a & b correctly reverts the "destructive" effects of the carry. – AnT Oct 23 '09 at 16:35
@AndreyT: mine was not a 'why it works' comment. I didn't say it works b/c of commutativity; I said that b/c of commutativity, the non-obvious arrangement of (a+b)-(a&b) also evaluates to a|b. – JustJeff Nov 1 '09 at 20:55

Imagine you have two binary numbers: a and b. And let's say that these number never have 1 in the same bit at the same time, i.e. if a has 1 in some bit, the b always has 0 in the corresponding bit. And in other direction, if b has 1 in some bit, then a always has 0 in that bit. For example

a = 00100011
b = 11000100

This would be an example of a and b satisfying the above condition. In this case it is easy to see that a | b would be exactly the same as a + b.

a | b = 11100111
a + b = 11100111

Let's now take two numbers that violate our condition, i.e. two numbers have at least one 1 in some common bit

a = 00100111
b = 11000100

Is a | b the same as a + b in this case? No

a | b = 11100111
a + b = 11101011

Why are they different? They are different because when we + the bit that has 1 in both numbers, we produce so called carry: the resultant bit is 0, and 1 is carried to the next bit to the left: 1 + 1 = 10. Operation | has no carry, so 1 | 1 is again just 1.

This means that the difference between a | b and a + b occurs when and only when the numbers have at least one 1 in common bit. When we sum two numbers with 1 in common bits, these common bits get added "twice" and produce a carry, which ruins the similarity between a | b and a + b.

Now look at a & b. What does a & b calculate? a & b produces the number that has 1 in all bits where both a and b have 1. In our latest example

a =     00100111
b =     11000100
a & b = 00000100

As you saw above, these are exactly the bits that make a + b differ from a | b. The 1 in a & b indicate all positions where carry will occur.

Now, when we do a - (a & b) we effectively remove (subtract) all "offending" bits from a and only such bits

a - (a & b) = 00100011

Numbers a - (a & b) and b have no common 1 bits, which means that if we add a - (a & b) and b we won't run into a carry, and, if you think about it, we should end up with the same result as if we just did a | b

a - (a & b) + b = 11100111
share|improve this answer
This is also a great answer, thanks! – Brandon Yarbrough Oct 22 '09 at 0:08

A&B = C where any bits left set in C are those set in both A and in B.
Either A-C = D or B-C = E sets just these common bits to 0. There is no carrying effect because 1-1=0.
D+B or E+A is similar to A+B except that because we subtracted A&B previously there will be no carry due to having cleared all commonly set bits in D or E.

The net result is that A-A&B+B or B-A&B+A is equivalent to A|B.

Here's a truth table if it's still confusing:

 A | B | OR   A | B | &    A | B | -    A | B | + 
---+---+---- ---+---+---  ---+---+---  ---+---+---
 0 | 0 | 0    0 | 0 | 0    0 | 0 | 0    0 | 0 | 0  
 0 | 1 | 1    0 | 1 | 0    0 | 1 | 0-1  0 | 1 | 1
 1 | 0 | 1    1 | 0 | 0    1 | 0 | 1    1 | 0 | 1  
 1 | 1 | 1    1 | 1 | 1    1 | 1 | 0    1 | 1 | 1+1

Notice the carry rows in the + and - operations, we avoid those because A-(A&B) sets cases were both bits in A and B are 1 to 0 in A, then adding them back from B also brings in the other cases were there was a 1 in either A or B but not where both had 0, so the OR truth table and the A-(A&B)+B truth table are identical.

Another way to eyeball it is to see that A+B is almost like A|B except for the carry in the bottom row. A&B isolates that bottom row for us, A-A&B moves those isolated cased up two rows in the + table, and the (A-A&B)+B becomes equivalent to A|B.

While you could commute this to A+B-(A&B), I was afraid of a possible overflow but that was unjustified it seems:

#include <stdio.h>
int main(){ unsigned int a=0xC0000000, b=0xA0000000;
printf("%x %x %x %x\n",a,   b,       a|b,       a&b);
printf("%x %x %x %x\n",a+b, a-(a&b), a-(a&b)+b, a+b-(a&b)); }

c0000000 a0000000 e0000000 80000000
60000000 40000000 e0000000 e0000000

Edit: So I wrote this before there were answers, then there was some 2 hours of down time on my home connection, and I finally managed to post it, noticing only afterwards that it'd been properly answered twice. Personally I prefer referring to a truth table to work out bitwise operations, so I'll leave it in case it helps someone.

share|improve this answer
+1 for the truth table! – ojrac Oct 22 '09 at 4:31

share|improve this answer
What!?????????? – 0x499602D2 Mar 13 '13 at 0:20

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.