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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?

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"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
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4 Answers

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.

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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
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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. –  AndreyT 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
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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
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This is also a great answer, thanks! –  Brandon Yarbrough Oct 22 '09 at 0:08
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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.

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+1 for the truth table! –  ojrac Oct 22 '09 at 4:31
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What!?????????? –  0x499602D2 Mar 13 '13 at 0:20
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