# Bitwise operations on sign-magnitude big integers

I am writing a simple BigInteger type in Delphi. This type consist of an array of unsigned 32 bit integers (I call them limbs), a count (or size) and a sign bit. The value in the array is interpreted as absolute value, so this is a sign-magnitude representation. This has several advantages, but one disadvantage.

The bitwise operations like `and`, `or`, `xor` and `not` have two's complement semantics. This is no problem if both `BigInteger`s have positive values, but the magnitudes of negative `BigInteger`s must be converted to two's complement by negation. This can be a performance problem, since if we do, say

``````C := -A and -B;
``````

then I must negate the magnitudes of `A` and `B` before the `and` operation can be performed. Since the result is supposed to be negative too, I must negate the result too to get a positive magnitude again. For large `BigInteger`s, negating up to three values can be a considerable performance cost.

Mind you, I know how to do this and the results are correct, but I want to avoid the slowness caused by the necessary negations of large arrays.

I know of a few shortcuts, for instance

``````C := not A;
``````

can be achieved by calculating

``````C := -1 - A;
``````

which is what I do, and the result is fine. This makes `not` as performant as addition or subtraction, since it avoids the negation before (and after) the operation.

## Question

My question is: are there similar laws I can use to avoid negating the magnitudes of "negative" `BigInteger`s? I mean something like the calculation of `not` by using subtraction?

I mean simple or not-so-simple laws like

``````not A and not B = not (A or B) // = is Pascal for ==
not A or not B = not (A and B)
``````

but then for -A and/or -B, etc. I do know that

``````(-A and -B) <> -(A or B) // <> is Pascal for !=
``````

is not true, but perhaps there is something similar?

I simply can't find any such laws that relate to negative values and bitwise operations, if they exist at all. Hence my question.

• If you want to learn for yourself, why are you asking? You are asking because you want to learn from others. – David Heffernan Aug 30 '15 at 15:13
• I want to learn from others about the logics. I want to learn and apply what I have learned myself. What I have works, and works well. But I am always willing to improve. As I said, there is nothing wrong with finding knowledge, but simply copying the (GPL-ed) code of others is not what I want. – Rudy Velthuis Aug 30 '15 at 15:46
• I repeat, I am not telling you to use the code of others. What made you think I said that? – David Heffernan Aug 30 '15 at 15:52
• If you want a clean implementation then do it yourself. If you ask others to tell you how to do it, how do you know you are still clean? Suppose I read another library, work out how it solves these issues, and then write an answer here. How does that differ from you reading the code? – David Heffernan Aug 30 '15 at 16:00
• you can use 2's complement for the BigInteger. The most significant limb will be of a 2's complement signed type and the remaining limbs' type is unsigned. It's much easier to implement as most operations would be the same for signed and unsigned types – phuclv Aug 30 '15 at 16:48

Last time I checked negation worked like this:

``````-A = not(A) + 1; or
-A = not(A - 1);
that means that
-A and -B = not(A - 1) and not(B - 1)
``````

if we add another NOT at the front than we can replace the `and not` with an `or`

``````not(-A and -B) = not(not(A - 1) and not(B - 1)) =
(A - 1) or (B - 1)
``````

We still need to do an expensive `not` at the end, but because not is so close to `-` we can cheat and replace the expensive `not` with a cheap `-` like so:

``````-(-A and -B) = (A-1) or (B-1) + 1;
``````

And finally the outcome will be:

``````(-A and -B) = -((A-1) or (B-1) + 1);
``````

This should be much faster than flipping all the bits.

This will be very cheap to implement because:

1. Negation is a simple bit flip on your sign byte.
2. +1/-1 will run out of carry/borrow bits very soon in the overwelming amount of cases (only 1/2^32 cases will carry/borrow to the next limb).

The same goes for `or`; `not or` is very close to `and`.

• Thanks, that really helped me. Although, this still requires two subtractions, an addition and a negation, so that may not really simplify things. I'll check if I can take a few more shortcuts. – Rudy Velthuis Aug 30 '15 at 16:30
• FWIW, in my implementation, a negation takes more or less the same time as a subtraction or an addition, all, AFAICT, in the order of O(n). – Rudy Velthuis Aug 30 '15 at 16:34
• @RudyVelthuis, the -1 should take very little time, because you should run out of borrowing bits in the 1st-limb. except in 1/2^32 of cases (limb = \$FFFFFFFF). So it will take O(1) time in 99.99999% of the cases. The negation is (nearly) free. – Johan Aug 30 '15 at 16:38
• Note that negating the sign bit and doing a naive `and` is very different from doing a 2's complement negation and an `and`. So the implementation is really very cheap. – Johan Aug 30 '15 at 16:41
• you could be right. I'll check how I can optimize -1 that way. – Rudy Velthuis Aug 30 '15 at 17:02

My question is: are there similar laws I can use to avoid negating the magnitudes of "negative" BigIntegers?

Yes, and I did before what you want to do - see here, lines 105 - 115 (or better download the repository). Strange enough I also use the term 'Limb".

For example `arrAndTwoCompl` computes bitwise `and` of positive and negative, `arrAndTwoCompl2` computes bitwise `and` of 2 negatives.

I've taken these 'laws' from GMP sources.

Don't reinvent big integers, just use them.

• I could use GMP. But I want to re-invent them. I do this for fun, with no deadline in my neck. – Rudy Velthuis Aug 30 '15 at 17:30
• Most bigint libraries use the term limb, as far as I can tell – David Heffernan Aug 30 '15 at 17:30
• Knuth was probably (one of the) first to use that term, in his TAOCP. That is where I saw it the first time. – Rudy Velthuis Aug 30 '15 at 17:32
• And does DK address this issue at all? – David Heffernan Aug 30 '15 at 17:40
• Not as I am aware of. Knuth has good description of big integer division algorithm. – kludg Aug 30 '15 at 17:43