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 thinking about an algorithm in division of large numbers: dividing with remainder bigint C by bigint D, where we know the representation of C in base b, and D is of form b^k-1. It's probably the easiest to show it on an example. Let's try dividing C=21979182173 by D=999.

  • We write the number as sets of three digits: 21 979 182 173
  • We take sums (modulo 999) of consecutive sets, starting from the left: 21 001 183 356
  • We add 1 to those sets preceding the ones where we "went over 999": 22 001 183 356

Indeed, 21979182173/999=22001183 and remainder 356.

I've calculated the complexity and, if I'm not mistaken, the algorithm should work in O(n), n being the number of digits of C in base b representation. I've also done a very crude and unoptimized version of the algorithm (only for b=10) in C++, tested it against GMP's general integer division algorithm and it really does seem to fare better than GMP. I couldn't find anything like this implemented anywhere I looked, so I had to resort to testing it against general division.

I found several articles which discuss what seem to be quite similar matters, but none of them concentrate on actual implementations, especially in bases different than 2. I suppose that's because of the way numbers are internally stored, although the mentioned algorithm seems useful for, say, b=10, even taking that into account. I also tried contacting some other people, but, again, to no avail.

Thus, my question would be: is there an article or a book or something where the aforementioned algorithm is described, possibly discussing the implementations? If not, would it make sense for me to try and implement and test such an algorithm in, say, C/C++ or is this algorithm somehow inherently bad?

Also, I'm not a programmer and while I'm reasonably OK at programming, I admittedly don't have much knowledge of computer "internals". Thus, pardon my ignorance - it's highly possible there are one or more very stupid things in this post. Sorry once again.

Thanks a lot!


Further clarification of points raised in the comments/answers:

Thanks, everyone - as I didn't want to comment on all the great answers and advice with the same thing, I'd just like to address one point a lot of you touched on.

I am fully aware that working in bases 2^n is, generally speaking, clearly the most efficient way of doing things. Pretty much all bigint libraries use 2^32 or whatever. However, what if (and, I emphasize, it would be useful only for this particular algorithm!) we implement bigints as an array of digits in base b? Of course, we require b here to be "reasonable": b=10, the most natural case, seems reasonable enough. I know it's more or less inefficient both considering memory and time, taking into account how numbers are internally stored, but I have been able to, if my (basic and possibly somehow flawed) tests are correct, produce results faster than GMP's general division, which would give sense to implementing such an algorithm.

Ninefingers notices I'd have to use in that case an expensive modulo operation. I hope not: I can see if old+new crossed, say, 999, just by looking at the number of digits of old+new+1. If it has 4 digits, we're done. Even more, since old<999 and new<=999, we know that if old+new+1 has 4 digits (it can't have more), then, (old+new)%999 equals deleting the leftmost digit of (old+new+1), which I presume we can do cheaply.

Of course, I'm not disputing obvious limitations of this algorithm nor I claim it can't be improved - it can only divide with a certain class of numbers and we have to a priori know the representation of dividend in base b. However, for b=10, for instance, the latter seems natural.

Now, say we have implemented bignums as I outlined above. Say C=(a_1a_2...a_n) in base b and D=b^k-1. The algorithm (which could be probably much more optimized) would go like this. I hope there aren't many typos.

  • if k>n, we're obviously done
  • add a zero (i.e. a_0=0) at the beginning of C (just in case we try to divide, say, 9999 with 99)
  • l=n%k (mod for "regular" integers - shouldn't be too expensive)
  • old=(a_0...a_l) (the first set of digits, possibly with less than k digits)
  • for (i=l+1; i < n; i=i+k) (We will have floor(n/k) or so iterations)
    • new=(a_i...a_(i+k-1))
    • new=new+old (this is bigint addition, thus O(k))
    • aux=new+1 (again, bigint addition - O(k) - which I'm not happy about)
    • if aux has more than k digits
      • delete first digit of aux
      • old=old+1 (bigint addition once again)
      • fill old with zeroes at the beginning so it has as much digits as it should
      • (a_(i-k)...a_(i-1))=old (if i=l+1, (a _ 0...a _ l)=old)
      • new=aux
    • fill new with zeroes at the beginning so it has as much digits as it should
    • (a_i...a_(i+k-1)=new
  • quot=(a_0...a_(n-k+1))
  • rem=new

There, thanks for discussing this with me - as I said, this does seem to me to be an interesting "special case" algorithm to try to implement, test and discuss, if nobody sees any fatal flaws in it. If it's something not widely discussed so far, even better. Please, let me know what you think. Sorry about the long post.

Also, just a few more personal comments:

@Ninefingers: I actually have some (very basic!) knowledge of how GMP works, what it does and of general bigint division algorithms, so I was able to understand much of your argument. I'm also aware GMP is highly optimized and in a way customizes itself for different platforms, so I'm certainly not trying to "beat it" in general - that seems as much fruitful as attacking a tank with a pointed stick. However, that's not the idea of this algorithm - it works in very special cases (which GMP does not appear to cover). On an unrelated note, are you sure general divisions are done in O(n)? The most I've seen done is M(n). (And that can, if I understand correctly, in practice (Schönhage–Strassen etc.) not reach O(n). Fürer's algorithm, which still doesn't reach O(n), is, if I'm correct, almost purely theoretical.)

@Avi Berger: This doesn't actually seem to be exactly the same as "casting out nines", although the idea is similar. However, the aforementioned algorithm should work all the time, if I'm not mistaken.

share|improve this question
2  
So are you proposing to store all ints in BCD to make division faster? Converting base-2 to base-10 involves integer division, no? :-) – Ken Feb 23 '11 at 21:43
4  
Interesting algorithm, although probably of limited practical application. Technically, choosing different bases will allow you to use it with any arbitrary divisor, but the trick is converting it into that base in the first place. – Karl Bielefeldt Feb 23 '11 at 21:47
    
@Ninefingers: Seemed a little long to be an edit. I tried to delete it, but it seems a moderator already did it. Thanks anyway. – mornik Feb 24 '11 at 12:13

Your algorithm is a variation of a base 10 algorithm known as "casting out nines". Your example is using base 1000 and "casting out" 999's (one less than the base). This used to be taught in elementary school as way to do a quick check on hand calculations. I had a high school math teacher who was horrified to learn that it wasn't being taught anymore and filled us in on it.

Casting out 999's in base 1000 won't work as a general division algorithm. It will generate values that are congruent modulo 999 to the actual quotient and remainder - not the actual values. Your algorithm is a bit different and I haven't checked if it works, but it is based on effectively using base 1000 and the divisor being 1 less than the base. If you wanted to try it for dividing by 47, you would have to convert to a base 48 number system first.

Google "casting out nines" for more information.

Edit: I originally read your post a bit too quickly, and you do know of this as a working algorithm. As @Ninefingers and @Karl Bielefeldt have stated more clearly than me in their comments, what you aren't including in your performance estimate is the conversion into a base appropriate for the particular divisor at hand.

share|improve this answer
1  
...and the reason it's not used that the most efficient way to store limbs is just in plain binary fields, assuming the base is 2^field width. So you might typically use uint32_t to represent a limb. Then you're working 2^32 all the time. If you want to change base, you're going to need to access all the other limbs to manage the conversion. You can't just change base per limb. Second problem - bignum division of two numbers larger than the limb size. In that scenario, repeated calls to bignum_mod are very inefficient. +1, you are absolutely correct, good answer. – user257111 Feb 23 '11 at 23:25

I feel the need to add to this based on my comment. This isn't an answer, but an explanation as to the background.

A bignum library uses what are called limbs - search for mp_limb_t in the gmp source, which are usually a fixed-size integer field.

When you do something like addition, one way (albeit inefficient) to approach it is to do this:

doublelimb r = limb_a + limb_b + carryfrompreviousiteration

This double-sized limb catches the overflow of limb_a + limb_b in the case that the sum is bigger than the limb size. So if the total is bigger than 2^32 if we're using uint32_t as our limb size, the overflow can be caught.

Why do we need this? Well, what you typically do is loop through all the limbs - you've done this yourself in dividing your integer up and going through each one - but we do it LSL first (so the smallest limb first) just as you'd do arithmetic by hand.

This might seem inefficient, but this is just the C way of doing things. To really break out the big guns, x86 has adc as an instruction - add with carry. What this does is an arithmetic and on your fields and sets the carry bit if the arithmetic overflows the size of the register. The next time you do add or adc, the processor factors in the carry bit too. In subtraction it's called the borrow flag.

This also applies to shift operations. As such, this feature of the processor is crucial to what makes bignums fast. So the fact is, there's electronic circuitry in the chip for doing this stuff - doing it in software is always going to be slower.

Without going into too much detail, operations are built up from this ability to add, shift, subtract etc. They're crucial. Oh and you use the full width of your processor's register per limb if you're doing it right.

Second point - conversion between bases. You cannot take a value in the middle of a number and change it's base, because you can't account for the overflow from the digit beneath it in your original base, and that number can't account for the overflow from the digit beneath... and so on. In short, every time you want to change base, you need to convert the entire bignum from the original base to your new base back again. So you have to walk the bignum (all the limbs) three times at least. Or, alternatively, detect overflows expensively in all other operations... remember, now you need to do modulo operations to work out if you overflowed, whereas before the processor was doing it for us.

I should also like to add that whilst what you've got is probably quick for this case, bear in mind that as a bignum library gmp does a fair bit of work for you, like memory management. If you're using mpz_ you're using an abstraction above what I've described here, for starters. Finally, gmp uses hand optimised assembly with unrolled loops for just about every platform you've ever heard of, plus more. There's a very good reason it ships with Mathematica, Maple et al.

Now, just for reference, some reading material.

  • Modern Computer Arithmetic is a Knuth-like work for arbitrary precision libraries.
  • Donald Knuth, Seminumerical Algorithms (The Art of Computer Programming Volume II).
  • William Hart's blog on implementing algorithm's for bsdnt in which he discusses various division algorithms. If you're interested in bignum libraries, this is an excellent resource. I considered myself a good programmer until I started following this sort of stuff...

To sum it up for you: division assembly instructions suck, so people generally compute inverses and multiply instead, as you do when defining division in modular arithmetic. The various techniques that exist (see MCA) are mostly O(n).


Edit: Ok, not all of the techniques are O(n). Most of the techniques called div1 (dividing by something not bigger than a limb are O(n). When you go bigger you end up with O(n^2) complexity; this is hard to avoid.

Now, could you implement bigints as an array of digits? Well yes, of course you could. However, consider the idea just under addition

/* you wouldn't do this just before add, it's just to 
   show you the declaration.
 */
uint32_t* x = malloc(num_limbs*sizeof(uint32_t));
uint32_t* y = malloc(num_limbs*sizeof(uint32_t));
uint32_t* a = malloc(num_limbs*sizeof(uint32_t));
uint32_t m;

for ( i = 0; i < num_limbs; i++ )
{
    m = 0;
    uint64_t t = x[i] + y[i] + m;
    /* now we need to work out if that overflowed at all */
    if ( (t/somebase) >= 1 ) /* expensive division */
    {
        m = t % somebase; /* get the overflow */
    }
}

/* frees somewhere */

That's a rough sketch of what you're looking at for addition via your scheme. So you have to run the conversion between bases. So you're going to need a conversion to your representation for the base, then back when you're done, because this form is just really slow everywhere else. We're not talking about the difference between O(n) and O(n^2) here, but we are talking about an expensive division instruction per limb or an expensive conversion every time you want to divide. See this.

Next up, how do you expand your division for general case division? By that, I mean when you want to divide those two numbers x and y from the above code. You can't, is the answer, without resorting to bignum-based facilities, which are expensive. See Knuth. Taking modulo a number greater than your size doesn't work.

Let me explain. Try 21979182173 mod 1099. Let's assume here for simplicity's sake that the biggest size field we can have is three digits. This is a contrived example, but the biggest field size I know if uses 128 bits using gcc extensions. Anyway, the point is, you:

21 979 182 173

Split your number into limbs. Then you take modulo and sum:

21 1000 1182 1355

It doesn't work. This is where Avi is correct, because this is a form of casting out nines, or an adaption thereof, but it doesn't work here because our fields have overflowed for a start - you're using the modulo to ensure each field stays within its limb/field size.

So what's the solution? Split your number up into a series of appropriately sized bignums? And start using bignum functions to calculate everything you need to? This is going to be much slower than any existing way of manipulating the fields directly.

Now perhaps you're only proposing this case for dividing by a limb, not a bignum, in which case it can work, but hensel division and precomputed inverses etc do to without the conversion requirement. I have no idea if this algorithm would be faster than say hensel division; it would be an interesting comparison; the problem comes with a common representation across the bignum library. The representation chosen in existing bignum libraries is for the reasons I've expanded on - it makes sense at the assembly level, where it was first done.

As a side note; you don't have to use uint32_t to represent your limbs. You use a size ideally the size of the registers of the system (say uint64_t) so that you can take advantage of assembly-optimised versions. So on a 64-bit system adc rax, rbx only sets the overflow (CF) if the result overspills 2^64 bits.

tl;dr version: the problem isn't your algorithm or idea; it's the problem of converting between bases, since the representation you need for your algorithm isn't the most efficient way to do it in add/sub/mul etc. To paraphrase knuth: This shows you the difference between mathematical elegance and computational efficiency.

share|improve this answer
    
Thanks, that's a great comment/answer! However, there are some points about base conversion in my algorithm I'd like to clarify, but I don't have the time right now, so I'll probably write something in a couple of hours, when I get back home. – mornik Feb 24 '11 at 6:04
    
I don't know if you can see any new replies to this topic, so, this is just to let you know I've posted a clarification. Sorry if I'm bothering you, but you really were very helpful. Thanks once again! – mornik Feb 24 '11 at 11:05
    
Before I take a look at your edit in more detail, I just want to clarify something - probably I've misunderstood you, but you say "how do you expand your division for general case division?". I don't. I don't claim I can do general case division. Dividing 21979182173 with 1099 would only, in my algorithm, have some sense if representation of 21979182173 in base 1100 was available to you, which is improbable. Then, the numbers below would have nothing to do with what you've written: we'd divide that representation into segments of length only 1, not 3. Now, I might be missing your point here... – mornik Feb 24 '11 at 12:37
    
@mornik Ah ok. I thought that was the case, since it becomes very difficult, but I just wanted to say it for completeness. Then, the problem becomes base conversion and your representation - it adds an expense per division that doesn't exist any other way, even if the pure division itself is faster. – user257111 Feb 24 '11 at 12:49
    
OK then. That's good to hear. Now, about your addition code - that's essentially what I had in mind. However, since (t/somebase)<2, we don't have to use explicit division or modulo: m=t-somebase. If m<0, let m=0. We're done. Of course, then we couldn't use uint32_t, but int32_t. Would this help or bring more trouble? (Also, one way or the other, note I have only three additions in each step of for loop and that two of them can be considered almost always trivial: I just add 1, so, in all except very rare cases the addition will stop after the first one, perhaps two or three, limbs.) – mornik Feb 24 '11 at 13:20

Your Answer

 
discard

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.