# Division with really big numbers

I was just wondering what different strategies there are for division when dealing with big numbers. By big numbers, I mean ~50 digit numbers .

e.g. 9237639100273856744937827364095876289200667937278 / 8263744826271827396629934467882946252671

When both numbers are big, long division seems to lose its usefulness...

I thought one possibility is to count through multiplications of the divisor until you go over the dividend, but if it was the dividend in the example above divided by a small number, e.g. 4, then that's a huge amount of calculations to do.

So, is there simple, clean way to do this?

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You could just use Python (1117851445), or you could be more specific about the context in which you want to solve this. –  Marcelo Cantos Sep 2 '12 at 6:45
If you're interested in division algorithms, several approaches are covered in Modern Computer Arithmetic, which is free to download. I'll admit it can be a little slow going, but there's lots of good information there. –  DSM Sep 2 '12 at 6:54

What language / platform do you use? This is most likely already solved, so you don't need to implement it from scratch. E.g. Haskell has the `Integer` type, Java the `java.math.BigInteger` class, .NET the `System.Numerics.BigInteger` structure, etc.

If your question is really a theoretical one, I suggest you read Knuth, The Art of Computer Programming, Volume 2, Section 4.3.1. What you are looking for is called "Algorithm D" there. Here is a C implementation of that algorithm along with a short explanation: http://hackers-delight.org.ua/059.htm

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I'm using Obj-c but I'm trying to create my own implementation, instead of using pre-existing ones Thanks for the reference to Knuth, do you know if there is a way to read that section online, or do I need to go to a library? –  Mirror318 Sep 2 '12 at 7:22
You might get lucky on Google books (in my edition of the book the algorithm starts on page 273). But if you just search for: -- kunth division "algorithm d" -- you will find some examples and explanations like the one in my link above. –  Tilo Sep 2 '12 at 7:30
On a second thought: If you have never read Knuth, look on the web first. For example Kunth uses Pseudo Assembly instead of the Pseudocode you are used to from other algorithm books. –  Tilo Sep 2 '12 at 7:33
thanks for the help :) –  Mirror318 Sep 2 '12 at 12:09

Long division is not very complicated if you are working with binary representations of your numbers and probably the most efficient algorithm.

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if you don't need very exact result, you can use logarithms and exponents. Exponent is the function f(x)=e^x, where e is a mathmaticall constant equal to 2.71828182845...
Logarithm (marked by ln) is the inverse of the exponent.

Since ln(a/b)=ln(a)-ln(b), to calculate a/b you need to:
Calculate ln(a) and ln(b) [By library function, logarithm table or other methods]
substruct them: temp=ln(a)-lb(b)
calculate the exponent e^temp

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I need an exact result :\ Although I can chop off decimals/remainders, but I need the exact number rounded down to the nearest integer –  Mirror318 Sep 2 '12 at 7:04
Whell, mathmatically it is exact, buy the problem is that ln(a) abd ln(b) have to be rounded. –  LeeNeverGup Sep 2 '12 at 7:10
In your example, the real result is 1117851445. ln(a) is near 112.747, and ln(b) is near 91.912. e^the difference gives 1118215558. The same process with 5 digits after point gives 1117857786, and with 9 digits after point gives the real result. –  LeeNeverGup Sep 2 '12 at 7:21