# Algorithm for dividing very large numbers

I need to write an algorithm(I cannot use any 3rd party library, because this is an assignment) to divide(integer division, floating parts are not important) very large numbers like 100 - 1000 digits. I found http://en.wikipedia.org/wiki/Fourier_division algorithm but I don't know if it's the right way to go. Do you have any suggestions?

``````1) check divisior < dividend, otherwise it's zero (because it will be an int division)
2) start from the left
3) get equal portion of digits from the dividend
4) if it's divisor portion is still bigger, increment digits of dividend portion by 1
5) multiply divisor by 1-9 through the loop
6) when it exceeds the dividend portion, previous multiplier is the answer
7) repeat steps 3 to 5 until reaching to the end
``````
• "because this is an assignment"... Add the homework tag? May 21, 2010 at 17:28
• If you can do long division on paper, you already know a good algorithm to solve this problem. May 21, 2010 at 17:31
• @Neil: Well, I'm not expecting to receive a code sample. I'm just expecting to learn some math techniques to go beyond these language limitations. May 21, 2010 at 17:35
• @pocoa: then you should add the homework tag. The tag denotes that you want help/ideas/advice, but you don't want the work done for you. May 21, 2010 at 17:37
• @Carl: I think it's not that easy when you need to divide a 120 digits number with 75 :) This is why I'm asking. May 21, 2010 at 17:38

I'd imagine that dividing the 'long' way like in grade school would be a potential route. I'm assuming you are receiving the original number as a string, so what you do is parse each digit. Example:

Step 0:

``````   /-----------------
13 | 453453453435....
``````

Step 1: "How many times does 13 go into 4? 0

``````     0
/-----------------
13 | 453453453435....
``````

Step 2: "How many times does 13 go into 45? 3

``````     03
/-----------------
13 | 453453453435....
- 39
--
6
``````

Step 3: "How many times does 13 go into 63? 4

etc etc. With this strategy, you can have any number length and only really have to hold enough digits in memory for an int (divisor) and double (dividend). (Assuming I got those terms right). You store the result as the last digit in your result string.

When you hit a point where no digits remain and the calculation wont go in 1 or more times, you return your result, which is already formatted as a string (because it could be potentially larger than an int).

• A long time ago I was reading the source to a MP library (gmplib.org I think). It used this approach for "mid sized" numbers (bigger than long, smaller that about 30 bytes), then switched to Fourier division for very large number. I would be interesting to see if that is still the approach used. May 21, 2010 at 17:53
• @rschuler: So Fourier Division Algorithm can solve this problem, right? May 21, 2010 at 18:08
• Your solution is only useful for small divisors. It's much more complicated when the divisor is also a big number. May 22, 2010 at 5:17

The easiest division algorithm to implement for large numbers is shift and subtract.

``````if numerator is less than denominator then finish
shift denominator as far left as possible while it is still smaller than numerator
set bit in quotient for amount shifted
subtract shifted denominator from numerator
repeat
the numerator is now the remainder
``````

The shifting need not be literal. For example, you can write an algorithm to subtract a left shifted value from another value, instead of actually shifting the whole value left before subtracting. The same goes for comparison.

Long division is difficult to implement because one of the steps in long division is long division. If the divisor is an int, then you can do long division fairly easily.

Knuth, Donald, The Art of Computer Programming, ISBN 0-201-89684-2, Volume 2: Seminumerical Algorithms, Section 4.3.1: The Classical Algorithms

• Google for it; you will find lots of papers on line with "improvements" to the algorithm that Knuth so venerably documents. May 21, 2010 at 18:45
• @pocoa, you really should get it from your school's library, it's an excellent book. May 21, 2010 at 19:10
• Does anyone happen to have a 1 to 1 naive but working implementation in a C like language of Knuth's algorithm D? I am confused by multiple steps like D1 introduction of new digit u_(m+n) which should be set to 0 if d = 1, but else? In step D4 is it if any digit is < 0 that I should add the b^(n+1) to all digits? The borrow I am adding to left, should that be a 1? Also my brain has troubles replacing u. D6 why is there a 0 multiplied to v_(n-1)? I am fully aware that I am simply too deft to understand him. I found skanthak.homepage.t-online.de/division.html but many optimizations etc. Apr 13, 2020 at 9:50

You should probably try something like long division, but using computer words instead of digits.

In a high-level language, it will be most convenient to consider your "digit" to be half the size of your largest fixed-precision integer. For the long division method, you will need to handle the case where your partial intermediate result may be off by one, since your fixed-precision division can only handle the most-significant part of your arbitrary-precision divisor.

There are faster and more complicated means of doing arbitrary-precision arithmetic. Check out the appropriate wikipedia page. In particular, the Newton-Raphson method, when implemented carefully, can ensure that the time performance of your division is within a constant factor of your arbitrary-precision multiplication.

Unless part of your assignment was to be completely original, I would go with the algorithm I (and I assume you) were taught in grade school for doing large division by hand.

• Yeah, if I cannot find a better algorithm, I'll implement my own :) May 21, 2010 at 18:06
• Set a limit to the time you spend searching for a "better" algorithm. Implement the grade school algorithm while you wait for answers. :-) May 21, 2010 at 18:11
• @Thomas: Ahahaha.. Maybe this should be the answer! :)) Thanks for reminding! May 21, 2010 at 18:15