Question: A good and efficient algorithm for BigInt division?
Attempted: Polynomial long division, division with ints (overflow remainder), binary long division (any good? Not sure, that's what I have in the post below), quotient guessing division (too many subtractions with large quotients).
I have been trying to code BigInt division for a while. My latest algorithm uses binary division, but I don't think that this is the best method.
So I am looking for some ideas as to what algorithms may be out there ; ).
The language I'm working in doesn't support passing items such as arrays around or various data types. I'm stuck with integers and booleans and global arrays as well as local arrays declared at the top of the function.
I'm working with a word size of 32768 for increased speed, which happens to be 2^15. Because of this, I can quickly and efficiently convert to base 2 and back, which is why I decided to try a binary division algorithm approach.
My first approach caused the remainder to overflow in some situations, but it was extremely fast. My next approach was an idea of polynomial long division. I also tried the quotient idea, although it would fail on extremely big numbers as there would be way too many subtractions involved. Overall, I think that the crappy binary division algorithm may be the best bet ; |.
Numbers get smaller towards the end of the divisor and remainder arrays. They are smaller towards the beginning of the dividend array.
The final answer is stored in binaryDividendBuffer with size binaryDividendBufferSize (quotient) and remainder with size remainderSize (remainder). This thing works with 0 bugs, but I have a feeling that it is just really bad :o.
globals private static integer array binaryDividendBuffer //division binary buffer #1 (to be divided) private static integer binaryDividendBufferSize //division binary count #1 private static integer array binaryBufferDivisor //division binary buffer #2 (to divide) private static integer binaryBufferDivisorSize //division binary count #2 endglobals
local integer currentDividendDigit = binaryDividendBufferSize //to be divided int digit count local integer tempDigit2 //temp digit 2 local integer tempDigit3 //temp digit 3 local integer array remainder //remainder local integer remainderSize = 0 //remainder count local boolean remainderLessThanDividend //is the remainder < divisor? local integer binaryBufferDividendDigitOffset //subtract -1 or 0 (shift the divisor by 1 bit for extra digit) local boolean gatheredDigits //were bits gatheredDigits? loop //gather bits equal to the length of the divisor only if the current remainder isn't equal to length of divisor and there are bits remaining set gatheredDigits = false set gatheredDigits = remainderSize != binaryBufferDivisorSize and 0 != currentDividendDigit if (gatheredDigits) then loop exitwhen remainderSize == binaryBufferDivisorSize or 0 == currentDividendDigit set currentDividendDigit = currentDividendDigit - 1 set remainder[remainderSize] = binaryDividendBuffer[currentDividendDigit] set remainderSize = remainderSize + 1 set binaryDividendBuffer[currentDividendDigit] = 0 endloop endif //if the remainder is smaller than the divisor and there are no bits left to gather, exit if (remainderSize < binaryBufferDivisorSize and 0 == currentDividendDigit) then set binaryDividendBuffer[currentDividendDigit] = 0 exitwhen true endif //compare the remainder and the divisor to see which one is greater set tempDigit2 = 0 set remainderLessThanDividend = false loop set remainderLessThanDividend = remainder[tempDigit2] < binaryBufferDivisor[tempDigit2] set tempDigit2 = tempDigit2 + 1 exitwhen tempDigit2 == binaryBufferDivisorSize or remainderLessThanDividend or remainder[tempDigit2] > binaryBufferDivisor[tempDigit2] endloop //if remainderLessThanDividend and there are bits remaining, add an additional bit //set the dividend's current bit to 0 IF bits were gatheredDigits (division taking place) //if bits weren't gatheredDigits, then setting it to 0 will set an already divided bit if (remainderLessThanDividend) then exitwhen 0 == currentDividendDigit if (gatheredDigits) then set binaryDividendBuffer[currentDividendDigit] = 0 endif set currentDividendDigit = currentDividendDigit - 1 set remainder[remainderSize] = binaryDividendBuffer[currentDividendDigit] set remainderSize = remainderSize + 1 set binaryBufferDividendDigitOffset = -1 //shift divisor's bits by 1 to account for extra digit in remainder else set binaryBufferDividendDigitOffset = 0 //don't shift as there is no extra digit in remainder endif //subtract set binaryDividendBuffer[currentDividendDigit] = 1 set tempDigit2 = remainderSize loop set tempDigit2 = tempDigit2 - 1 //if only subtract if the divisor actually has a bit to do subtracting (remainder might have 1 more bit than divisor) if (tempDigit2 + binaryBufferDividendDigitOffset > -1) then //if the remainder's current bit is remainderLessThanDividend than the divisor's bit, borrow if (remainder[tempDigit2] < binaryBufferDivisor[tempDigit2 + binaryBufferDividendDigitOffset]) then set remainder[tempDigit2 - 1] = remainder[tempDigit2 - 1] - 1 set remainder[tempDigit2] = remainder[tempDigit2] + 2 endif //subtract them set remainder[tempDigit2] = remainder[tempDigit2] - binaryBufferDivisor[tempDigit2 + binaryBufferDividendDigitOffset] endif exitwhen 0 == tempDigit2 endloop //cut out all of the 0s in front of the remainder and shift it over //000033 -> 33 //this first loop goes through all of the 0s loop exitwhen 0 != remainder[tempDigit2] or tempDigit2 == remainderSize set tempDigit2 = tempDigit2 + 1 endloop //this loop removes the 0s by shifting over if (0 < tempDigit2) then if (tempDigit2 == remainderSize) then set remainderSize = 0 set remainder = 0 else set tempDigit3 = 0 set remainderSize = remainderSize-tempDigit2 loop set remainder[tempDigit3] = remainder[tempDigit3+tempDigit2] set remainder[tempDigit3+tempDigit2] = 0 set tempDigit3 = tempDigit3 + 1 exitwhen tempDigit3 == remainderSize endloop endif endif exitwhen 0 == currentDividendDigit endloop //cut out all of the 0s in front of dividend loop exitwhen 0 != binaryDividendBuffer[binaryDividendBufferSize] set binaryDividendBufferSize = binaryDividendBufferSize - 1 endloop