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I've created an algorithm for dividing a integer up to 255 bytes in size by an 8 bit integer and it works with the tests I've done. Does anyone have any comments for it or any improvement suggestions? Is there a better algorithm for this purpose? I don't want a bignum by bignum division algorithm, the second integer is an 8 bit integer.

Best solution so far (small endian):

typedef struct{
    u_int8_t * data;
    u_int8_t length;
}CBBigInt;
void CBBigIntEqualsDivisionByUInt8(CBBigInt * a,u_int8_t b,u_int8_t * ans){
    // base-256 long division.
    u_int16_t temp = 0;
    for (u_int8_t x = a->length-1;; x--) {
        temp <<= 8;
        temp |= a->data[x];
        ans[x] = temp / b;
        temp -= ans[x] * b;
        if (!x)
            break;
    }
    a->length -= ans[a->length-1]? 0 : 1; // If last byte is zero, adjust length.
    memmove(a->data, ans, a->length); // Done calculation. Move ans to "a".
}

Old solution with big endian:

It works by:

  1. If the divisor is a power of two, do a bit shift to the right.
  2. Else figure how much the divisor needs to be shifted left before it is larger than the dividend and make a 16 bit integer become the divisor as if it were shifted to the left. This will be used for subtraction.
  3. Set a bit corresponding to the shift amount on the answer. What was done is the amount the dividend can fit into the divisor up to a power of two was found.
  4. Take away the shifted byte from the dividend to create a remainder.
  5. Repeat from step 2 for the remainder, until the divisor is larger than the remainder. When this occurs the answer is found.

typedef struct{
    u_int8_t * data;
    u_int8_t length;
}CBBigInt;
u_int8_t CBPowerOf2Log2(u_int8_t a){
    switch (a) {
        case 1:
            return 0;
        case 2:
            return 1;
        case 4:
            return 2;
        case 8:
            return 3;
        case 16:
            return 4;
        case 32:
            return 5;
        case 64:
            return 6;
    }
    return 7;
}
u_int8_t CBFloorLog2(u_int8_t a){
    if (a < 16){
        if (a < 4) {
            if (a == 1){
                return 0;
            }
            return 1;
        }
        if (a < 8){
            return 2;
        }
        return 3;
    }
    if (a < 64){
        if (a < 32) {
            return 4;
        }
        return 5;
    }
    if (a < 128){
        return 6;
    }
    return 7;
}
void CBBigIntEqualsRightShiftByUInt8(CBBigInt * a,u_int8_t b){
    u_int8_t deadBytes = b / 8; // These bytes fall off the side.
    a->length -= deadBytes; // Reduce length of bignum by the removed bytes
    u_int8_t remainderShift = b % 8;
    if (!remainderShift) { // No more work
        return;
    }
    u_int16_t splitter;
    u_int8_t toRight = 0; // Bits taken from the left to the next byte.
    for (u_int8_t x = 0; x < a->length; x++) {
        splitter = a->data[x] << 8 - remainderShift; // Splits data in splitters between first and second byte.
        a->data[x] = splitter >> 8; // First byte in splitter is the new data.
        a->data[x] |= toRight; // Take the bits from the left
        toRight = splitter; // Second byte is the data going to the right from this byte.
    }
}
void CBBigIntEqualsDivisionByUInt8(CBBigInt * a,u_int8_t b,u_int8_t * ans){
    if (!(b & (b - 1))){
        // For powers of two, division can be done through bit shifts.
        CBBigIntEqualsRightShiftByUInt8(a,CBPowerOf2Log2(b));
        return;
    }
    // Determine how many times b will fit into a as a power of two and repeat for the remainders
    u_int8_t begin = 0; // Begining of CBBigInt in calculations
    bool continuing = true;
    u_int8_t leftMost;
    bool first = true;
    while (continuing){
        // How much does b have to be shifted by before it becomes larger than a? Complete the shift into a shiftedByte
        int16_t shiftAmount;
        u_int16_t shiftedByte;
        if (a->data[begin] > b){
            shiftAmount = CBFloorLog2(a->data[begin]/b);
            shiftedByte = b << 8 + shiftAmount;
        }else if (a->data[begin] < b){
            shiftAmount = -CBFloorLog2(b/a->data[begin]);
            shiftedByte = b << 8 + shiftAmount;
            // Shift right once again if "shiftedByte > (a->data[begin] << 8) + a->data[begin+1]" as the shifted divisor should be smaller
            if (shiftedByte > ((a->data[begin] << 8) + a->data[begin+1])){
                shiftedByte >>= 1;
                shiftAmount--; // Do not forget about changing "shiftAmount" for calculations
            }
        }else{
            shiftAmount = 0;
            shiftedByte = b << 8;
        }
        // Set bit on "ans"
        if (shiftAmount < 0){ // If "shiftAmount" is negative then the byte moves right.
            ans[begin+1] |= 1 << (8 + shiftAmount);
            if (first) leftMost = 1;
        }else{
            ans[begin] |= 1 << shiftAmount; // No movement to right byte, jsut shift bit into place.
            if (first) leftMost = 0;
        }
        first = false; // Do not set "leftMost" from here on
        // Take away the shifted byte to give the remainder
        u_int16_t sub = (a->data[begin] << 8) + a->data[begin+1] - shiftedByte;
        a->data[begin] = sub >> 8;
        if (begin != a->length - 1) 
            a->data[begin + 1] = sub; // Move second byte into next data byte if exists.
        // Move along "begin" to byte with more data
        for (u_int8_t x = begin;; x++){
            if (a->data[x]){
                if (x == a->length - 1)
                    // Last byte
                    if (a->data[x] < b){
                        // b can fit no more
                        continuing = false;
                        break;
                    }
                begin = x;
                break;
            }
            if (x == a->length - 1){
                continuing = false; // No more data
                break;
            }
        }
    }
    a->length -= leftMost; // If the first bit was onto the 2nd byte then the length is less one
    memmove(a->data, ans + leftMost, a->length); // Done calculation. Move ans to "a".
}

Thanks!

share|improve this question
1  
LOL ahem do you want us to read a bunch of complicated code without any description of how your algorithm operates on high level :-D ? –  Antti Huima May 9 '12 at 18:59
    
Sorry, didn't think it was that complicated. Hmmm.... I'll explain the steps it goes through... –  Matthew Mitchell May 9 '12 at 19:42
    
Oh no, what happened to the formatting? –  Matthew Mitchell May 9 '12 at 19:53
    
I would change the function CBFloorLog2 to a binary sort, less comparisons, less branches for longest path, –  MByD May 9 '12 at 19:57
    
Like a binary search? Good idea! –  Matthew Mitchell May 9 '12 at 20:13

1 Answer 1

up vote 2 down vote accepted

I'd describe this as "base 2 long division". A better alternative is "base 256 long division".

Here's an (untested and probably buggy) example:

typedef struct{
    u_int8_t * data;
    u_int8_t length;
} CBBigInt;


u_int8_t CBBigIntEqualsDivisionByUInt8(CBBigInt * a, u_int8_t b, u_int8_t * ans) {
    int i;
    unsigned int temp = 0;

    i = a.length;
    while(i > 0) {
       i--;
       temp <<= 8;
       temp |= a.data[i];
       ans.data[i] = temp / b;
       temp -= ans.data[i] * b;
    }
    return temp;   // Return remainder
}
share|improve this answer
    
Wow, that certainly is simpler! I'll give it a go... –  Matthew Mitchell May 9 '12 at 23:35
    
It failed all my tests. I'll post what I put... –  Matthew Mitchell May 10 '12 at 0:08
    
I changed a->length to a->length-1. Still doesn't work. –  Matthew Mitchell May 10 '12 at 1:34
    
Is your CBBigInt data in big-endian or little-endian format? I assumed little-endian.. –  Brendan May 10 '12 at 4:34
    
Thats it! I'm going to convert my bignums to little-endian (I think that is best on balance) and try again. –  Matthew Mitchell May 10 '12 at 20:07

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