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Let's say I want to calculate the following:

A/Z

Where A is of length 128 bit and Z is 64 bit long. A is stored in 2 64 bit registers since the registers of the system can store up to 64 bits. What would be an efficient way to calculate the result?

P.S: I've solved similar multiplication problems by using CSD representations. However, this would require calculating 1/Z first.

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What sort of operations are allowed to be used? –  harold Oct 14 '13 at 9:29
    
I'm open to all suggestions. But I would prefer a solution that would stick to adding, subtracting an shifting. –  hhachem Oct 14 '13 at 9:32
    
So something like Restoring Division? –  harold Oct 14 '13 at 9:44
1  
See this question –  Antti Huima Oct 14 '13 at 9:53
    
@AnttiHuima Thanks. That helps a lot. Currently checking the hacker's delight multiword division. –  hhachem Oct 14 '13 at 10:03

2 Answers 2

up vote 0 down vote accepted

The right way to solve such a problem, is by returning to the basics:

  • divide the most significant register by the denominator
  • calculate the quotient Q and the rest R
  • define a new temporary register preferrably with the same length as the other 2
  • the rest should occupy the most significant bits in the temporary register
  • shift the lesser significant register to the right by the same amount of bits contained iR and add to the result to the temporary register.
  • go back to step 1

after the division, the resulting rest must be casted to double, divided by the denominator then added to the quotient.

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I assume you want integer division so here is the math:

A = { a0 + (a1<<64) }
D = { d0 + (d1<<64) } ... division result
Z = { z0 }

D = A/Z 
D = (a0 + (a1<<64))/z0 
D = (a0/z0) + ((a1<<64)/z0)
D = (a0/z0) + ((a1/z0)<<64) + (((a1%z0)<<64)/z0)
d0 = (a0/z0) + (((a1%z0)<<64)/z0)
d1 = a1/z1 + d0>>64 
d0&=0xFFFFFFFFFFFFFFFF

and some 'C++' code:

ALU32 alu;
DWORD a1=0x12345678,a0=0x9ABCDEF0,d0,d1,z0=0x23,i;
// D = 0085270A C297AE99 R = 5
if (z0>=2)
    {
    d1=a1/z0; d0=a0/z0;
    a1=a1%z0; a0=a0%z0;
    if (a1)
        {
        i= (0xFFFFFFFF/z0)   *a1;
        alu.add(d0,d0,i); // addition with carry
        alu.adc(d1,d1,0);
        i=((0xFFFFFFFF%z0)+1)*a1;
        a0+=i; i=a0/z0; a0%=z0;
        alu.add(d0,d0,i); // addition with carry
        alu.adc(d1,d1,0);
        }
    }

Notes:

  • this is only 32 bit
  • to convert it to 64 bit just change 0xFFFFFFFF to 0xFFFFFFFFFFFFFFFF and DWORDs to your data type
  • ALU32 is just my class for basic 32bit operations with carry
  • I assume you are doing it in asm so you use CPU carry instead :)
  • division result is in d0,d1
  • remainder result is in a0
  • code does not handle negative values and division by 0,1 ... add ifs to handle it
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(a0/z0) + ((a1<<64)/z0) this won't work, because dividing the most significant byte by a constant might deliver an irrational number. Let's say a1=1 and z0=3, then a1/z0 = 0.333333333--- , in this case no matter how many times you shift this number, you will always end up with the wrong answer. Check my answer below –  hhachem Oct 18 '13 at 10:54
    
My approach is 100% working and tested ... for unsigned integers. No issues at all... if it should handle fractional parts then it should be mentioned somewhere (for example floating/fixed point division and not that values are 128-bit and in 64-bit registers which usually implies integer arithmetics) –  Spektre Oct 18 '13 at 19:34
    
have it tested on 8+8/8 bit , 16+16/16 bit all combinations without any errors,... and it uses only 3 half bits divisions and 2 full bits (or 4 half bits) additions no loops as you can see –  Spektre Oct 18 '13 at 19:40

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