40

Is it possible to divide an unsigned integer by 10 by using pure bit shifts, addition, subtraction and maybe multiply? Using a processor with very limited resources and slow divide.

  • It's possible (repeated subtraction is division), but the question is whether it's any faster than the slow division. – David Thornley Apr 5 '11 at 21:07
  • @esnyder. Sorry, I can't understand you. Are you talking in base 17 or base 22? – Thomas O Apr 5 '11 at 21:39
  • Base large two. Shifting right divides by 2^n which would solve your question if by "10" you mean 16 decimal or 10h. – tamarintech Apr 5 '11 at 21:42
  • Are you arguing with me? I'm actually trying to admit that I failed to mention my answer was not for decimal.... Might be a bit obscure, but that was my intention. – tamarintech Apr 5 '11 at 21:57
  • @Thomas O - see my comment. I don't notice an upvote.... – KevinDTimm Apr 5 '11 at 22:26
55

Here's what the Microsoft compiler does when compiling divisions by small integral constants. Assume a 32-bit machine (code can be adjusted accordingly):

int32_t div10(int32_t dividend)
{
    int64_t invDivisor = 0x1999999A;
    return (int32_t) ((invDivisor * dividend) >> 32);
}

What's going here is that we're multiplying by a close approximation of 1/10 * 2^32 and then removing the 2^32. This approach can be adapted to different divisors and different bit widths.

This works great for the ia32 architecture, since its IMUL instruction will put the 64-bit product into edx:eax, and the edx value will be the wanted value. Viz (assuming dividend is passed in eax and quotient returned in eax)

div10 proc 
    mov    edx,1999999Ah    ; load 1/10 * 2^32
    imul   eax              ; edx:eax = dividend / 10 * 2 ^32
    mov    eax,edx          ; eax = dividend / 10
    ret
    endp

Even on a machine with a slow multiply instruction, this will be faster than a software divide.

  • 12
    +1, and I'd like to emphasise that the compiler will do this for you automatically when you write "x/10" – Theran Apr 5 '11 at 21:25
  • hmm, isn't there some numerical inaccuracy here? – Jason S Apr 6 '11 at 12:49
  • 3
    You're always going to have numerical inaccuracy when doing integer divides: What do you you get when you divide 28 by 10 using integers? Answer: 2. – John Källén Apr 6 '11 at 12:52
  • 2
    There is no numerical inaccuracy in integer division, the result is exactly specified. However, the formula above is only exact for certain divisors. Even 10 is inaccurate if you want to do unsigned arithmetic: 4294967219 / 10 = 429496721, but 4294967219 * div >> 32 = 429496722 For larger divisors, the signed version will be inaccurate as well. – Evan Jul 3 '17 at 22:12
  • 1
    @Theran: No, compilers including MSVC will compile x/10 to a fixed-point multiplicative inverse (and make extra code to handle negative inputs for signed division) to give the correct answer for all possible 32-bit inputs. For unsigned division by 10, MSVC (and other compilers) (godbolt.org/g/aAq7jx) will multiply by 0xcccccccd and right-shift the high half by 3. – Peter Cordes Oct 18 '17 at 21:07
30

Though the answers given so far match the actual question, they do not match the title. So here's a solution heavily inspired by Hacker's Delight that really uses only bit shifts.

unsigned divu10(unsigned n) {
    unsigned q, r;
    q = (n >> 1) + (n >> 2);
    q = q + (q >> 4);
    q = q + (q >> 8);
    q = q + (q >> 16);
    q = q >> 3;
    r = n - (((q << 2) + q) << 1);
    return q + (r > 9);
}

I think that this is the best solution for architectures that lack a multiply instruction.

15

Of course you can if you can live with some loss in precision. If you know the value range of your input values you can come up with a bit shift and a multiplication which is exact. Some examples how you can divide by 10, 60, ... like it is described in this blog to format time the fastest way possible.

temp = (ms * 205) >> 11;  // 205/2048 is nearly the same as /10
  • 3
    You have to be aware that the intermediate value (ms * 205) can overflow. – Paul R Apr 5 '11 at 21:16
  • 2
    If you do int ms = 205 * (i >> 11); you will get wrong values if the numbers are small. You need a test suite to ensure that in a given value range the results are correct. – Alois Kraus Apr 5 '11 at 21:28
  • 2
    this is accurate for ms = 0..1028 – robert king Oct 18 '14 at 1:14
  • Why 205 specifically? – ernesto Nov 26 '17 at 11:01
  • 1
    @ernesto >> 11 is a division of 2048. When you want to divide by ten you need to divide that by 2048/10 which is 204,8 or 205 as closest integer number. – Alois Kraus Nov 26 '17 at 20:57
3

Considering Kuba Ober’s response, there is another one in the same vein. It uses iterative approximation of the result, but I wouldn’t expect any surprising performances.

Let say we have to find x where x = v / 10.

We’ll use the inverse operation v = x * 10 because it has the nice property that when x = a + b, then x * 10 = a * 10 + b * 10.

Let use x as variable holding the best approximation of result so far. When the search ends, x Will hold the result. We’ll set each bit b of x from the most significant to the less significant, one by one, end compare (x + b) * 10 with v. If its smaller or equal to v, then the bit b is set in x. To test the next bit, we simply shift b one position to the right (divide by two).

We can avoid the multiplication by 10 by holding x * 10 and b * 10 in other variables.

This yields the following algorithm to divide v by 10.

uin16_t x = 0, x10 = 0, b = 0x1000, b10 = 0xA000;
while (b != 0) {
    uint16_t t = x10 + b10;
    if (t <= v) {
        x10 = t;
        x |= b;
    }
    b10 >>= 1;
    b >>= 1;
}
// x = v / 10

Edit: to get the algorithm of Kuba Ober which avoids the need of variable x10 , we can subtract b10 from v and v10 instead. In this case x10 isn’t needed anymore. The algorithm becomes

uin16_t x = 0, b = 0x1000, b10 = 0xA000;
while (b != 0) {
    if (b10 <= v) {
        v -= b10;
        x |= b;
    }
    b10 >>= 1;
    b >>= 1;
}
// x = v / 10

The loop may be unwinded and the different values of b and b10 may be precomputed as constants.

2

Well division is subtraction, so yes. Shift right by 1 (divide by 2). Now subtract 5 from the result, counting the number of times you do the subtraction until the value is less than 5. The result is number of subtractions you did. Oh, and dividing is probably going to be faster.

A hybrid strategy of shift right then divide by 5 using the normal division might get you a performance improvement if the logic in the divider doesn't already do this for you.

2

On architectures that can only shift one place at a time, a series of explicit comparisons against decreasing powers of two multiplied by 10 might work better than the solution form hacker's delight. Assuming a 16 bit dividend:

uint16_t div10(uint16_t dividend) {
  uint16_t quotient = 0;
  #define div10_step(n) \
    do { if (dividend >= (n*10)) { quotient += n; dividend -= n*10; } } while (0)
  div10_step(0x1000);
  div10_step(0x0800);
  div10_step(0x0400);
  div10_step(0x0200);
  div10_step(0x0100);
  div10_step(0x0080);
  div10_step(0x0040);
  div10_step(0x0020);
  div10_step(0x0010);
  div10_step(0x0008);
  div10_step(0x0004);
  div10_step(0x0002);
  div10_step(0x0001);
  #undef div10_step
  if (dividend >= 5) ++quotient; // round the result (optional)
  return quotient;
}
  • Your code performs 16 multiplication by 10. Why do you think your code is faster than hacker’s delight ? – chmike Oct 7 '17 at 20:11
  • It doesn't matter what I think. What matters is whether at the applicable platform it is faster. Try yourself! There's no universally fastest solution here at all. Every solution has some platform in mind, and will work best on that platform, possibly better than any other solution. – Kuba Ober Oct 18 '17 at 16:09
  • I didn’t notice that n*10 is constant. It will thus be precomputed by the compiler. I provided an alternate algorithm in an answer. Our algorithm are equivalent except for one difference. You subtract b*10 from v and I add it to x*10. Your algorithm doesn’t need to keep track of x*10 which saves a variable. The code you show unrolls the my while loop. – chmike Oct 18 '17 at 19:10
  • @chmike: On a machine without hardware multiply, n*10 is still cheap: (n<<3) + (n<<1). These small-shift answers could maybe be useful on machines with slow or non-existent HW multiply, and only a shift by 1. Otherwise a fixed-point inverse is much better for compile-time constant divisors (like modern compilers do for x/10). – Peter Cordes Oct 18 '17 at 21:17
2

to expand Alois's answer a bit, we can expand the suggested y = (x * 205) >> 11 for a few more multiples/shifts:

y = (ms *        1) >>  3 // first error 8
y = (ms *        2) >>  4 // 8
y = (ms *        4) >>  5 // 8
y = (ms *        7) >>  6 // 19
y = (ms *       13) >>  7 // 69
y = (ms *       26) >>  8 // 69
y = (ms *       52) >>  9 // 69
y = (ms *      103) >> 10 // 179
y = (ms *      205) >> 11 // 1029
y = (ms *      410) >> 12 // 1029
y = (ms *      820) >> 13 // 1029
y = (ms *     1639) >> 14 // 2739
y = (ms *     3277) >> 15 // 16389
y = (ms *     6554) >> 16 // 16389
y = (ms *    13108) >> 17 // 16389
y = (ms *    26215) >> 18 // 43699
y = (ms *    52429) >> 19 // 262149
y = (ms *   104858) >> 20 // 262149
y = (ms *   209716) >> 21 // 262149
y = (ms *   419431) >> 22 // 699059
y = (ms *   838861) >> 23 // 4194309
y = (ms *  1677722) >> 24 // 4194309
y = (ms *  3355444) >> 25 // 4194309
y = (ms *  6710887) >> 26 // 11184819
y = (ms * 13421773) >> 27 // 67108869

each line is a single, independent, calculation, and you'll see your first "error"/incorrect result at the value shown in the comment. you're generally better off taking the smallest shift for a given error value as this will minimise the extra bits needed to store the intermediate value in the calculation, e.g. (x * 13) >> 7 is "better" than (x * 52) >> 9 as it needs two less bits of overhead, while both start to give wrong answers above 68.

if you want to calculate more of these, the following (Python) code can be used:

def mul_from_shift(shift):
    mid = 2**shift + 5.
    return int(round(mid / 10.))

and I did the obvious thing for calculating when this approximation starts to go wrong with:

def first_err(mul, shift):
    i = 1
    while True:
        y = (i * mul) >> shift
        if y != i // 10:
            return i
        i += 1

(note that // is used for "integer" division, i.e. it truncates/rounds towards zero)

the reason for the "3/1" pattern in errors (i.e. 8 repeats 3 times followed by 9) seems to be due to the change in bases, i.e. log2(10) is ~3.32. if we plot the errors we get the following:

errors

where the relative error is given by: mul_from_shift(shift) / (1<<shift) - 0.1

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