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What is the most efficient way to cacluate the closest power of a 2 or 10 to another number? e.g.

3.5 would return 4 for power of 2 and 1 for power of 10

123 would return 128 for power of 2 and 100 for power of 10

0.24 would return 0.25 for power of 2 and 0.1 for power of 10

I'm just looking for the algorithm and don't mind the language.

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I would think that 3.5 ought to be closer to 2^2 than 2^1 –  EvilTeach Nov 5 '08 at 1:10
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Similarly, 10^0 = 1 should be closer to 3.5 than 10^1 = 10. –  Adam Liss Nov 5 '08 at 1:12
    
Thanks EvilTeach - I've corrected that. Adam - I'm not sure your comment is correct, but thanks anyway –  Nick Randell Nov 5 '08 at 1:15
    
@Nick, I myself am sure that Adam's comment is correct. –  Daniel Daranas Apr 23 '09 at 14:19
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5 Answers

up vote 24 down vote accepted
n^round(log_n(x))

where log_n is the logarithm to base n. You may have to modify the round() depending on how you define "closest".

Note that log_n(x) can be implemented as:

log_n(x) = log(x) / log(n)

where log is a logarithm to any convenient base.

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In many popular languages n^x will return the bitwise exclusive or of n and x. –  Wedge Nov 5 '08 at 1:46
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Wedge: Yes, of course. I am using mathematical notation (within the bounds of ASCII) rather than a specific programming language. –  Greg Hewgill Nov 5 '08 at 3:45
    
Normal rounding to the nearest integer gives 10^n [or 2^n] for values >= 10^(n-0.5) [or 2^(n-0.5)]. I assume that's what you mean by "depending on how you define closest" –  Matthew Crumley Nov 23 '08 at 2:56
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For power of 2 on integers, there is a smart trick that consist of copying the last bit over and over to the right. Then, you only have to increment your number and you have your power of 2.

int NextPowerOf2(int n)
{
   n |= (n >> 16);
   n |= (n >> 8);
   n |= (n >> 4);
   n |= (n >> 2);
   n |= (n >> 1);
   ++n;
   return n;
}
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Note that this algorithm is for 32 bits. It also raises powers of two to the next value (for example, 4 will give 8). To change the bitness, add or remove terms so that the first term is half of the number of bits you have. To keep power of twos as is, simply subtract one at the beginning. –  Kevin Cox Feb 9 at 23:24
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For power of 2 and >= 1 you can see how many times you can bit shift right. For each time this is 1 extra power of 2 you are taking away. Once you get down to 0 you have your number.

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I think that I might approach the problem, but using log base 2 and log base 10.

log10 of (123) is 2.something. take the floor of that then raise 10 to that power, and that ought to get you close.

the same thing ought to work with log base 2.

log2 of (9) is 3.something take the floor of that then raise to to that power

you might play with rounding of the log.

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You may have to modify the round() depending on how you define "closest".

@Greg Hewgill's answer is correct except it rounds up too early for the examples you gave. For example, 10^round(log_10(3.5)) == 10, not 1. I'm assuming that's what he means by 'how you define "closest"'.

Probably the simplest way to use Greg's formula and if it's too high (or too low for x < 1), use the next lower power of two:

closest = n ^ round(log_n(x))

if (closest > x) {
    other = closest / n
} else {
    other = closest * n
}

if (abs(other - x) < abs(closest - x)) {
    return other
} else {
    return closest
}
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