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I'm trying to write a function to return the number of bits a positive integer less that the Javascript limit of (2^53)-1 is. However im being hit by precision problems, and want to avoid big integer libraries.

Method 1:

function bitSize(num)
{
return Math.floor( Math.log(num) / Math.log(2) ) + 1;
}

Pass: bitSize( Math.pow(2, 16) -1 ) = 16
Pass: bitSize( Math.pow(2, 16) ) = 17
Fail (Should be 48): bitSize( Math.pow(2, 48) -1 ) = 49 
Pass: bitSize( Math.pow(2, 48) ) = 49

Method 2:

function bitSize(num)
{
var count = 0;
while(num > 0)
{
    num = num >> 1;
    count++;
}
return count;
}

Pass: bitSize( Math.pow(2, 16) -1 ) = 16
Pass: bitSize( Math.pow(2, 16) ) = 17
Fail (Should be 48): bitSize( Math.pow(2, 48) -1 ) = 1
Fail (Should be 49): bitSize( Math.pow(2, 48) ) = 1

Both methods fail to precision issues I think.

Can anyone suggest an alternative method that will work for numbers between 0 -> 2^53-1

Thanks.

share|improve this question
    
See also stackoverflow.com/questions/680002/… – hippietrail Apr 17 '11 at 9:54
up vote 6 down vote accepted

You can do:

function bitSize(num) {
    return num.toString(2).length;
}

The toString() method of Number takes the radix as an optional argument.

Here are some tests. Works on Chrome, Safari, Opera, and Firefox. No access to IE, sorry.

share|improve this answer

Bitwise operations will only work reliably in Javascript for "integers" up to 32-bits. To quote from The Complete JavaScript Number Reference:

Bitwise operations are a bit of a hack in Javascript. Since all numbers in Javascript are floating point, and bitwise operators only work on integers, Javascript does a little behind the scenes magic to make it appear bitwise operations are being applied to a 32bit signed integer.

Specifically, Javascript takes the number you are working on and takes the integer portion of the number. It then converts the integer to the most number of bits that number represents, up to 31 bits (1 bit for the sign). So 0 would create a two bit number (1 for the sign, and 1 bit for 0), likewise 1 would create two bits. 2 would create a 3 bit number, 4 would create a 4 bit number, etc…

It's important to realize that you're not guaranteed a 32bit number, for instance running not on zero should, in theory, convert 0 to 4,294,967,295, instead it will return -1 for two reasons, the first being that all numbers are signed in Javascript so "not" always reverses the sign, and second Javascript couldn't make more than one bit from the number zero and not zero becomes one. Therefore ~0=-1.

So bitwise signs in Javascript are up to 32 bits.

As Anurag notes, you should simply use the built-in num.toString(2) in this situation instead, which outputs a minimal length string of ASCII '1's and '0's, which you can simply take the length of.

share|improve this answer
1  
That third paragraph is kinda silly. I don't know how the numbers are actually stored in a ~0 operation, but -1 still makes complete sense even if it's stored in 32 bits. 0 == 0x00000000 and ~0 == 0xFFFFFFFF (all bits set to 1). As a signed 32-bit integer, 0xFFFFFFFF == -1 using two's complement. – robyoder Apr 23 at 7:28

Build a lookup table with the respective boundaries where bits change. You could do this for larger values only and still do smaller ones through the logarithm. It seems to be generally floating-point-related as I can reproduce it in PowerShell here as well.

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The ES6 standard brings Math.clz32(), so for numbers in the range of 32 bits you can write:

num_bits = 32 - Math.clz32(0b1000000);   

Test it in this snippet:

var input = document.querySelector('input');
var bits = document.querySelector('#bits');

input.oninput = function() {
    var num = parseInt(input.value);
    bits.textContent = 32 - Math.clz32(num);
};
Number (Decimal): <input type="text"><br>
Number of bits: <span id="bits"></span>

On MDN's documentation of Math.clz32 a polyfill is provided:

Math.imul = Math.imul || function(a, b) {
  var ah = (a >>> 16) & 0xffff;
  var al = a & 0xffff;
  var bh = (b >>> 16) & 0xffff;
  var bl = b & 0xffff;
  // the shift by 0 fixes the sign on the high part
  // the final |0 converts the unsigned value into a signed value
  return ((al * bl) + (((ah * bl + al * bh) << 16) >>> 0)|0);
};

Math.clz32 = Math.clz32 || (function () {
  'use strict';

  var table = [
    32, 31,  0, 16,  0, 30,  3,  0, 15,  0,  0,  0, 29, 10,  2,  0,
     0,  0, 12, 14, 21,  0, 19,  0,  0, 28,  0, 25,  0,  9,  1,  0,
    17,  0,  4,   ,  0,  0, 11,  0, 13, 22, 20,  0, 26,  0,  0, 18,
     5,  0,  0, 23,  0, 27,  0,  6,  0, 24,  7,  0,  8,  0,  0,  0]

  // Adapted from an algorithm in Hacker's Delight, page 103.
  return function (x) {
    // Note that the variables may not necessarily be the same.

    // 1. Let n = ToUint32(x).
    var v = Number(x) >>> 0

    // 2. Let p be the number of leading zero bits in the 32-bit binary representation of n.
    v |= v >>> 1
    v |= v >>> 2
    v |= v >>> 4
    v |= v >>> 8
    v |= v >>> 16
    v = table[Math.imul(v, 0x06EB14F9) >>> 26]

    // Return p.
    return v
  }
})();

document.body.textContent = 32 - Math.clz32(0b1000000);

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