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I use the following function to calculate log base 2 for integers:

public static int log2(int n){
    if(n <= 0) throw new IllegalArgumentException();
    return 31 - Integer.numberOfLeadingZeros(n);

Does it have optimal performance?

Does someone know ready J2SE API function for that purpose?

UPD1 Surprisingly for me, float point arithmetics appears to be faster than integer arithmetics.

UPD2 Due to comments I will conduct more detailed investigation.

UPD3 My integer arithmetic function is 10 times faster than Math.log(n)/Math.log(2).

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How did you test the performance of this? On my System (Core i7, jdk 1.6 x64) the integer version is almost 10 times faster than the floating point version. Be sure to actually do something with the result of the function so that the JIT can't remove the calculation entirely! – x4u Jul 22 '10 at 3:57
You are correct. I did not use results of calculation and compiler have optimized something. Now I have the same result as you - integer function is 10 times faster (Core 2 Duo, jdk 1.6 c64) – Nulldevice Jul 22 '10 at 5:03
up vote 34 down vote accepted

If you are thinking about using floating-point to help with integer arithmetics, you have to be careful.

I usually try to avoid FP calculations whenever possible.

Floating-point operations are not exact. You can never know for sure what will (int)(Math.log(65536)/Math.log(2)) evaluate to. For example, Math.ceil(Math.log(1<<29) / Math.log(2)) is 30 on my PC where mathematically it should be exactly 29. I didn't find a value for x where (int)(Math.log(x)/Math.log(2)) fails (just because there are only 32 "dangerous" values), but it does not mean that it will work the same way on any PC.

The usual trick here is using "epsilon" when rounding. Like (int)(Math.log(x)/Math.log(2)+1e-10) should never fail. The choice of this "epsilon" is not a trivial task.

More demonstration, using a more general task - trying to implement int log(int x, int base):

The testing code:

static int pow(int base, int power) {
    int result = 1;
    for (int i = 0; i < power; i++)
        result *= base;
    return result;

private static void test(int base, int pow) {
    int x = pow(base, pow);
    if (pow != log(x, base))
        System.out.println(String.format("error at %d^%d", base, pow));
    if(pow!=0 && (pow-1) != log(x-1, base))
        System.out.println(String.format("error at %d^%d-1", base, pow));

public static void main(String[] args) {
    for (int base = 2; base < 500; base++) {
        int maxPow = (int) (Math.log(Integer.MAX_VALUE) / Math.log(base));
        for (int pow = 0; pow <= maxPow; pow++) {
            test(base, pow);

If we use the most straight-forward implementation of logarithm,

static int log(int x, int base)
    return (int) (Math.log(x) / Math.log(base));

this prints:

error at 3^5
error at 3^10
error at 3^13
error at 3^15
error at 3^17
error at 9^5
error at 10^3
error at 10^6
error at 10^9
error at 11^7
error at 12^7

To completely get rid of errors I had to add epsilon which is between 1e-11 and 1e-14. Could you have told this before testing? I definitely could not.

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"it does not mean that it will work the same way on any PC" -- It would if you used strictfp, no? – Ken Jul 22 '10 at 5:14
@Ken: Maybe... But you can only be sure after exhaustively enumerating all the possible input values. (we are lucky there are so few of them here) – Rotsor Jul 22 '10 at 11:01
Technically, yes, but that's true of any function. At some point you have to trust that if you use the available documentation, and test some well-chosen but vanishingly small fraction of "all possible input values", that your program will work well enough. strictfp seems to have actually gotten a lot of crap for being, in fact, strict. :-) – Ken Jul 25 '10 at 18:31
Why the downvote? – Rotsor May 28 '11 at 4:03

This is the function that I use for this calculation:

public static int binlog( int bits ) // returns 0 for bits=0
    int log = 0;
    if( ( bits & 0xffff0000 ) != 0 ) { bits >>>= 16; log = 16; }
    if( bits >= 256 ) { bits >>>= 8; log += 8; }
    if( bits >= 16  ) { bits >>>= 4; log += 4; }
    if( bits >= 4   ) { bits >>>= 2; log += 2; }
    return log + ( bits >>> 1 );

It is slightly faster than Integer.numberOfLeadingZeros() (20-30%) and almost 10 times faster (jdk 1.6 x64) than a Math.log() based implementation like this one:

private static final double log2div = 1.000000000001 / Math.log( 2 );
public static int log2fp0( int bits )
    if( bits == 0 )
        return 0; // or throw exception
    return (int) ( Math.log( bits & 0xffffffffL ) * log2div );

Both functions return the same results for all possible input values.

Update: The Java 1.7 server JIT is able to replace a few static math functions with alternative implementations based on CPU intrinsics. One of those functions is Integer.numberOfLeadingZeros(). So with a 1.7 or newer server VM, a implementation like the one in the question is actually slightly faster than the binlog above. Unfortunatly the client JIT doesn't seem to have this optimization.

public static int log2nlz( int bits )
    if( bits == 0 )
        return 0; // or throw exception
    return 31 - Integer.numberOfLeadingZeros( bits );

This implementation also returns the same results for all 2^32 possible input values as the the other two implementations I posted above.

Here are the actual runtimes on my PC (Sandy Bridge i7):

JDK 1.7 32 Bits client VM:

binlog:         11.5s
log2nlz:        16.5s
log2fp:        118.1s
log(x)/log(2): 165.0s

JDK 1.7 x64 server VM:

binlog:          5.8s
log2nlz:         5.1s
log2fp:         89.5s
log(x)/log(2): 108.1s

This is the test code:

int sum = 0, x = 0;
long time = System.nanoTime();
do sum += log2nlz( x ); while( ++x != 0 );
time = System.nanoTime() - time;
System.out.println( "time=" + time / 1000000L / 1000.0 + "s -> " + sum );
share|improve this answer
x86's BSR instruction does 32 - numberOfLeadingZeros, but undefined for 0, so a (JIT) compiler has to check for non-zero if it can't prove it doesn't have to. The BMI instruction set extensions (Haswell and newer) introduced LZCNT, which fully implements numberOfLeadingZeros exactly, in a single instruction. They're both 3 cycle latency, 1 per cycle throughput. So I'd absolutely recommend using numberOfLeadingZeros, because that makes it easy for a good JVM. (The one weird thing about lzcnt is that it has a false dependency on the old value of the register it overwrites.) – Peter Cordes Sep 15 '15 at 16:14

you can use the identity

 log[b]x = ---------

so this would be applicable for log2.

 log[2]x = ----------

just plug this into the java Math log10 method....

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Try Math.log(x) / Math.log(2)

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Why not:

public static double log2(int n)
    return (Math.log(n) / Math.log(2));
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There is the function in guava libraries:


So I suggest to use it.

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How can I add this package to my application? – Elvin Mammadov Oct 14 '15 at 5:52

let's add:

int[] fastLogs;

private void populateFastLogs(int length) {
    fastLogs = new int[length + 1];
    int counter = 0;
    int log = 0;
    int num = 1;
    fastLogs[0] = 0;
    for (int i = 1; i < fastLogs.length; i++) {
        fastLogs[i] = log;
        if (counter == num) {
            num *= 2;
            counter = 0;


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