How to do an integer log2() in C++?

In the C++ standard libraries I found only a floating point log method. Now I use log to find the level of an index in a binary tree ( `floor(2log(index))` ).

Code (C++):

``````int targetlevel = int(log(index)/log(2));
``````

I am afraid that for some of the edge elements (the elements with value 2^n) log will return n-1.999999999999 instead of n.0. Is this fear correct? How can I modify my statement so that it always will return a correct answer?

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I don't get the question. Why would it return n - 1,9(9)? –  sharptooth Jun 15 '09 at 5:37
Because not all integers can be stored exactly in as a floating point number. If 7 would be not fitting, it would be stored as 7.000001 or 6.999999 for example. –  Peter Smit Jun 15 '09 at 5:43
Yeap, I know that. But where has this 1,9(9) come from? Perhaps you could reformat the question using <sup></sup> for upper indices and <sub></sub> for lower indices? –  sharptooth Jun 15 '09 at 5:49
Any integer can be stored exactly in a floating-point number. However, the log() function isn't necessarily precise, and even if it is log(2) is irrational for either natural logs or base 10, so there's no reason to expect an exact result. Given that exact results can't be guaranteed, it makes sense to worry about the exact border conditions. –  David Thornley Jun 15 '09 at 14:00
You have to have pretty large integers, probably 2^exponentsize before they can't be exactly represented. If you have loss of precision in this case, it's because log(2) can't be exactly represented. Will you only ever call this method for 2^n? If so, you can round to nearest integer (or just use the accepted answer) –  erikkallen Jun 15 '09 at 14:03

You can use this method instead:

``````int targetlevel = 0;
while (index >>= 1) ++targetlevel;
``````

Note: this will modify index. If you need it unchanged, create another temporary int.

The corner case is when index is 0. You probably should check it separately and throw an exception or return an error if index == 0.

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Does the while loop evaluate 0-integers to false? –  Peter Smit Jun 15 '09 at 5:57
If index = 0, targetlevel is going to be 0. In your code it will probably cause exception. What value would you like to get for index = 0? –  Igor Krivokon Jun 15 '09 at 6:02
I mean to say, the loop has to stop when index >>= 1 evaluates to 0. I couldn't find somewhere quickly that the while loop will really stop when the expression evaluates to an integer zero. It is of course logic it will, because the bits are the same then as boolean false. –  Peter Smit Jun 15 '09 at 6:07
...actually, in your code it's not not exception - it will evaluate to minus infinity and then converted to int as maximum negative int value. –  Igor Krivokon Jun 15 '09 at 6:07
Make sure to specify `index` as `unsigned int`, otherwise you have a very dangerous potentially infinite loop bug on your hands. –  bobobobo Feb 14 '13 at 17:41

If you are on a recent-ish x86 or x86-64 platform (and you probably are), use the `bsr` instruction which will return the position of the highest set bit in an unsigned integer. It turns out that this is exactly the same as log2(). Here is a short C or C++ function that invokes `bsr` using inline ASM:

``````#include <stdint.h>
static inline uint32_t log2(const uint32_t x) {
uint32_t y;
asm ( "\tbsr %1, %0\n"
: "=r"(y)
: "r" (x)
);
return y;
}
``````
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And on ARM you'd want clz, which returns 31 minus the value you want. GCC has __builtin_clz, which presumably uses bsr on x86. –  Steve Jessop Jun 15 '09 at 11:44
That is a really great answer –  bobobobo Feb 14 '13 at 17:46
To avoid the subtraction, use `__builtin_ctz` instead. `int log2 (int x){return __builtin_ctz (x);}` It also works on x86. –  user2573802 Sep 8 '13 at 16:43
@user2573802 This is wrong. `__builtin_ctz(9) = 0` which is not `log2(9)`. –  nixeagle Oct 11 '13 at 1:52
Oh, I remember now. It's finding the lowest-order bit that's set, so it only works for numbers which are exact powers of two. The first bit (bit 0) is set for 9 (1001), so it returns 0. –  user2573802 Nov 25 '13 at 1:35

If you just want a fast integer log2 operation, the following function will do it without having to worry about floating-point accuracy:

``````static unsigned int mylog2 (unsigned int val) {
unsigned int ret = -1;
while (val != 0) {
val >>= 1;
ret++;
}
return ret;
}
``````

It will return -1 for an input value of 0, rather than the correct infinity (which is a little hard to represent in an integer :-)

By the way, there are some insanely fast hacks to do exactly this (find the highest bit set in a 2's complement number) available from here. I wouldn't suggest using them unless speed is of the essence (I prefer readability myself) but you should be made aware that they exist.

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paxdiablo — I like that you're returning –1 for an input value of 0. Note, however, that you aren't actually returning `-1`, but actually instead `~0` (e.g., 0xFFFFFFFF if you have 32-bit integers), since you've declared the function to return an `unsigned int` rather than `int`. In this sense, `~0` is the closest to infinity that you can get in an integer. –  Todd Lehman Jul 21 '14 at 18:31

Base-2 Integer Logarithm

Here is what I do for 64-bit unsigned integers. This calculates the floor of the base-2 logarithm, which is equivalent to the index of the most significant bit. This method is smokingly fast for large numbers because it uses an unrolled loop that executes always in log₂64 = 6 steps.

Essentially, what it does is subtracts away progressively smaller squares in the sequence { 0 ≤ k ≤ 5: 2^(2^k) } = { 2³², 2¹⁶, 2⁸, 2⁴, 2², 2¹ } = { 4294967296, 65536, 256, 16, 4, 2, 1 } and sums the exponents k of the subtracted values.

``````int uint64_log2(uint64_t n)
{
#define S(k) if (n >= (UINT64_C(1) << k)) { i += k; n >>= k; }

int i = -(n == 0); S(32); S(16); S(8); S(4); S(2); S(1); return i;

#undef S
}
``````

Note that this returns –1 if given the invalid input of 0 (which is what the initial `-(n == 0)` is checking for). If you never expect to invoke it with `n == 0`, you could substitute `int i = 0;` for the initializer and add `assert(n != 0);` at entry to the function.

Base-10 Integer Logarithm

Base-10 integer logarithms can be calculated using similarly — with the largest square to test being 10¹⁶ because log₁₀2⁶⁴ ≅ 19.2659...

``````int uint64_log10(uint64_t n)
{
#define S(k, m) if (n >= UINT64_C(m)) { i += k; n /= UINT64_C(m); }

int i = -(n == 0);
S(16,10000000000000000); S(8,100000000); S(4,10000); S(2,100); S(1,10);
return i;

#undef S
}
``````
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Very pretty. With a decent compiler and the right instruction set, the conditional actions might all be implemented as predicated instructions, so there are no branch mispredicts; it is all pure computation in the registers at the (superscalar) rate the typical modern processor can achieve. –  Ira Baxter Aug 9 '14 at 17:03
@IraBaxter — Thanks... And surprisingly, in the `log2` case, this method of comparing against a list of constants is about 60% faster (on my system) than shifting and checking for zero. (I suppose because of modern instruction pipeline caches.) That is, doing `if (n >> k) {...}` to shift and compare with zero is actually 60% slower than doing `if (n >= (UINT64_C(1) << k)) {...}` to compare against a 64-bit constant. –  Todd Lehman Aug 9 '14 at 19:13

I've never had any problem with floating-point accuracy on the formula you're using (and a quick check of numbers from 1 to 231 - 1 found no errors), but if you're worried, you can use this function instead, which returns the same results and is about 66% faster in my tests:

``````int HighestBit(int i){
if(i == 0)
return -1;

int bit = 31;
if((i & 0xFFFFFF00) == 0){
i <<= 24;
bit = 7;
}else if((i & 0xFFFF0000) == 0){
i <<= 16;
bit = 15;
}else if((i & 0xFF000000) == 0){
i <<= 8;
bit = 23;
}

if((i & 0xF0000000) == 0){
i <<= 4;
bit -= 4;
}

while((i & 0x80000000) == 0){
i <<= 1;
bit--;
}

return bit;
}
``````
-
Indeed, the danger in using the log(number)/log(base) method isn't so much with a base of 2 as it is with other numbers. For example `log(1000) / log(10)` gives 2.9999999999999996 (the `floor` of which is 2 instead of 3) with IEEE double-precision semantics. –  Todd Lehman Jul 21 '14 at 18:37
But also note that since IEEE double-precision values only have 53 bits of mantissa (52 plus an understood leading 1-bit), the log(number)/log(base) method falls apart completely for numbers above 2⁵³, which is a very large subset of the 64-bit integers. So while you're safe using log(number)/log(base) with 32-bit integers, you're asking for trouble with 64-bit integers. –  Todd Lehman Jul 21 '14 at 18:40

This isn't standard or necessarily portable, but it will in general work. I don't know how efficient it is.

Convert the integer index into a floating-point number of sufficient precision. The representation will be exact, assuming the precision is sufficient.

Look up the representation of IEEE floating-point numbers, extract the exponent, and make the necessary adjustment to find the base 2 log.

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"Sufficient precision" here equals IEEE double-precision (64-bit a.k.a. `double` in C) for handling 32-bit integers and IEEE extended-double-precision (80-bit a.k.a. `long double` in C) for handling 64-bit integers. –  Todd Lehman Jul 21 '14 at 18:42
``````int targetIndex = floor(log(i + 0.5)/log(2.0));
``````
-

This function determines how many bits are required to represent the numeric interval: [0..maxvalue].

``````unsigned binary_depth( unsigned maxvalue )
{
int depth=0;
while ( maxvalue ) maxvalue>>=1, depth++;
return depth;
}
``````

By subtracting 1 from the result, you get `floor(log2(x))`, which is an exact representation of `log2(x)` when `x` is a power of 2.

xyy-1
00-1
110
221
321
432
532
632
732
843

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This can easily be generalized to support any 'radix' (numeric base) -- just use `/=radix` (divide by radix) in place of the `>>=1`. –  nobar Aug 26 '13 at 19:56

How deep do you project your tree to be? You could set a range of say... +/- 0.00000001 to the number to force it to an integer value.

I'm actually not certain you'll hit a number like 1.99999999 because your log2 should not lose any accuracy when calculating 2^n values (Since floating point rounds to the nearest power of 2).

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This function I wrote here

``````// The 'i' is for int, there is a log2 for double in stdclib
inline unsigned int log2i( unsigned int x )
{
unsigned int log2Val = 0 ;
// Count push off bits to right until 0
// 101 => 10 => 1 => 0
// which means hibit was 3rd bit, its value is 2^3
while( x>>=1 ) log2Val++;  // div by 2 until find log2.  log_2(63)=5.97, so
// take that as 5, (this is a traditional integer function!)
// eg x=63 (111111), log2Val=5 (last one isn't counted by the while loop)
return log2Val ;
}
``````
-

This has been proposed in the comments above. Using gcc builtins:

``````static inline int log2i(int x) {
assert(x > 0);

return sizeof(int) * 8 - __builtin_clz(x) - 1;
}

static void test_log2i(void) {
assert_se(log2i(1) == 0);
assert_se(log2i(2) == 1);
assert_se(log2i(3) == 1);
assert_se(log2i(4) == 2);
assert_se(log2i(32) == 5);
assert_se(log2i(33) == 5);
assert_se(log2i(63) == 5);
assert_se(log2i(INT_MAX) == sizeof(int)*8-2);
}
``````
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