# Fast computing of log2 for 64-bit integers

A great programming resource, Bit Twiddling Hacks, proposes (here) the following method to compute log2 of a 32-bit integer:

``````#define LT(n) n, n, n, n, n, n, n, n, n, n, n, n, n, n, n, n
static const char LogTable256 =
{
-1, 0, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3, 3, 3, 3, 3,
LT(4), LT(5), LT(5), LT(6), LT(6), LT(6), LT(6),
LT(7), LT(7), LT(7), LT(7), LT(7), LT(7), LT(7), LT(7)
};

unsigned int v; // 32-bit word to find the log of
unsigned r;     // r will be lg(v)
register unsigned int t, tt; // temporaries
if (tt = v >> 16)
{
r = (t = tt >> 8) ? 24 + LogTable256[t] : 16 + LogTable256[tt];
}
else
{
r = (t = v >> 8) ? 8 + LogTable256[t] : LogTable256[v];
}
``````

and mentions that

The lookup table method takes only about 7 operations to find the log of a 32-bit value. If extended for 64-bit quantities, it would take roughly 9 operations.

but, alas, doesn't give any additional info about which way one should actually go to extend the algorithm to 64-bit integers.

Any hints about how a 64-bit algorithm of this kind would look like?

• @dbaupp I've got bags of `if`s of all possible kinds, sorts, and taste, which ones would do best? – Desmond Hume Jul 7 '12 at 15:41
• That's just an academical question, right? Otherwise just use `_BitScanReverse64` (msvc) or `__builtin_clzll` (gcc) – harold Jul 7 '12 at 15:42
• Ones like the ones you already have. (Using the most naive extension, it'll look something like `if (tt = v >> 48) { ... } else if (tt = v >> 32) { ... } ...`, although this will perform marginally worse than the proper binary search Kendall correctly suggests.) – huon Jul 7 '12 at 15:43
• @harold: No, this is not an academical question at all. Even if someone decides to use compiler-specific intrisincs, they will go into compiler-specific `#if` branches. This, of course, does not eliminate the need for a "default" branch implemented more or less universally. – AnT Jul 7 '12 at 16:39
• @AndreyT it would be interesting if people started doing that. Code might actually become real-life-portable, instead of Ivory-Tower-portable (where a sensible implementation of int can not be relied upon, but gcc-specific language extenstion can) – harold Jul 7 '12 at 16:59

Intrinsic functions are really fast, but still are insufficient for a truly cross-platform, compiler-independent implementation of log2. So in case anyone is interested, here is the fastest, branch-free, CPU-abstract DeBruijn-like algorithm I've come to while researching the topic on my own.

``````const int tab64 = {
63,  0, 58,  1, 59, 47, 53,  2,
60, 39, 48, 27, 54, 33, 42,  3,
61, 51, 37, 40, 49, 18, 28, 20,
55, 30, 34, 11, 43, 14, 22,  4,
62, 57, 46, 52, 38, 26, 32, 41,
50, 36, 17, 19, 29, 10, 13, 21,
56, 45, 25, 31, 35, 16,  9, 12,
44, 24, 15,  8, 23,  7,  6,  5};

int log2_64 (uint64_t value)
{
value |= value >> 1;
value |= value >> 2;
value |= value >> 4;
value |= value >> 8;
value |= value >> 16;
value |= value >> 32;
return tab64[((uint64_t)((value - (value >> 1))*0x07EDD5E59A4E28C2)) >> 58];
}
``````

The part of rounding down to the next lower power of 2 was taken from Power-of-2 Boundaries and the part of getting the number of trailing zeros was taken from BitScan (the `(bb & -bb)` code there is to single out the rightmost bit that is set to 1, which is not needed after we've rounded the value down to the next power of 2).

And the 32-bit implementation, by the way, is

``````const int tab32 = {
0,  9,  1, 10, 13, 21,  2, 29,
11, 14, 16, 18, 22, 25,  3, 30,
8, 12, 20, 28, 15, 17, 24,  7,
19, 27, 23,  6, 26,  5,  4, 31};

int log2_32 (uint32_t value)
{
value |= value >> 1;
value |= value >> 2;
value |= value >> 4;
value |= value >> 8;
value |= value >> 16;
return tab32[(uint32_t)(value*0x07C4ACDD) >> 27];
}
``````

As with any other computational method, log2 requires the input value to be greater than zero.

• @ArjunShankar You're welcome. However, I still think there is a way of shaving off those two ops in the table lookup line, namely subtraction and right shift, by means of generating another perfect hashing function. Don't know if I'll have enough time for this pursuing of zen as long as my main compilers are MSVC and GCC ;) – Desmond Hume Jul 9 '12 at 16:29
• @ArjunShankar And, for the clarity of where the operations, table entries, and constants come from, I've updated the answer to cite the sources. – Desmond Hume Jul 9 '12 at 16:50
• To help with the trade off between portability and speed, on an Intel(R) Xeon(R) CPU X5650 @ 2.67GHz the lookup table is on average about 4 times slower than the intrinsic (about 13 cycles vs 4 cycles) – Come Raczy Aug 15 '13 at 13:23
• @DesmondHume — Since, as you say, the input value must be greater than zero, maybe you want to add a line at the beginning of the function that says `assert(value > 0);`. This not only helps catch any errors but also serves to help document the entry conditions. – Todd Lehman Apr 21 '16 at 14:39
• @DesmondHume — Another observation: Instead of having the `tab64[]` table contain `int` values, why not have it contain 8-bit values and specify the table as `const int8_t tab64`... This way, the table requires only 64 bytes (instead of 256). Additionally, if you include `__attribute__((aligned(64)))`, then it is also guaranteed to fit within a single cache line on a modern processor. As currently written (with 256 bytes and no alignment), the table could be using up to 5 cache lines. – Todd Lehman Apr 21 '16 at 14:44

If you are using GCC, a lookup table is unnecessary in this case.

GCC provides a builtin function to determine the amount of leading zeros:

Built-in Function: `int __builtin_clz (unsigned int x)`
Returns the number of leading 0-bits in x, starting at the most significant bit position. If x is 0, the result is undefined.

So you can define:

``````#define LOG2(X) ((unsigned) (8*sizeof (unsigned long long) - __builtin_clzll((X)) - 1))
``````

and it will work for any unsigned long long int. The result is rounded down.

For x86 and AMD64 GCC will compile it to a `bsr` instruction, so the solution is very fast (much faster than lookup tables).

``````#include <stdio.h>

#define LOG2(X) ((unsigned) (8*sizeof (unsigned long long) - __builtin_clzll((X)) - 1))

int main(void) {
unsigned long long input;
while (scanf("%llu", &input) == 1) {
printf("log(%llu) = %u\n", input, LOG2(input));
}
return 0;
}
``````
• How about also handling "If x is 0, the result is undefined." in your example? :) – ArjunShankar Jul 7 '12 at 16:41
• @ArjunShankar actually I thought about it, but couldn't think of an appropriate integer for that case. ;) I leave it to the interested reader to add an if-else case to the macro. (Also only the result will be undefined [most likely 0], but there won't be a crash if a 0 was supplied.) – kay Jul 7 '12 at 16:46
• @kay Didn't know about `bsr` instruction. Wanted it to be more CPU-independent tho. Thanks. – Desmond Hume Jul 7 '12 at 17:27
• @DesmondHume __builtin_clz is not processor specific. GCC will find a set of instructions for that will perform well for any supported architecture. – kay Jul 7 '12 at 17:36
• If you compile for Haswell or later, GCC and Clang select LZCNT instead of BSR. Clang then even generates just `lzcnt rax, rdi; xor eax, 63` whereas GCC or ICC select 1 or 2 extra instructions, for this integer log2 function. – maxschlepzig Sep 24 at 10:49

I was trying to convert Find the log base 2 of an N-bit integer in O(lg(N)) operations with multiply and lookup to 64-bit by brute forcing the magic number. Needless to say it was taking a while.

I then found Desmond's answer and decided to try his magic number as a start point. Since I have a 6 core processor I ran it in parallel starting at 0x07EDD5E59A4E28C2 / 6 multiples. I was surprised it found something immediately. Turns out 0x07EDD5E59A4E28C2 / 2 worked.

So here is the code for 0x07EDD5E59A4E28C2 which saves you a shift and subtract:

``````int LogBase2(uint64_t n)
{
static const int table = {
0, 58, 1, 59, 47, 53, 2, 60, 39, 48, 27, 54, 33, 42, 3, 61,
51, 37, 40, 49, 18, 28, 20, 55, 30, 34, 11, 43, 14, 22, 4, 62,
57, 46, 52, 38, 26, 32, 41, 50, 36, 17, 19, 29, 10, 13, 21, 56,
45, 25, 31, 35, 16, 9, 12, 44, 24, 15, 8, 23, 7, 6, 5, 63 };

n |= n >> 1;
n |= n >> 2;
n |= n >> 4;
n |= n >> 8;
n |= n >> 16;
n |= n >> 32;

return table[(n * 0x03f6eaf2cd271461) >> 58];
}
``````
• Are you 100% sure this is correct in all cases? I haven't really wrapped my head around how this works internally yet, so I don't know if there is a way to prove correctness... – Markus A. Oct 3 '14 at 17:54
• It's correct for all inputs except 0. It returns 0 for 0 which may be valid for what you're using it for. The lines with the shifts round n up to 1 less than the next power of 2. It basically sets all bits after the leading 1 bit to 1. This reduces all possible inputs to 64 possible values: 0x0, 0x1, 0x3, 0x7, 0xf, 0x1f, 0x3f, etc. Multiplying those 64 values with the number 0x03f6eaf2cd271461 gives you another 64 unique values in the top 6 bits. The shift by 58 just positions those 6 bits for use as an index into table. – Avernar Oct 7 '14 at 1:27
• That makes perfect sense. Thank you. Somehow I had a brain-block and I was reading the code as n = n | (n >> 1) | (n >> 2) and so forth and was trying to figure out how many cases I would have to check to verify correctness... D'Uh... Always good to know why something works! :) +1 – Markus A. Oct 7 '14 at 3:24
• @Avernar — As I was just pointing out to Desmond Hume in his nearly identical solution, if you make your table contain elements of type `int8_t` instead of `int`, and align it to a 64-byte boundary, then the table will be only 64 bytes instead of 256 bytes and will fit within a single cache line on modern processors. – Todd Lehman Apr 21 '16 at 14:49
• I guess this works because your "magic number" `m` is a DeBruin sequence B(2, 6) that starts with six `0`s followed by six `1`s. With such a sequence, multiplying with `n`s of the form `00011111` instead of `00010000` still works. Now the operation is `m * (2^(n+1) - 1)`, or `m * 2^(n+1) - m`, instead of `m * 2^n`. Since the sequence starts with six `0`s, multiplying by `2^(n+1)` still results in a perfect hash. Because of the following six `1s`, the subtraction always propagates a carry bit into the upper six bits of the result. – nwellnhof May 30 '17 at 0:29

## 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... (Note: This is not the fastest way to accomplish a base-10 integer logarithm, because it uses integer division, which is inherently slow. A faster implementation would be to use an accumulator with values that grow exponentially, and compare against the accumulator, in effect doing a sort of binary search.)

``````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
}
``````

Here's a pretty compact and fast extension, using no additional temporaries:

``````r = 0;

/* If its wider than 32 bits, then we already know that log >= 32.
So store it in R.  */
if (v >> 32)
{
r = 32;
v >>= 32;
}

/* Now do the exact same thing as the 32 bit algorithm,
except we ADD to R this time.  */
if (tt = v >> 16)
{
r += (t = tt >> 8) ? 24 + LogTable256[t] : 16 + LogTable256[tt];
}
else
{
r += (t = v >> 8) ? 8 + LogTable256[t] : LogTable256[v];
}
``````

Here is one built with a chain of `if`s, again using no additional temporaries. Might not be the fastest though.

``````  if (tt = v >> 48)
{
r = (t = tt >> 8) ? 56 + LogTable256[t] : 48 + LogTable256[tt];
}
else if (tt = v >> 32)
{
r = (t = tt >> 8) ? 40 + LogTable256[t] : 32 + LogTable256[tt];
}
else if (tt = v >> 16)
{
r = (t = tt >> 8) ? 24 + LogTable256[t] : 16 + LogTable256[tt];
}
else
{
r = (t = v >> 8) ? 8 + LogTable256[t] : LogTable256[v];
}
``````
• (`unsigned long long` or `uint64_t`) – huon Jul 7 '12 at 15:58
• @dbaupp - I was just too lazy to write a `main` and include `stdint.h`. Thanks for the nudge. I tried it in the meanwhile, and it's working fine. – ArjunShankar Jul 7 '12 at 16:02
• @ArjunShankar The first algorithm is hands down awesome. Thank you. – Desmond Hume Jul 7 '12 at 16:53

The algorithm basically finds out which byte contains the most significant 1 bit, and then looks up that byte in the lookup to find the log of the byte, then adds it to the position of the byte.

Here is a somewhat simplified version of the 32-bit algorithm:

``````if (tt = v >> 16)
{
if (t = tt >> 8)
{
r = 24 + LogTable256[t];
}
else
{
r = 16 + LogTable256[tt];
}
}
else
{
if (t = v >> 8)
{
r = 8 + LogTable256[t];
}
else
{
r = LogTable256[v];
}
}
``````

This is the equivalent 64-bit algorithm:

``````if (ttt = v >> 32)
{
if (tt = ttt >> 16)
{
if (t = tt >> 8)
{
r = 56 + LogTable256[t];
}
else
{
r = 48 + LogTable256[tt];
}
}
else
{
if (t = ttt >> 8)
{
r = 40 + LogTable256[t];
}
else
{
r = 32 + LogTable256[ttt];
}
}
}
else
{
if (tt = v >> 16)
{
if (t = tt >> 8)
{
r = 24 + LogTable256[t];
}
else
{
r = 16 + LogTable256[tt];
}
}
else
{
if (t = v >> 8)
{
r = 8 + LogTable256[t];
}
else
{
r = LogTable256[v];
}
}
}
``````

I came up with an algorithm for any size types that I think is nicer than the original.

``````unsigned int v = 42;
unsigned int r = 0;
unsigned int b;
for (b = sizeof(v) << 2; b; b = b >> 1)
{
if (v >> b)
{
v = v >> b;
r += b;
}
}
``````

Note: `b = sizeof(v) << 2` sets b to half the number of bits in v. I used shifting instead of multiplication here (just because I felt like it).

You could add a lookup table to that algorithm to speed it up possibly, but it's more a proof-of-concept.

• Just personally, I think the more compact ternary version is "simpler": takes up less space. :) – huon Jul 7 '12 at 15:45
• @dbaupp: Depends on your point of view. I expanded the ternary so it was easier to see what was going on. – Kendall Frey Jul 7 '12 at 15:48
• @KendallFrey Thank you, but would the fourth table look-up, if count from the beginning of the 64-bit algorithm, be able to overrun the boundaries of the table? – Desmond Hume Jul 7 '12 at 15:53
• @DesmondHume: Yes, I believe so. Copy-n-paste error here. Fixed. – Kendall Frey Jul 7 '12 at 15:56

Here is a slightly modified one from SPWorley on 3/22/2009 (see post for details)

``````double ff=(double)(v|1);
return ((*(1+(uint32_t *)&ff))>>52)-1023;  // assumes x86 endianness
``````

Side-note: some users pointed out that when compiled in some situations this may result in an incorrect answer.

Take this:

``````typedef unsigned int uint;
typedef uint64_t ulong;
uint as_uint(const float x) {
return *(uint*)&x;
}
ulong as_ulong(const double x) {
return *(ulong*)&x;
}
uint log2_fast(const uint x) {
return (uint)((as_uint((float)x)>>23)-127);
}
uint log2_fast(const ulong x) {
return (uint)((as_ulong((double)x)>>52)-1023);
}
``````

How it works: The input integer `x` is casted to `float` and then reinterpret as bits. The IEEE `float` format stores the exponent in bits 30-23 as an integer with bias 127, so by shifting it 23 bits to the right and subtracting the bias, we get log2(x). For a 64-bit integer input, `x` is casted to `double`, for which the exponent is in bits 62-52 (shift 52 bits to the right) and the exponent bias is 1023.

If you were looking for the c++ answer and you got here and since it boils down to counting zeroes then you got the `std::countl_zero` which according to godbolt.org calls `bsr`. `std::countl_zero` is available from C++20, you may need to add `-std=gnu++2a` to your compiler command line