## 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
}
```