Below is an example C implementation of Clay S. Turner's fixed-point log base 2 algorithm[1]. The algorithm doesn't require any kind of look-up table. This can be useful on systems where memory constraints are tight and the processor lacks an FPU, such as is the case with many microcontrollers. Log base *e* and log base 10 are then also supported by using the property of logarithms that, for any base *n*:

```
log (x)
y
log (x) = _______
n log (n)
y
```

where, for this algorithm, *y* equals 2.

A nice feature of this implementation is that it supports variable precision: the precision can be determined at runtime, at the expense of range. The way I've implemented it, the processor (or compiler) must be capable of doing 64-bit math for holding some intermediate results. It can be easily adapted to not require 64-bit support, but the range will be reduced.

When using these functions, `x`

is expected to be a fixed-point value scaled according to the
specified `precision`

. For instance, if `precision`

is 16, then `x`

should be scaled by 2^16 (65536). The result is a fixed-point value with the same scale factor as the input. A return value of `INT32_MIN`

represents negative infinity. A return value of `INT32_MAX`

indicates an error and `errno`

will be set to `EINVAL`

, indicating that the input precision was invalid.

```
#include <errno.h>
#include <stddef.h>
#include "log2fix.h"
#define INV_LOG2_E_Q1DOT31 UINT64_C(0x58b90bfc) // Inverse log base 2 of e
#define INV_LOG2_10_Q1DOT31 UINT64_C(0x268826a1) // Inverse log base 2 of 10
int32_t log2fix (uint32_t x, size_t precision)
{
int32_t b = 1U << (precision - 1);
int32_t y = 0;
if (precision < 1 || precision > 31) {
errno = EINVAL;
return INT32_MAX; // indicates an error
}
if (x == 0) {
return INT32_MIN; // represents negative infinity
}
while (x < 1U << precision) {
x <<= 1;
y -= 1U << precision;
}
while (x >= 2U << precision) {
x >>= 1;
y += 1U << precision;
}
uint64_t z = x;
for (size_t i = 0; i < precision; i++) {
z = z * z >> precision;
if (z >= 2U << precision) {
z >>= 1;
y += b;
}
b >>= 1;
}
return y;
}
int32_t logfix (uint32_t x, size_t precision)
{
uint64_t t;
t = log2fix(x, precision) * INV_LOG2_E_Q1DOT31;
return t >> 31;
}
int32_t log10fix (uint32_t x, size_t precision)
{
uint64_t t;
t = log2fix(x, precision) * INV_LOG2_10_Q1DOT31;
return t >> 31;
}
```

The code for this implementation also lives at Github, along with a sample/test program that illustrates how to use this function to compute and display logarithms from numbers read from standard input.

[1] C. S. Turner, "A Fast Binary Logarithm Algorithm", *IEEE Signal Processing Mag.*, pp. 124,140, Sep. 2010.

fastfunctions, those`exp( y * log( x ) )`

implementations aren't going to cut it. – MSalters Jan 11 '11 at 12:23