If you're interested in seeing source code for algorithms for this kind of thing, then fdlibm - the "Freely Distributable `libm`

", originally from Sun, and the reference implementation for Java's math libraries - might be a good place to start. (For casual browsing, it's certainly a better place to start than GNU libc, where the pieces are scattered around various subdirectories - `math/`

, `sysdeps/ieee754/`

, etc.)

fdlibm assumes that it's working with an IEEE 754 format `double`

, and if you look at the implementations - for example, the core of the implementation of log() - you'll see that they use all sorts of clever tricks, often using a mixture of both standard `double`

arithmetic, and knowledge of the bit representation of a `double`

.

(And if you're interested in algorithms for supporting basic IEEE 754 floating point arithmetic, such as might be used for processors without hardware floating point support, take a look at John R. Hauser's SoftFloat.)

As for your edit: in general, `ceil()`

and `floor()`

might well be implemented in hardware; for example, on x86, GCC (with optimisations enabled) generates code using the `frndint`

instruction with appropriate fiddling of the FPU control word to set the rounding mode. But fdlibm's pure software implementations (`s_ceil.c`

, `s_floor.c`

) do work using the bit representation directly.

`sqrt`

,`sin`

,`exp`

, etc. usually involves knowing numerical analysis and applying an approximation method, possibly with argument reduction and other tricks too. – R.. GitHub STOP HELPING ICE Jun 1 '11 at 22:54