According to the OpenCL spec (version 1.1, page 215):

`float length(floatn p)`

: Return the length of vector `p`

, i.e. `sqrt(p.x²+p.y²+...)`

`float fast_length(floatn p)`

: Return the length of vector `p`

computed as `half_sqrt(p.x²+p.y²+...)`

So `fast_length`

uses `half_sqrt`

, while `length`

uses `sqrt`

. As you can guess `sqrt`

has better guarantees on accuracy, but might be slower. More to the point:

- Min Accuracy of
`sqrt`

: 3ulp (unit of least precision)
Min Accuracy of `half_sqrt`

: 8192ulp

So `half_sqrt`

can be about 11bits less accurate then `sqrt`

(well actually it can be 13 bit less accurate, since there ist no requirement for `sqrt`

not to be better then strictly necessary). Since `float`

has a mantissa of `23bit`

(plus one implicit bit) `half_sqrt`

only promises about 10bit of precision (11bit including the implicit 1). It might however be faster, if the hardware has such a function. In hardware it's not unusual to have `sqrt`

or `rsqrt`

instruction providing only a small number of bits (like 10-14) and using Newton-Raphson iterations after the instruction to get the necessary precision. In such a case using `half_sqrt`

is obviously faster.