The only thing I found so far are "error-free transformations". For any floating point numbers errors from `a+b`

, `a-b`

, and `a*b`

are also floating point numbers (in round to nearest mode, assuming no overflow/underflow etc. etc.).

Addition (and obviously subtraction) error is easy to compute; if `abs(a) >= abs(b)`

, error is exactly `b-((a+b)-a)`

(2 flops, or 4-5 if we don't know which is bigger). Multiplication error is trivial to compute with `fma`

- it is simply `fma(a,b,-a*b)`

. Without `fma`

it's 16 flops of rather nasty code. And fully generic emulation of correctly rounded `fma`

is even slower than that.

Extra 16 flops of error tracking per flop of real computation is a huge overkill, but with just 1-5 pipeline-friendly flops it's quite reasonable, and for many algorithms based on that 50%-200% overhead of error tracking and compensation results in error as small as if all calculations were done in twice the number of bits they were, avoiding ill-conditioning in many cases.

Interestingly, `fma`

isn't ever used in these algorithms to compute results, just to find errors, because finding error of `fma`

is a slow as finding error of multiplication was without `fma`

.

Relevant keywords to search would be "compensated Horner scheme" and "compensated dot product", with Horner scheme benefiting a lot more.