One way to implement FMA in software is by splitting the significant into high and low bits. I use Dekker's algorithm

```
typedef struct { float hi; float lo; } doublefloat;
doublefloat split(float a) {
float t = ((1<<12)+1)*a;
float hi = t - (t - a);
float lo = a - hi;
return (doublefloat){hi, lo};
}
```

Once you split the the float you can calculate `a*b-c`

with a single rounding like this

```
float fmsub(float a, float b, float c) {
doublefloat as = split(a), bs = split(b);
return ((as.hi*bs.hi - c) + as.hi*bs.lo + as.lo*bs.hi) + as.lo*bs.lo;
}
```

This basically subtracts `c`

from `(ahi,alo)*(bhi,blo) = (ahi*bhi + ahi*blo + alo*bhi + alo*blo)`

.

I got this idea from the `twoProd`

function in the paper Extended-Precision Floating-Point Numbers for GPU Computation and from the `mul_sub_x`

function in Agner Fog's vector class library. He uses a different function for splitting vectors of floats which splits differently. I tried to reproduce a scalar version here

```
typedef union {float f; int i;} u;
doublefloat split2(float a) {
u lo, hi = {a};
hi.i &= -(1<<12);
lo.f = a - hi.f;
return (doublefloat){hi.f,lo.f};
}
```

In any case using `split`

or `split2`

in `fmsub`

agrees well with `fma(a,b,-c)`

from the math library in glibc. For whatever reason my version is significantly faster than `fma`

except on a machine that has hardware fma (in which case I use `_mm_fmsub_ss`

anyway).

`-mfma`

or`-mfma4`

or`-march=something`

where`something`

is a fma-supporting processor). On Linux, you might look at`sysdeps/ieee754/dbl-64/s_fma.c`

in glibc to get an idea of what the library function fallback looks like. – tmyklebu Feb 20 '15 at 15:17