It looks like their `(fusedMA <mode> foo bar baz)`

returns `foo*bar/2 + baz`

. Something weird, either in the theorem prover or in real fused multiply-adds, seems to happen when either the arguments or the result is subnormal.

I ran this to see what it thought the offending product and FMA were:

```
(set-logic QF_FPA)
; s7 is equivalent to single-precision +0
(define-fun s7 () (_ FP 8 24) ((_ asFloat 8 24) roundNearestTiesToEven (/ 0 1)))
(declare-fun s0 () (_ FP 8 24))
(declare-fun s1 () (_ FP 8 24))
(declare-fun prod () (_ FP 8 24))
(declare-fun fma () (_ FP 8 24))
(assert
(let ((s2 (== s0 s0))) ; make sure s0 is not NaN
(let ((s3 (== s1 s1))) ; make sure s1 is not NaN
(let ((s4 (and s2 s3)))
(let ((s5 (not s4))) ; s5 is True when either argument is NaN
(let ((s6 (* roundNearestTiesToEven s0 s1))) ; s6 = s0*s1
(let ((s8 (fusedMA roundNearestTiesToEven s0 s1 s7))) ; s8 = s0*s1 + s7 = s0*s1 since s7 is 0
(let ((s9 (== s6 s8))) ; s9 should always be true provided arguments are not NaN
(let ((s10 (or s5 s9))) ; thus; s10 is true always
(and (== fma s8) (== prod s6) (not s10))))))))))) ; hence, the whole expression is unsatisfiable
(check-sat)
(get-model)
```

and got this:

```
sat
(model
(define-fun prod () (_ FP 8 24) (as -1.0572719573974609375p-9 (_ FP 8 24)))
(define-fun fma () (_ FP 8 24) (as -1.0572719573974609375p-10 (_ FP 8 24)))
(define-fun s1 () (_ FP 8 24) (as +1.62525212764739990234375p118 (_ FP 8 24)))
(define-fun s0 () (_ FP 8 24) (as -0.0101644992828369140625p-126 (_ FP 8 24)))
)
```

Neither the product nor the FMA really line up with something that's about -2^{-14}, which is...irksome.

If you bound `prod`

and `fma`

below by 2^{-125}, you can get something like this:

```
sat
(model
(define-fun prod () (_ FP 8 24) (as +1.52807605266571044921875p-3 (_ FP 8 24)))
(define-fun fma () (_ FP 8 24) (as +1.528076171875p-3 (_ FP 8 24)))
(define-fun s1 () (_ FP 8 24) (as -0.0002593994140625p-126 (_ FP 8 24)))
(define-fun s0 () (_ FP 8 24) (as -1.4381892681121826171875p125 (_ FP 8 24)))
)
```

If you also bound `s0`

and `s1`

below by 2^{-125}, it returns `unsat`

.