Actually, it seems that `fix (* 0) == 0`

only works for `Integer`

, if you run `fix (* 0) :: Double`

or `fix (* 0) :: Int`

, you still get `***Exception <<loop>>`

That's because in `instance Num Integer`

, `(*)`

is defined as `(*) = timesInteger`

`timesInteger`

is defined in `Data.Integer`

```
-- | Multiply two 'Integer's
timesInteger :: Integer -> Integer -> Integer
timesInteger _ (S# 0#) = S# 0#
timesInteger (S# 0#) _ = S# 0#
timesInteger x (S# 1#) = x
timesInteger (S# 1#) y = y
timesInteger x (S# -1#) = negateInteger x
timesInteger (S# -1#) y = negateInteger y
timesInteger (S# x#) (S# y#)
= case mulIntMayOflo# x# y# of
0# -> S# (x# *# y#)
_ -> timesInt2Integer x# y#
timesInteger x@(S# _) y = timesInteger y x
-- no S# as first arg from here on
timesInteger (Jp# x) (Jp# y) = Jp# (timesBigNat x y)
timesInteger (Jp# x) (Jn# y) = Jn# (timesBigNat x y)
timesInteger (Jp# x) (S# y#)
| isTrue# (y# >=# 0#) = Jp# (timesBigNatWord x (int2Word# y#))
| True = Jn# (timesBigNatWord x (int2Word# (negateInt# y#)))
timesInteger (Jn# x) (Jn# y) = Jp# (timesBigNat x y)
timesInteger (Jn# x) (Jp# y) = Jn# (timesBigNat x y)
timesInteger (Jn# x) (S# y#)
| isTrue# (y# >=# 0#) = Jn# (timesBigNatWord x (int2Word# y#))
| True = Jp# (timesBigNatWord x (int2Word# (negateInt# y#)))
```

Look at the above code, if you run `(* 0) x`

, then `timesInteger _ (S# 0#)`

would match so that `x`

would not be evaluated, while if you run `(0 *) x`

, then when checking whether `timesInteger _ (S# 0#)`

matches, x would be evaluated and cause infinite loop

We can use below code to test it:

```
module Test where
import Data.Function(fix)
-- fix (0 ~*) == 0
-- fix (~* 0) == ***Exception<<loop>>
(~*) :: (Num a, Eq a) => a -> a -> a
0 ~* _ = 0
_ ~* 0 = 0
x ~* y = x ~* y
-- fix (0 *~) == ***Exception<<loop>>
-- fix (*~ 0) == 0
(*~) :: (Num a, Eq a) => a -> a -> a
_ *~ 0 = 0
0 *~ _ = 0
x *~ y = x *~ y
```

There is something even more interesting, in GHCI:

```
*Test> let x = fix (* 0)
*Test> x
0
*Test> x :: Double
*** Exception: <<loop>>
*Test>
```

exactlythe point that makes denotational semantics not completely equivalent to operational semantics, i.e. not fully abstract. The former can represent a function`f`

with`f undefined 0 = 0`

and`f 0 undefined = 0`

while the latter cannot. Language implementations follow operational semantics, thus making it impossible to define such an`f`

without some trickery.