As others have noted, it's unclear that your simplifications even hold in Haskell. For instance, I can define
newtype NInt = N Int
instance Num NInt where
N a + _ = N a
N b * _ = N b
... -- etc
and now sum . reverse :: Num [a] -> a
does not equal sum :: Num [a] -> a
since I can specialize each to [NInt] -> NInt
where sum . reverse == sum
clearly does not hold.
This is one general tension that exists around optimizing "complex" operations—you actually need quite a lot of information in order to successfully prove that it's okay to optimize something. This is why the syntax-level compiler optimization which do exist are usually monomorphic and related to the structure of programs---it's usually such a simplified domain that there's "no way" for the optimization to go wrong. Even that is often unsafe because the domain is never quite so simplified and well-known to the compiler.
As an example, a very popular "high-level" syntactic optimization is stream fusion. In this case the compiler is given enough information to know that stream fusion can occur and is basically safe, but even in this canonical example we have to skirt around notions of non-termination.
So what does it take to have \x -> sum [0..x]
get replaced by \x -> x*(x + 1)/2
? The compiler would need a theory of numbers and algebra built-in. This is not possible in Haskell or ML, but becomes possible in dependently typed languages like Coq, Agda, or Idris. There you could specify things like
revCommute :: (_+_ :: a -> a -> a)
-> Commutative _+_
-> foldr _+_ z (reverse as) == foldr _+_ z as
and then, theoretically, tell the compiler to rewrite according to revCommute
. This would still be difficult and finicky, but at least we'd have enough information around. To be clear, I'm writing something very strange above, a dependent type. The type not only depends on the ability to introduce both a type and a name for the argument inline, but also the existence of the entire syntax of your language "at the type level".
There are a lot of differences between what I just wrote and what you'd do in Haskell, though. First, in order to form a basis where such promises can be taken seriously, we must throw away general recursion (and thus we already don't have to worry about questions of non-termination like stream-fusion does). We also must have enough structure around to create something like the promise Commutative _+_
---this likely depends upon there being an entire theory of operators and mathematics built into the language's standard library else you would need to create that yourself. Finally, the richness of type system required to even express these kinds of theories adds a lot of complexity to the entire system and tosses out type inference as you know it today.
But, given all that structure, I'd never be able to create an obligation Commutative _+_
for the _+_
defined to work on NInt
s and so we could be certain that foldr (+) 0 . reverse == foldr (+) 0
actually does hold.
But now we'd need to tell the compiler how to actually perform that optimization. For stream-fusion, the compiler rules only kick in when we write something in exactly the right syntactic form to be "clearly" an optimization redex. The same kinds of restrictions would apply to our sum . reverse
rule. In fact, already we're sunk because
foldr (+) 0 . reverse
foldr (+) 0 (reverse as)
don't match. They're "obviously" the same due to some rules we could prove about (.)
, but that means that now the compiler must invoke two built-in rules in order to perform our optimization.
At the end of the day, you need a very smart optimization search over the sets of known laws in order to achieve the kinds of automatic optimizations you're talking about.
So not only do we add a lot of complexity to the entire system, require a lot of base work to build-in some useful algebraic theories, and lose Turing completeness (which might not be the worst thing), we also only get a finicky promise that our rule would even fire unless we perform an exponentially painful search during compilation.
Blech.
The compromise that exists today tends to be that sometimes we have enough control over what's being written to be mostly certain that a certain obvious optimization can be performed. This is the regime of stream fusion and it requires a lot of hidden types, carefully written proofs, exploitations of parametricity, and hand-waving before it's something the community trusts enough to run on their code.
And it doesn't even always fire. For an example of battling that problem take a look at the source of Vector
for all of the RULES pragmas that specify all of the common circumstances where Vector
's stream-fusion optimizations should kick in.
All of this is not at all a critique of compiler optimizations or dependent type theories. Both are really incredible. Instead it's just an amplification of the tradeoffs involved in introducing such an optimization. It's not to be done lightly.