Every now and again I have been noticing the following in Haskell documentation:
(for example in Data.Text
):
Subject to fusion
What is fusion and how do I use it?
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Every now and again I have been noticing the following in Haskell documentation:
(for example in Data.Text
):
Subject to fusion
What is fusion and how do I use it?
In general, fusion refers to transformations whose purpose is to get rid of intermediate data structures. You fuse function calls that result in wasteful memory allocations into something more efficient. This is actually IMO one of the biggest applications of Haskell being pure. And you pretty much don't need to do anything to get it, it comes for free through the GHC compiler.
Because Haskell is pure, we get this thing called referential transparency, which (from the link), means that "expression always evaluates to the same result in any context"^{1}. That means that I can do very general program level manipulations without changing what the program will actually output. For example, even without knowing what x
, y
, z
and w
are I always know that
((x ++ y) ++ z) ++ w
will evaluate to the same thing as
x ++ (y ++ (z ++ w))
yet the second one will in practice involve less memory allocations (since x ++ y
requires reallocating whole prefix of the output list).
In fact, there are a whole lot of this sort of optimization we can do, and, because Haskell is pure, we can basically just move whole expressions around (replacing x
, y
, z
, or w
for actual lists or expressions that evaluate to lists in the example above changes nothing). This becomes a pretty mechanical process.
Furthermore, it turns out that you can come up with a lot of equivalences for higher order functions (Theorems for free!). For example,
map f (map g xs) = map (f . g) xs
no matter what f
, g
, and xs
are (the two sides are semantically equal). Yet while the two sides of this equation produce the same value output, the left hand side is always worse in efficiency: it ends up allocating space for an intermediate list map g xs
, that is immediately thrown away. We'd like to tell the compiler to, whenever it encounters something like map f (map g xs)
, replace it with map (f . g) xs
. And, for GHC, that is through rewrite rules:
{-# RULES "map/map" forall f g xs. map f (map g xs) = map (f.g) xs #-}
The f
, g
, and xs
can be matched against any expressions, not just variables (so something like map (+1) (map (*2) ([1,2] ++ [3,4]))
gets transformed into map ((+1) . (*2)) ([1,2] ++ [3,4])
. (There doesn't appear to be a good way to search for rewrite rules, so I compiled a list). This paper explains the motivation and workings of GHC rewrite rules.
map
?Actually, not quite. The thing above is short-cut fusion. The name sort of implies the drawback: it doesn't scale too well and is annoying to debug. You end up having to write a ton of ad-hoc rules for all arrangements of the same common functions. Then, you hope that repeated application of rewrite rules will simplify your expressions nicely.
It turns out that we can do even better in some cases by organizing our re-write rules so that we build up some intermediate normal form and then have rules targeting that intermediate form. This way, we start getting "hot" paths of rewrite rules.
Probably the most advanced of these systems is stream fusion targeting coinductive sequences (basically lazy sequences like lists). Check out this thesis and this paper (which is actually pretty much how the vector
package is implemented). For example, in vector
, your code gets first transformed into an intermediate form involving Stream
s and Bundle
s, is optimized in that form, then gets transformed back into vectors.
Data.Text
?Data.Text
uses stream fusion to minimize the number of memory allocations that occur (I think this is especially important for the strict variant). If you check out the source, you'll see that the functions "subject to fusion" actually manipulate Stream
s for the most part (they are of the general form unstream . (stuff manipulating stream) . stream
) and there are a bunch of RULES
pragmas for transforming Stream
s. In the end, any combination of these functions is supposed to get fused so that only one allocation needs to occur.
The only real way to know when your code is subject to fusion is to have a good understanding of the rewrite rules involved and understand well how GHC works. That said, there is one thing that you should do: try to use non-recursive higher order functions when possible, since these can be (at least for now, but in general will always be more) easily fused.
Because fusion in Haskell occurs through repeated application of rewrite rules, it suffices to convince yourself of each rewrite rule's correctness to know that the whole "fused" program does the same thing as your original program does. Except there are edge cases relating to programs terminating. For example, one might think that
reverse (reverse xs) = xs
yet that is clearly not true, since head $ reverse (reverse [1..])
will not terminate yet head [1..]
will. More information from the Haskell Wiki.
^{1} This is actually true only provided that in these contexts the expression maintains the same type.
stream-fusion
library, which has not compiled for years. It predates the general use of thetext
andvector
libraries, which do use stream fusion, and do compile, and are fundamental to modern Haskell. The author of the accepted answer seems to be completely ignorant of the existence of these libraries. Read today, the accepted answer is basically disinformation, and anyway does not give the advice asked for above when genuine worthwhile advice really does exist. – Michael Aug 11 '16 at 20:54