# Correctness of short cut fusion

## 1 Short cut fusion

Short cut fusion allows elimination of intermediate data structures using rewrite rules that can also be performed automatically during compilation.

The two most popular instances are the
foldr
/
build
- and the
destroy
/
unfoldr

### 1.1 foldr/build

The
foldr
/
build
-rule eliminates intermediate lists produced by
build
and consumed by
foldr
, where these functions are defined as follows:
```foldr :: (a -> b -> b) -> b -> [a] -> b
foldr c n []     = n
foldr c n (x:xs) = c x (foldr c n xs)

build :: (forall b. (a -> b -> b) -> b -> b) -> [a]
build g = g (:) []```
Note the rank-2 polymorphic type of
build
. The
foldr
/
build
-rule now means the following replacement for appropriately typed
g
,
c
, and
n
:
`foldr c n (build g) <nowiki>&rarr;</nowiki> g c n`

### 1.2 destroy/unfoldr

The
destroy
/
unfoldr
-rule eliminates intermediate lists produced by
unfoldr
and consumed by
destroy
, where these functions are defined as follows:
```destroy :: (forall b. (b -> Maybe (a,b)) -> b -> c) -> [a] -> c
destroy g = g listpsi

listpsi :: [a] -> Maybe (a,[a])
listpsi []     = Nothing
listpsi (x:xs) = Just (x,xs)

unfoldr :: (b -> Maybe (a,b)) -> b -> [a]
unfoldr p e = case p e of Nothing     -> []
Just (x,e') -> x:unfoldr p e'```
Note the rank-2 polymorphic type of
destroy
. The
destroy
/
unfoldr
-rule now means the following replacement for appropriately typed
g
,
p
, and
e
:
`destroy g (unfoldr p e) <nowiki>&rarr;</nowiki> g p e`

## 2 Correctness

If the
foldr
/
build
- and the
destroy
/
unfoldr
-rule are to be automatically performed during compilation, as is possible using GHC's RULES pragmas, we clearly want them to be equivalences.

That is, the left- and right-hand sides should be semantically the same for each instance of either rule. Unfortunately, this is not so in Haskell.

We can distinguish two situations, depending on whether
g
is defined using
seq
or not.

### 2.1 In the absence of seq

#### 2.1.1 foldr/build

If
g
does not use
seq
, then the
foldr
/
build
-rule really is a semantic equivalence, that is, it holds that
`foldr c n (build g) = g c n`

The two sides are semantically interchangeable.

#### 2.1.2 destroy/unfoldr

The
destroy
/
unfoldr
-rule, however, is not a semantic equivalence.

To see this, consider the following instance:

```g = \x y -> case x y of Just z -> 0
p = \x -> if x==0 then Just undefined else Nothing
e = 0```
These values have appropriate types for being used in the
destroy
/
unfoldr
-rule. But with them, that rule's left-hand side "evaluates" as follows:
```destroy g (unfoldr p e) = g listpsi (unfoldr p e)
= case listpsi (unfoldr p e) of Just z -> 0
= case listpsi (case p e of Nothing     -> []
Just (x,e') -> x:unfoldr p e') of Just z -> 0
= case listpsi (case Just undefined of Nothing     -> []
Just (x,e') -> x:unfoldr p e') of Just z -> 0
= undefined```

while its right-hand side "evaluates" as follows:

```g p e = case p e of Just z -> 0
= case Just undefined of Just z -> 0
= 0```
Thus, by applying the
destroy
/
unfoldr
-rule, a nonterminating (or otherwise failing) program can be transformed into a safely terminating one.

The obvious questions now are:

1. Can the converse also happen, that is, can a safely terminating program be transformed into a failing one?
2. Can a safely terminating program be transformed into another safely terminating one that gives a different value as result?

There is no formal proof yet, but strong evidence supporting the conjecture that the answer to both questions is "No!".

The conjecture goes that if
g
does not use
seq
, then the
destroy
/
unfoldr
-rule is a semantic approximation from left to right, that is, it holds that
`destroy g (unfoldr p e) <math>\sqsubseteq</math> g p e`

What is known is that semantic equivalence can be recovered here by putting moderate restrictions on p.

More precisely, if
g
does not use
seq
and
p
is a strict function that never returns
Just <math>\bot</math>
(where $\bot$ denotes any kind of failure or nontermination), then indeed:
`destroy g (unfoldr p e) = g p e`

### 2.2 In the presence of seq

This is the more interesting setting, given that in Haskell there is no way to restrict the use of
seq
, so in any given program we must be prepared for the possibility that the
g
appearing in the
foldr
/
build
- or the
destroy
/
unfoldr
-rule is defined using
seq
.

Unsurprisingly, it is also the setting in which more can go wrong than above.

#### 2.2.1 foldr/build

In the presence of
seq
, the
foldr
/
build
-rule is not anymore a semantic equivalence.

The instance

```g = seq
c = undefined
n = 0```
shows, via similar "evaluations" as above, that the right-hand side (
g c n
) can be strictly less defined than the left-hand side (
foldr c n (build g)
).

The converse cannot happen, because the following always holds:

`foldr c n (build g) <math>\sqsupseteq</math> g c n`

Moreover, semantic equivalence can again be recovered by putting restrictions on the involved functions.

More precisely, if
(c <math>\bot~\bot)\neq\bot</math>
and
n <math>\neq\bot</math>
, then even in the presence of
seq
:
`foldr c n (build g) = g c n`

#### 2.2.2 destroy/unfoldr

Contrary to the situation without
seq
, now also the
destroy
/
unfoldr
-rule may decrease the definedness of a program.

This is witnessed by the following instance:

```g = \x y -> seq x 0
p = undefined
e = 0```
Here the left-hand side of the rule (
destroy g (unfoldr p e)
) yields

, while the right-hand side (
g p e
) yields
undefined
.

Conditions for semantic approximation in either direction can be given as follows.

If
p <math>\neq\bot</math>
and
(p <math>\bot</math>)<math>\in\{\bot,</math>Just <math>\bot\}</math>
, then:
`destroy g (unfoldr p e) <math>\sqsubseteq</math> g p e`
If
p
is strict and total and never returns
Just <math>\bot</math>
, then:
`destroy g (unfoldr p e) <math>\sqsupseteq</math> g p e`

Of course, conditions for semantic equivalence can be obtained by combining the two laws above.

## 3 Literature

Various parts of the above story, and elaborations thereof, are also told in the following papers:

• A. Gill, J. Launchbury, and S.L. Peyton Jones. A short cut to deforestation. Functional Programming Languages and Computer Architecture, Proceedings, pages 223-232, ACM Press, 1993.
• J. Svenningsson. Shortcut fusion for accumulating parameters & zip-like functions. International Conference on Functional Programming, Proceedings, pages 124-132, ACM Press, 2002.
• P. Johann and J. Voigtländer. Free theorems in the presence of seq. Principles of Programming Languages, Proceedings, pages 99-110, ACM Press, 2004.
• P. Johann. On proving the correctness of program transformations based on free theorems for higher-order polymorphic calculi. Mathematical Structures in Computer Science, 15:201-229, 2005.
• P. Johann and J. Voigtländer. The impact of seq on free theorems-based program transformations. Fundamenta Informaticae, 69:63-102, 2006.
• J. Voigtländer and P. Johann. Selective strictness and parametricity in structural operational semantics. Technical Report TUD-FI06-02, Technische Universität Dresden, 2006.