Two examples, one where
Proxy is necessary, and one where
Proxy doesn't fundamentally change the types, but I tend to use it anyway.
Proxy or some equivalent trick is necessary when there's some intermediate type, not exposed in the normal type signature, that you want the consumer to be able to specify. Perhaps the intermediate type changes the semantics, such as
read . show :: String -> String. With
ScopedTypeVariables enabled, I'd write
f :: forall proxy a. (Read a, Show a) => proxy a -> String -> String
f _ = (show :: a -> String) . read
> f (Proxy :: Proxy Int) "3"
> f (Proxy :: Proxy Bool) "3"
"*** Exception: Prelude.read: no parse
The proxy parameter allows me to expose
a as a type parameter.
show . read is kind of a stupid example. A better situation may be where some algorithm uses a generic collection internally, where the collection type selected has some performance characteristics that you want to the consumer to be able to control without requiring (or permitting) them to provide or receive the intermediate value.
Something like this, using
fgl types, where we don't want to expose the internal
Data type. (Perhaps someone can suggest an appropriate algorithm for this example?)
f :: Input -> Output
f = g . h
h :: Gr graph Data => Input -> graph Data
g :: Gr graph Data => graph Data -> Output
Exposing a proxy argument would allow the user to select between a Patricia tree or a normal tree graph implementation.
Proxy as API or implementation convenience
I sometimes use
Proxy as a tool to choose a typeclass instance, especially in recursive or inductive class instances. Consider the
MightBeA class I wrote in this answer about using nested
class MightBeA t a where
isA :: proxy t -> a -> Maybe t
fromA :: t -> a
instance MightBeA t t where
isA _ = Just
fromA = id
instance MightBeA t (Either t b) where
isA _ (Left i) = Just i
isA _ _ = Nothing
fromA = Left
instance MightBeA t b => MightBeA t (Either a b) where
isA p (Right xs) = isA p xs
isA _ _ = Nothing
fromA = Right . fromA
The idea is to extract a
Maybe Int from, say,
Either String (Either Bool Int). The type of
isA is basically
a -> Maybe t. There are two reasons to use a proxy here:
First, it eliminates type signatures for the consumer. You can call
isA (Proxy :: Proxy Int) rather than
isA :: MightBeA Int a => a -> Maybe Int.
Second, it's easier for me to think through the inductive case by just passing the proxy through. With
ScopedTypeVariables, the class can be rewritten without a proxy argument; the inductive case would be implemented as
instance MightBeA' t b => MightBeA' t (Either a b) where
-- no proxy argument
isA' (Right xs) = (isA' :: b -> Maybe t) xs
isA' _ = Nothing
fromA' = Right . fromA'
This isn't really a big change in this case; if the type signature of
isA was considerably more complex, using the proxy would be a big improvement.
When the use is exclusively for implementation convenience, I'd typically export a wrapper function so the user needn't provide the proxy.
In all of my examples, the type parameter
a doesn't add anything useful to the output type itself. (In the first two examples, it's unrelated to the output type; in the last example, it's redundant of the output type.) If I returned a
Tagged a x, the consumer would invariably untag it immediately. Furthermore, the user will have to write out the type of
x in full, which is sometimes very inconvenient because it's some complicated intermediate type. (Maybe someday we'll be able to use
_ in type signatures...)
(I'm interested to hear other answers on this sub-question; I've literally never written anything using
Tagged (without rewriting it in short order using
Proxy) and wonder whether I'm missing something.)