What I mean by first-order constraint
First, I'll explain what I mean by first-order constraint on arrows: Due to the way arrows desugar, you cannot use a locally bound name where an arrow command is expected in the arrow do-notation.
Here is an example to illustrate:
proc x -> f -< x + 1 desugars to
arr (\x -> x + 1) >>> f and similarly
proc x -> g x -< () would desugar to
arr (\x -> ()) >>> g x, where the second
x is a free variable. The GHC user guide explains this and says that when your arrow is also a monad you may make an instance of
ArrowApply and use
app to get around this. Something like,
proc x -> g x -<< () becomes
arr (\x -> (g x, ())) >>> app.
Yampa defines the
accumHold function with this type:
a -> SF (Event (a -> a)) a.
Due to this first-order limitation of arrows, I'm struggling to write the following function:
accumHoldNoiseR :: (RandomGen g, Random a) => (a,a) -> g -> SF (Event (a -> a)) a accumHoldNoiseR r g = proc f -> do n <- noiseR r g -< () accumHold n -< f
The definition above doesn't work because
n is not in scope after desugaring.
Or, similarly this function, where the first part of the pair to
SF is meant to be the initial value passed to
accumHold' :: SF (a,Event (a -> a)) -> a accumHold' = ...
Is there some combinator or trick that I'm missing? Or is it not possible to write these definitions without an
tl;dr: Is it possible to define
accumHoldNoiseR :: (RandomGen g, Random a) => (a,a) -> g -> SF (Event (a -> a)) a or
accumHold' :: SF (a,Event (a -> a)) -> a in yampa?
Note: There is no instance of
SF. My understanding is that it doesn't make sense to define one either. See "Programming with Arrows" for details.