# Why does folding Events and Behaviors use so much memory?

I am currently exploring the possibility to use basic containers to give FRP networks more structure and by that to create more sophisticated event networks easier.

Note: I use ordrea but had the same problem with reactive-banana too, so I guess this problem is not specific to the chosen frp implementation.

In this special case I am using a simple `Matrix` to store `Events`:

``````newtype Matrix (w :: Nat) (h :: Nat) v a where
Matrix :: Vector a -> Matrix w h v a

-- deriving instances: Functor, Foldable, Traversable, Applicative
``````

`Matrix` is basically just a thin wrapper around `Data.Vector` and most functions I'll use are basically the same as the corresponding `Vector` ones. The notable exception is indexing, but that should be self explanatory.

With this I can define matrices of events like `Matrix 10 10 (Event Double)` and are able to define basic convolution algorithms on that:

``````applyStencil :: (KnownNat w, KnownNat h, KnownNat w', KnownNat h')
=> M.Matrix w' h' (a -> c)
-> M.Matrix w h (Event a)
-> M.Matrix w h (Event c)
applyStencil s m = M.generate stencil
where stencil x y = fold \$ M.imap (sub x y) s
sub x0 y0 x y g = g <\$> M.clampedIndex m (x0 - halfW + x) (y0 - halfH + y)
halfW = M.width s `div` 2
halfH = M.height s `div` 2
``````

Notes:

• `M.generate :: (Int -> Int -> a) -> M.Matrix w h a` and

`M.imap :: (Int -> Int -> a -> b) -> M.Matrix w h a -> M.Matrix w h b`

are just wrappers around `Vector.generate` and `Vector.imap` respectively.

• `M.clampedIndex` clamps indices into the bounds of the matrix.
• `Event` is an instance of `Monoid` which is why it is possible to just `fold` the `Matrix w' h' (Event c)` returned by `M.imap (sub x y) s`.

I have a setup approximately like this:

``````let network = do
-- inputs triggered from external events
let inputs :: M.Matrix 128 128 (Event Double)

-- stencil used:
let stencil :: M.Matrix 3 3 (Double -> Double)
stencil = fmap ((*) . (/16)) \$ M.fromList [1,2,1,2,4,2,1,2,1]

-- convolute matrix by applying stencil
let convoluted = applyStencil stencil inputs

-- collect events in order to display them later
-- type: M.Matrix 128 128 (Behavior [Double])
let behaviors = fmap eventToBehavior convoluted

-- now there is a neat trick you can play because Matrix
-- is Traversable and Behaviors are Applicative:
-- type: Behavior (Matrix 128 128 [Double])
return \$ Data.Traversable.sequenceA behaviors
``````

Using something like this I am triggering ~15kEvents/s with no problems and lots of headroom in that regard.

Problem is that as soon as I sample the network I can only get about two samples per second from it:

``````main :: IO ()
main = do

-- initialize the network
sample <- start network

forever \$ do

-- not all of the 128*128 inputs are triggered each "frame"
triggerInputs

-- sample the network
mat <- sample

-- display the matrix somehow (actually with gloss)
displayMatrix mat
``````

So far I have made the following observations:

• Profiling tells me that productivity is very low (4%-8%)
• Most of the time is spend by the garbage collector in Gen 1 (~95%)
• `Data.Matrix.foldMap` (ie `fold`) is allocating the most memory (~45%, as per `-p`)

• When I was still working with reactive-banana Heinrich Apfelmus recommended that tree based traversals are a better fit for behaviors¹. I tried that for `sequenceA`, `fold` and `traverse` with no success.

• I suspected that the newtype wrapper was preventing vectors fusion rules to fire². This is most likely not the culprit.

At this point I have spent the better part of the week searching for a solution to this problem. Intuitively I'd say that sampling should be much faster and and `foldMap` should not create so much garbage memory. Any ideas?

• I have no idea what the problem is (because I know nothing about these FRP frameworks) but I don't think `traverse` and `sequenceA` and such are likely what he meant—those are actually based on list traversals. Nov 20, 2014 at 16:09
• @dfeuer `traverse` and `sequenceA` from `Data.Traversable`. I thought that was clear :)
– fho
Nov 20, 2014 at 16:39
• I can't say anything about `ordrea`. But Tim is right, every matrix corresponds to `128*128 = 16384` nodes. You may be much better off using an event of matrices `Event (Matrix ...)` instead of a matrix of events `Matrix (Event ...)`. In the latter case, I think that `Vector` doesn't buy you anything at all, you could use nested lists and still get the same (abysmal) performance. Nov 20, 2014 at 23:16
• @Florian: I will believe you as soon as you use a plain list for the matrix of events, `[[Event Double]]`. :-) In general, your observation that one event occurrence should only trigger `3*3 = 9` other events is sound, though However, you need to be careful about observing this. The standard `sequenceA` combinator will definitely not work, because it "touches" all behavior updates. You're trying to write an incremental algorithm here, and you have to make sure that every "incremental update" makes only small changes to the end result -- running time is proportional to the size of the change. Nov 21, 2014 at 10:26
• While I haven’t profiled, it looks to me like you’re building a lot of large intermediate data structures unnecessarily, particularly in `foldMapTree`, which splits a list and then does a non-tail-call operation on both lazily-evaluated lists. You might try a strict left fold or an eagerly-evaluated lazy right fold instead. Jan 2, 2018 at 1:42