Controlling memory allocation/GC in a simulation?

I'm having a bit of trouble figuring out how to reduce memory usage and GC time in a simulation running in the `State` monad. Presently I have to run the compiled code with `+RTS -K100M` to avoid stack space overflow, and the GC stats are pretty hideous (see below).

Here are relevant snippets of the code. Complete, working (GHC 7.4.1) code can be found at http://hpaste.org/68527.

``````-- Lone algebraic data type holding the simulation configuration.
data SimConfig = SimConfig {
numDimensions :: !Int            -- strict
,   numWalkers    :: !Int            -- strict
,   simArray      :: IntMap [Double] -- strict spine
,   logP          :: Seq Double      -- strict spine
,   logL          :: Seq Double      -- strict spine
,   pairStream    :: [(Int, Int)]    -- lazy (infinite) list of random vals
,   doubleStream  :: [Double]        -- lazy (infinite) list of random vals
} deriving Show

-- The transition kernel for the simulation.
simKernel :: State SimConfig ()
simKernel = do
config <- get
let arr   = simArray      config
let n     = numWalkers    config
let d     = numDimensions config
let rstm0 = pairStream    config
let rstm1 = doubleStream  config
let lp    = logP          config
let ll    = logL          config

let (a, b)    = head rstm0                           -- uses random stream
let z0 = head . map affineTransform \$ take 1 rstm1   -- uses random stream
where affineTransform a = 0.5 * (a + 1) ^ 2

let proposal  = zipWith (+) r1 r2
where r1    = map (*z0)     \$ fromJust (IntMap.lookup a arr)
r2    = map (*(1-z0)) \$ fromJust (IntMap.lookup b arr)

let logA = if val > 0 then 0 else val
where val = logP_proposal + logL_proposal - (lp `index` (a - 1)) - (ll `index` (a - 1)) + ((fromIntegral n - 1) * log z0)
logP_proposal = logPrior proposal
logL_proposal = logLikelihood proposal

let cVal       = (rstm1 !! 1) <= exp logA            -- uses random stream

let newConfig = SimConfig { simArray = if   cVal
then IntMap.update (\_ -> Just proposal) a arr
else arr
, numWalkers = n
, numDimensions = d
, pairStream   = drop 1 rstm0
, doubleStream = drop 2 rstm1
, logP = if   cVal
then Seq.update (a - 1) (logPrior proposal) lp
else lp
, logL = if   cVal
then Seq.update (a - 1) (logLikelihood proposal) ll
else ll
}

put newConfig

main = do
-- (some stuff omitted)
let sim = logL \$ (`execState` initConfig) . replicateM 100000 \$ simKernel
print sim
``````

In terms of the heap, a profile seems to cue that the `System.Random` functions, in addition to `(,)`, are memory culprits. I can't include an image directly, but you can see a heap profile here: http://i.imgur.com/5LKxX.png.

I have no idea how to reduce the presence of those things any further. The random variates are generated outside the `State` monad (to avoid splitting the generator on every iteration), and I believe the only instance of `(,)` inside `simKernel` arises when plucking a pair from the lazy list (`pairStream`) that is included in the simulation configuration.

The stats, including GC, are as follows:

``````  1,220,911,360 bytes allocated in the heap
787,192,920 bytes copied during GC
186,821,752 bytes maximum residency (10 sample(s))
1,030,400 bytes maximum slop
449 MB total memory in use (0 MB lost due to fragmentation)

Tot time (elapsed)  Avg pause  Max pause
Gen  0      2159 colls,     0 par    0.80s    0.81s     0.0004s    0.0283s
Gen  1        10 colls,     0 par    0.96s    1.09s     0.1094s    0.4354s

INIT    time    0.00s  (  0.00s elapsed)
MUT     time    0.95s  (  0.97s elapsed)
GC      time    1.76s  (  1.91s elapsed)
EXIT    time    0.00s  (  0.00s elapsed)
Total   time    2.72s  (  2.88s elapsed)

%GC     time      64.9%  (66.2% elapsed)

Alloc rate    1,278,074,521 bytes per MUT second

Productivity  35.1% of total user, 33.1% of total elapsed
``````

And again, I have to bump up the maximum stack size in order to even run the simulation. I know there must be a big thunk building up somewhere.. but I can't figure out where?

How can I improve the heap/stack allocation and GC in a problem like this? How can I identify where a thunk may be building up? Is the use of the `State` monad here misguided?

--

UPDATE:

I neglected to look over the output of the profiler when compiling with `-fprof-auto`. Here is the head of that output:

``````COST CENTRE                       MODULE                             no.     entries  %time %alloc   %time %alloc

MAIN                              MAIN                                58           0    0.0    0.0   100.0  100.0
main                             Main                               117           0    0.0    0.0   100.0  100.0
main.randomList                 Main                               147           1   62.0   55.5    62.0   55.5
main.arr                        Main                               142           1    0.0    0.0     0.0    0.0
streamToAssocList              Main                               143           1    0.0    0.0     0.0    0.0
streamToAssocList.go          Main                               146           5    0.0    0.0     0.0    0.0
main.pairList                   Main                               137           1    0.0    0.0     9.5   16.5
consPairStream                 Main                               138           1    0.7    0.9     9.5   16.5
consPairStream.ys             Main                               140           1    4.3    7.8     4.3    7.8
consPairStream.xs             Main                               139           1    4.5    7.8     4.5    7.8
main.initConfig                 Main                               122           1    0.0    0.0     0.0    0.0
logLikelihood                  Main                               163           0    0.0    0.0     0.0    0.0
logPrior                       Main                               161           5    0.0    0.0     0.0    0.0
main.sim                        Main                               118           1    1.0    2.2    28.6   28.1
simKernel                      Main                               120           0    4.8    5.1    27.6   25.8
``````

I'm not sure how to interpret this exactly, but the lazy stream of random doubles, `randomList`, makes me wince. I have no idea how that could be improved.

-
I've switched to the System.Random.MWC generator and observed an instant boost in performance. I still have to use +RTS -K100M at runtime, though, so I guess a large thunk is still building up somewhere. An updated snapshot of the code is here: hpaste.org/68532, and an improved heap profile is here: i.imgur.com/YzoNE.png. – jtobin May 15 '12 at 6:42
I presume you're also using `ghc -O2` ? – Don Stewart May 15 '12 at 13:43
Right; compiling with `ghc --make -O2 blah.hs -fllvm -funbox-strict-fields -rtsopts`. – jtobin May 15 '12 at 19:35

I've updated the hpaste with a working example. It looks like the culprits are:

• Missing strictness annotations in three `SimConfig` fields: `simArray`, `logP` and `logL`
```    data SimConfig = SimConfig {
numDimensions :: !Int            -- strict
,   numWalkers    :: !Int            -- strict
,   simArray      :: !(IntMap [Double]) -- strict spine
,   logP          :: !(Seq Double)      -- strict spine
,   logL          :: !(Seq Double)      -- strict spine
,   pairStream    :: [(Int, Int)]    -- lazy
,   doubleStream  :: [Double]        -- lazy
} deriving Show
```
• `newConfig` was never evaluated in the `simKernel` loop due to `State` being lazy. Another alternative would be to use the strict `State` monad instead.

``````put \$! newConfig
``````
• `execState ... replicateM` also builds thunks. I originally replaced this with a `foldl'` and moved the `execState` into the fold, but I would think swapping in `replicateM_` is equivalent and easier to read:

``````let sim = logL \$ execState (replicateM_ epochs simKernel) initConfig
--  sim = logL \$ foldl' (const . execState simKernel) initConfig [1..epochs]
``````

And a few calls to `mapM .. replicate` have been replaced with `replicateM`. Particularly noteworthy in `consPairList` where it reduces memory usage quite a bit. There is still room for improvement but the lowest hanging fruit involves unsafeInterleaveST... so I stopped.

I have no idea if the output results are what you want:

```fromList [-4.287033457733427,-1.8000404912760795,-5.581988678626085,-0.9362372340483293,-5.267791907985331]
```

But here are the stats:

```     268,004,448 bytes allocated in the heap
70,753,952 bytes copied during GC
16,014,224 bytes maximum residency (7 sample(s))
1,372,456 bytes maximum slop
40 MB total memory in use (0 MB lost due to fragmentation)

Tot time (elapsed)  Avg pause  Max pause
Gen  0       490 colls,     0 par    0.05s    0.05s     0.0001s    0.0012s
Gen  1         7 colls,     0 par    0.04s    0.05s     0.0076s    0.0209s

INIT    time    0.00s  (  0.00s elapsed)
MUT     time    0.12s  (  0.12s elapsed)
GC      time    0.09s  (  0.10s elapsed)
EXIT    time    0.00s  (  0.00s elapsed)
Total   time    0.21s  (  0.22s elapsed)

%GC     time      42.2%  (45.1% elapsed)

Alloc rate    2,241,514,569 bytes per MUT second

Productivity  57.8% of total user, 53.7% of total elapsed
```
-
Wow. Adding strictness annotations to the ADT record types alone makes the memory use plummet. I guess I misunderstood the meaning of a 'strict-spined' data structure, because I didn't even try to add strictness annotations there. I think it would have taken me quite awhile to figure out that I should be folding the `execState`. Great stuff, thanks. – jtobin May 15 '12 at 10:15
@jtobin The value still needs to be evaluated to WHNF, regardless of it's internal strictness guarantees. I've also updated the `execState` call to be more clear, using `replicateM_` instead of `foldl'`. If you look at the results of `runState (replicateM 10 (return ())) ()` vs. the `replicateM_` variant in GHCi it should be obvious why this is necessary. – Nathan Howell May 15 '12 at 17:36