In this programming problem, the input is an `n`

×`m`

integer matrix. Typically, `n`

≈ 10^{5} and `m`

≈ 10. The official solution (1606D, Tutorial) is quite imperative: it involves some matrix manipulation, precomputation and aggregation. For fun, I took it as an STUArray implementation exercise.

## Issue

I have managed to implement it using STUArray, but still the program takes way more memory than permitted (256MB). Even when run locally, the maximum resident set size is >400 MB. On profiling, reading from stdin seems to be dominating the memory footprint:

Functions `readv`

and `readv.readInt`

, responsible for parsing integers and saving them into a 2D list, are **taking around 50-70 MB, as opposed to around 16 MB** = (10^{6} integers) × (8 bytes per integer + 8 bytes per link).

Is there a hope I can **get the total memory below 256 MB?** I'm already using `Text`

package for input. Maybe I should avoid lists altogether and **directly read integers from stdin to the array. How can we do that?** Or, is the issue elsewhere?

### Code

```
{-# OPTIONS_GHC -O2 #-}
module CF1606D where
import qualified Data.Text as T
import qualified Data.Text.IO as TI
import qualified Data.Text.Read as TR
import Control.Monad
import qualified Data.List as DL
import qualified Data.IntSet as DS
import Control.Monad.ST
import Data.Array.ST.Safe
import Data.Int (Int32)
import Data.Array.Unboxed
solve :: IO ()
solve = do
~[n,m] <- readv
-- 2D list
input <- {-# SCC input #-} replicateM (fromIntegral n) readv
let
ints = [1..]
sorted = DL.sortOn (head.fst) (zip input ints)
(rows,indices) = {-# SCC rows_inds #-} unzip sorted
-- 2D list converted into matrix:
matrix = mat (fromIntegral n) (fromIntegral m) rows
infinite = 10^7
asc x y = [x,x+1..y]
desc x y = [y,y-1..x]
-- Four prefix-matrices:
tlMax = runSTUArray $ prefixMat max 0 asc asc (subtract 1) (subtract 1) =<< matrix
blMin = runSTUArray $ prefixMat min infinite desc asc (+1) (subtract 1) =<< matrix
trMin = runSTUArray $ prefixMat min infinite asc desc (subtract 1) (+1) =<< matrix
brMax = runSTUArray $ prefixMat max 0 desc desc (+1) (+1) =<< matrix
good _ (i,j)
| tlMax!(i,j) < blMin!(i+1,j) && brMax!(i+1,j+1) < trMin!(i,j+1) = Left (i,j)
| otherwise = Right ()
{-# INLINABLE good #-}
nearAns = foldM good () [(i,j)|i<-[1..n-1],j<-[1..m-1]]
ans = either (\(i,j)-> "YES\n" ++ color n (take i indices) ++ " " ++ show j) (const "NO") nearAns
putStrLn ans
type I = Int32
type S s = (STUArray s (Int, Int) I)
type R = Int -> Int -> [Int]
type F = Int -> Int
mat :: Int -> Int -> [[I]] -> ST s (S s)
mat n m rows = newListArray ((1,1),(n,m)) $ concat rows
prefixMat :: (I->I->I) -> I -> R -> R -> F -> F -> S s -> ST s (S s)
prefixMat opt worst ordi ordj previ prevj mat = do
((ilo,jlo),(ihi,jhi)) <- getBounds mat
pre <- newArray ((ilo-1,jlo-1),(ihi+1,jhi+1)) worst
forM_ (ordi ilo ihi) $ \i-> do
forM_ (ordj jlo jhi) $ \j -> do
matij <- readArray mat (i,j)
prei <- readArray pre (previ i,j)
prej <- readArray pre (i, prevj j)
writeArray pre (i,j) (opt (opt prei prej) matij)
return pre
color :: Int -> [Int] -> String
color n inds = let
temp = DS.fromList inds
colors = [if DS.member i temp then 'B' else 'R' | i<-[1..n]]
in colors
readv :: Integral t => IO [t]
readv = map readInt . T.words <$> TI.getLine where
readInt = fromIntegral . either (const 0) fst . TR.signed TR.decimal
{-# INLINABLE readv #-}
main :: IO ()
main = do
~[n] <- readv
replicateM_ n solve
```

**Quick description of the code above:**

- Read
`n`

rows each having`m`

integers. - Sort the rows by their first element.
- Now compute four 'prefix matrices', one from each corner. For top-left and bottom-right corners, it's the prefix-maximum, and for the other two corners, it's the prefix-minimum that we need to compute.
- Find a cell [i,j] at which these prefix matrices satisfy the following condition: top_left [i,j] < bottom_left [i,j] and top_right [i,j] > bottom_right [i,j]
- For rows 1 through i, mark their original indices (i.e. position in the unsorted input matrix) as Blue. Mark the rest as Red.

**Sample input and Commands**

Sample input: inp3.txt.

Command:

```
> stack ghc -- -main-is CF1606D.main -with-rtsopts="-s -h -p -P" -rtsopts -prof -fprof-auto CF1606D
> gtime -v ./CF1606D < inp3.txt > outp
...
...
MUT time 2.990s ( 3.744s elapsed) # RTS -s output
GC time 4.525s ( 6.231s elapsed) # RTS -s output
...
...
Maximum resident set size (kbytes): 408532 # >256 MB (gtime output)
> stack exec -- hp2ps -t0.1 -e8in -c CF1606D.hp && open CF1606D.ps
```

**Question about GC:** As shown above in the +RTS -s output, GC seems to be taking longer than the actual logic execution. Is this normal? Is there a way to visualize the GC activity over time? I tried making matrices strict but that didn't have any impact.

Probably this is not a functional-friendly problem at all (although I'll be happy to be disproved on this). For example, **Java uses GC too but there are lots of successful Java submissions.** Still, I want to see how far I can push. Thanks!

`vector<vector<int>>`

, instead of a monolithic matrix. That allows you to re-use rows or at least garbage-collecting them individually.`prefixMat`

, and the inner arrays should probably still be unboxed.`listUArray :: Ix a => (a, a) -> [e] -> UArray a e; listUArray (lo,hi) xs = runSTUArray (newListArray (lo,hi) xs)`

and met with`Could not deduce (MArray (STUArray s) e (GHC.ST.ST s))`

. Replacing`e`

with`Int`

seems to fix the issue, but replacing`e`

with`UArray Int Int`

brings back the error. What am I missing?`matrix`

(into which you pack the ints from the lists) is a program in the`ST`

monad, as opposed to the final matrix afterrunningthe`ST`

program. You then use in 4 entirely separate`runSTUArray`

calls; I'd worry that this would repeat the work of building the starting array from the lists, which means the lists can't be garbage collected. But maybe this is how you're supposed to use this API and it's actually fine.2more comments