I'm solving a knapsack problem in Haskell using Dynamic Programing. My first attempt was to build a two-dimensional table. But the memory easily gets blown up when the input is large(e.g. a 100 * 3190802 table).
Knowing that any given row
i only depends on the row
(i - 1), I instead write a function in the hope to take the advantage of tail recursion:
import Data.Vector (Vector, (!)) import qualified Data.Vector as V -- n items, k capacity, vs values, ws weights ans:: Int -> Int -> Vector Int -> Vector Int -> Int ans n k vs ws = let row = initRow k vs ws in row ! k initRow :: Int -> Vector Int -> Vector Int -> Vector Int initRow k vs ws = itbl 1 $ V.replicate (k + 1) 0 where n = V.length vs itbl i row | i > n = row | otherwise = itbl (i + 1) $ V.generate (k + 1) gen where gen w = let w_i = ws ! (i - 1) no_i = row ! w ok_i = row ! (w - w_i) + (vs ! (i - 1)) in if w < w_i then no_i else max no_i ok_i
As shown in the code,
itbl calls itself recursively and no further computation is made on its return value. However, I still see memory grow relentlessly in
VIRT PID USER PR NI RES SHR S %CPU %MEM TIME+ COMMAND 1214m 9878 root 20 0 424m 1028 S 40.8 85.6 0:16.80 ghc
Is there anything in the code that prevents the compiler to produce optimized code for tail recursion?