It is continuation of this question. Since vector library doesn't seem to have a fusible O(1) update function, I am wondering if it is possible to write a fusible O(1) update function that doesn't involve
unsafeThaw. It would use
vector stream representation, I guess - I am not familiar with how to write one using
unstream - hence, this question. The reason is this will give us the ability to write a cache-friendly update function on vector where only a narrow region of vector is being modified, and so, we don't want to walk through entire vector just to process that narrow region (and this operation can happen billions of times in each function call - so, the motivation to keep the overhead really low). The transformation functions like
map process entire vector - so they will be too slow.
I have a toy example of what I want to do, but the
upd function below uses
unsafeFreeze - it doesn't seem to be optimized away in the core, and also breaks the promise of not using the buffer further:
module Main where import Data.Vector.Unboxed as U import Data.Vector.Unboxed.Mutable as MU import Control.Monad.ST upd :: Vector Int -> Int -> Int -> Vector Int upd v i x = runST $ do v' <- U.unsafeThaw v MU.write v' i x U.unsafeFreeze v' sum :: Vector Int -> Int sum = U.sum . (\x -> upd x 0 73) . (\x -> upd x 1 61) main = print $ Main.sum $ U.fromList [1..3]
I know how to implement imperative algorithms using
STVector. In case you are wondering why this alternative approach, I want to try out this approach of using pure vectors to check how
GHC transformation of a particular algorithm differs when written using fusible pure vector streams (with monadic operations under the hood of course).
When the algorithm is written using
STVector, it doesn't seem to be as nicely iterative as I would like it to be (I guess it is harder for GHC optimizer to spot loops when there is lot of mutability strewn around). So, I am investigating this alternative approach to see I can get a nicer loop in there.