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Consider you have a table with 3 keys (A,B,C) and 1 value (D) that you would like to fetch. We will always ensure that there are no repeating rows with the same set of keys and different value. Something of this sort

A    | B    | C    | D
========================
a1   | b1   | c1   | d1
a1   | b1   | c2   | d1
a3   | b2   | c3   | d1
a2   | b3   | c2   | d2
a2   | b1   | c2   | d2
a2   | b2   | c3   | d3

(We would never have "a1,b1,c1,d1" and "a1,b1,c1,d2" at the same time in the table since this is conflicting)

This currently has 6 entries. Now suppose we start supporting the use of "star" (or "ALL") in the keys. When we try to fetch the value of D for a query set of keys, the maximal matching row is selected (maximal matching in the sense that the row where the maximum number of keys in A,B,C match exactly and the rest match with "star")

Sample resultant table (This is just one option, there are many other solutions as well)

A    | B    | C    | D
========================
*    | *    | *    | d1
a2   | *    | *    | d2
a2   | b2   | c3   | d3

This has only 3 entries which is half of the initial table. The compression would only increase as we start increasing the amount of data in the table and the number of keys etc.

Is there any algorithm that we can use to perform this kind of an optimization? Even a bruteforce/sub optimal solution is appreciated since I am currently clueless as to how this can be done.

Thanks!

0

If table is ordered (and you cannot change that order), simply count for all cols until all values change, the last changed fields will be fixed, the others will be asterisks. Repeat until EOF.

If you can reorder the table, the problem looks NP-complete.

This to set cover problem: elements are the rows and sets are, for each different value x for each field i, the rows where it appear.

1,0
1,2
3,2
3,4

is the set cover problem { {1}, {1,2}, {2,3}, {3,4}, {4} }.

set cover problem to this: you can construct a problem mapping each element to 1, 2, 3, ... and creating a field for each input set.

The later problem come back into:

1,-,0,-,-
1,-,-,2,-
-,3,-,2,-
-,3,-,-,4

(- values could be null values)

If this is the case, you should use some kind of heuristic but the best solution is not feasible.

(Note: as brute force you can use any NP ("nondeterministic polynomial") algorithm, e.g. count occurences for each x value on i field, get one with maximum value and repeat; you can use backtracking, branch and bound, etc. but if you need it to be useful, you will need some heuristics and not demand the best solution)

EDITED

Without heuristic, you can enumerate all possibilities:

{-# LANGUAGE TupleSections #-}
import Data.List (sort, (\\), nub, sortBy)
import Data.Function (on)
import Data.Map (Map)
import qualified Data.Map as M

type Key  = ({- value -} String, {- icol -} Int)
type Freq = (Key, [{- irow -} Int])

-- group and count by each value on each column
frequencies :: [[String]] -> [Freq]
frequencies = M.assocs . M.fromListWith (++) . concat . zipWith row [1..]
    where row ir rw = [((x, ic), [ir]) | (ic, x) <- zip [1..] rw]

-- simply delete rows, drop fields if asterisks
dropRows :: [Int] -> [Freq] -> ([Key], [Freq])
dropRows rs = dr
    where dr [] = ([], [])
          dr ((k,ps):xs) = let (ks, fs) = dr xs
                           in  case (rs \\ ps, ps \\ rs) of
                                 ([], []) -> (k:ks, fs) -- exact match
                                 (as, []) -> (  ks, fs) -- contained in
                                 ([], bs) -> (k:ks, (k,bs):fs) -- left match
                                 (as, bs) -> (  ks, (k,bs):fs) -- partial match

-- all paths
nondeterminism :: [Freq] -> [[Freq]]
nondeterminism [] = [[]]
nondeterminism fs = do
    (_,f) <- fs                     -- non determinism here, what is the best `f`?
    let (ks, ps) = dropRows f fs
    let uss@(us:_) = sortBy (compare `on` length) $ nondeterminism ps -- reduce output size
    fs' <- takeWhile (\vs -> length vs == length us) uss
    return $ map (,take 1 f) ks ++ fs'

-- format to
toTable :: [Freq] -> [[String]]
toTable fs = let m  = M.fromList [((ic, ir), x) | ((x, ic), rs) <- fs, ir <- rs]
                 us = nub $ sort $ map fst $ M.keys m
                 vs = nub $ sort $ map snd $ M.keys m
             in  [[maybe "*" id (M.lookup (ic, ir) m) | ic <- us] | ir <- vs]

instance1 =
    [["a1", "b1", "c1", "d1"]
    ,["a1", "b1", "c2", "d1"]
    ,["a3", "b2", "c3", "d1"]
    ,["a2", "b3", "c2", "d2"]
    ,["a2", "b1", "c2", "d2"]
    ,["a2", "b2", "c3", "d3"]]

Using your example, the "best" solution is:

*Main> mapM_ (\s -> putStrLn "=======" >> mapM_ print s) $ take 3 $ sortBy (compare `on` length) $ map toTable $ nondeterminism $ frequencies instance1
=======
["*","d1"]
["a2","*"]
=======
["*","d1"]
["a2","*"]
=======
["a1","b1","*","d1"]
["a3","b2","c3","d1"]
["a2","*","*","*"]

You should define heuristic criterias to branch and bound the (big) possibilities forest.

  • Hi, could you take an example for the brute force approach you have mentioned, I'm not completely sure I understand how it would work. Thanks! – Vishal Batchu Jun 13 at 3:58
  • @VishalBatchu, I've added a naive algorithm – josejuan Jun 13 at 11:39

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