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.