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Recently, I implemented a naïve DPLL Sat Solver in Haskell, adapted from John Harrison's Handbook of Practical Logic and Automated Reasoning.

DPLL is a variety of backtrack search, so I want to experiment with using the Logic monad from Oleg Kiselyov et al. I don't really understand what I need to change, however.

Here's the code I've got.

• What code do I need to change to use the Logic monad?
• Bonus: Is there any concrete performance benefit to using the Logic monad?

``````{-# LANGUAGE MonadComprehensions #-}
module DPLL where
import Prelude hiding (foldr)
import Data.Set.Monad (Set, (\\), member, partition, toList, foldr)
import Data.Maybe (listToMaybe)

-- "Literal" propositions are either true or false
data Lit p = T p | F p deriving (Show,Ord,Eq)

neg :: Lit p -> Lit p
neg (T p) = F p
neg (F p) = T p

-- We model DPLL like a sequent calculus
-- LHS: a set of assumptions / partial model (set of literals)
-- RHS: a set of goals
data Sequent p = (Set (Lit p)) :|-: Set (Set (Lit p)) deriving Show

{- --------------------------- Goal Reduction Rules -------------------------- -}
{- "Unit Propogation" takes literal x and A :|-: B to A,x :|-: B',
- where B' has no clauses with x,
- and all instances of -x are deleted -}
unitP :: Ord p => Lit p -> Sequent p -> Sequent p
unitP x (assms :|-:  clauses) = (assms' :|-:  clauses')
where
assms' = (return x) `mplus` assms
clauses_ = [ c | c <- clauses, not (x `member` c) ]
clauses' = [ [ u | u <- c, u /= neg x] | c <- clauses_ ]

{- Find literals that only occur positively or negatively
- and perform unit propogation on these -}
pureRule :: Ord p => Sequent p -> Maybe (Sequent p)
pureRule sequent@(_ :|-:  clauses) =
let
sign (T _) = True
sign (F _) = False
-- Partition the positive and negative formulae
(positive,negative) = partition sign (join clauses)
-- Compute the literals that are purely positive/negative
purePositive = positive \\ (fmap neg negative)
pureNegative = negative \\ (fmap neg positive)
pure = purePositive `mplus` pureNegative
-- Unit Propagate the pure literals
sequent' = foldr unitP sequent pure
in if (pure /= mzero) then Just sequent'
else Nothing

{- Add any singleton clauses to the assumptions
- and simplify the clauses -}
oneRule :: Ord p => Sequent p -> Maybe (Sequent p)
oneRule sequent@(_ :|-:  clauses) =
do
-- Extract literals that occur alone and choose one
let singletons = join [ c | c <- clauses, isSingle c ]
x <- (listToMaybe . toList) singletons
-- Return the new simplified problem
return \$ unitP x sequent
where
isSingle c = case (toList c) of { [a] -> True ; _ -> False }

{- ------------------------------ DPLL Algorithm ----------------------------- -}
dpll :: Ord p => Set (Set (Lit p)) -> Maybe (Set (Lit p))
dpll goalClauses = dpll' \$ mzero :|-: goalClauses
where
dpll' sequent@(assms :|-: clauses) = do
-- Fail early if falsum is a subgoal
guard \$ not (mzero `member` clauses)
case (toList . join) \$ clauses of
-- Return the assumptions if there are no subgoals left
[]  -> return assms
-- Otherwise try various tactics for resolving goals
x:_ -> dpll' =<< msum [ pureRule sequent
, oneRule sequent
, return \$ unitP x sequent
, return \$ unitP (neg x) sequent ]
``````
-
...all of it, I guess. – Daniel Wagner Jul 28 '12 at 0:57
@DanielWagner: Really? The part that does the backtracking is the `msum` - I sort of thought I just needed to modify `dpll'`...? – Matt W-D Jul 28 '12 at 1:41

Ok, changing your code to use `Logic` turned out to be entirely trivial. I went through and rewrote everything to use plain `Set` functions rather than the `Set` monad, because you're not really using `Set` monadically in a uniform way, and certainly not for the backtracking logic. The monad comprehensions were also more clearly written as maps and filters and the like. This didn't need to happen, but it did help me sort through what was happening, and it certainly made evident that the one real remaining monad, that used for backtracking, was just `Maybe`.

In any case, you can just generalize the type signature of `pureRule`, `oneRule`, and `dpll` to operate over not just `Maybe`, but any `m` with the constraint `MonadPlus m =>`.

Then, in `pureRule`, your types won't match because you construct `Maybe`s explicitly, so go and change it a bit:

``````in if (pure /= mzero) then Just sequent'
else Nothing
``````

becomes

``````in if (not \$ S.null pure) then return sequent' else mzero
``````

And in `oneRule`, similarly change the usage of `listToMaybe` to an explicit match so

``````   x <- (listToMaybe . toList) singletons
``````

becomes

`````` case singletons of
x:_ -> return \$ unitP x sequent  -- Return the new simplified problem
[] -> mzero
``````

And, outside of the type signature change, `dpll` needs no changes at all!

Now, your code operates over both `Maybe` and `Logic`!

to run the `Logic` code, you can use a function like the following:

``````dpllLogic s = observe \$ dpll' s
``````

You can use `observeAll` or the like to see more results.

For reference, here's the complete working code:

``````{-# LANGUAGE MonadComprehensions #-}
module DPLL where
import Prelude hiding (foldr)
import Data.Set (Set, (\\), member, partition, toList, foldr)
import qualified Data.Set as S
import Data.Maybe (listToMaybe)

-- "Literal" propositions are either true or false
data Lit p = T p | F p deriving (Show,Ord,Eq)

neg :: Lit p -> Lit p
neg (T p) = F p
neg (F p) = T p

-- We model DPLL like a sequent calculus
-- LHS: a set of assumptions / partial model (set of literals)
-- RHS: a set of goals
data Sequent p = (Set (Lit p)) :|-: Set (Set (Lit p)) --deriving Show

{- --------------------------- Goal Reduction Rules -------------------------- -}
{- "Unit Propogation" takes literal x and A :|-: B to A,x :|-: B',
- where B' has no clauses with x,
- and all instances of -x are deleted -}
unitP :: Ord p => Lit p -> Sequent p -> Sequent p
unitP x (assms :|-:  clauses) = (assms' :|-:  clauses')
where
assms' = S.insert x assms
clauses_ = S.filter (not . (x `member`)) clauses
clauses' = S.map (S.filter (/= neg x)) clauses_

{- Find literals that only occur positively or negatively
- and perform unit propogation on these -}
pureRule sequent@(_ :|-:  clauses) =
let
sign (T _) = True
sign (F _) = False
-- Partition the positive and negative formulae
(positive,negative) = partition sign (S.unions . S.toList \$ clauses)
-- Compute the literals that are purely positive/negative
purePositive = positive \\ (S.map neg negative)
pureNegative = negative \\ (S.map neg positive)
pure = purePositive `S.union` pureNegative
-- Unit Propagate the pure literals
sequent' = foldr unitP sequent pure
in if (not \$ S.null pure) then return sequent'
else mzero

{- Add any singleton clauses to the assumptions
- and simplify the clauses -}
oneRule sequent@(_ :|-:  clauses) =
do
-- Extract literals that occur alone and choose one
let singletons = concatMap toList . filter isSingle \$ S.toList clauses
case singletons of
x:_ -> return \$ unitP x sequent  -- Return the new simplified problem
[] -> mzero
where
isSingle c = case (toList c) of { [a] -> True ; _ -> False }

{- ------------------------------ DPLL Algorithm ----------------------------- -}
dpll goalClauses = dpll' \$ S.empty :|-: goalClauses
where
dpll' sequent@(assms :|-: clauses) = do
-- Fail early if falsum is a subgoal
guard \$ not (S.empty `member` clauses)
case concatMap S.toList \$ S.toList clauses of
-- Return the assumptions if there are no subgoals left
[]  -> return assms
-- Otherwise try various tactics for resolving goals
x:_ -> dpll' =<< msum [ pureRule sequent
, oneRule sequent
, return \$ unitP x sequent
, return \$ unitP (neg x) sequent ]

dpllLogic s = observe \$ dpll s
``````
-

Is there any concrete performance benefit to using the Logic monad?

TL;DR: Not that I can find; it appears that `Maybe` outperforms `Logic` since it has less overhead.

I decided to implement a simple benchmark to check the performance of `Logic` versus `Maybe`. In my test, I randomly construct 5000 CNFs with `n` clauses, each clause containing three literals. Performance is evaluated as the number of clauses `n` is varied.

In my code, I modified `dpllLogic` as follows:

``````dpllLogic s = listToMaybe \$ observeMany 1 \$ dpll s
``````

I also tested modifying `dpll` with fair disjunction, like so:

``````dpll goalClauses = dpll' \$ S.empty :|-: goalClauses
where
dpll' sequent@(assms :|-: clauses) = do
-- Fail early if falsum is a subgoal
guard \$ not (S.empty `member` clauses)
case concatMap S.toList \$ S.toList clauses of
-- Return the assumptions if there are no subgoals left
[]  -> return assms
-- Otherwise try various tactics for resolving goals
x:_ -> msum [ pureRule sequent
, oneRule sequent
, return \$ unitP x sequent
, return \$ unitP (neg x) sequent ]
>>- dpll'
``````

I then tested the using `Maybe`, `Logic`, and `Logic` with fair disjunction.

Here are the benchmark results for this test:

As we can see, `Logic` with or without fair disjunction in this case makes no difference. The `dpll` solve using the `Maybe` monad appears to run in linear time in `n`, while using the `Logic` monad incurs additional overhead. It appears that the overhead incurred plateaus off.

Here is the `Main.hs` file used to generate these test. Someone wishing to reproduce these benchmarks might wish to review Haskell's notes on profiling:

``````module Main where
import DPLL
import System.Environment (getArgs)
import System.Random
import Data.Set (fromList)

randLit = do let clauses = [ T p | p <- ['a'..'f'] ]
++ [ F p | p <- ['a'..'f'] ]
r <- randomRIO (0, (length clauses) - 1)
return \$ clauses !! r

randClause n = fmap fromList \$ replicateM n \$ fmap fromList \$ replicateM 3 randLit

main = do args <- getArgs
let n = read (args !! 0) :: Int
clauses <- replicateM 5000 \$ randClause n
-- To use the Maybe monad
--let satisfiable = filter (/= Nothing) \$ map dpll clauses
let satisfiable = filter (/= Nothing) \$ map dpllLogic clauses
putStrLn \$ (show \$ length satisfiable) ++ " satisfiable out of "
++ (show \$ length clauses)
``````
-