{-# LANGUAGE PatternGuards, ViewPatterns #-}
{-
map f [] = []
map f (x:xs) = f x : map f xs
foldr f z [] = z
foldr f z (x:xs) = f x (foldr f z xs)
foldl f z [] = z
foldl f z (x:xs) = foldl f (f z x) xs
-}
{-
f (x:xs) = negate x + f xs ; f [] = 0 -- f xs = foldr ((+) . negate) 0 xs
f (x:xs) = x + 1 : f xs ; f [] = [] -- f xs = map (+ 1) xs
f z (x:xs) = f (z*x) xs ; f z [] = z -- f z xs = foldl (*) z xs
f a (x:xs) b = x + a + b : f a xs b ; f a [] b = [] -- f a xs b = map (\ x -> x + a + b) xs
f [] a = return a ; f (x:xs) a = a + x >>= \fax -> f xs fax -- f xs a = foldM (+) a xs
foos [] x = x; foos (y:ys) x = foo y $ foos ys x -- foos ys x = foldr foo x ys
f [] y = y; f (x:xs) y = f xs $ g x y -- f xs y = foldl (flip g) y xs
f [] y = y; f (x : xs) y = let z = g x y in f xs z -- f xs y = foldl (flip g) y xs
f [] y = y; f (x:xs) y = f xs (f xs z)
-}
module Hint.ListRec(listRecHint) where
import Hint.Type
import Util
import Hint.Util
import Data.List
import Data.Maybe
import Data.Ord
import Data.Either
import Control.Monad
listRecHint :: DeclHint
listRecHint _ _ = concatMap f . universe
where
f o = maybeToList $ do
let x = o
(x, addCase) <- findCase x
(use,severity,x) <- matchListRec x
let y = addCase x
guard $ recursiveStr `notElem` varss y
return $ idea severity ("Use " ++ use) o y
recursiveStr = "_recursive_"
recursive = toNamed recursiveStr
-- recursion parameters, nil-case, (x,xs,cons-case)
-- for cons-case delete any recursive calls with xs from them
-- any recursive calls are marked "_recursive_"
data ListCase = ListCase [String] Exp_ (String,String,Exp_)
deriving Show
data BList = BNil | BCons String String
deriving (Eq,Ord,Show)
-- function name, parameters, list-position, list-type, body (unmodified)
data Branch = Branch String [String] Int BList Exp_
deriving Show
---------------------------------------------------------------------
-- MATCH THE RECURSION
matchListRec :: ListCase -> Maybe (String,Severity,Exp_)
matchListRec o@(ListCase vs nil (x,xs,cons))
| [] <- vs, nil ~= "[]", InfixApp _ lhs c rhs <- cons, opExp c ~= ":"
, fromParen rhs =~= recursive, xs `notElem` vars lhs
= Just $ (,,) "map" Error $ appsBracket
[toNamed "map", niceLambda [x] lhs, toNamed xs]
| [] <- vs, App2 op lhs rhs <- view cons
, vars op `disjoint` [x,xs]
, fromParen rhs == recursive, xs `notElem` vars lhs
= Just $ (,,) "foldr" Warning $ appsBracket
[toNamed "foldr", niceLambda [x] $ appsBracket [op,lhs], nil, toNamed xs]
| [v] <- vs, view nil == Var_ v, App _ r lhs <- cons, r =~= recursive
, xs `notElem` vars lhs
= Just $ (,,) "foldl" Warning $ appsBracket
[toNamed "foldl", niceLambda [v,x] lhs, toNamed v, toNamed xs]
| [v] <- vs, App _ ret res <- nil, ret ~= "return", res ~= "()" || view res == Var_ v
, [Generator _ (view -> PVar_ b1) e, Qualifier _ (fromParen -> App _ r (view -> Var_ b2))] <- asDo cons
, b1 == b2, r == recursive, xs `notElem` vars e
, name <- "foldM" ++ ['_'|res ~= "()"]
= Just $ (,,) name Warning $ appsBracket
[toNamed name, niceLambda [v,x] e, toNamed v, toNamed xs]
| otherwise = Nothing
-- Very limited attempt to convert >>= to do, only useful for foldM/foldM_
asDo :: Exp_ -> [Stmt S]
asDo (view -> App2 bind lhs (Lambda _ [v] rhs)) = [Generator an v lhs, Qualifier an rhs]
asDo (Do _ x) = x
asDo x = [Qualifier an x]
---------------------------------------------------------------------
-- FIND THE CASE ANALYSIS
findCase :: Decl_ -> Maybe (ListCase, Exp_ -> Decl_)
findCase x = do
FunBind _ [x1,x2] <- return x
Branch name1 ps1 p1 c1 b1 <- findBranch x1
Branch name2 ps2 p2 c2 b2 <- findBranch x2
guard (name1 == name2 && ps1 == ps2 && p1 == p2)
[(BNil, b1), (BCons x xs, b2)] <- return $ sortBy (comparing fst) [(c1,b1), (c2,b2)]
b2 <- transformAppsM (delCons name1 p1 xs) b2
(ps,b2) <- return $ eliminateArgs ps1 b2
let ps12 = let (a,b) = splitAt p1 ps1 in map toNamed $ a ++ xs : b
return (ListCase ps b1 (x,xs,b2)
,\e -> FunBind an [Match an (toNamed name1) ps12 (UnGuardedRhs an e) Nothing])
delCons :: String -> Int -> String -> Exp_ -> Maybe Exp_
delCons func pos var (fromApps -> (view -> Var_ x):xs) | func == x = do
(pre, (view -> Var_ v):post) <- return $ splitAt pos xs
guard $ v == var
return $ apps $ recursive : pre ++ post
delCons _ _ _ x = return x
eliminateArgs :: [String] -> Exp_ -> ([String], Exp_)
eliminateArgs ps cons = (remove ps, transform f cons)
where
args = [zs | z:zs <- map fromApps $ universeApps cons, z =~= recursive]
elim = [all (\xs -> length xs > i && view (xs !! i) == Var_ p) args | (i,p) <- zip [0..] ps] ++ repeat False
remove = concat . zipWith (\b x -> [x | not b]) elim
f (fromApps -> x:xs) | x == recursive = apps $ x : remove xs
f x = x
---------------------------------------------------------------------
-- FIND A BRANCH
findBranch :: Match S -> Maybe Branch
findBranch x = do
Match _ name ps (UnGuardedRhs _ bod) Nothing <- return x
(a,b,c) <- findPat ps
return $ Branch (fromNamed name) a b c $ simplifyExp bod
findPat :: [Pat_] -> Maybe ([String], Int, BList)
findPat ps = do
ps <- mapM readPat ps
[i] <- return $ findIndices isRight_ ps
let (left,[right]) = partitionEithers ps
return (left, i, right)
readPat :: Pat_ -> Maybe (Either String BList)
readPat (view -> PVar_ x) = Just $ Left x
readPat (PParen _ (PInfixApp _ (view -> PVar_ x) (Special _ Cons{}) (view -> PVar_ xs))) = Just $ Right $ BCons x xs
readPat (PList _ []) = Just $ Right BNil
readPat _ = Nothing