-- |An efficient implementation of 'Data.Graph.Inductive.Graph.Graph'
-- using big-endian patricia tree (i.e. "Data.IntMap").
--
-- This module provides the following specialised functions to gain
-- more performance, using GHC's RULES pragma:
--
-- * 'Data.Graph.Inductive.Graph.insNode'
--
-- * 'Data.Graph.Inductive.Graph.insEdge'
--
-- * 'Data.Graph.Inductive.Graph.gmap'
--
-- * 'Data.Graph.Inductive.Graph.nmap'
--
-- * 'Data.Graph.Inductive.Graph.emap'
--
-- Code is from Hackage `fgl` package version 5.7.0.3


module GHC.Data.Graph.Inductive.PatriciaTree
    ( Gr
    , UGr
    )
    where

import GHC.Prelude

import GHC.Data.Graph.Inductive.Graph

import           Data.IntMap         (IntMap)
import qualified Data.IntMap         as IM
import           Data.List           (sort)
import           Data.Maybe          (fromMaybe)
import           Data.Tuple          (swap)

import qualified Data.IntMap.Strict as IMS

import GHC.Generics (Generic)

import Data.Bifunctor

----------------------------------------------------------------------
-- GRAPH REPRESENTATION
----------------------------------------------------------------------

newtype Gr a b = Gr (GraphRep a b)
  deriving ((forall x. Gr a b -> Rep (Gr a b) x)
-> (forall x. Rep (Gr a b) x -> Gr a b) -> Generic (Gr a b)
forall x. Rep (Gr a b) x -> Gr a b
forall x. Gr a b -> Rep (Gr a b) x
forall a.
(forall x. a -> Rep a x) -> (forall x. Rep a x -> a) -> Generic a
forall a b x. Rep (Gr a b) x -> Gr a b
forall a b x. Gr a b -> Rep (Gr a b) x
$cfrom :: forall a b x. Gr a b -> Rep (Gr a b) x
from :: forall x. Gr a b -> Rep (Gr a b) x
$cto :: forall a b x. Rep (Gr a b) x -> Gr a b
to :: forall x. Rep (Gr a b) x -> Gr a b
Generic)

type GraphRep a b = IntMap (Context' a b)
type Context' a b = (IntMap [b], a, IntMap [b])

type UGr = Gr () ()

----------------------------------------------------------------------
-- CLASS INSTANCES
----------------------------------------------------------------------

instance (Eq a, Ord b) => Eq (Gr a b) where
  (Gr IntMap (IntMap [b], a, IntMap [b])
g1) == :: Gr a b -> Gr a b -> Bool
== (Gr IntMap (IntMap [b], a, IntMap [b])
g2) = ((IntMap [b], a, IntMap [b]) -> (IntMap [b], a, IntMap [b]))
-> IntMap (IntMap [b], a, IntMap [b])
-> IntMap (IntMap [b], a, IntMap [b])
forall a b. (a -> b) -> IntMap a -> IntMap b
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
fmap (IntMap [b], a, IntMap [b]) -> (IntMap [b], a, IntMap [b])
forall {f :: * -> *} {f :: * -> *} {a} {a} {b}.
(Functor f, Functor f, Ord a, Ord a) =>
(f [a], b, f [a]) -> (f [a], b, f [a])
sortAdj IntMap (IntMap [b], a, IntMap [b])
g1 IntMap (IntMap [b], a, IntMap [b])
-> IntMap (IntMap [b], a, IntMap [b]) -> Bool
forall a. Eq a => a -> a -> Bool
== ((IntMap [b], a, IntMap [b]) -> (IntMap [b], a, IntMap [b]))
-> IntMap (IntMap [b], a, IntMap [b])
-> IntMap (IntMap [b], a, IntMap [b])
forall a b. (a -> b) -> IntMap a -> IntMap b
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
fmap (IntMap [b], a, IntMap [b]) -> (IntMap [b], a, IntMap [b])
forall {f :: * -> *} {f :: * -> *} {a} {a} {b}.
(Functor f, Functor f, Ord a, Ord a) =>
(f [a], b, f [a]) -> (f [a], b, f [a])
sortAdj IntMap (IntMap [b], a, IntMap [b])
g2
    where
      sortAdj :: (f [a], b, f [a]) -> (f [a], b, f [a])
sortAdj (f [a]
p,b
n,f [a]
s) = (([a] -> [a]) -> f [a] -> f [a]
forall a b. (a -> b) -> f a -> f b
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
fmap [a] -> [a]
forall a. Ord a => [a] -> [a]
sort f [a]
p,b
n,([a] -> [a]) -> f [a] -> f [a]
forall a b. (a -> b) -> f a -> f b
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
fmap [a] -> [a]
forall a. Ord a => [a] -> [a]
sort f [a]
s)

instance (Show a, Show b) => Show (Gr a b) where
  showsPrec :: Int -> Gr a b -> ShowS
showsPrec Int
d Gr a b
g = Bool -> ShowS -> ShowS
showParen (Int
d Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
> Int
10) (ShowS -> ShowS) -> ShowS -> ShowS
forall a b. (a -> b) -> a -> b
$
                    String -> ShowS
showString String
"mkGraph "
                    ShowS -> ShowS -> ShowS
forall b c a. (b -> c) -> (a -> b) -> a -> c
. [LNode a] -> ShowS
forall a. Show a => a -> ShowS
shows (Gr a b -> [LNode a]
forall a b. Gr a b -> [LNode a]
forall (gr :: * -> * -> *) a b. Graph gr => gr a b -> [LNode a]
labNodes Gr a b
g)
                    ShowS -> ShowS -> ShowS
forall b c a. (b -> c) -> (a -> b) -> a -> c
. String -> ShowS
showString String
" "
                    ShowS -> ShowS -> ShowS
forall b c a. (b -> c) -> (a -> b) -> a -> c
. [LEdge b] -> ShowS
forall a. Show a => a -> ShowS
shows (Gr a b -> [LEdge b]
forall a b. Gr a b -> [LEdge b]
forall (gr :: * -> * -> *) a b. Graph gr => gr a b -> [LEdge b]
labEdges Gr a b
g)

instance (Read a, Read b) => Read (Gr a b) where
  readsPrec :: Int -> ReadS (Gr a b)
readsPrec Int
p = Bool -> ReadS (Gr a b) -> ReadS (Gr a b)
forall a. Bool -> ReadS a -> ReadS a
readParen (Int
p Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
> Int
10) (ReadS (Gr a b) -> ReadS (Gr a b))
-> ReadS (Gr a b) -> ReadS (Gr a b)
forall a b. (a -> b) -> a -> b
$ \ String
r -> do
    ("mkGraph", s) <- ReadS String
lex String
r
    (ns,t) <- reads s
    (es,u) <- reads t
    return (mkGraph ns es, u)

instance Graph Gr where
    empty :: forall a b. Gr a b
empty           = GraphRep a b -> Gr a b
forall a b. GraphRep a b -> Gr a b
Gr GraphRep a b
forall a. IntMap a
IM.empty

    isEmpty :: forall a b. Gr a b -> Bool
isEmpty (Gr GraphRep a b
g)  = GraphRep a b -> Bool
forall a. IntMap a -> Bool
IM.null GraphRep a b
g

    match :: forall a b. Int -> Gr a b -> Decomp Gr a b
match           = Int -> Gr a b -> Decomp Gr a b
forall a b. Int -> Gr a b -> Decomp Gr a b
matchGr

    mkGraph :: forall a b. [LNode a] -> [LEdge b] -> Gr a b
mkGraph [LNode a]
vs [LEdge b]
es   = [LEdge b] -> Gr a b -> Gr a b
forall (gr :: * -> * -> *) b a.
DynGraph gr =>
[LEdge b] -> gr a b -> gr a b
insEdges [LEdge b]
es
                      (Gr a b -> Gr a b) -> ([LNode a] -> Gr a b) -> [LNode a] -> Gr a b
forall b c a. (b -> c) -> (a -> b) -> a -> c
. GraphRep a b -> Gr a b
forall a b. GraphRep a b -> Gr a b
Gr
                      (GraphRep a b -> Gr a b)
-> ([LNode a] -> GraphRep a b) -> [LNode a] -> Gr a b
forall b c a. (b -> c) -> (a -> b) -> a -> c
. [(Int, Context' a b)] -> GraphRep a b
forall a. [(Int, a)] -> IntMap a
IM.fromList
                      ([(Int, Context' a b)] -> GraphRep a b)
-> ([LNode a] -> [(Int, Context' a b)])
-> [LNode a]
-> GraphRep a b
forall b c a. (b -> c) -> (a -> b) -> a -> c
. (LNode a -> (Int, Context' a b))
-> [LNode a] -> [(Int, Context' a b)]
forall a b. (a -> b) -> [a] -> [b]
map ((a -> Context' a b) -> LNode a -> (Int, Context' a b)
forall b c a. (b -> c) -> (a, b) -> (a, c)
forall (p :: * -> * -> *) b c a.
Bifunctor p =>
(b -> c) -> p a b -> p a c
second (\a
l -> (IntMap [b]
forall a. IntMap a
IM.empty,a
l,IntMap [b]
forall a. IntMap a
IM.empty)))
                      ([LNode a] -> Gr a b) -> [LNode a] -> Gr a b
forall a b. (a -> b) -> a -> b
$ [LNode a]
vs

    labNodes :: forall a b. Gr a b -> [LNode a]
labNodes (Gr GraphRep a b
g) = [ (Int
node, a
label)
                            | (Int
node, (IntMap [b]
_, a
label, IntMap [b]
_)) <- GraphRep a b -> [(Int, Context' a b)]
forall a. IntMap a -> [(Int, a)]
IM.toList GraphRep a b
g ]

    noNodes :: forall a b. Gr a b -> Int
noNodes   (Gr GraphRep a b
g) = GraphRep a b -> Int
forall a. IntMap a -> Int
IM.size GraphRep a b
g

    nodeRange :: forall a b. Gr a b -> (Int, Int)
nodeRange (Gr GraphRep a b
g) = (Int, Int) -> Maybe (Int, Int) -> (Int, Int)
forall a. a -> Maybe a -> a
fromMaybe (String -> (Int, Int)
forall a. HasCallStack => String -> a
error String
"nodeRange of empty graph")
                       (Maybe (Int, Int) -> (Int, Int)) -> Maybe (Int, Int) -> (Int, Int)
forall a b. (a -> b) -> a -> b
$ (Int -> Int -> (Int, Int))
-> Maybe Int -> Maybe Int -> Maybe (Int, Int)
forall a b c. (a -> b -> c) -> Maybe a -> Maybe b -> Maybe c
forall (f :: * -> *) a b c.
Applicative f =>
(a -> b -> c) -> f a -> f b -> f c
liftA2 (,) (Maybe ((Int, Context' a b), GraphRep a b) -> Maybe Int
forall {b} {b} {b}. Maybe ((b, b), b) -> Maybe b
ix (GraphRep a b -> Maybe ((Int, Context' a b), GraphRep a b)
forall a. IntMap a -> Maybe ((Int, a), IntMap a)
IM.minViewWithKey GraphRep a b
g))
                                    (Maybe ((Int, Context' a b), GraphRep a b) -> Maybe Int
forall {b} {b} {b}. Maybe ((b, b), b) -> Maybe b
ix (GraphRep a b -> Maybe ((Int, Context' a b), GraphRep a b)
forall a. IntMap a -> Maybe ((Int, a), IntMap a)
IM.maxViewWithKey GraphRep a b
g))
      where
        ix :: Maybe ((b, b), b) -> Maybe b
ix = (((b, b), b) -> b) -> Maybe ((b, b), b) -> Maybe b
forall a b. (a -> b) -> Maybe a -> Maybe b
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
fmap ((b, b) -> b
forall a b. (a, b) -> a
fst ((b, b) -> b) -> (((b, b), b) -> (b, b)) -> ((b, b), b) -> b
forall b c a. (b -> c) -> (a -> b) -> a -> c
. ((b, b), b) -> (b, b)
forall a b. (a, b) -> a
fst)

    labEdges :: forall a b. Gr a b -> [LEdge b]
labEdges (Gr GraphRep a b
g) = do (node, (_, _, s)) <- GraphRep a b -> [(Int, Context' a b)]
forall a. IntMap a -> [(Int, a)]
IM.toList GraphRep a b
g
                         (next, labels)    <- IM.toList s
                         label             <- labels
                         return (node, next, label)

instance DynGraph Gr where
    (Adj b
p, Int
v, a
l, Adj b
s) & :: forall a b. Context a b -> Gr a b -> Gr a b
& (Gr GraphRep a b
g)
        = let !g1 :: GraphRep a b
g1 = Int -> (IntMap [b], a, IntMap [b]) -> GraphRep a b -> GraphRep a b
forall a. Int -> a -> IntMap a -> IntMap a
IM.insert Int
v (IntMap [b]
preds, a
l, IntMap [b]
succs) GraphRep a b
g
              !(Int
np, IntMap [b]
preds) = Adj b -> (Int, IntMap [b])
forall b. Adj b -> (Int, IntMap [b])
fromAdjCounting Adj b
p
              !(Int
ns, IntMap [b]
succs) = Adj b -> (Int, IntMap [b])
forall b. Adj b -> (Int, IntMap [b])
fromAdjCounting Adj b
s
              !g2 :: GraphRep a b
g2 = GraphRep a b -> Int -> Int -> IntMap [b] -> GraphRep a b
forall a b.
GraphRep a b -> Int -> Int -> IntMap [b] -> GraphRep a b
addSucc GraphRep a b
g1 Int
v Int
np IntMap [b]
preds
              !g3 :: GraphRep a b
g3 = GraphRep a b -> Int -> Int -> IntMap [b] -> GraphRep a b
forall a b.
GraphRep a b -> Int -> Int -> IntMap [b] -> GraphRep a b
addPred GraphRep a b
g2 Int
v Int
ns IntMap [b]
succs
          in GraphRep a b -> Gr a b
forall a b. GraphRep a b -> Gr a b
Gr GraphRep a b
g3


instance Functor (Gr a) where
  fmap :: forall a b. (a -> b) -> Gr a a -> Gr a b
fmap = (a -> b) -> Gr a a -> Gr a b
forall a a b. (a -> b) -> Gr a a -> Gr a b
fastEMap

instance Bifunctor Gr where
  bimap :: forall a b c d. (a -> b) -> (c -> d) -> Gr a c -> Gr b d
bimap = (a -> b) -> (c -> d) -> Gr a c -> Gr b d
forall a b c d. (a -> c) -> (b -> d) -> Gr a b -> Gr c d
fastNEMap

  first :: forall a b c. (a -> b) -> Gr a c -> Gr b c
first = (a -> b) -> Gr a c -> Gr b c
forall a b c. (a -> c) -> Gr a b -> Gr c b
fastNMap

  second :: forall b c a. (b -> c) -> Gr a b -> Gr a c
second = (b -> c) -> Gr a b -> Gr a c
forall a a b. (a -> b) -> Gr a a -> Gr a b
fastEMap


matchGr :: Node -> Gr a b -> Decomp Gr a b
matchGr :: forall a b. Int -> Gr a b -> Decomp Gr a b
matchGr Int
node (Gr GraphRep a b
g)
    = case Int -> GraphRep a b -> Maybe (Context' a b)
forall a. Int -> IntMap a -> Maybe a
IM.lookup Int
node GraphRep a b
g of
        Maybe (Context' a b)
Nothing
            -> (Maybe (Context a b)
forall a. Maybe a
Nothing, GraphRep a b -> Gr a b
forall a b. GraphRep a b -> Gr a b
Gr GraphRep a b
g)

        Just (IntMap [b]
p, a
label, IntMap [b]
s)
            -> let !g1 :: GraphRep a b
g1 = Int -> GraphRep a b -> GraphRep a b
forall a. Int -> IntMap a -> IntMap a
IM.delete Int
node GraphRep a b
g
                   !p' :: IntMap [b]
p' = Int -> IntMap [b] -> IntMap [b]
forall a. Int -> IntMap a -> IntMap a
IM.delete Int
node IntMap [b]
p
                   !s' :: IntMap [b]
s' = Int -> IntMap [b] -> IntMap [b]
forall a. Int -> IntMap a -> IntMap a
IM.delete Int
node IntMap [b]
s
                   !g2 :: GraphRep a b
g2 = GraphRep a b -> Int -> IntMap [b] -> GraphRep a b
forall a b x. GraphRep a b -> Int -> IntMap x -> GraphRep a b
clearPred GraphRep a b
g1 Int
node IntMap [b]
s'
                   !g3 :: GraphRep a b
g3 = GraphRep a b -> Int -> IntMap [b] -> GraphRep a b
forall a b x. GraphRep a b -> Int -> IntMap x -> GraphRep a b
clearSucc GraphRep a b
g2 Int
node IntMap [b]
p'
               in (Context a b -> Maybe (Context a b)
forall a. a -> Maybe a
Just (IntMap [b] -> Adj b
forall b. IntMap [b] -> Adj b
toAdj IntMap [b]
p', Int
node, a
label, IntMap [b] -> Adj b
forall b. IntMap [b] -> Adj b
toAdj IntMap [b]
s), GraphRep a b -> Gr a b
forall a b. GraphRep a b -> Gr a b
Gr GraphRep a b
g3)

----------------------------------------------------------------------
-- OVERRIDING FUNCTIONS
----------------------------------------------------------------------

{-

{- RULES
      "insNode/Data.Graph.Inductive.PatriciaTree"  insNode = fastInsNode
  -}
fastInsNode :: LNode a -> Gr a b -> Gr a b
fastInsNode (v, l) (Gr g) = g' `seq` Gr g'
  where
    g' = IM.insert v (IM.empty, l, IM.empty) g

-}
{-# RULES
      "insEdge/GHC.Data.Graph.Inductive.PatriciaTree"  insEdge = fastInsEdge
  #-}
fastInsEdge :: LEdge b -> Gr a b -> Gr a b
fastInsEdge :: forall b a. LEdge b -> Gr a b -> Gr a b
fastInsEdge (Int
v, Int
w, b
l) (Gr GraphRep a b
g) = GraphRep a b
g2 GraphRep a b -> Gr a b -> Gr a b
forall a b. a -> b -> b
`seq` GraphRep a b -> Gr a b
forall a b. GraphRep a b -> Gr a b
Gr GraphRep a b
g2
  where
    g1 :: GraphRep a b
g1 = ((IntMap [b], a, IntMap [b]) -> (IntMap [b], a, IntMap [b]))
-> Int -> GraphRep a b -> GraphRep a b
forall a. (a -> a) -> Int -> IntMap a -> IntMap a
IM.adjust (IntMap [b], a, IntMap [b]) -> (IntMap [b], a, IntMap [b])
addS' Int
v GraphRep a b
g
    g2 :: GraphRep a b
g2 = ((IntMap [b], a, IntMap [b]) -> (IntMap [b], a, IntMap [b]))
-> Int -> GraphRep a b -> GraphRep a b
forall a. (a -> a) -> Int -> IntMap a -> IntMap a
IM.adjust (IntMap [b], a, IntMap [b]) -> (IntMap [b], a, IntMap [b])
addP' Int
w GraphRep a b
g1

    addS' :: (IntMap [b], a, IntMap [b]) -> (IntMap [b], a, IntMap [b])
addS' (IntMap [b]
ps, a
l', IntMap [b]
ss) = (IntMap [b]
ps, a
l', ([b] -> [b] -> [b]) -> Int -> [b] -> IntMap [b] -> IntMap [b]
forall a. (a -> a -> a) -> Int -> a -> IntMap a -> IntMap a
IM.insertWith [b] -> [b] -> [b]
forall a. [a] -> [a] -> [a]
addLists Int
w [b
l] IntMap [b]
ss)
    addP' :: (IntMap [b], a, IntMap [b]) -> (IntMap [b], a, IntMap [b])
addP' (IntMap [b]
ps, a
l', IntMap [b]
ss) = (([b] -> [b] -> [b]) -> Int -> [b] -> IntMap [b] -> IntMap [b]
forall a. (a -> a -> a) -> Int -> a -> IntMap a -> IntMap a
IM.insertWith [b] -> [b] -> [b]
forall a. [a] -> [a] -> [a]
addLists Int
v [b
l] IntMap [b]
ps, a
l', IntMap [b]
ss)

{-

{- RULES
      "gmap/Data.Graph.Inductive.PatriciaTree"  gmap = fastGMap
  -}
fastGMap :: forall a b c d. (Context a b -> Context c d) -> Gr a b -> Gr c d
fastGMap f (Gr g) = Gr (IM.mapWithKey f' g)
  where
    f' :: Node -> Context' a b -> Context' c d
    f' = ((fromContext . f) .) . toContext

{- RULES
      "nmap/Data.Graph.Inductive.PatriciaTree"  nmap = fastNMap
  -}
-}
fastNMap :: forall a b c. (a -> c) -> Gr a b -> Gr c b
fastNMap :: forall a b c. (a -> c) -> Gr a b -> Gr c b
fastNMap a -> c
f (Gr GraphRep a b
g) = GraphRep c b -> Gr c b
forall a b. GraphRep a b -> Gr a b
Gr ((Context' a b -> Context' c b) -> GraphRep a b -> GraphRep c b
forall a b. (a -> b) -> IntMap a -> IntMap b
IM.map Context' a b -> Context' c b
f' GraphRep a b
g)
  where
    f' :: Context' a b -> Context' c b
    f' :: Context' a b -> Context' c b
f' (IntMap [b]
ps, a
a, IntMap [b]
ss) = (IntMap [b]
ps, a -> c
f a
a, IntMap [b]
ss)
{-

{- RULES
      "emap/GHC.Data.Graph.Inductive.PatriciaTree"  emap = fastEMap
   -}
-}
fastEMap :: forall a b c. (b -> c) -> Gr a b -> Gr a c
fastEMap :: forall a a b. (a -> b) -> Gr a a -> Gr a b
fastEMap b -> c
f (Gr GraphRep a b
g) = GraphRep a c -> Gr a c
forall a b. GraphRep a b -> Gr a b
Gr ((Context' a b -> Context' a c) -> GraphRep a b -> GraphRep a c
forall a b. (a -> b) -> IntMap a -> IntMap b
IM.map Context' a b -> Context' a c
f' GraphRep a b
g)
  where
    f' :: Context' a b -> Context' a c
    f' :: Context' a b -> Context' a c
f' (IntMap [b]
ps, a
a, IntMap [b]
ss) = (([b] -> [c]) -> IntMap [b] -> IntMap [c]
forall a b. (a -> b) -> IntMap a -> IntMap b
IM.map ((b -> c) -> [b] -> [c]
forall a b. (a -> b) -> [a] -> [b]
map b -> c
f) IntMap [b]
ps, a
a, ([b] -> [c]) -> IntMap [b] -> IntMap [c]
forall a b. (a -> b) -> IntMap a -> IntMap b
IM.map ((b -> c) -> [b] -> [c]
forall a b. (a -> b) -> [a] -> [b]
map b -> c
f) IntMap [b]
ss)

{-  RULES
      "nemap/GHC.Data.Graph.Inductive.PatriciaTree"  nemap = fastNEMap
   -}

fastNEMap :: forall a b c d. (a -> c) -> (b -> d) -> Gr a b -> Gr c d
fastNEMap :: forall a b c d. (a -> c) -> (b -> d) -> Gr a b -> Gr c d
fastNEMap a -> c
fn b -> d
fe (Gr GraphRep a b
g) = GraphRep c d -> Gr c d
forall a b. GraphRep a b -> Gr a b
Gr ((Context' a b -> Context' c d) -> GraphRep a b -> GraphRep c d
forall a b. (a -> b) -> IntMap a -> IntMap b
IM.map Context' a b -> Context' c d
f GraphRep a b
g)
  where
    f :: Context' a b -> Context' c d
    f :: Context' a b -> Context' c d
f (IntMap [b]
ps, a
a, IntMap [b]
ss) = (([b] -> [d]) -> IntMap [b] -> IntMap [d]
forall a b. (a -> b) -> IntMap a -> IntMap b
IM.map ((b -> d) -> [b] -> [d]
forall a b. (a -> b) -> [a] -> [b]
map b -> d
fe) IntMap [b]
ps, a -> c
fn a
a, ([b] -> [d]) -> IntMap [b] -> IntMap [d]
forall a b. (a -> b) -> IntMap a -> IntMap b
IM.map ((b -> d) -> [b] -> [d]
forall a b. (a -> b) -> [a] -> [b]
map b -> d
fe) IntMap [b]
ss)



----------------------------------------------------------------------
-- UTILITIES
----------------------------------------------------------------------

toAdj :: IntMap [b] -> Adj b
toAdj :: forall b. IntMap [b] -> Adj b
toAdj = ((Int, [b]) -> [(b, Int)]) -> [(Int, [b])] -> [(b, Int)]
forall (t :: * -> *) a b. Foldable t => (a -> [b]) -> t a -> [b]
concatMap (Int, [b]) -> [(b, Int)]
forall {b} {a}. (b, [a]) -> [(a, b)]
expand ([(Int, [b])] -> [(b, Int)])
-> (IntMap [b] -> [(Int, [b])]) -> IntMap [b] -> [(b, Int)]
forall b c a. (b -> c) -> (a -> b) -> a -> c
. IntMap [b] -> [(Int, [b])]
forall a. IntMap a -> [(Int, a)]
IM.toList
  where
    expand :: (b, [a]) -> [(a, b)]
expand (b
n,[a]
ls) = (a -> (a, b)) -> [a] -> [(a, b)]
forall a b. (a -> b) -> [a] -> [b]
map ((a -> b -> (a, b)) -> b -> a -> (a, b)
forall a b c. (a -> b -> c) -> b -> a -> c
flip (,) b
n) [a]
ls

--fromAdj :: Adj b -> IntMap [b]
--fromAdj = IM.fromListWith addLists . map (second (:[]) . swap)

data FromListCounting a = FromListCounting !Int !(IntMap a)
  deriving (FromListCounting a -> FromListCounting a -> Bool
(FromListCounting a -> FromListCounting a -> Bool)
-> (FromListCounting a -> FromListCounting a -> Bool)
-> Eq (FromListCounting a)
forall a. Eq a => FromListCounting a -> FromListCounting a -> Bool
forall a. (a -> a -> Bool) -> (a -> a -> Bool) -> Eq a
$c== :: forall a. Eq a => FromListCounting a -> FromListCounting a -> Bool
== :: FromListCounting a -> FromListCounting a -> Bool
$c/= :: forall a. Eq a => FromListCounting a -> FromListCounting a -> Bool
/= :: FromListCounting a -> FromListCounting a -> Bool
Eq, Int -> FromListCounting a -> ShowS
[FromListCounting a] -> ShowS
FromListCounting a -> String
(Int -> FromListCounting a -> ShowS)
-> (FromListCounting a -> String)
-> ([FromListCounting a] -> ShowS)
-> Show (FromListCounting a)
forall a. Show a => Int -> FromListCounting a -> ShowS
forall a. Show a => [FromListCounting a] -> ShowS
forall a. Show a => FromListCounting a -> String
forall a.
(Int -> a -> ShowS) -> (a -> String) -> ([a] -> ShowS) -> Show a
$cshowsPrec :: forall a. Show a => Int -> FromListCounting a -> ShowS
showsPrec :: Int -> FromListCounting a -> ShowS
$cshow :: forall a. Show a => FromListCounting a -> String
show :: FromListCounting a -> String
$cshowList :: forall a. Show a => [FromListCounting a] -> ShowS
showList :: [FromListCounting a] -> ShowS
Show, ReadPrec [FromListCounting a]
ReadPrec (FromListCounting a)
Int -> ReadS (FromListCounting a)
ReadS [FromListCounting a]
(Int -> ReadS (FromListCounting a))
-> ReadS [FromListCounting a]
-> ReadPrec (FromListCounting a)
-> ReadPrec [FromListCounting a]
-> Read (FromListCounting a)
forall a. Read a => ReadPrec [FromListCounting a]
forall a. Read a => ReadPrec (FromListCounting a)
forall a. Read a => Int -> ReadS (FromListCounting a)
forall a. Read a => ReadS [FromListCounting a]
forall a.
(Int -> ReadS a)
-> ReadS [a] -> ReadPrec a -> ReadPrec [a] -> Read a
$creadsPrec :: forall a. Read a => Int -> ReadS (FromListCounting a)
readsPrec :: Int -> ReadS (FromListCounting a)
$creadList :: forall a. Read a => ReadS [FromListCounting a]
readList :: ReadS [FromListCounting a]
$creadPrec :: forall a. Read a => ReadPrec (FromListCounting a)
readPrec :: ReadPrec (FromListCounting a)
$creadListPrec :: forall a. Read a => ReadPrec [FromListCounting a]
readListPrec :: ReadPrec [FromListCounting a]
Read)

getFromListCounting :: FromListCounting a -> (Int, IntMap a)
getFromListCounting :: forall a. FromListCounting a -> (Int, IntMap a)
getFromListCounting (FromListCounting Int
i IntMap a
m) = (Int
i, IntMap a
m)
{-# INLINE getFromListCounting #-}

fromListWithKeyCounting :: (Int -> a -> a -> a) -> [(Int, a)] -> (Int, IntMap a)
fromListWithKeyCounting :: forall a. (Int -> a -> a -> a) -> [(Int, a)] -> (Int, IntMap a)
fromListWithKeyCounting Int -> a -> a -> a
f = FromListCounting a -> (Int, IntMap a)
forall a. FromListCounting a -> (Int, IntMap a)
getFromListCounting (FromListCounting a -> (Int, IntMap a))
-> ([(Int, a)] -> FromListCounting a)
-> [(Int, a)]
-> (Int, IntMap a)
forall b c a. (b -> c) -> (a -> b) -> a -> c
. (FromListCounting a -> (Int, a) -> FromListCounting a)
-> FromListCounting a -> [(Int, a)] -> FromListCounting a
forall b a. (b -> a -> b) -> b -> [a] -> b
forall (t :: * -> *) b a.
Foldable t =>
(b -> a -> b) -> b -> t a -> b
foldl' FromListCounting a -> (Int, a) -> FromListCounting a
ins (Int -> IntMap a -> FromListCounting a
forall a. Int -> IntMap a -> FromListCounting a
FromListCounting Int
0 IntMap a
forall a. IntMap a
IM.empty)
  where
    ins :: FromListCounting a -> (Int, a) -> FromListCounting a
ins (FromListCounting Int
i IntMap a
t) (Int
k,a
x) = Int -> IntMap a -> FromListCounting a
forall a. Int -> IntMap a -> FromListCounting a
FromListCounting (Int
i Int -> Int -> Int
forall a. Num a => a -> a -> a
+ Int
1) ((Int -> a -> a -> a) -> Int -> a -> IntMap a -> IntMap a
forall a. (Int -> a -> a -> a) -> Int -> a -> IntMap a -> IntMap a
IM.insertWithKey Int -> a -> a -> a
f Int
k a
x IntMap a
t)
{-# INLINE fromListWithKeyCounting #-}

fromListWithCounting :: (a -> a -> a) -> [(Int, a)] -> (Int, IntMap a)
fromListWithCounting :: forall a. (a -> a -> a) -> [(Int, a)] -> (Int, IntMap a)
fromListWithCounting a -> a -> a
f = (Int -> a -> a -> a) -> [(Int, a)] -> (Int, IntMap a)
forall a. (Int -> a -> a -> a) -> [(Int, a)] -> (Int, IntMap a)
fromListWithKeyCounting (\Int
_ a
x a
y -> a -> a -> a
f a
x a
y)
{-# INLINE fromListWithCounting #-}

fromAdjCounting :: Adj b -> (Int, IntMap [b])
fromAdjCounting :: forall b. Adj b -> (Int, IntMap [b])
fromAdjCounting = ([b] -> [b] -> [b]) -> [(Int, [b])] -> (Int, IntMap [b])
forall a. (a -> a -> a) -> [(Int, a)] -> (Int, IntMap a)
fromListWithCounting [b] -> [b] -> [b]
forall a. [a] -> [a] -> [a]
addLists ([(Int, [b])] -> (Int, IntMap [b]))
-> (Adj b -> [(Int, [b])]) -> Adj b -> (Int, IntMap [b])
forall b c a. (b -> c) -> (a -> b) -> a -> c
. ((b, Int) -> (Int, [b])) -> Adj b -> [(Int, [b])]
forall a b. (a -> b) -> [a] -> [b]
map ((b -> [b]) -> (Int, b) -> (Int, [b])
forall b c a. (b -> c) -> (a, b) -> (a, c)
forall (p :: * -> * -> *) b c a.
Bifunctor p =>
(b -> c) -> p a b -> p a c
second (b -> [b] -> [b]
forall a. a -> [a] -> [a]
:[]) ((Int, b) -> (Int, [b]))
-> ((b, Int) -> (Int, b)) -> (b, Int) -> (Int, [b])
forall b c a. (b -> c) -> (a -> b) -> a -> c
. (b, Int) -> (Int, b)
forall a b. (a, b) -> (b, a)
swap)

-- We use differenceWith to modify a graph more than bulkThreshold times,
-- and repeated insertWith otherwise.
bulkThreshold :: Int
bulkThreshold :: Int
bulkThreshold = Int
5

--toContext :: Node -> Context' a b -> Context a b
--toContext v (ps, a, ss) = (toAdj ps, v, a, toAdj ss)

--fromContext :: Context a b -> Context' a b
--fromContext (ps, _, a, ss) = (fromAdj ps, a, fromAdj ss)

-- A version of @++@ where order isn't important, so @xs ++ [x]@
-- becomes @x:xs@.  Used when we have to have a function of type @[a]
-- -> [a] -> [a]@ but one of the lists is just going to be a single
-- element (and it isn't possible to tell which).
addLists :: [a] -> [a] -> [a]
addLists :: forall a. [a] -> [a] -> [a]
addLists [a
a] [a]
as  = a
a a -> [a] -> [a]
forall a. a -> [a] -> [a]
: [a]
as
addLists [a]
as  [a
a] = a
a a -> [a] -> [a]
forall a. a -> [a] -> [a]
: [a]
as
addLists [a]
xs  [a]
ys  = [a]
xs [a] -> [a] -> [a]
forall a. [a] -> [a] -> [a]
++ [a]
ys

addSucc :: forall a b . GraphRep a b -> Node -> Int -> IM.IntMap [b] -> GraphRep a b
addSucc :: forall a b.
GraphRep a b -> Int -> Int -> IntMap [b] -> GraphRep a b
addSucc GraphRep a b
g0 Int
v Int
numAdd IntMap [b]
xs
  | Int
numAdd Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
< Int
bulkThreshold = (GraphRep a b -> Int -> [b] -> GraphRep a b)
-> GraphRep a b -> IntMap [b] -> GraphRep a b
forall a b. (a -> Int -> b -> a) -> a -> IntMap b -> a
foldlWithKey' GraphRep a b -> Int -> [b] -> GraphRep a b
go GraphRep a b
g0 IntMap [b]
xs
  where
    go :: GraphRep a b -> Node -> [b] -> GraphRep a b
    go :: GraphRep a b -> Int -> [b] -> GraphRep a b
go GraphRep a b
g Int
p [b]
l = (Context' a b -> Context' a b)
-> Int -> GraphRep a b -> GraphRep a b
forall a. (a -> a) -> Int -> IntMap a -> IntMap a
IMS.adjust Context' a b -> Context' a b
f Int
p GraphRep a b
g
      where f :: Context' a b -> Context' a b
f (IntMap [b]
ps, a
l', IntMap [b]
ss) = let !ss' :: IntMap [b]
ss' = ([b] -> [b] -> [b]) -> Int -> [b] -> IntMap [b] -> IntMap [b]
forall a. (a -> a -> a) -> Int -> a -> IntMap a -> IntMap a
IM.insertWith [b] -> [b] -> [b]
forall a. [a] -> [a] -> [a]
addLists Int
v [b]
l IntMap [b]
ss
                             in (IntMap [b]
ps, a
l', IntMap [b]
ss')
addSucc GraphRep a b
g Int
v Int
_ IntMap [b]
xs = (Context' a b -> [b] -> Maybe (Context' a b))
-> GraphRep a b -> IntMap [b] -> GraphRep a b
forall a b. (a -> b -> Maybe a) -> IntMap a -> IntMap b -> IntMap a
IMS.differenceWith Context' a b -> [b] -> Maybe (Context' a b)
go GraphRep a b
g IntMap [b]
xs
  where
    go :: Context' a b -> [b] -> Maybe (Context' a b)
    go :: Context' a b -> [b] -> Maybe (Context' a b)
go (IntMap [b]
ps, a
l', IntMap [b]
ss) [b]
l = let !ss' :: IntMap [b]
ss' = ([b] -> [b] -> [b]) -> Int -> [b] -> IntMap [b] -> IntMap [b]
forall a. (a -> a -> a) -> Int -> a -> IntMap a -> IntMap a
IM.insertWith [b] -> [b] -> [b]
forall a. [a] -> [a] -> [a]
addLists Int
v [b]
l IntMap [b]
ss
                        in Context' a b -> Maybe (Context' a b)
forall a. a -> Maybe a
Just (IntMap [b]
ps, a
l', IntMap [b]
ss')

foldlWithKey' :: (a -> IM.Key -> b -> a) -> a -> IntMap b -> a
foldlWithKey' :: forall a b. (a -> Int -> b -> a) -> a -> IntMap b -> a
foldlWithKey' =
  (a -> Int -> b -> a) -> a -> IntMap b -> a
forall a b. (a -> Int -> b -> a) -> a -> IntMap b -> a
IM.foldlWithKey'

addPred :: forall a b . GraphRep a b -> Node -> Int -> IM.IntMap [b] -> GraphRep a b
addPred :: forall a b.
GraphRep a b -> Int -> Int -> IntMap [b] -> GraphRep a b
addPred GraphRep a b
g0 Int
v Int
numAdd IntMap [b]
xs
  | Int
numAdd Int -> Int -> Bool
forall a. Ord a => a -> a -> Bool
< Int
bulkThreshold = (GraphRep a b -> Int -> [b] -> GraphRep a b)
-> GraphRep a b -> IntMap [b] -> GraphRep a b
forall a b. (a -> Int -> b -> a) -> a -> IntMap b -> a
foldlWithKey' GraphRep a b -> Int -> [b] -> GraphRep a b
go GraphRep a b
g0 IntMap [b]
xs
  where
    go :: GraphRep a b -> Node -> [b] -> GraphRep a b
    go :: GraphRep a b -> Int -> [b] -> GraphRep a b
go GraphRep a b
g Int
p [b]
l = (Context' a b -> Context' a b)
-> Int -> GraphRep a b -> GraphRep a b
forall a. (a -> a) -> Int -> IntMap a -> IntMap a
IMS.adjust Context' a b -> Context' a b
f Int
p GraphRep a b
g
      where f :: Context' a b -> Context' a b
f (IntMap [b]
ps, a
l', IntMap [b]
ss) = let !ps' :: IntMap [b]
ps' = ([b] -> [b] -> [b]) -> Int -> [b] -> IntMap [b] -> IntMap [b]
forall a. (a -> a -> a) -> Int -> a -> IntMap a -> IntMap a
IM.insertWith [b] -> [b] -> [b]
forall a. [a] -> [a] -> [a]
addLists Int
v [b]
l IntMap [b]
ps
                             in (IntMap [b]
ps', a
l', IntMap [b]
ss)
addPred GraphRep a b
g Int
v Int
_ IntMap [b]
xs = (Context' a b -> [b] -> Maybe (Context' a b))
-> GraphRep a b -> IntMap [b] -> GraphRep a b
forall a b. (a -> b -> Maybe a) -> IntMap a -> IntMap b -> IntMap a
IMS.differenceWith Context' a b -> [b] -> Maybe (Context' a b)
go GraphRep a b
g IntMap [b]
xs
  where
    go :: Context' a b -> [b] -> Maybe (Context' a b)
    go :: Context' a b -> [b] -> Maybe (Context' a b)
go (IntMap [b]
ps, a
l', IntMap [b]
ss) [b]
l = let !ps' :: IntMap [b]
ps' = ([b] -> [b] -> [b]) -> Int -> [b] -> IntMap [b] -> IntMap [b]
forall a. (a -> a -> a) -> Int -> a -> IntMap a -> IntMap a
IM.insertWith [b] -> [b] -> [b]
forall a. [a] -> [a] -> [a]
addLists Int
v [b]
l IntMap [b]
ps
                        in Context' a b -> Maybe (Context' a b)
forall a. a -> Maybe a
Just (IntMap [b]
ps', a
l', IntMap [b]
ss)

clearSucc :: forall a b x . GraphRep a b -> Node -> IM.IntMap x -> GraphRep a b
clearSucc :: forall a b x. GraphRep a b -> Int -> IntMap x -> GraphRep a b
clearSucc GraphRep a b
g Int
v = (Context' a b -> x -> Maybe (Context' a b))
-> GraphRep a b -> IntMap x -> GraphRep a b
forall a b. (a -> b -> Maybe a) -> IntMap a -> IntMap b -> IntMap a
IMS.differenceWith Context' a b -> x -> Maybe (Context' a b)
go GraphRep a b
g
  where
    go :: Context' a b -> x -> Maybe (Context' a b)
    go :: Context' a b -> x -> Maybe (Context' a b)
go (IntMap [b]
ps, a
l, IntMap [b]
ss) x
_ = let !ss' :: IntMap [b]
ss' = Int -> IntMap [b] -> IntMap [b]
forall a. Int -> IntMap a -> IntMap a
IM.delete Int
v IntMap [b]
ss
                       in Context' a b -> Maybe (Context' a b)
forall a. a -> Maybe a
Just (IntMap [b]
ps, a
l, IntMap [b]
ss')

clearPred :: forall a b x . GraphRep a b -> Node -> IM.IntMap x -> GraphRep a b
clearPred :: forall a b x. GraphRep a b -> Int -> IntMap x -> GraphRep a b
clearPred GraphRep a b
g Int
v = (Context' a b -> x -> Maybe (Context' a b))
-> GraphRep a b -> IntMap x -> GraphRep a b
forall a b. (a -> b -> Maybe a) -> IntMap a -> IntMap b -> IntMap a
IMS.differenceWith Context' a b -> x -> Maybe (Context' a b)
go GraphRep a b
g
  where
    go :: Context' a b -> x -> Maybe (Context' a b)
    go :: Context' a b -> x -> Maybe (Context' a b)
go (IntMap [b]
ps, a
l, IntMap [b]
ss) x
_ = let !ps' :: IntMap [b]
ps' = Int -> IntMap [b] -> IntMap [b]
forall a. Int -> IntMap a -> IntMap a
IM.delete Int
v IntMap [b]
ps
                       in Context' a b -> Maybe (Context' a b)
forall a. a -> Maybe a
Just (IntMap [b]
ps', a
l, IntMap [b]
ss)

{-----------------------------------------------------------------

Copyright (c) 1999-2008, Martin Erwig
              2010, Ivan Lazar Miljenovic
              2022, Norman Ramsey
All rights reserved.

Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:

1. Redistributions of source code must retain the above copyright notice,
   this list of conditions and the following disclaimer.

2. Redistributions in binary form must reproduce the above copyright
   notice, this list of conditions and the following disclaimer in the
   documentation and/or other materials provided with the distribution.

3. Neither the name of the author nor the names of its contributors may be
   used to endorse or promote products derived from this software without
   specific prior written permission.

THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
POSSIBILITY OF SUCH DAMAGE.

----------------------------------------------------------------}