module Darcs.Util.Diff.Myers
( getChanges
, shiftBoundaries
, initP
, aLen
, PArray
, getSlice
) where
import Prelude ()
import Darcs.Prelude
import Control.Monad
import Data.Int
import Control.Monad.ST
import Data.Maybe
import Darcs.Util.ByteString (hashPS)
import qualified Data.ByteString as B (empty, ByteString)
import Data.Array.Base
import Data.Array.Unboxed
import qualified Data.Map as Map ( lookup, empty, insertWith )
getChanges :: [B.ByteString] -> [B.ByteString]
-> [(Int,[B.ByteString],[B.ByteString])]
getChanges a b = dropStart (initP a) (initP b) 1
dropStart :: PArray -> PArray -> Int
-> [(Int,[B.ByteString],[B.ByteString])]
dropStart a b off
| off > aLen a = [(off 1, [], getSlice b off (aLen b))]
| off > aLen b = [(off 1, getSlice a off (aLen a), [])]
| a!off == b!off = dropStart a b (off + 1)
| otherwise = dropEnd a b off 0
dropEnd :: PArray -> PArray -> Int -> Int
-> [(Int,[B.ByteString],[B.ByteString])]
dropEnd a b off end
| off > alast = [(off 1, [], getSlice b off blast)]
| off > blast = [(off 1, getSlice a off alast, [])]
| a!alast == b!blast = dropEnd a b off (end + 1)
| otherwise = getChanges' (a, (off, alast)) (b, (off, blast))
where alast = aLen a end
blast = aLen b end
getSlice :: PArray -> Int -> Int -> [B.ByteString]
getSlice a from to
| from > to = []
| otherwise = (a ! from) : getSlice a (from + 1) to
getChanges' :: (PArray, (Int, Int)) -> (PArray, (Int, Int))
-> [(Int,[B.ByteString],[B.ByteString])]
getChanges' (a, abounds) (b, bbounds) =
map (convertPatch 0 a b) $ createPatch c_a c_b
where
toHash x bnds = listArray bnds [ hashPS $ x!i | i <- range bnds]
ah = toHash a abounds :: HArray
mkAMap m (i:is) =
let ins (_,_,_,new) (collision,_,_,old) =
(collision || (new /= old), True, False, old)
m' = Map.insertWith ins (ah!i) (False, True, False, a!i) m
in mkAMap m' is
mkAMap m _ = m
hm_a = mkAMap Map.empty (range abounds)
bh = toHash b bbounds :: HArray
mkBMap m (i:is) =
let ins (_,_,_,new) (collision,in_a,_,old) =
(collision || (new /= old), in_a, True, old)
m' = Map.insertWith ins (bh!i) (False, False, True, b!i) m
in mkBMap m' is
mkBMap m _ = m
hm = mkBMap hm_a (range bbounds)
get (i, h) = case Map.lookup h hm of
Just (_,False,_,_) -> Nothing
Just (_,_,False,_) -> Nothing
Just (False,True,True,_) -> Just (i, h)
Just (True,True,True,_) -> Just (i, markColl)
Nothing -> impossible
a' = mapMaybe get [(i, ah!i) | i <- range (bounds ah)]
b' = mapMaybe get [(i, bh!i) | i <- range (bounds bh)]
(c_a, c_b) = diffArr a' b' (a, abounds) (b, bbounds)
markColl :: Int32
markColl = 2345677
diffArr :: [(Int,Int32)] -> [(Int,Int32)]
-> (PArray, (Int, Int)) -> (PArray, (Int, Int))
-> (BArray, BArray)
diffArr a b (p_a, (off_a, l_a)) (p_b, (off_b, l_b)) = runST (
do let h_a = initH (map snd a)
h_b = initH (map snd b)
m_a = initM (map fst a)
m_b = initM (map fst b)
end_a = aLen p_a
end_b = aLen p_b
c_a <- initVChanged end_a
c_b <- initVChanged end_b
mapM_ (\ (l,_) -> writeArray c_a l False) a
mapM_ (\ (l,_) -> writeArray c_b l False) b
_ <- cmpseq h_a h_b p_a p_b m_a m_b c_a c_b 0 0 (aLen h_a) (aLen h_b)
let unchanged ar = do {xs <- getElems ar; return $ length (filter not xs) 1}
err <- liftM2 (/=) (unchanged c_a) (unchanged c_b)
when err impossible
mapM_ (\ i -> writeArray c_a i False ) [1..(off_a 1)]
mapM_ (\ i -> writeArray c_b i False ) [1..(off_b 1)]
mapM_ (\ i -> writeArray c_a i False ) [(l_a + 1) .. end_a]
mapM_ (\ i -> writeArray c_b i False ) [(l_b + 1) .. end_b]
shiftBoundaries c_a c_b p_a 1 1
shiftBoundaries c_b c_a p_b 1 1
err1 <- liftM2 (/=) (unchanged c_a) (unchanged c_b)
when err1 impossible
c_a' <- unsafeFreeze c_a
c_b' <- unsafeFreeze c_b
return (c_a', c_b'))
cmpseq :: HArray -> HArray -> PArray -> PArray -> MapArray -> MapArray
-> BSTArray s -> BSTArray s -> Int -> Int -> Int -> Int -> ST s Int
cmpseq _ _ _ _ _ _ _ _ _ _ 0 0 = return 0
cmpseq h_a h_b p_a p_b m_a m_b c_a c_b off_a off_b l_a l_b = do
let lim_a = off_a+l_a
lim_b = off_b+l_b
off_a' = findSnake h_a h_b p_a p_b m_a m_b off_a off_b l_a l_b off_a off_b
off_b' = off_b+off_a'off_a
lim_a' = findSnakeRev h_a h_b p_a p_b m_a m_b lim_a lim_b off_a' off_b'
lim_b' = lim_b+lim_a'lim_a
l_a' = lim_a'off_a'
l_b' = lim_b'off_b'
if l_a' == 0 || l_b' == 0
then if l_a' == 0
then do when (l_b' > 0) $
mapM_ (\i -> writeArray c_b (m_b!i) True)
[(off_b' + 1) .. lim_b']
return l_b'
else do when (l_a' > 0) $
mapM_ (\i -> writeArray c_a (m_a!i) True)
[(off_a' + 1) .. lim_a']
return l_a'
else do let m = l_a' + l_b'
del = l_a' l_b'
dodd = odd del
v <- initV m
vrev <- initVRev m l_a'
writeArray vrev 0 l_a'
writeArray v 0 0
(xmid, ymid, _) <- findDiag 1 h_a h_b p_a p_b m_a m_b v vrev
off_a' off_b' l_a' l_b' del dodd
when ((xmid == 0 && ymid == 0) || (xmid == l_a' && ymid == l_b')
|| (xmid < 0 || ymid < 0 || xmid > l_a' || ymid > l_b'))
impossible
c1 <- cmpseq h_a h_b p_a p_b m_a m_b c_a c_b
off_a' off_b' xmid ymid
c2 <- cmpseq h_a h_b p_a p_b m_a m_b c_a c_b
(off_a' + xmid) (off_b' + ymid)
(l_a' xmid) (l_b' ymid)
return $ c1 + c2
findDiag :: Int -> HArray -> HArray -> PArray -> PArray -> MapArray -> MapArray
-> VSTArray s -> VSTArray s -> Int -> Int -> Int -> Int -> Int -> Bool
-> ST s (Int, Int, Int)
findDiag c h_a h_b p_a p_b m_a m_b v vrev off_a off_b l_a l_b del dodd = do
when (c > l_a + l_b) $ error "findDiag failed"
r <- findF
case r of
Just (xmid, ymid) -> return (xmid, ymid, c*2 1)
Nothing ->
do r' <- findR
case r' of
Just (xmid, ymid) -> return (xmid, ymid, c*2)
Nothing -> findDiag (c + 1) h_a h_b p_a p_b m_a m_b v vrev
off_a off_b l_a l_b del dodd
where fdmax = if c <= l_a then c else l_a ((l_a + c) `mod` 2)
rdmax = if c <= l_b then c else l_b ((l_b + c) `mod` 2)
lastrdmax = if (c1) <= l_b then c1 else l_b(l_b + (c1) `mod` 2)
lastrdmin = (if (c1) <= l_a then c1 else l_a((l_a + (c1)) `mod` 2))
fdmin = rdmax
rdmin = fdmax
findF = findF' fdmax
findR = findR' rdmax
findF' d = do x <- findOne h_a h_b p_a p_b m_a m_b v d off_a off_b l_a l_b
if dodd && d del >= lastrdmin && d del <= lastrdmax
then do xr <- readArray vrev (d del)
if xr <= x then return $ Just (x, x d)
else if d <= fdmin then return Nothing
else findF' (d2)
else if d <= fdmin then return Nothing else findF' (d2)
findR' d = do x <- findOneRev h_a h_b p_a p_b m_a m_b vrev d del off_a off_b
if not dodd && (d + del >= fdmin) && (d + del <= fdmax)
then do xf <- readArray v (d + del)
if x <= xf then return $ Just (x,xdeld)
else if d <= rdmin then return Nothing
else findR' (d2)
else if d <= rdmin then return Nothing else findR' (d2)
findOne :: HArray -> HArray -> PArray -> PArray -> MapArray -> MapArray
-> VSTArray s -> Int -> Int -> Int -> Int -> Int -> ST s Int
findOne h_a h_b p_a p_b m_a m_b v d off_a off_b l_a l_b = do
x0 <- do xbelow <- readArray v (d 1)
xover <- readArray v (d + 1)
return $ if xover > xbelow then xover else xbelow + 1
let y0 = x0 d
x = findSnake h_a h_b p_a p_b m_a m_b (x0+off_a) (y0+off_b)
l_a l_b off_a off_b
writeArray v d (x off_a)
return (xoff_a)
findSnake :: HArray -> HArray -> PArray -> PArray -> MapArray -> MapArray
-> Int -> Int -> Int -> Int -> Int -> Int -> Int
findSnake h_a h_b p_a p_b m_a m_b x y l_a l_b off_a off_b =
if x < l_a + off_a && y < l_b + off_b && h_a!(x+1) == h_b!(y+1)
&& (h_a!(x+1) /= markColl || p_a!(m_a!(x+1)) == p_b!(m_b!(y+1)))
then findSnake h_a h_b p_a p_b m_a m_b (x + 1) (y + 1) l_a l_b off_a off_b
else x
findOneRev :: HArray -> HArray -> PArray -> PArray -> MapArray -> MapArray
-> VSTArray s -> Int -> Int -> Int -> Int -> ST s Int
findOneRev h_a h_b p_a p_b m_a m_b v d del off_a off_b = do
x0 <- do xbelow <- readArray v (d 1)
xover <- readArray v (d + 1)
return $ if xbelow < xover then xbelow else xover1
let y0 = x0 del d
x = findSnakeRev h_a h_b p_a p_b m_a m_b (x0+off_a) (y0+off_b)
off_a off_b
writeArray v d (xoff_a)
return (xoff_a)
findSnakeRev :: HArray -> HArray -> PArray -> PArray -> MapArray -> MapArray
-> Int -> Int -> Int -> Int -> Int
findSnakeRev h_a h_b p_a p_b m_a m_b x y off_a off_b =
if x > off_a && y > off_b && h_a!x == h_b!y
&& (h_a!x /= markColl || p_a!(m_a!x) == p_b!(m_b!y))
then findSnakeRev h_a h_b p_a p_b m_a m_b (x 1) (y 1) off_a off_b
else x
shiftBoundaries :: BSTArray s -> BSTArray s -> PArray -> Int -> Int -> ST s ()
shiftBoundaries c_a c_b p_a i_ j_ =
do x <- nextChanged c_a i_
case x of
Just start ->
do let skipped = start i_
j1 <- nextUnchangedN c_b skipped j_
end <- nextUnchanged c_a start
j2 <- nextUnchanged c_b j1
(i3,j3) <- expand start end j2
shiftBoundaries c_a c_b p_a i3 j3
Nothing -> return ()
where noline = aLen p_a + 1
expand start i j =
do let len = i start
(start0,i0,j0) <- shiftBackward start i j
b <- if j0 > 1 then readArray c_b (j01) else return False
let corr = if b then i0 else noline
let blank = if p_a!(i01) == B.empty then i0
else noline
(start1,i1,j1,corr1,blank1) <- shiftForward start0 i0 j0 corr blank
let newi = if corr1 == noline then blank1
else corr1
(start2,i2,j2) <- moveCorr start1 i1 j1 newi
if len /= i2 start2
then expand start2 i2 j2
else return (i2, j2)
shiftBackward start i j =
if start > 1 && p_a!(i1) == p_a!(start1)
then do when (i == start) impossible
b1 <- readArray c_a (i1)
b2 <- readArray c_a (start1)
when (not b1 || b2) impossible
writeArray c_a (i1) False
writeArray c_a (start1) True
b <- if start > 2 then readArray c_a (start2)
else return False
start' <- if b then liftM (1+) (prevUnchanged c_a (start2))
else return (start1)
j' <- prevUnchanged c_b (j1)
shiftBackward start' (i1) j'
else return (start,i,j)
shiftForward start i j corr blank =
if i <= aLen p_a && p_a!i == p_a!start &&
not ((i == aLen p_a) && (p_a!i == B.empty))
then do when (i == start) impossible
b1 <- readArray c_a i
b2 <- readArray c_a start
when (not b2 || b1) impossible
writeArray c_a i True
writeArray c_a start False
i0 <- nextUnchanged c_a (i+1)
j0 <- nextUnchanged c_b (j+1)
let corr0
| i0 > (i+1) = noline
| j0j > 2 = i0
| otherwise = corr
let blank0
| i0 > i+1 = noline
| p_a!(i01) == B.empty = i0
| otherwise = blank
shiftForward (start+1) i0 j0 corr0 blank0
else return (start,i,j,corr,blank)
moveCorr start i j corr =
if corr >= i
then return (start,i,j)
else do b1 <- readArray c_a (i1)
b2 <- readArray c_a (start1)
when (not b1 || b2) impossible
when (p_a!(i1) /= p_a!(start1)) impossible
writeArray c_a (i1) False
writeArray c_a (start1) True
j' <- prevUnchanged c_b (j1)
moveCorr (start1) (i1) j' corr
nextUnchanged :: BSTArray s -> Int -> ST s Int
nextUnchanged c i = do
len <- aLenM c
if i == len + 1 then return i
else do b <- readArray c i
if b then nextUnchanged c (i+1)
else return i
skipOneUnChanged :: BSTArray s -> Int -> ST s Int
skipOneUnChanged c i = do
len <- aLenM c
if i == len + 1
then return i
else do b <- readArray c i
if not b then return (i+1)
else skipOneUnChanged c (i+1)
nextUnchangedN :: BSTArray s -> Int -> Int -> ST s Int
nextUnchangedN c n i =
if n == 0 then return i
else do i' <- skipOneUnChanged c i
nextUnchangedN c (n1) i'
nextChanged :: BSTArray s -> Int -> ST s (Maybe Int)
nextChanged c i = do
len <- aLenM c
if i <= len
then do b <- readArray c i
if not b then nextChanged c (i+1)
else return $ Just i
else return Nothing
prevUnchanged :: BSTArray s -> Int -> ST s Int
prevUnchanged c i = do
b <- readArray c i
if b then prevUnchanged c (i1)
else return i
type HArray = UArray Int Int32
type BArray = UArray Int Bool
type PArray = Array Int B.ByteString
type MapArray = UArray Int Int
type VSTArray s = STUArray s Int Int
type BSTArray s = STUArray s Int Bool
initV :: Int -> ST s (VSTArray s)
initV dmax = newArray ((dmax + 1), dmax + 1) (1)
initVRev :: Int -> Int -> ST s (VSTArray s)
initVRev dmax xmax = newArray ((dmax + 1), dmax + 1) (xmax + 1)
initVChanged :: Int -> ST s (BSTArray s)
initVChanged l = do
a <- newArray (0, l) True
writeArray a 0 False
return a
initH :: [Int32] -> HArray
initH a = listArray (0, length a) (0:a)
initM :: [Int] -> MapArray
initM a = listArray (0, length a) (0:a)
initP :: [B.ByteString] -> PArray
initP a = listArray (0, length a) (B.empty:a)
aLen :: (IArray a e) => a Int e -> Int
aLen a = snd $ bounds a
aLenM :: (MArray a e m) => a Int e -> m Int
aLenM a = snd `liftM` getBounds a
convertPatch :: Int -> PArray -> PArray -> (Int, Int, Int, Int)
-> (Int,[B.ByteString],[B.ByteString])
convertPatch off a b (a0,a1,b0,b1)
| b0 == b1 = (b0+off,getDelete a a0 a1,[])
| a0 == a1 = (b0+off,[],getInsert b b0 b1)
| otherwise = (b0+off,getDelete a a0 a1,getInsert b b0 b1)
getInsert :: PArray -> Int -> Int -> [B.ByteString]
getInsert b from to
| from >= to = []
| otherwise = (b!(from+1)):getInsert b (from+1) to
getDelete :: PArray -> Int -> Int -> [B.ByteString]
getDelete a from to
| from >= to = []
| otherwise = (a!(from+1)):getDelete a (from+1) to
createPatch :: BArray -> BArray -> [(Int, Int, Int, Int)]
createPatch c_a c_b =
reverse $ createP c_a c_b (aLen c_a) (aLen c_b)
createP :: BArray -> BArray -> Int -> Int -> [(Int, Int, Int, Int)]
createP _ _ 0 0 = []
createP c_a c_b ia ib =
if c_a!ia || c_b!ib
then let ia' = skipChangedRev c_a ia
ib' = skipChangedRev c_b ib
in (ia',ia,ib',ib):createP c_a c_b ia' ib'
else createP c_a c_b (ia1) (ib1)
skipChangedRev :: BArray -> Int -> Int
skipChangedRev c i = if i >= 0 && c!i then skipChangedRev c (i1) else i