module Bio.Bam.Index (
BamIndex(..),
readBamIndex,
readBaiIndex,
readTabix,
Region(..),
Subsequence(..),
eneeBamRefseq,
eneeBamSubseq,
eneeBamRegions,
eneeBamUnaligned
) where
import Bio.Bam.Header
import Bio.Bam.Reader
import Bio.Bam.Rec
import Bio.Bam.Regions ( Region(..), Subsequence(..) )
import Bio.Iteratee
import Bio.Prelude
import System.Posix.Files ( fileExist )
import qualified Bio.Bam.Regions as R
import qualified Data.IntMap.Strict as M
import qualified Data.ByteString as B
import qualified Data.Vector as V
import qualified Data.Vector.Mutable as W
import qualified Data.Vector.Unboxed as U
import qualified Data.Vector.Unboxed.Mutable as N
import qualified Data.Vector.Algorithms.Intro as N
data BamIndex a = BamIndex {
minshift :: !Int,
depth :: !Int,
unaln_off :: !Int64,
extensions :: a,
refseq_bins :: !(V.Vector Bins),
refseq_ckpoints :: !(V.Vector Ckpoints) }
deriving Show
type Bins = IntMap Segments
type Segments = U.Vector (Int64,Int64)
type Ckpoints = IntMap Int64
data Segment = Segment !Int64 !Int64 !Int deriving Show
segmentLists :: BamIndex a -> Refseq -> R.Subsequence -> [[Segment]]
segmentLists bi@BamIndex{..} (Refseq ref) (R.Subsequence imap)
| Just bins <- refseq_bins V.!? fromIntegral ref,
Just cpts <- refseq_ckpoints V.!? fromIntegral ref
= [ rgnToSegments bi beg end bins cpts | (beg,end) <- M.toList imap ]
segmentLists _ _ _ = []
rgnToSegments :: BamIndex a -> Int -> Int -> Bins -> Ckpoints -> [Segment]
rgnToSegments bi@BamIndex{..} beg end bins cpts =
[ Segment boff' eoff end
| bin <- binList bi beg end
, (boff,eoff) <- maybe [] U.toList $ M.lookup bin bins
, let boff' = max boff cpt
, boff' < eoff ]
where
!cpt = maybe 0 snd $ M.lookupLE beg cpts
binList :: BamIndex a -> Int -> Int -> [Int]
binList BamIndex{..} beg end = binlist' 0 (minshift + 3*depth) 0
where
binlist' l s t = if l > depth then [] else [b..e] ++ go
where
b = t + beg `shiftR` s
e = t + (end1) `shiftR` s
go = binlist' (l+1) (s3) (t + 1 `shiftL` (3*l))
infix 4 ~~
(~~) :: [Segment] -> [Segment] -> [Segment]
Segment a b e : xs ~~ Segment u v f : ys
| b < u = Segment a b e : (xs ~~ Segment u v f : ys)
| a < u && b < v = Segment a v (max e f) : (xs ~~ ys)
| b < v = Segment u v (max e f) : (xs ~~ ys)
| v < a = Segment u v f : (xs ~~ Segment a b e : ys)
| u < a = Segment u b (max e f) : (xs ~~ ys)
| otherwise = Segment a b (max e f) : (xs ~~ ys)
[] ~~ ys = ys
xs ~~ [] = xs
readBamIndex :: FilePath -> IO (BamIndex ())
readBamIndex fp | ".bai" `isSuffixOf` fp = enumFile defaultBufSize fp readBaiIndex >>= run
| ".csi" `isSuffixOf` fp = enumFile defaultBufSize fp readBaiIndex >>= run
| otherwise = tryIx (fp ++ ".bai") $
tryIx (dropExtension fp ++ "bai") $
tryIx (fp ++ ".csi") $
tryIx (dropExtension fp ++ "csi") $
enumFile defaultBufSize fp readBaiIndex >>= run
where
dropExtension p = reverse $ (if null b then "." ++ f else b) ++ d
where
(f,d) = break (=='/') $ reverse p
b = dropWhile (/='.') f
tryIx f k = do e <- fileExist f
if e then do r <- enumFile defaultBufSize f readBaiIndex >>= tryRun
case r of Right ix -> return ix
Left (IterStringException _) -> k
else k
readBaiIndex :: MonadIO m => Iteratee Bytes m (BamIndex ())
readBaiIndex = iGetString 4 >>= switch
where
switch "BAI\1" = do nref <- fromIntegral `liftM` endianRead4 LSB
getIndexArrays nref 14 5 (const return) getIntervals
switch "CSI\1" = do minshift <- fromIntegral `liftM` endianRead4 LSB
depth <- fromIntegral `liftM` endianRead4 LSB
endianRead4 LSB >>= dropStreamBS . fromIntegral
nref <- fromIntegral `liftM` endianRead4 LSB
getIndexArrays nref minshift depth (addOneCheckpoint minshift depth) return
switch magic = throwErr . iterStrExc $ "index signature " ++ show magic ++ " not recognized"
addOneCheckpoint minshift depth bin cp = do
loffset <- fromIntegral `liftM` endianRead8 LSB
let key = llim (fromIntegral bin) (3*depth) minshift
return $! M.insertWith min key loffset cp
llim bin dp sf | dp == 0 = 0
| bin >= ix = (bin ix) `shiftL` sf
| otherwise = llim bin (dp3) (sf+3)
where ix = (1 `shiftL` dp 1) `div` 7
type TabIndex = BamIndex TabMeta
data TabMeta = TabMeta { format :: TabFormat
, col_seq :: Int
, col_beg :: Int
, col_end :: Int
, comment_char :: Char
, skip_lines :: Int
, names :: V.Vector Bytes }
deriving Show
data TabFormat = Generic | SamFormat | VcfFormat | ZeroBased deriving Show
readTabix :: MonadIO m => Iteratee Bytes m TabIndex
readTabix = joinI $ decompressBgzf $ iGetString 4 >>= switch
where
switch "TBI\1" = do nref <- fromIntegral `liftM` endianRead4 LSB
format <- liftM toFormat (endianRead4 LSB)
col_seq <- liftM fromIntegral (endianRead4 LSB)
col_beg <- liftM fromIntegral (endianRead4 LSB)
col_end <- liftM fromIntegral (endianRead4 LSB)
comment_char <- liftM (chr . fromIntegral) (endianRead4 LSB)
skip_lines <- liftM fromIntegral (endianRead4 LSB)
names <- liftM (V.fromList . B.split 0) . iGetString . fromIntegral =<< endianRead4 LSB
ix <- getIndexArrays nref 14 5 (const return) getIntervals
fin <- isFinished
if fin then return $! ix { extensions = TabMeta{..} }
else do unaln <- fromIntegral `liftM` endianRead8 LSB
return $! ix { unaln_off = unaln, extensions = TabMeta{..} }
switch magic = throwErr . iterStrExc $ "index signature " ++ show magic ++ " not recognized"
toFormat 1 = SamFormat
toFormat 2 = VcfFormat
toFormat x = if testBit x 16 then ZeroBased else Generic
getIntervals :: Monad m => (IntMap Int64, Int64) -> Iteratee Bytes m (IntMap Int64, Int64)
getIntervals (cp,mx0) = do
nintv <- fromIntegral `liftM` endianRead4 LSB
reduceM 0 nintv (cp,mx0) $ \(!im,!mx) int -> do
oo <- fromIntegral `liftM` endianRead8 LSB
return (if oo == 0 then im else M.insert (int * 0x4000) oo im, max mx oo)
getIndexArrays :: MonadIO m => Int -> Int -> Int
-> (Word32 -> Ckpoints -> Iteratee Bytes m Ckpoints)
-> ((Ckpoints, Int64) -> Iteratee Bytes m (Ckpoints, Int64))
-> Iteratee Bytes m (BamIndex ())
getIndexArrays nref minshift depth addOneCheckpoint addManyCheckpoints
| nref < 1 = return $ BamIndex minshift depth 0 () V.empty V.empty
| otherwise = do
rbins <- liftIO $ W.new nref
rckpts <- liftIO $ W.new nref
mxR <- reduceM 0 nref 0 $ \mx0 r -> do
nbins <- endianRead4 LSB
(!bins,!cpts,!mx1) <- reduceM 0 nbins (M.empty,M.empty,mx0) $ \(!im,!cp,!mx) _ -> do
bin <- endianRead4 LSB
cp' <- addOneCheckpoint bin cp
segsarr <- getSegmentArray
let !mx' = if U.null segsarr then mx else max mx (snd (U.last segsarr))
return (M.insert (fromIntegral bin) segsarr im, cp', mx')
(!cpts',!mx2) <- addManyCheckpoints (cpts,mx1)
liftIO $ W.write rbins r bins >> W.write rckpts r cpts'
return mx2
liftM2 (BamIndex minshift depth mxR ()) (liftIO $ V.unsafeFreeze rbins) (liftIO $ V.unsafeFreeze rckpts)
getSegmentArray :: MonadIO m => Iteratee Bytes m Segments
getSegmentArray = do
nsegs <- fromIntegral `liftM` endianRead4 LSB
segsarr <- liftIO $ N.new nsegs
loopM 0 nsegs $ \i -> do beg <- fromIntegral `liftM` endianRead8 LSB
end <- fromIntegral `liftM` endianRead8 LSB
liftIO $ N.write segsarr i (beg,end)
liftIO $ N.sort segsarr >> U.unsafeFreeze segsarr
reduceM :: (Monad m, Enum ix, Eq ix) => ix -> ix -> a -> (a -> ix -> m a) -> m a
reduceM beg end acc cons = if beg /= end then cons acc beg >>= \n -> reduceM (succ beg) end n cons else return acc
loopM :: (Monad m, Enum ix, Eq ix) => ix -> ix -> (ix -> m ()) -> m ()
loopM beg end k = if beg /= end then k beg >> loopM (succ beg) end k else return ()
eneeBamRefseq :: Monad m => BamIndex b -> Refseq -> Enumeratee [BamRaw] [BamRaw] m a
eneeBamRefseq BamIndex{..} (Refseq r) iter
| Just ckpts <- refseq_ckpoints V.!? fromIntegral r
, Just (voff, _) <- M.minView ckpts
, voff /= 0 = do seek $ fromIntegral voff
breakE ((Refseq r /=) . b_rname . unpackBam) iter
| otherwise = return iter
eneeBamUnaligned :: Monad m => BamIndex b -> Enumeratee [BamRaw] [BamRaw] m a
eneeBamUnaligned BamIndex{..} iter = do when (unaln_off /= 0) $ seek $ fromIntegral unaln_off
filterStream (not . isValidRefseq . b_rname . unpackBam) iter
eneeBamSegment :: Monad m => Segment -> Enumeratee [BamRaw] [BamRaw] m r
eneeBamSegment (Segment beg end mpos) out = do
peekStream >>= \x -> case x of
Just br | beg <= o && beg + 0x8000 > o -> return ()
where o = fromIntegral $ virt_offset br
_ -> seek $ fromIntegral beg
let in_segment br = virt_offset br <= fromIntegral end && b_pos (unpackBam br) <= mpos
takeWhileE in_segment out
eneeBamSubseq :: Monad m => BamIndex b -> Refseq -> R.Subsequence -> Enumeratee [BamRaw] [BamRaw] m a
eneeBamSubseq bi ref subs = foldr ((>=>) . eneeBamSegment) return segs ><> filterStream olap
where
segs = foldr (~~) [] $ segmentLists bi ref subs
olap br = b_rname == ref && R.overlaps b_pos (b_pos + alignedLength b_cigar) subs
where BamRec{..} = unpackBam br
eneeBamRegions :: Monad m => BamIndex b -> [R.Region] -> Enumeratee [BamRaw] [BamRaw] m a
eneeBamRegions bi = foldr ((>=>) . uncurry (eneeBamSubseq bi)) return . R.toList . R.fromList