{-# LANGUAGE GADTs, BangPatterns #-}
module CmmCommonBlockElim
  ( elimCommonBlocks
  )
where


import BlockId
import Cmm
import CmmUtils
import CmmContFlowOpt
-- import PprCmm ()
import Prelude hiding (iterate, succ, unzip, zip)

import Hoopl hiding (ChangeFlag)
import Data.Bits
import Data.Maybe (mapMaybe)
import qualified Data.List as List
import Data.Word
import qualified Data.Map as M
import Outputable
import UniqFM
import Unique
import Control.Arrow (first, second)

-- -----------------------------------------------------------------------------
-- Eliminate common blocks

-- If two blocks are identical except for the label on the first node,
-- then we can eliminate one of the blocks. To ensure that the semantics
-- of the program are preserved, we have to rewrite each predecessor of the
-- eliminated block to proceed with the block we keep.

-- The algorithm iterates over the blocks in the graph,
-- checking whether it has seen another block that is equal modulo labels.
-- If so, then it adds an entry in a map indicating that the new block
-- is made redundant by the old block.
-- Otherwise, it is added to the useful blocks.

-- To avoid comparing every block with every other block repeatedly, we group
-- them by
--   * a hash of the block, ignoring labels (explained below)
--   * the list of outgoing labels
-- The hash is invariant under relabeling, so we only ever compare within
-- the same group of blocks.
--
-- The list of outgoing labels is updated as we merge blocks (that is why they
-- are not included in the hash, which we want to calculate only once).
--
-- All in all, two blocks should never be compared if they have different
-- hashes, and at most once otherwise. Previously, we were slower, and people
-- rightfully complained: #10397

-- TODO: Use optimization fuel
elimCommonBlocks :: CmmGraph -> CmmGraph
elimCommonBlocks g = replaceLabels env $ copyTicks env g
  where
     env = iterate mapEmpty blocks_with_key
     groups = groupByInt hash_block (postorderDfs g)
     blocks_with_key = [ [ (successors b, [b]) | b <- bs] | bs <- groups]

-- Invariant: The blocks in the list are pairwise distinct
-- (so avoid comparing them again)
type DistinctBlocks = [CmmBlock]
type Key = [Label]
type Subst = BlockEnv BlockId

-- The outer list groups by hash. We retain this grouping throughout.
iterate :: Subst -> [[(Key, DistinctBlocks)]] -> Subst
iterate subst blocks
    | mapNull new_substs = subst
    | otherwise = iterate subst' updated_blocks
  where
    grouped_blocks :: [[(Key, [DistinctBlocks])]]
    grouped_blocks = map groupByLabel blocks

    merged_blocks :: [[(Key, DistinctBlocks)]]
    (new_substs, merged_blocks) = List.mapAccumL (List.mapAccumL go) mapEmpty grouped_blocks
      where
        go !new_subst1 (k,dbs) = (new_subst1 `mapUnion` new_subst2, (k,db))
          where
            (new_subst2, db) = mergeBlockList subst dbs

    subst' = subst `mapUnion` new_substs
    updated_blocks = map (map (first (map (lookupBid subst')))) merged_blocks

mergeBlocks :: Subst -> DistinctBlocks -> DistinctBlocks -> (Subst, DistinctBlocks)
mergeBlocks subst existing new = go new
  where
    go [] = (mapEmpty, existing)
    go (b:bs) = case List.find (eqBlockBodyWith (eqBid subst) b) existing of
        -- This block is a duplicate. Drop it, and add it to the substitution
        Just b' -> first (mapInsert (entryLabel b) (entryLabel b')) $ go bs
        -- This block is not a duplicate, keep it.
        Nothing -> second (b:) $ go bs

mergeBlockList :: Subst -> [DistinctBlocks] -> (Subst, DistinctBlocks)
mergeBlockList _ [] = pprPanic "mergeBlockList" empty
mergeBlockList subst (b:bs) = go mapEmpty b bs
  where
    go !new_subst1 b [] = (new_subst1, b)
    go !new_subst1 b1 (b2:bs) = go new_subst b bs
      where
        (new_subst2, b) =  mergeBlocks subst b1 b2
        new_subst = new_subst1 `mapUnion` new_subst2


-- -----------------------------------------------------------------------------
-- Hashing and equality on blocks

-- Below here is mostly boilerplate: hashing blocks ignoring labels,
-- and comparing blocks modulo a label mapping.

-- To speed up comparisons, we hash each basic block modulo jump labels.
-- The hashing is a bit arbitrary (the numbers are completely arbitrary),
-- but it should be fast and good enough.

-- We want to get as many small buckets as possible, as comparing blocks is
-- expensive. So include as much as possible in the hash. Ideally everything
-- that is compared with (==) in eqBlockBodyWith.

type HashCode = Int

hash_block :: CmmBlock -> HashCode
hash_block block =
  fromIntegral (foldBlockNodesB3 (hash_fst, hash_mid, hash_lst) block (0 :: Word32) .&. (0x7fffffff :: Word32))
  -- UniqFM doesn't like negative Ints
  where hash_fst _ h = h
        hash_mid m h = hash_node m + h `shiftL` 1
        hash_lst m h = hash_node m + h `shiftL` 1

        hash_node :: CmmNode O x -> Word32
        hash_node n | dont_care n = 0 -- don't care
        hash_node (CmmUnwind _ e) = hash_e e
        hash_node (CmmAssign r e) = hash_reg r + hash_e e
        hash_node (CmmStore e e') = hash_e e + hash_e e'
        hash_node (CmmUnsafeForeignCall t _ as) = hash_tgt t + hash_list hash_e as
        hash_node (CmmBranch _) = 23 -- NB. ignore the label
        hash_node (CmmCondBranch p _ _) = hash_e p
        hash_node (CmmCall e _ _ _ _ _) = hash_e e
        hash_node (CmmForeignCall t _ _ _ _ _ _) = hash_tgt t
        hash_node (CmmSwitch e _) = hash_e e
        hash_node _ = error "hash_node: unknown Cmm node!"

        hash_reg :: CmmReg -> Word32
        hash_reg   (CmmLocal localReg) = hash_unique localReg -- important for performance, see #10397
        hash_reg   (CmmGlobal _)    = 19

        hash_e :: CmmExpr -> Word32
        hash_e (CmmLit l) = hash_lit l
        hash_e (CmmLoad e _) = 67 + hash_e e
        hash_e (CmmReg r) = hash_reg r
        hash_e (CmmMachOp _ es) = hash_list hash_e es -- pessimal - no operator check
        hash_e (CmmRegOff r i) = hash_reg r + cvt i
        hash_e (CmmStackSlot _ _) = 13

        hash_lit :: CmmLit -> Word32
        hash_lit (CmmInt i _) = fromInteger i
        hash_lit (CmmFloat r _) = truncate r
        hash_lit (CmmVec ls) = hash_list hash_lit ls
        hash_lit (CmmLabel _) = 119 -- ugh
        hash_lit (CmmLabelOff _ i) = cvt $ 199 + i
        hash_lit (CmmLabelDiffOff _ _ i) = cvt $ 299 + i
        hash_lit (CmmBlock _) = 191 -- ugh
        hash_lit (CmmHighStackMark) = cvt 313

        hash_tgt (ForeignTarget e _) = hash_e e
        hash_tgt (PrimTarget _) = 31 -- lots of these

        hash_list f = foldl (\z x -> f x + z) (0::Word32)

        cvt = fromInteger . toInteger

        hash_unique :: Uniquable a => a -> Word32
        hash_unique = cvt . getKey . getUnique

-- | Ignore these node types for equality
dont_care :: CmmNode O x -> Bool
dont_care CmmComment {}  = True
dont_care CmmTick {}     = True
dont_care _other         = False

-- Utilities: equality and substitution on the graph.

-- Given a map ``subst'' from BlockID -> BlockID, we define equality.
eqBid :: BlockEnv BlockId -> BlockId -> BlockId -> Bool
eqBid subst bid bid' = lookupBid subst bid == lookupBid subst bid'
lookupBid :: BlockEnv BlockId -> BlockId -> BlockId
lookupBid subst bid = case mapLookup bid subst of
                        Just bid  -> lookupBid subst bid
                        Nothing -> bid

-- Middle nodes and expressions can contain BlockIds, in particular in
-- CmmStackSlot and CmmBlock, so we have to use a special equality for
-- these.
--
eqMiddleWith :: (BlockId -> BlockId -> Bool)
             -> CmmNode O O -> CmmNode O O -> Bool
eqMiddleWith eqBid (CmmAssign r1 e1) (CmmAssign r2 e2)
  = r1 == r2 && eqExprWith eqBid e1 e2
eqMiddleWith eqBid (CmmStore l1 r1) (CmmStore l2 r2)
  = eqExprWith eqBid l1 l2 && eqExprWith eqBid r1 r2
eqMiddleWith eqBid (CmmUnsafeForeignCall t1 r1 a1)
                   (CmmUnsafeForeignCall t2 r2 a2)
  = t1 == t2 && r1 == r2 && and (zipWith (eqExprWith eqBid) a1 a2)
eqMiddleWith _ _ _ = False

eqExprWith :: (BlockId -> BlockId -> Bool)
           -> CmmExpr -> CmmExpr -> Bool
eqExprWith eqBid = eq
 where
  CmmLit l1          `eq` CmmLit l2          = eqLit l1 l2
  CmmLoad e1 _       `eq` CmmLoad e2 _       = e1 `eq` e2
  CmmReg r1          `eq` CmmReg r2          = r1==r2
  CmmRegOff r1 i1    `eq` CmmRegOff r2 i2    = r1==r2 && i1==i2
  CmmMachOp op1 es1  `eq` CmmMachOp op2 es2  = op1==op2 && es1 `eqs` es2
  CmmStackSlot a1 i1 `eq` CmmStackSlot a2 i2 = eqArea a1 a2 && i1==i2
  _e1                `eq` _e2                = False

  xs `eqs` ys = and (zipWith eq xs ys)

  eqLit (CmmBlock id1) (CmmBlock id2) = eqBid id1 id2
  eqLit l1 l2 = l1 == l2

  eqArea Old Old = True
  eqArea (Young id1) (Young id2) = eqBid id1 id2
  eqArea _ _ = False

-- Equality on the body of a block, modulo a function mapping block
-- IDs to block IDs.
eqBlockBodyWith :: (BlockId -> BlockId -> Bool) -> CmmBlock -> CmmBlock -> Bool
eqBlockBodyWith eqBid block block'
  {-
  | equal     = pprTrace "equal" (vcat [ppr block, ppr block']) True
  | otherwise = pprTrace "not equal" (vcat [ppr block, ppr block']) False
  -}
  = equal
  where (_,m,l)   = blockSplit block
        nodes     = filter (not . dont_care) (blockToList m)
        (_,m',l') = blockSplit block'
        nodes'    = filter (not . dont_care) (blockToList m')

        equal = and (zipWith (eqMiddleWith eqBid) nodes nodes') &&
                eqLastWith eqBid l l'


eqLastWith :: (BlockId -> BlockId -> Bool) -> CmmNode O C -> CmmNode O C -> Bool
eqLastWith eqBid (CmmBranch bid1) (CmmBranch bid2) = eqBid bid1 bid2
eqLastWith eqBid (CmmCondBranch c1 t1 f1) (CmmCondBranch c2 t2 f2) =
  c1 == c2 && eqBid t1 t2 && eqBid f1 f2
eqLastWith eqBid (CmmCall t1 c1 g1 a1 r1 u1) (CmmCall t2 c2 g2 a2 r2 u2) =
  t1 == t2 && eqMaybeWith eqBid c1 c2 && a1 == a2 && r1 == r2 && u1 == u2 && g1 == g2
eqLastWith eqBid (CmmSwitch e1 bs1) (CmmSwitch e2 bs2) =
  e1 == e2 && eqListWith (eqMaybeWith eqBid) bs1 bs2
eqLastWith _ _ _ = False

eqListWith :: (a -> b -> Bool) -> [a] -> [b] -> Bool
eqListWith eltEq es es' = all (uncurry eltEq) (List.zip es es')

eqMaybeWith :: (a -> b -> Bool) -> Maybe a -> Maybe b -> Bool
eqMaybeWith eltEq (Just e) (Just e') = eltEq e e'
eqMaybeWith _ Nothing Nothing = True
eqMaybeWith _ _ _ = False

-- | Given a block map, ensure that all "target" blocks are covered by
-- the same ticks as the respective "source" blocks. This not only
-- means copying ticks, but also adjusting tick scopes where
-- necessary.
copyTicks :: BlockEnv BlockId -> CmmGraph -> CmmGraph
copyTicks env g
  | mapNull env = g
  | otherwise   = ofBlockMap (g_entry g) $ mapMap copyTo blockMap
  where -- Reverse block merge map
        blockMap = toBlockMap g
        revEnv = mapFoldWithKey insertRev M.empty env
        insertRev k x = M.insertWith (const (k:)) x [k]
        -- Copy ticks and scopes into the given block
        copyTo block = case M.lookup (entryLabel block) revEnv of
          Nothing -> block
          Just ls -> foldr copy block $ mapMaybe (flip mapLookup blockMap) ls
        copy from to =
          let ticks = blockTicks from
              CmmEntry  _   scp0        = firstNode from
              (CmmEntry lbl scp1, code) = blockSplitHead to
          in CmmEntry lbl (combineTickScopes scp0 scp1) `blockJoinHead`
             foldr blockCons code (map CmmTick ticks)

-- Group by [Label]
groupByLabel :: [(Key, a)] -> [(Key, [a])]
groupByLabel = go M.empty
  where
    go !m [] = M.elems m
    go !m ((k,v) : entries) = go (M.alter adjust k' m) entries
      where k' = map getUnique k
            adjust Nothing       = Just (k,[v])
            adjust (Just (_,vs)) = Just (k,v:vs)


groupByInt :: (a -> Int) -> [a] -> [[a]]
groupByInt f xs = eltsUFM $ List.foldl' go emptyUFM xs
  where go m x = alterUFM (Just . maybe [x] (x:)) m (f x)