import UniqSet
import UniqFM
+import Unique
import State
+import Outputable
import Data.Maybe
import Data.List
-type Slot = Int
-
-- | Clean out unneeded spill/reloads from this top level thing.
cleanSpills :: LiveCmmTop -> LiveCmmTop
cleanSpills cmm
-- then we don't need to do the reload.
--
cleanReload
- :: Assoc Reg Slot -- ^ a reg and slot are associated when they have the same value.
+ :: Assoc Store -- ^ two store locations are associated if they have the same value
-> [LiveInstr] -- ^ acc
-> [LiveInstr] -- ^ instrs to clean (in backwards order)
-> CleanM [LiveInstr] -- ^ cleaned instrs (in forward order)
cleanReload _ acc []
= return acc
+-- write out live range joins via spill slots to just a spill and a reg-reg move
+-- hopefully the spill will be also be cleaned in the next pass
+--
+cleanReload assoc acc (Instr i1 live1 : Instr i2 _ : instrs)
+
+ | SPILL reg1 slot1 <- i1
+ , RELOAD slot2 reg2 <- i2
+ , slot1 == slot2
+ = do
+ modify $ \s -> s { sCleanedReloadsAcc = sCleanedReloadsAcc s + 1 }
+ cleanReload assoc acc
+ (Instr i1 live1 : Instr (mkRegRegMoveInstr reg1 reg2) Nothing : instrs)
+
+
+cleanReload assoc acc (li@(Instr i1 _) : instrs)
+ | Just (r1, r2) <- isRegRegMove i1
+ = if r1 == r2
+ -- erase any left over nop reg reg moves while we're here
+ -- this will also catch any nop moves that the "write out live range joins" case above
+ -- happens to add
+ then cleanReload assoc acc instrs
+
+ -- if r1 has the same value as some slots and we copy r1 to r2,
+ -- then r2 is now associated with those slots instead
+ else do let assoc' = addAssoc (SReg r1) (SReg r2)
+ $ delAssoc (SReg r2)
+ $ assoc
+
+ cleanReload assoc' (li : acc) instrs
+
+
cleanReload assoc acc (li@(Instr instr _) : instrs)
| SPILL reg slot <- instr
- = let assoc' = addAssoc reg slot -- doing the spill makes reg and slot the same value
- $ deleteBAssoc slot -- slot value changes on spill
+ = let assoc' = addAssoc (SReg reg) (SSlot slot) -- doing the spill makes reg and slot the same value
+ $ delAssoc (SSlot slot) -- slot value changes on spill
$ assoc
in cleanReload assoc' (li : acc) instrs
| RELOAD slot reg <- instr
- = if elemAssoc reg slot assoc
+ = if elemAssoc (SSlot slot) (SReg reg) assoc
- -- reg and slot had the same value before reload
- -- we don't need the reload.
+ -- if the reg and slot had the same value before reload
+ -- then we don't need the reload.
then do
modify $ \s -> s { sCleanedReloadsAcc = sCleanedReloadsAcc s + 1 }
cleanReload assoc acc instrs
-- reg and slot had different values before reload
else
- let assoc' = addAssoc reg slot -- doing the reload makes reg and slot the same value
- $ deleteAAssoc reg -- reg value changes on reload
+ let assoc' = addAssoc (SReg reg) (SSlot slot) -- doing the reload makes reg and slot the same value
+ $ delAssoc (SReg reg) -- reg value changes on reload
$ assoc
in cleanReload assoc' (li : acc) instrs
- -- on a jump, remember the reg/slot association.
+ -- remember the association over a jump
| targets <- jumpDests instr []
, not $ null targets
= do mapM_ (accJumpValid assoc) targets
-- writing to a reg changes its value.
| RU _ written <- regUsage instr
- = let assoc' = foldr deleteAAssoc assoc written
+ = let assoc' = foldr delAssoc assoc (map SReg $ nub written)
in cleanReload assoc' (li : acc) instrs
-- then the slot was never read and we don't need the spill.
cleanSpill
- :: UniqSet Int -- ^ slots that have been spilled, but not reload from
+ :: UniqSet Int -- ^ slots that have been spilled, but not reloaded from
-> [LiveInstr] -- ^ acc
-> [LiveInstr] -- ^ instrs to clean (in forwards order)
-> CleanM [LiveInstr] -- ^ cleaned instrs (in backwards order)
-- collateJoinPoints:
--
--- | Look at information about what regs were valid across jumps and work out
--- whether it's safe to avoid reloads after join points.
+-- | combine the associations from all the inward control flow edges.
--
collateJoinPoints :: CleanM ()
collateJoinPoints
{ sJumpValid = mapUFM intersects (sJumpValidAcc s)
, sJumpValidAcc = emptyUFM }
-intersects :: [Assoc Reg Slot] -> Assoc Reg Slot
+intersects :: [Assoc Store] -> Assoc Store
intersects [] = emptyAssoc
intersects assocs = foldl1' intersectAssoc assocs
data CleanS
= CleanS
{ -- regs which are valid at the start of each block.
- sJumpValid :: UniqFM (Assoc Reg Slot)
+ sJumpValid :: UniqFM (Assoc Store)
-- collecting up what regs were valid across each jump.
-- in the next pass we can collate these and write the results
-- to sJumpValid.
- , sJumpValidAcc :: UniqFM [Assoc Reg Slot]
+ , sJumpValidAcc :: UniqFM [Assoc Store]
-- spills/reloads cleaned each pass (latest at front)
, sCleanedCount :: [(Int, Int)]
, sCleanedReloadsAcc = 0 }
--- | Remember that these regs were valid before a jump to this block
-accJumpValid :: Assoc Reg Slot -> BlockId -> CleanM ()
-accJumpValid regs target
+-- | Remember the associations before a jump
+accJumpValid :: Assoc Store -> BlockId -> CleanM ()
+accJumpValid assocs target
= modify $ \s -> s {
sJumpValidAcc = addToUFM_C (++)
(sJumpValidAcc s)
target
- [regs] }
+ [assocs] }
+
+--------------
+-- A store location can be a stack slot or a register
+--
+data Store
+ = SSlot Int
+ | SReg Reg
+
+-- spill cleaning is only done once all virtuals have been allocated to realRegs
+--
+instance Uniquable Store where
+ getUnique (SReg r)
+ | RealReg i <- r
+ = mkUnique 'R' i
+
+ | otherwise
+ = error "RegSpillClean.getUnique: found virtual reg during spill clean, only real regs expected."
+
+ getUnique (SSlot i) = mkUnique 'S' i
+
+instance Outputable Store where
+ ppr (SSlot i) = text "slot" <> int i
+ ppr (SReg r) = ppr r
--------------
--- An association table / many to many mapping.
--- TODO: implement this better than a simple association list.
--- two maps of sets, one for each direction would be better
+-- Association graphs.
+-- In the spill cleaner, two store locations are associated if they are known
+-- to hold the same value.
--
-data Assoc a b
- = Assoc
- { aList :: [(a, b)] }
+type Assoc a = UniqFM (UniqSet a)
-- | an empty association
-emptyAssoc :: Assoc a b
-emptyAssoc = Assoc { aList = [] }
+emptyAssoc :: Assoc a
+emptyAssoc = emptyUFM
+
+
+-- | add an association between these two things
+addAssoc :: Uniquable a
+ => a -> a -> Assoc a -> Assoc a
+addAssoc a b m
+ = let m1 = addToUFM_C unionUniqSets m a (unitUniqSet b)
+ m2 = addToUFM_C unionUniqSets m1 b (unitUniqSet a)
+ in m2
--- | add an association to the table.
-addAssoc
- :: (Eq a, Eq b)
- => a -> b -> Assoc a b -> Assoc a b
-addAssoc a b m = m { aList = (a, b) : aList m }
+-- | delete all associations to a node
+delAssoc :: (Outputable a, Uniquable a)
+ => a -> Assoc a -> Assoc a
+
+delAssoc a m
+ | Just aSet <- lookupUFM m a
+ , m1 <- delFromUFM m a
+ = foldUniqSet (\x m -> delAssoc1 x a m) m1 aSet
+
+ | otherwise = m
+
+
+-- | delete a single association edge (a -> b)
+delAssoc1 :: Uniquable a
+ => a -> a -> Assoc a -> Assoc a
+
+delAssoc1 a b m
+ | Just aSet <- lookupUFM m a
+ = addToUFM m a (delOneFromUniqSet aSet b)
+
+ | otherwise = m
-- | check if these two things are associated
-elemAssoc
- :: (Eq a, Eq b)
- => a -> b -> Assoc a b -> Bool
-elemAssoc a b m = elem (a, b) $ aList m
+elemAssoc :: (Outputable a, Uniquable a)
+ => a -> a -> Assoc a -> Bool
+
+elemAssoc a b m
+ = elementOfUniqSet b (closeAssoc a m)
+-- | find the refl. trans. closure of the association from this point
+closeAssoc :: (Outputable a, Uniquable a)
+ => a -> Assoc a -> UniqSet a
--- | delete all associations with this A element
-deleteAAssoc
- :: Eq a
- => a -> Assoc a b -> Assoc a b
+closeAssoc a assoc
+ = closeAssoc' assoc emptyUniqSet (unitUniqSet a)
+ where
+ closeAssoc' assoc visited toVisit
+ = case uniqSetToList toVisit of
-deleteAAssoc x m
- = m { aList = [ (a, b) | (a, b) <- aList m
- , a /= x ] }
+ -- nothing else to visit, we're done
+ [] -> visited
+ (x:_)
--- | delete all associations with this B element
-deleteBAssoc
- :: Eq b
- => b -> Assoc a b -> Assoc a b
+ -- we've already seen this node
+ | elementOfUniqSet x visited
+ -> closeAssoc' assoc visited (delOneFromUniqSet toVisit x)
-deleteBAssoc x m
- = m { aList = [ (a, b) | (a, b) <- aList m
- , b /= x ] }
+ -- haven't seen this node before,
+ -- remember to visit all its neighbors
+ | otherwise
+ -> let neighbors
+ = case lookupUFM assoc x of
+ Nothing -> emptyUniqSet
+ Just set -> set
+ in closeAssoc' assoc
+ (addOneToUniqSet visited x)
+ (unionUniqSets toVisit neighbors)
--- | intersect two associations
+-- | intersect
intersectAssoc
- :: (Eq a, Eq b)
- => Assoc a b -> Assoc a b -> Assoc a b
+ :: Uniquable a
+ => Assoc a -> Assoc a -> Assoc a
-intersectAssoc a1 a2
- = emptyAssoc
- { aList = intersect (aList a1) (aList a2) }
+intersectAssoc a b
+ = intersectUFM_C (intersectUniqSets) a b