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{-
(c) The AQUA Project, Glasgow University, 1993-1998
-}
{-# LANGUAGE CPP #-}
{-# LANGUAGE DeriveFunctor #-}
{-# OPTIONS_GHC -Wno-incomplete-record-updates #-}
module GHC.Core.Opt.Monad (
-- * Configuration of the core-to-core passes
CoreToDo(..), runWhen, runMaybe,
SimplMode(..),
FloatOutSwitches(..),
pprPassDetails,
-- * Plugins
CorePluginPass, bindsOnlyPass,
-- * Counting
SimplCount, doSimplTick, doFreeSimplTick, simplCountN,
pprSimplCount, plusSimplCount, zeroSimplCount,
isZeroSimplCount, hasDetailedCounts, Tick(..),
-- * The monad
CoreM, runCoreM,
-- ** Reading from the monad
getHscEnv, getRuleBase, getModule,
getDynFlags, getPackageFamInstEnv,
getVisibleOrphanMods, getUniqMask,
getPrintUnqualified, getSrcSpanM,
-- ** Writing to the monad
addSimplCount,
-- ** Lifting into the monad
liftIO, liftIOWithCount,
-- ** Dealing with annotations
getAnnotations, getFirstAnnotations,
-- ** Screen output
putMsg, putMsgS, errorMsg, errorMsgS, warnMsg,
fatalErrorMsg, fatalErrorMsgS,
debugTraceMsg, debugTraceMsgS,
dumpIfSet_dyn
) where
import GHC.Prelude hiding ( read )
import GHC.Core
import GHC.Driver.Types
import GHC.Unit.Module
import GHC.Driver.Session
import GHC.Types.Basic ( CompilerPhase(..) )
import GHC.Types.Annotations
import GHC.Data.IOEnv hiding ( liftIO, failM, failWithM )
import qualified GHC.Data.IOEnv as IOEnv
import GHC.Types.Var
import GHC.Utils.Outputable as Outputable
import GHC.Data.FastString
import GHC.Utils.Error( Severity(..), DumpFormat (..), dumpOptionsFromFlag )
import GHC.Types.Unique.Supply
import GHC.Utils.Monad
import GHC.Types.Name.Env
import GHC.Types.SrcLoc
import Data.Bifunctor ( bimap )
import GHC.Utils.Error (dumpAction)
import Data.List (intersperse, groupBy, sortBy)
import Data.Ord
import Data.Dynamic
import Data.Map (Map)
import qualified Data.Map as Map
import qualified Data.Map.Strict as MapStrict
import Data.Word
import Control.Monad
import Control.Applicative ( Alternative(..) )
import GHC.Utils.Panic (throwGhcException, GhcException(..))
{-
************************************************************************
* *
The CoreToDo type and related types
Abstraction of core-to-core passes to run.
* *
************************************************************************
-}
data CoreToDo -- These are diff core-to-core passes,
-- which may be invoked in any order,
-- as many times as you like.
= CoreDoSimplify -- The core-to-core simplifier.
Int -- Max iterations
SimplMode
| CoreDoPluginPass String CorePluginPass
| CoreDoFloatInwards
| CoreDoFloatOutwards FloatOutSwitches
| CoreLiberateCase
| CoreDoPrintCore
| CoreDoStaticArgs
| CoreDoCallArity
| CoreDoExitify
| CoreDoDemand
| CoreDoCpr
| CoreDoWorkerWrapper
| CoreDoSpecialising
| CoreDoSpecConstr
| CoreCSE
| CoreDoRuleCheck CompilerPhase String -- Check for non-application of rules
-- matching this string
| CoreDoNothing -- Useful when building up
| CoreDoPasses [CoreToDo] -- lists of these things
| CoreDesugar -- Right after desugaring, no simple optimisation yet!
| CoreDesugarOpt -- CoreDesugarXXX: Not strictly a core-to-core pass, but produces
-- Core output, and hence useful to pass to endPass
| CoreTidy
| CorePrep
| CoreOccurAnal
instance Outputable CoreToDo where
ppr (CoreDoSimplify _ _) = text "Simplifier"
ppr (CoreDoPluginPass s _) = text "Core plugin: " <+> text s
ppr CoreDoFloatInwards = text "Float inwards"
ppr (CoreDoFloatOutwards f) = text "Float out" <> parens (ppr f)
ppr CoreLiberateCase = text "Liberate case"
ppr CoreDoStaticArgs = text "Static argument"
ppr CoreDoCallArity = text "Called arity analysis"
ppr CoreDoExitify = text "Exitification transformation"
ppr CoreDoDemand = text "Demand analysis"
ppr CoreDoCpr = text "Constructed Product Result analysis"
ppr CoreDoWorkerWrapper = text "Worker Wrapper binds"
ppr CoreDoSpecialising = text "Specialise"
ppr CoreDoSpecConstr = text "SpecConstr"
ppr CoreCSE = text "Common sub-expression"
ppr CoreDesugar = text "Desugar (before optimization)"
ppr CoreDesugarOpt = text "Desugar (after optimization)"
ppr CoreTidy = text "Tidy Core"
ppr CorePrep = text "CorePrep"
ppr CoreOccurAnal = text "Occurrence analysis"
ppr CoreDoPrintCore = text "Print core"
ppr (CoreDoRuleCheck {}) = text "Rule check"
ppr CoreDoNothing = text "CoreDoNothing"
ppr (CoreDoPasses passes) = text "CoreDoPasses" <+> ppr passes
pprPassDetails :: CoreToDo -> SDoc
pprPassDetails (CoreDoSimplify n md) = vcat [ text "Max iterations =" <+> int n
, ppr md ]
pprPassDetails _ = Outputable.empty
data SimplMode -- See comments in GHC.Core.Opt.Simplify.Monad
= SimplMode
{ sm_names :: [String] -- Name(s) of the phase
, sm_phase :: CompilerPhase
, sm_dflags :: DynFlags -- Just for convenient non-monadic
-- access; we don't override these
, sm_rules :: Bool -- Whether RULES are enabled
, sm_inline :: Bool -- Whether inlining is enabled
, sm_case_case :: Bool -- Whether case-of-case is enabled
, sm_eta_expand :: Bool -- Whether eta-expansion is enabled
}
instance Outputable SimplMode where
ppr (SimplMode { sm_phase = p, sm_names = ss
, sm_rules = r, sm_inline = i
, sm_eta_expand = eta, sm_case_case = cc })
= text "SimplMode" <+> braces (
sep [ text "Phase =" <+> ppr p <+>
brackets (text (concat $ intersperse "," ss)) <> comma
, pp_flag i (sLit "inline") <> comma
, pp_flag r (sLit "rules") <> comma
, pp_flag eta (sLit "eta-expand") <> comma
, pp_flag cc (sLit "case-of-case") ])
where
pp_flag f s = ppUnless f (text "no") <+> ptext s
data FloatOutSwitches = FloatOutSwitches {
floatOutLambdas :: Maybe Int, -- ^ Just n <=> float lambdas to top level, if
-- doing so will abstract over n or fewer
-- value variables
-- Nothing <=> float all lambdas to top level,
-- regardless of how many free variables
-- Just 0 is the vanilla case: float a lambda
-- iff it has no free vars
floatOutConstants :: Bool, -- ^ True <=> float constants to top level,
-- even if they do not escape a lambda
floatOutOverSatApps :: Bool,
-- ^ True <=> float out over-saturated applications
-- based on arity information.
-- See Note [Floating over-saturated applications]
-- in GHC.Core.Opt.SetLevels
floatToTopLevelOnly :: Bool -- ^ Allow floating to the top level only.
}
instance Outputable FloatOutSwitches where
ppr = pprFloatOutSwitches
pprFloatOutSwitches :: FloatOutSwitches -> SDoc
pprFloatOutSwitches sw
= text "FOS" <+> (braces $
sep $ punctuate comma $
[ text "Lam =" <+> ppr (floatOutLambdas sw)
, text "Consts =" <+> ppr (floatOutConstants sw)
, text "OverSatApps =" <+> ppr (floatOutOverSatApps sw) ])
-- The core-to-core pass ordering is derived from the DynFlags:
runWhen :: Bool -> CoreToDo -> CoreToDo
runWhen True do_this = do_this
runWhen False _ = CoreDoNothing
runMaybe :: Maybe a -> (a -> CoreToDo) -> CoreToDo
runMaybe (Just x) f = f x
runMaybe Nothing _ = CoreDoNothing
{-
************************************************************************
* *
Types for Plugins
* *
************************************************************************
-}
-- | A description of the plugin pass itself
type CorePluginPass = ModGuts -> CoreM ModGuts
bindsOnlyPass :: (CoreProgram -> CoreM CoreProgram) -> ModGuts -> CoreM ModGuts
bindsOnlyPass pass guts
= do { binds' <- pass (mg_binds guts)
; return (guts { mg_binds = binds' }) }
{-
************************************************************************
* *
Counting and logging
* *
************************************************************************
-}
getVerboseSimplStats :: (Bool -> SDoc) -> SDoc
getVerboseSimplStats = getPprDebug -- For now, anyway
zeroSimplCount :: DynFlags -> SimplCount
isZeroSimplCount :: SimplCount -> Bool
hasDetailedCounts :: SimplCount -> Bool
pprSimplCount :: SimplCount -> SDoc
doSimplTick :: DynFlags -> Tick -> SimplCount -> SimplCount
doFreeSimplTick :: Tick -> SimplCount -> SimplCount
plusSimplCount :: SimplCount -> SimplCount -> SimplCount
data SimplCount
= VerySimplCount !Int -- Used when don't want detailed stats
| SimplCount {
ticks :: !Int, -- Total ticks
details :: !TickCounts, -- How many of each type
n_log :: !Int, -- N
log1 :: [Tick], -- Last N events; <= opt_HistorySize,
-- most recent first
log2 :: [Tick] -- Last opt_HistorySize events before that
-- Having log1, log2 lets us accumulate the
-- recent history reasonably efficiently
}
type TickCounts = Map Tick Int
simplCountN :: SimplCount -> Int
simplCountN (VerySimplCount n) = n
simplCountN (SimplCount { ticks = n }) = n
zeroSimplCount dflags
-- This is where we decide whether to do
-- the VerySimpl version or the full-stats version
| dopt Opt_D_dump_simpl_stats dflags
= SimplCount {ticks = 0, details = Map.empty,
n_log = 0, log1 = [], log2 = []}
| otherwise
= VerySimplCount 0
isZeroSimplCount (VerySimplCount n) = n==0
isZeroSimplCount (SimplCount { ticks = n }) = n==0
hasDetailedCounts (VerySimplCount {}) = False
hasDetailedCounts (SimplCount {}) = True
doFreeSimplTick tick sc@SimplCount { details = dts }
= sc { details = dts `addTick` tick }
doFreeSimplTick _ sc = sc
doSimplTick dflags tick
sc@(SimplCount { ticks = tks, details = dts, n_log = nl, log1 = l1 })
| nl >= historySize dflags = sc1 { n_log = 1, log1 = [tick], log2 = l1 }
| otherwise = sc1 { n_log = nl+1, log1 = tick : l1 }
where
sc1 = sc { ticks = tks+1, details = dts `addTick` tick }
doSimplTick _ _ (VerySimplCount n) = VerySimplCount (n+1)
addTick :: TickCounts -> Tick -> TickCounts
addTick fm tick = MapStrict.insertWith (+) tick 1 fm
plusSimplCount sc1@(SimplCount { ticks = tks1, details = dts1 })
sc2@(SimplCount { ticks = tks2, details = dts2 })
= log_base { ticks = tks1 + tks2
, details = MapStrict.unionWith (+) dts1 dts2 }
where
-- A hackish way of getting recent log info
log_base | null (log1 sc2) = sc1 -- Nothing at all in sc2
| null (log2 sc2) = sc2 { log2 = log1 sc1 }
| otherwise = sc2
plusSimplCount (VerySimplCount n) (VerySimplCount m) = VerySimplCount (n+m)
plusSimplCount lhs rhs =
throwGhcException . PprProgramError "plusSimplCount" $ vcat
[ text "lhs"
, pprSimplCount lhs
, text "rhs"
, pprSimplCount rhs
]
-- We use one or the other consistently
pprSimplCount (VerySimplCount n) = text "Total ticks:" <+> int n
pprSimplCount (SimplCount { ticks = tks, details = dts, log1 = l1, log2 = l2 })
= vcat [text "Total ticks: " <+> int tks,
blankLine,
pprTickCounts dts,
getVerboseSimplStats $ \dbg -> if dbg
then
vcat [blankLine,
text "Log (most recent first)",
nest 4 (vcat (map ppr l1) $$ vcat (map ppr l2))]
else Outputable.empty
]
{- Note [Which transformations are innocuous]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
At one point (Jun 18) I wondered if some transformations (ticks)
might be "innocuous", in the sense that they do not unlock a later
transformation that does not occur in the same pass. If so, we could
refrain from bumping the overall tick-count for such innocuous
transformations, and perhaps terminate the simplifier one pass
earlier.
But alas I found that virtually nothing was innocuous! This Note
just records what I learned, in case anyone wants to try again.
These transformations are not innocuous:
*** NB: I think these ones could be made innocuous
EtaExpansion
LetFloatFromLet
LetFloatFromLet
x = K (let z = e2 in Just z)
prepareRhs transforms to
x2 = let z=e2 in Just z
x = K xs
And now more let-floating can happen in the
next pass, on x2
PreInlineUnconditionally
Example in spectral/cichelli/Auxil
hinsert = ...let lo = e in
let j = ...lo... in
case x of
False -> ()
True -> case lo of I# lo' ->
...j...
When we PreInlineUnconditionally j, lo's occ-info changes to once,
so it can be PreInlineUnconditionally in the next pass, and a
cascade of further things can happen.
PostInlineUnconditionally
let x = e in
let y = ...x.. in
case .. of { A -> ...x...y...
B -> ...x...y... }
Current postinlineUnconditinaly will inline y, and then x; sigh.
But PostInlineUnconditionally might also unlock subsequent
transformations for the same reason as PreInlineUnconditionally,
so it's probably not innocuous anyway.
KnownBranch, BetaReduction:
May drop chunks of code, and thereby enable PreInlineUnconditionally
for some let-binding which now occurs once
EtaExpansion:
Example in imaginary/digits-of-e1
fail = \void. e where e :: IO ()
--> etaExpandRhs
fail = \void. (\s. (e |> g) s) |> sym g where g :: IO () ~ S -> (S,())
--> Next iteration of simplify
fail1 = \void. \s. (e |> g) s
fail = fail1 |> Void# -> sym g
And now inline 'fail'
CaseMerge:
case x of y {
DEFAULT -> case y of z { pi -> ei }
alts2 }
---> CaseMerge
case x of { pi -> let z = y in ei
; alts2 }
The "let z=y" case-binder-swap gets dealt with in the next pass
-}
pprTickCounts :: Map Tick Int -> SDoc
pprTickCounts counts
= vcat (map pprTickGroup groups)
where
groups :: [[(Tick,Int)]] -- Each group shares a common tag
-- toList returns common tags adjacent
groups = groupBy same_tag (Map.toList counts)
same_tag (tick1,_) (tick2,_) = tickToTag tick1 == tickToTag tick2
pprTickGroup :: [(Tick, Int)] -> SDoc
pprTickGroup group@((tick1,_):_)
= hang (int (sum [n | (_,n) <- group]) <+> text (tickString tick1))
2 (vcat [ int n <+> pprTickCts tick
-- flip as we want largest first
| (tick,n) <- sortBy (flip (comparing snd)) group])
pprTickGroup [] = panic "pprTickGroup"
data Tick -- See Note [Which transformations are innocuous]
= PreInlineUnconditionally Id
| PostInlineUnconditionally Id
| UnfoldingDone Id
| RuleFired FastString -- Rule name
| LetFloatFromLet
| EtaExpansion Id -- LHS binder
| EtaReduction Id -- Binder on outer lambda
| BetaReduction Id -- Lambda binder
| CaseOfCase Id -- Bndr on *inner* case
| KnownBranch Id -- Case binder
| CaseMerge Id -- Binder on outer case
| AltMerge Id -- Case binder
| CaseElim Id -- Case binder
| CaseIdentity Id -- Case binder
| FillInCaseDefault Id -- Case binder
| SimplifierDone -- Ticked at each iteration of the simplifier
instance Outputable Tick where
ppr tick = text (tickString tick) <+> pprTickCts tick
instance Eq Tick where
a == b = case a `cmpTick` b of
EQ -> True
_ -> False
instance Ord Tick where
compare = cmpTick
tickToTag :: Tick -> Int
tickToTag (PreInlineUnconditionally _) = 0
tickToTag (PostInlineUnconditionally _) = 1
tickToTag (UnfoldingDone _) = 2
tickToTag (RuleFired _) = 3
tickToTag LetFloatFromLet = 4
tickToTag (EtaExpansion _) = 5
tickToTag (EtaReduction _) = 6
tickToTag (BetaReduction _) = 7
tickToTag (CaseOfCase _) = 8
tickToTag (KnownBranch _) = 9
tickToTag (CaseMerge _) = 10
tickToTag (CaseElim _) = 11
tickToTag (CaseIdentity _) = 12
tickToTag (FillInCaseDefault _) = 13
tickToTag SimplifierDone = 16
tickToTag (AltMerge _) = 17
tickString :: Tick -> String
tickString (PreInlineUnconditionally _) = "PreInlineUnconditionally"
tickString (PostInlineUnconditionally _)= "PostInlineUnconditionally"
tickString (UnfoldingDone _) = "UnfoldingDone"
tickString (RuleFired _) = "RuleFired"
tickString LetFloatFromLet = "LetFloatFromLet"
tickString (EtaExpansion _) = "EtaExpansion"
tickString (EtaReduction _) = "EtaReduction"
tickString (BetaReduction _) = "BetaReduction"
tickString (CaseOfCase _) = "CaseOfCase"
tickString (KnownBranch _) = "KnownBranch"
tickString (CaseMerge _) = "CaseMerge"
tickString (AltMerge _) = "AltMerge"
tickString (CaseElim _) = "CaseElim"
tickString (CaseIdentity _) = "CaseIdentity"
tickString (FillInCaseDefault _) = "FillInCaseDefault"
tickString SimplifierDone = "SimplifierDone"
pprTickCts :: Tick -> SDoc
pprTickCts (PreInlineUnconditionally v) = ppr v
pprTickCts (PostInlineUnconditionally v)= ppr v
pprTickCts (UnfoldingDone v) = ppr v
pprTickCts (RuleFired v) = ppr v
pprTickCts LetFloatFromLet = Outputable.empty
pprTickCts (EtaExpansion v) = ppr v
pprTickCts (EtaReduction v) = ppr v
pprTickCts (BetaReduction v) = ppr v
pprTickCts (CaseOfCase v) = ppr v
pprTickCts (KnownBranch v) = ppr v
pprTickCts (CaseMerge v) = ppr v
pprTickCts (AltMerge v) = ppr v
pprTickCts (CaseElim v) = ppr v
pprTickCts (CaseIdentity v) = ppr v
pprTickCts (FillInCaseDefault v) = ppr v
pprTickCts _ = Outputable.empty
cmpTick :: Tick -> Tick -> Ordering
cmpTick a b = case (tickToTag a `compare` tickToTag b) of
GT -> GT
EQ -> cmpEqTick a b
LT -> LT
cmpEqTick :: Tick -> Tick -> Ordering
cmpEqTick (PreInlineUnconditionally a) (PreInlineUnconditionally b) = a `compare` b
cmpEqTick (PostInlineUnconditionally a) (PostInlineUnconditionally b) = a `compare` b
cmpEqTick (UnfoldingDone a) (UnfoldingDone b) = a `compare` b
cmpEqTick (RuleFired a) (RuleFired b) = a `compare` b
cmpEqTick (EtaExpansion a) (EtaExpansion b) = a `compare` b
cmpEqTick (EtaReduction a) (EtaReduction b) = a `compare` b
cmpEqTick (BetaReduction a) (BetaReduction b) = a `compare` b
cmpEqTick (CaseOfCase a) (CaseOfCase b) = a `compare` b
cmpEqTick (KnownBranch a) (KnownBranch b) = a `compare` b
cmpEqTick (CaseMerge a) (CaseMerge b) = a `compare` b
cmpEqTick (AltMerge a) (AltMerge b) = a `compare` b
cmpEqTick (CaseElim a) (CaseElim b) = a `compare` b
cmpEqTick (CaseIdentity a) (CaseIdentity b) = a `compare` b
cmpEqTick (FillInCaseDefault a) (FillInCaseDefault b) = a `compare` b
cmpEqTick _ _ = EQ
{-
************************************************************************
* *
Monad and carried data structure definitions
* *
************************************************************************
-}
data CoreReader = CoreReader {
cr_hsc_env :: HscEnv,
cr_rule_base :: RuleBase,
cr_module :: Module,
cr_print_unqual :: PrintUnqualified,
cr_loc :: SrcSpan, -- Use this for log/error messages so they
-- are at least tagged with the right source file
cr_visible_orphan_mods :: !ModuleSet,
cr_uniq_mask :: !Char -- Mask for creating unique values
}
-- Note: CoreWriter used to be defined with data, rather than newtype. If it
-- is defined that way again, the cw_simpl_count field, at least, must be
-- strict to avoid a space leak (#7702).
newtype CoreWriter = CoreWriter {
cw_simpl_count :: SimplCount
}
emptyWriter :: DynFlags -> CoreWriter
emptyWriter dflags = CoreWriter {
cw_simpl_count = zeroSimplCount dflags
}
plusWriter :: CoreWriter -> CoreWriter -> CoreWriter
plusWriter w1 w2 = CoreWriter {
cw_simpl_count = (cw_simpl_count w1) `plusSimplCount` (cw_simpl_count w2)
}
type CoreIOEnv = IOEnv CoreReader
-- | The monad used by Core-to-Core passes to register simplification statistics.
-- Also used to have common state (in the form of UniqueSupply) for generating Uniques.
newtype CoreM a = CoreM { unCoreM :: CoreIOEnv (a, CoreWriter) }
deriving (Functor)
instance Monad CoreM where
mx >>= f = CoreM $ do
(x, w1) <- unCoreM mx
(y, w2) <- unCoreM (f x)
let w = w1 `plusWriter` w2
return $ seq w (y, w)
-- forcing w before building the tuple avoids a space leak
-- (#7702)
instance Applicative CoreM where
pure x = CoreM $ nop x
(<*>) = ap
m *> k = m >>= \_ -> k
instance Alternative CoreM where
empty = CoreM Control.Applicative.empty
m <|> n = CoreM (unCoreM m <|> unCoreM n)
instance MonadPlus CoreM
instance MonadUnique CoreM where
getUniqueSupplyM = do
mask <- read cr_uniq_mask
liftIO $! mkSplitUniqSupply mask
getUniqueM = do
mask <- read cr_uniq_mask
liftIO $! uniqFromMask mask
runCoreM :: HscEnv
-> RuleBase
-> Char -- ^ Mask
-> Module
-> ModuleSet
-> PrintUnqualified
-> SrcSpan
-> CoreM a
-> IO (a, SimplCount)
runCoreM hsc_env rule_base mask mod orph_imps print_unqual loc m
= liftM extract $ runIOEnv reader $ unCoreM m
where
reader = CoreReader {
cr_hsc_env = hsc_env,
cr_rule_base = rule_base,
cr_module = mod,
cr_visible_orphan_mods = orph_imps,
cr_print_unqual = print_unqual,
cr_loc = loc,
cr_uniq_mask = mask
}
extract :: (a, CoreWriter) -> (a, SimplCount)
extract (value, writer) = (value, cw_simpl_count writer)
{-
************************************************************************
* *
Core combinators, not exported
* *
************************************************************************
-}
nop :: a -> CoreIOEnv (a, CoreWriter)
nop x = do
r <- getEnv
return (x, emptyWriter $ (hsc_dflags . cr_hsc_env) r)
read :: (CoreReader -> a) -> CoreM a
read f = CoreM $ getEnv >>= (\r -> nop (f r))
write :: CoreWriter -> CoreM ()
write w = CoreM $ return ((), w)
-- \subsection{Lifting IO into the monad}
-- | Lift an 'IOEnv' operation into 'CoreM'
liftIOEnv :: CoreIOEnv a -> CoreM a
liftIOEnv mx = CoreM (mx >>= (\x -> nop x))
instance MonadIO CoreM where
liftIO = liftIOEnv . IOEnv.liftIO
-- | Lift an 'IO' operation into 'CoreM' while consuming its 'SimplCount'
liftIOWithCount :: IO (SimplCount, a) -> CoreM a
liftIOWithCount what = liftIO what >>= (\(count, x) -> addSimplCount count >> return x)
{-
************************************************************************
* *
Reader, writer and state accessors
* *
************************************************************************
-}
getHscEnv :: CoreM HscEnv
getHscEnv = read cr_hsc_env
getRuleBase :: CoreM RuleBase
getRuleBase = read cr_rule_base
getVisibleOrphanMods :: CoreM ModuleSet
getVisibleOrphanMods = read cr_visible_orphan_mods
getPrintUnqualified :: CoreM PrintUnqualified
getPrintUnqualified = read cr_print_unqual
getSrcSpanM :: CoreM SrcSpan
getSrcSpanM = read cr_loc
addSimplCount :: SimplCount -> CoreM ()
addSimplCount count = write (CoreWriter { cw_simpl_count = count })
getUniqMask :: CoreM Char
getUniqMask = read cr_uniq_mask
-- Convenience accessors for useful fields of HscEnv
instance HasDynFlags CoreM where
getDynFlags = fmap hsc_dflags getHscEnv
instance HasModule CoreM where
getModule = read cr_module
getPackageFamInstEnv :: CoreM PackageFamInstEnv
getPackageFamInstEnv = do
hsc_env <- getHscEnv
eps <- liftIO $ hscEPS hsc_env
return $ eps_fam_inst_env eps
{-
************************************************************************
* *
Dealing with annotations
* *
************************************************************************
-}
-- | Get all annotations of a given type. This happens lazily, that is
-- no deserialization will take place until the [a] is actually demanded and
-- the [a] can also be empty (the UniqFM is not filtered).
--
-- This should be done once at the start of a Core-to-Core pass that uses
-- annotations.
--
-- See Note [Annotations]
getAnnotations :: Typeable a => ([Word8] -> a) -> ModGuts -> CoreM (ModuleEnv [a], NameEnv [a])
getAnnotations deserialize guts = do
hsc_env <- getHscEnv
ann_env <- liftIO $ prepareAnnotations hsc_env (Just guts)
return (deserializeAnns deserialize ann_env)
-- | Get at most one annotation of a given type per annotatable item.
getFirstAnnotations :: Typeable a => ([Word8] -> a) -> ModGuts -> CoreM (ModuleEnv a, NameEnv a)
getFirstAnnotations deserialize guts
= bimap mod name <$> getAnnotations deserialize guts
where
mod = mapModuleEnv head . filterModuleEnv (const $ not . null)
name = mapNameEnv head . filterNameEnv (not . null)
{-
Note [Annotations]
~~~~~~~~~~~~~~~~~~
A Core-to-Core pass that wants to make use of annotations calls
getAnnotations or getFirstAnnotations at the beginning to obtain a UniqFM with
annotations of a specific type. This produces all annotations from interface
files read so far. However, annotations from interface files read during the
pass will not be visible until getAnnotations is called again. This is similar
to how rules work and probably isn't too bad.
The current implementation could be optimised a bit: when looking up
annotations for a thing from the HomePackageTable, we could search directly in
the module where the thing is defined rather than building one UniqFM which
contains all annotations we know of. This would work because annotations can
only be given to things defined in the same module. However, since we would
only want to deserialise every annotation once, we would have to build a cache
for every module in the HTP. In the end, it's probably not worth it as long as
we aren't using annotations heavily.
************************************************************************
* *
Direct screen output
* *
************************************************************************
-}
msg :: Severity -> WarnReason -> SDoc -> CoreM ()
msg sev reason doc
= do { dflags <- getDynFlags
; loc <- getSrcSpanM
; unqual <- getPrintUnqualified
; let sty = case sev of
SevError -> err_sty
SevWarning -> err_sty
SevDump -> dump_sty
_ -> user_sty
err_sty = mkErrStyle unqual
user_sty = mkUserStyle unqual AllTheWay
dump_sty = mkDumpStyle unqual
; liftIO $ putLogMsg dflags reason sev loc (withPprStyle sty doc) }
-- | Output a String message to the screen
putMsgS :: String -> CoreM ()
putMsgS = putMsg . text
-- | Output a message to the screen
putMsg :: SDoc -> CoreM ()
putMsg = msg SevInfo NoReason
-- | Output an error to the screen. Does not cause the compiler to die.
errorMsgS :: String -> CoreM ()
errorMsgS = errorMsg . text
-- | Output an error to the screen. Does not cause the compiler to die.
errorMsg :: SDoc -> CoreM ()
errorMsg = msg SevError NoReason
warnMsg :: WarnReason -> SDoc -> CoreM ()
warnMsg = msg SevWarning
-- | Output a fatal error to the screen. Does not cause the compiler to die.
fatalErrorMsgS :: String -> CoreM ()
fatalErrorMsgS = fatalErrorMsg . text
-- | Output a fatal error to the screen. Does not cause the compiler to die.
fatalErrorMsg :: SDoc -> CoreM ()
fatalErrorMsg = msg SevFatal NoReason
-- | Output a string debugging message at verbosity level of @-v@ or higher
debugTraceMsgS :: String -> CoreM ()
debugTraceMsgS = debugTraceMsg . text
-- | Outputs a debugging message at verbosity level of @-v@ or higher
debugTraceMsg :: SDoc -> CoreM ()
debugTraceMsg = msg SevDump NoReason
-- | Show some labelled 'SDoc' if a particular flag is set or at a verbosity level of @-v -ddump-most@ or higher
dumpIfSet_dyn :: DumpFlag -> String -> DumpFormat -> SDoc -> CoreM ()
dumpIfSet_dyn flag str fmt doc
= do { dflags <- getDynFlags
; unqual <- getPrintUnqualified
; when (dopt flag dflags) $ liftIO $ do
let sty = mkDumpStyle unqual
dumpAction dflags sty (dumpOptionsFromFlag flag) str fmt doc }
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