ghc-8.8.1: stgSyn/CoreToStg.hs
{-# LANGUAGE CPP #-}
--
-- (c) The GRASP/AQUA Project, Glasgow University, 1993-1998
--
--------------------------------------------------------------
-- Converting Core to STG Syntax
--------------------------------------------------------------
-- And, as we have the info in hand, we may convert some lets to
-- let-no-escapes.
module CoreToStg ( coreToStg ) where
#include "HsVersions.h"
import GhcPrelude
import CoreSyn
import CoreUtils ( exprType, findDefault, isJoinBind
, exprIsTickedString_maybe )
import CoreArity ( manifestArity )
import StgSyn
import Type
import RepType
import TyCon
import MkId ( coercionTokenId )
import Id
import IdInfo
import DataCon
import CostCentre
import VarEnv
import Module
import Name ( isExternalName, nameOccName, nameModule_maybe )
import OccName ( occNameFS )
import BasicTypes ( Arity )
import TysWiredIn ( unboxedUnitDataCon, unitDataConId )
import Literal
import Outputable
import MonadUtils
import FastString
import Util
import DynFlags
import ForeignCall
import Demand ( isUsedOnce )
import PrimOp ( PrimCall(..), primOpWrapperId )
import SrcLoc ( mkGeneralSrcSpan )
import Data.List.NonEmpty (nonEmpty, toList)
import Data.Maybe (fromMaybe)
import Control.Monad (liftM, ap)
-- Note [Live vs free]
-- ~~~~~~~~~~~~~~~~~~~
--
-- The two are not the same. Liveness is an operational property rather
-- than a semantic one. A variable is live at a particular execution
-- point if it can be referred to directly again. In particular, a dead
-- variable's stack slot (if it has one):
--
-- - should be stubbed to avoid space leaks, and
-- - may be reused for something else.
--
-- There ought to be a better way to say this. Here are some examples:
--
-- let v = [q] \[x] -> e
-- in
-- ...v... (but no q's)
--
-- Just after the `in', v is live, but q is dead. If the whole of that
-- let expression was enclosed in a case expression, thus:
--
-- case (let v = [q] \[x] -> e in ...v...) of
-- alts[...q...]
--
-- (ie `alts' mention `q'), then `q' is live even after the `in'; because
-- we'll return later to the `alts' and need it.
--
-- Let-no-escapes make this a bit more interesting:
--
-- let-no-escape v = [q] \ [x] -> e
-- in
-- ...v...
--
-- Here, `q' is still live at the `in', because `v' is represented not by
-- a closure but by the current stack state. In other words, if `v' is
-- live then so is `q'. Furthermore, if `e' mentions an enclosing
-- let-no-escaped variable, then its free variables are also live if `v' is.
-- Note [What are these SRTs all about?]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
--
-- Consider the Core program,
--
-- fibs = go 1 1
-- where go a b = let c = a + c
-- in c : go b c
-- add x = map (\y -> x*y) fibs
--
-- In this case we have a CAF, 'fibs', which is quite large after evaluation and
-- has only one possible user, 'add'. Consequently, we want to ensure that when
-- all references to 'add' die we can garbage collect any bit of 'fibs' that we
-- have evaluated.
--
-- However, how do we know whether there are any references to 'fibs' still
-- around? Afterall, the only reference to it is buried in the code generated
-- for 'add'. The answer is that we record the CAFs referred to by a definition
-- in its info table, namely a part of it known as the Static Reference Table
-- (SRT).
--
-- Since SRTs are so common, we use a special compact encoding for them in: we
-- produce one table containing a list of CAFs in a module and then include a
-- bitmap in each info table describing which entries of this table the closure
-- references.
--
-- See also: Commentary/Rts/Storage/GC/CAFs on the GHC Wiki.
-- Note [What is a non-escaping let]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
--
-- NB: Nowadays this is recognized by the occurrence analyser by turning a
-- "non-escaping let" into a join point. The following is then an operational
-- account of join points.
--
-- Consider:
--
-- let x = fvs \ args -> e
-- in
-- if ... then x else
-- if ... then x else ...
--
-- `x' is used twice (so we probably can't unfold it), but when it is
-- entered, the stack is deeper than it was when the definition of `x'
-- happened. Specifically, if instead of allocating a closure for `x',
-- we saved all `x's fvs on the stack, and remembered the stack depth at
-- that moment, then whenever we enter `x' we can simply set the stack
-- pointer(s) to these remembered (compile-time-fixed) values, and jump
-- to the code for `x'.
--
-- All of this is provided x is:
-- 1. non-updatable;
-- 2. guaranteed to be entered before the stack retreats -- ie x is not
-- buried in a heap-allocated closure, or passed as an argument to
-- something;
-- 3. all the enters have exactly the right number of arguments,
-- no more no less;
-- 4. all the enters are tail calls; that is, they return to the
-- caller enclosing the definition of `x'.
--
-- Under these circumstances we say that `x' is non-escaping.
--
-- An example of when (4) does not hold:
--
-- let x = ...
-- in case x of ...alts...
--
-- Here, `x' is certainly entered only when the stack is deeper than when
-- `x' is defined, but here it must return to ...alts... So we can't just
-- adjust the stack down to `x''s recalled points, because that would lost
-- alts' context.
--
-- Things can get a little more complicated. Consider:
--
-- let y = ...
-- in let x = fvs \ args -> ...y...
-- in ...x...
--
-- Now, if `x' is used in a non-escaping way in ...x..., and `y' is used in a
-- non-escaping way in ...y..., then `y' is non-escaping.
--
-- `x' can even be recursive! Eg:
--
-- letrec x = [y] \ [v] -> if v then x True else ...
-- in
-- ...(x b)...
-- Note [Cost-centre initialization plan]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
--
-- Previously `coreToStg` was initializing cost-centre stack fields as `noCCS`,
-- and the fields were then fixed by a separate pass `stgMassageForProfiling`.
-- We now initialize these correctly. The initialization works like this:
--
-- - For non-top level bindings always use `currentCCS`.
--
-- - For top-level bindings, check if the binding is a CAF
--
-- - CAF: If -fcaf-all is enabled, create a new CAF just for this CAF
-- and use it. Note that these new cost centres need to be
-- collected to be able to generate cost centre initialization
-- code, so `coreToTopStgRhs` now returns `CollectedCCs`.
--
-- If -fcaf-all is not enabled, use "all CAFs" cost centre.
--
-- - Non-CAF: Top-level (static) data is not counted in heap profiles; nor
-- do we set CCCS from it; so we just slam in
-- dontCareCostCentre.
-- --------------------------------------------------------------
-- Setting variable info: top-level, binds, RHSs
-- --------------------------------------------------------------
coreToStg :: DynFlags -> Module -> CoreProgram
-> ([StgTopBinding], CollectedCCs)
coreToStg dflags this_mod pgm
= (pgm', final_ccs)
where
(_, (local_ccs, local_cc_stacks), pgm')
= coreTopBindsToStg dflags this_mod emptyVarEnv emptyCollectedCCs pgm
prof = WayProf `elem` ways dflags
final_ccs
| prof && gopt Opt_AutoSccsOnIndividualCafs dflags
= (local_ccs,local_cc_stacks) -- don't need "all CAFs" CC
| prof
= (all_cafs_cc:local_ccs, all_cafs_ccs:local_cc_stacks)
| otherwise
= emptyCollectedCCs
(all_cafs_cc, all_cafs_ccs) = getAllCAFsCC this_mod
coreTopBindsToStg
:: DynFlags
-> Module
-> IdEnv HowBound -- environment for the bindings
-> CollectedCCs
-> CoreProgram
-> (IdEnv HowBound, CollectedCCs, [StgTopBinding])
coreTopBindsToStg _ _ env ccs []
= (env, ccs, [])
coreTopBindsToStg dflags this_mod env ccs (b:bs)
= (env2, ccs2, b':bs')
where
(env1, ccs1, b' ) =
coreTopBindToStg dflags this_mod env ccs b
(env2, ccs2, bs') =
coreTopBindsToStg dflags this_mod env1 ccs1 bs
coreTopBindToStg
:: DynFlags
-> Module
-> IdEnv HowBound
-> CollectedCCs
-> CoreBind
-> (IdEnv HowBound, CollectedCCs, StgTopBinding)
coreTopBindToStg _ _ env ccs (NonRec id e)
| Just str <- exprIsTickedString_maybe e
-- top-level string literal
-- See Note [CoreSyn top-level string literals] in CoreSyn
= let
env' = extendVarEnv env id how_bound
how_bound = LetBound TopLet 0
in (env', ccs, StgTopStringLit id str)
coreTopBindToStg dflags this_mod env ccs (NonRec id rhs)
= let
env' = extendVarEnv env id how_bound
how_bound = LetBound TopLet $! manifestArity rhs
(stg_rhs, ccs') =
initCts env $
coreToTopStgRhs dflags ccs this_mod (id,rhs)
bind = StgTopLifted $ StgNonRec id stg_rhs
in
assertConsistentCaInfo dflags id bind (ppr bind)
-- NB: previously the assertion printed 'rhs' and 'bind'
-- as well as 'id', but that led to a black hole
-- where printing the assertion error tripped the
-- assertion again!
(env', ccs', bind)
coreTopBindToStg dflags this_mod env ccs (Rec pairs)
= ASSERT( not (null pairs) )
let
binders = map fst pairs
extra_env' = [ (b, LetBound TopLet $! manifestArity rhs)
| (b, rhs) <- pairs ]
env' = extendVarEnvList env extra_env'
-- generate StgTopBindings and CAF cost centres created for CAFs
(ccs', stg_rhss)
= initCts env' $ do
mapAccumLM (\ccs rhs -> do
(rhs', ccs') <-
coreToTopStgRhs dflags ccs this_mod rhs
return (ccs', rhs'))
ccs
pairs
bind = StgTopLifted $ StgRec (zip binders stg_rhss)
in
assertConsistentCaInfo dflags (head binders) bind (ppr binders)
(env', ccs', bind)
-- | CAF consistency issues will generally result in segfaults and are quite
-- difficult to debug (see #16846). We enable checking of the
-- 'consistentCafInfo' invariant with @-dstg-lint@ to increase the chance that
-- we catch these issues.
assertConsistentCaInfo :: DynFlags -> Id -> StgTopBinding -> SDoc -> a -> a
assertConsistentCaInfo dflags id bind err_doc result
| gopt Opt_DoStgLinting dflags || debugIsOn
, not $ consistentCafInfo id bind = pprPanic "assertConsistentCaInfo" err_doc
| otherwise = result
-- Assertion helper: this checks that the CafInfo on the Id matches
-- what CoreToStg has figured out about the binding's SRT. The
-- CafInfo will be exact in all cases except when CorePrep has
-- floated out a binding, in which case it will be approximate.
consistentCafInfo :: Id -> StgTopBinding -> Bool
consistentCafInfo id bind
= WARN( not (exact || is_sat_thing) , ppr id <+> ppr id_marked_caffy <+> ppr binding_is_caffy )
safe
where
safe = id_marked_caffy || not binding_is_caffy
exact = id_marked_caffy == binding_is_caffy
id_marked_caffy = mayHaveCafRefs (idCafInfo id)
binding_is_caffy = topStgBindHasCafRefs bind
is_sat_thing = occNameFS (nameOccName (idName id)) == fsLit "sat"
coreToTopStgRhs
:: DynFlags
-> CollectedCCs
-> Module
-> (Id,CoreExpr)
-> CtsM (StgRhs, CollectedCCs)
coreToTopStgRhs dflags ccs this_mod (bndr, rhs)
= do { new_rhs <- coreToStgExpr rhs
; let (stg_rhs, ccs') =
mkTopStgRhs dflags this_mod ccs bndr new_rhs
stg_arity =
stgRhsArity stg_rhs
; return (ASSERT2( arity_ok stg_arity, mk_arity_msg stg_arity) stg_rhs,
ccs') }
where
-- It's vital that the arity on a top-level Id matches
-- the arity of the generated STG binding, else an importing
-- module will use the wrong calling convention
-- (Trac #2844 was an example where this happened)
-- NB1: we can't move the assertion further out without
-- blocking the "knot" tied in coreTopBindsToStg
-- NB2: the arity check is only needed for Ids with External
-- Names, because they are externally visible. The CorePrep
-- pass introduces "sat" things with Local Names and does
-- not bother to set their Arity info, so don't fail for those
arity_ok stg_arity
| isExternalName (idName bndr) = id_arity == stg_arity
| otherwise = True
id_arity = idArity bndr
mk_arity_msg stg_arity
= vcat [ppr bndr,
text "Id arity:" <+> ppr id_arity,
text "STG arity:" <+> ppr stg_arity]
-- ---------------------------------------------------------------------------
-- Expressions
-- ---------------------------------------------------------------------------
coreToStgExpr
:: CoreExpr
-> CtsM StgExpr
-- The second and third components can be derived in a simple bottom up pass, not
-- dependent on any decisions about which variables will be let-no-escaped or
-- not. The first component, that is, the decorated expression, may then depend
-- on these components, but it in turn is not scrutinised as the basis for any
-- decisions. Hence no black holes.
-- No LitInteger's or LitNatural's should be left by the time this is called.
-- CorePrep should have converted them all to a real core representation.
coreToStgExpr (Lit (LitNumber LitNumInteger _ _)) = panic "coreToStgExpr: LitInteger"
coreToStgExpr (Lit (LitNumber LitNumNatural _ _)) = panic "coreToStgExpr: LitNatural"
coreToStgExpr (Lit l) = return (StgLit l)
coreToStgExpr (App (Lit LitRubbish) _some_unlifted_type)
-- We lower 'LitRubbish' to @()@ here, which is much easier than doing it in
-- a STG to Cmm pass.
= coreToStgExpr (Var unitDataConId)
coreToStgExpr (Var v) = coreToStgApp Nothing v [] []
coreToStgExpr (Coercion _) = coreToStgApp Nothing coercionTokenId [] []
coreToStgExpr expr@(App _ _)
= coreToStgApp Nothing f args ticks
where
(f, args, ticks) = myCollectArgs expr
coreToStgExpr expr@(Lam _ _)
= let
(args, body) = myCollectBinders expr
args' = filterStgBinders args
in
extendVarEnvCts [ (a, LambdaBound) | a <- args' ] $ do
body' <- coreToStgExpr body
let
result_expr = case nonEmpty args' of
Nothing -> body'
Just args'' -> StgLam args'' body'
return result_expr
coreToStgExpr (Tick tick expr)
= do case tick of
HpcTick{} -> return ()
ProfNote{} -> return ()
SourceNote{} -> return ()
Breakpoint{} -> panic "coreToStgExpr: breakpoint should not happen"
expr2 <- coreToStgExpr expr
return (StgTick tick expr2)
coreToStgExpr (Cast expr _)
= coreToStgExpr expr
-- Cases require a little more real work.
coreToStgExpr (Case scrut _ _ [])
= coreToStgExpr scrut
-- See Note [Empty case alternatives] in CoreSyn If the case
-- alternatives are empty, the scrutinee must diverge or raise an
-- exception, so we can just dive into it.
--
-- Of course this may seg-fault if the scrutinee *does* return. A
-- belt-and-braces approach would be to move this case into the
-- code generator, and put a return point anyway that calls a
-- runtime system error function.
coreToStgExpr (Case scrut bndr _ alts) = do
alts2 <- extendVarEnvCts [(bndr, LambdaBound)] (mapM vars_alt alts)
scrut2 <- coreToStgExpr scrut
return (StgCase scrut2 bndr (mkStgAltType bndr alts) alts2)
where
vars_alt (con, binders, rhs)
| DataAlt c <- con, c == unboxedUnitDataCon
= -- This case is a bit smelly.
-- See Note [Nullary unboxed tuple] in Type.hs
-- where a nullary tuple is mapped to (State# World#)
ASSERT( null binders )
do { rhs2 <- coreToStgExpr rhs
; return (DEFAULT, [], rhs2) }
| otherwise
= let -- Remove type variables
binders' = filterStgBinders binders
in
extendVarEnvCts [(b, LambdaBound) | b <- binders'] $ do
rhs2 <- coreToStgExpr rhs
return (con, binders', rhs2)
coreToStgExpr (Let bind body) = do
coreToStgLet bind body
coreToStgExpr e = pprPanic "coreToStgExpr" (ppr e)
mkStgAltType :: Id -> [CoreAlt] -> AltType
mkStgAltType bndr alts
| isUnboxedTupleType bndr_ty || isUnboxedSumType bndr_ty
= MultiValAlt (length prim_reps) -- always use MultiValAlt for unboxed tuples
| otherwise
= case prim_reps of
[LiftedRep] -> case tyConAppTyCon_maybe (unwrapType bndr_ty) of
Just tc
| isAbstractTyCon tc -> look_for_better_tycon
| isAlgTyCon tc -> AlgAlt tc
| otherwise -> ASSERT2( _is_poly_alt_tycon tc, ppr tc )
PolyAlt
Nothing -> PolyAlt
[unlifted] -> PrimAlt unlifted
not_unary -> MultiValAlt (length not_unary)
where
bndr_ty = idType bndr
prim_reps = typePrimRep bndr_ty
_is_poly_alt_tycon tc
= isFunTyCon tc
|| isPrimTyCon tc -- "Any" is lifted but primitive
|| isFamilyTyCon tc -- Type family; e.g. Any, or arising from strict
-- function application where argument has a
-- type-family type
-- Sometimes, the TyCon is a AbstractTyCon which may not have any
-- constructors inside it. Then we may get a better TyCon by
-- grabbing the one from a constructor alternative
-- if one exists.
look_for_better_tycon
| ((DataAlt con, _, _) : _) <- data_alts =
AlgAlt (dataConTyCon con)
| otherwise =
ASSERT(null data_alts)
PolyAlt
where
(data_alts, _deflt) = findDefault alts
-- ---------------------------------------------------------------------------
-- Applications
-- ---------------------------------------------------------------------------
coreToStgApp
:: Maybe UpdateFlag -- Just upd <=> this application is
-- the rhs of a thunk binding
-- x = [...] \upd [] -> the_app
-- with specified update flag
-> Id -- Function
-> [CoreArg] -- Arguments
-> [Tickish Id] -- Debug ticks
-> CtsM StgExpr
coreToStgApp _ f args ticks = do
(args', ticks') <- coreToStgArgs args
how_bound <- lookupVarCts f
let
n_val_args = valArgCount args
-- Mostly, the arity info of a function is in the fn's IdInfo
-- But new bindings introduced by CoreSat may not have no
-- arity info; it would do us no good anyway. For example:
-- let f = \ab -> e in f
-- No point in having correct arity info for f!
-- Hence the hasArity stuff below.
-- NB: f_arity is only consulted for LetBound things
f_arity = stgArity f how_bound
saturated = f_arity <= n_val_args
res_ty = exprType (mkApps (Var f) args)
app = case idDetails f of
DataConWorkId dc
| saturated -> StgConApp dc args'
(dropRuntimeRepArgs (fromMaybe [] (tyConAppArgs_maybe res_ty)))
-- Some primitive operator that might be implemented as a library call.
-- As described in Note [Primop wrappers] in PrimOp.hs, here we
-- turn unsaturated primop applications into applications of
-- the primop's wrapper.
PrimOpId op
| saturated -> StgOpApp (StgPrimOp op) args' res_ty
| otherwise -> StgApp (primOpWrapperId op) args'
-- A call to some primitive Cmm function.
FCallId (CCall (CCallSpec (StaticTarget _ lbl (Just pkgId) True)
PrimCallConv _))
-> ASSERT( saturated )
StgOpApp (StgPrimCallOp (PrimCall lbl pkgId)) args' res_ty
-- A regular foreign call.
FCallId call -> ASSERT( saturated )
StgOpApp (StgFCallOp call (idUnique f)) args' res_ty
TickBoxOpId {} -> pprPanic "coreToStg TickBox" $ ppr (f,args')
_other -> StgApp f args'
tapp = foldr StgTick app (ticks ++ ticks')
-- Forcing these fixes a leak in the code generator, noticed while
-- profiling for trac #4367
app `seq` return tapp
-- ---------------------------------------------------------------------------
-- Argument lists
-- This is the guy that turns applications into A-normal form
-- ---------------------------------------------------------------------------
coreToStgArgs :: [CoreArg] -> CtsM ([StgArg], [Tickish Id])
coreToStgArgs []
= return ([], [])
coreToStgArgs (Type _ : args) = do -- Type argument
(args', ts) <- coreToStgArgs args
return (args', ts)
coreToStgArgs (Coercion _ : args) -- Coercion argument; replace with place holder
= do { (args', ts) <- coreToStgArgs args
; return (StgVarArg coercionTokenId : args', ts) }
coreToStgArgs (Tick t e : args)
= ASSERT( not (tickishIsCode t) )
do { (args', ts) <- coreToStgArgs (e : args)
; return (args', t:ts) }
coreToStgArgs (arg : args) = do -- Non-type argument
(stg_args, ticks) <- coreToStgArgs args
arg' <- coreToStgExpr arg
let
(aticks, arg'') = stripStgTicksTop tickishFloatable arg'
stg_arg = case arg'' of
StgApp v [] -> StgVarArg v
StgConApp con [] _ -> StgVarArg (dataConWorkId con)
StgLit lit -> StgLitArg lit
_ -> pprPanic "coreToStgArgs" (ppr arg)
-- WARNING: what if we have an argument like (v `cast` co)
-- where 'co' changes the representation type?
-- (This really only happens if co is unsafe.)
-- Then all the getArgAmode stuff in CgBindery will set the
-- cg_rep of the CgIdInfo based on the type of v, rather
-- than the type of 'co'.
-- This matters particularly when the function is a primop
-- or foreign call.
-- Wanted: a better solution than this hacky warning
let
arg_ty = exprType arg
stg_arg_ty = stgArgType stg_arg
bad_args = (isUnliftedType arg_ty && not (isUnliftedType stg_arg_ty))
|| (typePrimRep arg_ty /= typePrimRep stg_arg_ty)
-- In GHCi we coerce an argument of type BCO# (unlifted) to HValue (lifted),
-- and pass it to a function expecting an HValue (arg_ty). This is ok because
-- we can treat an unlifted value as lifted. But the other way round
-- we complain.
-- We also want to check if a pointer is cast to a non-ptr etc
WARN( bad_args, text "Dangerous-looking argument. Probable cause: bad unsafeCoerce#" $$ ppr arg )
return (stg_arg : stg_args, ticks ++ aticks)
-- ---------------------------------------------------------------------------
-- The magic for lets:
-- ---------------------------------------------------------------------------
coreToStgLet
:: CoreBind -- bindings
-> CoreExpr -- body
-> CtsM StgExpr -- new let
coreToStgLet bind body = do
(bind2, body2)
<- do
( bind2, env_ext)
<- vars_bind bind
-- Do the body
extendVarEnvCts env_ext $ do
body2 <- coreToStgExpr body
return (bind2, body2)
-- Compute the new let-expression
let
new_let | isJoinBind bind = StgLetNoEscape noExtSilent bind2 body2
| otherwise = StgLet noExtSilent bind2 body2
return new_let
where
mk_binding binder rhs
= (binder, LetBound NestedLet (manifestArity rhs))
vars_bind :: CoreBind
-> CtsM (StgBinding,
[(Id, HowBound)]) -- extension to environment
vars_bind (NonRec binder rhs) = do
rhs2 <- coreToStgRhs (binder,rhs)
let
env_ext_item = mk_binding binder rhs
return (StgNonRec binder rhs2, [env_ext_item])
vars_bind (Rec pairs)
= let
binders = map fst pairs
env_ext = [ mk_binding b rhs
| (b,rhs) <- pairs ]
in
extendVarEnvCts env_ext $ do
rhss2 <- mapM coreToStgRhs pairs
return (StgRec (binders `zip` rhss2), env_ext)
coreToStgRhs :: (Id,CoreExpr)
-> CtsM StgRhs
coreToStgRhs (bndr, rhs) = do
new_rhs <- coreToStgExpr rhs
return (mkStgRhs bndr new_rhs)
-- Generate a top-level RHS. Any new cost centres generated for CAFs will be
-- appended to `CollectedCCs` argument.
mkTopStgRhs :: DynFlags -> Module -> CollectedCCs
-> Id -> StgExpr -> (StgRhs, CollectedCCs)
mkTopStgRhs dflags this_mod ccs bndr rhs
| StgLam bndrs body <- rhs
= -- StgLam can't have empty arguments, so not CAF
( StgRhsClosure noExtSilent
dontCareCCS
ReEntrant
(toList bndrs) body
, ccs )
| StgConApp con args _ <- unticked_rhs
, -- Dynamic StgConApps are updatable
not (isDllConApp dflags this_mod con args)
= -- CorePrep does this right, but just to make sure
ASSERT2( not (isUnboxedTupleCon con || isUnboxedSumCon con)
, ppr bndr $$ ppr con $$ ppr args)
( StgRhsCon dontCareCCS con args, ccs )
-- Otherwise it's a CAF, see Note [Cost-centre initialization plan].
| gopt Opt_AutoSccsOnIndividualCafs dflags
= ( StgRhsClosure noExtSilent
caf_ccs
upd_flag [] rhs
, collectCC caf_cc caf_ccs ccs )
| otherwise
= ( StgRhsClosure noExtSilent
all_cafs_ccs
upd_flag [] rhs
, ccs )
where
(_, unticked_rhs) = stripStgTicksTop (not . tickishIsCode) rhs
upd_flag | isUsedOnce (idDemandInfo bndr) = SingleEntry
| otherwise = Updatable
-- CAF cost centres generated for -fcaf-all
caf_cc = mkAutoCC bndr modl
caf_ccs = mkSingletonCCS caf_cc
-- careful: the binder might be :Main.main,
-- which doesn't belong to module mod_name.
-- bug #249, tests prof001, prof002
modl | Just m <- nameModule_maybe (idName bndr) = m
| otherwise = this_mod
-- default CAF cost centre
(_, all_cafs_ccs) = getAllCAFsCC this_mod
-- Generate a non-top-level RHS. Cost-centre is always currentCCS,
-- see Note [Cost-centre initialzation plan].
mkStgRhs :: Id -> StgExpr -> StgRhs
mkStgRhs bndr rhs
| StgLam bndrs body <- rhs
= StgRhsClosure noExtSilent
currentCCS
ReEntrant
(toList bndrs) body
| isJoinId bndr -- must be a nullary join point
= ASSERT(idJoinArity bndr == 0)
StgRhsClosure noExtSilent
currentCCS
ReEntrant -- ignored for LNE
[] rhs
| StgConApp con args _ <- unticked_rhs
= StgRhsCon currentCCS con args
| otherwise
= StgRhsClosure noExtSilent
currentCCS
upd_flag [] rhs
where
(_, unticked_rhs) = stripStgTicksTop (not . tickishIsCode) rhs
upd_flag | isUsedOnce (idDemandInfo bndr) = SingleEntry
| otherwise = Updatable
{-
SDM: disabled. Eval/Apply can't handle functions with arity zero very
well; and making these into simple non-updatable thunks breaks other
assumptions (namely that they will be entered only once).
upd_flag | isPAP env rhs = ReEntrant
| otherwise = Updatable
-- Detect thunks which will reduce immediately to PAPs, and make them
-- non-updatable. This has several advantages:
--
-- - the non-updatable thunk behaves exactly like the PAP,
--
-- - the thunk is more efficient to enter, because it is
-- specialised to the task.
--
-- - we save one update frame, one stg_update_PAP, one update
-- and lots of PAP_enters.
--
-- - in the case where the thunk is top-level, we save building
-- a black hole and furthermore the thunk isn't considered to
-- be a CAF any more, so it doesn't appear in any SRTs.
--
-- We do it here, because the arity information is accurate, and we need
-- to do it before the SRT pass to save the SRT entries associated with
-- any top-level PAPs.
isPAP env (StgApp f args) = listLengthCmp args arity == LT -- idArity f > length args
where
arity = stgArity f (lookupBinding env f)
isPAP env _ = False
-}
{- ToDo:
upd = if isOnceDem dem
then (if isNotTop toplev
then SingleEntry -- HA! Paydirt for "dem"
else
(if debugIsOn then trace "WARNING: SE CAFs unsupported, forcing UPD instead" else id) $
Updatable)
else Updatable
-- For now we forbid SingleEntry CAFs; they tickle the
-- ASSERT in rts/Storage.c line 215 at newCAF() re mut_link,
-- and I don't understand why. There's only one SE_CAF (well,
-- only one that tickled a great gaping bug in an earlier attempt
-- at ClosureInfo.getEntryConvention) in the whole of nofib,
-- specifically Main.lvl6 in spectral/cryptarithm2.
-- So no great loss. KSW 2000-07.
-}
-- ---------------------------------------------------------------------------
-- A monad for the core-to-STG pass
-- ---------------------------------------------------------------------------
-- There's a lot of stuff to pass around, so we use this CtsM
-- ("core-to-STG monad") monad to help. All the stuff here is only passed
-- *down*.
newtype CtsM a = CtsM
{ unCtsM :: IdEnv HowBound
-> a
}
data HowBound
= ImportBound -- Used only as a response to lookupBinding; never
-- exists in the range of the (IdEnv HowBound)
| LetBound -- A let(rec) in this module
LetInfo -- Whether top level or nested
Arity -- Its arity (local Ids don't have arity info at this point)
| LambdaBound -- Used for both lambda and case
deriving (Eq)
data LetInfo
= TopLet -- top level things
| NestedLet
deriving (Eq)
-- For a let(rec)-bound variable, x, we record LiveInfo, the set of
-- variables that are live if x is live. This LiveInfo comprises
-- (a) dynamic live variables (ones with a non-top-level binding)
-- (b) static live variabes (CAFs or things that refer to CAFs)
--
-- For "normal" variables (a) is just x alone. If x is a let-no-escaped
-- variable then x is represented by a code pointer and a stack pointer
-- (well, one for each stack). So all of the variables needed in the
-- execution of x are live if x is, and are therefore recorded in the
-- LetBound constructor; x itself *is* included.
--
-- The set of dynamic live variables is guaranteed ot have no further
-- let-no-escaped variables in it.
-- The std monad functions:
initCts :: IdEnv HowBound -> CtsM a -> a
initCts env m = unCtsM m env
{-# INLINE thenCts #-}
{-# INLINE returnCts #-}
returnCts :: a -> CtsM a
returnCts e = CtsM $ \_ -> e
thenCts :: CtsM a -> (a -> CtsM b) -> CtsM b
thenCts m k = CtsM $ \env
-> unCtsM (k (unCtsM m env)) env
instance Functor CtsM where
fmap = liftM
instance Applicative CtsM where
pure = returnCts
(<*>) = ap
instance Monad CtsM where
(>>=) = thenCts
-- Functions specific to this monad:
extendVarEnvCts :: [(Id, HowBound)] -> CtsM a -> CtsM a
extendVarEnvCts ids_w_howbound expr
= CtsM $ \env
-> unCtsM expr (extendVarEnvList env ids_w_howbound)
lookupVarCts :: Id -> CtsM HowBound
lookupVarCts v = CtsM $ \env -> lookupBinding env v
lookupBinding :: IdEnv HowBound -> Id -> HowBound
lookupBinding env v = case lookupVarEnv env v of
Just xx -> xx
Nothing -> ASSERT2( isGlobalId v, ppr v ) ImportBound
getAllCAFsCC :: Module -> (CostCentre, CostCentreStack)
getAllCAFsCC this_mod =
let
span = mkGeneralSrcSpan (mkFastString "<entire-module>") -- XXX do better
all_cafs_cc = mkAllCafsCC this_mod span
all_cafs_ccs = mkSingletonCCS all_cafs_cc
in
(all_cafs_cc, all_cafs_ccs)
-- Misc.
filterStgBinders :: [Var] -> [Var]
filterStgBinders bndrs = filter isId bndrs
myCollectBinders :: Expr Var -> ([Var], Expr Var)
myCollectBinders expr
= go [] expr
where
go bs (Lam b e) = go (b:bs) e
go bs (Cast e _) = go bs e
go bs e = (reverse bs, e)
-- | Precondition: argument expression is an 'App', and there is a 'Var' at the
-- head of the 'App' chain.
myCollectArgs :: CoreExpr -> (Id, [CoreArg], [Tickish Id])
myCollectArgs expr
= go expr [] []
where
go (Var v) as ts = (v, as, ts)
go (App f a) as ts = go f (a:as) ts
go (Tick t e) as ts = ASSERT( all isTypeArg as )
go e as (t:ts) -- ticks can appear in type apps
go (Cast e _) as ts = go e as ts
go (Lam b e) as ts
| isTyVar b = go e as ts -- Note [Collect args]
go _ _ _ = pprPanic "CoreToStg.myCollectArgs" (ppr expr)
-- Note [Collect args]
-- ~~~~~~~~~~~~~~~~~~~
--
-- This big-lambda case occurred following a rather obscure eta expansion.
-- It all seems a bit yukky to me.
stgArity :: Id -> HowBound -> Arity
stgArity _ (LetBound _ arity) = arity
stgArity f ImportBound = idArity f
stgArity _ LambdaBound = 0