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|
%
% (c) The GRASP/AQUA Project, Glasgow University, 1993-1998
%
\section[CoreToStg]{Converts Core to STG Syntax}
And, as we have the info in hand, we may convert some lets to
let-no-escapes.
\begin{code}
module CoreToStg ( coreToStg, coreExprToStg ) where
#include "HsVersions.h"
import CoreSyn
import CoreUtils
import StgSyn
import Type
import TyCon ( isAlgTyCon )
import Literal
import Id
import Var ( Var, globalIdDetails, varType )
#ifdef ILX
import MkId ( unsafeCoerceId )
#endif
import IdInfo
import DataCon
import CostCentre ( noCCS )
import VarSet
import VarEnv
import Maybes ( maybeToBool )
import Name ( getOccName, isExternalName, nameOccName )
import OccName ( occNameUserString, occNameFS )
import BasicTypes ( Arity )
import CmdLineOpts ( DynFlags, opt_RuntimeTypes )
import Outputable
infixr 9 `thenLne`
\end{code}
%************************************************************************
%* *
\subsection[live-vs-free-doc]{Documentation}
%* *
%************************************************************************
(There is other relevant documentation in codeGen/CgLetNoEscape.)
The actual Stg datatype is decorated with {\em live variable}
information, as well as {\em free variable} information. The two are
{\em 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 {\em directly} again. In particular, a dead
variable's stack slot (if it has one):
\begin{enumerate}
\item
should be stubbed to avoid space leaks, and
\item
may be reused for something else.
\end{enumerate}
There ought to be a better way to say this. Here are some examples:
\begin{verbatim}
let v = [q] \[x] -> e
in
...v... (but no q's)
\end{verbatim}
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:
\begin{verbatim}
case (let v = [q] \[x] -> e in ...v...) of
alts[...q...]
\end{verbatim}
(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:
\begin{verbatim}
let-no-escape v = [q] \ [x] -> e
in
...v...
\end{verbatim}
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 {\em its} free variables are also live
if @v@ is.
%************************************************************************
%* *
\subsection[caf-info]{Collecting live CAF info}
%* *
%************************************************************************
In this pass we also collect information on which CAFs are live for
constructing SRTs (see SRT.lhs).
A top-level Id has CafInfo, which is
- MayHaveCafRefs, if it may refer indirectly to
one or more CAFs, or
- NoCafRefs if it definitely doesn't
The CafInfo has already been calculated during the CoreTidy pass.
During CoreToStg, we then pin onto each binding and case expression, a
list of Ids which represents the "live" CAFs at that point. The meaning
of "live" here is the same as for live variables, see above (which is
why it's convenient to collect CAF information here rather than elsewhere).
The later SRT pass takes these lists of Ids and uses them to construct
the actual nested SRTs, and replaces the lists of Ids with (offset,length)
pairs.
Interaction of let-no-escape with SRTs [Sept 01]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Consider
let-no-escape x = ...caf1...caf2...
in
...x...x...x...
where caf1,caf2 are CAFs. Since x doesn't have a closure, we
build SRTs just as if x's defn was inlined at each call site, and
that means that x's CAF refs get duplicated in the overall SRT.
This is unlike ordinary lets, in which the CAF refs are not duplicated.
We could fix this loss of (static) sharing by making a sort of pseudo-closure
for x, solely to put in the SRTs lower down.
%************************************************************************
%* *
\subsection[binds-StgVarInfo]{Setting variable info: top-level, binds, RHSs}
%* *
%************************************************************************
\begin{code}
coreToStg :: DynFlags -> [CoreBind] -> IO [StgBinding]
coreToStg dflags pgm
= return pgm'
where (_, _, pgm') = coreTopBindsToStg emptyVarEnv pgm
coreExprToStg :: CoreExpr -> StgExpr
coreExprToStg expr
= new_expr where (new_expr,_,_) = initLne emptyVarEnv (coreToStgExpr expr)
coreTopBindsToStg
:: IdEnv HowBound -- environment for the bindings
-> [CoreBind]
-> (IdEnv HowBound, FreeVarsInfo, [StgBinding])
coreTopBindsToStg env [] = (env, emptyFVInfo, [])
coreTopBindsToStg env (b:bs)
= (env2, fvs2, b':bs')
where
-- env accumulates down the list of binds, fvs accumulates upwards
(env1, fvs2, b' ) = coreTopBindToStg env fvs1 b
(env2, fvs1, bs') = coreTopBindsToStg env1 bs
coreTopBindToStg
:: IdEnv HowBound
-> FreeVarsInfo -- Info about the body
-> CoreBind
-> (IdEnv HowBound, FreeVarsInfo, StgBinding)
coreTopBindToStg env body_fvs (NonRec id rhs)
= let
env' = extendVarEnv env id how_bound
how_bound = LetBound TopLet (manifestArity rhs)
(stg_rhs, fvs') =
initLne env (
coreToTopStgRhs body_fvs (id,rhs) `thenLne` \ (stg_rhs, fvs') ->
returnLne (stg_rhs, fvs')
)
bind = StgNonRec id stg_rhs
in
ASSERT2(manifestArity rhs == stgRhsArity stg_rhs, ppr id)
ASSERT2(consistentCafInfo id bind, ppr id)
-- WARN(not (consistent caf_info bind), ppr id <+> ppr cafs <+> ppCafInfo caf_info)
(env', fvs' `unionFVInfo` body_fvs, bind)
coreTopBindToStg env body_fvs (Rec pairs)
= let
(binders, rhss) = unzip pairs
extra_env' = [ (b, LetBound TopLet (manifestArity rhs))
| (b, rhs) <- pairs ]
env' = extendVarEnvList env extra_env'
(stg_rhss, fvs')
= initLne env' (
mapAndUnzipLne (coreToTopStgRhs body_fvs) pairs
`thenLne` \ (stg_rhss, fvss') ->
let fvs' = unionFVInfos fvss' in
returnLne (stg_rhss, fvs')
)
bind = StgRec (zip binders stg_rhss)
in
ASSERT2(and [manifestArity rhs == stgRhsArity stg_rhs | (rhs,stg_rhs) <- rhss `zip` stg_rhss], ppr binders)
ASSERT2(consistentCafInfo (head binders) bind, ppr binders)
(env', fvs' `unionFVInfo` body_fvs, bind)
#ifdef DEBUG
-- 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 bind
| occNameFS (nameOccName (idName id)) == FSLIT("sat")
= safe
| otherwise
= WARN (not exact, ppr id) 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 = stgBindHasCafRefs bind
#endif
\end{code}
\begin{code}
coreToTopStgRhs
:: FreeVarsInfo -- Free var info for the scope of the binding
-> (Id,CoreExpr)
-> LneM (StgRhs, FreeVarsInfo)
coreToTopStgRhs scope_fv_info (bndr, rhs)
= coreToStgExpr rhs `thenLne` \ (new_rhs, rhs_fvs, _) ->
freeVarsToLiveVars rhs_fvs `thenLne` \ lv_info ->
returnLne (mkTopStgRhs upd rhs_fvs (mkSRT lv_info) bndr_info new_rhs, rhs_fvs)
where
bndr_info = lookupFVInfo scope_fv_info bndr
upd | rhsIsNonUpd rhs = SingleEntry
| otherwise = Updatable
mkTopStgRhs :: UpdateFlag -> FreeVarsInfo -> SRT -> StgBinderInfo -> StgExpr
-> StgRhs
mkTopStgRhs upd rhs_fvs srt binder_info (StgLam _ bndrs body)
= StgRhsClosure noCCS binder_info
(getFVs rhs_fvs)
ReEntrant
srt
bndrs body
mkTopStgRhs upd rhs_fvs srt binder_info (StgConApp con args)
| not (isUpdatable upd) -- StgConApps can be updatable (see isCrossDllConApp)
= StgRhsCon noCCS con args
mkTopStgRhs upd rhs_fvs srt binder_info rhs
= StgRhsClosure noCCS binder_info
(getFVs rhs_fvs)
upd
srt
[] rhs
\end{code}
-- ---------------------------------------------------------------------------
-- Expressions
-- ---------------------------------------------------------------------------
\begin{code}
coreToStgExpr
:: CoreExpr
-> LneM (StgExpr, -- Decorated STG expr
FreeVarsInfo, -- Its free vars (NB free, not live)
EscVarsSet) -- Its escapees, a subset of its free vars;
-- also a subset of the domain of the envt
-- because we are only interested in the escapees
-- for vars which might be turned into
-- let-no-escaped ones.
\end{code}
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.
\begin{code}
coreToStgExpr (Lit l) = returnLne (StgLit l, emptyFVInfo, emptyVarSet)
coreToStgExpr (Var v) = coreToStgApp Nothing v []
coreToStgExpr expr@(App _ _)
= coreToStgApp Nothing f args
where
(f, args) = myCollectArgs expr
coreToStgExpr expr@(Lam _ _)
= let
(args, body) = myCollectBinders expr
args' = filterStgBinders args
in
extendVarEnvLne [ (a, LambdaBound) | a <- args' ] $
coreToStgExpr body `thenLne` \ (body, body_fvs, body_escs) ->
let
fvs = args' `minusFVBinders` body_fvs
escs = body_escs `delVarSetList` args'
result_expr | null args' = body
| otherwise = StgLam (exprType expr) args' body
in
returnLne (result_expr, fvs, escs)
coreToStgExpr (Note (SCC cc) expr)
= coreToStgExpr expr `thenLne` ( \ (expr2, fvs, escs) ->
returnLne (StgSCC cc expr2, fvs, escs) )
#ifdef ILX
-- For ILX, convert (__coerce__ to_ty from_ty e)
-- into (coerce to_ty from_ty e)
-- where coerce is real function
coreToStgExpr (Note (Coerce to_ty from_ty) expr)
= coreToStgExpr (mkApps (Var unsafeCoerceId)
[Type from_ty, Type to_ty, expr])
#endif
coreToStgExpr (Note other_note expr)
= coreToStgExpr expr
-- Cases require a little more real work.
coreToStgExpr (Case scrut bndr alts)
= extendVarEnvLne [(bndr, LambdaBound)] (
mapAndUnzip3Lne vars_alt alts `thenLne` \ (alts2, fvs_s, escs_s) ->
returnLne ( mkStgAlts (idType bndr) alts2,
unionFVInfos fvs_s,
unionVarSets escs_s )
) `thenLne` \ (alts2, alts_fvs, alts_escs) ->
let
-- Determine whether the default binder is dead or not
-- This helps the code generator to avoid generating an assignment
-- for the case binder (is extremely rare cases) ToDo: remove.
bndr' | bndr `elementOfFVInfo` alts_fvs = bndr
| otherwise = bndr `setIdOccInfo` IAmDead
-- Don't consider the default binder as being 'live in alts',
-- since this is from the point of view of the case expr, where
-- the default binder is not free.
alts_fvs_wo_bndr = bndr `minusFVBinder` alts_fvs
alts_escs_wo_bndr = alts_escs `delVarSet` bndr
in
freeVarsToLiveVars alts_fvs_wo_bndr `thenLne` \ alts_lv_info ->
-- We tell the scrutinee that everything
-- live in the alts is live in it, too.
setVarsLiveInCont alts_lv_info (
coreToStgExpr scrut `thenLne` \ (scrut2, scrut_fvs, scrut_escs) ->
freeVarsToLiveVars scrut_fvs `thenLne` \ scrut_lv_info ->
returnLne (scrut2, scrut_fvs, scrut_escs, scrut_lv_info)
)
`thenLne` \ (scrut2, scrut_fvs, scrut_escs, scrut_lv_info) ->
returnLne (
StgCase scrut2 (getLiveVars scrut_lv_info)
(getLiveVars alts_lv_info)
bndr'
(mkSRT alts_lv_info)
alts2,
scrut_fvs `unionFVInfo` alts_fvs_wo_bndr,
alts_escs_wo_bndr `unionVarSet` getFVSet scrut_fvs
-- You might think we should have scrut_escs, not
-- (getFVSet scrut_fvs), but actually we can't call, and
-- then return from, a let-no-escape thing.
)
where
vars_alt (con, binders, rhs)
= let -- Remove type variables
binders' = filterStgBinders binders
in
extendVarEnvLne [(b, LambdaBound) | b <- binders'] $
coreToStgExpr rhs `thenLne` \ (rhs2, rhs_fvs, rhs_escs) ->
let
-- Records whether each param is used in the RHS
good_use_mask = [ b `elementOfFVInfo` rhs_fvs | b <- binders' ]
in
returnLne ( (con, binders', good_use_mask, rhs2),
binders' `minusFVBinders` rhs_fvs,
rhs_escs `delVarSetList` binders' )
-- ToDo: remove the delVarSet;
-- since escs won't include any of these binders
\end{code}
Lets not only take quite a bit of work, but this is where we convert
then to let-no-escapes, if we wish.
(Meanwhile, we don't expect to see let-no-escapes...)
\begin{code}
coreToStgExpr (Let bind body)
= fixLne (\ ~(_, _, _, no_binder_escapes) ->
coreToStgLet no_binder_escapes bind body
) `thenLne` \ (new_let, fvs, escs, _) ->
returnLne (new_let, fvs, escs)
\end{code}
\begin{code}
mkStgAlts scrut_ty orig_alts
| is_prim_case = StgPrimAlts (tyConAppTyCon scrut_ty) prim_alts deflt
| otherwise = StgAlgAlts maybe_tycon alg_alts deflt
where
is_prim_case = isUnLiftedType scrut_ty && not (isUnboxedTupleType scrut_ty)
prim_alts = [(lit, rhs) | (LitAlt lit, _, _, rhs) <- other_alts]
alg_alts = [(con, bndrs, use, rhs) | (DataAlt con, bndrs, use, rhs) <- other_alts]
(other_alts, deflt)
= case orig_alts of -- DEFAULT is always first if it's there at all
(DEFAULT, _, _, rhs) : other_alts -> (other_alts, StgBindDefault rhs)
other -> (orig_alts, StgNoDefault)
maybe_tycon = case alg_alts of
-- Get the tycon from the data con
(dc, _, _, _) : _rest -> Just (dataConTyCon dc)
-- Otherwise just do your best
[] -> case splitTyConApp_maybe (repType scrut_ty) of
Just (tc,_) | isAlgTyCon tc -> Just tc
_other -> Nothing
\end{code}
-- ---------------------------------------------------------------------------
-- Applications
-- ---------------------------------------------------------------------------
\begin{code}
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
-> LneM (StgExpr, FreeVarsInfo, EscVarsSet)
coreToStgApp maybe_thunk_body f args
= coreToStgArgs args `thenLne` \ (args', args_fvs) ->
lookupVarLne f `thenLne` \ how_bound ->
let
n_val_args = valArgCount args
not_letrec_bound = not (isLetBound how_bound)
fun_fvs
= let fvs = singletonFVInfo f how_bound fun_occ in
-- e.g. (f :: a -> int) (x :: a)
-- Here the free variables are "f", "x" AND the type variable "a"
-- coreToStgArgs will deal with the arguments recursively
if opt_RuntimeTypes then
fvs `unionFVInfo` tyvarFVInfo (tyVarsOfType (varType f))
else fvs
-- 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
fun_occ
| not_letrec_bound = noBinderInfo -- Uninteresting variable
| f_arity > 0 && saturated = stgSatOcc -- Saturated or over-saturated function call
| otherwise = stgUnsatOcc -- Unsaturated function or thunk
fun_escs
| not_letrec_bound = emptyVarSet -- Only letrec-bound escapees are interesting
| f_arity == n_val_args = emptyVarSet -- A function *or thunk* with an exactly
-- saturated call doesn't escape
-- (let-no-escape applies to 'thunks' too)
| otherwise = unitVarSet f -- Inexact application; it does escape
-- At the moment of the call:
-- either the function is *not* let-no-escaped, in which case
-- nothing is live except live_in_cont
-- or the function *is* let-no-escaped in which case the
-- variables it uses are live, but still the function
-- itself is not. PS. In this case, the function's
-- live vars should already include those of the
-- continuation, but it does no harm to just union the
-- two regardless.
res_ty = exprType (mkApps (Var f) args)
app = case globalIdDetails f of
DataConWorkId dc | saturated -> StgConApp dc args'
PrimOpId op -> ASSERT( saturated )
StgOpApp (StgPrimOp op) args' res_ty
FCallId call -> ASSERT( saturated )
StgOpApp (StgFCallOp call (idUnique f)) args' res_ty
_other -> StgApp f args'
in
returnLne (
app,
fun_fvs `unionFVInfo` args_fvs,
fun_escs `unionVarSet` (getFVSet args_fvs)
-- All the free vars of the args are disqualified
-- from being let-no-escaped.
)
-- ---------------------------------------------------------------------------
-- Argument lists
-- This is the guy that turns applications into A-normal form
-- ---------------------------------------------------------------------------
coreToStgArgs :: [CoreArg] -> LneM ([StgArg], FreeVarsInfo)
coreToStgArgs []
= returnLne ([], emptyFVInfo)
coreToStgArgs (Type ty : args) -- Type argument
= coreToStgArgs args `thenLne` \ (args', fvs) ->
if opt_RuntimeTypes then
returnLne (StgTypeArg ty : args', fvs `unionFVInfo` tyvarFVInfo (tyVarsOfType ty))
else
returnLne (args', fvs)
coreToStgArgs (arg : args) -- Non-type argument
= coreToStgArgs args `thenLne` \ (stg_args, args_fvs) ->
coreToStgExpr arg `thenLne` \ (arg', arg_fvs, escs) ->
let
fvs = args_fvs `unionFVInfo` arg_fvs
stg_arg = case arg' of
StgApp v [] -> StgVarArg v
StgConApp con [] -> StgVarArg (dataConWorkId con)
StgLit lit -> StgLitArg lit
_ -> pprPanic "coreToStgArgs" (ppr arg)
in
returnLne (stg_arg : stg_args, fvs)
-- ---------------------------------------------------------------------------
-- The magic for lets:
-- ---------------------------------------------------------------------------
coreToStgLet
:: Bool -- True <=> yes, we are let-no-escaping this let
-> CoreBind -- bindings
-> CoreExpr -- body
-> LneM (StgExpr, -- new let
FreeVarsInfo, -- variables free in the whole let
EscVarsSet, -- variables that escape from the whole let
Bool) -- True <=> none of the binders in the bindings
-- is among the escaping vars
coreToStgLet let_no_escape bind body
= fixLne (\ ~(_, _, _, _, _, rec_body_fvs, _, _) ->
-- Do the bindings, setting live_in_cont to empty if
-- we ain't in a let-no-escape world
getVarsLiveInCont `thenLne` \ live_in_cont ->
setVarsLiveInCont (if let_no_escape
then live_in_cont
else emptyLiveInfo)
(vars_bind rec_body_fvs bind)
`thenLne` \ ( bind2, bind_fvs, bind_escs, bind_lv_info, env_ext) ->
-- Do the body
extendVarEnvLne env_ext (
coreToStgExpr body `thenLne` \(body2, body_fvs, body_escs) ->
freeVarsToLiveVars body_fvs `thenLne` \ body_lv_info ->
returnLne (bind2, bind_fvs, bind_escs, getLiveVars bind_lv_info,
body2, body_fvs, body_escs, getLiveVars body_lv_info)
)
) `thenLne` (\ (bind2, bind_fvs, bind_escs, bind_lvs,
body2, body_fvs, body_escs, body_lvs) ->
-- Compute the new let-expression
let
new_let | let_no_escape = StgLetNoEscape live_in_whole_let bind_lvs bind2 body2
| otherwise = StgLet bind2 body2
free_in_whole_let
= binders `minusFVBinders` (bind_fvs `unionFVInfo` body_fvs)
live_in_whole_let
= bind_lvs `unionVarSet` (body_lvs `delVarSetList` binders)
real_bind_escs = if let_no_escape then
bind_escs
else
getFVSet bind_fvs
-- Everything escapes which is free in the bindings
let_escs = (real_bind_escs `unionVarSet` body_escs) `delVarSetList` binders
all_escs = bind_escs `unionVarSet` body_escs -- Still includes binders of
-- this let(rec)
no_binder_escapes = isEmptyVarSet (set_of_binders `intersectVarSet` all_escs)
#ifdef DEBUG
-- Debugging code as requested by Andrew Kennedy
checked_no_binder_escapes
| not no_binder_escapes && any is_join_var binders
= pprTrace "Interesting! A join var that isn't let-no-escaped" (ppr binders)
False
| otherwise = no_binder_escapes
#else
checked_no_binder_escapes = no_binder_escapes
#endif
-- Mustn't depend on the passed-in let_no_escape flag, since
-- no_binder_escapes is used by the caller to derive the flag!
in
returnLne (
new_let,
free_in_whole_let,
let_escs,
checked_no_binder_escapes
))
where
set_of_binders = mkVarSet binders
binders = bindersOf bind
mk_binding bind_lv_info binder rhs
= (binder, LetBound (NestedLet live_vars) (manifestArity rhs))
where
live_vars | let_no_escape = addLiveVar bind_lv_info binder
| otherwise = unitLiveVar binder
-- c.f. the invariant on NestedLet
vars_bind :: FreeVarsInfo -- Free var info for body of binding
-> CoreBind
-> LneM (StgBinding,
FreeVarsInfo,
EscVarsSet, -- free vars; escapee vars
LiveInfo, -- Vars and CAFs live in binding
[(Id, HowBound)]) -- extension to environment
vars_bind body_fvs (NonRec binder rhs)
= coreToStgRhs body_fvs [] (binder,rhs)
`thenLne` \ (rhs2, bind_fvs, bind_lv_info, escs) ->
let
env_ext_item = mk_binding bind_lv_info binder rhs
in
returnLne (StgNonRec binder rhs2,
bind_fvs, escs, bind_lv_info, [env_ext_item])
vars_bind body_fvs (Rec pairs)
= fixLne (\ ~(_, rec_rhs_fvs, _, bind_lv_info, _) ->
let
rec_scope_fvs = unionFVInfo body_fvs rec_rhs_fvs
binders = map fst pairs
env_ext = [ mk_binding bind_lv_info b rhs
| (b,rhs) <- pairs ]
in
extendVarEnvLne env_ext (
mapAndUnzip4Lne (coreToStgRhs rec_scope_fvs binders) pairs
`thenLne` \ (rhss2, fvss, lv_infos, escss) ->
let
bind_fvs = unionFVInfos fvss
bind_lv_info = foldr unionLiveInfo emptyLiveInfo lv_infos
escs = unionVarSets escss
in
returnLne (StgRec (binders `zip` rhss2),
bind_fvs, escs, bind_lv_info, env_ext)
)
)
is_join_var :: Id -> Bool
-- A hack (used only for compiler debuggging) to tell if
-- a variable started life as a join point ($j)
is_join_var j = occNameUserString (getOccName j) == "$j"
\end{code}
\begin{code}
coreToStgRhs :: FreeVarsInfo -- Free var info for the scope of the binding
-> [Id]
-> (Id,CoreExpr)
-> LneM (StgRhs, FreeVarsInfo, LiveInfo, EscVarsSet)
coreToStgRhs scope_fv_info binders (bndr, rhs)
= coreToStgExpr rhs `thenLne` \ (new_rhs, rhs_fvs, rhs_escs) ->
getEnvLne `thenLne` \ env ->
freeVarsToLiveVars (binders `minusFVBinders` rhs_fvs) `thenLne` \ lv_info ->
returnLne (mkStgRhs rhs_fvs (mkSRT lv_info) bndr_info new_rhs,
rhs_fvs, lv_info, rhs_escs)
where
bndr_info = lookupFVInfo scope_fv_info bndr
mkStgRhs :: FreeVarsInfo -> SRT -> StgBinderInfo -> StgExpr -> StgRhs
mkStgRhs rhs_fvs srt binder_info (StgConApp con args)
= StgRhsCon noCCS con args
mkStgRhs rhs_fvs srt binder_info (StgLam _ bndrs body)
= StgRhsClosure noCCS binder_info
(getFVs rhs_fvs)
ReEntrant
srt bndrs body
mkStgRhs rhs_fvs srt binder_info rhs
= StgRhsClosure noCCS binder_info
(getFVs rhs_fvs)
upd_flag srt [] rhs
where
upd_flag = 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
-}
{- ToDo:
upd = if isOnceDem dem
then (if isNotTop toplev
then SingleEntry -- HA! Paydirt for "dem"
else
#ifdef DEBUG
trace "WARNING: SE CAFs unsupported, forcing UPD instead" $
#endif
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.
-}
\end{code}
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 futhermore 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
%************************************************************************
%* *
\subsection[LNE-monad]{A little monad for this let-no-escaping pass}
%* *
%************************************************************************
There's a lot of stuff to pass around, so we use this @LneM@ monad to
help. All the stuff here is only passed *down*.
\begin{code}
type LneM a = IdEnv HowBound
-> LiveInfo -- Vars and CAFs live in continuation
-> a
type LiveInfo = (StgLiveVars, -- Dynamic live variables;
-- i.e. ones with a nested (non-top-level) binding
CafSet) -- Static live variables;
-- i.e. top-level variables that are CAFs or refer to them
type EscVarsSet = IdSet
type CafSet = IdSet
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
data LetInfo
= TopLet -- top level things
| NestedLet LiveInfo -- For nested things, what is live if this
-- thing is live? Invariant: the binder
-- itself is always a member of
-- the dynamic set of its own LiveInfo
isLetBound (LetBound _ _) = True
isLetBound other = False
topLevelBound ImportBound = True
topLevelBound (LetBound TopLet _) = True
topLevelBound other = False
\end{code}
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.
\begin{code}
emptyLiveInfo :: LiveInfo
emptyLiveInfo = (emptyVarSet,emptyVarSet)
unitLiveVar :: Id -> LiveInfo
unitLiveVar lv = (unitVarSet lv, emptyVarSet)
unitLiveCaf :: Id -> LiveInfo
unitLiveCaf caf = (emptyVarSet, unitVarSet caf)
addLiveVar :: LiveInfo -> Id -> LiveInfo
addLiveVar (lvs, cafs) id = (lvs `extendVarSet` id, cafs)
unionLiveInfo :: LiveInfo -> LiveInfo -> LiveInfo
unionLiveInfo (lv1,caf1) (lv2,caf2) = (lv1 `unionVarSet` lv2, caf1 `unionVarSet` caf2)
mkSRT :: LiveInfo -> SRT
mkSRT (_, cafs) = SRTEntries cafs
getLiveVars :: LiveInfo -> StgLiveVars
getLiveVars (lvs, _) = lvs
\end{code}
The std monad functions:
\begin{code}
initLne :: IdEnv HowBound -> LneM a -> a
initLne env m = m env emptyLiveInfo
{-# INLINE thenLne #-}
{-# INLINE returnLne #-}
returnLne :: a -> LneM a
returnLne e env lvs_cont = e
thenLne :: LneM a -> (a -> LneM b) -> LneM b
thenLne m k env lvs_cont
= k (m env lvs_cont) env lvs_cont
mapLne :: (a -> LneM b) -> [a] -> LneM [b]
mapLne f [] = returnLne []
mapLne f (x:xs)
= f x `thenLne` \ r ->
mapLne f xs `thenLne` \ rs ->
returnLne (r:rs)
mapAndUnzipLne :: (a -> LneM (b,c)) -> [a] -> LneM ([b],[c])
mapAndUnzipLne f [] = returnLne ([],[])
mapAndUnzipLne f (x:xs)
= f x `thenLne` \ (r1, r2) ->
mapAndUnzipLne f xs `thenLne` \ (rs1, rs2) ->
returnLne (r1:rs1, r2:rs2)
mapAndUnzip3Lne :: (a -> LneM (b,c,d)) -> [a] -> LneM ([b],[c],[d])
mapAndUnzip3Lne f [] = returnLne ([],[],[])
mapAndUnzip3Lne f (x:xs)
= f x `thenLne` \ (r1, r2, r3) ->
mapAndUnzip3Lne f xs `thenLne` \ (rs1, rs2, rs3) ->
returnLne (r1:rs1, r2:rs2, r3:rs3)
mapAndUnzip4Lne :: (a -> LneM (b,c,d,e)) -> [a] -> LneM ([b],[c],[d],[e])
mapAndUnzip4Lne f [] = returnLne ([],[],[],[])
mapAndUnzip4Lne f (x:xs)
= f x `thenLne` \ (r1, r2, r3, r4) ->
mapAndUnzip4Lne f xs `thenLne` \ (rs1, rs2, rs3, rs4) ->
returnLne (r1:rs1, r2:rs2, r3:rs3, r4:rs4)
fixLne :: (a -> LneM a) -> LneM a
fixLne expr env lvs_cont
= result
where
result = expr result env lvs_cont
\end{code}
Functions specific to this monad:
\begin{code}
getVarsLiveInCont :: LneM LiveInfo
getVarsLiveInCont env lvs_cont = lvs_cont
setVarsLiveInCont :: LiveInfo -> LneM a -> LneM a
setVarsLiveInCont new_lvs_cont expr env lvs_cont
= expr env new_lvs_cont
extendVarEnvLne :: [(Id, HowBound)] -> LneM a -> LneM a
extendVarEnvLne ids_w_howbound expr env lvs_cont
= expr (extendVarEnvList env ids_w_howbound) lvs_cont
lookupVarLne :: Id -> LneM HowBound
lookupVarLne v env lvs_cont = returnLne (lookupBinding env v) env lvs_cont
getEnvLne :: LneM (IdEnv HowBound)
getEnvLne env lvs_cont = returnLne env env lvs_cont
lookupBinding :: IdEnv HowBound -> Id -> HowBound
lookupBinding env v = case lookupVarEnv env v of
Just xx -> xx
Nothing -> ASSERT2( isGlobalId v, ppr v ) ImportBound
-- The result of lookupLiveVarsForSet, a set of live variables, is
-- only ever tacked onto a decorated expression. It is never used as
-- the basis of a control decision, which might give a black hole.
freeVarsToLiveVars :: FreeVarsInfo -> LneM LiveInfo
freeVarsToLiveVars fvs env live_in_cont
= returnLne live_info env live_in_cont
where
live_info = foldr unionLiveInfo live_in_cont lvs_from_fvs
lvs_from_fvs = map do_one (allFreeIds fvs)
do_one (v, how_bound)
= case how_bound of
ImportBound -> unitLiveCaf v -- Only CAF imports are
-- recorded in fvs
LetBound TopLet _
| mayHaveCafRefs (idCafInfo v) -> unitLiveCaf v
| otherwise -> emptyLiveInfo
LetBound (NestedLet lvs) _ -> lvs -- lvs already contains v
-- (see the invariant on NestedLet)
_lambda_or_case_binding -> unitLiveVar v -- Bound by lambda or case
\end{code}
%************************************************************************
%* *
\subsection[Free-var info]{Free variable information}
%* *
%************************************************************************
\begin{code}
type FreeVarsInfo = VarEnv (Var, HowBound, StgBinderInfo)
-- The Var is so we can gather up the free variables
-- as a set.
--
-- The HowBound info just saves repeated lookups;
-- we look up just once when we encounter the occurrence.
-- INVARIANT: Any ImportBound Ids are HaveCafRef Ids
-- Imported Ids without CAF refs are simply
-- not put in the FreeVarsInfo for an expression.
-- See singletonFVInfo and freeVarsToLiveVars
--
-- StgBinderInfo records how it occurs; notably, we
-- are interested in whether it only occurs in saturated
-- applications, because then we don't need to build a
-- curried version.
-- If f is mapped to noBinderInfo, that means
-- that f *is* mentioned (else it wouldn't be in the
-- IdEnv at all), but perhaps in an unsaturated applications.
--
-- All case/lambda-bound things are also mapped to
-- noBinderInfo, since we aren't interested in their
-- occurence info.
--
-- For ILX we track free var info for type variables too;
-- hence VarEnv not IdEnv
\end{code}
\begin{code}
emptyFVInfo :: FreeVarsInfo
emptyFVInfo = emptyVarEnv
singletonFVInfo :: Id -> HowBound -> StgBinderInfo -> FreeVarsInfo
-- Don't record non-CAF imports at all, to keep free-var sets small
singletonFVInfo id ImportBound info
| mayHaveCafRefs (idCafInfo id) = unitVarEnv id (id, ImportBound, info)
| otherwise = emptyVarEnv
singletonFVInfo id how_bound info = unitVarEnv id (id, how_bound, info)
tyvarFVInfo :: TyVarSet -> FreeVarsInfo
tyvarFVInfo tvs = foldVarSet add emptyFVInfo tvs
where
add tv fvs = extendVarEnv fvs tv (tv, LambdaBound, noBinderInfo)
-- Type variables must be lambda-bound
unionFVInfo :: FreeVarsInfo -> FreeVarsInfo -> FreeVarsInfo
unionFVInfo fv1 fv2 = plusVarEnv_C plusFVInfo fv1 fv2
unionFVInfos :: [FreeVarsInfo] -> FreeVarsInfo
unionFVInfos fvs = foldr unionFVInfo emptyFVInfo fvs
minusFVBinders :: [Id] -> FreeVarsInfo -> FreeVarsInfo
minusFVBinders vs fv = foldr minusFVBinder fv vs
minusFVBinder :: Id -> FreeVarsInfo -> FreeVarsInfo
minusFVBinder v fv | isId v && opt_RuntimeTypes
= (fv `delVarEnv` v) `unionFVInfo`
tyvarFVInfo (tyVarsOfType (idType v))
| otherwise = fv `delVarEnv` v
-- When removing a binder, remember to add its type variables
-- c.f. CoreFVs.delBinderFV
elementOfFVInfo :: Id -> FreeVarsInfo -> Bool
elementOfFVInfo id fvs = maybeToBool (lookupVarEnv fvs id)
lookupFVInfo :: FreeVarsInfo -> Id -> StgBinderInfo
-- Find how the given Id is used.
-- Externally visible things may be used any old how
lookupFVInfo fvs id
| isExternalName (idName id) = noBinderInfo
| otherwise = case lookupVarEnv fvs id of
Nothing -> noBinderInfo
Just (_,_,info) -> info
allFreeIds :: FreeVarsInfo -> [(Id,HowBound)] -- Both top level and non-top-level Ids
allFreeIds fvs = [(id,how_bound) | (id,how_bound,_) <- rngVarEnv fvs, isId id]
-- Non-top-level things only, both type variables and ids
-- (type variables only if opt_RuntimeTypes)
getFVs :: FreeVarsInfo -> [Var]
getFVs fvs = [id | (id, how_bound, _) <- rngVarEnv fvs,
not (topLevelBound how_bound) ]
getFVSet :: FreeVarsInfo -> VarSet
getFVSet fvs = mkVarSet (getFVs fvs)
plusFVInfo (id1,hb1,info1) (id2,hb2,info2)
= ASSERT (id1 == id2 && hb1 `check_eq_how_bound` hb2)
(id1, hb1, combineStgBinderInfo info1 info2)
#ifdef DEBUG
-- The HowBound info for a variable in the FVInfo should be consistent
check_eq_how_bound ImportBound ImportBound = True
check_eq_how_bound LambdaBound LambdaBound = True
check_eq_how_bound (LetBound li1 ar1) (LetBound li2 ar2) = ar1 == ar2 && check_eq_li li1 li2
check_eq_how_bound hb1 hb2 = False
check_eq_li (NestedLet _) (NestedLet _) = True
check_eq_li TopLet TopLet = True
check_eq_li li1 li2 = False
#endif
\end{code}
Misc.
\begin{code}
filterStgBinders :: [Var] -> [Var]
filterStgBinders bndrs
| opt_RuntimeTypes = bndrs
| otherwise = filter isId bndrs
\end{code}
\begin{code}
-- Ignore all notes except SCC
myCollectBinders expr
= go [] expr
where
go bs (Lam b e) = go (b:bs) e
go bs e@(Note (SCC _) _) = (reverse bs, e)
go bs (Note _ e) = go bs e
go bs e = (reverse bs, e)
myCollectArgs :: CoreExpr -> (Id, [CoreArg])
-- We assume that we only have variables
-- in the function position by now
myCollectArgs expr
= go expr []
where
go (Var v) as = (v, as)
go (App f a) as = go f (a:as)
go (Note (SCC _) e) as = pprPanic "CoreToStg.myCollectArgs" (ppr expr)
go (Note n e) as = go e as
go _ as = pprPanic "CoreToStg.myCollectArgs" (ppr expr)
\end{code}
\begin{code}
stgArity :: Id -> HowBound -> Arity
stgArity f (LetBound _ arity) = arity
stgArity f ImportBound = idArity f
stgArity f LambdaBound = 0
\end{code}
|