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|
{-
(c) The University of Glasgow 2006
(c) The GRASP/AQUA Project, Glasgow University, 1992-1998
The Desugarer: turning HsSyn into Core.
-}
{-# LANGUAGE CPP #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE ViewPatterns #-}
{-# OPTIONS_GHC -Wno-incomplete-uni-patterns #-}
module GHC.HsToCore (
-- * Desugaring operations
deSugar, deSugarExpr
) where
#include "HsVersions.h"
import GhcPrelude
import GHC.HsToCore.Usage
import DynFlags
import HscTypes
import GHC.Hs
import TcRnTypes
import TcRnMonad ( finalSafeMode, fixSafeInstances )
import TcRnDriver ( runTcInteractive )
import Id
import IdInfo
import Name
import Type
import TyCon ( tyConDataCons )
import Avail
import CoreSyn
import CoreFVs ( exprsSomeFreeVarsList )
import CoreOpt ( simpleOptPgm, simpleOptExpr )
import CoreUtils
import CoreUnfold
import PprCore
import GHC.HsToCore.Monad
import GHC.HsToCore.Expr
import GHC.HsToCore.Binds
import GHC.HsToCore.Foreign.Decl
import PrelNames
import TysPrim
import Coercion
import TysWiredIn
import DataCon ( dataConWrapId )
import MkCore
import Module
import NameSet
import NameEnv
import Rules
import BasicTypes
import CoreMonad ( CoreToDo(..) )
import CoreLint ( endPassIO )
import VarSet
import FastString
import ErrUtils
import Outputable
import SrcLoc
import GHC.HsToCore.Coverage
import Util
import MonadUtils
import OrdList
import GHC.HsToCore.Docs
import Data.List
import Data.IORef
import Control.Monad( when )
import Plugins ( LoadedPlugin(..) )
{-
************************************************************************
* *
* The main function: deSugar
* *
************************************************************************
-}
-- | Main entry point to the desugarer.
deSugar :: HscEnv -> ModLocation -> TcGblEnv -> IO (Messages, Maybe ModGuts)
-- Can modify PCS by faulting in more declarations
deSugar hsc_env
mod_loc
tcg_env@(TcGblEnv { tcg_mod = id_mod,
tcg_semantic_mod = mod,
tcg_src = hsc_src,
tcg_type_env = type_env,
tcg_imports = imports,
tcg_exports = exports,
tcg_keep = keep_var,
tcg_th_splice_used = tc_splice_used,
tcg_rdr_env = rdr_env,
tcg_fix_env = fix_env,
tcg_inst_env = inst_env,
tcg_fam_inst_env = fam_inst_env,
tcg_merged = merged,
tcg_warns = warns,
tcg_anns = anns,
tcg_binds = binds,
tcg_imp_specs = imp_specs,
tcg_dependent_files = dependent_files,
tcg_ev_binds = ev_binds,
tcg_th_foreign_files = th_foreign_files_var,
tcg_fords = fords,
tcg_rules = rules,
tcg_patsyns = patsyns,
tcg_tcs = tcs,
tcg_insts = insts,
tcg_fam_insts = fam_insts,
tcg_hpc = other_hpc_info,
tcg_complete_matches = complete_matches
})
= do { let dflags = hsc_dflags hsc_env
print_unqual = mkPrintUnqualified dflags rdr_env
; withTiming dflags
(text "Desugar"<+>brackets (ppr mod))
(const ()) $
do { -- Desugar the program
; let export_set = availsToNameSet exports
target = hscTarget dflags
hpcInfo = emptyHpcInfo other_hpc_info
; (binds_cvr, ds_hpc_info, modBreaks)
<- if not (isHsBootOrSig hsc_src)
then addTicksToBinds hsc_env mod mod_loc
export_set (typeEnvTyCons type_env) binds
else return (binds, hpcInfo, Nothing)
; (msgs, mb_res) <- initDs hsc_env tcg_env $
do { ds_ev_binds <- dsEvBinds ev_binds
; core_prs <- dsTopLHsBinds binds_cvr
; core_prs <- patchMagicDefns core_prs
; (spec_prs, spec_rules) <- dsImpSpecs imp_specs
; (ds_fords, foreign_prs) <- dsForeigns fords
; ds_rules <- mapMaybeM dsRule rules
; let hpc_init
| gopt Opt_Hpc dflags = hpcInitCode mod ds_hpc_info
| otherwise = empty
; return ( ds_ev_binds
, foreign_prs `appOL` core_prs `appOL` spec_prs
, spec_rules ++ ds_rules
, ds_fords `appendStubC` hpc_init) }
; case mb_res of {
Nothing -> return (msgs, Nothing) ;
Just (ds_ev_binds, all_prs, all_rules, ds_fords) ->
do { -- Add export flags to bindings
keep_alive <- readIORef keep_var
; let (rules_for_locals, rules_for_imps) = partition isLocalRule all_rules
final_prs = addExportFlagsAndRules target export_set keep_alive
rules_for_locals (fromOL all_prs)
final_pgm = combineEvBinds ds_ev_binds final_prs
-- Notice that we put the whole lot in a big Rec, even the foreign binds
-- When compiling PrelFloat, which defines data Float = F# Float#
-- we want F# to be in scope in the foreign marshalling code!
-- You might think it doesn't matter, but the simplifier brings all top-level
-- things into the in-scope set before simplifying; so we get no unfolding for F#!
; endPassIO hsc_env print_unqual CoreDesugar final_pgm rules_for_imps
; (ds_binds, ds_rules_for_imps)
<- simpleOptPgm dflags mod final_pgm rules_for_imps
-- The simpleOptPgm gets rid of type
-- bindings plus any stupid dead code
; endPassIO hsc_env print_unqual CoreDesugarOpt ds_binds ds_rules_for_imps
; let used_names = mkUsedNames tcg_env
pluginModules =
map lpModule (cachedPlugins (hsc_dflags hsc_env))
; deps <- mkDependencies (thisInstalledUnitId (hsc_dflags hsc_env))
(map mi_module pluginModules) tcg_env
; used_th <- readIORef tc_splice_used
; dep_files <- readIORef dependent_files
; safe_mode <- finalSafeMode dflags tcg_env
; usages <- mkUsageInfo hsc_env mod (imp_mods imports) used_names
dep_files merged pluginModules
-- id_mod /= mod when we are processing an hsig, but hsigs
-- never desugared and compiled (there's no code!)
-- Consequently, this should hold for any ModGuts that make
-- past desugaring. See Note [Identity versus semantic module].
; MASSERT( id_mod == mod )
; foreign_files <- readIORef th_foreign_files_var
; let (doc_hdr, decl_docs, arg_docs) = extractDocs tcg_env
; let mod_guts = ModGuts {
mg_module = mod,
mg_hsc_src = hsc_src,
mg_loc = mkFileSrcSpan mod_loc,
mg_exports = exports,
mg_usages = usages,
mg_deps = deps,
mg_used_th = used_th,
mg_rdr_env = rdr_env,
mg_fix_env = fix_env,
mg_warns = warns,
mg_anns = anns,
mg_tcs = tcs,
mg_insts = fixSafeInstances safe_mode insts,
mg_fam_insts = fam_insts,
mg_inst_env = inst_env,
mg_fam_inst_env = fam_inst_env,
mg_patsyns = patsyns,
mg_rules = ds_rules_for_imps,
mg_binds = ds_binds,
mg_foreign = ds_fords,
mg_foreign_files = foreign_files,
mg_hpc_info = ds_hpc_info,
mg_modBreaks = modBreaks,
mg_safe_haskell = safe_mode,
mg_trust_pkg = imp_trust_own_pkg imports,
mg_complete_sigs = complete_matches,
mg_doc_hdr = doc_hdr,
mg_decl_docs = decl_docs,
mg_arg_docs = arg_docs
}
; return (msgs, Just mod_guts)
}}}}
mkFileSrcSpan :: ModLocation -> SrcSpan
mkFileSrcSpan mod_loc
= case ml_hs_file mod_loc of
Just file_path -> mkGeneralSrcSpan (mkFastString file_path)
Nothing -> interactiveSrcSpan -- Presumably
dsImpSpecs :: [LTcSpecPrag] -> DsM (OrdList (Id,CoreExpr), [CoreRule])
dsImpSpecs imp_specs
= do { spec_prs <- mapMaybeM (dsSpec Nothing) imp_specs
; let (spec_binds, spec_rules) = unzip spec_prs
; return (concatOL spec_binds, spec_rules) }
combineEvBinds :: [CoreBind] -> [(Id,CoreExpr)] -> [CoreBind]
-- Top-level bindings can include coercion bindings, but not via superclasses
-- See Note [Top-level evidence]
combineEvBinds [] val_prs
= [Rec val_prs]
combineEvBinds (NonRec b r : bs) val_prs
| isId b = combineEvBinds bs ((b,r):val_prs)
| otherwise = NonRec b r : combineEvBinds bs val_prs
combineEvBinds (Rec prs : bs) val_prs
= combineEvBinds bs (prs ++ val_prs)
{-
Note [Top-level evidence]
~~~~~~~~~~~~~~~~~~~~~~~~~
Top-level evidence bindings may be mutually recursive with the top-level value
bindings, so we must put those in a Rec. But we can't put them *all* in a Rec
because the occurrence analyser doesn't take account of type/coercion variables
when computing dependencies.
So we pull out the type/coercion variables (which are in dependency order),
and Rec the rest.
-}
deSugarExpr :: HscEnv -> LHsExpr GhcTc -> IO (Messages, Maybe CoreExpr)
deSugarExpr hsc_env tc_expr = do {
let dflags = hsc_dflags hsc_env
; showPass dflags "Desugar"
-- Do desugaring
; (msgs, mb_core_expr) <- runTcInteractive hsc_env $ initDsTc $
dsLExpr tc_expr
; case mb_core_expr of
Nothing -> return ()
Just expr -> dumpIfSet_dyn dflags Opt_D_dump_ds "Desugared"
FormatCore (pprCoreExpr expr)
; return (msgs, mb_core_expr) }
{-
************************************************************************
* *
* Add rules and export flags to binders
* *
************************************************************************
-}
addExportFlagsAndRules
:: HscTarget -> NameSet -> NameSet -> [CoreRule]
-> [(Id, t)] -> [(Id, t)]
addExportFlagsAndRules target exports keep_alive rules prs
= mapFst add_one prs
where
add_one bndr = add_rules name (add_export name bndr)
where
name = idName bndr
---------- Rules --------
-- See Note [Attach rules to local ids]
-- NB: the binder might have some existing rules,
-- arising from specialisation pragmas
add_rules name bndr
| Just rules <- lookupNameEnv rule_base name
= bndr `addIdSpecialisations` rules
| otherwise
= bndr
rule_base = extendRuleBaseList emptyRuleBase rules
---------- Export flag --------
-- See Note [Adding export flags]
add_export name bndr
| dont_discard name = setIdExported bndr
| otherwise = bndr
dont_discard :: Name -> Bool
dont_discard name = is_exported name
|| name `elemNameSet` keep_alive
-- In interactive mode, we don't want to discard any top-level
-- entities at all (eg. do not inline them away during
-- simplification), and retain them all in the TypeEnv so they are
-- available from the command line.
--
-- isExternalName separates the user-defined top-level names from those
-- introduced by the type checker.
is_exported :: Name -> Bool
is_exported | targetRetainsAllBindings target = isExternalName
| otherwise = (`elemNameSet` exports)
{-
Note [Adding export flags]
~~~~~~~~~~~~~~~~~~~~~~~~~~
Set the no-discard flag if either
a) the Id is exported
b) it's mentioned in the RHS of an orphan rule
c) it's in the keep-alive set
It means that the binding won't be discarded EVEN if the binding
ends up being trivial (v = w) -- the simplifier would usually just
substitute w for v throughout, but we don't apply the substitution to
the rules (maybe we should?), so this substitution would make the rule
bogus.
You might wonder why exported Ids aren't already marked as such;
it's just because the type checker is rather busy already and
I didn't want to pass in yet another mapping.
Note [Attach rules to local ids]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Find the rules for locally-defined Ids; then we can attach them
to the binders in the top-level bindings
Reason
- It makes the rules easier to look up
- It means that transformation rules and specialisations for
locally defined Ids are handled uniformly
- It keeps alive things that are referred to only from a rule
(the occurrence analyser knows about rules attached to Ids)
- It makes sure that, when we apply a rule, the free vars
of the RHS are more likely to be in scope
- The imported rules are carried in the in-scope set
which is extended on each iteration by the new wave of
local binders; any rules which aren't on the binding will
thereby get dropped
************************************************************************
* *
* Desugaring transformation rules
* *
************************************************************************
-}
dsRule :: LRuleDecl GhcTc -> DsM (Maybe CoreRule)
dsRule (L loc (HsRule { rd_name = name
, rd_act = rule_act
, rd_tmvs = vars
, rd_lhs = lhs
, rd_rhs = rhs }))
= putSrcSpanDs loc $
do { let bndrs' = [var | L _ (RuleBndr _ (L _ var)) <- vars]
; lhs' <- unsetGOptM Opt_EnableRewriteRules $
unsetWOptM Opt_WarnIdentities $
dsLExpr lhs -- Note [Desugaring RULE left hand sides]
; rhs' <- dsLExpr rhs
; this_mod <- getModule
; (bndrs'', lhs'', rhs'') <- unfold_coerce bndrs' lhs' rhs'
-- Substitute the dict bindings eagerly,
-- and take the body apart into a (f args) form
; dflags <- getDynFlags
; case decomposeRuleLhs dflags bndrs'' lhs'' of {
Left msg -> do { warnDs NoReason msg; return Nothing } ;
Right (final_bndrs, fn_id, args) -> do
{ let is_local = isLocalId fn_id
-- NB: isLocalId is False of implicit Ids. This is good because
-- we don't want to attach rules to the bindings of implicit Ids,
-- because they don't show up in the bindings until just before code gen
fn_name = idName fn_id
final_rhs = simpleOptExpr dflags rhs'' -- De-crap it
rule_name = snd (unLoc name)
final_bndrs_set = mkVarSet final_bndrs
arg_ids = filterOut (`elemVarSet` final_bndrs_set) $
exprsSomeFreeVarsList isId args
; rule <- dsMkUserRule this_mod is_local
rule_name rule_act fn_name final_bndrs args
final_rhs
; when (wopt Opt_WarnInlineRuleShadowing dflags) $
warnRuleShadowing rule_name rule_act fn_id arg_ids
; return (Just rule)
} } }
dsRule (L _ (XRuleDecl nec)) = noExtCon nec
warnRuleShadowing :: RuleName -> Activation -> Id -> [Id] -> DsM ()
-- See Note [Rules and inlining/other rules]
warnRuleShadowing rule_name rule_act fn_id arg_ids
= do { check False fn_id -- We often have multiple rules for the same Id in a
-- module. Maybe we should check that they don't overlap
-- but currently we don't
; mapM_ (check True) arg_ids }
where
check check_rules_too lhs_id
| isLocalId lhs_id || canUnfold (idUnfolding lhs_id)
-- If imported with no unfolding, no worries
, idInlineActivation lhs_id `competesWith` rule_act
= warnDs (Reason Opt_WarnInlineRuleShadowing)
(vcat [ hang (text "Rule" <+> pprRuleName rule_name
<+> text "may never fire")
2 (text "because" <+> quotes (ppr lhs_id)
<+> text "might inline first")
, text "Probable fix: add an INLINE[n] or NOINLINE[n] pragma for"
<+> quotes (ppr lhs_id)
, whenPprDebug (ppr (idInlineActivation lhs_id) $$ ppr rule_act) ])
| check_rules_too
, bad_rule : _ <- get_bad_rules lhs_id
= warnDs (Reason Opt_WarnInlineRuleShadowing)
(vcat [ hang (text "Rule" <+> pprRuleName rule_name
<+> text "may never fire")
2 (text "because rule" <+> pprRuleName (ruleName bad_rule)
<+> text "for"<+> quotes (ppr lhs_id)
<+> text "might fire first")
, text "Probable fix: add phase [n] or [~n] to the competing rule"
, whenPprDebug (ppr bad_rule) ])
| otherwise
= return ()
get_bad_rules lhs_id
= [ rule | rule <- idCoreRules lhs_id
, ruleActivation rule `competesWith` rule_act ]
-- See Note [Desugaring coerce as cast]
unfold_coerce :: [Id] -> CoreExpr -> CoreExpr -> DsM ([Var], CoreExpr, CoreExpr)
unfold_coerce bndrs lhs rhs = do
(bndrs', wrap) <- go bndrs
return (bndrs', wrap lhs, wrap rhs)
where
go :: [Id] -> DsM ([Id], CoreExpr -> CoreExpr)
go [] = return ([], id)
go (v:vs)
| Just (tc, [k, t1, t2]) <- splitTyConApp_maybe (idType v)
, tc `hasKey` coercibleTyConKey = do
u <- newUnique
let ty' = mkTyConApp eqReprPrimTyCon [k, k, t1, t2]
v' = mkLocalCoVar
(mkDerivedInternalName mkRepEqOcc u (getName v)) ty'
box = Var (dataConWrapId coercibleDataCon) `mkTyApps`
[k, t1, t2] `App`
Coercion (mkCoVarCo v')
(bndrs, wrap) <- go vs
return (v':bndrs, mkCoreLet (NonRec v box) . wrap)
| otherwise = do
(bndrs,wrap) <- go vs
return (v:bndrs, wrap)
{- Note [Desugaring RULE left hand sides]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
For the LHS of a RULE we do *not* want to desugar
[x] to build (\cn. x `c` n)
We want to leave explicit lists simply as chains
of cons's. We can achieve that slightly indirectly by
switching off EnableRewriteRules. See GHC.HsToCore.Expr.dsExplicitList.
That keeps the desugaring of list comprehensions simple too.
Nor do we want to warn of conversion identities on the LHS;
the rule is precisely to optimise them:
{-# RULES "fromRational/id" fromRational = id :: Rational -> Rational #-}
Note [Desugaring coerce as cast]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
We want the user to express a rule saying roughly “mapping a coercion over a
list can be replaced by a coercion”. But the cast operator of Core (▷) cannot
be written in Haskell. So we use `coerce` for that (#2110). The user writes
map coerce = coerce
as a RULE, and this optimizes any kind of mapped' casts away, including `map
MkNewtype`.
For that we replace any forall'ed `c :: Coercible a b` value in a RULE by
corresponding `co :: a ~#R b` and wrap the LHS and the RHS in
`let c = MkCoercible co in ...`. This is later simplified to the desired form
by simpleOptExpr (for the LHS) resp. the simplifiers (for the RHS).
See also Note [Getting the map/coerce RULE to work] in CoreOpt.
Note [Rules and inlining/other rules]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
If you have
f x = ...
g x = ...
{-# RULES "rule-for-f" forall x. f (g x) = ... #-}
then there's a good chance that in a potential rule redex
...f (g e)...
then 'f' or 'g' will inline before the rule can fire. Solution: add an
INLINE [n] or NOINLINE [n] pragma to 'f' and 'g'.
Note that this applies to all the free variables on the LHS, both the
main function and things in its arguments.
We also check if there are Ids on the LHS that have competing RULES.
In the above example, suppose we had
{-# RULES "rule-for-g" forally. g [y] = ... #-}
Then "rule-for-f" and "rule-for-g" would compete. Better to add phase
control, so "rule-for-f" has a chance to fire before "rule-for-g" becomes
active; or perhaps after "rule-for-g" has become inactive. This is checked
by 'competesWith'
Class methods have a built-in RULE to select the method from the dictionary,
so you can't change the phase on this. That makes id very dubious to
match on class methods in RULE lhs's. See #10595. I'm not happy
about this. For example in Control.Arrow we have
{-# RULES "compose/arr" forall f g .
(arr f) . (arr g) = arr (f . g) #-}
and similar, which will elicit exactly these warnings, and risk never
firing. But it's not clear what to do instead. We could make the
class method rules inactive in phase 2, but that would delay when
subsequent transformations could fire.
-}
{-
************************************************************************
* *
* Magic definitions
* *
************************************************************************
Note [Patching magic definitions]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
We sometimes need to have access to defined Ids in pure contexts. Usually, we
simply "wire in" these entities, as we do for types in TysWiredIn and for Ids
in MkId. See Note [Wired-in Ids] in MkId.
However, it is sometimes *much* easier to define entities in Haskell,
even if we need pure access; note that wiring-in an Id requires all
entities used in its definition *also* to be wired in, transitively
and recursively. This can be a huge pain. The little trick
documented here allows us to have the best of both worlds.
Motivating example: unsafeCoerce#. See [Wiring in unsafeCoerce#] for the
details.
The trick is to
* Define the known-key Id in a library module, with a stub definition,
unsafeCoerce# :: ..a suitable type signature..
unsafeCoerce# = error "urk"
* Magically over-write its RHS here in the desugarer, in
patchMagicDefns. This update can be done with full access to the
DsM monad, and hence, dsLookupGlobal. We thus do not have to wire in
all the entities used internally, a potentially big win.
This step should not change the Name or type of the Id.
Because an Id stores its unfolding directly (as opposed to in the second
component of a (Id, CoreExpr) pair), the patchMagicDefns function returns
a new Id to use.
Here are the moving parts:
- patchMagicDefns checks whether we're in a module with magic definitions;
if so, patch the magic definitions. If not, skip.
- patchMagicDefn just looks up in an environment to find a magic defn and
patches it in.
- magicDefns holds the magic definitions.
- magicDefnsEnv allows for quick access to magicDefns.
- magicDefnModules, built also from magicDefns, contains the modules that
need careful attention.
Note [Wiring in unsafeCoerce#]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
We want (Haskell)
unsafeCoerce# :: forall (r1 :: RuntimeRep) (r2 :: RuntimeRep)
(a :: TYPE r1) (b :: TYPE r2).
a -> b
unsafeCoerce# x = case unsafeEqualityProof @r1 @r2 of
UnsafeRefl -> case unsafeEqualityProof @a @b of
UnsafeRefl -> x
or (Core)
unsafeCoerce# :: forall (r1 :: RuntimeRep) (r2 :: RuntimeRep)
(a :: TYPE r1) (b :: TYPE r2).
a -> b
unsafeCoerce# = \ @r1 @r2 @a @b (x :: a).
case unsafeEqualityProof @RuntimeRep @r1 @r2 of
UnsafeRefl (co1 :: r1 ~# r2) ->
case unsafeEqualityProof @(TYPE r2) @(a |> TYPE co1) @b of
UnsafeRefl (co2 :: (a |> TYPE co1) ~# b) ->
(x |> (GRefl :: a ~# (a |> TYPE co1)) ; co2)
It looks like we can write this in Haskell directly, but we can't:
the levity polymorphism checks defeat us. Note that `x` is a levity-
polymorphic variable. So we must wire it in with a compulsory
unfolding, like other levity-polymorphic primops.
The challenge is that UnsafeEquality is a GADT, and wiring in a GADT
is *hard*: it has a worker separate from its wrapper, with all manner
of complications. (Simon and Richard tried to do this. We nearly wept.)
The solution is documented in Note [Patching magic definitions]. We now
simply look up the UnsafeEquality GADT in the environment, leaving us
only to wire in unsafeCoerce# directly.
Wrinkle:
--------
We must make absolutely sure that unsafeCoerce# is inlined. You might
think that giving it a compulsory unfolding is enough. However,
unsafeCoerce# is put in an interface file like any other definition.
At optimization level 0, we enable -fignore-interface-pragmas, which
ignores pragmas in interface files. We thus must check to see whether
there is a compulsory unfolding, even with -fignore-interface-pragmas.
This is done in TcIface.tcIdInfo.
Test case: ghci/linker/dyn/T3372
-}
-- Postcondition: the returned Ids are in one-to-one correspondence as the
-- input Ids; each returned Id has the same type as the passed-in Id.
-- See Note [Patching magic definitions]
patchMagicDefns :: OrdList (Id,CoreExpr)
-> DsM (OrdList (Id,CoreExpr))
patchMagicDefns pairs
-- optimization: check whether we're in a magic module before looking
-- at all the ids
= do { this_mod <- getModule
; if this_mod `elemModuleSet` magicDefnModules
then traverse patchMagicDefn pairs
else return pairs }
patchMagicDefn :: (Id, CoreExpr) -> DsM (Id, CoreExpr)
patchMagicDefn orig_pair@(orig_id, orig_rhs)
| Just mk_magic_pair <- lookupNameEnv magicDefnsEnv (getName orig_id)
= do { magic_pair@(magic_id, _) <- mk_magic_pair orig_id orig_rhs
-- Patching should not change the Name or the type of the Id
; MASSERT( getUnique magic_id == getUnique orig_id )
; MASSERT( varType magic_id `eqType` varType orig_id )
; return magic_pair }
| otherwise
= return orig_pair
magicDefns :: [(Name, Id -> CoreExpr -- old Id and RHS
-> DsM (Id, CoreExpr) -- new Id and RHS
)]
magicDefns = [ (unsafeCoercePrimName, mkUnsafeCoercePrimPair) ]
magicDefnsEnv :: NameEnv (Id -> CoreExpr -> DsM (Id, CoreExpr))
magicDefnsEnv = mkNameEnv magicDefns
magicDefnModules :: ModuleSet
magicDefnModules = mkModuleSet $ map (nameModule . getName . fst) magicDefns
mkUnsafeCoercePrimPair :: Id -> CoreExpr -> DsM (Id, CoreExpr)
-- See Note [Wiring in unsafeCoerce#] for the defn we are creating here
mkUnsafeCoercePrimPair _old_id old_expr
= do { unsafe_equality_proof_id <- dsLookupGlobalId unsafeEqualityProofName
; unsafe_equality_tc <- dsLookupTyCon unsafeEqualityTyConName
; let [unsafe_refl_data_con] = tyConDataCons unsafe_equality_tc
rhs = mkLams [ runtimeRep1TyVar, runtimeRep2TyVar
, openAlphaTyVar, openBetaTyVar
, x ] $
mkSingleAltCase scrut1
(mkWildValBinder scrut1_ty)
(DataAlt unsafe_refl_data_con)
[rr_cv] $
mkSingleAltCase scrut2
(mkWildValBinder scrut2_ty)
(DataAlt unsafe_refl_data_con)
[ab_cv] $
Var x `mkCast` x_co
[x, rr_cv, ab_cv] = mkTemplateLocals
[ openAlphaTy -- x :: a
, rr_cv_ty -- rr_cv :: r1 ~# r2
, ab_cv_ty -- ab_cv :: (alpha |> alpha_co ~# beta)
]
-- Returns (scrutinee, scrutinee type, type of covar in AltCon)
unsafe_equality k a b
= ( mkTyApps (Var unsafe_equality_proof_id) [k,b,a]
, mkTyConApp unsafe_equality_tc [k,b,a]
, mkHeteroPrimEqPred k k a b
)
-- NB: UnsafeRefl :: (b ~# a) -> UnsafeEquality a b, so we have to
-- carefully swap the arguments above
(scrut1, scrut1_ty, rr_cv_ty) = unsafe_equality runtimeRepTy
runtimeRep1Ty
runtimeRep2Ty
(scrut2, scrut2_ty, ab_cv_ty) = unsafe_equality (tYPE runtimeRep2Ty)
(openAlphaTy `mkCastTy` alpha_co)
openBetaTy
-- alpha_co :: TYPE r1 ~# TYPE r2
-- alpha_co = TYPE rr_cv
alpha_co = mkTyConAppCo Nominal tYPETyCon [mkCoVarCo rr_cv]
-- x_co :: alpha ~R# beta
x_co = mkGReflCo Representational openAlphaTy (MCo alpha_co) `mkTransCo`
mkSubCo (mkCoVarCo ab_cv)
info = noCafIdInfo `setInlinePragInfo` alwaysInlinePragma
`setUnfoldingInfo` mkCompulsoryUnfolding rhs
ty = mkSpecForAllTys [ runtimeRep1TyVar, runtimeRep2TyVar
, openAlphaTyVar, openBetaTyVar ] $
mkVisFunTy openAlphaTy openBetaTy
id = mkExportedVanillaId unsafeCoercePrimName ty `setIdInfo` info
; return (id, old_expr) }
where
|