% % (c) The GRASP/AQUA Project, Glasgow University, 1992-1998 % \section[StgSyn]{Shared term graph (STG) syntax for spineless-tagless code generation} This data type represents programs just before code generation (conversion to @Cmm@): basically, what we have is a stylised form of @CoreSyntax@, the style being one that happens to be ideally suited to spineless tagless code generation. \begin{code} module StgSyn ( GenStgArg(..), GenStgLiveVars, GenStgBinding(..), GenStgExpr(..), GenStgRhs(..), GenStgAlt, AltType(..), UpdateFlag(..), isUpdatable, StgBinderInfo, noBinderInfo, stgSatOcc, stgUnsatOcc, satCallsOnly, combineStgBinderInfo, -- a set of synonyms for the most common (only :-) parameterisation StgArg, StgLiveVars, StgBinding, StgExpr, StgRhs, StgAlt, -- StgOp StgOp(..), -- SRTs SRT(..), -- utils stgBindHasCafRefs, stgArgHasCafRefs, stgRhsArity, isDllConApp, stgArgType, pprStgBinding, pprStgBindings, pprStgLVs ) where #include "HsVersions.h" import Bitmap import CoreSyn ( AltCon ) import CostCentre ( CostCentreStack, CostCentre ) import DataCon import DynFlags import FastString import ForeignCall ( ForeignCall ) import Id import IdInfo ( mayHaveCafRefs ) import Literal ( Literal, literalType ) import Module import Outputable import Packages ( isDllName ) import Platform import PprCore ( {- instances -} ) import PrimOp ( PrimOp, PrimCall ) import TyCon ( PrimRep(..) ) import TyCon ( TyCon ) import Type ( Type ) import Type ( typePrimRep ) import UniqSet import Unique ( Unique ) import Util import VarSet ( IdSet, isEmptyVarSet ) \end{code} %************************************************************************ %* * \subsection{@GenStgBinding@} %* * %************************************************************************ As usual, expressions are interesting; other things are boring. Here are the boring things [except note the @GenStgRhs@], parameterised with respect to binder and occurrence information (just as in @CoreSyn@): There is one SRT for each group of bindings. \begin{code} data GenStgBinding bndr occ = StgNonRec bndr (GenStgRhs bndr occ) | StgRec [(bndr, GenStgRhs bndr occ)] \end{code} %************************************************************************ %* * \subsection{@GenStgArg@} %* * %************************************************************************ \begin{code} data GenStgArg occ = StgVarArg occ | StgLitArg Literal -- | Does this constructor application refer to -- anything in a different *Windows* DLL? -- If so, we can't allocate it statically isDllConApp :: DynFlags -> Module -> DataCon -> [StgArg] -> Bool isDllConApp dflags this_mod con args | platformOS (targetPlatform dflags) == OSMinGW32 = isDllName dflags this_pkg this_mod (dataConName con) || any is_dll_arg args | otherwise = False where -- NB: typePrimRep is legit because any free variables won't have -- unlifted type (there are no unlifted things at top level) is_dll_arg :: StgArg -> Bool is_dll_arg (StgVarArg v) = isAddrRep (typePrimRep (idType v)) && isDllName dflags this_pkg this_mod (idName v) is_dll_arg _ = False this_pkg = thisPackage dflags -- True of machine addresses; these are the things that don't -- work across DLLs. The key point here is that VoidRep comes -- out False, so that a top level nullary GADT constructor is -- False for isDllConApp -- data T a where -- T1 :: T Int -- gives -- T1 :: forall a. (a~Int) -> T a -- and hence the top-level binding -- $WT1 :: T Int -- $WT1 = T1 Int (Coercion (Refl Int)) -- The coercion argument here gets VoidRep isAddrRep :: PrimRep -> Bool isAddrRep AddrRep = True isAddrRep PtrRep = True isAddrRep _ = False -- | Type of an @StgArg@ -- -- Very half baked becase we have lost the type arguments. stgArgType :: StgArg -> Type stgArgType (StgVarArg v) = idType v stgArgType (StgLitArg lit) = literalType lit \end{code} %************************************************************************ %* * \subsection{STG expressions} %* * %************************************************************************ The @GenStgExpr@ data type is parameterised on binder and occurrence info, as before. %************************************************************************ %* * \subsubsection{@GenStgExpr@ application} %* * %************************************************************************ An application is of a function to a list of atoms [not expressions]. Operationally, we want to push the arguments on the stack and call the function. (If the arguments were expressions, we would have to build their closures first.) There is no constructor for a lone variable; it would appear as @StgApp var [] _@. \begin{code} type GenStgLiveVars occ = UniqSet occ data GenStgExpr bndr occ = StgApp occ -- function [GenStgArg occ] -- arguments; may be empty \end{code} %************************************************************************ %* * \subsubsection{@StgConApp@ and @StgPrimApp@---saturated applications} %* * %************************************************************************ There are a specialised forms of application, for constructors, primitives, and literals. \begin{code} | StgLit Literal -- StgConApp is vital for returning unboxed tuples -- which can't be let-bound first | StgConApp DataCon [GenStgArg occ] -- Saturated | StgOpApp StgOp -- Primitive op or foreign call [GenStgArg occ] -- Saturated Type -- Result type -- We need to know this so that we can -- assign result registers \end{code} %************************************************************************ %* * \subsubsection{@StgLam@} %* * %************************************************************************ StgLam is used *only* during CoreToStg's work. Before CoreToStg has finished it encodes (\x -> e) as (let f = \x -> e in f) \begin{code} | StgLam [bndr] StgExpr -- Body of lambda \end{code} %************************************************************************ %* * \subsubsection{@GenStgExpr@: case-expressions} %* * %************************************************************************ This has the same boxed/unboxed business as Core case expressions. \begin{code} | StgCase (GenStgExpr bndr occ) -- the thing to examine (GenStgLiveVars occ) -- Live vars of whole case expression, -- plus everything that happens after the case -- i.e., those which mustn't be overwritten (GenStgLiveVars occ) -- Live vars of RHSs (plus what happens afterwards) -- i.e., those which must be saved before eval. -- -- note that an alt's constructor's -- binder-variables are NOT counted in the -- free vars for the alt's RHS bndr -- binds the result of evaluating the scrutinee SRT -- The SRT for the continuation AltType [GenStgAlt bndr occ] -- The DEFAULT case is always *first* -- if it is there at all \end{code} %************************************************************************ %* * \subsubsection{@GenStgExpr@: @let(rec)@-expressions} %* * %************************************************************************ The various forms of let(rec)-expression encode most of the interesting things we want to do. \begin{enumerate} \item \begin{verbatim} let-closure x = [free-vars] [args] expr in e \end{verbatim} is equivalent to \begin{verbatim} let x = (\free-vars -> \args -> expr) free-vars \end{verbatim} \tr{args} may be empty (and is for most closures). It isn't under circumstances like this: \begin{verbatim} let x = (\y -> y+z) \end{verbatim} This gets mangled to \begin{verbatim} let-closure x = [z] [y] (y+z) \end{verbatim} The idea is that we compile code for @(y+z)@ in an environment in which @z@ is bound to an offset from \tr{Node}, and @y@ is bound to an offset from the stack pointer. (A let-closure is an @StgLet@ with a @StgRhsClosure@ RHS.) \item \begin{verbatim} let-constructor x = Constructor [args] in e \end{verbatim} (A let-constructor is an @StgLet@ with a @StgRhsCon@ RHS.) \item Letrec-expressions are essentially the same deal as let-closure/let-constructor, so we use a common structure and distinguish between them with an @is_recursive@ boolean flag. \item \begin{verbatim} let-unboxed u = an arbitrary arithmetic expression in unboxed values in e \end{verbatim} All the stuff on the RHS must be fully evaluated. No function calls either! (We've backed away from this toward case-expressions with suitably-magical alts ...) \item ~[Advanced stuff here! Not to start with, but makes pattern matching generate more efficient code.] \begin{verbatim} let-escapes-not fail = expr in e' \end{verbatim} Here the idea is that @e'@ guarantees not to put @fail@ in a data structure, or pass it to another function. All @e'@ will ever do is tail-call @fail@. Rather than build a closure for @fail@, all we need do is to record the stack level at the moment of the @let-escapes-not@; then entering @fail@ is just a matter of adjusting the stack pointer back down to that point and entering the code for it. Another example: \begin{verbatim} f x y = let z = huge-expression in if y==1 then z else if y==2 then z else 1 \end{verbatim} (A let-escapes-not is an @StgLetNoEscape@.) \item We may eventually want: \begin{verbatim} let-literal x = Literal in e \end{verbatim} \end{enumerate} And so the code for let(rec)-things: \begin{code} | StgLet (GenStgBinding bndr occ) -- right hand sides (see below) (GenStgExpr bndr occ) -- body | StgLetNoEscape -- remember: ``advanced stuff'' (GenStgLiveVars occ) -- Live in the whole let-expression -- Mustn't overwrite these stack slots -- _Doesn't_ include binders of the let(rec). (GenStgLiveVars occ) -- Live in the right hand sides (only) -- These are the ones which must be saved on -- the stack if they aren't there already -- _Does_ include binders of the let(rec) if recursive. (GenStgBinding bndr occ) -- right hand sides (see below) (GenStgExpr bndr occ) -- body \end{code} %************************************************************************ %* * \subsubsection{@GenStgExpr@: @scc@ expressions} %* * %************************************************************************ For @scc@ expressions we introduce a new STG construct. \begin{code} | StgSCC CostCentre -- label of SCC expression !Bool -- bump the entry count? !Bool -- push the cost centre? (GenStgExpr bndr occ) -- scc expression \end{code} %************************************************************************ %* * \subsubsection{@GenStgExpr@: @hpc@ expressions} %* * %************************************************************************ Finally for @hpc@ expressions we introduce a new STG construct. \begin{code} | StgTick Module -- the module of the source of this tick Int -- tick number (GenStgExpr bndr occ) -- sub expression -- END of GenStgExpr \end{code} %************************************************************************ %* * \subsection{STG right-hand sides} %* * %************************************************************************ Here's the rest of the interesting stuff for @StgLet@s; the first flavour is for closures: \begin{code} data GenStgRhs bndr occ = StgRhsClosure CostCentreStack -- CCS to be attached (default is CurrentCCS) StgBinderInfo -- Info about how this binder is used (see below) [occ] -- non-global free vars; a list, rather than -- a set, because order is important !UpdateFlag -- ReEntrant | Updatable | SingleEntry SRT -- The SRT reference [bndr] -- arguments; if empty, then not a function; -- as above, order is important. (GenStgExpr bndr occ) -- body \end{code} An example may be in order. Consider: \begin{verbatim} let t = \x -> \y -> ... x ... y ... p ... q in e \end{verbatim} Pulling out the free vars and stylising somewhat, we get the equivalent: \begin{verbatim} let t = (\[p,q] -> \[x,y] -> ... x ... y ... p ...q) p q \end{verbatim} Stg-operationally, the @[x,y]@ are on the stack, the @[p,q]@ are offsets from @Node@ into the closure, and the code ptr for the closure will be exactly that in parentheses above. The second flavour of right-hand-side is for constructors (simple but important): \begin{code} | StgRhsCon CostCentreStack -- CCS to be attached (default is CurrentCCS). -- Top-level (static) ones will end up with -- DontCareCCS, because we don't count static -- data in heap profiles, and we don't set CCCS -- from static closure. DataCon -- constructor [GenStgArg occ] -- args stgRhsArity :: StgRhs -> Int stgRhsArity (StgRhsClosure _ _ _ _ _ bndrs _) = ASSERT( all isId bndrs ) length bndrs -- The arity never includes type parameters, but they should have gone by now stgRhsArity (StgRhsCon _ _ _) = 0 stgBindHasCafRefs :: GenStgBinding bndr Id -> Bool stgBindHasCafRefs (StgNonRec _ rhs) = rhsHasCafRefs rhs stgBindHasCafRefs (StgRec binds) = any rhsHasCafRefs (map snd binds) rhsHasCafRefs :: GenStgRhs bndr Id -> Bool rhsHasCafRefs (StgRhsClosure _ _ _ upd srt _ _) = isUpdatable upd || nonEmptySRT srt rhsHasCafRefs (StgRhsCon _ _ args) = any stgArgHasCafRefs args stgArgHasCafRefs :: GenStgArg Id -> Bool stgArgHasCafRefs (StgVarArg id) = mayHaveCafRefs (idCafInfo id) stgArgHasCafRefs _ = False \end{code} Here's the @StgBinderInfo@ type, and its combining op: \begin{code} data StgBinderInfo = NoStgBinderInfo | SatCallsOnly -- All occurrences are *saturated* *function* calls -- This means we don't need to build an info table and -- slow entry code for the thing -- Thunks never get this value noBinderInfo, stgUnsatOcc, stgSatOcc :: StgBinderInfo noBinderInfo = NoStgBinderInfo stgUnsatOcc = NoStgBinderInfo stgSatOcc = SatCallsOnly satCallsOnly :: StgBinderInfo -> Bool satCallsOnly SatCallsOnly = True satCallsOnly NoStgBinderInfo = False combineStgBinderInfo :: StgBinderInfo -> StgBinderInfo -> StgBinderInfo combineStgBinderInfo SatCallsOnly SatCallsOnly = SatCallsOnly combineStgBinderInfo _ _ = NoStgBinderInfo -------------- pp_binder_info :: StgBinderInfo -> SDoc pp_binder_info NoStgBinderInfo = empty pp_binder_info SatCallsOnly = ptext (sLit "sat-only") \end{code} %************************************************************************ %* * \subsection[Stg-case-alternatives]{STG case alternatives} %* * %************************************************************************ Very like in @CoreSyntax@ (except no type-world stuff). The type constructor is guaranteed not to be abstract; that is, we can see its representation. This is important because the code generator uses it to determine return conventions etc. But it's not trivial where there's a moduule loop involved, because some versions of a type constructor might not have all the constructors visible. So mkStgAlgAlts (in CoreToStg) ensures that it gets the TyCon from the constructors or literals (which are guaranteed to have the Real McCoy) rather than from the scrutinee type. \begin{code} type GenStgAlt bndr occ = (AltCon, -- alts: data constructor, [bndr], -- constructor's parameters, [Bool], -- "use mask", same length as -- parameters; a True in a -- param's position if it is -- used in the ... GenStgExpr bndr occ) -- ...right-hand side. data AltType = PolyAlt -- Polymorphic (a type variable) | UbxTupAlt Int -- Unboxed tuple of this arity | AlgAlt TyCon -- Algebraic data type; the AltCons will be DataAlts | PrimAlt TyCon -- Primitive data type; the AltCons will be LitAlts \end{code} %************************************************************************ %* * \subsection[Stg]{The Plain STG parameterisation} %* * %************************************************************************ This happens to be the only one we use at the moment. \begin{code} type StgBinding = GenStgBinding Id Id type StgArg = GenStgArg Id type StgLiveVars = GenStgLiveVars Id type StgExpr = GenStgExpr Id Id type StgRhs = GenStgRhs Id Id type StgAlt = GenStgAlt Id Id \end{code} %************************************************************************ %* * \subsubsection[UpdateFlag-datatype]{@UpdateFlag@} %* * %************************************************************************ This is also used in @LambdaFormInfo@ in the @ClosureInfo@ module. A @ReEntrant@ closure may be entered multiple times, but should not be updated or blackholed. An @Updatable@ closure should be updated after evaluation (and may be blackholed during evaluation). A @SingleEntry@ closure will only be entered once, and so need not be updated but may safely be blackholed. \begin{code} data UpdateFlag = ReEntrant | Updatable | SingleEntry instance Outputable UpdateFlag where ppr u = char $ case u of ReEntrant -> 'r' Updatable -> 'u' SingleEntry -> 's' isUpdatable :: UpdateFlag -> Bool isUpdatable ReEntrant = False isUpdatable SingleEntry = False isUpdatable Updatable = True \end{code} %************************************************************************ %* * \subsubsection{StgOp} %* * %************************************************************************ An StgOp allows us to group together PrimOps and ForeignCalls. It's quite useful to move these around together, notably in StgOpApp and COpStmt. \begin{code} data StgOp = StgPrimOp PrimOp | StgPrimCallOp PrimCall | StgFCallOp ForeignCall Unique -- The Unique is occasionally needed by the C pretty-printer -- (which lacks a unique supply), notably when generating a -- typedef for foreign-export-dynamic \end{code} %************************************************************************ %* * \subsubsection[Static Reference Tables]{@SRT@} %* * %************************************************************************ There is one SRT per top-level function group. Each local binding and case expression within this binding group has a subrange of the whole SRT, expressed as an offset and length. In CoreToStg we collect the list of CafRefs at each SRT site, which is later converted into the length and offset form by the SRT pass. \begin{code} data SRT = NoSRT | SRTEntries IdSet -- generated by CoreToStg | SRT !Int{-offset-} !Int{-length-} !Bitmap{-bitmap-} -- generated by computeSRTs nonEmptySRT :: SRT -> Bool nonEmptySRT NoSRT = False nonEmptySRT (SRTEntries vs) = not (isEmptyVarSet vs) nonEmptySRT _ = True pprSRT :: SRT -> SDoc pprSRT (NoSRT) = ptext (sLit "_no_srt_") pprSRT (SRTEntries ids) = text "SRT:" <> ppr ids pprSRT (SRT off _ _) = parens (ppr off <> comma <> text "*bitmap*") \end{code} %************************************************************************ %* * \subsection[Stg-pretty-printing]{Pretty-printing} %* * %************************************************************************ Robin Popplestone asked for semi-colon separators on STG binds; here's hoping he likes terminators instead... Ditto for case alternatives. \begin{code} pprGenStgBinding :: (OutputableBndr bndr, Outputable bdee, Ord bdee) => GenStgBinding bndr bdee -> SDoc pprGenStgBinding (StgNonRec bndr rhs) = hang (hsep [pprBndr LetBind bndr, equals]) 4 (ppr rhs <> semi) pprGenStgBinding (StgRec pairs) = vcat $ ifPprDebug (ptext $ sLit "{- StgRec (begin) -}") : map (ppr_bind) pairs ++ [ifPprDebug $ ptext $ sLit "{- StgRec (end) -}"] where ppr_bind (bndr, expr) = hang (hsep [pprBndr LetBind bndr, equals]) 4 (ppr expr <> semi) pprStgBinding :: StgBinding -> SDoc pprStgBinding bind = pprGenStgBinding bind pprStgBindings :: [StgBinding] -> SDoc pprStgBindings binds = vcat (map pprGenStgBinding binds) instance (Outputable bdee) => Outputable (GenStgArg bdee) where ppr = pprStgArg instance (OutputableBndr bndr, Outputable bdee, Ord bdee) => Outputable (GenStgBinding bndr bdee) where ppr = pprGenStgBinding instance (OutputableBndr bndr, Outputable bdee, Ord bdee) => Outputable (GenStgExpr bndr bdee) where ppr = pprStgExpr instance (OutputableBndr bndr, Outputable bdee, Ord bdee) => Outputable (GenStgRhs bndr bdee) where ppr rhs = pprStgRhs rhs pprStgArg :: (Outputable bdee) => GenStgArg bdee -> SDoc pprStgArg (StgVarArg var) = ppr var pprStgArg (StgLitArg con) = ppr con pprStgExpr :: (OutputableBndr bndr, Outputable bdee, Ord bdee) => GenStgExpr bndr bdee -> SDoc -- special case pprStgExpr (StgLit lit) = ppr lit -- general case pprStgExpr (StgApp func args) = hang (ppr func) 4 (sep (map (ppr) args)) pprStgExpr (StgConApp con args) = hsep [ ppr con, brackets (interppSP args)] pprStgExpr (StgOpApp op args _) = hsep [ pprStgOp op, brackets (interppSP args)] pprStgExpr (StgLam bndrs body) = sep [ char '\\' <+> ppr_list (map (pprBndr LambdaBind) bndrs) <+> ptext (sLit "->"), pprStgExpr body ] where ppr_list = brackets . fsep . punctuate comma -- special case: let v = -- in -- let ... -- in -- ... -- -- Very special! Suspicious! (SLPJ) {- pprStgExpr (StgLet srt (StgNonRec bndr (StgRhsClosure cc bi free_vars upd_flag args rhs)) expr@(StgLet _ _)) = ($$) (hang (hcat [ptext (sLit "let { "), ppr bndr, ptext (sLit " = "), ppr cc, pp_binder_info bi, ptext (sLit " ["), ifPprDebug (interppSP free_vars), ptext (sLit "] \\"), ppr upd_flag, ptext (sLit " ["), interppSP args, char ']']) 8 (sep [hsep [ppr rhs, ptext (sLit "} in")]])) (ppr expr) -} -- special case: let ... in let ... pprStgExpr (StgLet bind expr@(StgLet _ _)) = ($$) (sep [hang (ptext (sLit "let {")) 2 (hsep [pprGenStgBinding bind, ptext (sLit "} in")])]) (ppr expr) -- general case pprStgExpr (StgLet bind expr) = sep [hang (ptext (sLit "let {")) 2 (pprGenStgBinding bind), hang (ptext (sLit "} in ")) 2 (ppr expr)] pprStgExpr (StgLetNoEscape lvs_whole lvs_rhss bind expr) = sep [hang (ptext (sLit "let-no-escape {")) 2 (pprGenStgBinding bind), hang (ptext (sLit "} in ") <> ifPprDebug ( nest 4 ( hcat [ptext (sLit "-- lvs: ["), interppSP (uniqSetToList lvs_whole), ptext (sLit "]; rhs lvs: ["), interppSP (uniqSetToList lvs_rhss), char ']']))) 2 (ppr expr)] pprStgExpr (StgSCC cc tick push expr) = sep [ hsep [scc, ppr cc], pprStgExpr expr ] where scc | tick && push = ptext (sLit "_scc_") | tick = ptext (sLit "_tick_") | otherwise = ptext (sLit "_push_") pprStgExpr (StgTick m n expr) = sep [ hsep [ptext (sLit "_tick_"), pprModule m,text (show n)], pprStgExpr expr ] pprStgExpr (StgCase expr lvs_whole lvs_rhss bndr srt alt_type alts) = sep [sep [ptext (sLit "case"), nest 4 (hsep [pprStgExpr expr, ifPprDebug (dcolon <+> ppr alt_type)]), ptext (sLit "of"), pprBndr CaseBind bndr, char '{'], ifPprDebug ( nest 4 ( hcat [ptext (sLit "-- lvs: ["), interppSP (uniqSetToList lvs_whole), ptext (sLit "]; rhs lvs: ["), interppSP (uniqSetToList lvs_rhss), ptext (sLit "]; "), pprMaybeSRT srt])), nest 2 (vcat (map pprStgAlt alts)), char '}'] pprStgAlt :: (OutputableBndr bndr, Outputable occ, Ord occ) => GenStgAlt bndr occ -> SDoc pprStgAlt (con, params, _use_mask, expr) = hang (hsep [ppr con, sep (map (pprBndr CaseBind) params), ptext (sLit "->")]) 4 (ppr expr <> semi) pprStgOp :: StgOp -> SDoc pprStgOp (StgPrimOp op) = ppr op pprStgOp (StgPrimCallOp op)= ppr op pprStgOp (StgFCallOp op _) = ppr op instance Outputable AltType where ppr PolyAlt = ptext (sLit "Polymorphic") ppr (UbxTupAlt n) = ptext (sLit "UbxTup") <+> ppr n ppr (AlgAlt tc) = ptext (sLit "Alg") <+> ppr tc ppr (PrimAlt tc) = ptext (sLit "Prim") <+> ppr tc pprStgLVs :: Outputable occ => GenStgLiveVars occ -> SDoc pprStgLVs lvs = getPprStyle $ \ sty -> if userStyle sty || isEmptyUniqSet lvs then empty else hcat [text "{-lvs:", interpp'SP (uniqSetToList lvs), text "-}"] pprStgRhs :: (OutputableBndr bndr, Outputable bdee, Ord bdee) => GenStgRhs bndr bdee -> SDoc -- special case pprStgRhs (StgRhsClosure cc bi [free_var] upd_flag srt [{-no args-}] (StgApp func [])) = hcat [ ppr cc, pp_binder_info bi, brackets (ifPprDebug (ppr free_var)), ptext (sLit " \\"), ppr upd_flag, pprMaybeSRT srt, ptext (sLit " [] "), ppr func ] -- general case pprStgRhs (StgRhsClosure cc bi free_vars upd_flag srt args body) = sdocWithDynFlags $ \dflags -> hang (hsep [if gopt Opt_SccProfilingOn dflags then ppr cc else empty, pp_binder_info bi, ifPprDebug (brackets (interppSP free_vars)), char '\\' <> ppr upd_flag, pprMaybeSRT srt, brackets (interppSP args)]) 4 (ppr body) pprStgRhs (StgRhsCon cc con args) = hcat [ ppr cc, space, ppr con, ptext (sLit "! "), brackets (interppSP args)] pprMaybeSRT :: SRT -> SDoc pprMaybeSRT (NoSRT) = empty pprMaybeSRT srt = ptext (sLit "srt:") <> pprSRT srt \end{code}