{-# LANGUAGE Safe #-} -- | -- Language.Haskell.TH.Lib contains lots of useful helper functions for -- generating and manipulating Template Haskell terms -- Note: this module mostly re-exports functions from -- Language.Haskell.TH.Lib.Internal, but if a change occurs to Template -- Haskell which requires breaking the API offered in this module, we opt to -- copy the old definition here, and make the changes in -- Language.Haskell.TH.Lib.Internal. This way, we can retain backwards -- compatibility while still allowing GHC to make changes as it needs. module Language.Haskell.TH.Lib ( -- All of the exports from this module should -- be "public" functions. The main module TH -- re-exports them all. -- * Library functions -- ** Abbreviations InfoQ, ExpQ, TExpQ, CodeQ, DecQ, DecsQ, ConQ, TypeQ, KindQ, TyLitQ, CxtQ, PredQ, DerivClauseQ, MatchQ, ClauseQ, BodyQ, GuardQ, StmtQ, RangeQ, SourceStrictnessQ, SourceUnpackednessQ, BangQ, BangTypeQ, VarBangTypeQ, StrictTypeQ, VarStrictTypeQ, FieldExpQ, PatQ, FieldPatQ, RuleBndrQ, TySynEqnQ, PatSynDirQ, PatSynArgsQ, FamilyResultSigQ, DerivStrategyQ, TyVarBndrUnit, TyVarBndrSpec, -- ** Constructors lifted to 'Q' -- *** Literals intPrimL, wordPrimL, floatPrimL, doublePrimL, integerL, rationalL, charL, stringL, stringPrimL, charPrimL, bytesPrimL, mkBytes, -- *** Patterns litP, varP, tupP, unboxedTupP, unboxedSumP, conP, uInfixP, parensP, infixP, tildeP, bangP, asP, wildP, recP, listP, sigP, viewP, fieldPat, -- *** Pattern Guards normalB, guardedB, normalG, normalGE, patG, patGE, match, clause, -- *** Expressions dyn, varE, unboundVarE, labelE, implicitParamVarE, conE, litE, staticE, appE, appTypeE, uInfixE, parensE, infixE, infixApp, sectionL, sectionR, lamE, lam1E, lamCaseE, tupE, unboxedTupE, unboxedSumE, condE, multiIfE, letE, caseE, appsE, listE, sigE, recConE, recUpdE, stringE, fieldExp, getFieldE, projectionE, -- **** Ranges fromE, fromThenE, fromToE, fromThenToE, -- ***** Ranges with more indirection arithSeqE, fromR, fromThenR, fromToR, fromThenToR, -- **** Statements doE, mdoE, compE, bindS, letS, noBindS, parS, recS, -- *** Types forallT, forallVisT, varT, conT, appT, appKindT, arrowT, infixT, mulArrowT, uInfixT, parensT, equalityT, listT, tupleT, unboxedTupleT, unboxedSumT, sigT, litT, wildCardT, promotedT, promotedTupleT, promotedNilT, promotedConsT, implicitParamT, -- **** Type literals numTyLit, strTyLit, charTyLit, -- **** Strictness noSourceUnpackedness, sourceNoUnpack, sourceUnpack, noSourceStrictness, sourceLazy, sourceStrict, isStrict, notStrict, unpacked, bang, bangType, varBangType, strictType, varStrictType, -- **** Class Contexts cxt, classP, equalP, -- **** Constructors normalC, recC, infixC, forallC, gadtC, recGadtC, -- *** Kinds varK, conK, tupleK, arrowK, listK, appK, starK, constraintK, -- *** Type variable binders plainTV, kindedTV, plainInvisTV, kindedInvisTV, specifiedSpec, inferredSpec, -- *** Roles nominalR, representationalR, phantomR, inferR, -- *** Top Level Declarations -- **** Data valD, funD, tySynD, dataD, newtypeD, derivClause, DerivClause(..), stockStrategy, anyclassStrategy, newtypeStrategy, viaStrategy, DerivStrategy(..), -- **** Class classD, instanceD, instanceWithOverlapD, Overlap(..), sigD, kiSigD, standaloneDerivD, standaloneDerivWithStrategyD, defaultSigD, -- **** Role annotations roleAnnotD, -- **** Type Family / Data Family dataFamilyD, openTypeFamilyD, closedTypeFamilyD, dataInstD, newtypeInstD, tySynInstD, tySynEqn, injectivityAnn, noSig, kindSig, tyVarSig, -- **** Fixity infixLD, infixRD, infixND, -- **** Foreign Function Interface (FFI) cCall, stdCall, cApi, prim, javaScript, unsafe, safe, interruptible, forImpD, -- **** Functional dependencies funDep, -- **** Pragmas ruleVar, typedRuleVar, valueAnnotation, typeAnnotation, moduleAnnotation, pragInlD, pragSpecD, pragSpecInlD, pragSpecInstD, pragRuleD, pragAnnD, pragLineD, pragCompleteD, -- **** Pattern Synonyms patSynD, patSynSigD, unidir, implBidir, explBidir, prefixPatSyn, infixPatSyn, recordPatSyn, -- **** Implicit Parameters implicitParamBindD, -- ** Reify thisModule, -- ** Documentation withDecDoc, withDecsDoc, funD_doc, dataD_doc, newtypeD_doc, dataInstD_doc, newtypeInstD_doc, patSynD_doc ) where import Language.Haskell.TH.Lib.Internal hiding ( tySynD , dataD , newtypeD , classD , pragRuleD , dataInstD , newtypeInstD , dataFamilyD , openTypeFamilyD , closedTypeFamilyD , tySynEqn , forallC , forallT , sigT , plainTV , kindedTV , starK , constraintK , noSig , kindSig , tyVarSig , derivClause , standaloneDerivWithStrategyD , doE , mdoE , tupE , unboxedTupE , conP , Role , InjectivityAnn ) import qualified Language.Haskell.TH.Lib.Internal as Internal import Language.Haskell.TH.Syntax import Control.Applicative ( liftA2 ) import Foreign.ForeignPtr import Data.Word import Prelude -- All definitions below represent the "old" API, since their definitions are -- different in Language.Haskell.TH.Lib.Internal. Please think carefully before -- deciding to change the APIs of the functions below, as they represent the -- public API (as opposed to the Internal module, which has no API promises.) ------------------------------------------------------------------------------- -- * Dec tySynD :: Quote m => Name -> [TyVarBndr ()] -> m Type -> m Dec tySynD tc tvs rhs = do { rhs1 <- rhs; return (TySynD tc tvs rhs1) } dataD :: Quote m => m Cxt -> Name -> [TyVarBndr ()] -> Maybe Kind -> [m Con] -> [m DerivClause] -> m Dec dataD ctxt tc tvs ksig cons derivs = do ctxt1 <- ctxt cons1 <- sequenceA cons derivs1 <- sequenceA derivs return (DataD ctxt1 tc tvs ksig cons1 derivs1) newtypeD :: Quote m => m Cxt -> Name -> [TyVarBndr ()] -> Maybe Kind -> m Con -> [m DerivClause] -> m Dec newtypeD ctxt tc tvs ksig con derivs = do ctxt1 <- ctxt con1 <- con derivs1 <- sequenceA derivs return (NewtypeD ctxt1 tc tvs ksig con1 derivs1) classD :: Quote m => m Cxt -> Name -> [TyVarBndr ()] -> [FunDep] -> [m Dec] -> m Dec classD ctxt cls tvs fds decs = do decs1 <- sequenceA decs ctxt1 <- ctxt return $ ClassD ctxt1 cls tvs fds decs1 pragRuleD :: Quote m => String -> [m RuleBndr] -> m Exp -> m Exp -> Phases -> m Dec pragRuleD n bndrs lhs rhs phases = do bndrs1 <- sequenceA bndrs lhs1 <- lhs rhs1 <- rhs return $ PragmaD $ RuleP n Nothing bndrs1 lhs1 rhs1 phases dataInstD :: Quote m => m Cxt -> Name -> [m Type] -> Maybe Kind -> [m Con] -> [m DerivClause] -> m Dec dataInstD ctxt tc tys ksig cons derivs = do ctxt1 <- ctxt ty1 <- foldl appT (conT tc) tys cons1 <- sequenceA cons derivs1 <- sequenceA derivs return (DataInstD ctxt1 Nothing ty1 ksig cons1 derivs1) newtypeInstD :: Quote m => m Cxt -> Name -> [m Type] -> Maybe Kind -> m Con -> [m DerivClause] -> m Dec newtypeInstD ctxt tc tys ksig con derivs = do ctxt1 <- ctxt ty1 <- foldl appT (conT tc) tys con1 <- con derivs1 <- sequenceA derivs return (NewtypeInstD ctxt1 Nothing ty1 ksig con1 derivs1) dataFamilyD :: Quote m => Name -> [TyVarBndr ()] -> Maybe Kind -> m Dec dataFamilyD tc tvs kind = pure $ DataFamilyD tc tvs kind openTypeFamilyD :: Quote m => Name -> [TyVarBndr ()] -> FamilyResultSig -> Maybe InjectivityAnn -> m Dec openTypeFamilyD tc tvs res inj = pure $ OpenTypeFamilyD (TypeFamilyHead tc tvs res inj) closedTypeFamilyD :: Quote m => Name -> [TyVarBndr ()] -> FamilyResultSig -> Maybe InjectivityAnn -> [m TySynEqn] -> m Dec closedTypeFamilyD tc tvs result injectivity eqns = do eqns1 <- sequenceA eqns return (ClosedTypeFamilyD (TypeFamilyHead tc tvs result injectivity) eqns1) tySynEqn :: Quote m => (Maybe [TyVarBndr ()]) -> m Type -> m Type -> m TySynEqn tySynEqn tvs lhs rhs = do lhs1 <- lhs rhs1 <- rhs return (TySynEqn tvs lhs1 rhs1) forallC :: Quote m => [TyVarBndr Specificity] -> m Cxt -> m Con -> m Con forallC ns ctxt con = liftA2 (ForallC ns) ctxt con ------------------------------------------------------------------------------- -- * Type forallT :: Quote m => [TyVarBndr Specificity] -> m Cxt -> m Type -> m Type forallT tvars ctxt ty = do ctxt1 <- ctxt ty1 <- ty return $ ForallT tvars ctxt1 ty1 sigT :: Quote m => m Type -> Kind -> m Type sigT t k = do t' <- t return $ SigT t' k ------------------------------------------------------------------------------- -- * Kind plainTV :: Name -> TyVarBndr () plainTV n = PlainTV n () kindedTV :: Name -> Kind -> TyVarBndr () kindedTV n k = KindedTV n () k starK :: Kind starK = StarT constraintK :: Kind constraintK = ConstraintT ------------------------------------------------------------------------------- -- * Type family result noSig :: FamilyResultSig noSig = NoSig kindSig :: Kind -> FamilyResultSig kindSig = KindSig tyVarSig :: TyVarBndr () -> FamilyResultSig tyVarSig = TyVarSig ------------------------------------------------------------------------------- -- * Top Level Declarations derivClause :: Quote m => Maybe DerivStrategy -> [m Pred] -> m DerivClause derivClause mds p = do p' <- cxt p return $ DerivClause mds p' standaloneDerivWithStrategyD :: Quote m => Maybe DerivStrategy -> m Cxt -> m Type -> m Dec standaloneDerivWithStrategyD mds ctxt ty = do ctxt' <- ctxt ty' <- ty return $ StandaloneDerivD mds ctxt' ty' ------------------------------------------------------------------------------- -- * Bytes literals -- | Create a Bytes datatype representing raw bytes to be embedded into the -- program/library binary. -- -- @since 2.16.0.0 mkBytes :: ForeignPtr Word8 -- ^ Pointer to the data -> Word -- ^ Offset from the pointer -> Word -- ^ Number of bytes -> Bytes mkBytes = Bytes ------------------------------------------------------------------------------- -- * Tuple expressions tupE :: Quote m => [m Exp] -> m Exp tupE es = do { es1 <- sequenceA es; return (TupE $ map Just es1)} unboxedTupE :: Quote m => [m Exp] -> m Exp unboxedTupE es = do { es1 <- sequenceA es; return (UnboxedTupE $ map Just es1)} ------------------------------------------------------------------------------- -- * Do expressions doE :: Quote m => [m Stmt] -> m Exp doE = Internal.doE Nothing mdoE :: Quote m => [m Stmt] -> m Exp mdoE = Internal.mdoE Nothing ------------------------------------------------------------------------------- -- * Patterns conP :: Quote m => Name -> [m Pat] -> m Pat conP n xs = Internal.conP n [] xs